kolibrios-fun/programs/develop/objconv/mac2asm.cpp

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/**************************** mac2asm.cpp *********************************
* Author: Agner Fog
* Date created: 2007-05-24
* Last modified: 2008-05-12
* Project: objconv
* Module: mac2asm.cpp
* Description:
* Module for disassembling Mach-O files
*
* Copyright 2007-2008 GNU General Public License http://www.gnu.org/licenses
*****************************************************************************/
#include "stdafx.h"
// Constructor
template <class TMAC_header, class TMAC_segment_command, class TMAC_section, class TMAC_nlist, class MInt>
CMAC2ASM<MACSTRUCTURES>::CMAC2ASM() {
}
// Convert
template <class TMAC_header, class TMAC_segment_command, class TMAC_section, class TMAC_nlist, class MInt>
void CMAC2ASM<MACSTRUCTURES>::Convert() {
// Do the conversion
// Check cpu type
switch (this->FileHeader.cputype) {
case MAC_CPU_TYPE_I386:
this->WordSize = 32; break;
case MAC_CPU_TYPE_X86_64:
this->WordSize = 64; break;
default:
// Wrong type
err.submit(2011, ""); return;
}
// check object/executable file type
uint32 ExeType; // File type: 0 = object, 1 = position independent shared object, 2 = executable
switch (this->FileHeader.filetype) {
case MAC_OBJECT: // Relocatable object file
ExeType = 0; break;
case MAC_FVMLIB: // fixed VM shared library file
case MAC_DYLIB: // dynamicly bound shared library file
case MAC_BUNDLE: // part of universal binary
ExeType = 1; break;
case MAC_EXECUTE: // demand paged executable file
case MAC_CORE: // core file
case MAC_PRELOAD: // preloaded executable file
ExeType = 2; break;
default: // Other types
err.submit(2011, ""); return;
}
// Tell disassembler
// Disasm.Init(ExeType, this->ImageBase);
Disasm.Init(ExeType, 0);
// Make Sections list and relocations list
MakeSectionList();
// Make Symbols list in Disasm
MakeSymbolList();
// Make relocations list in Disasm
MakeRelocations();
// Make symbol entries for imported symbols
MakeImports();
Disasm.Go(); // Disassemble
*this << Disasm.OutFile; // Take over output file from Disasm
}
// MakeSectionList
template <class TMAC_header, class TMAC_segment_command, class TMAC_section, class TMAC_nlist, class MInt>
void CMAC2ASM<MACSTRUCTURES>::MakeSectionList() {
// Make Sections list and Relocations list in Disasm
uint32 icmd; // Command index
int32 isec1; // Section index within segment
int32 isec2 = 0; // Section index global
int32 nsect; // Number of sections in segment
uint32 cmd; // Load command
uint32 cmdsize; // Command size
StringBuffer.Push(0, 1); // Initialize string buffer
// Pointer to current position
uint8 * currentp = (uint8*)(this->Buf() + sizeof(TMAC_header));
// Loop through file commands
for (icmd = 1; icmd <= this->FileHeader.ncmds; icmd++) {
cmd = ((MAC_load_command*)currentp) -> cmd;
cmdsize = ((MAC_load_command*)currentp) -> cmdsize;
if (cmd == MAC_LC_SEGMENT || cmd == MAC_LC_SEGMENT_64) {
// This is a segment command
if ((this->WordSize == 64) ^ (cmd == MAC_LC_SEGMENT_64)) {
// Inconsistent word size
err.submit(2320); break;
}
// Number of sections in segment
nsect = ((TMAC_segment_command*)currentp) -> nsects;
// Find first section header
TMAC_section * sectp = (TMAC_section*)(currentp + sizeof(TMAC_segment_command));
// Loop through section headers
for (isec1 = 1; isec1 <= nsect; isec1++, sectp++) {
if (sectp->offset >= this->GetDataSize()) {
// points outside file
err.submit(2035); break;
}
// Get section properties
isec2++; // Section number
uint32 MacSectionType = sectp->flags & MAC_SECTION_TYPE;
uint8 * Buffer = (uint8*)(this->Buf()) + sectp->offset;
uint32 TotalSize = (uint32)sectp->size;
uint32 InitSize = TotalSize;
if (MacSectionType == MAC_S_ZEROFILL) InitSize = 0;
uint32 SectionAddress = (uint32)sectp->addr;
uint32 Align = sectp->align;
// Get section type
// 0 = unknown, 1 = code, 2 = data, 3 = uninitialized data, 4 = constant data
uint32 Type = 0;
if (sectp->flags & (MAC_S_ATTR_PURE_INSTRUCTIONS | MAC_S_ATTR_SOME_INSTRUCTIONS)) {
Type = 1; // code
}
else if (MacSectionType == MAC_S_ZEROFILL) {
Type = 3; // uninitialized data
