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llvm-mirror/lib/MC/MCObjectStreamer.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

879 lines
32 KiB
C++

//===- lib/MC/MCObjectStreamer.cpp - Object File MCStreamer Interface -----===//
//
// 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/MCObjectStreamer.h"
#include "llvm/ADT/STLExtras.h"
#include "llvm/MC/MCAsmBackend.h"
#include "llvm/MC/MCAsmInfo.h"
#include "llvm/MC/MCAssembler.h"
#include "llvm/MC/MCCodeEmitter.h"
#include "llvm/MC/MCCodeView.h"
#include "llvm/MC/MCContext.h"
#include "llvm/MC/MCDwarf.h"
#include "llvm/MC/MCExpr.h"
#include "llvm/MC/MCObjectFileInfo.h"
#include "llvm/MC/MCObjectWriter.h"
#include "llvm/MC/MCSection.h"
#include "llvm/MC/MCSymbol.h"
#include "llvm/MC/MCValue.h"
#include "llvm/Support/ErrorHandling.h"
#include "llvm/Support/SourceMgr.h"
using namespace llvm;
MCObjectStreamer::MCObjectStreamer(MCContext &Context,
std::unique_ptr<MCAsmBackend> TAB,
std::unique_ptr<MCObjectWriter> OW,
std::unique_ptr<MCCodeEmitter> Emitter)
: MCStreamer(Context),
Assembler(std::make_unique<MCAssembler>(
Context, std::move(TAB), std::move(Emitter), std::move(OW))),
EmitEHFrame(true), EmitDebugFrame(false) {
if (Assembler->getBackendPtr())
setAllowAutoPadding(Assembler->getBackend().allowAutoPadding());
}
MCObjectStreamer::~MCObjectStreamer() {}
// AssemblerPtr is used for evaluation of expressions and causes
// difference between asm and object outputs. Return nullptr to in
// inline asm mode to limit divergence to assembly inputs.
MCAssembler *MCObjectStreamer::getAssemblerPtr() {
if (getUseAssemblerInfoForParsing())
return Assembler.get();
return nullptr;
}
void MCObjectStreamer::addPendingLabel(MCSymbol* S) {
MCSection *CurSection = getCurrentSectionOnly();
if (CurSection) {
// Register labels that have not yet been assigned to a Section.
if (!PendingLabels.empty()) {
for (MCSymbol* Sym : PendingLabels)
CurSection->addPendingLabel(Sym);
PendingLabels.clear();
}
// Add this label to the current Section / Subsection.
CurSection->addPendingLabel(S, CurSubsectionIdx);
// Add this Section to the list of PendingLabelSections.
PendingLabelSections.insert(CurSection);
} else
// There is no Section / Subsection for this label yet.
PendingLabels.push_back(S);
}
void MCObjectStreamer::flushPendingLabels(MCFragment *F, uint64_t FOffset) {
MCSection *CurSection = getCurrentSectionOnly();
if (!CurSection) {
assert(PendingLabels.empty());
return;
}
// Register labels that have not yet been assigned to a Section.
if (!PendingLabels.empty()) {
for (MCSymbol* Sym : PendingLabels)
CurSection->addPendingLabel(Sym, CurSubsectionIdx);
PendingLabels.clear();
}
// Associate a fragment with this label, either the supplied fragment
// or an empty data fragment.
if (F)
CurSection->flushPendingLabels(F, FOffset, CurSubsectionIdx);
else
CurSection->flushPendingLabels(nullptr, 0, CurSubsectionIdx);
}
void MCObjectStreamer::flushPendingLabels() {
// Register labels that have not yet been assigned to a Section.
if (!PendingLabels.empty()) {
MCSection *CurSection = getCurrentSectionOnly();
assert(CurSection);
for (MCSymbol* Sym : PendingLabels)
CurSection->addPendingLabel(Sym, CurSubsectionIdx);
PendingLabels.clear();
}
// Assign an empty data fragment to all remaining pending labels.
for (MCSection* Section : PendingLabelSections)
Section->flushPendingLabels();
}
// When fixup's offset is a forward declared label, e.g.:
//
// .reloc 1f, R_MIPS_JALR, foo
// 1: nop
//
// postpone adding it to Fixups vector until the label is defined and its offset
// is known.
