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llvm / llvm-project / flang / refs/heads/main / . / lib / Optimizer / Builder / Character.cpp
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//===-- Character.cpp -----------------------------------------------------===//
//
// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
// See https://llvm.org/LICENSE.txt for license information.
// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
//
//===----------------------------------------------------------------------===//
//
// Coding style: https://mlir.llvm.org/getting_started/DeveloperGuide/
//
//===----------------------------------------------------------------------===//
#include "flang/Optimizer/Builder/Character.h"
#include "flang/Optimizer/Builder/DoLoopHelper.h"
#include "flang/Optimizer/Builder/FIRBuilder.h"
#include "flang/Optimizer/Builder/Todo.h"
#include "flang/Optimizer/Dialect/FIROpsSupport.h"
#include "llvm/Support/Debug.h"
#include <optional>
#define DEBUG_TYPE "flang-lower-character"
//===----------------------------------------------------------------------===//
// CharacterExprHelper implementation
//===----------------------------------------------------------------------===//
/// Unwrap all the ref and box types and return the inner element type.
static mlir::Type unwrapBoxAndRef(mlir::Type type) {
if (auto boxType = mlir::dyn_cast<fir::BoxCharType>(type))
return boxType.getEleTy();
while (true) {
type = fir::unwrapRefType(type);
if (auto boxTy = mlir::dyn_cast<fir::BoxType>(type))
type = boxTy.getEleTy();
else
break;
}
return type;
}
/// Unwrap base fir.char<kind,len> type.
static fir::CharacterType recoverCharacterType(mlir::Type type) {
type = fir::unwrapSequenceType(unwrapBoxAndRef(type));
if (auto charTy = mlir::dyn_cast<fir::CharacterType>(type))
return charTy;
llvm::report_fatal_error("expected a character type");
}
bool fir::factory::CharacterExprHelper::isCharacterScalar(mlir::Type type) {
type = unwrapBoxAndRef(type);
return !mlir::isa<fir::SequenceType>(type) && fir::isa_char(type);
}
bool fir::factory::CharacterExprHelper::isArray(mlir::Type type) {
type = unwrapBoxAndRef(type);
if (auto seqTy = mlir::dyn_cast<fir::SequenceType>(type))
return fir::isa_char(seqTy.getEleTy());
return false;
}
fir::CharacterType
fir::factory::CharacterExprHelper::getCharacterType(mlir::Type type) {
assert(isCharacterScalar(type) && "expected scalar character");
return recoverCharacterType(type);
}
fir::CharacterType
fir::factory::CharacterExprHelper::getCharType(mlir::Type type) {
return recoverCharacterType(type);
}
fir::CharacterType fir::factory::CharacterExprHelper::getCharacterType(
const fir::CharBoxValue &box) {
return getCharacterType(box.getBuffer().getType());
}
fir::CharacterType
fir::factory::CharacterExprHelper::getCharacterType(mlir::Value str) {
return getCharacterType(str.getType());
}
/// Determine the static size of the character. Returns the computed size, not
/// an IR Value.
static std::optional<fir::CharacterType::LenType>
getCompileTimeLength(const fir::CharBoxValue &box) {
auto len = recoverCharacterType(box.getBuffer().getType()).getLen();
if (len == fir::CharacterType::unknownLen())
return {};
return len;
}
/// Detect the precondition that the value `str` does not reside in memory. Such
/// values will have a type `!fir.array<...x!fir.char<N>>` or `!fir.char<N>`.
LLVM_ATTRIBUTE_UNUSED static bool needToMaterialize(mlir::Value str) {
return mlir::isa<fir::SequenceType>(str.getType()) ||
fir::isa_char(str.getType());
}
/// This is called only if `str` does not reside in memory. Such a bare string
/// value will be converted into a memory-based temporary and an extended
/// boxchar value returned.
fir::CharBoxValue
fir::factory::CharacterExprHelper::materializeValue(mlir::Value str) {
assert(needToMaterialize(str));
auto ty = str.getType();
assert(isCharacterScalar(ty) && "expected scalar character");
auto charTy = mlir::dyn_cast<fir::CharacterType>(ty);
if (!charTy || charTy.getLen() == fir::CharacterType::unknownLen()) {
LLVM_DEBUG(llvm::dbgs() << "cannot materialize: " << str << '\n');
llvm_unreachable("must be a !fir.char<N> type");
}
auto len = builder.createIntegerConstant(
loc, builder.getCharacterLengthType(), charTy.getLen());
auto temp = builder.create<fir::AllocaOp>(loc, charTy);
builder.create<fir::StoreOp>(loc, str, temp);
LLVM_DEBUG(llvm::dbgs() << "materialized as local: " << str << " -> (" << temp
<< ", " << len << ")\n");
return {temp, len};
}
fir::ExtendedValue
fir::factory::CharacterExprHelper::toExtendedValue(mlir::Value character,
mlir::Value len) {
auto lenType = builder.getCharacterLengthType();
auto type = character.getType();
auto base = fir::isa_passbyref_type(type) ? character : mlir::Value{};
auto resultLen = len;
llvm::SmallVector<mlir::Value> extents;
if (auto eleType = fir::dyn_cast_ptrEleTy(type))
type = eleType;
if (auto arrayType = mlir::dyn_cast<fir::SequenceType>(type)) {
type = arrayType.getEleTy();
auto indexType = builder.getIndexType();
for (auto extent : arrayType.getShape()) {
if (extent == fir::SequenceType::getUnknownExtent())
break;
extents.emplace_back(
builder.createIntegerConstant(loc, indexType, extent));
}
// Last extent might be missing in case of assumed-size. If more extents
// could not be deduced from type, that's an error (a fir.box should
// have been used in the interface).
