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llvm-mirror/lib/MC/MCDwarf.cpp
Saleem Abdulrasool f56e4f6d3d RISCV: adjust handling of relocation emission for RISCV 
This re-architects the RISCV relocation handling to bring the
implementation closer in line with the implementation in binutils.  We
would previously aggressively resolve the relocation.  With this
restructuring, we always will emit a paired relocation for any symbolic
difference of the type of S±T[±C] where S and T are labels and C is a
constant.

GAS has a special target hook controlled by `RELOC_EXPANSION_POSSIBLE`
which indicates that a fixup may be expanded into multiple relocations.
This is used by the RISCV backend to always emit a paired relocation -
either ADD[WIDTH] + SUB[WIDTH] for text relocations or SET[WIDTH] +
SUB[WIDTH] for a debug info relocation.  Irrespective of whether linker
relaxation support is enabled, symbolic difference is always emitted as
a paired relocation.

This change also sinks the target specific behaviour down into the
target specific area rather than exposing it to the shared relocation
handling.  In the process, we also sink the "special" handling for debug
information down into the RISCV target.  Although this improves the path
for the other targets, this is not necessarily entirely ideal either.
The changes in the debug info emission could be done through another
type of hook as this functionality would be required by any other target
which wishes to do linker relaxation.  However, as there are no other
targets in LLVM which currently do this, this is a reasonable thing to
do until such time as the code needs to be shared.

Improve the handling of the relocation (and add a reduced test case from
the Linux kernel) to ensure that we handle complex expressions for
symbolic difference.  This ensures that we correct relocate symbols with
the adddends normalized and associated with the addition portion of the
paired relocation.

This change also addresses some review comments from Alex Bradbury about
the relocations meant for use in the DWARF CFA being named incorrectly
(using ADD6 instead of SET6) in the original change which introduced the
relocation type.

This resolves the issues with the symbolic difference emission
sufficiently to enable building the Linux kernel with clang+IAS+lld
(without linker relaxation).

Resolves PR50153, PR50156!
Fixes: ClangBuiltLinux/linux#1023, ClangBuiltLinux/linux#1143

Reviewed By: nickdesaulniers, maskray

Differential Revision: https://reviews.llvm.org/D103539
2021-06-17 08:20:02 -07:00

1920 lines
68 KiB
C++
Raw Blame History

//===- lib/MC/MCDwarf.cpp - MCDwarf implementation ------------------------===//
//
// 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/MCDwarf.h"
#include "llvm/ADT/ArrayRef.h"
#include "llvm/ADT/DenseMap.h"
#include "llvm/ADT/Hashing.h"
#include "llvm/ADT/Optional.h"
#include "llvm/ADT/STLExtras.h"
#include "llvm/ADT/SmallString.h"
#include "llvm/ADT/SmallVector.h"
#include "llvm/ADT/StringRef.h"
#include "llvm/ADT/Twine.h"
#include "llvm/BinaryFormat/Dwarf.h"
#include "llvm/Config/config.h"
#include "llvm/MC/MCAsmInfo.h"
#include "llvm/MC/MCContext.h"
#include "llvm/MC/MCExpr.h"
#include "llvm/MC/MCObjectFileInfo.h"
#include "llvm/MC/MCObjectStreamer.h"
#include "llvm/MC/MCRegisterInfo.h"
#include "llvm/MC/MCSection.h"
#include "llvm/MC/MCStreamer.h"
#include "llvm/MC/MCSymbol.h"
#include "llvm/MC/StringTableBuilder.h"
#include "llvm/Support/Casting.h"
#include "llvm/Support/Endian.h"
#include "llvm/Support/EndianStream.h"
#include "llvm/Support/ErrorHandling.h"
#include "llvm/Support/LEB128.h"
#include "llvm/Support/MathExtras.h"
#include "llvm/Support/Path.h"
#include "llvm/Support/SourceMgr.h"
#include "llvm/Support/raw_ostream.h"
#include <cassert>
#include <cstdint>
#include <string>
#include <utility>
#include <vector>
using namespace llvm;
MCSymbol *mcdwarf::emitListsTableHeaderStart(MCStreamer &S) {
MCSymbol *Start = S.getContext().createTempSymbol("debug_list_header_start");
MCSymbol *End = S.getContext().createTempSymbol("debug_list_header_end");
auto DwarfFormat = S.getContext().getDwarfFormat();
if (DwarfFormat == dwarf::DWARF64) {
S.AddComment("DWARF64 mark");
S.emitInt32(dwarf::DW_LENGTH_DWARF64);
}
S.AddComment("Length");
S.emitAbsoluteSymbolDiff(End, Start,
dwarf::getDwarfOffsetByteSize(DwarfFormat));
S.emitLabel(Start);
S.AddComment("Version");
S.emitInt16(S.getContext().getDwarfVersion());
S.AddComment("Address size");
S.emitInt8(S.getContext().getAsmInfo()->getCodePointerSize());
S.AddComment("Segment selector size");
S.emitInt8(0);
return End;
}
/// Manage the .debug_line_str section contents, if we use it.
class llvm::MCDwarfLineStr {
MCSymbol *LineStrLabel = nullptr;
StringTableBuilder LineStrings{StringTableBuilder::DWARF};
bool UseRelocs = false;
public:
/// Construct an instance that can emit .debug_line_str (for use in a normal
/// v5 line table).
explicit MCDwarfLineStr(MCContext &Ctx) {
UseRelocs = Ctx.getAsmInfo()->doesDwarfUseRelocationsAcrossSections();
if (UseRelocs)
LineStrLabel =
Ctx.getObjectFileInfo()->getDwarfLineStrSection()->getBeginSymbol();
}
/// Emit a reference to the string.
void emitRef(MCStreamer *MCOS, StringRef Path);
/// Emit the .debug_line_str section if appropriate.
void emitSection(MCStreamer *MCOS);
};
static inline uint64_t ScaleAddrDelta(MCContext &Context, uint64_t AddrDelta) {
unsigned MinInsnLength = Context.getAsmInfo()->getMinInstAlignment();
if (MinInsnLength == 1)
return AddrDelta;
if (AddrDelta % MinInsnLength != 0) {
// TODO: report this error, but really only once.
;
}
return AddrDelta / MinInsnLength;
}
//
// This is called when an instruction is assembled into the specified section
// and if there is information from the last .loc directive that has yet to have
// a line entry made for it is made.
//
void MCDwarfLineEntry::make(MCStreamer *MCOS, MCSection *Section) {
if (!MCOS->getContext().getDwarfLocSeen())
return;
// Create a symbol at in the current section for use in the line entry.
MCSymbol *LineSym = MCOS->getContext().createTempSymbol();
// Set the value of the symbol to use for the MCDwarfLineEntry.
MCOS->emitLabel(LineSym);
// Get the current .loc info saved in the context.
const MCDwarfLoc &DwarfLoc = MCOS->getContext().getCurrentDwarfLoc();
// Create a (local) line entry with the symbol and the current .loc info.
MCDwarfLineEntry LineEntry(LineSym, DwarfLoc);
// clear DwarfLocSeen saying the current .loc info is now used.
MCOS->getContext().clearDwarfLocSeen();
// Add the line entry to this section's entries.
MCOS->getContext()
.getMCDwarfLineTable(MCOS->getContext().getDwarfCompileUnitID())
.getMCLineSections()
.addLineEntry(LineEntry, Section);
}
//
// This helper routine returns an expression of End - Start + IntVal .
//
static inline const MCExpr *makeEndMinusStartExpr(MCContext &Ctx,
const MCSymbol &Start,
const MCSymbol &End,
int IntVal) {
MCSymbolRefExpr::VariantKind Variant = MCSymbolRefExpr::VK_None;
const MCExpr *Res = MCSymbolRefExpr::create(&End, Variant, Ctx);
const MCExpr *RHS = MCSymbolRefExpr::create(&Start, Variant, Ctx);
const MCExpr *Res1 = MCBinaryExpr::create(MCBinaryExpr::Sub, Res, RHS, Ctx);
const MCExpr *Res2 = MCConstantExpr::create(IntVal, Ctx);
const MCExpr *Res3 = MCBinaryExpr::create(MCBinaryExpr::Sub, Res1, Res2, Ctx);
return Res3;
}
//
// This helper routine returns an expression of Start + IntVal .
//
static inline const MCExpr *
makeStartPlusIntExpr(MCContext &Ctx, const MCSymbol &Start, int IntVal) {
MCSymbolRefExpr::VariantKind Variant = MCSymbolRefExpr::VK_None;
const MCExpr *LHS = MCSymbolRefExpr::create(&Start, Variant, Ctx);
const MCExpr *RHS = MCConstantExpr::create(IntVal, Ctx);
const MCExpr *Res = MCBinaryExpr::create(MCBinaryExpr::Add, LHS, RHS, Ctx);
return Res;
}
//
// This emits the Dwarf line table for the specified section from the entries
// in the LineSection.