void MCObjectStreamer::resolvePendingFixups() {
for (PendingMCFixup &PendingFixup : PendingFixups) {
if (!PendingFixup.Sym || PendingFixup.Sym->isUndefined ()) {
getContext().reportError(PendingFixup.Fixup.getLoc(),
"unresolved relocation offset");
continue;
}
flushPendingLabels(PendingFixup.DF, PendingFixup.DF->getContents().size());
PendingFixup.Fixup.setOffset(PendingFixup.Sym->getOffset());
PendingFixup.DF->getFixups().push_back(PendingFixup.Fixup);
}
PendingFixups.clear();
}
// As a compile-time optimization, avoid allocating and evaluating an MCExpr
// tree for (Hi - Lo) when Hi and Lo are offsets into the same fragment.
static Optional<uint64_t> absoluteSymbolDiff(const MCSymbol *Hi,
const MCSymbol *Lo) {
assert(Hi && Lo);
if (!Hi->getFragment() || Hi->getFragment() != Lo->getFragment() ||
Hi->isVariable() || Lo->isVariable())
return None;
return Hi->getOffset() - Lo->getOffset();
}
void MCObjectStreamer::emitAbsoluteSymbolDiff(const MCSymbol *Hi,
const MCSymbol *Lo,
unsigned Size) {
if (!getAssembler().getContext().getTargetTriple().isRISCV())
if (Optional<uint64_t> Diff = absoluteSymbolDiff(Hi, Lo))
return emitIntValue(*Diff, Size);
MCStreamer::emitAbsoluteSymbolDiff(Hi, Lo, Size);
}
void MCObjectStreamer::emitAbsoluteSymbolDiffAsULEB128(const MCSymbol *Hi,
const MCSymbol *Lo) {
if (!getAssembler().getContext().getTargetTriple().isRISCV())
if (Optional<uint64_t> Diff = absoluteSymbolDiff(Hi, Lo))
return emitULEB128IntValue(*Diff);
MCStreamer::emitAbsoluteSymbolDiffAsULEB128(Hi, Lo);
}
void MCObjectStreamer::reset() {
if (Assembler)
Assembler->reset();
CurInsertionPoint = MCSection::iterator();
EmitEHFrame = true;
EmitDebugFrame = false;
PendingLabels.clear();
PendingLabelSections.clear();
MCStreamer::reset();
}
void MCObjectStreamer::emitFrames(MCAsmBackend *MAB) {
if (!getNumFrameInfos())
return;
if (EmitEHFrame)
MCDwarfFrameEmitter::Emit(*this, MAB, true);
if (EmitDebugFrame)
MCDwarfFrameEmitter::Emit(*this, MAB, false);
}
MCFragment *MCObjectStreamer::getCurrentFragment() const {
assert(getCurrentSectionOnly() && "No current section!");
if (CurInsertionPoint != getCurrentSectionOnly()->getFragmentList().begin())
return &*std::prev(CurInsertionPoint);
return nullptr;
}
static bool canReuseDataFragment(const MCDataFragment &F,
const MCAssembler &Assembler,
const MCSubtargetInfo *STI) {
if (!F.hasInstructions())
return true;
// When bundling is enabled, we don't want to add data to a fragment that
// already has instructions (see MCELFStreamer::emitInstToData for details)
if (Assembler.isBundlingEnabled())
return Assembler.getRelaxAll();
// If the subtarget is changed mid fragment we start a new fragment to record
// the new STI.
return !STI || F.getSubtargetInfo() == STI;
}
MCDataFragment *
MCObjectStreamer::getOrCreateDataFragment(const MCSubtargetInfo *STI) {
MCDataFragment *F = dyn_cast_or_null<MCDataFragment>(getCurrentFragment());
if (!F || !canReuseDataFragment(*F, *Assembler, STI)) {
F = new MCDataFragment();
insert(F);
}
return F;
}
void MCObjectStreamer::visitUsedSymbol(const MCSymbol &Sym) {
Assembler->registerSymbol(Sym);
}
void MCObjectStreamer::emitCFISections(bool EH, bool Debug) {
MCStreamer::emitCFISections(EH, Debug);
EmitEHFrame = EH;
EmitDebugFrame = Debug;
}
void MCObjectStreamer::emitValueImpl(const MCExpr *Value, unsigned Size,
SMLoc Loc) {
MCStreamer::emitValueImpl(Value, Size, Loc);
MCDataFragment *DF = getOrCreateDataFragment();
flushPendingLabels(DF, DF->getContents().size());
MCDwarfLineEntry::make(this, getCurrentSectionOnly());
// Avoid fixups when possible.