if (extents.size() + 1 < arrayType.getShape().size())
mlir::emitError(loc, "cannot retrieve array extents from type");
}
if (auto charTy = mlir::dyn_cast<fir::CharacterType>(type)) {
if (!resultLen && charTy.getLen() != fir::CharacterType::unknownLen())
resultLen = builder.createIntegerConstant(loc, lenType, charTy.getLen());
} else if (auto boxCharType = mlir::dyn_cast<fir::BoxCharType>(type)) {
auto refType = builder.getRefType(boxCharType.getEleTy());
// If the embox is accessible, use its operand to avoid filling
// the generated fir with embox/unbox.
mlir::Value boxCharLen;
if (auto definingOp = character.getDefiningOp()) {
if (auto box = mlir::dyn_cast<fir::EmboxCharOp>(definingOp)) {
base = box.getMemref();
boxCharLen = box.getLen();
}
}
if (!boxCharLen) {
auto unboxed =
builder.create<fir::UnboxCharOp>(loc, refType, lenType, character);
base = builder.createConvert(loc, refType, unboxed.getResult(0));
boxCharLen = unboxed.getResult(1);
}
if (!resultLen) {
resultLen = boxCharLen;
}
} else if (mlir::isa<fir::BoxType>(type)) {
mlir::emitError(loc, "descriptor or derived type not yet handled");
} else {
llvm_unreachable("Cannot translate mlir::Value to character ExtendedValue");
}
if (!base) {
if (auto load =
mlir::dyn_cast_or_null<fir::LoadOp>(character.getDefiningOp())) {
base = load.getOperand();
} else {
return materializeValue(fir::getBase(character));
}
}
if (!resultLen)
llvm::report_fatal_error("no dynamic length found for character");
if (!extents.empty())
return fir::CharArrayBoxValue{base, resultLen, extents};
return fir::CharBoxValue{base, resultLen};
}
static mlir::Type getSingletonCharType(mlir::MLIRContext *ctxt, int kind) {
return fir::CharacterType::getSingleton(ctxt, kind);
}
mlir::Value
fir::factory::CharacterExprHelper::createEmbox(const fir::CharBoxValue &box) {
// Base CharBoxValue of CharArrayBoxValue are ok here (do not require a scalar
// type)
auto charTy = recoverCharacterType(box.getBuffer().getType());
auto boxCharType =
fir::BoxCharType::get(builder.getContext(), charTy.getFKind());
auto refType = fir::ReferenceType::get(boxCharType.getEleTy());
mlir::Value buff = box.getBuffer();
// fir.boxchar requires a memory reference. Allocate temp if the character is
// not in memory.
if (!fir::isa_ref_type(buff.getType())) {
auto temp = builder.createTemporary(loc, buff.getType());
builder.create<fir::StoreOp>(loc, buff, temp);
buff = temp;
}
// fir.emboxchar only accepts scalar, cast array buffer to a scalar buffer.
if (mlir::isa<fir::SequenceType>(fir::dyn_cast_ptrEleTy(buff.getType())))
buff = builder.createConvert(loc, refType, buff);
// Convert in case the provided length is not of the integer type that must
// be used in boxchar.
auto len = builder.createConvert(loc, builder.getCharacterLengthType(),
box.getLen());
return builder.create<fir::EmboxCharOp>(loc, boxCharType, buff, len);
}
fir::CharBoxValue fir::factory::CharacterExprHelper::toScalarCharacter(
const fir::CharArrayBoxValue &box) {
if (mlir::isa<fir::PointerType>(box.getBuffer().getType()))
TODO(loc, "concatenating non contiguous character array into a scalar");
// TODO: add a fast path multiplying new length at compile time if the info is
// in the array type.
auto lenType = builder.getCharacterLengthType();
auto len = builder.createConvert(loc, lenType, box.getLen());
for (auto extent : box.getExtents())
len = builder.create<mlir::arith::MulIOp>(
loc, len, builder.createConvert(loc, lenType, extent));
// TODO: typeLen can be improved in compiled constant cases
// TODO: allow bare fir.array<> (no ref) conversion here ?
auto typeLen = fir::CharacterType::unknownLen();
auto kind = recoverCharacterType(box.getBuffer().getType()).getFKind();
auto charTy = fir::CharacterType::get(builder.getContext(), kind, typeLen);
auto type = fir::ReferenceType::get(charTy);
auto buffer = builder.createConvert(loc, type, box.getBuffer());
return {buffer, len};
}
mlir::Value fir::factory::CharacterExprHelper::createEmbox(
const fir::CharArrayBoxValue &box) {
// Use same embox as for scalar. It's losing the actual data size information
// (We do not multiply the length by the array size), but that is what Fortran
// call interfaces using boxchar expect.
return createEmbox(static_cast<const fir::CharBoxValue &>(box));
}
/// Get the address of the element at position \p index of the scalar character
/// \p buffer.
