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llvm-mirror/lib/Support/TargetParser.cpp
Saleem Abdulrasool 6159f0c20b Support: catch invalid accesses
It is possible to invoke these methods on an invalid input resulting in an
invalid substring construction.  It seems that we do not have unit tests for
these methods.  Tests to ensure that the invalid call is caught to follow in
clang.

Resolves PR26839.

llvm-svn: 262778
2016-03-05 20:00:44 +00:00

610 lines
17 KiB
C++

//===-- TargetParser - Parser for target features ---------------*- C++ -*-===//
//
// The LLVM Compiler Infrastructure
//
// This file is distributed under the University of Illinois Open Source
// License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//
//
// This file implements a target parser to recognise hardware features such as
// FPU/CPU/ARCH names as well as specific support such as HDIV, etc.
//
//===----------------------------------------------------------------------===//
#include "llvm/Support/ARMBuildAttributes.h"
#include "llvm/Support/TargetParser.h"
#include "llvm/ADT/StringExtras.h"
#include "llvm/ADT/StringSwitch.h"
#include "llvm/ADT/Twine.h"
#include <cctype>
using namespace llvm;
using namespace ARM;
namespace {
// List of canonical FPU names (use getFPUSynonym) and which architectural
// features they correspond to (use getFPUFeatures).
// FIXME: TableGen this.
// The entries must appear in the order listed in ARM::FPUKind for correct indexing
static const struct {
const char *NameCStr;
size_t NameLength;
ARM::FPUKind ID;
ARM::FPUVersion FPUVersion;
ARM::NeonSupportLevel NeonSupport;
ARM::FPURestriction Restriction;
StringRef getName() const { return StringRef(NameCStr, NameLength); }
} FPUNames[] = {
#define ARM_FPU(NAME, KIND, VERSION, NEON_SUPPORT, RESTRICTION) \
{ NAME, sizeof(NAME) - 1, KIND, VERSION, NEON_SUPPORT, RESTRICTION },
#include "llvm/Support/ARMTargetParser.def"
};
// List of canonical arch names (use getArchSynonym).
// This table also provides the build attribute fields for CPU arch
// and Arch ID, according to the Addenda to the ARM ABI, chapters
// 2.4 and 2.3.5.2 respectively.
// FIXME: SubArch values were simplified to fit into the expectations
// of the triples and are not conforming with their official names.
// Check to see if the expectation should be changed.
// FIXME: TableGen this.
static const struct {
const char *NameCStr;
size_t NameLength;
const char *CPUAttrCStr;
size_t CPUAttrLength;
const char *SubArchCStr;
size_t SubArchLength;
unsigned DefaultFPU;
unsigned ArchBaseExtensions;
ARM::ArchKind ID;
ARMBuildAttrs::CPUArch ArchAttr; // Arch ID in build attributes.
StringRef getName() const { return StringRef(NameCStr, NameLength); }
// CPU class in build attributes.
StringRef getCPUAttr() const { return StringRef(CPUAttrCStr, CPUAttrLength); }
// Sub-Arch name.
StringRef getSubArch() const { return StringRef(SubArchCStr, SubArchLength); }
} ARCHNames[] = {
#define ARM_ARCH(NAME, ID, CPU_ATTR, SUB_ARCH, ARCH_ATTR, ARCH_FPU, ARCH_BASE_EXT) \
{NAME, sizeof(NAME) - 1, CPU_ATTR, sizeof(CPU_ATTR) - 1, SUB_ARCH, \
sizeof(SUB_ARCH) - 1, ARCH_FPU, ARCH_BASE_EXT, ID, ARCH_ATTR},
#include "llvm/Support/ARMTargetParser.def"
};
// List of Arch Extension names.
// FIXME: TableGen this.
static const struct {
const char *NameCStr;
size_t NameLength;
unsigned ID;
const char *Feature;
const char *NegFeature;
StringRef getName() const { return StringRef(NameCStr, NameLength); }
} ARCHExtNames[] = {
#define ARM_ARCH_EXT_NAME(NAME, ID, FEATURE, NEGFEATURE) \
{ NAME, sizeof(NAME) - 1, ID, FEATURE, NEGFEATURE },
#include "llvm/Support/ARMTargetParser.def"
};
// List of HWDiv names (use getHWDivSynonym) and which architectural
// features they correspond to (use getHWDivFeatures).
