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llvm-mirror/lib/Support/AArch64TargetParser.cpp
Lucas Prates 60c2a88e72 [AArch64] Add support for the Branch Record Buffer extension
This introduces asm support for the Branch Record Buffer extension, through
the new 'brbe' subtarget feature. It consists of a new set of system registers
that enable the handling of branch records.

Patch written by Simon Tatham.

Reviewed By: ostannard

Differential Revision: https://reviews.llvm.org/D92389
2020-12-18 11:11:06 +00:00

272 lines
8.2 KiB
C++

//===-- AArch64TargetParser - Parser for AArch64 features -------*- 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 a target parser to recognise AArch64 hardware features
// such as FPU/CPU/ARCH and extension names.
//
//===----------------------------------------------------------------------===//
#include "llvm/Support/AArch64TargetParser.h"
#include "llvm/ADT/StringSwitch.h"
#include "llvm/ADT/Triple.h"
#include <cctype>
using namespace llvm;
static unsigned checkArchVersion(llvm::StringRef Arch) {
if (Arch.size() >= 2 && Arch[0] == 'v' && std::isdigit(Arch[1]))
return (Arch[1] - 48);
return 0;
}
unsigned AArch64::getDefaultFPU(StringRef CPU, AArch64::ArchKind AK) {
if (CPU == "generic")
return AArch64ARCHNames[static_cast<unsigned>(AK)].DefaultFPU;
return StringSwitch<unsigned>(CPU)
#define AARCH64_CPU_NAME(NAME, ID, DEFAULT_FPU, IS_DEFAULT, DEFAULT_EXT) \
.Case(NAME, ARM::DEFAULT_FPU)
#include "../../include/llvm/Support/AArch64TargetParser.def"
.Default(ARM::FK_INVALID);
}
uint64_t AArch64::getDefaultExtensions(StringRef CPU, AArch64::ArchKind AK) {
if (CPU == "generic")
return AArch64ARCHNames[static_cast<unsigned>(AK)].ArchBaseExtensions;
return StringSwitch<uint64_t>(CPU)
#define AARCH64_CPU_NAME(NAME, ID, DEFAULT_FPU, IS_DEFAULT, DEFAULT_EXT) \
.Case(NAME, AArch64ARCHNames[static_cast<unsigned>(ArchKind::ID)] \
.ArchBaseExtensions | \
DEFAULT_EXT)
#include "../../include/llvm/Support/AArch64TargetParser.def"
.Default(AArch64::AEK_INVALID);
}
AArch64::ArchKind AArch64::getCPUArchKind(StringRef CPU) {
if (CPU == "generic")
return ArchKind::ARMV8A;
return StringSwitch<AArch64::ArchKind>(CPU)
#define AARCH64_CPU_NAME(NAME, ID, DEFAULT_FPU, IS_DEFAULT, DEFAULT_EXT) \
.Case(NAME, ArchKind::ID)
#include "../../include/llvm/Support/AArch64TargetParser.def"
.Default(ArchKind::INVALID);
}
bool AArch64::getExtensionFeatures(uint64_t Extensions,
std::vector<StringRef> &Features) {
if (Extensions == AArch64::AEK_INVALID)
return false;
if (Extensions & AEK_FP)
Features.push_back("+fp-armv8");
if (Extensions & AEK_SIMD)
Features.push_back("+neon");
if (Extensions & AEK_CRC)
Features.push_back("+crc");
if (Extensions & AEK_CRYPTO)
Features.push_back("+crypto");
if (Extensions & AEK_DOTPROD)
Features.push_back("+dotprod");
if (Extensions & AEK_FP16FML)
Features.push_back("+fp16fml");
if (Extensions & AEK_FP16)
Features.push_back("+fullfp16");
if (Extensions & AEK_PROFILE)
Features.push_back("+spe");
if (Extensions & AEK_RAS)
Features.push_back("+ras");
if (Extensions & AEK_LSE)
Features.push_back("+lse");
if (Extensions & AEK_RDM)
Features.push_back("+rdm");
if (Extensions & AEK_SVE)
Features.push_back("+sve");
if (Extensions & AEK_SVE2)
Features.push_back("+sve2");
if (Extensions & AEK_SVE2AES)
Features.push_back("+sve2-aes");
if (Extensions & AEK_SVE2SM4)
Features.push_back("+sve2-sm4");
if (Extensions & AEK_SVE2SHA3)
Features.push_back("+sve2-sha3");
if (Extensions & AEK_SVE2BITPERM)
Features.push_back("+sve2-bitperm");
if (Extensions & AEK_RCPC)
Features.push_back("+rcpc");
if (Extensions & AEK_BRBE)
Features.push_back("+brbe");
return true;
}
bool AArch64::getArchFeatures(AArch64::ArchKind AK,
std::vector<StringRef> &Features) {
if (AK == ArchKind::ARMV8_1A)
Features.push_back("+v8.1a");
if (AK == ArchKind::ARMV8_2A)
Features.push_back("+v8.2a");
if (AK == ArchKind::ARMV8_3A)
Features.push_back("+v8.3a");
