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llvm-project/lldb/source/Plugins/ObjectFile/Mach-O/ObjectFileMachO.cpp

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//===-- ObjectFileMachO.cpp -------------------------------------*- C++ -*-===//
//
// The LLVM Compiler Infrastructure
//
// This file is distributed under the University of Illinois Open Source
// License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//
// C Includes
// C++ Includes
// Other libraries and framework includes
#include "llvm/ADT/StringRef.h"
// Project includes
#include "lldb/Core/ArchSpec.h"
#include "lldb/Core/DataBuffer.h"
#include "lldb/Core/Debugger.h"
#include "lldb/Core/Error.h"
#include "lldb/Core/FileSpecList.h"
#include "lldb/Core/Log.h"
#include "lldb/Core/Module.h"
#include "lldb/Core/ModuleSpec.h"
#include "lldb/Core/PluginManager.h"
#include "lldb/Core/RangeMap.h"
#include "lldb/Core/Section.h"
#include "lldb/Core/StreamFile.h"
#include "lldb/Core/StreamString.h"
#include "lldb/Core/Timer.h"
#include "lldb/Core/UUID.h"
#include "lldb/Host/Host.h"
#include "lldb/Host/FileSpec.h"
#include "lldb/Symbol/DWARFCallFrameInfo.h"
#include "lldb/Symbol/ObjectFile.h"
#include "lldb/Target/MemoryRegionInfo.h"
#include "lldb/Target/Platform.h"
#include "lldb/Target/Process.h"
#include "lldb/Target/SectionLoadList.h"
#include "lldb/Target/Target.h"
#include "lldb/Target/Thread.h"
#include "lldb/Target/ThreadList.h"
#include "Plugins/Process/Utility/RegisterContextDarwin_arm.h"
#include "Plugins/Process/Utility/RegisterContextDarwin_arm64.h"
#include "Plugins/Process/Utility/RegisterContextDarwin_i386.h"
#include "Plugins/Process/Utility/RegisterContextDarwin_x86_64.h"
#include "lldb/Utility/SafeMachO.h"
#include "ObjectFileMachO.h"
#if defined (__APPLE__) && (defined (__arm__) || defined (__arm64__) || defined (__aarch64__))
// GetLLDBSharedCacheUUID() needs to call dlsym()
#include <dlfcn.h>
#endif
#ifndef __APPLE__
#include "Utility/UuidCompatibility.h"
#endif
#define THUMB_ADDRESS_BIT_MASK 0xfffffffffffffffeull
using namespace lldb;
using namespace lldb_private;
using namespace llvm::MachO;
// Some structure definitions needed for parsing the dyld shared cache files
// found on iOS devices.
struct lldb_copy_dyld_cache_header_v1
{
char magic[16]; // e.g. "dyld_v0 i386", "dyld_v1 armv7", etc.
uint32_t mappingOffset; // file offset to first dyld_cache_mapping_info
uint32_t mappingCount; // number of dyld_cache_mapping_info entries
uint32_t imagesOffset;
uint32_t imagesCount;
uint64_t dyldBaseAddress;
uint64_t codeSignatureOffset;
uint64_t codeSignatureSize;
uint64_t slideInfoOffset;
uint64_t slideInfoSize;
uint64_t localSymbolsOffset;
uint64_t localSymbolsSize;
uint8_t uuid[16]; // v1 and above, also recorded in dyld_all_image_infos v13 and later
};
struct lldb_copy_dyld_cache_mapping_info
{
uint64_t address;
uint64_t size;
uint64_t fileOffset;
uint32_t maxProt;
uint32_t initProt;
};
struct lldb_copy_dyld_cache_local_symbols_info
{
uint32_t nlistOffset;
uint32_t nlistCount;
uint32_t stringsOffset;
uint32_t stringsSize;
uint32_t entriesOffset;
uint32_t entriesCount;
};
struct lldb_copy_dyld_cache_local_symbols_entry
{
uint32_t dylibOffset;
uint32_t nlistStartIndex;
uint32_t nlistCount;
};
class RegisterContextDarwin_x86_64_Mach : public RegisterContextDarwin_x86_64
{
public:
RegisterContextDarwin_x86_64_Mach (lldb_private::Thread &thread, const DataExtractor &data) :
RegisterContextDarwin_x86_64 (thread, 0)
{
SetRegisterDataFrom_LC_THREAD (data);
}
void
InvalidateAllRegisters() override
{
// Do nothing... registers are always valid...
