llvm-project/llvm/lib/MC/MCContext.cpp

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//===- lib/MC/MCContext.cpp - Machine Code Context ------------------------===//
//
// 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
//
//===----------------------------------------------------------------------===//
#include "llvm/MC/MCContext.h"
#include "llvm/ADT/Optional.h"
#include "llvm/ADT/SmallString.h"
#include "llvm/ADT/SmallVector.h"
#include "llvm/ADT/StringMap.h"
#include "llvm/ADT/StringRef.h"
#include "llvm/ADT/Twine.h"
#include "llvm/BinaryFormat/COFF.h"
#include "llvm/BinaryFormat/ELF.h"
#include "llvm/BinaryFormat/XCOFF.h"
#include "llvm/MC/MCAsmInfo.h"
#include "llvm/MC/MCCodeView.h"
#include "llvm/MC/MCDwarf.h"
#include "llvm/MC/MCExpr.h"
#include "llvm/MC/MCFragment.h"
#include "llvm/MC/MCLabel.h"
#include "llvm/MC/MCObjectFileInfo.h"
#include "llvm/MC/MCSectionCOFF.h"
#include "llvm/MC/MCSectionELF.h"
#include "llvm/MC/MCSectionGOFF.h"
#include "llvm/MC/MCSectionMachO.h"
#include "llvm/MC/MCSectionWasm.h"
#include "llvm/MC/MCSectionXCOFF.h"
#include "llvm/MC/MCStreamer.h"
#include "llvm/MC/MCSymbol.h"
#include "llvm/MC/MCSymbolCOFF.h"
#include "llvm/MC/MCSymbolELF.h"
#include "llvm/MC/MCSymbolGOFF.h"
#include "llvm/MC/MCSymbolMachO.h"
#include "llvm/MC/MCSymbolWasm.h"
#include "llvm/MC/MCSymbolXCOFF.h"
#include "llvm/MC/SectionKind.h"
#include "llvm/Support/Casting.h"
#include "llvm/Support/CommandLine.h"
#include "llvm/Support/ErrorHandling.h"
#include "llvm/Support/MemoryBuffer.h"
#include "llvm/Support/Path.h"
#include "llvm/Support/Signals.h"
#include "llvm/Support/SourceMgr.h"
#include "llvm/Support/raw_ostream.h"
#include <cassert>
#include <cstdlib>
#include <tuple>
#include <utility>
using namespace llvm;
static cl::opt<char*>
AsSecureLogFileName("as-secure-log-file-name",
cl::desc("As secure log file name (initialized from "
"AS_SECURE_LOG_FILE env variable)"),
cl::init(getenv("AS_SECURE_LOG_FILE")), cl::Hidden);
static void defaultDiagHandler(const SMDiagnostic &SMD, bool, const SourceMgr &,
std::vector<const MDNode *> &) {
SMD.print(nullptr, errs());
}
MCContext::MCContext(const Triple &TheTriple, const MCAsmInfo *mai,
const MCRegisterInfo *mri, const MCSubtargetInfo *msti,
const SourceMgr *mgr, MCTargetOptions const *TargetOpts,
bool DoAutoReset)
: TT(TheTriple), SrcMgr(mgr), InlineSrcMgr(nullptr),
DiagHandler(defaultDiagHandler), MAI(mai), MRI(mri), MSTI(msti),
Symbols(Allocator), UsedNames(Allocator),
InlineAsmUsedLabelNames(Allocator),
CurrentDwarfLoc(0, 0, 0, DWARF2_FLAG_IS_STMT, 0, 0),
AutoReset(DoAutoReset), TargetOptions(TargetOpts) {
SecureLogFile = AsSecureLogFileName;
if (SrcMgr && SrcMgr->getNumBuffers())
MainFileName = std::string(SrcMgr->getMemoryBuffer(SrcMgr->getMainFileID())
->getBufferIdentifier());
switch (TheTriple.getObjectFormat()) {
case Triple::MachO:
Env = IsMachO;
break;
case Triple::COFF:
if (!TheTriple.isOSWindows())
report_fatal_error(
"Cannot initialize MC for non-Windows COFF object files.");
Env = IsCOFF;
break;
case Triple::ELF:
Env = IsELF;
break;
case Triple::Wasm:
Env = IsWasm;
break;
case Triple::XCOFF:
Env = IsXCOFF;
break;
case Triple::GOFF:
Env = IsGOFF;
break;
case Triple::UnknownObjectFormat:
report_fatal_error("Cannot initialize MC for unknown object file format.");
break;
}
}
MCContext::~MCContext() {
if (AutoReset)
reset();
// NOTE: The symbols are all allocated out of a bump pointer allocator,
// we don't need to free them here.