}
else {
Type = 2; // data or anything else
}
// Make section name by combining segment name and section name
uint32 NameOffset = StringBuffer.Push(sectp->segname, (uint32)strlen(sectp->segname)); // Segment name
StringBuffer.Push(".", 1); // Separate by dot
StringBuffer.PushString(sectp->sectname); // Section name
char * Name = StringBuffer.Buf() + NameOffset;
// Save section record
Disasm.AddSection(Buffer, InitSize, TotalSize, SectionAddress, Type, Align, this->WordSize, Name);
// Save information about relocation list for this section
if (sectp->nreloc) {
MAC_SECT_WITH_RELOC RelList = {isec2, sectp->offset, sectp->nreloc, sectp->reloff};
RelocationQueue.Push(RelList);
}
// Find import tables
if (MacSectionType >= MAC_S_NON_LAZY_SYMBOL_POINTERS && MacSectionType <= MAC_S_LAZY_SYMBOL_POINTERS /*?*/) {
// This is an import table
ImportSections.Push(sectp);
}
// Find literals sections
if (MacSectionType == MAC_S_4BYTE_LITERALS || MacSectionType == MAC_S_8BYTE_LITERALS) {
// This is a literals section
ImportSections.Push(sectp);
}
}
}
currentp += cmdsize;
}
}
// MakeRelocations
template <class TMAC_header, class TMAC_segment_command, class TMAC_section, class TMAC_nlist, class MInt>
void CMAC2ASM<MACSTRUCTURES>::MakeRelocations() {
// Make relocations for object and executable files
uint32 iqq; // Index into RelocationQueue = table of relocation tables
uint32 irel; // Index into relocation table
int32 Section; // Section index
uint32 SectOffset; // File offset of section binary data
uint32 NumReloc; // Number of relocations records for this section
uint32 ReltabOffset; // File offset of relocation table for this section
uint32 SourceOffset; // Section-relative offset of relocation source
uint32 SourceSize; // Size of relocation source
int32 Inline = 0; // Inline addend at relocation source
uint32 TargetAddress; // Base-relative address of relocation target
uint32 TargetSymbol; // Symbol index of target
//int32 TargetSection; // Target section
int32 Addend; // Offset to add to target
uint32 ReferenceAddress; // Base-relative address of reference point
uint32 ReferenceSymbol; // Symbol index of reference point
uint32 R_Type; // Relocation type in Mach-O record
uint32 R_Type2; // Relocation type of second entry of a pair
uint32 R_PCRel; // Relocation is self-relative
uint32 RelType = 0; // Relocation type translated to disasm record
// Loop through RelocationQueue. There is one entry for each relocation table
for (iqq = 0; iqq < RelocationQueue.GetNumEntries(); iqq++) {
Section = RelocationQueue[iqq].Section; // Section index
SectOffset = RelocationQueue[iqq].SectOffset; // File offset of section binary data
NumReloc = RelocationQueue[iqq].NumReloc; // Number of relocations records for this section
ReltabOffset = RelocationQueue[iqq].ReltabOffset; // File offset of relocation table for this section
if (NumReloc == 0) continue;
if (ReltabOffset == 0 || ReltabOffset >= this->GetDataSize() || ReltabOffset + NumReloc*sizeof(MAC_relocation_info) >= this->GetDataSize()) {
// Pointer out of range
err.submit(2035); return;
}
// pointer to relocation info
union {
MAC_relocation_info * r;
MAC_scattered_relocation_info * s;
int8 * b;
} relp;
// Point to first relocation entry
relp.b = this->Buf() + ReltabOffset;
// Loop through relocation table
for (irel = 0; irel < NumReloc; irel++, relp.r++) {
// Set defaults
ReferenceAddress = ReferenceSymbol = TargetSymbol = Addend = 0;
if (relp.s->r_scattered) {
// scattered relocation entry
SourceOffset = relp.s->r_address;
SourceSize = 1 << relp.s->r_length;
R_PCRel = relp.s->r_pcrel;
R_Type = relp.s->r_type;
TargetAddress = relp.s->r_value;
TargetSymbol = 0;
}
else {
// non-scattered relocation entry
SourceOffset = relp.r->r_address;
SourceSize = 1 << relp.r->r_length;
R_PCRel = relp.r->r_pcrel;
R_Type = relp.r->r_type;
if (relp.r->r_extern) {
TargetSymbol = relp.r->r_symbolnum + 1;
}
else {
//TargetSection = relp.r->r_symbolnum;
}
TargetAddress = 0;
}
if (this->WordSize == 32 && (R_Type == MAC32_RELOC_SECTDIFF || R_Type == MAC32_RELOC_LOCAL_SECTDIFF)) {
// This is the first of a pair of relocation entries.
