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clang-p2996/llvm/lib/Target/LoongArch/MCTargetDesc/LoongArchBaseInfo.cpp
Alex Rønne Petersen 72a218056d [llvm][Triple] Add Environment members and parsing for glibc/musl parity. (#107664) 
This adds support for:

* `muslabin32` (MIPS N32)
* `muslabi64` (MIPS N64)
* `muslf32` (LoongArch ILP32F/LP64F)
* `muslsf` (LoongArch ILP32S/LP64S)

As we start adding glibc/musl cross-compilation support for these
targets in Zig, it would make our life easier if LLVM recognized these
triples. I'm hoping this'll be uncontroversial since the same has
already been done for `musleabi`, `musleabihf`, and `muslx32`.

I intentionally left out a musl equivalent of `gnuf64` (LoongArch
ILP32D/LP64D); my understanding is that Loongson ultimately settled on
simply `gnu` for this much more common case, so there doesn't *seem* to
be a particularly compelling reason to add a `muslf64` that's basically
deprecated on arrival.

Note: I don't have commit access.
2024-09-20 08:53:03 +08:00

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//= LoongArchBaseInfo.cpp - Top level definitions for LoongArch MC -*- C++ -*-//
//
// 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
//
//===----------------------------------------------------------------------===//
//
// This file implements helper functions for the LoongArch target useful for the
// compiler back-end and the MC libraries.
//
//===----------------------------------------------------------------------===//
#include "LoongArchBaseInfo.h"
#include "LoongArchMCTargetDesc.h"
#include "llvm/ADT/ArrayRef.h"
#include "llvm/MC/MCSubtargetInfo.h"
#include "llvm/Support/ErrorHandling.h"
#include "llvm/Support/raw_ostream.h"
#include "llvm/TargetParser/Triple.h"
namespace llvm {
namespace LoongArchABI {
// Check if ABI has been standardized; issue a warning if it hasn't.
// FIXME: Once all ABIs are standardized, this will be removed.
static ABI checkABIStandardized(ABI Abi) {
StringRef ABIName;
switch (Abi) {
case ABI_ILP32S:
ABIName = "ilp32s";
break;
case ABI_ILP32F:
ABIName = "ilp32f";
break;
case ABI_ILP32D:
ABIName = "ilp32d";
break;
case ABI_LP64F:
ABIName = "lp64f";
break;
case ABI_LP64S:
case ABI_LP64D:
return Abi;
default:
llvm_unreachable("");
}
errs() << "warning: '" << ABIName << "' has not been standardized\n";
return Abi;
}
static ABI getTripleABI(const Triple &TT) {
bool Is64Bit = TT.isArch64Bit();
ABI TripleABI;
switch (TT.getEnvironment()) {
case llvm::Triple::EnvironmentType::GNUSF:
case llvm::Triple::EnvironmentType::MuslSF:
TripleABI = Is64Bit ? ABI_LP64S : ABI_ILP32S;
break;
case llvm::Triple::EnvironmentType::GNUF32:
case llvm::Triple::EnvironmentType::MuslF32:
TripleABI = Is64Bit ? ABI_LP64F : ABI_ILP32F;
break;
// Let the fallback case behave like {ILP32,LP64}D.
case llvm::Triple::EnvironmentType::GNUF64:
default:
TripleABI = Is64Bit ? ABI_LP64D : ABI_ILP32D;
break;
}
return TripleABI;
}
ABI computeTargetABI(const Triple &TT, const FeatureBitset &FeatureBits,
StringRef ABIName) {
bool Is64Bit = TT.isArch64Bit();
ABI ArgProvidedABI = getTargetABI(ABIName);
ABI TripleABI = getTripleABI(TT);
auto IsABIValidForFeature = [=](ABI Abi) {
switch (Abi) {
default:
return false;
case ABI_ILP32S:
return !Is64Bit;
case ABI_ILP32F:
return !Is64Bit && FeatureBits[LoongArch::FeatureBasicF];