}
void MCContext::initInlineSourceManager() {
if (!InlineSrcMgr)
InlineSrcMgr.reset(new SourceMgr());
}
//===----------------------------------------------------------------------===//
// Module Lifetime Management
//===----------------------------------------------------------------------===//
void MCContext::reset() {
SrcMgr = nullptr;
InlineSrcMgr.reset();
LocInfos.clear();
DiagHandler = defaultDiagHandler;
// Call the destructors so the fragments are freed
COFFAllocator.DestroyAll();
ELFAllocator.DestroyAll();
GOFFAllocator.DestroyAll();
MachOAllocator.DestroyAll();
XCOFFAllocator.DestroyAll();
MCInstAllocator.DestroyAll();
MCSubtargetAllocator.DestroyAll();
InlineAsmUsedLabelNames.clear();
UsedNames.clear();
Symbols.clear();
Allocator.Reset();
Instances.clear();
CompilationDir.clear();
MainFileName.clear();
MCDwarfLineTablesCUMap.clear();
SectionsForRanges.clear();
MCGenDwarfLabelEntries.clear();
DwarfDebugFlags = StringRef();
DwarfCompileUnitID = 0;
CurrentDwarfLoc = MCDwarfLoc(0, 0, 0, DWARF2_FLAG_IS_STMT, 0, 0);
2010-11-26 12:16:08 +08:00
CVContext.reset();
MachOUniquingMap.clear();
ELFUniquingMap.clear();
GOFFUniquingMap.clear();
COFFUniquingMap.clear();
WasmUniquingMap.clear();
XCOFFUniquingMap.clear();
[MC][ELF] Put explicit section name symbols into entry size compatible sections Ensure that symbols explicitly* assigned a section name are placed into a section with a compatible entry size. This is done by creating multiple sections with the same name** if incompatible symbols are explicitly given the name of an incompatible section, whilst: - Avoiding using uniqued sections where possible (for readability and to maximize compatibly with assemblers). - Creating as few SHF_MERGE sections as possible (for efficiency). Given that each symbol is assigned to a section in a single pass, we must decide which section each symbol is assigned to without seeing the properties of all symbols. A stable and easy to understand assignment is desirable. The following rules facilitate this: The "generic" section for a given section name will be mergeable if the name is a mergeable "default" section name (such as .debug_str), a mergeable "implicit" section name (such as .rodata.str2.2), or MC has already created a mergeable "generic" section for the given section name (e.g. in response to a section directive in inline assembly). Otherwise, the "generic" section for a given name is non-mergeable; and, non-mergeable symbols are assigned to the "generic" section, while mergeable symbols are assigned to uniqued sections. Terminology: "default" sections are those always created by MC initially, e.g. .text or .debug_str. "implicit" sections are those created normally by MC in response to the symbols that it encounters, i.e. in the absence of an explicit section name assignment on the symbol, e.g. a function foo might be placed into a .text.foo section. "generic" sections are those that are referred to when a unique section ID is not supplied, e.g. if there are multiple unique .bob sections then ".quad .bob" will reference the generic .bob section. Typically, the generic section is just the first section of a given name to be created. Default sections are always generic. * Typically, section names might be explicitly assigned in source code using a language extension e.g. a section attribute: _attribute_ ((section ("section-name"))) - https://clang.llvm.org/docs/AttributeReference.html ** I refer to such sections as unique/uniqued sections. In assembly the ", unique," assembly syntax is used to express such sections. Fixes https://bugs.llvm.org/show_bug.cgi?id=43457. See https://reviews.llvm.org/D68101 for previous discussions leading to this patch. Some minor fixes were required to LLVM's tests, for tests had been using the old behavior - which allowed for explicitly assigning globals with incompatible entry sizes to a section. This fix relies on the ",unique ," assembly feature. This feature is not available until bintuils version 2.35 (https://sourceware.org/bugzilla/show_bug.cgi?id=25380). If the integrated assembler is not being used then we avoid using this feature for compatibility and instead try to place mergeable symbols into non-mergeable sections or issue an error otherwise. Differential Revision: https://reviews.llvm.org/D72194
2020-04-16 18:45:31 +08:00
ELFEntrySizeMap.clear();
ELFSeenGenericMergeableSections.clear();
NextID.clear();
AllowTemporaryLabels = true;
DwarfLocSeen = false;
GenDwarfForAssembly = false;
GenDwarfFileNumber = 0;
HadError = false;
}
//===----------------------------------------------------------------------===//
// MCInst Management
//===----------------------------------------------------------------------===//
MCInst *MCContext::createMCInst() {
return new (MCInstAllocator.Allocate()) MCInst;
}
//===----------------------------------------------------------------------===//
// Symbol Manipulation
//===----------------------------------------------------------------------===//
MCSymbol *MCContext::getOrCreateSymbol(const Twine &Name) {
SmallString<128> NameSV;
StringRef NameRef = Name.toStringRef(NameSV);
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assert(!NameRef.empty() && "Normal symbols cannot be unnamed!");
MCSymbol *&Sym = Symbols[NameRef];
if (!Sym)
Sym = createSymbol(NameRef, false, false);
return Sym;
}
MCSymbol *MCContext::getOrCreateFrameAllocSymbol(StringRef FuncName,
unsigned Idx) {
return getOrCreateSymbol(Twine(MAI->getPrivateGlobalPrefix()) + FuncName +
"$frame_escape_" + Twine(Idx));
}
MCSymbol *MCContext::getOrCreateParentFrameOffsetSymbol(StringRef FuncName) {
return getOrCreateSymbol(Twine(MAI->getPrivateGlobalPrefix()) + FuncName +
"$parent_frame_offset");
}
MCSymbol *MCContext::getOrCreateLSDASymbol(StringRef FuncName) {
return getOrCreateSymbol(Twine(MAI->getPrivateGlobalPrefix()) + "__ehtable$" +
FuncName);
}
MCSymbol *MCContext::createSymbolImpl(const StringMapEntry<bool> *Name,
bool IsTemporary) {
static_assert(std::is_trivially_destructible<MCSymbolCOFF>(),
"MCSymbol classes must be trivially destructible");
static_assert(std::is_trivially_destructible<MCSymbolELF>(),
"MCSymbol classes must be trivially destructible");
static_assert(std::is_trivially_destructible<MCSymbolMachO>(),
"MCSymbol classes must be trivially destructible");
static_assert(std::is_trivially_destructible<MCSymbolWasm>(),
"MCSymbol classes must be trivially destructible");
static_assert(std::is_trivially_destructible<MCSymbolXCOFF>(),
"MCSymbol classes must be trivially destructible");
switch (getObjectFileType()) {
case MCContext::IsCOFF:
return new (Name, *this) MCSymbolCOFF(Name, IsTemporary);
case MCContext::IsELF:
return new (Name, *this) MCSymbolELF(Name, IsTemporary);
case MCContext::IsGOFF:
return new (Name, *this) MCSymbolGOFF(Name, IsTemporary);
case MCContext::IsMachO:
return new (Name, *this) MCSymbolMachO(Name, IsTemporary);
case MCContext::IsWasm:
return new (Name, *this) MCSymbolWasm(Name, IsTemporary);
case MCContext::IsXCOFF:
return createXCOFFSymbolImpl(Name, IsTemporary);
}
return new (Name, *this) MCSymbol(MCSymbol::SymbolKindUnset, Name,
IsTemporary);
}
MCSymbol *MCContext::createSymbol(StringRef Name, bool AlwaysAddSuffix,
bool CanBeUnnamed) {
if (CanBeUnnamed && !UseNamesOnTempLabels)
return createSymbolImpl(nullptr, true);
// Determine whether this is a user written assembler temporary or normal
// label, if used.
bool IsTemporary = CanBeUnnamed;
if (AllowTemporaryLabels && !IsTemporary)
IsTemporary = Name.startswith(MAI->getPrivateGlobalPrefix());
SmallString<128> NewName = Name;
bool AddSuffix = AlwaysAddSuffix;
unsigned &NextUniqueID = NextID[Name];
while (true) {
if (AddSuffix) {
NewName.resize(Name.size());
raw_svector_ostream(NewName) << NextUniqueID++;
}
auto NameEntry = UsedNames.insert(std::make_pair(NewName.str(), true));
if (NameEntry.second || !NameEntry.first->second) {
// Ok, we found a name.
// Mark it as used for a non-section symbol.