/// \p buffer must be of type !fir.ref<fir.char<k, len>>. The length may be
/// unknown. \p index must have any integer type, and is zero based. The return
/// value is a singleton address (!fir.ref<!fir.char<kind>>)
mlir::Value
fir::factory::CharacterExprHelper::createElementAddr(mlir::Value buffer,
mlir::Value index) {
// The only way to address an element of a fir.ref<char<kind, len>> is to cast
// it to a fir.array<len x fir.char<kind>> and use fir.coordinate_of.
auto bufferType = buffer.getType();
assert(fir::isa_ref_type(bufferType));
assert(isCharacterScalar(bufferType));
auto charTy = recoverCharacterType(bufferType);
auto singleTy = getSingletonCharType(builder.getContext(), charTy.getFKind());
auto singleRefTy = builder.getRefType(singleTy);
auto extent = fir::SequenceType::getUnknownExtent();
if (charTy.getLen() != fir::CharacterType::unknownLen())
extent = charTy.getLen();
auto coorTy = builder.getRefType(fir::SequenceType::get({extent}, singleTy));
auto coor = builder.createConvert(loc, coorTy, buffer);
auto i = builder.createConvert(loc, builder.getIndexType(), index);
return builder.create<fir::CoordinateOp>(loc, singleRefTy, coor, i);
}
/// Load a character out of `buff` from offset `index`.
/// `buff` must be a reference to memory.
mlir::Value
fir::factory::CharacterExprHelper::createLoadCharAt(mlir::Value buff,
mlir::Value index) {
LLVM_DEBUG(llvm::dbgs() << "load a char: " << buff << " type: "
<< buff.getType() << " at: " << index << '\n');
return builder.create<fir::LoadOp>(loc, createElementAddr(buff, index));
}
/// Store the singleton character `c` to `str` at offset `index`.
/// `str` must be a reference to memory.
void fir::factory::CharacterExprHelper::createStoreCharAt(mlir::Value str,
mlir::Value index,
mlir::Value c) {
LLVM_DEBUG(llvm::dbgs() << "store the char: " << c << " into: " << str
<< " type: " << str.getType() << " at: " << index
<< '\n');
auto addr = createElementAddr(str, index);
builder.create<fir::StoreOp>(loc, c, addr);
}
// FIXME: this temp is useless... either fir.coordinate_of needs to
// work on "loaded" characters (!fir.array<len x fir.char<kind>>) or
// character should never be loaded.
// If this is a fir.array<>, allocate and store the value so that
// fir.cooridnate_of can be use on the value.
mlir::Value fir::factory::CharacterExprHelper::getCharBoxBuffer(
const fir::CharBoxValue &box) {
auto buff = box.getBuffer();
if (fir::isa_char(buff.getType())) {
auto newBuff = builder.create<fir::AllocaOp>(loc, buff.getType());
builder.create<fir::StoreOp>(loc, buff, newBuff);
return newBuff;
}
return buff;
}
/// Create a loop to copy `count` characters from `src` to `dest`. Note that the
/// KIND indicates the number of bits in a code point. (ASCII, UCS-2, or UCS-4.)
void fir::factory::CharacterExprHelper::createCopy(
const fir::CharBoxValue &dest, const fir::CharBoxValue &src,
mlir::Value count) {
auto fromBuff = getCharBoxBuffer(src);
auto toBuff = getCharBoxBuffer(dest);
LLVM_DEBUG(llvm::dbgs() << "create char copy from: "; src.dump();
llvm::dbgs() << " to: "; dest.dump();
llvm::dbgs() << " count: " << count << '\n');
auto kind = getCharacterKind(src.getBuffer().getType());
// If the src and dest are the same KIND, then use memmove to move the bits.
// We don't have to worry about overlapping ranges with memmove.
if (getCharacterKind(dest.getBuffer().getType()) == kind) {
auto bytes = builder.getKindMap().getCharacterBitsize(kind) / 8;
auto i64Ty = builder.getI64Type();
auto kindBytes = builder.createIntegerConstant(loc, i64Ty, bytes);
auto castCount = builder.createConvert(loc, i64Ty, count);
auto totalBytes =
builder.create<mlir::arith::MulIOp>(loc, kindBytes, castCount);
auto notVolatile = builder.createBool(loc, false);
auto memmv = getLlvmMemmove(builder);
auto argTys = memmv.getFunctionType().getInputs();
auto toPtr = builder.createConvert(loc, argTys[0], toBuff);
auto fromPtr = builder.createConvert(loc, argTys[1], fromBuff);
builder.create<fir::CallOp>(
loc, memmv, mlir::ValueRange{toPtr, fromPtr, totalBytes, notVolatile});
return;
}
// Convert a CHARACTER of one KIND into a CHARACTER of another KIND.