//
static inline void emitDwarfLineTable(
MCStreamer *MCOS, MCSection *Section,
const MCLineSection::MCDwarfLineEntryCollection &LineEntries) {
unsigned FileNum = 1;
unsigned LastLine = 1;
unsigned Column = 0;
unsigned Flags = DWARF2_LINE_DEFAULT_IS_STMT ? DWARF2_FLAG_IS_STMT : 0;
unsigned Isa = 0;
unsigned Discriminator = 0;
MCSymbol *LastLabel = nullptr;
// Loop through each MCDwarfLineEntry and encode the dwarf line number table.
for (const MCDwarfLineEntry &LineEntry : LineEntries) {
int64_t LineDelta = static_cast<int64_t>(LineEntry.getLine()) - LastLine;
if (FileNum != LineEntry.getFileNum()) {
FileNum = LineEntry.getFileNum();
MCOS->emitInt8(dwarf::DW_LNS_set_file);
MCOS->emitULEB128IntValue(FileNum);
}
if (Column != LineEntry.getColumn()) {
Column = LineEntry.getColumn();
MCOS->emitInt8(dwarf::DW_LNS_set_column);
MCOS->emitULEB128IntValue(Column);
}
if (Discriminator != LineEntry.getDiscriminator() &&
MCOS->getContext().getDwarfVersion() >= 4) {
Discriminator = LineEntry.getDiscriminator();
unsigned Size = getULEB128Size(Discriminator);
MCOS->emitInt8(dwarf::DW_LNS_extended_op);
MCOS->emitULEB128IntValue(Size + 1);
MCOS->emitInt8(dwarf::DW_LNE_set_discriminator);
MCOS->emitULEB128IntValue(Discriminator);
}
if (Isa != LineEntry.getIsa()) {
Isa = LineEntry.getIsa();
MCOS->emitInt8(dwarf::DW_LNS_set_isa);
MCOS->emitULEB128IntValue(Isa);
}
if ((LineEntry.getFlags() ^ Flags) & DWARF2_FLAG_IS_STMT) {
Flags = LineEntry.getFlags();
MCOS->emitInt8(dwarf::DW_LNS_negate_stmt);
}
if (LineEntry.getFlags() & DWARF2_FLAG_BASIC_BLOCK)
MCOS->emitInt8(dwarf::DW_LNS_set_basic_block);
if (LineEntry.getFlags() & DWARF2_FLAG_PROLOGUE_END)
MCOS->emitInt8(dwarf::DW_LNS_set_prologue_end);
if (LineEntry.getFlags() & DWARF2_FLAG_EPILOGUE_BEGIN)
MCOS->emitInt8(dwarf::DW_LNS_set_epilogue_begin);
MCSymbol *Label = LineEntry.getLabel();
// At this point we want to emit/create the sequence to encode the delta in
// line numbers and the increment of the address from the previous Label
// and the current Label.
const MCAsmInfo *asmInfo = MCOS->getContext().getAsmInfo();
MCOS->emitDwarfAdvanceLineAddr(LineDelta, LastLabel, Label,
asmInfo->getCodePointerSize());
Discriminator = 0;
LastLine = LineEntry.getLine();
LastLabel = Label;
}
// Generate DWARF line end entry.
MCOS->emitDwarfLineEndEntry(Section, LastLabel);
}
//
// This emits the Dwarf file and the line tables.
//
void MCDwarfLineTable::emit(MCStreamer *MCOS, MCDwarfLineTableParams Params) {
MCContext &context = MCOS->getContext();
auto &LineTables = context.getMCDwarfLineTables();
// Bail out early so we don't switch to the debug_line section needlessly and
// in doing so create an unnecessary (if empty) section.
if (LineTables.empty())
return;
// In a v5 non-split line table, put the strings in a separate section.
Optional<MCDwarfLineStr> LineStr;
if (context.getDwarfVersion() >= 5)
LineStr = MCDwarfLineStr(context);
// Switch to the section where the table will be emitted into.
MCOS->SwitchSection(context.getObjectFileInfo()->getDwarfLineSection());
// Handle the rest of the Compile Units.
for (const auto &CUIDTablePair : LineTables) {
CUIDTablePair.second.emitCU(MCOS, Params, LineStr);
}
if (LineStr)
LineStr->emitSection(MCOS);
}
void MCDwarfDwoLineTable::Emit(MCStreamer &MCOS, MCDwarfLineTableParams Params,
MCSection *Section) const {
if (!HasSplitLineTable)
return;
Optional<MCDwarfLineStr> NoLineStr(None);
MCOS.SwitchSection(Section);
MCOS.emitLabel(Header.Emit(&MCOS, Params, None, NoLineStr).second);
}
std::pair<MCSymbol *, MCSymbol *>
MCDwarfLineTableHeader::Emit(MCStreamer *MCOS, MCDwarfLineTableParams Params,
Optional<MCDwarfLineStr> &LineStr) const {
static const char StandardOpcodeLengths[] = {
0, // length of DW_LNS_copy
1, // length of DW_LNS_advance_pc
1, // length of DW_LNS_advance_line
1, // length of DW_LNS_set_file
1, // length of DW_LNS_set_column
0, // length of DW_LNS_negate_stmt
0, // length of DW_LNS_set_basic_block
0, // length of DW_LNS_const_add_pc
1, // length of DW_LNS_fixed_advance_pc
0, // length of DW_LNS_set_prologue_end
0, // length of DW_LNS_set_epilogue_begin
1 // DW_LNS_set_isa
};
assert(array_lengthof(StandardOpcodeLengths) >=
(Params.DWARF2LineOpcodeBase - 1U));
return Emit(
MCOS, Params,
makeArrayRef(StandardOpcodeLengths, Params.DWARF2LineOpcodeBase - 1),
LineStr);
}
static const MCExpr *forceExpAbs(MCStreamer &OS, const MCExpr* Expr) {
MCContext &Context = OS.getContext();
assert(!isa<MCSymbolRefExpr>(Expr));
if (Context.getAsmInfo()->hasAggressiveSymbolFolding())
return Expr;
MCSymbol *ABS = Context.createTempSymbol();
OS.emitAssignment(ABS, Expr);
return MCSymbolRefExpr::create(ABS, Context);
}
static void emitAbsValue(MCStreamer &OS, const MCExpr *Value, unsigned Size) {
const MCExpr *ABS = forceExpAbs(OS, Value);
OS.emitValue(ABS, Size);
}
void MCDwarfLineStr::emitSection(MCStreamer *MCOS) {
// Switch to the .debug_line_str section.
MCOS->SwitchSection(
MCOS->getContext().getObjectFileInfo()->getDwarfLineStrSection());
// Emit the strings without perturbing the offsets we used.
LineStrings.finalizeInOrder();
SmallString<0> Data;
Data.resize(LineStrings.getSize());
LineStrings.write((uint8_t *)Data.data());
MCOS->emitBinaryData(Data.str());
}
void MCDwarfLineStr::emitRef(MCStreamer *MCOS, StringRef Path) {
int RefSize =
dwarf::getDwarfOffsetByteSize(MCOS->getContext().getDwarfFormat());
size_t Offset = LineStrings.add(Path);
if (UseRelocs) {
MCContext &Ctx = MCOS->getContext();
MCOS->emitValue(makeStartPlusIntExpr(Ctx, *LineStrLabel, Offset), RefSize);
} else
MCOS->emitIntValue(Offset, RefSize);
}
void MCDwarfLineTableHeader::emitV2FileDirTables(MCStreamer *MCOS) const {
// First the directory table.
for (auto &Dir : MCDwarfDirs) {
MCOS->emitBytes(Dir); // The DirectoryName, and...
MCOS->emitBytes(StringRef("\0", 1)); // its null terminator.
}
MCOS->emitInt8(0); // Terminate the directory list.
// Second the file table.
for (unsigned i = 1; i < MCDwarfFiles.size(); i++) {
assert(!MCDwarfFiles[i].Name.empty());
MCOS->emitBytes(MCDwarfFiles[i].Name); // FileName and...
MCOS->emitBytes(StringRef("\0", 1)); // its null terminator.
MCOS->emitULEB128IntValue(MCDwarfFiles[i].DirIndex); // Directory number.
MCOS->emitInt8(0); // Last modification timestamp (always 0).
MCOS->emitInt8(0); // File size (always 0).
}
MCOS->emitInt8(0); // Terminate the file list.
}
static void emitOneV5FileEntry(MCStreamer *MCOS, const MCDwarfFile &DwarfFile,
bool EmitMD5, bool HasSource,
Optional<MCDwarfLineStr> &LineStr) {
assert(!DwarfFile.Name.empty());
if (LineStr)
LineStr->emitRef(MCOS, DwarfFile.Name);
else {
MCOS->emitBytes(DwarfFile.Name); // FileName and...
MCOS->emitBytes(StringRef("\0", 1)); // its null terminator.
}
MCOS->emitULEB128IntValue(DwarfFile.DirIndex); // Directory number.
if (EmitMD5) {
const MD5::MD5Result &Cksum = *DwarfFile.Checksum;
MCOS->emitBinaryData(
StringRef(reinterpret_cast<const char *>(Cksum.Bytes.data()),
Cksum.Bytes.size()));
}
if (HasSource) {
if (LineStr)
LineStr->emitRef(MCOS, DwarfFile.Source.getValueOr(StringRef()));
else {
MCOS->emitBytes(
DwarfFile.Source.getValueOr(StringRef())); // Source and...
MCOS->emitBytes(StringRef("\0", 1)); // its null terminator.
}
}
}
void MCDwarfLineTableHeader::emitV5FileDirTables(
MCStreamer *MCOS, Optional<MCDwarfLineStr> &LineStr) const {
// The directory format, which is just a list of the directory paths. In a
// non-split object, these are references to .debug_line_str; in a split
// object, they are inline strings.
MCOS->emitInt8(1);
MCOS->emitULEB128IntValue(dwarf::DW_LNCT_path);
MCOS->emitULEB128IntValue(LineStr ? dwarf::DW_FORM_line_strp
: dwarf::DW_FORM_string);
MCOS->emitULEB128IntValue(MCDwarfDirs.size() + 1);
// Try not to emit an empty compilation directory.
const StringRef CompDir = CompilationDir.empty()
? MCOS->getContext().getCompilationDir()
: StringRef(CompilationDir);
if (LineStr) {
// Record path strings, emit references here.
LineStr->emitRef(MCOS, CompDir);
for (const auto &Dir : MCDwarfDirs)
LineStr->emitRef(MCOS, Dir);
} else {
// The list of directory paths. Compilation directory comes first.
MCOS->emitBytes(CompDir);
MCOS->emitBytes(StringRef("\0", 1));
for (const auto &Dir : MCDwarfDirs) {
MCOS->emitBytes(Dir); // The DirectoryName, and...
MCOS->emitBytes(StringRef("\0", 1)); // its null terminator.
}
}
// The file format, which is the inline null-terminated filename and a
// directory index. We don't track file size/timestamp so don't emit them
// in the v5 table. Emit MD5 checksums and source if we have them.
uint64_t Entries = 2;
if (HasAllMD5)
Entries += 1;
if (HasSource)
Entries += 1;
MCOS->emitInt8(Entries);
MCOS->emitULEB128IntValue(dwarf::DW_LNCT_path);
MCOS->emitULEB128IntValue(LineStr ? dwarf::DW_FORM_line_strp
: dwarf::DW_FORM_string);
MCOS->emitULEB128IntValue(dwarf::DW_LNCT_directory_index);
MCOS->emitULEB128IntValue(dwarf::DW_FORM_udata);
if (HasAllMD5) {
MCOS->emitULEB128IntValue(dwarf::DW_LNCT_MD5);
MCOS->emitULEB128IntValue(dwarf::DW_FORM_data16);
}
if (HasSource) {
MCOS->emitULEB128IntValue(dwarf::DW_LNCT_LLVM_source);
MCOS->emitULEB128IntValue(LineStr ? dwarf::DW_FORM_line_strp
: dwarf::DW_FORM_string);
}
// Then the counted list of files. The root file is file #0, then emit the
// files as provide by .file directives.