// FIXME: TableGen this.
static const struct {
const char *NameCStr;
size_t NameLength;
unsigned ID;
StringRef getName() const { return StringRef(NameCStr, NameLength); }
} HWDivNames[] = {
#define ARM_HW_DIV_NAME(NAME, ID) { NAME, sizeof(NAME) - 1, ID },
#include "llvm/Support/ARMTargetParser.def"
};
// List of CPU names and their arches.
// The same CPU can have multiple arches and can be default on multiple arches.
// When finding the Arch for a CPU, first-found prevails. Sort them accordingly.
// When this becomes table-generated, we'd probably need two tables.
// FIXME: TableGen this.
static const struct {
const char *NameCStr;
size_t NameLength;
ARM::ArchKind ArchID;
bool Default; // is $Name the default CPU for $ArchID ?
unsigned DefaultExtensions;
StringRef getName() const { return StringRef(NameCStr, NameLength); }
} CPUNames[] = {
#define ARM_CPU_NAME(NAME, ID, DEFAULT_FPU, IS_DEFAULT, DEFAULT_EXT) \
{ NAME, sizeof(NAME) - 1, ID, IS_DEFAULT, DEFAULT_EXT },
#include "llvm/Support/ARMTargetParser.def"
};
} // namespace
// ======================================================= //
// Information by ID
// ======================================================= //
StringRef llvm::ARM::getFPUName(unsigned FPUKind) {
if (FPUKind >= ARM::FK_LAST)
return StringRef();
return FPUNames[FPUKind].getName();
}
unsigned llvm::ARM::getFPUVersion(unsigned FPUKind) {
if (FPUKind >= ARM::FK_LAST)
return 0;
return FPUNames[FPUKind].FPUVersion;
}
unsigned llvm::ARM::getFPUNeonSupportLevel(unsigned FPUKind) {
if (FPUKind >= ARM::FK_LAST)
return 0;
return FPUNames[FPUKind].NeonSupport;
}
unsigned llvm::ARM::getFPURestriction(unsigned FPUKind) {
if (FPUKind >= ARM::FK_LAST)
return 0;
return FPUNames[FPUKind].Restriction;
}
unsigned llvm::ARM::getDefaultFPU(StringRef CPU, unsigned ArchKind) {
if (CPU == "generic")
return ARCHNames[ArchKind].DefaultFPU;
return StringSwitch<unsigned>(CPU)
#define ARM_CPU_NAME(NAME, ID, DEFAULT_FPU, IS_DEFAULT, DEFAULT_EXT) \
.Case(NAME, DEFAULT_FPU)
#include "llvm/Support/ARMTargetParser.def"
.Default(ARM::FK_INVALID);
}
unsigned llvm::ARM::getDefaultExtensions(StringRef CPU, unsigned ArchKind) {
if (CPU == "generic")
return ARCHNames[ArchKind].ArchBaseExtensions;
return StringSwitch<unsigned>(CPU)
#define ARM_CPU_NAME(NAME, ID, DEFAULT_FPU, IS_DEFAULT, DEFAULT_EXT) \
.Case(NAME, ARCHNames[ID].ArchBaseExtensions | DEFAULT_EXT)
#include "llvm/Support/ARMTargetParser.def"
.Default(ARM::AEK_INVALID);
}
bool llvm::ARM::getHWDivFeatures(unsigned HWDivKind,
std::vector<const char *> &Features) {
if (HWDivKind == ARM::AEK_INVALID)
return false;
if (HWDivKind & ARM::AEK_HWDIVARM)
Features.push_back("+hwdiv-arm");
else
Features.push_back("-hwdiv-arm");
if (HWDivKind & ARM::AEK_HWDIV)
Features.push_back("+hwdiv");
else
Features.push_back("-hwdiv");
return true;
}
bool llvm::ARM::getExtensionFeatures(unsigned Extensions,
std::vector<const char *> &Features) {
if (Extensions == ARM::AEK_INVALID)
return false;
if (Extensions & ARM::AEK_CRC)
Features.push_back("+crc");
else
Features.push_back("-crc");
if (Extensions & ARM::AEK_DSP)
Features.push_back("+dsp");
else
Features.push_back("-dsp");
return getHWDivFeatures(Extensions, Features);
}
bool llvm::ARM::getFPUFeatures(unsigned FPUKind,
std::vector<const char *> &Features) {
if (FPUKind >= ARM::FK_LAST || FPUKind == ARM::FK_INVALID)
return false;
// fp-only-sp and d16 subtarget features are independent of each other, so we
// must enable/disable both.