builder.create<fir::CharConvertOp>(loc, src.getBuffer(), count,
dest.getBuffer());
}
void fir::factory::CharacterExprHelper::createPadding(
const fir::CharBoxValue &str, mlir::Value lower, mlir::Value upper) {
auto blank = createBlankConstant(getCharacterType(str));
// Always create the loop, if upper < lower, no iteration will be
// executed.
auto toBuff = getCharBoxBuffer(str);
fir::factory::DoLoopHelper{builder, loc}.createLoop(
lower, upper, [&](fir::FirOpBuilder &, mlir::Value index) {
createStoreCharAt(toBuff, index, blank);
});
}
fir::CharBoxValue
fir::factory::CharacterExprHelper::createCharacterTemp(mlir::Type type,
mlir::Value len) {
auto kind = recoverCharacterType(type).getFKind();
auto typeLen = fir::CharacterType::unknownLen();
// If len is a constant, reflect the length in the type.
if (auto cstLen = getIntIfConstant(len))
typeLen = *cstLen;
auto *ctxt = builder.getContext();
auto charTy = fir::CharacterType::get(ctxt, kind, typeLen);
llvm::SmallVector<mlir::Value> lenParams;
if (typeLen == fir::CharacterType::unknownLen())
lenParams.push_back(len);
auto ref = builder.allocateLocal(loc, charTy, "", ".chrtmp",
/*shape=*/std::nullopt, lenParams);
return {ref, len};
}
fir::CharBoxValue fir::factory::CharacterExprHelper::createTempFrom(
const fir::ExtendedValue &source) {
const auto *charBox = source.getCharBox();
if (!charBox)
fir::emitFatalError(loc, "source must be a fir::CharBoxValue");
auto len = charBox->getLen();
auto sourceTy = charBox->getBuffer().getType();
auto temp = createCharacterTemp(sourceTy, len);
if (fir::isa_ref_type(sourceTy)) {
createCopy(temp, *charBox, len);
} else {
auto ref = builder.createConvert(loc, builder.getRefType(sourceTy),
temp.getBuffer());
builder.create<fir::StoreOp>(loc, charBox->getBuffer(), ref);
}
return temp;
}
// Simple length one character assignment without loops.
void fir::factory::CharacterExprHelper::createLengthOneAssign(
const fir::CharBoxValue &lhs, const fir::CharBoxValue &rhs) {
auto addr = lhs.getBuffer();
auto toTy = fir::unwrapRefType(addr.getType());
mlir::Value val = rhs.getBuffer();
if (fir::isa_ref_type(val.getType())) {
auto fromCharLen1RefTy = builder.getRefType(getSingletonCharType(
builder.getContext(),
getCharacterKind(fir::unwrapRefType(val.getType()))));
val = builder.create<fir::LoadOp>(
loc, builder.createConvert(loc, fromCharLen1RefTy, val));
}
auto toCharLen1Ty =
getSingletonCharType(builder.getContext(), getCharacterKind(toTy));
val = builder.createConvert(loc, toCharLen1Ty, val);
builder.create<fir::StoreOp>(
loc, val,
builder.createConvert(loc, builder.getRefType(toCharLen1Ty), addr));
}
/// Returns the minimum of integer mlir::Value \p a and \b.
mlir::Value genMin(fir::FirOpBuilder &builder, mlir::Location loc,
mlir::Value a, mlir::Value b) {
auto cmp = builder.create<mlir::arith::CmpIOp>(
loc, mlir::arith::CmpIPredicate::slt, a, b);
return builder.create<mlir::arith::SelectOp>(loc, cmp, a, b);
}
void fir::factory::CharacterExprHelper::createAssign(
const fir::CharBoxValue &lhs, const fir::CharBoxValue &rhs) {
auto rhsCstLen = getCompileTimeLength(rhs);
auto lhsCstLen = getCompileTimeLength(lhs);
bool compileTimeSameLength = false;
bool isLengthOneAssign = false;
if (lhsCstLen && rhsCstLen && *lhsCstLen == *rhsCstLen) {
compileTimeSameLength = true;
if (*lhsCstLen == 1)
isLengthOneAssign = true;
} else if (rhs.getLen() == lhs.getLen()) {
compileTimeSameLength = true;
// If the length values are the same for LHS and RHS,
// then we can rely on the constant length deduced from
// any of the two types.
if (lhsCstLen && *lhsCstLen == 1)
isLengthOneAssign = true;
if (rhsCstLen && *rhsCstLen == 1)
isLengthOneAssign = true;
// We could have recognized constant operations here (e.g.
// two different arith.constant ops may produce the same value),
// but for now leave it to CSE to get rid of the duplicates.