// MCDwarfFiles has an unused element [0] so use size() not size()+1.
// But sometimes MCDwarfFiles is empty, in which case we still emit one file.
MCOS->emitULEB128IntValue(MCDwarfFiles.empty() ? 1 : MCDwarfFiles.size());
// To accommodate assembler source written for DWARF v4 but trying to emit
// v5: If we didn't see a root file explicitly, replicate file #1.
assert((!RootFile.Name.empty() || MCDwarfFiles.size() >= 1) &&
"No root file and no .file directives");
emitOneV5FileEntry(MCOS, RootFile.Name.empty() ? MCDwarfFiles[1] : RootFile,
HasAllMD5, HasSource, LineStr);
for (unsigned i = 1; i < MCDwarfFiles.size(); ++i)
emitOneV5FileEntry(MCOS, MCDwarfFiles[i], HasAllMD5, HasSource, LineStr);
}
std::pair<MCSymbol *, MCSymbol *>
MCDwarfLineTableHeader::Emit(MCStreamer *MCOS, MCDwarfLineTableParams Params,
ArrayRef<char> StandardOpcodeLengths,
Optional<MCDwarfLineStr> &LineStr) const {
MCContext &context = MCOS->getContext();
// Create a symbol at the beginning of the line table.
MCSymbol *LineStartSym = Label;
if (!LineStartSym)
LineStartSym = context.createTempSymbol();
// Set the value of the symbol, as we are at the start of the line table.
MCOS->emitDwarfLineStartLabel(LineStartSym);
unsigned OffsetSize = dwarf::getDwarfOffsetByteSize(context.getDwarfFormat());
MCSymbol *LineEndSym = MCOS->emitDwarfUnitLength("debug_line", "unit length");
// Next 2 bytes is the Version.
unsigned LineTableVersion = context.getDwarfVersion();
MCOS->emitInt16(LineTableVersion);
// In v5, we get address info next.
if (LineTableVersion >= 5) {
MCOS->emitInt8(context.getAsmInfo()->getCodePointerSize());
MCOS->emitInt8(0); // Segment selector; same as EmitGenDwarfAranges.
}
// Create symbols for the start/end of the prologue.
MCSymbol *ProStartSym = context.createTempSymbol("prologue_start");
MCSymbol *ProEndSym = context.createTempSymbol("prologue_end");
// Length of the prologue, is the next 4 bytes (8 bytes for DWARF64). This is
// actually the length from after the length word, to the end of the prologue.
MCOS->emitAbsoluteSymbolDiff(ProEndSym, ProStartSym, OffsetSize);
MCOS->emitLabel(ProStartSym);
// Parameters of the state machine, are next.
MCOS->emitInt8(context.getAsmInfo()->getMinInstAlignment());
// maximum_operations_per_instruction
// For non-VLIW architectures this field is always 1.
// FIXME: VLIW architectures need to update this field accordingly.
if (LineTableVersion >= 4)
MCOS->emitInt8(1);
MCOS->emitInt8(DWARF2_LINE_DEFAULT_IS_STMT);
MCOS->emitInt8(Params.DWARF2LineBase);
MCOS->emitInt8(Params.DWARF2LineRange);
MCOS->emitInt8(StandardOpcodeLengths.size() + 1);
// Standard opcode lengths
for (char Length : StandardOpcodeLengths)
MCOS->emitInt8(Length);
// Put out the directory and file tables. The formats vary depending on
// the version.
if (LineTableVersion >= 5)
emitV5FileDirTables(MCOS, LineStr);
else
emitV2FileDirTables(MCOS);
// This is the end of the prologue, so set the value of the symbol at the
// end of the prologue (that was used in a previous expression).
MCOS->emitLabel(ProEndSym);
return std::make_pair(LineStartSym, LineEndSym);
}
void MCDwarfLineTable::emitCU(MCStreamer *MCOS, MCDwarfLineTableParams Params,
Optional<MCDwarfLineStr> &LineStr) const {
MCSymbol *LineEndSym = Header.Emit(MCOS, Params, LineStr).second;
// Put out the line tables.
for (const auto &LineSec : MCLineSections.getMCLineEntries())
emitDwarfLineTable(MCOS, LineSec.first, LineSec.second);
// This is the end of the section, so set the value of the symbol at the end
// of this section (that was used in a previous expression).
MCOS->emitLabel(LineEndSym);
}
Expected<unsigned> MCDwarfLineTable::tryGetFile(StringRef &Directory,
StringRef &FileName,
Optional<MD5::MD5Result> Checksum,
Optional<StringRef> Source,
uint16_t DwarfVersion,
unsigned FileNumber) {
return Header.tryGetFile(Directory, FileName, Checksum, Source, DwarfVersion,
FileNumber);
}
static bool isRootFile(const MCDwarfFile &RootFile, StringRef &Directory,
StringRef &FileName, Optional<MD5::MD5Result> Checksum) {
if (RootFile.Name.empty() || RootFile.Name != FileName.data())
return false;
return RootFile.Checksum == Checksum;
}
Expected<unsigned>
MCDwarfLineTableHeader::tryGetFile(StringRef &Directory,
StringRef &FileName,
Optional<MD5::MD5Result> Checksum,
Optional<StringRef> Source,
uint16_t DwarfVersion,
unsigned FileNumber) {
if (Directory == CompilationDir)
Directory = "";
if (FileName.empty()) {
FileName = "<stdin>";
Directory = "";
}
assert(!FileName.empty());
// Keep track of whether any or all files have an MD5 checksum.
// If any files have embedded source, they all must.
if (MCDwarfFiles.empty()) {
trackMD5Usage(Checksum.hasValue());
HasSource = (Source != None);
}
if (isRootFile(RootFile, Directory, FileName, Checksum) && DwarfVersion >= 5)
return 0;
if (FileNumber == 0) {
// File numbers start with 1 and/or after any file numbers
// allocated by inline-assembler .file directives.
FileNumber = MCDwarfFiles.empty() ? 1 : MCDwarfFiles.size();
SmallString<256> Buffer;
auto IterBool = SourceIdMap.insert(
std::make_pair((Directory + Twine('\0') + FileName).toStringRef(Buffer),
FileNumber));
if (!IterBool.second)
return IterBool.first->second;
}
// Make space for this FileNumber in the MCDwarfFiles vector if needed.
if (FileNumber >= MCDwarfFiles.size())
MCDwarfFiles.resize(FileNumber + 1);
// Get the new MCDwarfFile slot for this FileNumber.
MCDwarfFile &File = MCDwarfFiles[FileNumber];
// It is an error to see the same number more than once.
if (!File.Name.empty())
return make_error<StringError>("file number already allocated",
inconvertibleErrorCode());
// If any files have embedded source, they all must.
if (HasSource != (Source != None))
return make_error<StringError>("inconsistent use of embedded source",
inconvertibleErrorCode());
if (Directory.empty()) {
// Separate the directory part from the basename of the FileName.
StringRef tFileName = sys::path::filename(FileName);
if (!tFileName.empty()) {
Directory = sys::path::parent_path(FileName);
if (!Directory.empty())
FileName = tFileName;
}
}
// Find or make an entry in the MCDwarfDirs vector for this Directory.
// Capture directory name.
unsigned DirIndex;
if (Directory.empty()) {
// For FileNames with no directories a DirIndex of 0 is used.
DirIndex = 0;
} else {
DirIndex = llvm::find(MCDwarfDirs, Directory) - MCDwarfDirs.begin();
if (DirIndex >= MCDwarfDirs.size())
MCDwarfDirs.push_back(std::string(Directory));
// The DirIndex is one based, as DirIndex of 0 is used for FileNames with
// no directories. MCDwarfDirs[] is unlike MCDwarfFiles[] in that the
// directory names are stored at MCDwarfDirs[DirIndex-1] where FileNames
// are stored at MCDwarfFiles[FileNumber].Name .
DirIndex++;
}
File.Name = std::string(FileName);
File.DirIndex = DirIndex;
File.Checksum = Checksum;
trackMD5Usage(Checksum.hasValue());
File.Source = Source;
if (Source)
HasSource = true;
// return the allocated FileNumber.
return FileNumber;
}
/// Utility function to emit the encoding to a streamer.
void MCDwarfLineAddr::Emit(MCStreamer *MCOS, MCDwarfLineTableParams Params,
int64_t LineDelta, uint64_t AddrDelta) {
MCContext &Context = MCOS->getContext();
SmallString<256> Tmp;
raw_svector_ostream OS(Tmp);
MCDwarfLineAddr::Encode(Context, Params, LineDelta, AddrDelta, OS);
MCOS->emitBytes(OS.str());
}
/// Given a special op, return the address skip amount (in units of
/// DWARF2_LINE_MIN_INSN_LENGTH).
static uint64_t SpecialAddr(MCDwarfLineTableParams Params, uint64_t op) {
return (op - Params.DWARF2LineOpcodeBase) / Params.DWARF2LineRange;
}
/// Utility function to encode a Dwarf pair of LineDelta and AddrDeltas.
void MCDwarfLineAddr::Encode(MCContext &Context, MCDwarfLineTableParams Params,
int64_t LineDelta, uint64_t AddrDelta,
raw_ostream &OS) {
uint64_t Temp, Opcode;
bool NeedCopy = false;
// The maximum address skip amount that can be encoded with a special op.
uint64_t MaxSpecialAddrDelta = SpecialAddr(Params, 255);
// Scale the address delta by the minimum instruction length.
