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Open Menu /contrib/llvm-project/llvm/lib/Target/RISCV/Utils/RISCVBaseInfo.cpp 
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#include "RISCVBaseInfo.h"
#include "llvm/ADT/ArrayRef.h"
#include "llvm/ADT/Triple.h"
#include "llvm/Support/raw_ostream.h"

namespace llvm {
namespace RISCVSysReg {
#define GET_SysRegsList_IMPL
#include "RISCVGenSystemOperands.inc"
} // namespace RISCVSysReg

namespace RISCVABI {
ABI computeTargetABI(const Triple &TT, FeatureBitset FeatureBits,
                     StringRef ABIName) {
  auto TargetABI = getTargetABI(ABIName);
  bool IsRV64 = TT.isArch64Bit();
  bool IsRV32E = FeatureBits[RISCV::FeatureRV32E];

  if (!ABIName.empty() && TargetABI == ABI_Unknown) {
    errs()
        << "'" << ABIName
        << "' is not a recognized ABI for this target (ignoring target-abi)\n";
  } else if (ABIName.startswith("ilp32") && IsRV64) {
    errs() << "32-bit ABIs are not supported for 64-bit targets (ignoring "
              "target-abi)\n";
    TargetABI = ABI_Unknown;
  } else if (ABIName.startswith("lp64") && !IsRV64) {
    errs() << "64-bit ABIs are not supported for 32-bit targets (ignoring "
              "target-abi)\n";
    TargetABI = ABI_Unknown;
  } else if (IsRV32E && TargetABI != ABI_ILP32E && TargetABI != ABI_Unknown) {
    // TODO: move this checking to RISCVTargetLowering and RISCVAsmParser
    errs()
        << "Only the ilp32e ABI is supported for RV32E (ignoring target-abi)\n";
    TargetABI = ABI_Unknown;
  }

  if (TargetABI != ABI_Unknown)
    return TargetABI;

  // For now, default to the ilp32/ilp32e/lp64 ABI if no explicit ABI is given
  // or an invalid/unrecognised string is given. In the future, it might be
  // worth changing this to default to ilp32f/lp64f and ilp32d/lp64d when
  // hardware support for floating point is present.
  if (IsRV32E)
    return ABI_ILP32E;
  if (IsRV64)
    return ABI_LP64;
  return ABI_ILP32;
}

ABI getTargetABI(StringRef ABIName) {
  auto TargetABI = StringSwitch<ABI>(ABIName)
                       .Case("ilp32", ABI_ILP32)
                       .Case("ilp32f", ABI_ILP32F)
                       .Case("ilp32d", ABI_ILP32D)
                       .Case("ilp32e", ABI_ILP32E)
                       .Case("lp64", ABI_LP64)
                       .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. RV32E only has X8 and X9 as callee
// saved registers and X8 will be used as fp. So we choose X9 as bp.
Register getBPReg() { return RISCV::X9; }

} // namespace RISCVABI

namespace RISCVFeatures {

void validate(const Triple &TT, const FeatureBitset &FeatureBits) {
  if (TT.isArch64Bit() && FeatureBits[RISCV::FeatureRV32E])
    report_fatal_error("RV32E can't be enabled for an RV64 target");
}

} // namespace RISCVFeatures

} // namespace llvm