int64_t AbsValue;
if (Value->evaluateAsAbsolute(AbsValue, getAssemblerPtr())) {
if (!isUIntN(8 * Size, AbsValue) && !isIntN(8 * Size, AbsValue)) {
getContext().reportError(
Loc, "value evaluated as " + Twine(AbsValue) + " is out of range.");
return;
}
emitIntValue(AbsValue, Size);
return;
}
DF->getFixups().push_back(
MCFixup::create(DF->getContents().size(), Value,
MCFixup::getKindForSize(Size, false), Loc));
DF->getContents().resize(DF->getContents().size() + Size, 0);
}
MCSymbol *MCObjectStreamer::emitCFILabel() {
MCSymbol *Label = getContext().createTempSymbol("cfi");
emitLabel(Label);
return Label;
}
void MCObjectStreamer::emitCFIStartProcImpl(MCDwarfFrameInfo &Frame) {
// We need to create a local symbol to avoid relocations.
Frame.Begin = getContext().createTempSymbol();
emitLabel(Frame.Begin);
}
void MCObjectStreamer::emitCFIEndProcImpl(MCDwarfFrameInfo &Frame) {
Frame.End = getContext().createTempSymbol();
emitLabel(Frame.End);
}
void MCObjectStreamer::emitLabel(MCSymbol *Symbol, SMLoc Loc) {
MCStreamer::emitLabel(Symbol, Loc);
getAssembler().registerSymbol(*Symbol);
// If there is a current fragment, mark the symbol as pointing into it.
// Otherwise queue the label and set its fragment pointer when we emit the
// next fragment.
auto *F = dyn_cast_or_null<MCDataFragment>(getCurrentFragment());
if (F && !(getAssembler().isBundlingEnabled() &&
getAssembler().getRelaxAll())) {
Symbol->setFragment(F);
Symbol->setOffset(F->getContents().size());
} else {
// Assign all pending labels to offset 0 within the dummy "pending"
// fragment. (They will all be reassigned to a real fragment in
// flushPendingLabels())
Symbol->setOffset(0);
addPendingLabel(Symbol);
}
}
// Emit a label at a previously emitted fragment/offset position. This must be
// within the currently-active section.
void MCObjectStreamer::emitLabelAtPos(MCSymbol *Symbol, SMLoc Loc,
MCFragment *F, uint64_t Offset) {
assert(F->getParent() == getCurrentSectionOnly());
MCStreamer::emitLabel(Symbol, Loc);
getAssembler().registerSymbol(*Symbol);
auto *DF = dyn_cast_or_null<MCDataFragment>(F);
Symbol->setOffset(Offset);
if (DF) {
Symbol->setFragment(F);
} else {
assert(isa<MCDummyFragment>(F) &&
"F must either be an MCDataFragment or the pending MCDummyFragment");
assert(Offset == 0);
addPendingLabel(Symbol);
}
}
void MCObjectStreamer::emitULEB128Value(const MCExpr *Value) {
int64_t IntValue;
if (Value->evaluateAsAbsolute(IntValue, getAssemblerPtr())) {
emitULEB128IntValue(IntValue);
return;
}
insert(new MCLEBFragment(*Value, false));
}
void MCObjectStreamer::emitSLEB128Value(const MCExpr *Value) {
int64_t IntValue;
if (Value->evaluateAsAbsolute(IntValue, getAssemblerPtr())) {
emitSLEB128IntValue(IntValue);
return;
}
insert(new MCLEBFragment(*Value, true));
}
void MCObjectStreamer::emitWeakReference(MCSymbol *Alias,
const MCSymbol *Symbol) {
report_fatal_error("This file format doesn't support weak aliases.");
}
void MCObjectStreamer::changeSection(MCSection *Section,
const MCExpr *Subsection) {
changeSectionImpl(Section, Subsection);
}
bool MCObjectStreamer::changeSectionImpl(MCSection *Section,
const MCExpr *Subsection) {
assert(Section && "Cannot switch to a null section!");
getContext().clearDwarfLocSeen();
bool Created = getAssembler().registerSection(*Section);
int64_t IntSubsection = 0;
if (Subsection &&
!Subsection->evaluateAsAbsolute(IntSubsection, getAssemblerPtr()))
report_fatal_error("Cannot evaluate subsection number");
if (IntSubsection < 0 || IntSubsection > 8192)