switch (FPUNames[FPUKind].Restriction) {
case ARM::FR_SP_D16:
Features.push_back("+fp-only-sp");
Features.push_back("+d16");
break;
case ARM::FR_D16:
Features.push_back("-fp-only-sp");
Features.push_back("+d16");
break;
case ARM::FR_None:
Features.push_back("-fp-only-sp");
Features.push_back("-d16");
break;
}
// FPU version subtarget features are inclusive of lower-numbered ones, so
// enable the one corresponding to this version and disable all that are
// higher. We also have to make sure to disable fp16 when vfp4 is disabled,
// as +vfp4 implies +fp16 but -vfp4 does not imply -fp16.
switch (FPUNames[FPUKind].FPUVersion) {
case ARM::FV_VFPV5:
Features.push_back("+fp-armv8");
break;
case ARM::FV_VFPV4:
Features.push_back("+vfp4");
Features.push_back("-fp-armv8");
break;
case ARM::FV_VFPV3_FP16:
Features.push_back("+vfp3");
Features.push_back("+fp16");
Features.push_back("-vfp4");
Features.push_back("-fp-armv8");
break;
case ARM::FV_VFPV3:
Features.push_back("+vfp3");
Features.push_back("-fp16");
Features.push_back("-vfp4");
Features.push_back("-fp-armv8");
break;
case ARM::FV_VFPV2:
Features.push_back("+vfp2");
Features.push_back("-vfp3");
Features.push_back("-fp16");
Features.push_back("-vfp4");
Features.push_back("-fp-armv8");
break;
case ARM::FV_NONE:
Features.push_back("-vfp2");
Features.push_back("-vfp3");
Features.push_back("-fp16");
Features.push_back("-vfp4");
Features.push_back("-fp-armv8");
break;
}
// crypto includes neon, so we handle this similarly to FPU version.
switch (FPUNames[FPUKind].NeonSupport) {
case ARM::NS_Crypto:
Features.push_back("+neon");
Features.push_back("+crypto");
break;
case ARM::NS_Neon:
Features.push_back("+neon");
Features.push_back("-crypto");
break;
case ARM::NS_None:
Features.push_back("-neon");
Features.push_back("-crypto");
break;
}
return true;
}
StringRef llvm::ARM::getArchName(unsigned ArchKind) {
if (ArchKind >= ARM::AK_LAST)
return StringRef();
return ARCHNames[ArchKind].getName();
}
StringRef llvm::ARM::getCPUAttr(unsigned ArchKind) {
if (ArchKind == ARM::AK_INVALID || ArchKind >= ARM::AK_LAST)
return StringRef();
return ARCHNames[ArchKind].getCPUAttr();
}
StringRef llvm::ARM::getSubArch(unsigned ArchKind) {
if (ArchKind == ARM::AK_INVALID || ArchKind >= ARM::AK_LAST)
return StringRef();
return ARCHNames[ArchKind].getSubArch();
}
unsigned llvm::ARM::getArchAttr(unsigned ArchKind) {
if (ArchKind >= ARM::AK_LAST)
return ARMBuildAttrs::CPUArch::Pre_v4;
return ARCHNames[ArchKind].ArchAttr;
}
StringRef llvm::ARM::getArchExtName(unsigned ArchExtKind) {
for (const auto AE : ARCHExtNames) {
if (ArchExtKind == AE.ID)
return AE.getName();
}
return StringRef();
}
const char *llvm::ARM::getArchExtFeature(StringRef ArchExt) {
if (ArchExt.startswith("no")) {
StringRef ArchExtBase(ArchExt.substr(2));
for (const auto AE : ARCHExtNames) {
if (AE.NegFeature && ArchExtBase == AE.getName())
return AE.NegFeature;
}
}
for (const auto AE : ARCHExtNames) {
if (AE.Feature && ArchExt == AE.getName())
return AE.Feature;
}
return nullptr;
}
StringRef llvm::ARM::getHWDivName(unsigned HWDivKind) {
for (const auto D : HWDivNames) {
if (HWDivKind == D.ID)
return D.getName();
}
return StringRef();
}
StringRef llvm::ARM::getDefaultCPU(StringRef Arch) {
unsigned AK = parseArch(Arch);
if (AK == ARM::AK_INVALID)
return StringRef();
// Look for multiple AKs to find the default for pair AK+Name.