}
if (isLengthOneAssign) {
createLengthOneAssign(lhs, rhs);
return;
}
// Copy the minimum of the lhs and rhs lengths and pad the lhs remainder
// if needed.
auto copyCount = lhs.getLen();
auto idxTy = builder.getIndexType();
if (!compileTimeSameLength) {
auto lhsLen = builder.createConvert(loc, idxTy, lhs.getLen());
auto rhsLen = builder.createConvert(loc, idxTy, rhs.getLen());
copyCount = genMin(builder, loc, lhsLen, rhsLen);
}
// Actual copy
createCopy(lhs, rhs, copyCount);
// Pad if needed.
if (!compileTimeSameLength) {
auto one = builder.createIntegerConstant(loc, lhs.getLen().getType(), 1);
auto maxPadding =
builder.create<mlir::arith::SubIOp>(loc, lhs.getLen(), one);
createPadding(lhs, copyCount, maxPadding);
}
}
fir::CharBoxValue fir::factory::CharacterExprHelper::createConcatenate(
const fir::CharBoxValue &lhs, const fir::CharBoxValue &rhs) {
auto lhsLen = builder.createConvert(loc, builder.getCharacterLengthType(),
lhs.getLen());
auto rhsLen = builder.createConvert(loc, builder.getCharacterLengthType(),
rhs.getLen());
mlir::Value len = builder.create<mlir::arith::AddIOp>(loc, lhsLen, rhsLen);
auto temp = createCharacterTemp(getCharacterType(rhs), len);
createCopy(temp, lhs, lhsLen);
auto one = builder.createIntegerConstant(loc, len.getType(), 1);
auto upperBound = builder.create<mlir::arith::SubIOp>(loc, len, one);
auto lhsLenIdx = builder.createConvert(loc, builder.getIndexType(), lhsLen);
auto fromBuff = getCharBoxBuffer(rhs);
auto toBuff = getCharBoxBuffer(temp);
fir::factory::DoLoopHelper{builder, loc}.createLoop(
lhsLenIdx, upperBound, one,
[&](fir::FirOpBuilder &bldr, mlir::Value index) {
auto rhsIndex = bldr.create<mlir::arith::SubIOp>(loc, index, lhsLenIdx);
auto charVal = createLoadCharAt(fromBuff, rhsIndex);
createStoreCharAt(toBuff, index, charVal);
});
return temp;
}
mlir::Value fir::factory::CharacterExprHelper::genSubstringBase(
mlir::Value stringRawAddr, mlir::Value lowerBound,
mlir::Type substringAddrType, mlir::Value one) {
if (!one)
one = builder.createIntegerConstant(loc, lowerBound.getType(), 1);
auto offset =
builder.create<mlir::arith::SubIOp>(loc, lowerBound, one).getResult();
auto addr = createElementAddr(stringRawAddr, offset);
return builder.createConvert(loc, substringAddrType, addr);
}
fir::CharBoxValue fir::factory::CharacterExprHelper::createSubstring(
const fir::CharBoxValue &box, llvm::ArrayRef<mlir::Value> bounds) {
// Constant need to be materialize in memory to use fir.coordinate_of.
auto nbounds = bounds.size();
if (nbounds < 1 || nbounds > 2) {
mlir::emitError(loc, "Incorrect number of bounds in substring");
return {mlir::Value{}, mlir::Value{}};
}
mlir::SmallVector<mlir::Value> castBounds;
// Convert bounds to length type to do safe arithmetic on it.
for (auto bound : bounds)
castBounds.push_back(
builder.createConvert(loc, builder.getCharacterLengthType(), bound));
auto lowerBound = castBounds[0];
// FIR CoordinateOp is zero based but Fortran substring are one based.
auto kind = getCharacterKind(box.getBuffer().getType());
auto charTy = fir::CharacterType::getUnknownLen(builder.getContext(), kind);
auto resultType = builder.getRefType(charTy);
auto one = builder.createIntegerConstant(loc, lowerBound.getType(), 1);
auto substringRef =
genSubstringBase(box.getBuffer(), lowerBound, resultType, one);
// Compute the length.
mlir::Value substringLen;
if (nbounds < 2) {
substringLen =
builder.create<mlir::arith::SubIOp>(loc, box.getLen(), castBounds[0]);
} else {
substringLen =
builder.create<mlir::arith::SubIOp>(loc, castBounds[1], castBounds[0]);
}
substringLen = builder.create<mlir::arith::AddIOp>(loc, substringLen, one);
// Set length to zero if bounds were reversed (Fortran 2018 9.4.1)
auto zero = builder.createIntegerConstant(loc, substringLen.getType(), 0);
auto cdt = builder.create<mlir::arith::CmpIOp>(
loc, mlir::arith::CmpIPredicate::slt, substringLen, zero);
substringLen =
builder.create<mlir::arith::SelectOp>(loc, cdt, zero, substringLen);
return {substringRef, substringLen};
}
mlir::Value
fir::factory::CharacterExprHelper::createLenTrim(const fir::CharBoxValue &str) {
// Note: Runtime for LEN_TRIM should also be available at some
// point. For now use an inlined implementation.