AddrDelta = ScaleAddrDelta(Context, AddrDelta);
// A LineDelta of INT64_MAX is a signal that this is actually a
// DW_LNE_end_sequence. We cannot use special opcodes here, since we want the
// end_sequence to emit the matrix entry.
if (LineDelta == INT64_MAX) {
if (AddrDelta == MaxSpecialAddrDelta)
OS << char(dwarf::DW_LNS_const_add_pc);
else if (AddrDelta) {
OS << char(dwarf::DW_LNS_advance_pc);
encodeULEB128(AddrDelta, OS);
}
OS << char(dwarf::DW_LNS_extended_op);
OS << char(1);
OS << char(dwarf::DW_LNE_end_sequence);
return;
}
// Bias the line delta by the base.
Temp = LineDelta - Params.DWARF2LineBase;
// If the line increment is out of range of a special opcode, we must encode
// it with DW_LNS_advance_line.
if (Temp >= Params.DWARF2LineRange ||
Temp + Params.DWARF2LineOpcodeBase > 255) {
OS << char(dwarf::DW_LNS_advance_line);
encodeSLEB128(LineDelta, OS);
LineDelta = 0;
Temp = 0 - Params.DWARF2LineBase;
NeedCopy = true;
}
// Use DW_LNS_copy instead of a "line +0, addr +0" special opcode.
if (LineDelta == 0 && AddrDelta == 0) {
OS << char(dwarf::DW_LNS_copy);
return;
}
// Bias the opcode by the special opcode base.
Temp += Params.DWARF2LineOpcodeBase;
// Avoid overflow when addr_delta is large.
if (AddrDelta < 256 + MaxSpecialAddrDelta) {
// Try using a special opcode.
Opcode = Temp + AddrDelta * Params.DWARF2LineRange;
if (Opcode <= 255) {
OS << char(Opcode);
return;
}
// Try using DW_LNS_const_add_pc followed by special op.
Opcode = Temp + (AddrDelta - MaxSpecialAddrDelta) * Params.DWARF2LineRange;
if (Opcode <= 255) {
OS << char(dwarf::DW_LNS_const_add_pc);
OS << char(Opcode);
return;
}
}
// Otherwise use DW_LNS_advance_pc.
OS << char(dwarf::DW_LNS_advance_pc);
encodeULEB128(AddrDelta, OS);
if (NeedCopy)
OS << char(dwarf::DW_LNS_copy);
else {
assert(Temp <= 255 && "Buggy special opcode encoding.");
OS << char(Temp);
}
}
// Utility function to write a tuple for .debug_abbrev.
static void EmitAbbrev(MCStreamer *MCOS, uint64_t Name, uint64_t Form) {
MCOS->emitULEB128IntValue(Name);
MCOS->emitULEB128IntValue(Form);
}
// When generating dwarf for assembly source files this emits
// the data for .debug_abbrev section which contains three DIEs.
static void EmitGenDwarfAbbrev(MCStreamer *MCOS) {
MCContext &context = MCOS->getContext();
MCOS->SwitchSection(context.getObjectFileInfo()->getDwarfAbbrevSection());
// DW_TAG_compile_unit DIE abbrev (1).
MCOS->emitULEB128IntValue(1);
MCOS->emitULEB128IntValue(dwarf::DW_TAG_compile_unit);
MCOS->emitInt8(dwarf::DW_CHILDREN_yes);
dwarf::Form SecOffsetForm =
context.getDwarfVersion() >= 4
? dwarf::DW_FORM_sec_offset
: (context.getDwarfFormat() == dwarf::DWARF64 ? dwarf::DW_FORM_data8
: dwarf::DW_FORM_data4);
EmitAbbrev(MCOS, dwarf::DW_AT_stmt_list, SecOffsetForm);
if (context.getGenDwarfSectionSyms().size() > 1 &&
context.getDwarfVersion() >= 3) {
EmitAbbrev(MCOS, dwarf::DW_AT_ranges, SecOffsetForm);
} else {
EmitAbbrev(MCOS, dwarf::DW_AT_low_pc, dwarf::DW_FORM_addr);
EmitAbbrev(MCOS, dwarf::DW_AT_high_pc, dwarf::DW_FORM_addr);
}
EmitAbbrev(MCOS, dwarf::DW_AT_name, dwarf::DW_FORM_string);
if (!context.getCompilationDir().empty())
EmitAbbrev(MCOS, dwarf::DW_AT_comp_dir, dwarf::DW_FORM_string);
StringRef DwarfDebugFlags = context.getDwarfDebugFlags();
if (!DwarfDebugFlags.empty())
EmitAbbrev(MCOS, dwarf::DW_AT_APPLE_flags, dwarf::DW_FORM_string);
EmitAbbrev(MCOS, dwarf::DW_AT_producer, dwarf::DW_FORM_string);
EmitAbbrev(MCOS, dwarf::DW_AT_language, dwarf::DW_FORM_data2);
EmitAbbrev(MCOS, 0, 0);
// DW_TAG_label DIE abbrev (2).
MCOS->emitULEB128IntValue(2);
MCOS->emitULEB128IntValue(dwarf::DW_TAG_label);
MCOS->emitInt8(dwarf::DW_CHILDREN_no);
EmitAbbrev(MCOS, dwarf::DW_AT_name, dwarf::DW_FORM_string);
EmitAbbrev(MCOS, dwarf::DW_AT_decl_file, dwarf::DW_FORM_data4);
EmitAbbrev(MCOS, dwarf::DW_AT_decl_line, dwarf::DW_FORM_data4);
EmitAbbrev(MCOS, dwarf::DW_AT_low_pc, dwarf::DW_FORM_addr);
EmitAbbrev(MCOS, 0, 0);
// Terminate the abbreviations for this compilation unit.
MCOS->emitInt8(0);
}
// When generating dwarf for assembly source files this emits the data for
// .debug_aranges section. This section contains a header and a table of pairs
// of PointerSize'ed values for the address and size of section(s) with line
// table entries.
static void EmitGenDwarfAranges(MCStreamer *MCOS,
const MCSymbol *InfoSectionSymbol) {
MCContext &context = MCOS->getContext();
auto &Sections = context.getGenDwarfSectionSyms();
MCOS->SwitchSection(context.getObjectFileInfo()->getDwarfARangesSection());
unsigned UnitLengthBytes =
dwarf::getUnitLengthFieldByteSize(context.getDwarfFormat());
unsigned OffsetSize = dwarf::getDwarfOffsetByteSize(context.getDwarfFormat());
// This will be the length of the .debug_aranges section, first account for
// the size of each item in the header (see below where we emit these items).
int Length = UnitLengthBytes + 2 + OffsetSize + 1 + 1;
// Figure the padding after the header before the table of address and size
// pairs who's values are PointerSize'ed.
const MCAsmInfo *asmInfo = context.getAsmInfo();
int AddrSize = asmInfo->getCodePointerSize();
int Pad = 2 * AddrSize - (Length & (2 * AddrSize - 1));
if (Pad == 2 * AddrSize)
Pad = 0;
Length += Pad;
// Add the size of the pair of PointerSize'ed values for the address and size
// of each section we have in the table.
Length += 2 * AddrSize * Sections.size();
// And the pair of terminating zeros.
Length += 2 * AddrSize;
// Emit the header for this section.
if (context.getDwarfFormat() == dwarf::DWARF64)
// The DWARF64 mark.
MCOS->emitInt32(dwarf::DW_LENGTH_DWARF64);
// The 4 (8 for DWARF64) byte length not including the length of the unit
// length field itself.
MCOS->emitIntValue(Length - UnitLengthBytes, OffsetSize);
// The 2 byte version, which is 2.
MCOS->emitInt16(2);
// The 4 (8 for DWARF64) byte offset to the compile unit in the .debug_info
// from the start of the .debug_info.
if (InfoSectionSymbol)
MCOS->emitSymbolValue(InfoSectionSymbol, OffsetSize,
asmInfo->needsDwarfSectionOffsetDirective());
else
MCOS->emitIntValue(0, OffsetSize);
// The 1 byte size of an address.
MCOS->emitInt8(AddrSize);
// The 1 byte size of a segment descriptor, we use a value of zero.
MCOS->emitInt8(0);
// Align the header with the padding if needed, before we put out the table.
for(int i = 0; i < Pad; i++)
MCOS->emitInt8(0);
// Now emit the table of pairs of PointerSize'ed values for the section
// addresses and sizes.
for (MCSection *Sec : Sections) {
const MCSymbol *StartSymbol = Sec->getBeginSymbol();
MCSymbol *EndSymbol = Sec->getEndSymbol(context);
assert(StartSymbol && "StartSymbol must not be NULL");
assert(EndSymbol && "EndSymbol must not be NULL");
const MCExpr *Addr = MCSymbolRefExpr::create(
StartSymbol, MCSymbolRefExpr::VK_None, context);
const MCExpr *Size =
makeEndMinusStartExpr(context, *StartSymbol, *EndSymbol, 0);
MCOS->emitValue(Addr, AddrSize);
emitAbsValue(*MCOS, Size, AddrSize);
}
// And finally the pair of terminating zeros.
MCOS->emitIntValue(0, AddrSize);
MCOS->emitIntValue(0, AddrSize);
}
// When generating dwarf for assembly source files this emits the data for
// .debug_info section which contains three parts. The header, the compile_unit
// DIE and a list of label DIEs.
static void EmitGenDwarfInfo(MCStreamer *MCOS,
const MCSymbol *AbbrevSectionSymbol,
const MCSymbol *LineSectionSymbol,
const MCSymbol *RangesSymbol) {
MCContext &context = MCOS->getContext();
MCOS->SwitchSection(context.getObjectFileInfo()->getDwarfInfoSection());
// Create a symbol at the start and end of this section used in here for the
// expression to calculate the length in the header.
MCSymbol *InfoStart = context.createTempSymbol();
MCOS->emitLabel(InfoStart);
MCSymbol *InfoEnd = context.createTempSymbol();
// First part: the header.
unsigned UnitLengthBytes =
dwarf::getUnitLengthFieldByteSize(context.getDwarfFormat());
unsigned OffsetSize = dwarf::getDwarfOffsetByteSize(context.getDwarfFormat());
if (context.getDwarfFormat() == dwarf::DWARF64)
// Emit DWARF64 mark.