NameEntry.first->second = true;
// Have the MCSymbol object itself refer to the copy of the string that is
// embedded in the UsedNames entry.
return createSymbolImpl(&*NameEntry.first, IsTemporary);
}
assert(IsTemporary && "Cannot rename non-temporary symbols");
AddSuffix = true;
}
llvm_unreachable("Infinite loop");
}
MCSymbol *MCContext::createTempSymbol(const Twine &Name, bool AlwaysAddSuffix) {
SmallString<128> NameSV;
raw_svector_ostream(NameSV) << MAI->getPrivateGlobalPrefix() << Name;
return createSymbol(NameSV, AlwaysAddSuffix, true);
}
MCSymbol *MCContext::createNamedTempSymbol(const Twine &Name) {
SmallString<128> NameSV;
raw_svector_ostream(NameSV) << MAI->getPrivateGlobalPrefix() << Name;
return createSymbol(NameSV, true, false);
}
MCSymbol *MCContext::createLinkerPrivateTempSymbol() {
SmallString<128> NameSV;
raw_svector_ostream(NameSV) << MAI->getLinkerPrivateGlobalPrefix() << "tmp";
return createSymbol(NameSV, true, false);
}
MCSymbol *MCContext::createTempSymbol() { return createTempSymbol("tmp"); }
MCSymbol *MCContext::createNamedTempSymbol() {
return createNamedTempSymbol("tmp");
}
unsigned MCContext::NextInstance(unsigned LocalLabelVal) {
MCLabel *&Label = Instances[LocalLabelVal];
if (!Label)
Label = new (*this) MCLabel(0);
return Label->incInstance();
}
unsigned MCContext::GetInstance(unsigned LocalLabelVal) {
MCLabel *&Label = Instances[LocalLabelVal];
if (!Label)
Label = new (*this) MCLabel(0);
return Label->getInstance();
}
MCSymbol *MCContext::getOrCreateDirectionalLocalSymbol(unsigned LocalLabelVal,
unsigned Instance) {
MCSymbol *&Sym = LocalSymbols[std::make_pair(LocalLabelVal, Instance)];
if (!Sym)
Sym = createNamedTempSymbol();
return Sym;
}
MCSymbol *MCContext::createDirectionalLocalSymbol(unsigned LocalLabelVal) {
unsigned Instance = NextInstance(LocalLabelVal);
return getOrCreateDirectionalLocalSymbol(LocalLabelVal, Instance);
}
MCSymbol *MCContext::getDirectionalLocalSymbol(unsigned LocalLabelVal,
bool Before) {
unsigned Instance = GetInstance(LocalLabelVal);
if (!Before)
++Instance;
return getOrCreateDirectionalLocalSymbol(LocalLabelVal, Instance);
}
MCSymbol *MCContext::lookupSymbol(const Twine &Name) const {
SmallString<128> NameSV;
StringRef NameRef = Name.toStringRef(NameSV);
return Symbols.lookup(NameRef);
}
void MCContext::setSymbolValue(MCStreamer &Streamer,
StringRef Sym,
uint64_t Val) {
auto Symbol = getOrCreateSymbol(Sym);
Streamer.emitAssignment(Symbol, MCConstantExpr::create(Val, *this));
}
void MCContext::registerInlineAsmLabel(MCSymbol *Sym) {
InlineAsmUsedLabelNames[Sym->getName()] = Sym;
}
MCSymbolXCOFF *
MCContext::createXCOFFSymbolImpl(const StringMapEntry<bool> *Name,
bool IsTemporary) {
if (!Name)
return new (nullptr, *this) MCSymbolXCOFF(nullptr, IsTemporary);
StringRef OriginalName = Name->first();
if (OriginalName.startswith("._Renamed..") ||
OriginalName.startswith("_Renamed.."))
reportError(SMLoc(), "invalid symbol name from source");
if (MAI->isValidUnquotedName(OriginalName))
return new (Name, *this) MCSymbolXCOFF(Name, IsTemporary);
// Now we have a name that contains invalid character(s) for XCOFF symbol.
// Let's replace with something valid, but save the original name so that
// we could still use the original name in the symbol table.
SmallString<128> InvalidName(OriginalName);
// If it's an entry point symbol, we will keep the '.'
// in front for the convention purpose. Otherwise, add "_Renamed.."
// as prefix to signal this is an renamed symbol.
const bool IsEntryPoint = !InvalidName.empty() && InvalidName[0] == '.';
SmallString<128> ValidName =
StringRef(IsEntryPoint ? "._Renamed.." : "_Renamed..");
// Append the hex values of '_' and invalid characters with "_Renamed..";
// at the same time replace invalid characters with '_'.
for (size_t I = 0; I < InvalidName.size(); ++I) {
if (!MAI->isAcceptableChar(InvalidName[I]) || InvalidName[I] == '_') {
raw_svector_ostream(ValidName).write_hex(InvalidName[I]);
InvalidName[I] = '_';
}
}
// Skip entry point symbol's '.' as we already have a '.' in front of
// "_Renamed".
if (IsEntryPoint)
ValidName.append(InvalidName.substr(1, InvalidName.size() - 1));
else
ValidName.append(InvalidName);
auto NameEntry = UsedNames.insert(std::make_pair(ValidName.str(), true));
assert((NameEntry.second || !NameEntry.first->second) &&
"This name is used somewhere else.");
// Mark the name as used for a non-section symbol.
NameEntry.first->second = true;
// Have the MCSymbol object itself refer to the copy of the string
// that is embedded in the UsedNames entry.
MCSymbolXCOFF *XSym = new (&*NameEntry.first, *this)
MCSymbolXCOFF(&*NameEntry.first, IsTemporary);
XSym->setSymbolTableName(MCSymbolXCOFF::getUnqualifiedName(OriginalName));
return XSym;
}
//===----------------------------------------------------------------------===//
// Section Management
//===----------------------------------------------------------------------===//
MCSectionMachO *MCContext::getMachOSection(StringRef Segment, StringRef Section,
unsigned TypeAndAttributes,
unsigned Reserved2, SectionKind Kind,
const char *BeginSymName) {
// We unique sections by their segment/section pair. The returned section
// may not have the same flags as the requested section, if so this should be
// diagnosed by the client as an error.
2010-11-26 12:16:08 +08:00
// Form the name to look up.
assert(Section.size() <= 16 && "section name is too long");
assert(!memchr(Section.data(), '\0', Section.size()) &&
"section name cannot contain NUL");
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// Do the lookup, if we have a hit, return it.
auto R = MachOUniquingMap.try_emplace((Segment + Twine(',') + Section).str());
if (!R.second)
return R.first->second;
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MCSymbol *Begin = nullptr;
if (BeginSymName)
Begin = createTempSymbol(BeginSymName, false);
// Otherwise, return a new section.