auto indexType = builder.getIndexType();
auto len = builder.createConvert(loc, indexType, str.getLen());
auto one = builder.createIntegerConstant(loc, indexType, 1);
auto minusOne = builder.createIntegerConstant(loc, indexType, -1);
auto zero = builder.createIntegerConstant(loc, indexType, 0);
auto trueVal = builder.createIntegerConstant(loc, builder.getI1Type(), 1);
auto blank = createBlankConstantCode(getCharacterType(str));
mlir::Value lastChar = builder.create<mlir::arith::SubIOp>(loc, len, one);
auto iterWhile =
builder.create<fir::IterWhileOp>(loc, lastChar, zero, minusOne, trueVal,
/*returnFinalCount=*/false, lastChar);
auto insPt = builder.saveInsertionPoint();
builder.setInsertionPointToStart(iterWhile.getBody());
auto index = iterWhile.getInductionVar();
// Look for first non-blank from the right of the character.
auto fromBuff = getCharBoxBuffer(str);
auto elemAddr = createElementAddr(fromBuff, index);
auto codeAddr =
builder.createConvert(loc, builder.getRefType(blank.getType()), elemAddr);
auto c = builder.create<fir::LoadOp>(loc, codeAddr);
auto isBlank = builder.create<mlir::arith::CmpIOp>(
loc, mlir::arith::CmpIPredicate::eq, blank, c);
llvm::SmallVector<mlir::Value> results = {isBlank, index};
builder.create<fir::ResultOp>(loc, results);
builder.restoreInsertionPoint(insPt);
// Compute length after iteration (zero if all blanks)
mlir::Value newLen =
builder.create<mlir::arith::AddIOp>(loc, iterWhile.getResult(1), one);
auto result = builder.create<mlir::arith::SelectOp>(
loc, iterWhile.getResult(0), zero, newLen);
return builder.createConvert(loc, builder.getCharacterLengthType(), result);
}
fir::CharBoxValue
fir::factory::CharacterExprHelper::createCharacterTemp(mlir::Type type,
int len) {
assert(len >= 0 && "expected positive length");
auto kind = recoverCharacterType(type).getFKind();
auto charType = fir::CharacterType::get(builder.getContext(), kind, len);
auto addr = builder.create<fir::AllocaOp>(loc, charType);
auto mlirLen =
builder.createIntegerConstant(loc, builder.getCharacterLengthType(), len);
return {addr, mlirLen};
}
// Returns integer with code for blank. The integer has the same
// size as the character. Blank has ascii space code for all kinds.
mlir::Value fir::factory::CharacterExprHelper::createBlankConstantCode(
fir::CharacterType type) {
auto bits = builder.getKindMap().getCharacterBitsize(type.getFKind());
auto intType = builder.getIntegerType(bits);
return builder.createIntegerConstant(loc, intType, ' ');
}
mlir::Value fir::factory::CharacterExprHelper::createBlankConstant(
fir::CharacterType type) {
return createSingletonFromCode(createBlankConstantCode(type),
type.getFKind());
}
void fir::factory::CharacterExprHelper::createAssign(
const fir::ExtendedValue &lhs, const fir::ExtendedValue &rhs) {
if (auto *str = rhs.getBoxOf<fir::CharBoxValue>()) {
if (auto *to = lhs.getBoxOf<fir::CharBoxValue>()) {
createAssign(*to, *str);
return;
}
}
TODO(loc, "character array assignment");
// Note that it is not sure the array aspect should be handled
// by this utility.
}
mlir::Value
fir::factory::CharacterExprHelper::createEmboxChar(mlir::Value addr,
mlir::Value len) {
return createEmbox(fir::CharBoxValue{addr, len});
}
std::pair<mlir::Value, mlir::Value>
fir::factory::CharacterExprHelper::createUnboxChar(mlir::Value boxChar) {
using T = std::pair<mlir::Value, mlir::Value>;
return toExtendedValue(boxChar).match(
[](const fir::CharBoxValue &b) -> T {
return {b.getBuffer(), b.getLen()};
},
[](const fir::CharArrayBoxValue &b) -> T {
return {b.getBuffer(), b.getLen()};
},
[](const auto &) -> T { llvm::report_fatal_error("not a character"); });
}
bool fir::factory::CharacterExprHelper::isCharacterLiteral(mlir::Type type) {
if (auto seqType = mlir::dyn_cast<fir::SequenceType>(type))
return (seqType.getShape().size() == 1) &&
fir::isa_char(seqType.getEleTy());
return false;
}
fir::KindTy
fir::factory::CharacterExprHelper::getCharacterKind(mlir::Type type) {
assert(isCharacterScalar(type) && "expected scalar character");
return recoverCharacterType(type).getFKind();
}
fir::KindTy
fir::factory::CharacterExprHelper::getCharacterOrSequenceKind(mlir::Type type) {
return recoverCharacterType(type).getFKind();
}
bool fir::factory::CharacterExprHelper::hasConstantLengthInType(
const fir::ExtendedValue &exv) {
auto charTy = recoverCharacterType(fir::getBase(exv).getType());
return charTy.hasConstantLen();
}
mlir::Value
fir::factory::CharacterExprHelper::createSingletonFromCode(mlir::Value code,
int kind) {
auto charType = fir::CharacterType::get(builder.getContext(), kind, 1);