}
void
SetRegisterDataFrom_LC_THREAD (const DataExtractor &data)
{
lldb::offset_t offset = 0;
SetError (GPRRegSet, Read, -1);
SetError (FPURegSet, Read, -1);
SetError (EXCRegSet, Read, -1);
bool done = false;
while (!done)
{
int flavor = data.GetU32 (&offset);
if (flavor == 0)
done = true;
else
{
uint32_t i;
uint32_t count = data.GetU32 (&offset);
switch (flavor)
{
case GPRRegSet:
for (i=0; i<count; ++i)
(&gpr.rax)[i] = data.GetU64(&offset);
SetError (GPRRegSet, Read, 0);
done = true;
break;
case FPURegSet:
// TODO: fill in FPU regs....
//SetError (FPURegSet, Read, -1);
done = true;
break;
case EXCRegSet:
exc.trapno = data.GetU32(&offset);
exc.err = data.GetU32(&offset);
exc.faultvaddr = data.GetU64(&offset);
SetError (EXCRegSet, Read, 0);
done = true;
break;
case 7:
case 8:
case 9:
// fancy flavors that encapsulate of the above
// flavors...
break;
default:
done = true;
break;
}
}
}
}
static size_t
WriteRegister (RegisterContext *reg_ctx, const char *name, const char *alt_name, size_t reg_byte_size, Stream &data)
{
const RegisterInfo *reg_info = reg_ctx->GetRegisterInfoByName(name);
if (reg_info == NULL)
reg_info = reg_ctx->GetRegisterInfoByName(alt_name);
if (reg_info)
{
lldb_private::RegisterValue reg_value;
if (reg_ctx->ReadRegister(reg_info, reg_value))
{
if (reg_info->byte_size >= reg_byte_size)
data.Write(reg_value.GetBytes(), reg_byte_size);
else
{
data.Write(reg_value.GetBytes(), reg_info->byte_size);
for (size_t i=0, n = reg_byte_size - reg_info->byte_size; i<n; ++ i)
data.PutChar(0);
}
return reg_byte_size;
}
}
// Just write zeros if all else fails
for (size_t i=0; i<reg_byte_size; ++ i)
data.PutChar(0);
return reg_byte_size;
}
static bool
Create_LC_THREAD (Thread *thread, Stream &data)
{
RegisterContextSP reg_ctx_sp (thread->GetRegisterContext());
if (reg_ctx_sp)
{
RegisterContext *reg_ctx = reg_ctx_sp.get();
data.PutHex32 (GPRRegSet); // Flavor
data.PutHex32 (GPRWordCount);
WriteRegister (reg_ctx, "rax", NULL, 8, data);
WriteRegister (reg_ctx, "rbx", NULL, 8, data);
WriteRegister (reg_ctx, "rcx", NULL, 8, data);
WriteRegister (reg_ctx, "rdx", NULL, 8, data);
WriteRegister (reg_ctx, "rdi", NULL, 8, data);
WriteRegister (reg_ctx, "rsi", NULL, 8, data);
WriteRegister (reg_ctx, "rbp", NULL, 8, data);
WriteRegister (reg_ctx, "rsp", NULL, 8, data);
WriteRegister (reg_ctx, "r8", NULL, 8, data);
WriteRegister (reg_ctx, "r9", NULL, 8, data);
WriteRegister (reg_ctx, "r10", NULL, 8, data);
WriteRegister (reg_ctx, "r11", NULL, 8, data);
WriteRegister (reg_ctx, "r12", NULL, 8, data);
WriteRegister (reg_ctx, "r13", NULL, 8, data);
WriteRegister (reg_ctx, "r14", NULL, 8, data);
WriteRegister (reg_ctx, "r15", NULL, 8, data);
WriteRegister (reg_ctx, "rip", NULL, 8, data);
WriteRegister (reg_ctx, "rflags", NULL, 8, data);
WriteRegister (reg_ctx, "cs", NULL, 8, data);
WriteRegister (reg_ctx, "fs", NULL, 8, data);
WriteRegister (reg_ctx, "gs", NULL, 8, data);
// // Write out the FPU registers
// const size_t fpu_byte_size = sizeof(FPU);
// size_t bytes_written = 0;
// data.PutHex32 (FPURegSet);
// data.PutHex32 (fpu_byte_size/sizeof(uint64_t));