// Get second entry containing reference point
irel++; relp.r++;
if (irel >= NumReloc) {err.submit(2050); break;}
if (relp.s->r_scattered) {
// scattered relocation entry
R_Type2 = relp.s->r_type;
ReferenceAddress = relp.s->r_value;
ReferenceSymbol = 0;
}
else {
// non-scattered relocation entry
ReferenceSymbol = relp.r->r_symbolnum + 1;
R_Type2 = relp.r->r_type;
ReferenceAddress = 0;
}
if (R_Type2 != MAC32_RELOC_PAIR) {err.submit(2050); break;}
if (ReferenceSymbol == 0) {
// Reference point has no symbol index. Make one
ReferenceSymbol = Disasm.AddSymbol(ASM_SEGMENT_IMGREL, ReferenceAddress, 0, 0, 2, 0, 0);
}
}
if (this->WordSize == 64 && R_Type == MAC64_RELOC_SUBTRACTOR) {
// This is the first of a pair of relocation entries.
// The first entry contains reference point to subtract
irel++; relp.r++;
if (irel >= NumReloc || relp.s->r_scattered || relp.r->r_type != MAC64_RELOC_UNSIGNED) {
err.submit(2050); break;
}
ReferenceSymbol = TargetSymbol;
R_PCRel = relp.r->r_pcrel;
if (relp.r->r_extern) {
TargetSymbol = relp.r->r_symbolnum + 1;
}
else {
//TargetSection = relp.r->r_symbolnum;
}
TargetAddress = 0;
}
// Get inline addend or address
if (SectOffset + SourceOffset < this->GetDataSize()) {
switch (SourceSize) {
case 1:
Inline = CMemoryBuffer::Get<int8>(SectOffset+SourceOffset);
// (this->Get<int8> doesn't work on Gnu compiler 4.0.1)
break;
case 2:
Inline = CMemoryBuffer::Get<int16>(SectOffset+SourceOffset);
break;
case 4: case 8:
Inline = CMemoryBuffer::Get<int32>(SectOffset+SourceOffset);
break;
default:
Inline = 0;
}
}
if (this->WordSize == 32) {
// Calculate target address and addend, 32 bit system
if (R_Type == MAC32_RELOC_SECTDIFF || R_Type == MAC32_RELOC_LOCAL_SECTDIFF) {
// Relative to reference point
// Compensate for inline value = TargetAddress - ReferenceAddress;
Addend = ReferenceAddress - TargetAddress;
}
else if (R_PCRel) {
// Self-relative
TargetAddress += Inline + SourceOffset + SourceSize;
Addend = -4 - Inline;
}
else {
// Direct
TargetAddress += Inline;
Addend = -Inline;
}
}
if (TargetSymbol == 0) {
// Target has no symbol index. Make one
TargetSymbol = Disasm.AddSymbol(ASM_SEGMENT_IMGREL, TargetAddress, 0, 0, 2, 0, 0);
}
// Find type
if (this->WordSize == 32) {
switch (R_Type) {
case MAC32_RELOC_VANILLA:
// Direct or self-relative
RelType = R_PCRel ? 2 : 1;
break;
case MAC32_RELOC_SECTDIFF: case MAC32_RELOC_LOCAL_SECTDIFF:
// Relative to reference point
RelType = 0x10;
break;
case MAC32_RELOC_PB_LA_PTR:
// Lazy pointer
RelType = 0x41; //??