report_fatal_error("Subsection number out of range");
CurSubsectionIdx = unsigned(IntSubsection);
CurInsertionPoint =
Section->getSubsectionInsertionPoint(CurSubsectionIdx);
return Created;
}
void MCObjectStreamer::emitAssignment(MCSymbol *Symbol, const MCExpr *Value) {
getAssembler().registerSymbol(*Symbol);
MCStreamer::emitAssignment(Symbol, Value);
}
bool MCObjectStreamer::mayHaveInstructions(MCSection &Sec) const {
return Sec.hasInstructions();
}
void MCObjectStreamer::emitInstruction(const MCInst &Inst,
const MCSubtargetInfo &STI) {
const MCSection &Sec = *getCurrentSectionOnly();
if (Sec.isVirtualSection()) {
getContext().reportError(Inst.getLoc(), Twine(Sec.getVirtualSectionKind()) +
" section '" + Sec.getName() +
"' cannot have instructions");
return;
}
getAssembler().getBackend().emitInstructionBegin(*this, Inst);
emitInstructionImpl(Inst, STI);
getAssembler().getBackend().emitInstructionEnd(*this, Inst);
}
void MCObjectStreamer::emitInstructionImpl(const MCInst &Inst,
const MCSubtargetInfo &STI) {
MCStreamer::emitInstruction(Inst, STI);
MCSection *Sec = getCurrentSectionOnly();
Sec->setHasInstructions(true);
// Now that a machine instruction has been assembled into this section, make
// a line entry for any .loc directive that has been seen.
MCDwarfLineEntry::make(this, getCurrentSectionOnly());
// If this instruction doesn't need relaxation, just emit it as data.
MCAssembler &Assembler = getAssembler();
MCAsmBackend &Backend = Assembler.getBackend();
if (!(Backend.mayNeedRelaxation(Inst, STI) ||
Backend.allowEnhancedRelaxation())) {
emitInstToData(Inst, STI);
return;
}
// Otherwise, relax and emit it as data if either:
// - The RelaxAll flag was passed
// - Bundling is enabled and this instruction is inside a bundle-locked
// group. We want to emit all such instructions into the same data
// fragment.
if (Assembler.getRelaxAll() ||
(Assembler.isBundlingEnabled() && Sec->isBundleLocked())) {
MCInst Relaxed = Inst;
while (Backend.mayNeedRelaxation(Relaxed, STI))
Backend.relaxInstruction(Relaxed, STI);
emitInstToData(Relaxed, STI);
return;
}
// Otherwise emit to a separate fragment.
emitInstToFragment(Inst, STI);
}
void MCObjectStreamer::emitInstToFragment(const MCInst &Inst,
const MCSubtargetInfo &STI) {
if (getAssembler().getRelaxAll() && getAssembler().isBundlingEnabled())
llvm_unreachable("All instructions should have already been relaxed");
// Always create a new, separate fragment here, because its size can change
// during relaxation.
MCRelaxableFragment *IF = new MCRelaxableFragment(Inst, STI);
insert(IF);
SmallString<128> Code;
raw_svector_ostream VecOS(Code);
getAssembler().getEmitter().encodeInstruction(Inst, VecOS, IF->getFixups(),
STI);
IF->getContents().append(Code.begin(), Code.end());
}
#ifndef NDEBUG
static const char *const BundlingNotImplementedMsg =
"Aligned bundling is not implemented for this object format";
#endif
void MCObjectStreamer::emitBundleAlignMode(unsigned AlignPow2) {
llvm_unreachable(BundlingNotImplementedMsg);
}
void MCObjectStreamer::emitBundleLock(bool AlignToEnd) {
llvm_unreachable(BundlingNotImplementedMsg);
}
void MCObjectStreamer::emitBundleUnlock() {
llvm_unreachable(BundlingNotImplementedMsg);
}
void MCObjectStreamer::emitDwarfLocDirective(unsigned FileNo, unsigned Line,
unsigned Column, unsigned Flags,
unsigned Isa,
unsigned Discriminator,
StringRef FileName) {
// In case we see two .loc directives in a row, make sure the
// first one gets a line entry.