MCOS->emitInt32(dwarf::DW_LENGTH_DWARF64);
// The 4 (8 for DWARF64) byte total length of the information for this
// compilation unit, not including the unit length field itself.
const MCExpr *Length =
makeEndMinusStartExpr(context, *InfoStart, *InfoEnd, UnitLengthBytes);
emitAbsValue(*MCOS, Length, OffsetSize);
// The 2 byte DWARF version.
MCOS->emitInt16(context.getDwarfVersion());
// The DWARF v5 header has unit type, address size, abbrev offset.
// Earlier versions have abbrev offset, address size.
const MCAsmInfo &AsmInfo = *context.getAsmInfo();
int AddrSize = AsmInfo.getCodePointerSize();
if (context.getDwarfVersion() >= 5) {
MCOS->emitInt8(dwarf::DW_UT_compile);
MCOS->emitInt8(AddrSize);
}
// The 4 (8 for DWARF64) byte offset to the debug abbrevs from the start of
// the .debug_abbrev.
if (AbbrevSectionSymbol)
MCOS->emitSymbolValue(AbbrevSectionSymbol, OffsetSize,
AsmInfo.needsDwarfSectionOffsetDirective());
else
// Since the abbrevs are at the start of the section, the offset is zero.
MCOS->emitIntValue(0, OffsetSize);
if (context.getDwarfVersion() <= 4)
MCOS->emitInt8(AddrSize);
// Second part: the compile_unit DIE.
// The DW_TAG_compile_unit DIE abbrev (1).
MCOS->emitULEB128IntValue(1);
// DW_AT_stmt_list, a 4 (8 for DWARF64) byte offset from the start of the
// .debug_line section.
if (LineSectionSymbol)
MCOS->emitSymbolValue(LineSectionSymbol, OffsetSize,
AsmInfo.needsDwarfSectionOffsetDirective());
else
// The line table is at the start of the section, so the offset is zero.
MCOS->emitIntValue(0, OffsetSize);
if (RangesSymbol) {
// There are multiple sections containing code, so we must use
// .debug_ranges/.debug_rnglists. AT_ranges, the 4/8 byte offset from the
// start of the .debug_ranges/.debug_rnglists.
MCOS->emitSymbolValue(RangesSymbol, OffsetSize);
} else {
// If we only have one non-empty code section, we can use the simpler
// AT_low_pc and AT_high_pc attributes.
// Find the first (and only) non-empty text section
auto &Sections = context.getGenDwarfSectionSyms();
const auto TextSection = Sections.begin();
assert(TextSection != Sections.end() && "No text section found");
MCSymbol *StartSymbol = (*TextSection)->getBeginSymbol();
MCSymbol *EndSymbol = (*TextSection)->getEndSymbol(context);
assert(StartSymbol && "StartSymbol must not be NULL");
assert(EndSymbol && "EndSymbol must not be NULL");
// AT_low_pc, the first address of the default .text section.
const MCExpr *Start = MCSymbolRefExpr::create(
StartSymbol, MCSymbolRefExpr::VK_None, context);
MCOS->emitValue(Start, AddrSize);
// AT_high_pc, the last address of the default .text section.
const MCExpr *End = MCSymbolRefExpr::create(
EndSymbol, MCSymbolRefExpr::VK_None, context);
MCOS->emitValue(End, AddrSize);
}
// AT_name, the name of the source file. Reconstruct from the first directory
// and file table entries.
const SmallVectorImpl<std::string> &MCDwarfDirs = context.getMCDwarfDirs();
if (MCDwarfDirs.size() > 0) {
MCOS->emitBytes(MCDwarfDirs[0]);
MCOS->emitBytes(sys::path::get_separator());
}
const SmallVectorImpl<MCDwarfFile> &MCDwarfFiles = context.getMCDwarfFiles();
// MCDwarfFiles might be empty if we have an empty source file.
// If it's not empty, [0] is unused and [1] is the first actual file.
assert(MCDwarfFiles.empty() || MCDwarfFiles.size() >= 2);
const MCDwarfFile &RootFile =
MCDwarfFiles.empty()
? context.getMCDwarfLineTable(/*CUID=*/0).getRootFile()
: MCDwarfFiles[1];
MCOS->emitBytes(RootFile.Name);
MCOS->emitInt8(0); // NULL byte to terminate the string.
// AT_comp_dir, the working directory the assembly was done in.
if (!context.getCompilationDir().empty()) {
MCOS->emitBytes(context.getCompilationDir());
MCOS->emitInt8(0); // NULL byte to terminate the string.
}
// AT_APPLE_flags, the command line arguments of the assembler tool.
StringRef DwarfDebugFlags = context.getDwarfDebugFlags();
if (!DwarfDebugFlags.empty()){
MCOS->emitBytes(DwarfDebugFlags);
MCOS->emitInt8(0); // NULL byte to terminate the string.
}
// AT_producer, the version of the assembler tool.
StringRef DwarfDebugProducer = context.getDwarfDebugProducer();
if (!DwarfDebugProducer.empty())
MCOS->emitBytes(DwarfDebugProducer);
else
MCOS->emitBytes(StringRef("llvm-mc (based on LLVM " PACKAGE_VERSION ")"));
MCOS->emitInt8(0); // NULL byte to terminate the string.
// AT_language, a 4 byte value. We use DW_LANG_Mips_Assembler as the dwarf2
// draft has no standard code for assembler.
MCOS->emitInt16(dwarf::DW_LANG_Mips_Assembler);
// Third part: the list of label DIEs.
// Loop on saved info for dwarf labels and create the DIEs for them.
const std::vector<MCGenDwarfLabelEntry> &Entries =
MCOS->getContext().getMCGenDwarfLabelEntries();
for (const auto &Entry : Entries) {
// The DW_TAG_label DIE abbrev (2).
MCOS->emitULEB128IntValue(2);
// AT_name, of the label without any leading underbar.
MCOS->emitBytes(Entry.getName());
MCOS->emitInt8(0); // NULL byte to terminate the string.
// AT_decl_file, index into the file table.
MCOS->emitInt32(Entry.getFileNumber());
// AT_decl_line, source line number.
MCOS->emitInt32(Entry.getLineNumber());
// AT_low_pc, start address of the label.
const MCExpr *AT_low_pc = MCSymbolRefExpr::create(Entry.getLabel(),
MCSymbolRefExpr::VK_None, context);
MCOS->emitValue(AT_low_pc, AddrSize);
}
// Add the NULL DIE terminating the Compile Unit DIE's.
MCOS->emitInt8(0);
// Now set the value of the symbol at the end of the info section.
MCOS->emitLabel(InfoEnd);
}
// When generating dwarf for assembly source files this emits the data for
// .debug_ranges section. We only emit one range list, which spans all of the
// executable sections of this file.
static MCSymbol *emitGenDwarfRanges(MCStreamer *MCOS) {
MCContext &context = MCOS->getContext();
auto &Sections = context.getGenDwarfSectionSyms();
const MCAsmInfo *AsmInfo = context.getAsmInfo();
int AddrSize = AsmInfo->getCodePointerSize();
MCSymbol *RangesSymbol;
if (MCOS->getContext().getDwarfVersion() >= 5) {
MCOS->SwitchSection(context.getObjectFileInfo()->getDwarfRnglistsSection());
MCSymbol *EndSymbol = mcdwarf::emitListsTableHeaderStart(*MCOS);
MCOS->AddComment("Offset entry count");
MCOS->emitInt32(0);
RangesSymbol = context.createTempSymbol("debug_rnglist0_start");
MCOS->emitLabel(RangesSymbol);
for (MCSection *Sec : Sections) {
const MCSymbol *StartSymbol = Sec->getBeginSymbol();
const MCSymbol *EndSymbol = Sec->getEndSymbol(context);
const MCExpr *SectionStartAddr = MCSymbolRefExpr::create(
StartSymbol, MCSymbolRefExpr::VK_None, context);
const MCExpr *SectionSize =
makeEndMinusStartExpr(context, *StartSymbol, *EndSymbol, 0);
MCOS->emitInt8(dwarf::DW_RLE_start_length);
MCOS->emitValue(SectionStartAddr, AddrSize);
MCOS->emitULEB128Value(SectionSize);
}
MCOS->emitInt8(dwarf::DW_RLE_end_of_list);
MCOS->emitLabel(EndSymbol);
} else {
MCOS->SwitchSection(context.getObjectFileInfo()->getDwarfRangesSection());
RangesSymbol = context.createTempSymbol("debug_ranges_start");
MCOS->emitLabel(RangesSymbol);
for (MCSection *Sec : Sections) {
const MCSymbol *StartSymbol = Sec->getBeginSymbol();
const MCSymbol *EndSymbol = Sec->getEndSymbol(context);
// Emit a base address selection entry for the section start.
const MCExpr *SectionStartAddr = MCSymbolRefExpr::create(
StartSymbol, MCSymbolRefExpr::VK_None, context);
MCOS->emitFill(AddrSize, 0xFF);
MCOS->emitValue(SectionStartAddr, AddrSize);
// Emit a range list entry spanning this section.
const MCExpr *SectionSize =
makeEndMinusStartExpr(context, *StartSymbol, *EndSymbol, 0);
MCOS->emitIntValue(0, AddrSize);
emitAbsValue(*MCOS, SectionSize, AddrSize);
}
// Emit end of list entry
MCOS->emitIntValue(0, AddrSize);
MCOS->emitIntValue(0, AddrSize);
}
return RangesSymbol;
}
//
// When generating dwarf for assembly source files this emits the Dwarf
// sections.