StringRef Name = R.first->first();
R.first->second = new (MachOAllocator.Allocate())
MCSectionMachO(Segment, Name.substr(Name.size() - Section.size()),
TypeAndAttributes, Reserved2, Kind, Begin);
return R.first->second;
}
void MCContext::renameELFSection(MCSectionELF *Section, StringRef Name) {
StringRef GroupName;
if (const MCSymbol *Group = Section->getGroup())
GroupName = Group->getName();
// This function is only used by .debug*, which should not have the
// SHF_LINK_ORDER flag.
unsigned UniqueID = Section->getUniqueID();
ELFUniquingMap.erase(
ELFSectionKey{Section->getName(), GroupName, "", UniqueID});
auto I = ELFUniquingMap
.insert(std::make_pair(
ELFSectionKey{Name, GroupName, "", UniqueID}, Section))
.first;
StringRef CachedName = I->first.SectionName;
const_cast<MCSectionELF *>(Section)->setSectionName(CachedName);
}
MCSectionELF *MCContext::createELFSectionImpl(StringRef Section, unsigned Type,
unsigned Flags, SectionKind K,
unsigned EntrySize,
const MCSymbolELF *Group,
bool Comdat, unsigned UniqueID,
const MCSymbolELF *LinkedToSym) {
MCSymbolELF *R;
MCSymbol *&Sym = Symbols[Section];
// A section symbol can not redefine regular symbols. There may be multiple
// sections with the same name, in which case the first such section wins.
if (Sym && Sym->isDefined() &&
(!Sym->isInSection() || Sym->getSection().getBeginSymbol() != Sym))
reportError(SMLoc(), "invalid symbol redefinition");
if (Sym && Sym->isUndefined()) {
R = cast<MCSymbolELF>(Sym);
} else {
auto NameIter = UsedNames.insert(std::make_pair(Section, false)).first;
R = new (&*NameIter, *this) MCSymbolELF(&*NameIter, /*isTemporary*/ false);
if (!Sym)
Sym = R;
}
R->setBinding(ELF::STB_LOCAL);
R->setType(ELF::STT_SECTION);
auto *Ret = new (ELFAllocator.Allocate())
MCSectionELF(Section, Type, Flags, K, EntrySize, Group, Comdat, UniqueID,
R, LinkedToSym);
auto *F = new MCDataFragment();
Ret->getFragmentList().insert(Ret->begin(), F);
F->setParent(Ret);
R->setFragment(F);
return Ret;
}
MCSectionELF *MCContext::createELFRelSection(const Twine &Name, unsigned Type,
unsigned Flags, unsigned EntrySize,
const MCSymbolELF *Group,
const MCSectionELF *RelInfoSection) {
StringMap<bool>::iterator I;
bool Inserted;
std::tie(I, Inserted) =
RelSecNames.insert(std::make_pair(Name.str(), true));
return createELFSectionImpl(
I->getKey(), Type, Flags, SectionKind::getReadOnly(), EntrySize, Group,
true, true, cast<MCSymbolELF>(RelInfoSection->getBeginSymbol()));
}
MCSectionELF *MCContext::getELFNamedSection(const Twine &Prefix,
const Twine &Suffix, unsigned Type,
unsigned Flags,
unsigned EntrySize) {
return getELFSection(Prefix + "." + Suffix, Type, Flags, EntrySize, Suffix,
/*IsComdat=*/true);
}
MCSectionELF *MCContext::getELFSection(const Twine &Section, unsigned Type,
unsigned Flags, unsigned EntrySize,
const Twine &Group, bool IsComdat,
unsigned UniqueID,
const MCSymbolELF *LinkedToSym) {
MCSymbolELF *GroupSym = nullptr;
if (!Group.isTriviallyEmpty() && !Group.str().empty())
GroupSym = cast<MCSymbolELF>(getOrCreateSymbol(Group));
return getELFSection(Section, Type, Flags, EntrySize, GroupSym, IsComdat,
UniqueID, LinkedToSym);
}
MCSectionELF *MCContext::getELFSection(const Twine &Section, unsigned Type,
unsigned Flags, unsigned EntrySize,
const MCSymbolELF *GroupSym,
bool IsComdat, unsigned UniqueID,
const MCSymbolELF *LinkedToSym) {
StringRef Group = "";
if (GroupSym)
Group = GroupSym->getName();
assert(!(LinkedToSym && LinkedToSym->getName().empty()));
// Do the lookup, if we have a hit, return it.
auto IterBool = ELFUniquingMap.insert(std::make_pair(
ELFSectionKey{Section.str(), Group,
LinkedToSym ? LinkedToSym->getName() : "", UniqueID},
nullptr));
auto &Entry = *IterBool.first;
if (!IterBool.second)
return Entry.second;
2010-11-26 12:16:08 +08:00
StringRef CachedName = Entry.first.SectionName;
SectionKind Kind;
if (Flags & ELF::SHF_ARM_PURECODE)
Kind = SectionKind::getExecuteOnly();
else if (Flags & ELF::SHF_EXECINSTR)
Kind = SectionKind::getText();
else
Kind = SectionKind::getReadOnly();
MCSectionELF *Result =
createELFSectionImpl(CachedName, Type, Flags, Kind, EntrySize, GroupSym,
IsComdat, UniqueID, LinkedToSym);
Entry.second = Result;
[MC][ELF] Put explicit section name symbols into entry size compatible sections Ensure that symbols explicitly* assigned a section name are placed into a section with a compatible entry size. This is done by creating multiple sections with the same name** if incompatible symbols are explicitly given the name of an incompatible section, whilst: - Avoiding using uniqued sections where possible (for readability and to maximize compatibly with assemblers). - Creating as few SHF_MERGE sections as possible (for efficiency). Given that each symbol is assigned to a section in a single pass, we must decide which section each symbol is assigned to without seeing the properties of all symbols. A stable and easy to understand assignment is desirable. The following rules facilitate this: The "generic" section for a given section name will be mergeable if the name is a mergeable "default" section name (such as .debug_str), a mergeable "implicit" section name (such as .rodata.str2.2), or MC has already created a mergeable "generic" section for the given section name (e.g. in response to a section directive in inline assembly). Otherwise, the "generic" section for a given name is non-mergeable; and, non-mergeable symbols are assigned to the "generic" section, while mergeable symbols are assigned to uniqued sections. Terminology: "default" sections are those always created by MC initially, e.g. .text or .debug_str. "implicit" sections are those created normally by MC in response to the symbols that it encounters, i.e. in the absence of an explicit section name assignment on the symbol, e.g. a function foo might be placed into a .text.foo section. "generic" sections are those that are referred to when a unique section ID is not supplied, e.g. if there are multiple unique .bob sections then ".quad .bob" will reference the generic .bob section. Typically, the generic section is just the first section of a given name to be created. Default sections are always generic. * Typically, section names might be explicitly assigned in source code using a language extension e.g. a section attribute: _attribute_ ((section ("section-name"))) - https://clang.llvm.org/docs/AttributeReference.html ** I refer to such sections as unique/uniqued sections. In assembly the ", unique," assembly syntax is used to express such sections. Fixes https://bugs.llvm.org/show_bug.cgi?id=43457. See https://reviews.llvm.org/D68101 for previous discussions leading to this patch. Some minor fixes were required to LLVM's tests, for tests had been using the old behavior - which allowed for explicitly assigning globals with incompatible entry sizes to a section. This fix relies on the ",unique ," assembly feature. This feature is not available until bintuils version 2.35 (https://sourceware.org/bugzilla/show_bug.cgi?id=25380). If the integrated assembler is not being used then we avoid using this feature for compatibility and instead try to place mergeable symbols into non-mergeable sections or issue an error otherwise. Differential Revision: https://reviews.llvm.org/D72194