MCDwarfLineEntry::make(this, getCurrentSectionOnly());
this->MCStreamer::emitDwarfLocDirective(FileNo, Line, Column, Flags, Isa,
Discriminator, FileName);
}
static const MCExpr *buildSymbolDiff(MCObjectStreamer &OS, const MCSymbol *A,
const MCSymbol *B) {
MCContext &Context = OS.getContext();
MCSymbolRefExpr::VariantKind Variant = MCSymbolRefExpr::VK_None;
const MCExpr *ARef = MCSymbolRefExpr::create(A, Variant, Context);
const MCExpr *BRef = MCSymbolRefExpr::create(B, Variant, Context);
const MCExpr *AddrDelta =
MCBinaryExpr::create(MCBinaryExpr::Sub, ARef, BRef, Context);
return AddrDelta;
}
static void emitDwarfSetLineAddr(MCObjectStreamer &OS,
MCDwarfLineTableParams Params,
int64_t LineDelta, const MCSymbol *Label,
int PointerSize) {
// emit the sequence to set the address
OS.emitIntValue(dwarf::DW_LNS_extended_op, 1);
OS.emitULEB128IntValue(PointerSize + 1);
OS.emitIntValue(dwarf::DW_LNE_set_address, 1);
OS.emitSymbolValue(Label, PointerSize);
// emit the sequence for the LineDelta (from 1) and a zero address delta.
MCDwarfLineAddr::Emit(&OS, Params, LineDelta, 0);
}
void MCObjectStreamer::emitDwarfAdvanceLineAddr(int64_t LineDelta,
const MCSymbol *LastLabel,
const MCSymbol *Label,
unsigned PointerSize) {
if (!LastLabel) {
emitDwarfSetLineAddr(*this, Assembler->getDWARFLinetableParams(), LineDelta,
Label, PointerSize);
return;
}
const MCExpr *AddrDelta = buildSymbolDiff(*this, Label, LastLabel);
int64_t Res;
if (AddrDelta->evaluateAsAbsolute(Res, getAssemblerPtr())) {
MCDwarfLineAddr::Emit(this, Assembler->getDWARFLinetableParams(), LineDelta,
Res);
return;
}
insert(new MCDwarfLineAddrFragment(LineDelta, *AddrDelta));
}
void MCObjectStreamer::emitDwarfLineEndEntry(MCSection *Section,
MCSymbol *LastLabel) {
// Emit a DW_LNE_end_sequence for the end of the section.
// Use the section end label to compute the address delta and use INT64_MAX
// as the line delta which is the signal that this is actually a
// DW_LNE_end_sequence.
MCSymbol *SectionEnd = endSection(Section);
// Switch back the dwarf line section, in case endSection had to switch the
// section.
MCContext &Ctx = getContext();
SwitchSection(Ctx.getObjectFileInfo()->getDwarfLineSection());
const MCAsmInfo *AsmInfo = Ctx.getAsmInfo();
emitDwarfAdvanceLineAddr(INT64_MAX, LastLabel, SectionEnd,
AsmInfo->getCodePointerSize());
}
void MCObjectStreamer::emitDwarfAdvanceFrameAddr(const MCSymbol *LastLabel,
const MCSymbol *Label) {
const MCExpr *AddrDelta = buildSymbolDiff(*this, Label, LastLabel);
int64_t Res;
if (AddrDelta->evaluateAsAbsolute(Res, getAssemblerPtr())) {
MCDwarfFrameEmitter::EmitAdvanceLoc(*this, Res);
return;
}
insert(new MCDwarfCallFrameFragment(*AddrDelta));
}
void MCObjectStreamer::emitCVLocDirective(unsigned FunctionId, unsigned FileNo,
unsigned Line, unsigned Column,
bool PrologueEnd, bool IsStmt,
StringRef FileName, SMLoc Loc) {
// Validate the directive.
if (!checkCVLocSection(FunctionId, FileNo, Loc))
return;
// Emit a label at the current position and record it in the CodeViewContext.