for (const auto CPU : CPUNames) {
if (CPU.ArchID == AK && CPU.Default)
return CPU.getName();
}
// If we can't find a default then target the architecture instead
return "generic";
}
// ======================================================= //
// Parsers
// ======================================================= //
static StringRef getHWDivSynonym(StringRef HWDiv) {
return StringSwitch<StringRef>(HWDiv)
.Case("thumb,arm", "arm,thumb")
.Default(HWDiv);
}
static StringRef getFPUSynonym(StringRef FPU) {
return StringSwitch<StringRef>(FPU)
.Cases("fpa", "fpe2", "fpe3", "maverick", "invalid") // Unsupported
.Case("vfp2", "vfpv2")
.Case("vfp3", "vfpv3")
.Case("vfp4", "vfpv4")
.Case("vfp3-d16", "vfpv3-d16")
.Case("vfp4-d16", "vfpv4-d16")
.Cases("fp4-sp-d16", "vfpv4-sp-d16", "fpv4-sp-d16")
.Cases("fp4-dp-d16", "fpv4-dp-d16", "vfpv4-d16")
.Case("fp5-sp-d16", "fpv5-sp-d16")
.Cases("fp5-dp-d16", "fpv5-dp-d16", "fpv5-d16")
// FIXME: Clang uses it, but it's bogus, since neon defaults to vfpv3.
.Case("neon-vfpv3", "neon")
.Default(FPU);
}
static StringRef getArchSynonym(StringRef Arch) {
return StringSwitch<StringRef>(Arch)
.Case("v5", "v5t")
.Case("v5e", "v5te")
.Case("v6j", "v6")
.Case("v6hl", "v6k")
.Cases("v6m", "v6sm", "v6s-m", "v6-m")
.Cases("v6z", "v6zk", "v6kz")
.Cases("v7", "v7a", "v7hl", "v7l", "v7-a")
.Case("v7r", "v7-r")
.Case("v7m", "v7-m")
.Case("v7em", "v7e-m")
.Cases("v8", "v8a", "aarch64", "arm64", "v8-a")
.Case("v8.1a", "v8.1-a")
.Case("v8.2a", "v8.2-a")
.Case("v8m.base", "v8-m.base")
.Case("v8m.main", "v8-m.main")
.Default(Arch);
}
// MArch is expected to be of the form (arm|thumb)?(eb)?(v.+)?(eb)?, but
// (iwmmxt|xscale)(eb)? is also permitted. If the former, return
// "v.+", if the latter, return unmodified string, minus 'eb'.
// If invalid, return empty string.
StringRef llvm::ARM::getCanonicalArchName(StringRef Arch) {
size_t offset = StringRef::npos;
StringRef A = Arch;
StringRef Error = "";
// Begins with "arm" / "thumb", move past it.
if (A.startswith("arm64"))
offset = 5;
else if (A.startswith("arm"))
offset = 3;
else if (A.startswith("thumb"))
offset = 5;
else if (A.startswith("aarch64")) {
offset = 7;
// AArch64 uses "_be", not "eb" suffix.
if (A.find("eb") != StringRef::npos)
return Error;
if (A.substr(offset, 3) == "_be")
offset += 3;
}
// Ex. "armebv7", move past the "eb".
if (offset != StringRef::npos && A.substr(offset, 2) == "eb")
offset += 2;
// Or, if it ends with eb ("armv7eb"), chop it off.
else if (A.endswith("eb"))
A = A.substr(0, A.size() - 2);
// Trim the head
if (offset != StringRef::npos)
A = A.substr(offset);
// Empty string means offset reached the end, which means it's valid.
if (A.empty())
return Arch;
// Only match non-marketing names
if (offset != StringRef::npos) {
// Must start with 'vN'.
if (A[0] != 'v' || !std::isdigit(A[1]))
return Error;
// Can't have an extra 'eb'.
if (A.find("eb") != StringRef::npos)
return Error;
}
// Arch will either be a 'v' name (v7a) or a marketing name (xscale).