2020-04-16 18:45:31 +08:00
recordELFMergeableSectionInfo(Result->getName(), Result->getFlags(),
Result->getUniqueID(), Result->getEntrySize());
return Result;
}
MCSectionELF *MCContext::createELFGroupSection(const MCSymbolELF *Group,
bool IsComdat) {
return createELFSectionImpl(".group", ELF::SHT_GROUP, 0,
SectionKind::getReadOnly(), 4, Group, IsComdat,
MCSection::NonUniqueID, nullptr);
}
[MC][ELF] Put explicit section name symbols into entry size compatible sections Ensure that symbols explicitly* assigned a section name are placed into a section with a compatible entry size. This is done by creating multiple sections with the same name** if incompatible symbols are explicitly given the name of an incompatible section, whilst: - Avoiding using uniqued sections where possible (for readability and to maximize compatibly with assemblers). - Creating as few SHF_MERGE sections as possible (for efficiency). Given that each symbol is assigned to a section in a single pass, we must decide which section each symbol is assigned to without seeing the properties of all symbols. A stable and easy to understand assignment is desirable. The following rules facilitate this: The "generic" section for a given section name will be mergeable if the name is a mergeable "default" section name (such as .debug_str), a mergeable "implicit" section name (such as .rodata.str2.2), or MC has already created a mergeable "generic" section for the given section name (e.g. in response to a section directive in inline assembly). Otherwise, the "generic" section for a given name is non-mergeable; and, non-mergeable symbols are assigned to the "generic" section, while mergeable symbols are assigned to uniqued sections. Terminology: "default" sections are those always created by MC initially, e.g. .text or .debug_str. "implicit" sections are those created normally by MC in response to the symbols that it encounters, i.e. in the absence of an explicit section name assignment on the symbol, e.g. a function foo might be placed into a .text.foo section. "generic" sections are those that are referred to when a unique section ID is not supplied, e.g. if there are multiple unique .bob sections then ".quad .bob" will reference the generic .bob section. Typically, the generic section is just the first section of a given name to be created. Default sections are always generic. * Typically, section names might be explicitly assigned in source code using a language extension e.g. a section attribute: _attribute_ ((section ("section-name"))) - https://clang.llvm.org/docs/AttributeReference.html ** I refer to such sections as unique/uniqued sections. In assembly the ", unique," assembly syntax is used to express such sections. Fixes https://bugs.llvm.org/show_bug.cgi?id=43457. See https://reviews.llvm.org/D68101 for previous discussions leading to this patch. Some minor fixes were required to LLVM's tests, for tests had been using the old behavior - which allowed for explicitly assigning globals with incompatible entry sizes to a section. This fix relies on the ",unique ," assembly feature. This feature is not available until bintuils version 2.35 (https://sourceware.org/bugzilla/show_bug.cgi?id=25380). If the integrated assembler is not being used then we avoid using this feature for compatibility and instead try to place mergeable symbols into non-mergeable sections or issue an error otherwise. Differential Revision: https://reviews.llvm.org/D72194
2020-04-16 18:45:31 +08:00
void MCContext::recordELFMergeableSectionInfo(StringRef SectionName,
unsigned Flags, unsigned UniqueID,
unsigned EntrySize) {
bool IsMergeable = Flags & ELF::SHF_MERGE;
if (UniqueID == GenericSectionID)
[MC][ELF] Put explicit section name symbols into entry size compatible sections Ensure that symbols explicitly* assigned a section name are placed into a section with a compatible entry size. This is done by creating multiple sections with the same name** if incompatible symbols are explicitly given the name of an incompatible section, whilst: - Avoiding using uniqued sections where possible (for readability and to maximize compatibly with assemblers). - Creating as few SHF_MERGE sections as possible (for efficiency). Given that each symbol is assigned to a section in a single pass, we must decide which section each symbol is assigned to without seeing the properties of all symbols. A stable and easy to understand assignment is desirable. The following rules facilitate this: The "generic" section for a given section name will be mergeable if the name is a mergeable "default" section name (such as .debug_str), a mergeable "implicit" section name (such as .rodata.str2.2), or MC has already created a mergeable "generic" section for the given section name (e.g. in response to a section directive in inline assembly). Otherwise, the "generic" section for a given name is non-mergeable; and, non-mergeable symbols are assigned to the "generic" section, while mergeable symbols are assigned to uniqued sections. Terminology: "default" sections are those always created by MC initially, e.g. .text or .debug_str. "implicit" sections are those created normally by MC in response to the symbols that it encounters, i.e. in the absence of an explicit section name assignment on the symbol, e.g. a function foo might be placed into a .text.foo section. "generic" sections are those that are referred to when a unique section ID is not supplied, e.g. if there are multiple unique .bob sections then ".quad .bob" will reference the generic .bob section. Typically, the generic section is just the first section of a given name to be created. Default sections are always generic. * Typically, section names might be explicitly assigned in source code using a language extension e.g. a section attribute: _attribute_ ((section ("section-name"))) - https://clang.llvm.org/docs/AttributeReference.html ** I refer to such sections as unique/uniqued sections. In assembly the ", unique," assembly syntax is used to express such sections. Fixes https://bugs.llvm.org/show_bug.cgi?id=43457. See https://reviews.llvm.org/D68101 for previous discussions leading to this patch. Some minor fixes were required to LLVM's tests, for tests had been using the old behavior - which allowed for explicitly assigning globals with incompatible entry sizes to a section. This fix relies on the ",unique ," assembly feature. This feature is not available until bintuils version 2.35 (https://sourceware.org/bugzilla/show_bug.cgi?id=25380). If the integrated assembler is not being used then we avoid using this feature for compatibility and instead try to place mergeable symbols into non-mergeable sections or issue an error otherwise. Differential Revision: https://reviews.llvm.org/D72194
2020-04-16 18:45:31 +08:00
ELFSeenGenericMergeableSections.insert(SectionName);
// For mergeable sections or non-mergeable sections with a generic mergeable
// section name we enter their Unique ID into the ELFEntrySizeMap so that
// compatible globals can be assigned to the same section.