MCSymbol *LineSym = getContext().createTempSymbol();
emitLabel(LineSym);
getContext().getCVContext().recordCVLoc(getContext(), LineSym, FunctionId,
FileNo, Line, Column, PrologueEnd,
IsStmt);
}
void MCObjectStreamer::emitCVLinetableDirective(unsigned FunctionId,
const MCSymbol *Begin,
const MCSymbol *End) {
getContext().getCVContext().emitLineTableForFunction(*this, FunctionId, Begin,
End);
this->MCStreamer::emitCVLinetableDirective(FunctionId, Begin, End);
}
void MCObjectStreamer::emitCVInlineLinetableDirective(
unsigned PrimaryFunctionId, unsigned SourceFileId, unsigned SourceLineNum,
const MCSymbol *FnStartSym, const MCSymbol *FnEndSym) {
getContext().getCVContext().emitInlineLineTableForFunction(
*this, PrimaryFunctionId, SourceFileId, SourceLineNum, FnStartSym,
FnEndSym);
this->MCStreamer::emitCVInlineLinetableDirective(
PrimaryFunctionId, SourceFileId, SourceLineNum, FnStartSym, FnEndSym);
}
void MCObjectStreamer::emitCVDefRangeDirective(
ArrayRef<std::pair<const MCSymbol *, const MCSymbol *>> Ranges,
StringRef FixedSizePortion) {
MCFragment *Frag =
getContext().getCVContext().emitDefRange(*this, Ranges, FixedSizePortion);
// Attach labels that were pending before we created the defrange fragment to
// the beginning of the new fragment.
flushPendingLabels(Frag, 0);
this->MCStreamer::emitCVDefRangeDirective(Ranges, FixedSizePortion);
}
void MCObjectStreamer::emitCVStringTableDirective() {
getContext().getCVContext().emitStringTable(*this);
}
void MCObjectStreamer::emitCVFileChecksumsDirective() {
getContext().getCVContext().emitFileChecksums(*this);
}
void MCObjectStreamer::emitCVFileChecksumOffsetDirective(unsigned FileNo) {
getContext().getCVContext().emitFileChecksumOffset(*this, FileNo);
}
void MCObjectStreamer::emitBytes(StringRef Data) {
MCDwarfLineEntry::make(this, getCurrentSectionOnly());
MCDataFragment *DF = getOrCreateDataFragment();
flushPendingLabels(DF, DF->getContents().size());
DF->getContents().append(Data.begin(), Data.end());
}
void MCObjectStreamer::emitValueToAlignment(unsigned ByteAlignment,
int64_t Value,
unsigned ValueSize,
unsigned MaxBytesToEmit) {
if (MaxBytesToEmit == 0)
MaxBytesToEmit = ByteAlignment;
insert(new MCAlignFragment(ByteAlignment, Value, ValueSize, MaxBytesToEmit));
// Update the maximum alignment on the current section if necessary.
MCSection *CurSec = getCurrentSectionOnly();
if (ByteAlignment > CurSec->getAlignment())
CurSec->setAlignment(Align(ByteAlignment));
}
void MCObjectStreamer::emitCodeAlignment(unsigned ByteAlignment,
unsigned MaxBytesToEmit) {
emitValueToAlignment(ByteAlignment, 0, 1, MaxBytesToEmit);
cast<MCAlignFragment>(getCurrentFragment())->setEmitNops(true);
}
void MCObjectStreamer::emitValueToOffset(const MCExpr *Offset,
unsigned char Value,
SMLoc Loc) {
insert(new MCOrgFragment(*Offset, Value, Loc));
}
// Associate DTPRel32 fixup with data and resize data area
void MCObjectStreamer::emitDTPRel32Value(const MCExpr *Value) {
MCDataFragment *DF = getOrCreateDataFragment();
flushPendingLabels(DF, DF->getContents().size());
DF->getFixups().push_back(MCFixup::create(DF->getContents().size(),
Value, FK_DTPRel_4));
DF->getContents().resize(DF->getContents().size() + 4, 0);
}
// Associate DTPRel64 fixup with data and resize data area
void MCObjectStreamer::emitDTPRel64Value(const MCExpr *Value) {
MCDataFragment *DF = getOrCreateDataFragment();
flushPendingLabels(DF, DF->getContents().size());
DF->getFixups().push_back(MCFixup::create(DF->getContents().size(),
Value, FK_DTPRel_8));
DF->getContents().resize(DF->getContents().size() + 8, 0);
}
// Associate TPRel32 fixup with data and resize data area
void MCObjectStreamer::emitTPRel32Value(const MCExpr *Value) {
MCDataFragment *DF = getOrCreateDataFragment();