break;
default:
// Unknown type
err.submit(2030, R_Type);
break;
}
}
else { // 64-bit relocation types
switch (R_Type) {
case MAC64_RELOC_UNSIGNED:
// Absolute address
RelType = 1;
break;
case MAC64_RELOC_BRANCH:
// Signed 32-bit displacement with implicit -4 addend
case MAC64_RELOC_SIGNED:
// Signed 32-bit displacement with implicit -4 addend
case MAC64_RELOC_SIGNED_1:
// Signed 32-bit displacement with implicit -4 addend and explicit -1 addend
case MAC64_RELOC_SIGNED_2:
// Signed 32-bit displacement with implicit -4 addend and explicit -2 addend
case MAC64_RELOC_SIGNED_4:
// Signed 32-bit displacement with implicit -4 addend and explicit -4 addend
RelType = 2; Addend -= 4;
break;
case MAC64_RELOC_GOT:
// Absolute or relative reference to GOT?
// RelType = 0x1001; break;
case MAC64_RELOC_GOT_LOAD:
// Signed 32-bit displacement to GOT
RelType = 0x1002; Addend -= 4;
break;
case MAC64_RELOC_SUBTRACTOR:
// 32 or 64 bit relative to arbitrary reference point
RelType = 0x10;
break;
default:
// Unknown type
err.submit(2030, R_Type);
break;
}
}
// Make relocation record
Disasm.AddRelocation(Section, SourceOffset, Addend,
RelType, SourceSize, TargetSymbol, ReferenceSymbol);
}
}
}
// MakeSymbolList
template <class TMAC_header, class TMAC_segment_command, class TMAC_section, class TMAC_nlist, class MInt>
void CMAC2ASM<MACSTRUCTURES>::MakeSymbolList() {
// Make Symbols list in Disasm
uint32 symi; // Symbol index, 0-based
uint32 symn = 0; // Symbol number, 1-based
char * Name; // Symbol name
int32 Section; // Section number (1-based). 0 = external, ASM_SEGMENT_ABSOLUTE = absolute, ASM_SEGMENT_IMGREL = image-relative
uint32 Offset; // Offset into section. (Value for absolute symbol)
uint32 Type; // Symbol type. Use values listed above for SOpcodeDef operands. 0 = unknown type
uint32 Scope; // 1 = function local, 2 = file local, 4 = public, 8 = weak public, 0x10 = communal, 0x20 = external
// pointer to string table
char * strtab = (char*)(this->Buf() + this->StringTabOffset);
// loop through symbol table
TMAC_nlist * symp = (TMAC_nlist*)(this->Buf() + this->SymTabOffset);
for (symi = 0; symi < this->SymTabNumber; symi++, symp++) {
if (symp->n_type & MAC_N_STAB) {
// Debug symbol. Ignore
continue;
}
if (symp->n_strx < this->StringTabSize) {
// Normal symbol
Section = symp->n_sect;
Offset = (uint32)symp->n_value;
Name = strtab + symp->n_strx;
symn = symi + 1; // Convert 0-based to 1-based index
// Get scope
if (symi < this->iextdefsym) {
// Local
Scope = 2;
}
else if (Section && (symp->n_type & MAC_N_TYPE) != MAC_N_UNDF) {
// Public
Scope = 4;
}
else {
// External
Scope = 0x20;
}
// Check if absolute
if ((symp->n_type & MAC_N_TYPE) == MAC_N_ABS) {
// Absolute
Section = ASM_SEGMENT_ABSOLUTE; Scope = 4;
}
// Check if weak/communal
if (symp->n_type & MAC_N_PEXT) {
// Communal?