if (AK == ArchKind::ARMV8_4A)
Features.push_back("+v8.4a");
if (AK == ArchKind::ARMV8_5A)
Features.push_back("+v8.5a");
if (AK == AArch64::ArchKind::ARMV8_6A)
Features.push_back("+v8.6a");
if (AK == AArch64::ArchKind::ARMV8_7A)
Features.push_back("+v8.7a");
if(AK == AArch64::ArchKind::ARMV8R)
Features.push_back("+v8r");
return AK != ArchKind::INVALID;
}
StringRef AArch64::getArchName(AArch64::ArchKind AK) {
return AArch64ARCHNames[static_cast<unsigned>(AK)].getName();
}
StringRef AArch64::getCPUAttr(AArch64::ArchKind AK) {
return AArch64ARCHNames[static_cast<unsigned>(AK)].getCPUAttr();
}
StringRef AArch64::getSubArch(AArch64::ArchKind AK) {
return AArch64ARCHNames[static_cast<unsigned>(AK)].getSubArch();
}
unsigned AArch64::getArchAttr(AArch64::ArchKind AK) {
return AArch64ARCHNames[static_cast<unsigned>(AK)].ArchAttr;
}
StringRef AArch64::getArchExtName(unsigned ArchExtKind) {
for (const auto &AE : AArch64ARCHExtNames)
if (ArchExtKind == AE.ID)
return AE.getName();
return StringRef();
}
StringRef AArch64::getArchExtFeature(StringRef ArchExt) {
if (ArchExt.startswith("no")) {
StringRef ArchExtBase(ArchExt.substr(2));
for (const auto &AE : AArch64ARCHExtNames) {
if (AE.NegFeature && ArchExtBase == AE.getName())
return StringRef(AE.NegFeature);
}
}
for (const auto &AE : AArch64ARCHExtNames)
if (AE.Feature && ArchExt == AE.getName())
return StringRef(AE.Feature);
return StringRef();
}
StringRef AArch64::getDefaultCPU(StringRef Arch) {
ArchKind AK = parseArch(Arch);
if (AK == ArchKind::INVALID)
return StringRef();
// Look for multiple AKs to find the default for pair AK+Name.
for (const auto &CPU : AArch64CPUNames)
if (CPU.ArchID == AK && CPU.Default)
return CPU.getName();
// If we can't find a default then target the architecture instead
return "generic";
}
void AArch64::fillValidCPUArchList(SmallVectorImpl<StringRef> &Values) {
for (const auto &Arch : AArch64CPUNames) {
if (Arch.ArchID != ArchKind::INVALID)
Values.push_back(Arch.getName());
}
}
bool AArch64::isX18ReservedByDefault(const Triple &TT) {
return TT.isAndroid() || TT.isOSDarwin() || TT.isOSFuchsia() ||
TT.isOSWindows();
}
// Allows partial match, ex. "v8a" matches "armv8a".
AArch64::ArchKind AArch64::parseArch(StringRef Arch) {
Arch = ARM::getCanonicalArchName(Arch);
if (checkArchVersion(Arch) < 8)
return ArchKind::INVALID;
StringRef Syn = ARM::getArchSynonym(Arch);
for (const auto &A : AArch64ARCHNames) {
if (A.getName().endswith(Syn))
return A.ID;
}
return ArchKind::INVALID;
}
AArch64::ArchExtKind AArch64::parseArchExt(StringRef ArchExt) {
for (const auto &A : AArch64ARCHExtNames) {
if (ArchExt == A.getName())
return static_cast<ArchExtKind>(A.ID);
}
return AArch64::AEK_INVALID;
}
AArch64::ArchKind AArch64::parseCPUArch(StringRef CPU) {
for (const auto &C : AArch64CPUNames) {
if (CPU == C.getName())
return C.ArchID;
}
return ArchKind::INVALID;
}
// Parse a branch protection specification, which has the form
// standard | none | [bti,pac-ret[+b-key,+leaf]*]
// Returns true on success, with individual elements of the specification
// returned in `PBP`. Returns false in error, with `Err` containing
// an erroneous part of the spec.
bool AArch64::parseBranchProtection(StringRef Spec, ParsedBranchProtection &PBP,
StringRef &Err) {
PBP = {"none", "a_key", false};
if (Spec == "none")
return true; // defaults are ok
if (Spec == "standard") {
PBP.Scope = "non-leaf";
PBP.BranchTargetEnforcement = true;
return true;
}
SmallVector<StringRef, 4> Opts;
Spec.split(Opts, "+");
for (int I = 0, E = Opts.size(); I != E; ++I) {
StringRef Opt = Opts[I].trim();
if (Opt == "bti") {
PBP.BranchTargetEnforcement = true;
continue;
}
if (Opt == "pac-ret") {
PBP.Scope = "non-leaf";
for (; I + 1 != E; ++I) {
StringRef PACOpt = Opts[I + 1].trim();
if (PACOpt == "leaf")
PBP.Scope = "all";
else if (PACOpt == "b-key")
PBP.Key = "b_key";
else
break;
}
continue;
}
if (Opt == "")
Err = "<empty>";
else
Err = Opt;
return false;
}
return true;
}