//
void MCGenDwarfInfo::Emit(MCStreamer *MCOS) {
MCContext &context = MCOS->getContext();
// Create the dwarf sections in this order (.debug_line already created).
const MCAsmInfo *AsmInfo = context.getAsmInfo();
bool CreateDwarfSectionSymbols =
AsmInfo->doesDwarfUseRelocationsAcrossSections();
MCSymbol *LineSectionSymbol = nullptr;
if (CreateDwarfSectionSymbols)
LineSectionSymbol = MCOS->getDwarfLineTableSymbol(0);
MCSymbol *AbbrevSectionSymbol = nullptr;
MCSymbol *InfoSectionSymbol = nullptr;
MCSymbol *RangesSymbol = nullptr;
// Create end symbols for each section, and remove empty sections
MCOS->getContext().finalizeDwarfSections(*MCOS);
// If there are no sections to generate debug info for, we don't need
// to do anything
if (MCOS->getContext().getGenDwarfSectionSyms().empty())
return;
// We only use the .debug_ranges section if we have multiple code sections,
// and we are emitting a DWARF version which supports it.
const bool UseRangesSection =
MCOS->getContext().getGenDwarfSectionSyms().size() > 1 &&
MCOS->getContext().getDwarfVersion() >= 3;
CreateDwarfSectionSymbols |= UseRangesSection;
MCOS->SwitchSection(context.getObjectFileInfo()->getDwarfInfoSection());
if (CreateDwarfSectionSymbols) {
InfoSectionSymbol = context.createTempSymbol();
MCOS->emitLabel(InfoSectionSymbol);
}
MCOS->SwitchSection(context.getObjectFileInfo()->getDwarfAbbrevSection());
if (CreateDwarfSectionSymbols) {
AbbrevSectionSymbol = context.createTempSymbol();
MCOS->emitLabel(AbbrevSectionSymbol);
}
MCOS->SwitchSection(context.getObjectFileInfo()->getDwarfARangesSection());
// Output the data for .debug_aranges section.
EmitGenDwarfAranges(MCOS, InfoSectionSymbol);
if (UseRangesSection) {
RangesSymbol = emitGenDwarfRanges(MCOS);
assert(RangesSymbol);
}
// Output the data for .debug_abbrev section.
EmitGenDwarfAbbrev(MCOS);
// Output the data for .debug_info section.
EmitGenDwarfInfo(MCOS, AbbrevSectionSymbol, LineSectionSymbol, RangesSymbol);
}
//
// When generating dwarf for assembly source files this is called when symbol
// for a label is created. If this symbol is not a temporary and is in the
// section that dwarf is being generated for, save the needed info to create
// a dwarf label.
//
void MCGenDwarfLabelEntry::Make(MCSymbol *Symbol, MCStreamer *MCOS,
SourceMgr &SrcMgr, SMLoc &Loc) {
// We won't create dwarf labels for temporary symbols.
if (Symbol->isTemporary())
return;
MCContext &context = MCOS->getContext();
// We won't create dwarf labels for symbols in sections that we are not
// generating debug info for.
if (!context.getGenDwarfSectionSyms().count(MCOS->getCurrentSectionOnly()))
return;
// The dwarf label's name does not have the symbol name's leading
// underbar if any.
StringRef Name = Symbol->getName();
if (Name.startswith("_"))
Name = Name.substr(1, Name.size()-1);
// Get the dwarf file number to be used for the dwarf label.
unsigned FileNumber = context.getGenDwarfFileNumber();
// Finding the line number is the expensive part which is why we just don't
// pass it in as for some symbols we won't create a dwarf label.
unsigned CurBuffer = SrcMgr.FindBufferContainingLoc(Loc);
unsigned LineNumber = SrcMgr.FindLineNumber(Loc, CurBuffer);
// We create a temporary symbol for use for the AT_high_pc and AT_low_pc
// values so that they don't have things like an ARM thumb bit from the
// original symbol. So when used they won't get a low bit set after
// relocation.
MCSymbol *Label = context.createTempSymbol();
MCOS->emitLabel(Label);
// Create and entry for the info and add it to the other entries.
MCOS->getContext().addMCGenDwarfLabelEntry(
MCGenDwarfLabelEntry(Name, FileNumber, LineNumber, Label));
}
static int getDataAlignmentFactor(MCStreamer &streamer) {
MCContext &context = streamer.getContext();
const MCAsmInfo *asmInfo = context.getAsmInfo();
int size = asmInfo->getCalleeSaveStackSlotSize();
if (asmInfo->isStackGrowthDirectionUp())
return size;
else
return -size;
}
static unsigned getSizeForEncoding(MCStreamer &streamer,
unsigned symbolEncoding) {
MCContext &context = streamer.getContext();
unsigned format = symbolEncoding & 0x0f;
switch (format) {
default: llvm_unreachable("Unknown Encoding");
case dwarf::DW_EH_PE_absptr:
case dwarf::DW_EH_PE_signed:
return context.getAsmInfo()->getCodePointerSize();
case dwarf::DW_EH_PE_udata2:
case dwarf::DW_EH_PE_sdata2:
return 2;
case dwarf::DW_EH_PE_udata4:
case dwarf::DW_EH_PE_sdata4:
return 4;
case dwarf::DW_EH_PE_udata8:
case dwarf::DW_EH_PE_sdata8:
return 8;
}
}
static void emitFDESymbol(MCObjectStreamer &streamer, const MCSymbol &symbol,
unsigned symbolEncoding, bool isEH) {
MCContext &context = streamer.getContext();
const MCAsmInfo *asmInfo = context.getAsmInfo();
const MCExpr *v = asmInfo->getExprForFDESymbol(&symbol,
symbolEncoding,
streamer);
unsigned size = getSizeForEncoding(streamer, symbolEncoding);
if (asmInfo->doDwarfFDESymbolsUseAbsDiff() && isEH)
emitAbsValue(streamer, v, size);
else
streamer.emitValue(v, size);
}
static void EmitPersonality(MCStreamer &streamer, const MCSymbol &symbol,
unsigned symbolEncoding) {
MCContext &context = streamer.getContext();
const MCAsmInfo *asmInfo = context.getAsmInfo();
const MCExpr *v = asmInfo->getExprForPersonalitySymbol(&symbol,
symbolEncoding,
streamer);
unsigned size = getSizeForEncoding(streamer, symbolEncoding);
streamer.emitValue(v, size);
}
namespace {
class FrameEmitterImpl {
int CFAOffset = 0;
int InitialCFAOffset = 0;
bool IsEH;
MCObjectStreamer &Streamer;
public:
FrameEmitterImpl(bool IsEH, MCObjectStreamer &Streamer)
: IsEH(IsEH), Streamer(Streamer) {}
/// Emit the unwind information in a compact way.
void EmitCompactUnwind(const MCDwarfFrameInfo &frame);
const MCSymbol &EmitCIE(const MCDwarfFrameInfo &F);
void EmitFDE(const MCSymbol &cieStart, const MCDwarfFrameInfo &frame,
bool LastInSection, const MCSymbol &SectionStart);
void emitCFIInstructions(ArrayRef<MCCFIInstruction> Instrs,
MCSymbol *BaseLabel);
void emitCFIInstruction(const MCCFIInstruction &Instr);
};
} // end anonymous namespace
static void emitEncodingByte(MCObjectStreamer &Streamer, unsigned Encoding) {
Streamer.emitInt8(Encoding);
}
void FrameEmitterImpl::emitCFIInstruction(const MCCFIInstruction &Instr) {
int dataAlignmentFactor = getDataAlignmentFactor(Streamer);
auto *MRI = Streamer.getContext().getRegisterInfo();
switch (Instr.getOperation()) {
case MCCFIInstruction::OpRegister: {
unsigned Reg1 = Instr.getRegister();
unsigned Reg2 = Instr.getRegister2();
if (!IsEH) {
Reg1 = MRI->getDwarfRegNumFromDwarfEHRegNum(Reg1);
Reg2 = MRI->getDwarfRegNumFromDwarfEHRegNum(Reg2);
}
Streamer.emitInt8(dwarf::DW_CFA_register);
Streamer.emitULEB128IntValue(Reg1);
Streamer.emitULEB128IntValue(Reg2);
return;
}
case MCCFIInstruction::OpWindowSave:
Streamer.emitInt8(dwarf::DW_CFA_GNU_window_save);
return;
case MCCFIInstruction::OpNegateRAState:
Streamer.emitInt8(dwarf::DW_CFA_AARCH64_negate_ra_state);
return;
case MCCFIInstruction::OpUndefined: {
unsigned Reg = Instr.getRegister();
Streamer.emitInt8(dwarf::DW_CFA_undefined);
Streamer.emitULEB128IntValue(Reg);
return;
}
case MCCFIInstruction::OpAdjustCfaOffset:
case MCCFIInstruction::OpDefCfaOffset: {
const bool IsRelative =
Instr.getOperation() == MCCFIInstruction::OpAdjustCfaOffset;
Streamer.emitInt8(dwarf::DW_CFA_def_cfa_offset);
if (IsRelative)
CFAOffset += Instr.getOffset();
else
CFAOffset = Instr.getOffset();
Streamer.emitULEB128IntValue(CFAOffset);
return;
}
case MCCFIInstruction::OpDefCfa: {
unsigned Reg = Instr.getRegister();
if (!IsEH)
Reg = MRI->getDwarfRegNumFromDwarfEHRegNum(Reg);
Streamer.emitInt8(dwarf::DW_CFA_def_cfa);
Streamer.emitULEB128IntValue(Reg);
CFAOffset = Instr.getOffset();
Streamer.emitULEB128IntValue(CFAOffset);
return;
}
case MCCFIInstruction::OpDefCfaRegister: {
unsigned Reg = Instr.getRegister();
if (!IsEH)
Reg = MRI->getDwarfRegNumFromDwarfEHRegNum(Reg);
Streamer.emitInt8(dwarf::DW_CFA_def_cfa_register);
Streamer.emitULEB128IntValue(Reg);
return;
}
// TODO: Implement `_sf` variants if/when they need to be emitted.