if (IsMergeable || isELFGenericMergeableSection(SectionName)) {
ELFEntrySizeMap.insert(std::make_pair(
ELFEntrySizeKey{SectionName, Flags, EntrySize}, UniqueID));
}
}
bool MCContext::isELFImplicitMergeableSectionNamePrefix(StringRef SectionName) {
return SectionName.startswith(".rodata.str") ||
SectionName.startswith(".rodata.cst");
}
bool MCContext::isELFGenericMergeableSection(StringRef SectionName) {
return isELFImplicitMergeableSectionNamePrefix(SectionName) ||
ELFSeenGenericMergeableSections.count(SectionName);
}
Optional<unsigned> MCContext::getELFUniqueIDForEntsize(StringRef SectionName,
unsigned Flags,
unsigned EntrySize) {
auto I = ELFEntrySizeMap.find(
MCContext::ELFEntrySizeKey{SectionName, Flags, EntrySize});
return (I != ELFEntrySizeMap.end()) ? Optional<unsigned>(I->second) : None;
}
MCSectionGOFF *MCContext::getGOFFSection(StringRef Section, SectionKind Kind) {
// Do the lookup. If we don't have a hit, return a new section.
auto &GOFFSection = GOFFUniquingMap[Section.str()];
if (!GOFFSection)
GOFFSection = new (GOFFAllocator.Allocate()) MCSectionGOFF(Section, Kind);
return GOFFSection;
}
MCSectionCOFF *MCContext::getCOFFSection(StringRef Section,
unsigned Characteristics,
SectionKind Kind,
StringRef COMDATSymName, int Selection,
unsigned UniqueID,
const char *BeginSymName) {
MCSymbol *COMDATSymbol = nullptr;
if (!COMDATSymName.empty()) {
COMDATSymbol = getOrCreateSymbol(COMDATSymName);
COMDATSymName = COMDATSymbol->getName();
}
2010-11-26 12:16:08 +08:00
// Do the lookup, if we have a hit, return it.
COFFSectionKey T{Section, COMDATSymName, Selection, UniqueID};
auto IterBool = COFFUniquingMap.insert(std::make_pair(T, nullptr));
auto Iter = IterBool.first;
if (!IterBool.second)
return Iter->second;
MCSymbol *Begin = nullptr;
if (BeginSymName)
Begin = createTempSymbol(BeginSymName, false);
StringRef CachedName = Iter->first.SectionName;
MCSectionCOFF *Result = new (COFFAllocator.Allocate()) MCSectionCOFF(
CachedName, Characteristics, COMDATSymbol, Selection, Kind, Begin);
2010-11-26 12:16:08 +08:00
Iter->second = Result;
return Result;
}
MCSectionCOFF *MCContext::getCOFFSection(StringRef Section,
unsigned Characteristics,
SectionKind Kind,
const char *BeginSymName) {
return getCOFFSection(Section, Characteristics, Kind, "", 0, GenericSectionID,
BeginSymName);
}
MCSectionCOFF *MCContext::getAssociativeCOFFSection(MCSectionCOFF *Sec,
const MCSymbol *KeySym,
unsigned UniqueID) {
// Return the normal section if we don't have to be associative or unique.
if (!KeySym && UniqueID == GenericSectionID)
return Sec;
// If we have a key symbol, make an associative section with the same name and
// kind as the normal section.
unsigned Characteristics = Sec->getCharacteristics();
if (KeySym) {
Characteristics |= COFF::IMAGE_SCN_LNK_COMDAT;
return getCOFFSection(Sec->getName(), Characteristics, Sec->getKind(),
KeySym->getName(),
COFF::IMAGE_COMDAT_SELECT_ASSOCIATIVE, UniqueID);
}
return getCOFFSection(Sec->getName(), Characteristics, Sec->getKind(), "", 0,
UniqueID);
}
MCSectionWasm *MCContext::getWasmSection(const Twine &Section, SectionKind K,
unsigned Flags, const Twine &Group,
unsigned UniqueID,
const char *BeginSymName) {
MCSymbolWasm *GroupSym = nullptr;
if (!Group.isTriviallyEmpty() && !Group.str().empty()) {
GroupSym = cast<MCSymbolWasm>(getOrCreateSymbol(Group));
GroupSym->setComdat(true);
}
return getWasmSection(Section, K, Flags, GroupSym, UniqueID, BeginSymName);
}
MCSectionWasm *MCContext::getWasmSection(const Twine &Section, SectionKind Kind,
unsigned Flags,
const MCSymbolWasm *GroupSym,
unsigned UniqueID,
const char *BeginSymName) {
StringRef Group = "";
if (GroupSym)
Group = GroupSym->getName();
// Do the lookup, if we have a hit, return it.
auto IterBool = WasmUniquingMap.insert(
std::make_pair(WasmSectionKey{Section.str(), Group, UniqueID}, nullptr));
auto &Entry = *IterBool.first;
if (!IterBool.second)
return Entry.second;
StringRef CachedName = Entry.first.SectionName;
MCSymbol *Begin = createSymbol(CachedName, true, false);
Symbols[Begin->getName()] = Begin;
cast<MCSymbolWasm>(Begin)->setType(wasm::WASM_SYMBOL_TYPE_SECTION);
MCSectionWasm *Result = new (WasmAllocator.Allocate())
MCSectionWasm(CachedName, Kind, Flags, GroupSym, UniqueID, Begin);
Entry.second = Result;
auto *F = new MCDataFragment();
Result->getFragmentList().insert(Result->begin(), F);
F->setParent(Result);
Begin->setFragment(F);
return Result;
}
MCSectionXCOFF *MCContext::getXCOFFSection(
StringRef Section, SectionKind Kind,
Optional<XCOFF::CsectProperties> CsectProp, bool MultiSymbolsAllowed,
const char *BeginSymName,
Optional<XCOFF::DwarfSectionSubtypeFlags> DwarfSectionSubtypeFlags) {
bool IsDwarfSec = DwarfSectionSubtypeFlags.hasValue();
assert((IsDwarfSec != CsectProp.hasValue()) && "Invalid XCOFF section!");
// Do the lookup. If we have a hit, return it.
