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[flang] REAL(KIND=3) and COMPLEX(KIND=3) descriptors

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Update descriptor generation to correctly set the `type` field for
REAL(3) and COMPLEX(3) objects.
This commit is contained in:
V Donaldson
2023-04-14 11:54:07 -07:00
parent dcf296b541
commit bddd7a6436
7 changed files with 229 additions and 139 deletions
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9
flang/include/flang/ISO_Fortran_binding.h
View File

@@ -43,8 +43,7 @@ typedef unsigned char CFI_attribute_t;
typedef signed char CFI_type_t;
/* These codes are required to be macros (i.e., #ifdef will work).
* They are not required to be distinct, but neither are they required
* to have had their synonyms combined. Codes marked as extensions may be
* place holders for as yet unimplemented types.
* to have had their synonyms combined.
*/
#define CFI_type_signed_char 1
#define CFI_type_short 2
@@ -56,7 +55,7 @@ typedef signed char CFI_type_t;
#define CFI_type_int16_t 8
#define CFI_type_int32_t 9
#define CFI_type_int64_t 10
#define CFI_type_int128_t 11 /* extension */
#define CFI_type_int128_t 11 /* extension kind=16 */
#define CFI_type_int_least8_t 12
#define CFI_type_int_least16_t 13
#define CFI_type_int_least32_t 14
@@ -88,8 +87,8 @@ typedef signed char CFI_type_t;
#define CFI_type_char 40
#define CFI_type_cptr 41
#define CFI_type_struct 42
#define CFI_type_char16_t 43 /* extension */
#define CFI_type_char32_t 44 /* extension */
#define CFI_type_char16_t 43 /* extension kind=2 */
#define CFI_type_char32_t 44 /* extension kind=4 */
#define CFI_TYPE_LAST CFI_type_char32_t
#define CFI_type_other (-1) // must be negative

2
flang/include/flang/Optimizer/Dialect/FIRType.h
View File

@@ -359,6 +359,8 @@ bool hasAbstractResult(mlir::FunctionType ty);
mlir::Type fromRealTypeID(mlir::MLIRContext *context, llvm::Type::TypeID typeID,
fir::KindTy kind);
int getTypeCode(mlir::Type ty, KindMapping &kindMap);
inline bool BaseBoxType::classof(mlir::Type type) {
return type.isa<fir::BoxType, fir::ClassType>();
}

131
flang/lib/Optimizer/CodeGen/CodeGen.cpp
View File

@@ -1272,119 +1272,42 @@ struct EmboxCommonConversion : public FIROpConversion<OP> {
mlir::Location loc, mlir::ConversionPatternRewriter &rewriter,
mlir::Type boxEleTy, mlir::ValueRange lenParams = {}) const {
auto i64Ty = mlir::IntegerType::get(rewriter.getContext(), 64);
auto getKindMap = [&]() -> fir::KindMapping & {
return this->lowerTy().getKindMap();
};
auto doInteger =
[&](mlir::Type type,
unsigned width) -> std::tuple<mlir::Value, mlir::Value> {
int typeCode = fir::integerBitsToTypeCode(width);
return {
genTypeStrideInBytes(loc, i64Ty, rewriter, this->convertType(type)),
this->genConstantOffset(loc, rewriter, typeCode)};
};
auto doLogical =
[&](mlir::Type type,
unsigned width) -> std::tuple<mlir::Value, mlir::Value> {
int typeCode = fir::logicalBitsToTypeCode(width);
return {
genTypeStrideInBytes(loc, i64Ty, rewriter, this->convertType(type)),
this->genConstantOffset(loc, rewriter, typeCode)};
};
auto doFloat = [&](mlir::Type type,
unsigned width) -> std::tuple<mlir::Value, mlir::Value> {
int typeCode = fir::realBitsToTypeCode(width);
return {
genTypeStrideInBytes(loc, i64Ty, rewriter, this->convertType(type)),
this->genConstantOffset(loc, rewriter, typeCode)};
};
auto doComplex =
[&](mlir::Type type,
unsigned width) -> std::tuple<mlir::Value, mlir::Value> {
auto typeCode = fir::complexBitsToTypeCode(width);
return {
genTypeStrideInBytes(loc, i64Ty, rewriter, this->convertType(type)),
this->genConstantOffset(loc, rewriter, typeCode)};
};
auto doCharacter = [&](fir::CharacterType type, mlir::ValueRange lenParams)
-> std::tuple<mlir::Value, mlir::Value> {
unsigned bitWidth = getKindMap().getCharacterBitsize(type.getFKind());
auto typeCode = fir::characterBitsToTypeCode(bitWidth);
auto typeCodeVal = this->genConstantOffset(loc, rewriter, typeCode);
bool lengthIsConst = (type.getLen() != fir::CharacterType::unknownLen());
mlir::Value eleSize =
genTypeStrideInBytes(loc, i64Ty, rewriter, this->convertType(type));
if (!lengthIsConst) {
// If length is constant, then the fir::CharacterType will be
// represented as an array of known size of elements having
// the corresponding LLVM type. In this case eleSize already
// holds correct memory size. If length is not constant, then
// the fir::CharacterType will decay to a scalar type,
// so we have to multiply it by the non-constant length
// to get its size in memory.