// bytes_written += data.PutHex32(0); // uint32_t pad[0]
// bytes_written += data.PutHex32(0); // uint32_t pad[1]
// bytes_written += WriteRegister (reg_ctx, "fcw", "fctrl", 2, data); // uint16_t fcw; // "fctrl"
// bytes_written += WriteRegister (reg_ctx, "fsw" , "fstat", 2, data); // uint16_t fsw; // "fstat"
// bytes_written += WriteRegister (reg_ctx, "ftw" , "ftag", 1, data); // uint8_t ftw; // "ftag"
// bytes_written += data.PutHex8 (0); // uint8_t pad1;
// bytes_written += WriteRegister (reg_ctx, "fop" , NULL, 2, data); // uint16_t fop; // "fop"
// bytes_written += WriteRegister (reg_ctx, "fioff", "ip", 4, data); // uint32_t ip; // "fioff"
// bytes_written += WriteRegister (reg_ctx, "fiseg", NULL, 2, data); // uint16_t cs; // "fiseg"
// bytes_written += data.PutHex16 (0); // uint16_t pad2;
// bytes_written += WriteRegister (reg_ctx, "dp", "fooff" , 4, data); // uint32_t dp; // "fooff"
// bytes_written += WriteRegister (reg_ctx, "foseg", NULL, 2, data); // uint16_t ds; // "foseg"
// bytes_written += data.PutHex16 (0); // uint16_t pad3;
// bytes_written += WriteRegister (reg_ctx, "mxcsr", NULL, 4, data); // uint32_t mxcsr;
// bytes_written += WriteRegister (reg_ctx, "mxcsrmask", NULL, 4, data);// uint32_t mxcsrmask;
// bytes_written += WriteRegister (reg_ctx, "stmm0", NULL, sizeof(MMSReg), data);
// bytes_written += WriteRegister (reg_ctx, "stmm1", NULL, sizeof(MMSReg), data);
// bytes_written += WriteRegister (reg_ctx, "stmm2", NULL, sizeof(MMSReg), data);
// bytes_written += WriteRegister (reg_ctx, "stmm3", NULL, sizeof(MMSReg), data);
// bytes_written += WriteRegister (reg_ctx, "stmm4", NULL, sizeof(MMSReg), data);
// bytes_written += WriteRegister (reg_ctx, "stmm5", NULL, sizeof(MMSReg), data);
// bytes_written += WriteRegister (reg_ctx, "stmm6", NULL, sizeof(MMSReg), data);
// bytes_written += WriteRegister (reg_ctx, "stmm7", NULL, sizeof(MMSReg), data);
// bytes_written += WriteRegister (reg_ctx, "xmm0" , NULL, sizeof(XMMReg), data);
// bytes_written += WriteRegister (reg_ctx, "xmm1" , NULL, sizeof(XMMReg), data);
// bytes_written += WriteRegister (reg_ctx, "xmm2" , NULL, sizeof(XMMReg), data);
// bytes_written += WriteRegister (reg_ctx, "xmm3" , NULL, sizeof(XMMReg), data);
// bytes_written += WriteRegister (reg_ctx, "xmm4" , NULL, sizeof(XMMReg), data);
// bytes_written += WriteRegister (reg_ctx, "xmm5" , NULL, sizeof(XMMReg), data);
// bytes_written += WriteRegister (reg_ctx, "xmm6" , NULL, sizeof(XMMReg), data);
// bytes_written += WriteRegister (reg_ctx, "xmm7" , NULL, sizeof(XMMReg), data);
// bytes_written += WriteRegister (reg_ctx, "xmm8" , NULL, sizeof(XMMReg), data);
// bytes_written += WriteRegister (reg_ctx, "xmm9" , NULL, sizeof(XMMReg), data);
// bytes_written += WriteRegister (reg_ctx, "xmm10", NULL, sizeof(XMMReg), data);
// bytes_written += WriteRegister (reg_ctx, "xmm11", NULL, sizeof(XMMReg), data);
// bytes_written += WriteRegister (reg_ctx, "xmm12", NULL, sizeof(XMMReg), data);
// bytes_written += WriteRegister (reg_ctx, "xmm13", NULL, sizeof(XMMReg), data);