case ABI_ILP32D:
return !Is64Bit && FeatureBits[LoongArch::FeatureBasicD];
case ABI_LP64S:
return Is64Bit;
case ABI_LP64F:
return Is64Bit && FeatureBits[LoongArch::FeatureBasicF];
case ABI_LP64D:
return Is64Bit && FeatureBits[LoongArch::FeatureBasicD];
}
};
// 1. If the '-target-abi' is valid, use it.
if (IsABIValidForFeature(ArgProvidedABI)) {
if (TT.hasEnvironment() && ArgProvidedABI != TripleABI)
errs()
<< "warning: triple-implied ABI conflicts with provided target-abi '"
<< ABIName << "', using target-abi\n";
return checkABIStandardized(ArgProvidedABI);
}
// 2. If the triple-implied ABI is valid, use it.
if (IsABIValidForFeature(TripleABI)) {
// If target-abi is not specified, use the valid triple-implied ABI.
if (ABIName.empty())
return checkABIStandardized(TripleABI);
switch (ArgProvidedABI) {
case ABI_Unknown:
// Fallback to the triple-implied ABI if ABI name is specified but
// invalid.
errs() << "warning: the '" << ABIName
<< "' is not a recognized ABI for this target, ignoring and "
"using triple-implied ABI\n";
return checkABIStandardized(TripleABI);
case ABI_ILP32S:
case ABI_ILP32F:
case ABI_ILP32D:
if (Is64Bit) {
errs() << "warning: 32-bit ABIs are not supported for 64-bit targets, "
"ignoring and using triple-implied ABI\n";
return checkABIStandardized(TripleABI);
}
break;
case ABI_LP64S:
case ABI_LP64F:
case ABI_LP64D:
if (!Is64Bit) {
errs() << "warning: 64-bit ABIs are not supported for 32-bit targets, "
"ignoring and using triple-implied ABI\n";
return checkABIStandardized(TripleABI);
}
break;
}
switch (ArgProvidedABI) {
case ABI_ILP32F:
case ABI_LP64F:
errs() << "warning: the '" << ABIName
<< "' ABI can't be used for a target that doesn't support the 'F' "
"instruction set, ignoring and using triple-implied ABI\n";
break;
case ABI_ILP32D:
case ABI_LP64D:
errs() << "warning: the '" << ABIName
<< "' ABI can't be used for a target that doesn't support the 'D' "
"instruction set, ignoring and using triple-implied ABI\n";
break;
default:
llvm_unreachable("");
}
return checkABIStandardized(TripleABI);
}
// 3. Parse the 'feature-abi', and use it.
auto GetFeatureABI = [=]() {
if (FeatureBits[LoongArch::FeatureBasicD])
return Is64Bit ? ABI_LP64D : ABI_ILP32D;
if (FeatureBits[LoongArch::FeatureBasicF])
return Is64Bit ? ABI_LP64F : ABI_ILP32F;
return Is64Bit ? ABI_LP64S : ABI_ILP32S;
};
if (ABIName.empty())
errs() << "warning: the triple-implied ABI is invalid, ignoring and using "
"feature-implied ABI\n";
else
errs() << "warning: both target-abi and the triple-implied ABI are "
"invalid, ignoring and using feature-implied ABI\n";
return checkABIStandardized(GetFeatureABI());
}
ABI getTargetABI(StringRef ABIName) {
auto TargetABI = StringSwitch<ABI>(ABIName)
.Case("ilp32s", ABI_ILP32S)
.Case("ilp32f", ABI_ILP32F)
.Case("ilp32d", ABI_ILP32D)
.Case("lp64s", ABI_LP64S)
.Case("lp64f", ABI_LP64F)
.Case("lp64d", ABI_LP64D)
.Default(ABI_Unknown);
return TargetABI;
}
// To avoid the BP value clobbered by a function call, we need to choose a
// callee saved register to save the value. The `last` `S` register (s9) is
// used for FP. So we choose the previous (s8) as BP.
MCRegister getBPReg() { return LoongArch::R31; }
} // end namespace LoongArchABI
} // end namespace llvm
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