if (auto eleTy = fir::dyn_cast_ptrEleTy(boxEleTy))
boxEleTy = eleTy;
if (auto seqTy = boxEleTy.dyn_cast<fir::SequenceType>())
return getSizeAndTypeCode(loc, rewriter, seqTy.getEleTy(), lenParams);
if (boxEleTy.isa<mlir::NoneType>()) // unlimited polymorphic or assumed type
return {rewriter.create<mlir::LLVM::ConstantOp>(loc, i64Ty, 0),
this->genConstantOffset(loc, rewriter, CFI_type_other)};
mlir::Value typeCodeVal = this->genConstantOffset(
loc, rewriter,
fir::getTypeCode(boxEleTy, this->lowerTy().getKindMap()));
if (fir::isa_integer(boxEleTy) || boxEleTy.dyn_cast<fir::LogicalType>() ||
fir::isa_real(boxEleTy) || fir::isa_complex(boxEleTy))
return {genTypeStrideInBytes(loc, i64Ty, rewriter,
this->convertType(boxEleTy)),
typeCodeVal};
if (auto charTy = boxEleTy.dyn_cast<fir::CharacterType>()) {
mlir::Value size =
genTypeStrideInBytes(loc, i64Ty, rewriter, this->convertType(charTy));
if (charTy.getLen() == fir::CharacterType::unknownLen()) {
// Multiply the single character size by the length.
assert(!lenParams.empty());
auto len64 = FIROpConversion<OP>::integerCast(loc, rewriter, i64Ty,
lenParams.back());
eleSize =
rewriter.create<mlir::LLVM::MulOp>(loc, i64Ty, eleSize, len64);
size = rewriter.create<mlir::LLVM::MulOp>(loc, i64Ty, size, len64);
}
return {eleSize, typeCodeVal};
return {size, typeCodeVal};
};
// Pointer-like types.
if (auto eleTy = fir::dyn_cast_ptrEleTy(boxEleTy))
boxEleTy = eleTy;
// Integer types.
if (fir::isa_integer(boxEleTy)) {
if (auto ty = boxEleTy.dyn_cast<mlir::IntegerType>())
return doInteger(ty, ty.getWidth());
auto ty = boxEleTy.cast<fir::IntegerType>();
return doInteger(ty, getKindMap().getIntegerBitsize(ty.getFKind()));
}
// Floating point types.
if (fir::isa_real(boxEleTy)) {
if (auto ty = boxEleTy.dyn_cast<mlir::FloatType>())
return doFloat(ty, ty.getWidth());
auto ty = boxEleTy.cast<fir::RealType>();
return doFloat(ty, getKindMap().getRealBitsize(ty.getFKind()));
}
// Complex types.
if (fir::isa_complex(boxEleTy)) {
if (auto ty = boxEleTy.dyn_cast<mlir::ComplexType>())
return doComplex(
ty, ty.getElementType().cast<mlir::FloatType>().getWidth());
auto ty = boxEleTy.cast<fir::ComplexType>();
return doComplex(ty, getKindMap().getRealBitsize(ty.getFKind()));
}
// Character types.
if (auto ty = boxEleTy.dyn_cast<fir::CharacterType>())
return doCharacter(ty, lenParams);
// Logical type.
if (auto ty = boxEleTy.dyn_cast<fir::LogicalType>())
return doLogical(ty, getKindMap().getLogicalBitsize(ty.getFKind()));
// Array types.
