//===- lib/MC/MCSectionMachO.cpp - MachO Code Section Representation ------===// // // 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/MCSectionMachO.h" #include "llvm/MC/SectionKind.h" #include "llvm/Support/raw_ostream.h" namespace llvm { class MCAsmInfo; class MCExpr; class MCSymbol; class Triple; } // namespace llvm using namespace llvm; /// SectionTypeDescriptors - These are strings that describe the various section /// types. This *must* be kept in order with and stay synchronized with the /// section type list. static constexpr struct { StringLiteral AssemblerName, EnumName; } SectionTypeDescriptors[MachO::LAST_KNOWN_SECTION_TYPE + 1] = { {StringLiteral("regular"), StringLiteral("S_REGULAR")}, // 0x00 {StringLiteral("zerofill"), StringLiteral("S_ZEROFILL")}, // 0x01 {StringLiteral("cstring_literals"), StringLiteral("S_CSTRING_LITERALS")}, // 0x02 {StringLiteral("4byte_literals"), StringLiteral("S_4BYTE_LITERALS")}, // 0x03 {StringLiteral("8byte_literals"), StringLiteral("S_8BYTE_LITERALS")}, // 0x04 {StringLiteral("literal_pointers"), StringLiteral("S_LITERAL_POINTERS")}, // 0x05 {StringLiteral("non_lazy_symbol_pointers"), StringLiteral("S_NON_LAZY_SYMBOL_POINTERS")}, // 0x06 {StringLiteral("lazy_symbol_pointers"), StringLiteral("S_LAZY_SYMBOL_POINTERS")}, // 0x07 {StringLiteral("symbol_stubs"), StringLiteral("S_SYMBOL_STUBS")}, // 0x08 {StringLiteral("mod_init_funcs"), StringLiteral("S_MOD_INIT_FUNC_POINTERS")}, // 0x09 {StringLiteral("mod_term_funcs"), StringLiteral("S_MOD_TERM_FUNC_POINTERS")}, // 0x0A {StringLiteral("coalesced"), StringLiteral("S_COALESCED")}, // 0x0B {StringLiteral("") /*FIXME??*/, StringLiteral("S_GB_ZEROFILL")}, // 0x0C {StringLiteral("interposing"), StringLiteral("S_INTERPOSING")}, // 0x0D {StringLiteral("16byte_literals"), StringLiteral("S_16BYTE_LITERALS")}, // 0x0E {StringLiteral("") /*FIXME??*/, StringLiteral("S_DTRACE_DOF")}, // 0x0F {StringLiteral("") /*FIXME??*/, StringLiteral("S_LAZY_DYLIB_SYMBOL_POINTERS")}, // 0x10 {StringLiteral("thread_local_regular"), StringLiteral("S_THREAD_LOCAL_REGULAR")}, // 0x11 {StringLiteral("thread_local_zerofill"), StringLiteral("S_THREAD_LOCAL_ZEROFILL")}, // 0x12 {StringLiteral("thread_local_variables"), StringLiteral("S_THREAD_LOCAL_VARIABLES")}, // 0x13 {StringLiteral("thread_local_variable_pointers"), StringLiteral("S_THREAD_LOCAL_VARIABLE_POINTERS")}, // 0x14 {StringLiteral("thread_local_init_function_pointers"), StringLiteral("S_THREAD_LOCAL_INIT_FUNCTION_POINTERS")}, // 0x15 {StringLiteral("") /* linker-synthesized */, StringLiteral("S_INIT_FUNC_OFFSETS")}, // 0x16 }; /// SectionAttrDescriptors - This is an array of descriptors for section /// attributes. Unlike the SectionTypeDescriptors, this is not directly indexed /// by attribute, instead it is searched. static constexpr struct { unsigned AttrFlag; StringLiteral AssemblerName, EnumName; } SectionAttrDescriptors[] = { #define ENTRY(ASMNAME, ENUM) \ { MachO::ENUM, StringLiteral(ASMNAME), StringLiteral(#ENUM) }, ENTRY("pure_instructions", S_ATTR_PURE_INSTRUCTIONS) ENTRY("no_toc", S_ATTR_NO_TOC) ENTRY("strip_static_syms", S_ATTR_STRIP_STATIC_SYMS) ENTRY("no_dead_strip", S_ATTR_NO_DEAD_STRIP) ENTRY("live_support", S_ATTR_LIVE_SUPPORT) ENTRY("self_modifying_code", S_ATTR_SELF_MODIFYING_CODE) ENTRY("debug", S_ATTR_DEBUG) ENTRY("" /*FIXME*/, S_ATTR_SOME_INSTRUCTIONS) ENTRY("" /*FIXME*/, S_ATTR_EXT_RELOC) ENTRY("" /*FIXME*/, S_ATTR_LOC_RELOC) #undef