case MCCFIInstruction::OpLLVMDefAspaceCfa: {
unsigned Reg = Instr.getRegister();
if (!IsEH)
Reg = MRI->getDwarfRegNumFromDwarfEHRegNum(Reg);
Streamer.emitIntValue(dwarf::DW_CFA_LLVM_def_aspace_cfa, 1);
Streamer.emitULEB128IntValue(Reg);
CFAOffset = Instr.getOffset();
Streamer.emitULEB128IntValue(CFAOffset);
Streamer.emitULEB128IntValue(Instr.getAddressSpace());
return;
}
case MCCFIInstruction::OpOffset:
case MCCFIInstruction::OpRelOffset: {
const bool IsRelative =
Instr.getOperation() == MCCFIInstruction::OpRelOffset;
unsigned Reg = Instr.getRegister();
if (!IsEH)
Reg = MRI->getDwarfRegNumFromDwarfEHRegNum(Reg);
int Offset = Instr.getOffset();
if (IsRelative)
Offset -= CFAOffset;
Offset = Offset / dataAlignmentFactor;
if (Offset < 0) {
Streamer.emitInt8(dwarf::DW_CFA_offset_extended_sf);
Streamer.emitULEB128IntValue(Reg);
Streamer.emitSLEB128IntValue(Offset);
} else if (Reg < 64) {
Streamer.emitInt8(dwarf::DW_CFA_offset + Reg);
Streamer.emitULEB128IntValue(Offset);
} else {
Streamer.emitInt8(dwarf::DW_CFA_offset_extended);
Streamer.emitULEB128IntValue(Reg);
Streamer.emitULEB128IntValue(Offset);
}
return;
}
case MCCFIInstruction::OpRememberState:
Streamer.emitInt8(dwarf::DW_CFA_remember_state);
return;
case MCCFIInstruction::OpRestoreState:
Streamer.emitInt8(dwarf::DW_CFA_restore_state);
return;
case MCCFIInstruction::OpSameValue: {
unsigned Reg = Instr.getRegister();
Streamer.emitInt8(dwarf::DW_CFA_same_value);
Streamer.emitULEB128IntValue(Reg);
return;
}
case MCCFIInstruction::OpRestore: {
unsigned Reg = Instr.getRegister();
if (!IsEH)
Reg = MRI->getDwarfRegNumFromDwarfEHRegNum(Reg);
if (Reg < 64) {
Streamer.emitInt8(dwarf::DW_CFA_restore | Reg);
} else {
Streamer.emitInt8(dwarf::DW_CFA_restore_extended);
Streamer.emitULEB128IntValue(Reg);
}
return;
}
case MCCFIInstruction::OpGnuArgsSize:
Streamer.emitInt8(dwarf::DW_CFA_GNU_args_size);
Streamer.emitULEB128IntValue(Instr.getOffset());
return;
case MCCFIInstruction::OpEscape:
Streamer.emitBytes(Instr.getValues());
return;
}
llvm_unreachable("Unhandled case in switch");
}
/// Emit frame instructions to describe the layout of the frame.
void FrameEmitterImpl::emitCFIInstructions(ArrayRef<MCCFIInstruction> Instrs,
MCSymbol *BaseLabel) {
for (const MCCFIInstruction &Instr : Instrs) {
MCSymbol *Label = Instr.getLabel();
// Throw out move if the label is invalid.
if (Label && !Label->isDefined()) continue; // Not emitted, in dead code.
// Advance row if new location.
if (BaseLabel && Label) {
MCSymbol *ThisSym = Label;
if (ThisSym != BaseLabel) {
Streamer.emitDwarfAdvanceFrameAddr(BaseLabel, ThisSym);
BaseLabel = ThisSym;
}
}
emitCFIInstruction(Instr);
}
}
/// Emit the unwind information in a compact way.
void FrameEmitterImpl::EmitCompactUnwind(const MCDwarfFrameInfo &Frame) {
MCContext &Context = Streamer.getContext();
const MCObjectFileInfo *MOFI = Context.getObjectFileInfo();
// range-start range-length compact-unwind-enc personality-func lsda
// _foo LfooEnd-_foo 0x00000023 0 0
// _bar LbarEnd-_bar 0x00000025 __gxx_personality except_tab1
//
// .section __LD,__compact_unwind,regular,debug
//
// # compact unwind for _foo
// .quad _foo
// .set L1,LfooEnd-_foo
// .long L1
// .long 0x01010001
// .quad 0
// .quad 0
//
// # compact unwind for _bar
// .quad _bar
// .set L2,LbarEnd-_bar
// .long L2
// .long 0x01020011
// .quad __gxx_personality
// .quad except_tab1
uint32_t Encoding = Frame.CompactUnwindEncoding;
if (!Encoding) return;
bool DwarfEHFrameOnly = (Encoding == MOFI->getCompactUnwindDwarfEHFrameOnly());
// The encoding needs to know we have an LSDA.
if (!DwarfEHFrameOnly && Frame.Lsda)
Encoding |= 0x40000000;
// Range Start
unsigned FDEEncoding = MOFI->getFDEEncoding();
unsigned Size = getSizeForEncoding(Streamer, FDEEncoding);
Streamer.emitSymbolValue(Frame.Begin, Size);
// Range Length
const MCExpr *Range =
makeEndMinusStartExpr(Context, *Frame.Begin, *Frame.End, 0);
emitAbsValue(Streamer, Range, 4);
// Compact Encoding
Size = getSizeForEncoding(Streamer, dwarf::DW_EH_PE_udata4);
Streamer.emitIntValue(Encoding, Size);
// Personality Function
Size = getSizeForEncoding(Streamer, dwarf::DW_EH_PE_absptr);
if (!DwarfEHFrameOnly && Frame.Personality)
Streamer.emitSymbolValue(Frame.Personality, Size);
else
Streamer.emitIntValue(0, Size); // No personality fn
// LSDA
Size = getSizeForEncoding(Streamer, Frame.LsdaEncoding);
if (!DwarfEHFrameOnly && Frame.Lsda)
Streamer.emitSymbolValue(Frame.Lsda, Size);
else
Streamer.emitIntValue(0, Size); // No LSDA
}
static unsigned getCIEVersion(bool IsEH, unsigned DwarfVersion) {
if (IsEH)
return 1;
switch (DwarfVersion) {
case 2:
return 1;
case 3:
return 3;
case 4:
case 5:
return 4;
}
llvm_unreachable("Unknown version");
}
const MCSymbol &FrameEmitterImpl::EmitCIE(const MCDwarfFrameInfo &Frame) {
MCContext &context = Streamer.getContext();
const MCRegisterInfo *MRI = context.getRegisterInfo();
const MCObjectFileInfo *MOFI = context.getObjectFileInfo();
MCSymbol *sectionStart = context.createTempSymbol();
Streamer.emitLabel(sectionStart);
MCSymbol *sectionEnd = context.createTempSymbol();
dwarf::DwarfFormat Format = IsEH ? dwarf::DWARF32 : context.getDwarfFormat();
unsigned UnitLengthBytes = dwarf::getUnitLengthFieldByteSize(Format);
unsigned OffsetSize = dwarf::getDwarfOffsetByteSize(Format);
bool IsDwarf64 = Format == dwarf::DWARF64;
if (IsDwarf64)
// DWARF64 mark
Streamer.emitInt32(dwarf::DW_LENGTH_DWARF64);
// Length
const MCExpr *Length = makeEndMinusStartExpr(context, *sectionStart,
*sectionEnd, UnitLengthBytes);
emitAbsValue(Streamer, Length, OffsetSize);
// CIE ID
uint64_t CIE_ID =
IsEH ? 0 : (IsDwarf64 ? dwarf::DW64_CIE_ID : dwarf::DW_CIE_ID);
Streamer.emitIntValue(CIE_ID, OffsetSize);
// Version
uint8_t CIEVersion = getCIEVersion(IsEH, context.getDwarfVersion());
Streamer.emitInt8(CIEVersion);
if (IsEH) {
SmallString<8> Augmentation;
Augmentation += "z";
if (Frame.Personality)
Augmentation += "P";
if (Frame.Lsda)
Augmentation += "L";
Augmentation += "R";
if (Frame.IsSignalFrame)
Augmentation += "S";
if (Frame.IsBKeyFrame)
Augmentation += "B";
Streamer.emitBytes(Augmentation);
}
Streamer.emitInt8(0);
if (CIEVersion >= 4) {
// Address Size
Streamer.emitInt8(context.getAsmInfo()->getCodePointerSize());
// Segment Descriptor Size
Streamer.emitInt8(0);
}
// Code Alignment Factor
Streamer.emitULEB128IntValue(context.getAsmInfo()->getMinInstAlignment());
// Data Alignment Factor
Streamer.emitSLEB128IntValue(getDataAlignmentFactor(Streamer));
// Return Address Register
unsigned RAReg = Frame.RAReg;
if (RAReg == static_cast<unsigned>(INT_MAX))
RAReg = MRI->getDwarfRegNum(MRI->getRARegister(), IsEH);
if (CIEVersion == 1) {
assert(RAReg <= 255 &&
"DWARF 2 encodes return_address_register in one byte");
Streamer.emitInt8(RAReg);
} else {
Streamer.emitULEB128IntValue(RAReg);
}
// Augmentation Data Length (optional)
unsigned augmentationLength = 0;
if (IsEH) {
if (Frame.Personality) {
// Personality Encoding
augmentationLength += 1;
// Personality
augmentationLength +=
getSizeForEncoding(Streamer, Frame.PersonalityEncoding);
}
if (Frame.Lsda)
augmentationLength += 1;
// Encoding of the FDE pointers
augmentationLength += 1;
Streamer.emitULEB128IntValue(augmentationLength);
// Augmentation Data (optional)
if (Frame.Personality) {
// Personality Encoding
emitEncodingByte(Streamer, Frame.PersonalityEncoding);
// Personality
EmitPersonality(Streamer, *Frame.Personality, Frame.PersonalityEncoding);
}
if (Frame.Lsda)
emitEncodingByte(Streamer, Frame.LsdaEncoding);
// Encoding of the FDE pointers
emitEncodingByte(Streamer, MOFI->getFDEEncoding());
}
// Initial Instructions
const MCAsmInfo *MAI = context.getAsmInfo();
if (!Frame.IsSimple) {
const std::vector<MCCFIInstruction> &Instructions =
MAI->getInitialFrameState();
emitCFIInstructions(Instructions, nullptr);
}
InitialCFAOffset = CFAOffset;
// Padding
Streamer.emitValueToAlignment(IsEH ? 4 : MAI->getCodePointerSize());
Streamer.emitLabel(sectionEnd);
return *sectionStart;
}
void FrameEmitterImpl::EmitFDE(const MCSymbol &cieStart,
const MCDwarfFrameInfo &frame,
bool LastInSection,
const MCSymbol &SectionStart) {
MCContext &context = Streamer.getContext();
MCSymbol *fdeStart = context.createTempSymbol();
MCSymbol *fdeEnd = context.createTempSymbol();
const MCObjectFileInfo *MOFI = context.getObjectFileInfo();
CFAOffset = InitialCFAOffset;
dwarf::DwarfFormat Format = IsEH ? dwarf::DWARF32 : context.getDwarfFormat();
unsigned OffsetSize = dwarf::getDwarfOffsetByteSize(Format);
if (Format == dwarf::DWARF64)
// DWARF64 mark
Streamer.emitInt32(dwarf::DW_LENGTH_DWARF64);
// Length
const MCExpr *Length = makeEndMinusStartExpr(context, *fdeStart, *fdeEnd, 0);
emitAbsValue(Streamer, Length, OffsetSize);
Streamer.emitLabel(fdeStart);
// CIE Pointer
const MCAsmInfo *asmInfo = context.getAsmInfo();
if (IsEH) {
const MCExpr *offset =
makeEndMinusStartExpr(context, cieStart, *fdeStart, 0);
emitAbsValue(Streamer, offset, OffsetSize);
} else if (!asmInfo->doesDwarfUseRelocationsAcrossSections()) {
const MCExpr *offset =
makeEndMinusStartExpr(context, SectionStart, cieStart, 0);
emitAbsValue(Streamer, offset, OffsetSize);
} else {
Streamer.emitSymbolValue(&cieStart, OffsetSize,
asmInfo->needsDwarfSectionOffsetDirective());
}
// PC Begin
unsigned PCEncoding =
IsEH ? MOFI->getFDEEncoding() : (unsigned)dwarf::DW_EH_PE_absptr;
unsigned PCSize = getSizeForEncoding(Streamer, PCEncoding);
emitFDESymbol(Streamer, *frame.Begin, PCEncoding, IsEH);
// PC Range
const MCExpr *Range =
makeEndMinusStartExpr(context, *frame.Begin, *frame.End, 0);
emitAbsValue(Streamer, Range, PCSize);
if (IsEH) {
// Augmentation Data Length
unsigned augmentationLength = 0;
if (frame.Lsda)
augmentationLength += getSizeForEncoding(Streamer, frame.LsdaEncoding);
Streamer.emitULEB128IntValue(augmentationLength);
// Augmentation Data
if (frame.Lsda)
emitFDESymbol(Streamer, *frame.Lsda, frame.LsdaEncoding, true);
}
// Call Frame Instructions
emitCFIInstructions(frame.Instructions, frame.Begin);
// Padding
// The size of a .eh_frame section has to be a multiple of the alignment
// since a null CIE is interpreted as the end. Old systems overaligned
// .eh_frame, so we do too and account for it in the last FDE.