flushPendingLabels(DF, DF->getContents().size());
DF->getFixups().push_back(MCFixup::create(DF->getContents().size(),
Value, FK_TPRel_4));
DF->getContents().resize(DF->getContents().size() + 4, 0);
}
// Associate TPRel64 fixup with data and resize data area
void MCObjectStreamer::emitTPRel64Value(const MCExpr *Value) {
MCDataFragment *DF = getOrCreateDataFragment();
flushPendingLabels(DF, DF->getContents().size());
DF->getFixups().push_back(MCFixup::create(DF->getContents().size(),
Value, FK_TPRel_8));
DF->getContents().resize(DF->getContents().size() + 8, 0);
}
// Associate GPRel32 fixup with data and resize data area
void MCObjectStreamer::emitGPRel32Value(const MCExpr *Value) {
MCDataFragment *DF = getOrCreateDataFragment();
flushPendingLabels(DF, DF->getContents().size());
DF->getFixups().push_back(
MCFixup::create(DF->getContents().size(), Value, FK_GPRel_4));
DF->getContents().resize(DF->getContents().size() + 4, 0);
}
// Associate GPRel64 fixup with data and resize data area
void MCObjectStreamer::emitGPRel64Value(const MCExpr *Value) {
MCDataFragment *DF = getOrCreateDataFragment();
flushPendingLabels(DF, DF->getContents().size());
DF->getFixups().push_back(
MCFixup::create(DF->getContents().size(), Value, FK_GPRel_4));
DF->getContents().resize(DF->getContents().size() + 8, 0);
}
static Optional<std::pair<bool, std::string>>
getOffsetAndDataFragment(const MCSymbol &Symbol, uint32_t &RelocOffset,
MCDataFragment *&DF) {
if (Symbol.isVariable()) {
const MCExpr *SymbolExpr = Symbol.getVariableValue();
MCValue OffsetVal;
if(!SymbolExpr->evaluateAsRelocatable(OffsetVal, nullptr, nullptr))
return std::make_pair(false,
std::string("symbol in .reloc offset is not "
"relocatable"));
if (OffsetVal.isAbsolute()) {
RelocOffset = OffsetVal.getConstant();
MCFragment *Fragment = Symbol.getFragment();
// FIXME Support symbols with no DF. For example:
// .reloc .data, ENUM_VALUE, <some expr>
if (!Fragment || Fragment->getKind() != MCFragment::FT_Data)
return std::make_pair(false,
std::string("symbol in offset has no data "
"fragment"));
DF = cast<MCDataFragment>(Fragment);
return None;
}
if (OffsetVal.getSymB())
return std::make_pair(false,
std::string(".reloc symbol offset is not "
"representable"));
const MCSymbolRefExpr &SRE = cast<MCSymbolRefExpr>(*OffsetVal.getSymA());
if (!SRE.getSymbol().isDefined())
return std::make_pair(false,
std::string("symbol used in the .reloc offset is "
"not defined"));
if (SRE.getSymbol().isVariable())
return std::make_pair(false,
std::string("symbol used in the .reloc offset is "
"variable"));
MCFragment *Fragment = SRE.getSymbol().getFragment();
// FIXME Support symbols with no DF. For example:
// .reloc .data, ENUM_VALUE, <some expr>
if (!Fragment || Fragment->getKind() != MCFragment::FT_Data)
return std::make_pair(false,
std::string("symbol in offset has no data "
"fragment"));
RelocOffset = SRE.getSymbol().getOffset() + OffsetVal.getConstant();
DF = cast<MCDataFragment>(Fragment);
} else {
RelocOffset = Symbol.getOffset();
MCFragment *Fragment = Symbol.getFragment();
// FIXME Support symbols with no DF. For example:
// .reloc .data, ENUM_VALUE, <some expr>
if (!Fragment || Fragment->getKind() != MCFragment::FT_Data)
return std::make_pair(false,
std::string("symbol in offset has no data "
"fragment"));
DF = cast<MCDataFragment>(Fragment);
}
return None;
}
Optional<std::pair<bool, std::string>>
MCObjectStreamer::emitRelocDirective(const MCExpr &Offset, StringRef Name,
const MCExpr *Expr, SMLoc Loc,
const MCSubtargetInfo &STI) {
Optional<MCFixupKind> MaybeKind = Assembler->getBackend().getFixupKind(Name);
if (!MaybeKind.hasValue())
return std::make_pair(true, std::string("unknown relocation name"));
MCFixupKind Kind = *MaybeKind;