auto bits = builder.getKindMap().getCharacterBitsize(kind);
auto intType = builder.getIntegerType(bits);
auto cast = builder.createConvert(loc, intType, code);
auto undef = builder.create<fir::UndefOp>(loc, charType);
auto zero = builder.getIntegerAttr(builder.getIndexType(), 0);
return builder.create<fir::InsertValueOp>(loc, charType, undef, cast,
builder.getArrayAttr(zero));
}
mlir::Value fir::factory::CharacterExprHelper::extractCodeFromSingleton(
mlir::Value singleton) {
auto type = getCharacterType(singleton);
assert(type.getLen() == 1);
auto bits = builder.getKindMap().getCharacterBitsize(type.getFKind());
auto intType = builder.getIntegerType(bits);
auto zero = builder.getIntegerAttr(builder.getIndexType(), 0);
return builder.create<fir::ExtractValueOp>(loc, intType, singleton,
builder.getArrayAttr(zero));
}
mlir::Value
fir::factory::CharacterExprHelper::readLengthFromBox(mlir::Value box) {
auto charTy = recoverCharacterType(box.getType());
return readLengthFromBox(box, charTy);
}
mlir::Value fir::factory::CharacterExprHelper::readLengthFromBox(
mlir::Value box, fir::CharacterType charTy) {
auto lenTy = builder.getCharacterLengthType();
auto size = builder.create<fir::BoxEleSizeOp>(loc, lenTy, box);
auto bits = builder.getKindMap().getCharacterBitsize(charTy.getFKind());
auto width = bits / 8;
if (width > 1) {
auto widthVal = builder.createIntegerConstant(loc, lenTy, width);
return builder.create<mlir::arith::DivSIOp>(loc, size, widthVal);
}
return size;
}
mlir::Value fir::factory::CharacterExprHelper::getLength(mlir::Value memref) {
auto memrefType = memref.getType();
auto charType = recoverCharacterType(memrefType);
assert(charType && "must be a character type");
if (charType.hasConstantLen())
return builder.createIntegerConstant(loc, builder.getCharacterLengthType(),
charType.getLen());
if (mlir::isa<fir::BoxType>(memrefType))
return readLengthFromBox(memref);
if (mlir::isa<fir::BoxCharType>(memrefType))
return createUnboxChar(memref).second;
// Length cannot be deduced from memref.
return {};
}
std::pair<mlir::Value, mlir::Value>
fir::factory::extractCharacterProcedureTuple(fir::FirOpBuilder &builder,
mlir::Location loc,
mlir::Value tuple,
bool openBoxProc) {
mlir::TupleType tupleType = mlir::cast<mlir::TupleType>(tuple.getType());
mlir::Value addr = builder.create<fir::ExtractValueOp>(
loc, tupleType.getType(0), tuple,
builder.getArrayAttr(
{builder.getIntegerAttr(builder.getIndexType(), 0)}));
mlir::Value proc = [&]() -> mlir::Value {
if (openBoxProc)
if (auto addrTy = mlir::dyn_cast<fir::BoxProcType>(addr.getType()))
return builder.create<fir::BoxAddrOp>(loc, addrTy.getEleTy(), addr);
return addr;
}();
mlir::Value len = builder.create<fir::ExtractValueOp>(
loc, tupleType.getType(1), tuple,
builder.getArrayAttr(
{builder.getIntegerAttr(builder.getIndexType(), 1)}));
return {proc, len};
}
mlir::Value fir::factory::createCharacterProcedureTuple(
fir::FirOpBuilder &builder, mlir::Location loc, mlir::Type argTy,
mlir::Value addr, mlir::Value len) {
mlir::TupleType tupleType = mlir::cast<mlir::TupleType>(argTy);
addr = builder.createConvert(loc, tupleType.getType(0), addr);
if (len)
len = builder.createConvert(loc, tupleType.getType(1), len);
else
len = builder.create<fir::UndefOp>(loc, tupleType.getType(1));
mlir::Value tuple = builder.create<fir::UndefOp>(loc, tupleType);
tuple = builder.create<fir::InsertValueOp>(
loc, tupleType, tuple, addr,
builder.getArrayAttr(
{builder.getIntegerAttr(builder.getIndexType(), 0)}));
tuple = builder.create<fir::InsertValueOp>(
loc, tupleType, tuple, len,
builder.getArrayAttr(
{builder.getIntegerAttr(builder.getIndexType(), 1)}));
return tuple;
}
mlir::Type
fir::factory::getCharacterProcedureTupleType(mlir::Type funcPointerType) {
mlir::MLIRContext *context = funcPointerType.getContext();
mlir::Type lenType = mlir::IntegerType::get(context, 64);
return mlir::TupleType::get(context, {funcPointerType, lenType});
}
fir::CharBoxValue fir::factory::CharacterExprHelper::createCharExtremum(
bool predIsMin, llvm::ArrayRef<fir::CharBoxValue> opCBVs) {
// inputs: we are given a vector of all of the charboxes of the arguments
// passed to hlfir.char_extremum, as well as the predicate for whether we
// want llt or lgt
//
// note: we know that, regardless of whether we're looking at smallest or
// largest char, the size of the output buffer will be the same size as the
// largest character out of all of the operands. so, we find the biggest
// length first. It's okay if these char lengths are not known at compile
// time.