unsigned Align = LastInSection ? asmInfo->getCodePointerSize() : PCSize;
Streamer.emitValueToAlignment(Align);
Streamer.emitLabel(fdeEnd);
}
namespace {
struct CIEKey {
static const CIEKey getEmptyKey() {
return CIEKey(nullptr, 0, -1, false, false, static_cast<unsigned>(INT_MAX),
false);
}
static const CIEKey getTombstoneKey() {
return CIEKey(nullptr, -1, 0, false, false, static_cast<unsigned>(INT_MAX),
false);
}
CIEKey(const MCSymbol *Personality, unsigned PersonalityEncoding,
unsigned LSDAEncoding, bool IsSignalFrame, bool IsSimple,
unsigned RAReg, bool IsBKeyFrame)
: Personality(Personality), PersonalityEncoding(PersonalityEncoding),
LsdaEncoding(LSDAEncoding), IsSignalFrame(IsSignalFrame),
IsSimple(IsSimple), RAReg(RAReg), IsBKeyFrame(IsBKeyFrame) {}
explicit CIEKey(const MCDwarfFrameInfo &Frame)
: Personality(Frame.Personality),
PersonalityEncoding(Frame.PersonalityEncoding),
LsdaEncoding(Frame.LsdaEncoding), IsSignalFrame(Frame.IsSignalFrame),
IsSimple(Frame.IsSimple), RAReg(Frame.RAReg),
IsBKeyFrame(Frame.IsBKeyFrame) {}
StringRef PersonalityName() const {
if (!Personality)
return StringRef();
return Personality->getName();
}
bool operator<(const CIEKey &Other) const {
return std::make_tuple(PersonalityName(), PersonalityEncoding, LsdaEncoding,
IsSignalFrame, IsSimple, RAReg) <
std::make_tuple(Other.PersonalityName(), Other.PersonalityEncoding,
Other.LsdaEncoding, Other.IsSignalFrame,
Other.IsSimple, Other.RAReg);
}
const MCSymbol *Personality;
unsigned PersonalityEncoding;
unsigned LsdaEncoding;
bool IsSignalFrame;
bool IsSimple;
unsigned RAReg;
bool IsBKeyFrame;
};
} // end anonymous namespace
namespace llvm {
template <> struct DenseMapInfo<CIEKey> {
static CIEKey getEmptyKey() { return CIEKey::getEmptyKey(); }
static CIEKey getTombstoneKey() { return CIEKey::getTombstoneKey(); }
static unsigned getHashValue(const CIEKey &Key) {
return static_cast<unsigned>(hash_combine(
Key.Personality, Key.PersonalityEncoding, Key.LsdaEncoding,
Key.IsSignalFrame, Key.IsSimple, Key.RAReg, Key.IsBKeyFrame));
}
static bool isEqual(const CIEKey &LHS, const CIEKey &RHS) {
return LHS.Personality == RHS.Personality &&
LHS.PersonalityEncoding == RHS.PersonalityEncoding &&
LHS.LsdaEncoding == RHS.LsdaEncoding &&
LHS.IsSignalFrame == RHS.IsSignalFrame &&
LHS.IsSimple == RHS.IsSimple && LHS.RAReg == RHS.RAReg &&
LHS.IsBKeyFrame == RHS.IsBKeyFrame;
}
};
} // end namespace llvm
void MCDwarfFrameEmitter::Emit(MCObjectStreamer &Streamer, MCAsmBackend *MAB,
bool IsEH) {
Streamer.generateCompactUnwindEncodings(MAB);
MCContext &Context = Streamer.getContext();
const MCObjectFileInfo *MOFI = Context.getObjectFileInfo();
const MCAsmInfo *AsmInfo = Context.getAsmInfo();
FrameEmitterImpl Emitter(IsEH, Streamer);
ArrayRef<MCDwarfFrameInfo> FrameArray = Streamer.getDwarfFrameInfos();
// Emit the compact unwind info if available.
bool NeedsEHFrameSection = !MOFI->getSupportsCompactUnwindWithoutEHFrame();
if (IsEH && MOFI->getCompactUnwindSection()) {
bool SectionEmitted = false;
for (const MCDwarfFrameInfo &Frame : FrameArray) {
if (Frame.CompactUnwindEncoding == 0) continue;
if (!SectionEmitted) {
Streamer.SwitchSection(MOFI->getCompactUnwindSection());
Streamer.emitValueToAlignment(AsmInfo->getCodePointerSize());
SectionEmitted = true;
}
NeedsEHFrameSection |=
Frame.CompactUnwindEncoding ==
MOFI->getCompactUnwindDwarfEHFrameOnly();
Emitter.EmitCompactUnwind(Frame);
}
}
if (!NeedsEHFrameSection) return;
MCSection &Section =
IsEH ? *const_cast<MCObjectFileInfo *>(MOFI)->getEHFrameSection()
: *MOFI->getDwarfFrameSection();
Streamer.SwitchSection(&Section);
MCSymbol *SectionStart = Context.createTempSymbol();
Streamer.emitLabel(SectionStart);
DenseMap<CIEKey, const MCSymbol *> CIEStarts;
const MCSymbol *DummyDebugKey = nullptr;
bool CanOmitDwarf = MOFI->getOmitDwarfIfHaveCompactUnwind();
// Sort the FDEs by their corresponding CIE before we emit them.
// This isn't technically necessary according to the DWARF standard,
// but the Android libunwindstack rejects eh_frame sections where
// an FDE refers to a CIE other than the closest previous CIE.
std::vector<MCDwarfFrameInfo> FrameArrayX(FrameArray.begin(), FrameArray.end());
llvm::stable_sort(FrameArrayX,
[](const MCDwarfFrameInfo &X, const MCDwarfFrameInfo &Y) {
return CIEKey(X) < CIEKey(Y);
});
for (auto I = FrameArrayX.begin(), E = FrameArrayX.end(); I != E;) {
const MCDwarfFrameInfo &Frame = *I;
++I;
if (CanOmitDwarf && Frame.CompactUnwindEncoding !=
MOFI->getCompactUnwindDwarfEHFrameOnly())
// Don't generate an EH frame if we don't need one. I.e., it's taken care
// of by the compact unwind encoding.
continue;
CIEKey Key(Frame);
const MCSymbol *&CIEStart = IsEH ? CIEStarts[Key] : DummyDebugKey;
if (!CIEStart)
CIEStart = &Emitter.EmitCIE(Frame);
Emitter.EmitFDE(*CIEStart, Frame, I == E, *SectionStart);
}
}
void MCDwarfFrameEmitter::EmitAdvanceLoc(MCObjectStreamer &Streamer,
uint64_t AddrDelta) {
MCContext &Context = Streamer.getContext();
SmallString<256> Tmp;
raw_svector_ostream OS(Tmp);
MCDwarfFrameEmitter::EncodeAdvanceLoc(Context, AddrDelta, OS);
Streamer.emitBytes(OS.str());
}
void MCDwarfFrameEmitter::EncodeAdvanceLoc(MCContext &Context,
uint64_t AddrDelta,
raw_ostream &OS) {
// Scale the address delta by the minimum instruction length.
AddrDelta = ScaleAddrDelta(Context, AddrDelta);
if (AddrDelta == 0)
return;
support::endianness E =
Context.getAsmInfo()->isLittleEndian() ? support::little : support::big;
if (isUIntN(6, AddrDelta)) {
uint8_t Opcode = dwarf::DW_CFA_advance_loc | AddrDelta;
OS << Opcode;
} else if (isUInt<8>(AddrDelta)) {
OS << uint8_t(dwarf::DW_CFA_advance_loc1);
OS << uint8_t(AddrDelta);
} else if (isUInt<16>(AddrDelta)) {
OS << uint8_t(dwarf::DW_CFA_advance_loc2);
support::endian::write<uint16_t>(OS, AddrDelta, E);
} else {
assert(isUInt<32>(AddrDelta));
OS << uint8_t(dwarf::DW_CFA_advance_loc4);
support::endian::write<uint32_t>(OS, AddrDelta, E);
}
}
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