auto IterBool = XCOFFUniquingMap.insert(std::make_pair(
IsDwarfSec
? XCOFFSectionKey(Section.str(), DwarfSectionSubtypeFlags.getValue())
: XCOFFSectionKey(Section.str(), CsectProp->MappingClass),
nullptr));
auto &Entry = *IterBool.first;
if (!IterBool.second) {
MCSectionXCOFF *ExistedEntry = Entry.second;
if (ExistedEntry->isMultiSymbolsAllowed() != MultiSymbolsAllowed)
report_fatal_error("section's multiply symbols policy does not match");
return ExistedEntry;
}
// Otherwise, return a new section.
StringRef CachedName = Entry.first.SectionName;
MCSymbolXCOFF *QualName = nullptr;
// Debug section don't have storage class attribute.
if (IsDwarfSec)
QualName = cast<MCSymbolXCOFF>(getOrCreateSymbol(CachedName));
else
QualName = cast<MCSymbolXCOFF>(getOrCreateSymbol(
CachedName + "[" +
XCOFF::getMappingClassString(CsectProp->MappingClass) + "]"));
MCSymbol *Begin = nullptr;
if (BeginSymName)
Begin = createTempSymbol(BeginSymName, false);
// QualName->getUnqualifiedName() and CachedName are the same except when
// CachedName contains invalid character(s) such as '$' for an XCOFF symbol.
MCSectionXCOFF *Result = nullptr;
if (IsDwarfSec)
Result = new (XCOFFAllocator.Allocate())
MCSectionXCOFF(QualName->getUnqualifiedName(), Kind, QualName,
DwarfSectionSubtypeFlags.getValue(), Begin, CachedName,
MultiSymbolsAllowed);
else
Result = new (XCOFFAllocator.Allocate())
MCSectionXCOFF(QualName->getUnqualifiedName(), CsectProp->MappingClass,
CsectProp->Type, Kind, QualName, Begin, CachedName,
MultiSymbolsAllowed);
Entry.second = Result;
auto *F = new MCDataFragment();
Result->getFragmentList().insert(Result->begin(), F);
F->setParent(Result);
if (Begin)
Begin->setFragment(F);
return Result;
}
MCSubtargetInfo &MCContext::getSubtargetCopy(const MCSubtargetInfo &STI) {
return *new (MCSubtargetAllocator.Allocate()) MCSubtargetInfo(STI);
}
void MCContext::addDebugPrefixMapEntry(const std::string &From,
const std::string &To) {
DebugPrefixMap.insert(std::make_pair(From, To));
}
void MCContext::RemapDebugPaths() {
const auto &DebugPrefixMap = this->DebugPrefixMap;
if (DebugPrefixMap.empty())
return;
const auto RemapDebugPath = [&DebugPrefixMap](std::string &Path) {
SmallString<256> P(Path);
for (const auto &Entry : DebugPrefixMap) {
if (llvm::sys::path::replace_path_prefix(P, Entry.first, Entry.second)) {
Path = P.str().str();
break;
}
}
};
// Remap compilation directory.
std::string CompDir = std::string(CompilationDir.str());
RemapDebugPath(CompDir);
CompilationDir = CompDir;
// Remap MCDwarfDirs in all compilation units.
for (auto &CUIDTablePair : MCDwarfLineTablesCUMap)
for (auto &Dir : CUIDTablePair.second.getMCDwarfDirs())
RemapDebugPath(Dir);
}
//===----------------------------------------------------------------------===//
// Dwarf Management
//===----------------------------------------------------------------------===//
void MCContext::setGenDwarfRootFile(StringRef InputFileName, StringRef Buffer) {
// MCDwarf needs the root file as well as the compilation directory.
// If we find a '.file 0' directive that will supersede these values.
Optional<MD5::MD5Result> Cksum;
if (getDwarfVersion() >= 5) {
MD5 Hash;
MD5::MD5Result Sum;
Hash.update(Buffer);
Hash.final(Sum);
Cksum = Sum;
}
// Canonicalize the root filename. It cannot be empty, and should not
// repeat the compilation dir.
// The MCContext ctor initializes MainFileName to the name associated with
// the SrcMgr's main file ID, which might be the same as InputFileName (and
// possibly include directory components).
// Or, MainFileName might have been overridden by a -main-file-name option,
// which is supposed to be just a base filename with no directory component.
// So, if the InputFileName and MainFileName are not equal, assume
// MainFileName is a substitute basename and replace the last component.
SmallString<1024> FileNameBuf = InputFileName;
if (FileNameBuf.empty() || FileNameBuf == "-")
FileNameBuf = "<stdin>";
if (!getMainFileName().empty() && FileNameBuf != getMainFileName()) {
llvm::sys::path::remove_filename(FileNameBuf);
llvm::sys::path::append(FileNameBuf, getMainFileName());
}
StringRef FileName = FileNameBuf;
if (FileName.consume_front(getCompilationDir()))
if (llvm::sys::path::is_separator(FileName.front()))
FileName = FileName.drop_front();
assert(!FileName.empty());
setMCLineTableRootFile(
/*CUID=*/0, getCompilationDir(), FileName, Cksum, None);
}
/// getDwarfFile - takes a file name and number to place in the dwarf file and
/// directory tables. If the file number has already been allocated it is an
/// error and zero is returned and the client reports the error, else the
/// allocated file number is returned. The file numbers may be in any order.