if (auto seqTy = boxEleTy.dyn_cast<fir::SequenceType>())
return getSizeAndTypeCode(loc, rewriter, seqTy.getEleTy(), lenParams);
// Derived-type types.
if (boxEleTy.isa<fir::RecordType>()) {
auto eleSize = genTypeStrideInBytes(loc, i64Ty, rewriter,
this->convertType(boxEleTy));
return {eleSize,
this->genConstantOffset(loc, rewriter, fir::derivedToTypeCode())};
}
// Reference type.
if (fir::isa_ref_type(boxEleTy)) {
auto ptrTy = mlir::LLVM::LLVMPointerType::get(
mlir::LLVM::LLVMVoidType::get(rewriter.getContext()));
mlir::Value size = genTypeStrideInBytes(loc, i64Ty, rewriter, ptrTy);
return {size, this->genConstantOffset(loc, rewriter, CFI_type_cptr)};
return {genTypeStrideInBytes(loc, i64Ty, rewriter, ptrTy), typeCodeVal};
}
// Unlimited polymorphic or assumed type. Use 0 and CFI_type_other since the
// information is not none at this point.
if (boxEleTy.isa<mlir::NoneType>())
return {rewriter.create<mlir::LLVM::ConstantOp>(loc, i64Ty, 0),
this->genConstantOffset(loc, rewriter, CFI_type_other)};
if (boxEleTy.isa<fir::RecordType>())
return {genTypeStrideInBytes(loc, i64Ty, rewriter,
this->convertType(boxEleTy)),
typeCodeVal};
fir::emitFatalError(loc, "unhandled type in fir.box code generation");
}

92
flang/lib/Optimizer/Dialect/FIRType.cpp
View File

@@ -11,6 +11,7 @@
//===----------------------------------------------------------------------===//
#include "flang/Optimizer/Dialect/FIRType.h"
#include "flang/ISO_Fortran_binding.h"
#include "flang/Optimizer/Dialect/FIRDialect.h"
#include "flang/Optimizer/Dialect/Support/KindMapping.h"
#include "flang/Tools/PointerModels.h"
@@ -381,6 +382,97 @@ mlir::Type unwrapSeqOrBoxedSeqType(mlir::Type ty) {
return ty;
}
/// Return the ISO_C_BINDING intrinsic module value of type \p ty.
int getTypeCode(mlir::Type ty, fir::KindMapping &kindMap) {
unsigned width = 0;
if (mlir::IntegerType intTy = ty.dyn_cast<mlir::IntegerType>()) {
switch (intTy.getWidth()) {
case 8:
return CFI_type_int8_t;
case 16:
return CFI_type_int16_t;
case 32:
return CFI_type_int32_t;
case 64:
return CFI_type_int64_t;
case 128:
return CFI_type_int128_t;
}
llvm_unreachable("unsupported integer type");
}
if (fir::LogicalType logicalTy = ty.dyn_cast<fir::LogicalType>()) {
switch (kindMap.getLogicalBitsize(logicalTy.getFKind())) {
case 8:
return CFI_type_Bool;
case 16:
return CFI_type_int_least16_t;
case 32:
return CFI_type_int_least32_t;
case 64:
return CFI_type_int_least64_t;
}
llvm_unreachable("unsupported logical type");
}
if (mlir::FloatType floatTy = ty.dyn_cast<mlir::FloatType>()) {
switch (floatTy.getWidth()) {
case 16:
return floatTy.isBF16() ? CFI_type_bfloat : CFI_type_half_float;
case 32:
return CFI_type_float;
case 64:
return CFI_type_double;
case 80:
return CFI_type_extended_double;
case 128:
return CFI_type_float128;
}
llvm_unreachable("unsupported real type");
}
if (fir::isa_complex(ty)) {
if (mlir::ComplexType complexTy = ty.dyn_cast<mlir::ComplexType>()) {
mlir::FloatType floatTy =
complexTy.getElementType().cast<mlir::FloatType>();
if (floatTy.isBF16())
return CFI_type_bfloat_Complex;
width = floatTy.getWidth();
} else if (fir::ComplexType complexTy = ty.dyn_cast<fir::ComplexType>()) {
auto FKind = complexTy.getFKind();
if (FKind == 3)
return CFI_type_bfloat_Complex;
width = kindMap.getRealBitsize(FKind);
}
switch (width) {
case 16:
return CFI_type_half_float_Complex;
case 32:
return CFI_type_float_Complex;
case 64:
return CFI_type_double_Complex;
case 80:
return CFI_type_extended_double_Complex;
case 128:
return CFI_type_float128_Complex;
}
llvm_unreachable("unsupported complex size");
}
if (fir::CharacterType charTy = ty.dyn_cast<fir::CharacterType>()) {
switch (kindMap.getCharacterBitsize(charTy.getFKind())) {
case 8:
return CFI_type_char;
case 16:
return CFI_type_char16_t;
case 32:
return CFI_type_char32_t;
}
llvm_unreachable("unsupported character type");
}
if (fir::isa_ref_type(ty))
return CFI_type_cptr;
if (ty.isa<fir::RecordType>())
return CFI_type_struct;
llvm_unreachable("unsupported type");
}
} // namespace fir
namespace {

26
flang/lib/Optimizer/Transforms/PolymorphicOpConversion.cpp
View File

@@ -62,8 +62,6 @@ private:
mlir::Type ty, mlir::ModuleOp mod,
mlir::PatternRewriter &rewriter) const;
static int getTypeCode(mlir::Type ty, fir::KindMapping &kindMap);
mlir::LogicalResult genTypeLadderStep(mlir::Location loc,
mlir::Value selector,
mlir::Attribute attr, mlir::Block *dest,
@@ -362,7 +360,7 @@ mlir::LogicalResult SelectTypeConv::genTypeLadderStep(
a.getType().isa<fir::CharacterType>()) {
// For type guard statement with Intrinsic type spec the type code of
// the descriptor is compared.
int code = getTypeCode(a.getType(), kindMap);
int code = fir::getTypeCode(a.getType(), kindMap);
if (code == 0)
return mlir::emitError(loc)
<< "type code unavailable for " << a.getType();
@@ -461,28 +459,6 @@ SelectTypeConv::genTypeDescCompare(mlir::Location loc, mlir::Value selector,
loc, mlir::arith::CmpIPredicate::eq, typeDescInt, selectorTdescInt);
}
int SelectTypeConv::getTypeCode(mlir::Type ty, fir::KindMapping &kindMap) {
if (auto intTy = ty.dyn_cast<mlir::IntegerType>())
return fir::integerBitsToTypeCode(intTy.getWidth());
if (auto floatTy = ty.dyn_cast<mlir::FloatType>())
return fir::realBitsToTypeCode(floatTy.getWidth());
if (auto logicalTy = ty.dyn_cast<fir::LogicalType>())
return fir::logicalBitsToTypeCode(
kindMap.getLogicalBitsize(logicalTy.getFKind()));
if (fir::isa_complex(ty)) {
if (auto cmplxTy = ty.dyn_cast<mlir::ComplexType>())
return fir::complexBitsToTypeCode(