Scope = 0x10;
}
else if (symp->n_desc & MAC_N_WEAK_DEF) {
// Weak public
Scope = 8;
}
else if (symp->n_desc & MAC_N_WEAK_REF) {
// Weak external (not supported by disassembler)
Scope = 0x20;
}
// Get type
Type = 0;
// Offset is always based, not section-relative
if (Section > 0) Section = ASM_SEGMENT_IMGREL;
// Add symbol to diassembler
Disasm.AddSymbol(Section, Offset, 0, Type, Scope, symn, Name);
}
}
}
template <class TMAC_header, class TMAC_segment_command, class TMAC_section, class TMAC_nlist, class MInt>
void CMAC2ASM<MACSTRUCTURES>::MakeImports() {
// Make symbol entries for all import tables
uint32 isec; // Index into ImportSections list
uint32 SectionType; // Section type
TMAC_section * sectp; // Pointer to section
TMAC_nlist * symp0 = (TMAC_nlist*)(this->Buf() + this->SymTabOffset); // Pointer to symbol table
uint32 * IndSymp = (uint32*)(this->Buf() + this->IndirectSymTabOffset); // Pointer to indirect symbol table
uint32 iimp; // Index into import table
char * strtab = (char*)(this->Buf() + this->StringTabOffset); // pointer to string table
// Loop through import sections
for (isec = 0; isec < ImportSections.GetNumEntries(); isec++) {
// Pointer to section header
sectp = ImportSections[isec];
// Section type
SectionType = sectp->flags & MAC_SECTION_TYPE;
if (SectionType >= MAC_S_NON_LAZY_SYMBOL_POINTERS && SectionType <= MAC_S_MOD_INIT_FUNC_POINTERS) {
// This section contains import tables
// Entry size in import table
uint32 EntrySize = sectp->reserved2;
// Entry size is 4 if not specified
if (EntrySize == 0) EntrySize = 4;
// Number of entries
uint32 NumEntries = (uint32)sectp->size / EntrySize;
// Index into indirect symbol table entry of first entry in import table
uint32 Firsti = sectp->reserved1;
// Check if within range
if (Firsti + NumEntries > this->IndirectSymTabNumber) {
// This occurs when disassembling 64-bit Mach-O executable
// I don't know how to interpret the import table
err.submit(1054); continue;
}
// Loop through import table entries
for (iimp = 0; iimp < NumEntries; iimp++) {
// Address of import table entry
uint32 ImportAddress = (uint32)sectp->addr + iimp * EntrySize;
// Get symbol table index from indirect symbol table
uint32 symi = IndSymp[iimp + Firsti];
// Check index
if (symi == 0x80000000) {
// This value occurs. Maybe it means ignore?
continue;
}
// Check if index within symbol table
if (symi >= this->SymTabNumber) {
err.submit(1052); continue;
}
// Find name
uint32 StringIndex = symp0[symi].n_strx;
if (StringIndex >= this->StringTabSize) {
err.submit(1052); continue;
}
const char * Name = strtab + StringIndex;
// Name of .so to import from
const char * DLLName = "?";
// Symbol type
uint32 Type = 0;
switch (SectionType) {
case MAC_S_NON_LAZY_SYMBOL_POINTERS:
case MAC_S_LAZY_SYMBOL_POINTERS:
// pointer to symbol
Type = 3; break;
case MAC_S_SYMBOL_STUBS:
// jump to function
Type = 0x83;
// Make appear as direct call
DLLName = 0;
break;
case MAC_S_MOD_INIT_FUNC_POINTERS:
// function pointer?
Type = 0x0C; break;
}
// Make symbol record for disassembler
Disasm.AddSymbol(ASM_SEGMENT_IMGREL, ImportAddress, 4, Type, 2, 0, Name, DLLName);
}
}
else if (SectionType == MAC_S_4BYTE_LITERALS) {
// Section contains 4-byte float constants.
// Make symbol
Disasm.AddSymbol(ASM_SEGMENT_IMGREL, (uint32)sectp->addr, 4, 0x43, 2, 0, "Float_constants");
}
else if (SectionType == MAC_S_8BYTE_LITERALS) {
// Section contains 8-byte double constants.
// Make symbol
Disasm.AddSymbol(ASM_SEGMENT_IMGREL, (uint32)sectp->addr, 8, 0x44, 2, 0, "Double_constants");
}
}
}
// Make template instances for 32 and 64 bits
template class CMAC2ASM<MAC32STRUCTURES>;
template class CMAC2ASM<MAC64STRUCTURES>;