return A;
}
unsigned llvm::ARM::parseHWDiv(StringRef HWDiv) {
StringRef Syn = getHWDivSynonym(HWDiv);
for (const auto D : HWDivNames) {
if (Syn == D.getName())
return D.ID;
}
return ARM::AEK_INVALID;
}
unsigned llvm::ARM::parseFPU(StringRef FPU) {
StringRef Syn = getFPUSynonym(FPU);
for (const auto F : FPUNames) {
if (Syn == F.getName())
return F.ID;
}
return ARM::FK_INVALID;
}
// Allows partial match, ex. "v7a" matches "armv7a".
unsigned llvm::ARM::parseArch(StringRef Arch) {
Arch = getCanonicalArchName(Arch);
StringRef Syn = getArchSynonym(Arch);
for (const auto A : ARCHNames) {
if (A.getName().endswith(Syn))
return A.ID;
}
return ARM::AK_INVALID;
}
unsigned llvm::ARM::parseArchExt(StringRef ArchExt) {
for (const auto A : ARCHExtNames) {
if (ArchExt == A.getName())
return A.ID;
}
return ARM::AEK_INVALID;
}
unsigned llvm::ARM::parseCPUArch(StringRef CPU) {
for (const auto C : CPUNames) {
if (CPU == C.getName())
return C.ArchID;
}
return ARM::AK_INVALID;
}
// ARM, Thumb, AArch64
unsigned llvm::ARM::parseArchISA(StringRef Arch) {
return StringSwitch<unsigned>(Arch)
.StartsWith("aarch64", ARM::IK_AARCH64)
.StartsWith("arm64", ARM::IK_AARCH64)
.StartsWith("thumb", ARM::IK_THUMB)
.StartsWith("arm", ARM::IK_ARM)
.Default(ARM::EK_INVALID);
}
// Little/Big endian
unsigned llvm::ARM::parseArchEndian(StringRef Arch) {
if (Arch.startswith("armeb") || Arch.startswith("thumbeb") ||
Arch.startswith("aarch64_be"))
return ARM::EK_BIG;
if (Arch.startswith("arm") || Arch.startswith("thumb")) {
if (Arch.endswith("eb"))
return ARM::EK_BIG;
else
return ARM::EK_LITTLE;
}
if (Arch.startswith("aarch64"))
return ARM::EK_LITTLE;
return ARM::EK_INVALID;
}
// Profile A/R/M
unsigned llvm::ARM::parseArchProfile(StringRef Arch) {
Arch = getCanonicalArchName(Arch);
switch (parseArch(Arch)) {
case ARM::AK_ARMV6M:
case ARM::AK_ARMV7M:
case ARM::AK_ARMV7EM:
case ARM::AK_ARMV8MMainline:
case ARM::AK_ARMV8MBaseline:
return ARM::PK_M;
case ARM::AK_ARMV7R:
return ARM::PK_R;
case ARM::AK_ARMV7A:
case ARM::AK_ARMV7K:
case ARM::AK_ARMV8A:
case ARM::AK_ARMV8_1A:
case ARM::AK_ARMV8_2A:
return ARM::PK_A;
}
return ARM::PK_INVALID;
}
// Version number (ex. v7 = 7).
unsigned llvm::ARM::parseArchVersion(StringRef Arch) {
Arch = getCanonicalArchName(Arch);
switch (parseArch(Arch)) {
case ARM::AK_ARMV2:
case ARM::AK_ARMV2A:
return 2;
case ARM::AK_ARMV3:
case ARM::AK_ARMV3M:
return 3;
case ARM::AK_ARMV4:
case ARM::AK_ARMV4T:
return 4;
case ARM::AK_ARMV5T:
case ARM::AK_ARMV5TE:
case ARM::AK_IWMMXT:
case ARM::AK_IWMMXT2:
case ARM::AK_XSCALE:
case ARM::AK_ARMV5TEJ:
return 5;
case ARM::AK_ARMV6:
case ARM::AK_ARMV6K:
case ARM::AK_ARMV6T2:
case ARM::AK_ARMV6KZ:
case ARM::AK_ARMV6M:
return 6;
case ARM::AK_ARMV7A:
case ARM::AK_ARMV7R:
case ARM::AK_ARMV7M:
case ARM::AK_ARMV7S:
case ARM::AK_ARMV7EM:
case ARM::AK_ARMV7K:
return 7;
case ARM::AK_ARMV8A:
case ARM::AK_ARMV8_1A:
case ARM::AK_ARMV8_2A:
case ARM::AK_ARMV8MBaseline:
case ARM::AK_ARMV8MMainline:
return 8;
}
return 0;
}