cmplxTy.getElementType().cast<mlir::FloatType>().getWidth());
auto cmplxTy = ty.cast<fir::ComplexType>();
return fir::complexBitsToTypeCode(
kindMap.getRealBitsize(cmplxTy.getFKind()));
}
if (auto charTy = ty.dyn_cast<fir::CharacterType>())
return fir::characterBitsToTypeCode(
kindMap.getCharacterBitsize(charTy.getFKind()));
return 0;
}
llvm::SmallSet<llvm::StringRef, 4>
SelectTypeConv::collectAncestors(fir::DispatchTableOp dt,
mlir::ModuleOp mod) const {

10
flang/test/Fir/convert-to-llvm.fir
View File

@@ -1563,10 +1563,10 @@ func.func @embox0(%arg0: !fir.ref<!fir.array<100xi32>>) {
// CHECK-SAME: %[[ARG0:.*]]: !llvm.ptr<array<100 x i32>>
// CHECK: %[[C1:.*]] = llvm.mlir.constant(1 : i32) : i32
// CHECK: %[[ALLOCA:.*]] = llvm.alloca %[[C1]] x !llvm.struct<(ptr<array<100 x i32>>, i{{.*}}, i{{.*}}, i{{.*}}, i{{.*}}, i{{.*}}, i{{.*}})> {alignment = 8 : i64} : (i32) -> !llvm.ptr<struct<(ptr<array<100 x i32>>, i{{.*}}, i{{.*}}, i{{.*}}, i{{.*}}, i{{.*}}, i{{.*}})>>
// CHECK: %[[TYPE_CODE:.*]] = llvm.mlir.constant(9 : i32) : i32
// CHECK: %[[NULL:.*]] = llvm.mlir.null : !llvm.ptr<i32>
// CHECK: %[[GEP:.*]] = llvm.getelementptr %[[NULL]][1]
// CHECK: %[[I64_ELEM_SIZE:.*]] = llvm.ptrtoint %[[GEP]] : !llvm.ptr<i32> to i64
// CHECK: %[[TYPE_CODE:.*]] = llvm.mlir.constant(9 : i32) : i32
// CHECK: %[[DESC:.*]] = llvm.mlir.undef : !llvm.struct<(ptr<array<100 x i32>>, i{{.*}}, i{{.*}}, i{{.*}}, i{{.*}}, i{{.*}}, i{{.*}})>
// CHECK: %[[DESC0:.*]] = llvm.insertvalue %[[I64_ELEM_SIZE]], %[[DESC]][1] : !llvm.struct<(ptr<array<100 x i32>>, i{{.*}}, i{{.*}}, i{{.*}}, i{{.*}}, i{{.*}}, i{{.*}})>
// CHECK: %[[CFI_VERSION:.*]] = llvm.mlir.constant(20180515 : i32) : i32
@@ -1786,10 +1786,10 @@ func.func @xembox0(%arg0: !fir.ref<!fir.array<?xi32>>) {
// CHECK: %[[ALLOCA_SIZE:.*]] = llvm.mlir.constant(1 : i32) : i32
// CHECK: %[[ALLOCA:.*]] = llvm.alloca %[[ALLOCA_SIZE]] x !llvm.struct<(ptr<i32>, i{{.*}}, i{{.*}}, i{{.*}}, i{{.*}}, i{{.*}}, i{{.*}}, array<1 x array<3 x i64>>)> {alignment = 8 : i64} : (i32) -> !llvm.ptr<struct<(ptr<i32>, i{{.*}}, i{{.*}}, i{{.*}}, i{{.*}}, i{{.*}}, i{{.*}}, array<1 x array<3 x i64>>)>>
// CHECK: %[[C0:.*]] = llvm.mlir.constant(0 : i64) : i64
// CHECK: %[[TYPE:.*]] = llvm.mlir.constant(9 : i32) : i32
// CHECK: %[[NULL:.*]] = llvm.mlir.null : !llvm.ptr<i32>
// CHECK: %[[GEP:.*]] = llvm.getelementptr %[[NULL]][1]
// CHECK: %[[ELEM_LEN_I64:.*]] = llvm.ptrtoint %[[GEP]] : !llvm.ptr<i32> to i64
// CHECK: %[[TYPE:.*]] = llvm.mlir.constant(9 : i32) : i32
// CHECK: %[[BOX0:.*]] = llvm.mlir.undef : !llvm.struct<(ptr<i32>, i{{.*}}, i{{.*}}, i{{.*}}, i{{.*}}, i{{.*}}, i{{.*}}, array<1 x array<3 x i64>>)>
// CHECK: %[[BOX1:.*]] = llvm.insertvalue %[[ELEM_LEN_I64]], %[[BOX0]][1] : !llvm.struct<(ptr<i32>, i{{.*}}, i{{.*}}, i{{.*}}, i{{.*}}, i{{.*}}, i{{.*}}, array<1 x array<3 x i64>>)>