Expected<unsigned> MCContext::getDwarfFile(StringRef Directory,
StringRef FileName,
unsigned FileNumber,
Optional<MD5::MD5Result> Checksum,
Optional<StringRef> Source,
unsigned CUID) {
MCDwarfLineTable &Table = MCDwarfLineTablesCUMap[CUID];
[llvm] Prevent duplicate files in debug line header in dwarf 5: another attempt Another attempt to land the changes in debug line header to prevent duplicate files in Dwarf 5. I rolled back my previous commit because of a mistake in generating the object file in a test. Meanwhile, I addressed some offline comments and changed the implementation; the largest difference is that MCDwarfLineTableHeader does not keep DwarfVersion but gets it as a parameter. I also merged the patch to fix two lld tests that will strt to fail into this patch. Original Commit: https://reviews.llvm.org/D59515 Original Message: Motivation: In previous dwarf versions, file name indexes started from 1, and the primary source file was not explicit. Dwarf 5 standard (6.2.4) prescribes the primary source file to be explicitly given an entry with an index number 0. The current implementation honors the specification by just duplicating the main source file, once with index number 0, and later maybe with another index number. While this is compliant with the letter of the standard, the duplication causes problems for consumers of this information such as lldb. (Some files are duplicated, where only some of them have a line table although all refer to the same file) With this change, dwarf 5 debug line section files always start from 0, and the zeroth entry is not duplicated whenever possible. This requires different handling of dwarf 4 and dwarf 5 during generation (e.g. when a function returns an index zero for a file name, it signals an error in dwarf 4, but not in dwarf 5) However, I think the minor complication is worth it, because it enables all consumers (lldb, gdb, dwarfdump, objdump, and so on) to treat all files in the file name list homogenously. llvm-svn: 358732
2019-04-19 10:26:56 +08:00
return Table.tryGetFile(Directory, FileName, Checksum, Source, DwarfVersion,
FileNumber);
}
/// isValidDwarfFileNumber - takes a dwarf file number and returns true if it
/// currently is assigned and false otherwise.
bool MCContext::isValidDwarfFileNumber(unsigned FileNumber, unsigned CUID) {
const MCDwarfLineTable &LineTable = getMCDwarfLineTable(CUID);
if (FileNumber == 0)
[llvm] Prevent duplicate files in debug line header in dwarf 5: another attempt Another attempt to land the changes in debug line header to prevent duplicate files in Dwarf 5. I rolled back my previous commit because of a mistake in generating the object file in a test. Meanwhile, I addressed some offline comments and changed the implementation; the largest difference is that MCDwarfLineTableHeader does not keep DwarfVersion but gets it as a parameter. I also merged the patch to fix two lld tests that will strt to fail into this patch. Original Commit: https://reviews.llvm.org/D59515 Original Message: Motivation: In previous dwarf versions, file name indexes started from 1, and the primary source file was not explicit. Dwarf 5 standard (6.2.4) prescribes the primary source file to be explicitly given an entry with an index number 0. The current implementation honors the specification by just duplicating the main source file, once with index number 0, and later maybe with another index number. While this is compliant with the letter of the standard, the duplication causes problems for consumers of this information such as lldb. (Some files are duplicated, where only some of them have a line table although all refer to the same file) With this change, dwarf 5 debug line section files always start from 0, and the zeroth entry is not duplicated whenever possible. This requires different handling of dwarf 4 and dwarf 5 during generation (e.g. when a function returns an index zero for a file name, it signals an error in dwarf 4, but not in dwarf 5) However, I think the minor complication is worth it, because it enables all consumers (lldb, gdb, dwarfdump, objdump, and so on) to treat all files in the file name list homogenously. llvm-svn: 358732
2019-04-19 10:26:56 +08:00
return getDwarfVersion() >= 5;
if (FileNumber >= LineTable.getMCDwarfFiles().size())
return false;
return !LineTable.getMCDwarfFiles()[FileNumber].Name.empty();
}
2018-09-08 10:04:20 +08:00
/// Remove empty sections from SectionsForRanges, to avoid generating
/// useless debug info for them.
void MCContext::finalizeDwarfSections(MCStreamer &MCOS) {
SectionsForRanges.remove_if(
[&](MCSection *Sec) { return !MCOS.mayHaveInstructions(*Sec); });
}
CodeViewContext &MCContext::getCVContext() {
if (!CVContext.get())
CVContext.reset(new CodeViewContext);
return *CVContext.get();
}
//===----------------------------------------------------------------------===//
// Error Reporting
//===----------------------------------------------------------------------===//
void MCContext::diagnose(const SMDiagnostic &SMD) {
assert(DiagHandler && "MCContext::DiagHandler is not set");
bool UseInlineSrcMgr = false;
const SourceMgr *SMP = nullptr;
if (SrcMgr) {
SMP = SrcMgr;
} else if (InlineSrcMgr) {
SMP = InlineSrcMgr.get();
UseInlineSrcMgr = true;
} else
llvm_unreachable("Either SourceMgr should be available");
DiagHandler(SMD, UseInlineSrcMgr, *SMP, LocInfos);
}
void MCContext::reportCommon(
SMLoc Loc,
std::function<void(SMDiagnostic &, const SourceMgr *)> GetMessage) {
// * MCContext::SrcMgr is null when the MC layer emits machine code for input
// other than assembly file, say, for .c/.cpp/.ll/.bc.
// * MCContext::InlineSrcMgr is null when the inline asm is not used.
// * A default SourceMgr is needed for diagnosing when both MCContext::SrcMgr
// and MCContext::InlineSrcMgr are null.
SourceMgr SM;
const SourceMgr *SMP = &SM;
bool UseInlineSrcMgr = false;
// FIXME: Simplify these by combining InlineSrcMgr & SrcMgr.
// For MC-only execution, only SrcMgr is used;
// For non MC-only execution, InlineSrcMgr is only ctor'd if there is
// inline asm in the IR.
if (Loc.isValid()) {
if (SrcMgr) {
SMP = SrcMgr;
} else if (InlineSrcMgr) {
SMP = InlineSrcMgr.get();
UseInlineSrcMgr = true;
} else
llvm_unreachable("Either SourceMgr should be available");
}
SMDiagnostic D;
GetMessage(D, SMP);
DiagHandler(D, UseInlineSrcMgr, *SMP, LocInfos);
}
void MCContext::reportError(SMLoc Loc, const Twine &Msg) {
HadError = true;
reportCommon(Loc, [&](SMDiagnostic &D, const SourceMgr *SMP) {
D = SMP->GetMessage(Loc, SourceMgr::DK_Error, Msg);
});
}
void MCContext::reportWarning(SMLoc Loc, const Twine &Msg) {
if (TargetOptions && TargetOptions->MCNoWarn)
return;
if (TargetOptions && TargetOptions->MCFatalWarnings) {
reportError(Loc, Msg);
} else {
reportCommon(Loc, [&](SMDiagnostic &D, const SourceMgr *SMP) {
D = SMP->GetMessage(Loc, SourceMgr::DK_Warning, Msg);
});
}
}
void MCContext::reportFatalError(SMLoc Loc, const Twine &Msg) {
reportError(Loc, Msg);
// If we reached here, we are failing ungracefully. Run the interrupt handlers
// to make sure any special cleanups get done, in particular that we remove
// files registered with RemoveFileOnSignal.
sys::RunInterruptHandlers();
exit(1);
}