ENTRY { 0, StringLiteral("none"), StringLiteral("") }, // used if section has no attributes but has a stub size }; MCSectionMachO::MCSectionMachO(StringRef Segment, StringRef Section, unsigned TAA, unsigned reserved2, SectionKind K, MCSymbol *Begin) : MCSection(SV_MachO, Section, K.isText(), MachO::isVirtualSection(TAA & MachO::SECTION_TYPE), Begin), TypeAndAttributes(TAA), Reserved2(reserved2) { assert(Segment.size() <= 16 && Section.size() <= 16 && "Segment or section string too long"); for (unsigned i = 0; i != 16; ++i) { if (i < Segment.size()) SegmentName[i] = Segment[i]; else SegmentName[i] = 0; } } void MCSectionMachO::printSwitchToSection(const MCAsmInfo &MAI, const Triple &T, raw_ostream &OS, uint32_t Subsection) const { OS << "\t.section\t" << getSegmentName() << ',' << getName(); // Get the section type and attributes. unsigned TAA = getTypeAndAttributes(); if (TAA == 0) { OS << '\n'; return; } MachO::SectionType SectionType = getType(); assert(SectionType <= MachO::LAST_KNOWN_SECTION_TYPE && "Invalid SectionType specified!"); if (!SectionTypeDescriptors[SectionType].AssemblerName.empty()) { OS << ','; OS << SectionTypeDescriptors[SectionType].AssemblerName; } else { // If we have no name for the attribute, stop here. OS << '\n'; return; } // If we don't have any attributes, we're done. unsigned SectionAttrs = TAA & MachO::SECTION_ATTRIBUTES; if (SectionAttrs == 0) { // If we have a S_SYMBOL_STUBS size specified, print it along with 'none' as // the attribute specifier. if (Reserved2 != 0) OS << ",none," << Reserved2; OS << '\n'; return; } // Check each attribute to see if we have it. char Separator = ','; for (unsigned i = 0; SectionAttrs != 0 && SectionAttrDescriptors[i].AttrFlag; ++i) { // Check to see if we have this attribute. if ((SectionAttrDescriptors[i].AttrFlag & SectionAttrs) == 0) continue; // Yep, clear it and print it. SectionAttrs &= ~SectionAttrDescriptors[i].AttrFlag; OS << Separator; if (!SectionAttrDescriptors[i].AssemblerName.empty()) OS << SectionAttrDescriptors[i].AssemblerName; else OS << "<<" << SectionAttrDescriptors[i].EnumName << ">>"; Separator = '+'; } assert(SectionAttrs == 0 && "Unknown section attributes!"); // If we have a S_SYMBOL_STUBS size specified, print it. if (Reserved2 != 0) OS << ',' << Reserved2; OS << '\n'; } bool MCSectionMachO::useCodeAlign() const { return hasAttribute(MachO::S_ATTR_PURE_INSTRUCTIONS); } /// ParseSectionSpecifier - Parse the section specifier indicated by "Spec". /// This is a string that can appear after a .section directive in a mach-o /// flavored .s file. If successful, this fills in the specified Out /// parameters and returns an empty string. When an invalid section /// specifier is present, this returns a string indicating the problem. Error MCSectionMachO::ParseSectionSpecifier(StringRef Spec, // In. StringRef &Segment, // Out. StringRef &Section, // Out. unsigned &TAA, // Out. bool &TAAParsed, // Out. unsigned &StubSize) { // Out. TAAParsed = false; SmallVector SplitSpec; Spec.split(SplitSpec, ','); // Remove leading and trailing whitespace. auto GetEmptyOrTrim = [&SplitSpec](size_t Idx) -> StringRef { return SplitSpec.size() > Idx ? SplitSpec[Idx].trim() : StringRef(); }; Segment = GetEmptyOrTrim(0); Section = GetEmptyOrTrim(1); StringRef SectionType = GetEmptyOrTrim(2); StringRef Attrs = GetEmptyOrTrim(3); StringRef StubSizeStr = GetEmptyOrTrim(4); // Verify that the section is present. if (Section.empty()) return createStringError(inconvertibleErrorCode(), "mach-o section specifier requires a segment " "and section separated by a comma"); // Verify that the section is not too long. if (Section.size() > 16) return createStringError(inconvertibleErrorCode(), "mach-o section specifier requires a section " "whose length is between 1 and 16 characters"); // If there is no comma after the section, we're done. TAA = 0; StubSize = 0; if (SectionType.empty()) return Error::success(); // Figure out which section type it is. auto TypeDescriptor = llvm::find_if(SectionTypeDescriptors, [&](decltype(*SectionTypeDescriptors) &Descriptor) { return SectionType == Descriptor.AssemblerName; }); // If we didn't find the section type, reject it. if (TypeDescriptor == std::end(SectionTypeDescriptors)) return createStringError(inconvertibleErrorCode(), "mach-o section specifier uses an unknown " "section type"); // Remember the TypeID. TAA = TypeDescriptor - std::begin(SectionTypeDescriptors); TAAParsed = true; // If we have no comma after the section type, there are no attributes. if (Attrs.empty()) { // S_SYMBOL_STUBS always require a symbol stub size specifier. if (TAA == MachO::S_SYMBOL_STUBS) return createStringError(inconvertibleErrorCode(), "mach-o section specifier of type " "'symbol_stubs' requires a size specifier"); return Error::success(); } // The attribute list is a '+' separated list of attributes. SmallVector SectionAttrs; Attrs.split(SectionAttrs, '+', /*MaxSplit=*/-1, /*KeepEmpty=*/false); for (StringRef &SectionAttr : SectionAttrs) { auto AttrDescriptorI = llvm::find_if(SectionAttrDescriptors, [&](decltype(*SectionAttrDescriptors) &Descriptor) { return SectionAttr.trim() == Descriptor.AssemblerName; }); if (AttrDescriptorI == std::end(SectionAttrDescriptors)) return createStringError(inconvertibleErrorCode(), "mach-o section specifier has invalid " "attribute"); TAA |= AttrDescriptorI->AttrFlag; } // Okay, we've parsed the section attributes, see if we have a stub size spec. if (StubSizeStr.empty()) { // S_SYMBOL_STUBS always require a symbol stub size specifier. if (TAA == MachO::S_SYMBOL_STUBS) return createStringError(inconvertibleErrorCode(), "mach-o section specifier of type " "'symbol_stubs' requires a size specifier"); return Error::success(); } // If we have a stub size spec, we must have a sectiontype of S_SYMBOL_STUBS. if ((TAA & MachO::SECTION_TYPE) != MachO::S_SYMBOL_STUBS) return createStringError(inconvertibleErrorCode(), "mach-o section specifier cannot have a stub " "size specified because it does not have type " "'symbol_stubs'"); // Convert the stub size from a string to an integer. if (StubSizeStr.getAsInteger(0, StubSize)) return createStringError(inconvertibleErrorCode(), "mach-o section specifier has a malformed " "stub size"); return Error::success(); } void MCSectionMachO::allocAtoms() { auto *L = curFragList(); if (L->Tail) Atoms.resize(L->Tail->getLayoutOrder() + 1); } const MCSymbol *MCSectionMachO::getAtom(size_t I) const { return I < Atoms.size() ? Atoms[I] : nullptr; } void MCSectionMachO::setAtom(size_t I, const MCSymbol *Sym) { Atoms[I] = Sym; }