// CHECK: %[[VERSION:.*]] = llvm.mlir.constant(20180515 : i32) : i32
@@ -1885,10 +1885,10 @@ func.func private @_QPxb(!fir.box<!fir.array<?x?xf64>>)
// CHECK: %[[ARR_SIZE_TMP1:.*]] = llvm.mul %[[C1_0]], %[[N1]] : i64
// CHECK: %[[ARR_SIZE:.*]] = llvm.mul %[[ARR_SIZE_TMP1]], %[[N2]] : i64
// CHECK: %[[ARR:.*]] = llvm.alloca %[[ARR_SIZE]] x f64 {bindc_name = "arr", in_type = !fir.array<?x?xf64>, operand_segment_sizes = array<i32: 0, 2>, uniq_name = "_QFsbEarr"} : (i64) -> !llvm.ptr<f64>
// CHECK: %[[TYPE_CODE:.*]] = llvm.mlir.constant(28 : i32) : i32
// CHECK: %[[NULL:.*]] = llvm.mlir.null : !llvm.ptr<f64>
// CHECK: %[[GEP:.*]] = llvm.getelementptr %[[NULL]][1]
// CHECK: %[[ELEM_LEN_I64:.*]] = llvm.ptrtoint %[[GEP]] : !llvm.ptr<f64> to i64
// CHECK: %[[TYPE_CODE:.*]] = llvm.mlir.constant(28 : i32) : i32
// CHECK: %[[BOX0:.*]] = llvm.mlir.undef : !llvm.struct<(ptr<f64>, i{{.*}}, i{{.*}}, i{{.*}}, i{{.*}}, i{{.*}}, i{{.*}}, array<2 x array<3 x i64>>)>
// CHECK: %[[BOX1:.*]] = llvm.insertvalue %[[ELEM_LEN_I64]], %[[BOX0]][1] : !llvm.struct<(ptr<f64>, i{{.*}}, i{{.*}}, i{{.*}}, i{{.*}}, i{{.*}}, i{{.*}}, array<2 x array<3 x i64>>)>
// CHECK: %[[VERSION:.*]] = llvm.mlir.constant(20180515 : i32) : i32
@@ -1964,10 +1964,10 @@ func.func private @_QPtest_dt_callee(%arg0: !fir.box<!fir.array<?xi32>>)
// CHECK: %[[V:.*]] = llvm.alloca %[[ALLOCA_SIZE_V]] x i32 {bindc_name = "v", in_type = i32, operand_segment_sizes = array<i32: 0, 0>, uniq_name = "_QFtest_dt_sliceEv"} : (i64) -> !llvm.ptr<i32>
// CHECK: %[[ALLOCA_SIZE_X:.*]] = llvm.mlir.constant(1 : i64) : i64
// CHECK: %[[X:.*]] = llvm.alloca %[[ALLOCA_SIZE_X]] x !llvm.array<20 x struct<"_QFtest_dt_sliceTt", (i32, i32)>> {bindc_name = "x", in_type = !fir.array<20x!fir.type<_QFtest_dt_sliceTt{i:i32,j:i32}>>, operand_segment_sizes = array<i32: 0, 0>, uniq_name = "_QFtest_dt_sliceEx"} : (i64) -> !llvm.ptr<array<20 x struct<"_QFtest_dt_sliceTt", (i32, i32)>>>
// CHECK: %[[TYPE_CODE:.*]] = llvm.mlir.constant(9 : i32) : i32
// CHECK: %[[NULL:.*]] = llvm.mlir.null : !llvm.ptr<i32>
// CHECK: %[[GEP:.*]] = llvm.getelementptr %[[NULL]][1]
// CHECK: %[[ELEM_LEN_I64:.*]] = llvm.ptrtoint %[[GEP]] : !llvm.ptr<i32> to i64
// CHECK: %[[TYPE_CODE:.*]] = llvm.mlir.constant(9 : i32) : i32
// CHECK: %[[BOX0:.*]] = llvm.mlir.undef : !llvm.struct<(ptr<i32>, i{{.*}}, i{{.*}}, i{{.*}}, i{{.*}}, i{{.*}}, i{{.*}}, array<1 x array<3 x i64>>)>
// CHECK: %[[BOX1:.*]] = llvm.insertvalue %[[ELEM_LEN_I64]], %[[BOX0]][1] : !llvm.struct<(ptr<i32>, i{{.*}}, i{{.*}}, i{{.*}}, i{{.*}}, i{{.*}}, i{{.*}}, array<1 x array<3 x i64>>)>
// CHECK: %[[VERSION:.*]] = llvm.mlir.constant(20180515 : i32) : i32