if (Expr == nullptr)
Expr =
MCSymbolRefExpr::create(getContext().createTempSymbol(), getContext());
MCDataFragment *DF = getOrCreateDataFragment(&STI);
flushPendingLabels(DF, DF->getContents().size());
MCValue OffsetVal;
if (!Offset.evaluateAsRelocatable(OffsetVal, nullptr, nullptr))
return std::make_pair(false,
std::string(".reloc offset is not relocatable"));
if (OffsetVal.isAbsolute()) {
if (OffsetVal.getConstant() < 0)
return std::make_pair(false, std::string(".reloc offset is negative"));
DF->getFixups().push_back(
MCFixup::create(OffsetVal.getConstant(), Expr, Kind, Loc));
return None;
}
if (OffsetVal.getSymB())
return std::make_pair(false,
std::string(".reloc offset is not representable"));
const MCSymbolRefExpr &SRE = cast<MCSymbolRefExpr>(*OffsetVal.getSymA());
const MCSymbol &Symbol = SRE.getSymbol();
if (Symbol.isDefined()) {
uint32_t SymbolOffset = 0;
Optional<std::pair<bool, std::string>> Error;
Error = getOffsetAndDataFragment(Symbol, SymbolOffset, DF);
if (Error != None)
return Error;
DF->getFixups().push_back(
MCFixup::create(SymbolOffset + OffsetVal.getConstant(),
Expr, Kind, Loc));
return None;
}
PendingFixups.emplace_back(&SRE.getSymbol(), DF,
MCFixup::create(-1, Expr, Kind, Loc));
return None;
}
void MCObjectStreamer::emitFill(const MCExpr &NumBytes, uint64_t FillValue,
SMLoc Loc) {
MCDataFragment *DF = getOrCreateDataFragment();
flushPendingLabels(DF, DF->getContents().size());
assert(getCurrentSectionOnly() && "need a section");
insert(new MCFillFragment(FillValue, 1, NumBytes, Loc));
}
void MCObjectStreamer::emitFill(const MCExpr &NumValues, int64_t Size,
int64_t Expr, SMLoc Loc) {
int64_t IntNumValues;
// Do additional checking now if we can resolve the value.
if (NumValues.evaluateAsAbsolute(IntNumValues, getAssemblerPtr())) {
if (IntNumValues < 0) {
getContext().getSourceManager()->PrintMessage(
Loc, SourceMgr::DK_Warning,
"'.fill' directive with negative repeat count has no effect");
return;
}
// Emit now if we can for better errors.
int64_t NonZeroSize = Size > 4 ? 4 : Size;
Expr &= ~0ULL >> (64 - NonZeroSize * 8);
for (uint64_t i = 0, e = IntNumValues; i != e; ++i) {
emitIntValue(Expr, NonZeroSize);
if (NonZeroSize < Size)
emitIntValue(0, Size - NonZeroSize);
}
return;
}
// Otherwise emit as fragment.
MCDataFragment *DF = getOrCreateDataFragment();
flushPendingLabels(DF, DF->getContents().size());
assert(getCurrentSectionOnly() && "need a section");
insert(new MCFillFragment(Expr, Size, NumValues, Loc));
}
void MCObjectStreamer::emitNops(int64_t NumBytes, int64_t ControlledNopLength,
SMLoc Loc) {
// Emit an NOP fragment.
MCDataFragment *DF = getOrCreateDataFragment();
flushPendingLabels(DF, DF->getContents().size());
assert(getCurrentSectionOnly() && "need a section");
insert(new MCNopsFragment(NumBytes, ControlledNopLength, Loc));
}
void MCObjectStreamer::emitFileDirective(StringRef Filename) {
getAssembler().addFileName(Filename);
}
void MCObjectStreamer::emitAddrsig() {
getAssembler().getWriter().emitAddrsigSection();
}
void MCObjectStreamer::emitAddrsigSym(const MCSymbol *Sym) {
getAssembler().registerSymbol(*Sym);
getAssembler().getWriter().addAddrsigSymbol(Sym);
}
void MCObjectStreamer::finishImpl() {
getContext().RemapDebugPaths();
// If we are generating dwarf for assembly source files dump out the sections.
if (getContext().getGenDwarfForAssembly())
MCGenDwarfInfo::Emit(this);
// Dump out the dwarf file & directory tables and line tables.
MCDwarfLineTable::emit(this, getAssembler().getDWARFLinetableParams());
// Emit pseudo probes for the current module.
MCPseudoProbeTable::emit(this);
// Update any remaining pending labels with empty data fragments.
flushPendingLabels();
resolvePendingFixups();
getAssembler().Finish();
}