fir::CharBoxValue firstCBV = opCBVs[0];
mlir::Value firstBuf = getCharBoxBuffer(firstCBV);
auto firstLen = builder.createConvert(loc, builder.getCharacterLengthType(),
firstCBV.getLen());
mlir::Value resultBuf = firstBuf;
mlir::Value resultLen = firstLen;
mlir::Value biggestLen = firstLen;
// values for casting buf type and len type
auto typeLen = fir::CharacterType::unknownLen();
auto kind = recoverCharacterType(firstBuf.getType()).getFKind();
auto charTy = fir::CharacterType::get(builder.getContext(), kind, typeLen);
auto type = fir::ReferenceType::get(charTy);
size_t numOperands = opCBVs.size();
for (size_t cbv_idx = 1; cbv_idx < numOperands; ++cbv_idx) {
auto currChar = opCBVs[cbv_idx];
auto currBuf = getCharBoxBuffer(currChar);
auto currLen = builder.createConvert(loc, builder.getCharacterLengthType(),
currChar.getLen());
// biggest len result
mlir::Value lhsBigger = builder.create<mlir::arith::CmpIOp>(
loc, mlir::arith::CmpIPredicate::uge, biggestLen, currLen);
biggestLen = builder.create<mlir::arith::SelectOp>(loc, lhsBigger,
biggestLen, currLen);
auto cmp = predIsMin ? mlir::arith::CmpIPredicate::slt
: mlir::arith::CmpIPredicate::sgt;
// lexical compare result
mlir::Value resultCmp = fir::runtime::genCharCompare(
builder, loc, cmp, currBuf, currLen, resultBuf, resultLen);
// it's casting (to unknown size) time!
resultBuf = builder.createConvert(loc, type, resultBuf);
currBuf = builder.createConvert(loc, type, currBuf);
resultBuf = builder.create<mlir::arith::SelectOp>(loc, resultCmp, currBuf,
resultBuf);
resultLen = builder.create<mlir::arith::SelectOp>(loc, resultCmp, currLen,
resultLen);
}
// now that we know the lexicographically biggest/smallest char and which char
// had the biggest len, we can populate a temp CBV and return it
fir::CharBoxValue temp = createCharacterTemp(resultBuf.getType(), biggestLen);
auto toBuf = temp;
fir::CharBoxValue fromBuf{resultBuf, resultLen};
createAssign(toBuf, fromBuf);
return temp;
}
fir::CharBoxValue
fir::factory::convertCharacterKind(fir::FirOpBuilder &builder,
mlir::Location loc,
fir::CharBoxValue srcBoxChar, int toKind) {
// Use char_convert. Each code point is translated from a
// narrower/wider encoding to the target encoding. For example, 'A'
// may be translated from 0x41 : i8 to 0x0041 : i16. The symbol
// for euro (0x20AC : i16) may be translated from a wide character
// to "0xE2 0x82 0xAC" : UTF-8.
mlir::Value bufferSize = srcBoxChar.getLen();
auto kindMap = builder.getKindMap();
mlir::Value boxCharAddr = srcBoxChar.getAddr();
auto fromTy = boxCharAddr.getType();
if (auto charTy = mlir::dyn_cast<fir::CharacterType>(fromTy)) {
// boxchar is a value, not a variable. Turn it into a temporary.
// As a value, it ought to have a constant LEN value.
assert(charTy.hasConstantLen() && "must have constant length");
mlir::Value tmp = builder.createTemporary(loc, charTy);
builder.create<fir::StoreOp>(loc, boxCharAddr, tmp);
boxCharAddr = tmp;
}
auto fromBits = kindMap.getCharacterBitsize(
mlir::cast<fir::CharacterType>(fir::unwrapRefType(fromTy)).getFKind());
auto toBits = kindMap.getCharacterBitsize(toKind);
if (toBits < fromBits) {
// Scale by relative ratio to give a buffer of the same length.
auto ratio = builder.createIntegerConstant(loc, bufferSize.getType(),
fromBits / toBits);
bufferSize = builder.create<mlir::arith::MulIOp>(loc, bufferSize, ratio);
}
mlir::Type toType =
fir::CharacterType::getUnknownLen(builder.getContext(), toKind);
auto dest = builder.createTemporary(loc, toType, /*name=*/{}, /*shape=*/{},
mlir::ValueRange{bufferSize});
builder.create<fir::CharConvertOp>(loc, boxCharAddr, srcBoxChar.getLen(),
dest);
return fir::CharBoxValue{dest, srcBoxChar.getLen()};
}