@@ -2240,10 +2240,10 @@ func.func @test_rebox_1(%arg0: !fir.box<!fir.array<?x?xf32>>) {
//CHECK: %[[FIVE:.*]] = llvm.mlir.constant(5 : index) : i64
//CHECK: %[[SIX:.*]] = llvm.mlir.constant(6 : index) : i64
//CHECK: %[[EIGHTY:.*]] = llvm.mlir.constant(80 : index) : i64
//CHECK: %[[FLOAT_TYPE:.*]] = llvm.mlir.constant(27 : i32) : i32
//CHECK: %[[NULL:.*]] = llvm.mlir.null : !llvm.ptr<f32>
//CHECK: %[[GEP:.*]] = llvm.getelementptr %[[NULL]][1]
//CHECK: %[[ELEM_SIZE_I64:.*]] = llvm.ptrtoint %[[GEP]] : !llvm.ptr<f32> to i64
//CHECK: %[[FLOAT_TYPE:.*]] = llvm.mlir.constant(27 : i32) : i32
//CHECK: %[[RBOX:.*]] = llvm.mlir.undef : !llvm.struct<(ptr<f32>, i64, i32, i8, i8, i8, i8, array<1 x array<3 x i64>>)>
//CHECK: %[[RBOX_TMP1:.*]] = llvm.insertvalue %[[ELEM_SIZE_I64]], %[[RBOX]][1] : !llvm.struct<(ptr<f32>, i64, i32, i8, i8, i8, i8, array<1 x array<3 x i64>>)>
//CHECK: %[[CFI_VERSION:.*]] = llvm.mlir.constant(20180515 : i32) : i32

98
flang/test/Lower/real-descriptors.f90 Normal file
View File

@@ -0,0 +1,98 @@
! RUN: bbc %s -o - | tco | FileCheck %s
! CHECK-LABEL: define void @_QQmain()
program p
! CHECK-DAG: alloca { ptr, i64, i32, i8, i8, i8, i8 }, align 8
! CHECK-DAG: alloca { ptr, i64, i32, i8, i8, i8, i8 }, align 8
! CHECK-DAG: alloca { ptr, i64, i32, i8, i8, i8, i8 }, align 8
! CHECK-DAG: alloca { ptr, i64, i32, i8, i8, i8, i8 }, align 8
! CHECK-DAG: alloca { ptr, i64, i32, i8, i8, i8, i8 }, align 8
! CHECK-DAG: alloca { ptr, i64, i32, i8, i8, i8, i8 }, align 8
! CHECK-DAG: alloca { ptr, i64, i32, i8, i8, i8, i8 }, align 8
! CHECK-DAG: alloca { ptr, i64, i32, i8, i8, i8, i8 }, align 8
! CHECK-DAG: alloca { x86_fp80, x86_fp80 }, i64 1, align 16
! CHECK-DAG: alloca { fp128, fp128 }, i64 1, align 16
! CHECK-DAG: alloca { half, half }, i64 1, align 8
! CHECK-DAG: alloca { bfloat, bfloat }, i64 1, align 8
! CHECK-DAG: alloca { float, float }, i64 1, align 8
! CHECK-DAG: alloca { double, double }, i64 1, align 8
! CHECK-DAG: alloca x86_fp80, i64 1, align 16
! CHECK-DAG: alloca fp128, i64 1, align 16
! CHECK-DAG: alloca half, i64 1, align 2
! CHECK-DAG: alloca bfloat, i64 1, align 2
! CHECK-DAG: alloca float, i64 1, align 4
! CHECK-DAG: alloca double, i64 1, align 8
character(10) :: in = 'NaN NaN'
real(kind=2) :: x2
real(kind=3) :: x3
real(kind=4) :: x4
real(kind=8) :: x8
real(kind=10) :: x10
real(kind=16) :: x16
complex(kind=2) :: c2
complex(kind=3) :: c3
complex(kind=4) :: c4
complex(kind=8) :: c8
complex(kind=10) :: c10
complex(kind=16) :: c16
read(in,*) x2
! CHECK: insertvalue { ptr, i64, i32, i8, i8, i8, i8 } { ptr undef, i64 ptrtoint (ptr getelementptr (half, ptr null, i32 1) to i64), i32 {{[0-9]*}}, i8 0, i8 25, i8 0, i8 0 }, ptr %{{[0-9]*}}, 0
! CHECK: call i1 @_FortranAioOutputDescriptor(ptr %{{[0-9]*}}, ptr %{{[0-9]*}})
print "(z4)", x2
read(in,*) x3
! CHECK: insertvalue { ptr, i64, i32, i8, i8, i8, i8 } { ptr undef, i64 ptrtoint (ptr getelementptr (bfloat, ptr null, i32 1) to i64), i32 {{[0-9]*}}, i8 0, i8 26, i8 0, i8 0 }, ptr %{{[0-9]*}}, 0
! CHECK: call i1 @_FortranAioOutputDescriptor(ptr %{{[0-9]*}}, ptr %{{[0-9]*}})
print "(z4)", x3
read(in,*) x4
! CHECK: call i1 @_FortranAioOutputReal32(ptr %{{[0-9]*}}, float %{{[0-9]*}})
print "(z8)", x4
read(in,*) x8
! CHECK: call i1 @_FortranAioOutputReal64(ptr %{{[0-9]*}}, double %{{[0-9]*}})
print "(z16)", x8
read(in,*) x10
! CHECK: insertvalue { ptr, i64, i32, i8, i8, i8, i8 } { ptr undef, i64 ptrtoint (ptr getelementptr (x86_fp80, ptr null, i32 1) to i64), i32 {{[0-9]*}}, i8 0, i8 29, i8 0, i8 0 }, ptr %{{[0-9]*}}, 0
! CHECK: call i1 @_FortranAioOutputDescriptor(ptr %{{[0-9]*}}, ptr %{{[0-9]*}})
print "(z20)", x10
read(in,*) x16
! CHECK: insertvalue { ptr, i64, i32, i8, i8, i8, i8 } { ptr undef, i64 ptrtoint (ptr getelementptr (fp128, ptr null, i32 1) to i64), i32 {{[0-9]*}}, i8 0, i8 31, i8 0, i8 0 }, ptr %{{[0-9]*}}, 0
! CHECK: call i1 @_FortranAioOutputDescriptor(ptr %{{[0-9]*}}, ptr %{{[0-9]*}})
print "(z32)", x16
print*
read(in,*) c2
! CHECK: insertvalue { ptr, i64, i32, i8, i8, i8, i8 } { ptr undef, i64 ptrtoint (ptr getelementptr ({ half, half }, ptr null, i32 1) to i64), i32 {{[0-9]*}}, i8 0, i8 32, i8 0, i8 0 }, ptr %{{[0-9]*}}, 0
! CHECK: call i1 @_FortranAioOutputDescriptor(ptr %{{[0-9]*}}, ptr %{{[0-9]*}})
print "(z4,' ',z4)", c2
read(in,*) c3
! CHECK: insertvalue { ptr, i64, i32, i8, i8, i8, i8 } { ptr undef, i64 ptrtoint (ptr getelementptr ({ bfloat, bfloat }, ptr null, i32 1) to i64), i32 {{[0-9]*}}, i8 0, i8 33, i8 0, i8 0 }, ptr %{{[0-9]*}}, 0
! CHECK: call i1 @_FortranAioOutputDescriptor(ptr %{{[0-9]*}}, ptr %{{[0-9]*}})
print "(z4,' ',z4)", c3
read(in,*) c4
! CHECK: call i1 @_FortranAioOutputComplex32(ptr %{{[0-9]*}}, float %{{[0-9]*}}, float %{{[0-9]*}})
print "(z8,' ',z8)", c4
read(in,*) c8
! CHECK: call i1 @_FortranAioOutputComplex64(ptr %{{[0-9]*}}, double %{{[0-9]*}}, double %{{[0-9]*}})
print "(z16,' ',z16)", c8
read(in,*) c10
! CHECK: insertvalue { ptr, i64, i32, i8, i8, i8, i8 } { ptr undef, i64 ptrtoint (ptr getelementptr ({ x86_fp80, x86_fp80 }, ptr null, i32 1) to i64), i32 {{[0-9]*}}, i8 0, i8 36, i8 0, i8 0 }, ptr %{{[0-9]*}}, 0
! CHECK: call i1 @_FortranAioOutputDescriptor(ptr %{{[0-9]*}}, ptr %{{[0-9]*}})
print "(z20,' ',z20)", c10
read(in,*) c16
! CHECK: insertvalue { ptr, i64, i32, i8, i8, i8, i8 } { ptr undef, i64 ptrtoint (ptr getelementptr ({ fp128, fp128 }, ptr null, i32 1) to i64), i32 {{[0-9]*}}, i8 0, i8 38, i8 0, i8 0 }, ptr %{{[0-9]*}}, 0
! CHECK: call i1 @_FortranAioOutputDescriptor(ptr %{{[0-9]*}}, ptr %{{[0-9]*}})
print "(z32,' ',z32)", c16
end