// bytes_written += WriteRegister (reg_ctx, "xmm14", NULL, sizeof(XMMReg), data);
// bytes_written += WriteRegister (reg_ctx, "xmm15", NULL, sizeof(XMMReg), data);
//
// // Fill rest with zeros
// for (size_t i=0, n = fpu_byte_size - bytes_written; i<n; ++ i)
// data.PutChar(0);
// Write out the EXC registers
data.PutHex32 (EXCRegSet);
data.PutHex32 (EXCWordCount);
WriteRegister (reg_ctx, "trapno", NULL, 4, data);
WriteRegister (reg_ctx, "err", NULL, 4, data);
WriteRegister (reg_ctx, "faultvaddr", NULL, 8, data);
return true;
}
return false;
}
protected:
int
DoReadGPR(lldb::tid_t tid, int flavor, GPR &gpr) override
{
return 0;
}
int
DoReadFPU(lldb::tid_t tid, int flavor, FPU &fpu) override
{
return 0;
}
int
DoReadEXC(lldb::tid_t tid, int flavor, EXC &exc) override
{
return 0;
}
int
DoWriteGPR(lldb::tid_t tid, int flavor, const GPR &gpr) override
{
return 0;
}
int
DoWriteFPU(lldb::tid_t tid, int flavor, const FPU &fpu) override
{
return 0;
}
int
DoWriteEXC(lldb::tid_t tid, int flavor, const EXC &exc) override
{
return 0;
}
};
class RegisterContextDarwin_i386_Mach : public RegisterContextDarwin_i386
{
public:
RegisterContextDarwin_i386_Mach (lldb_private::Thread &thread, const DataExtractor &data) :
RegisterContextDarwin_i386 (thread, 0)
{
SetRegisterDataFrom_LC_THREAD (data);
}
void
InvalidateAllRegisters() override
{
// Do nothing... registers are always valid...
}
void
SetRegisterDataFrom_LC_THREAD (const DataExtractor &data)
{
lldb::offset_t offset = 0;
SetError (GPRRegSet, Read, -1);
SetError (FPURegSet, Read, -1);
SetError (EXCRegSet, Read, -1);
bool done = false;
while (!done)
{
int flavor = data.GetU32 (&offset);
if (flavor == 0)
done = true;
else
{
uint32_t i;
uint32_t count = data.GetU32 (&offset);
switch (flavor)
{
case GPRRegSet:
for (i=0; i<count; ++i)
(&gpr.eax)[i] = data.GetU32(&offset);
SetError (GPRRegSet, Read, 0);
done = true;
break;
case FPURegSet:
// TODO: fill in FPU regs....
//SetError (FPURegSet, Read, -1);
done = true;
break;
case EXCRegSet:
exc.trapno = data.GetU32(&offset);
exc.err = data.GetU32(&offset);
exc.faultvaddr = data.GetU32(&offset);
SetError (EXCRegSet, Read, 0);
done = true;
break;
case 7:
case 8:
case 9:
// fancy flavors that encapsulate of the above
// flavors...
break;
default:
done = true;
break;
}
}
}
}
static size_t
WriteRegister (RegisterContext *reg_ctx, const char *name, const char *alt_name, size_t reg_byte_size, Stream &data)
{
const RegisterInfo *reg_info = reg_ctx->GetRegisterInfoByName(name);
if (reg_info == NULL)
reg_info = reg_ctx->GetRegisterInfoByName(alt_name);
if (reg_info)
{
lldb_private::RegisterValue reg_value;
if (reg_ctx->ReadRegister(reg_info, reg_value))
{
if (reg_info->byte_size >= reg_byte_size)
data.Write(reg_value.GetBytes(), reg_byte_size);
else
{
data.Write(reg_value.GetBytes(), reg_info->byte_size);
for (size_t i=0, n = reg_byte_size - reg_info->byte_size; i<n; ++ i)
data.PutChar(0);
}
return reg_byte_size;
}
}
// Just write zeros if all else fails
for (size_t i=0; i<reg_byte_size; ++ i)
data.PutChar(0);
return reg_byte_size;
}
static bool
Create_LC_THREAD (Thread *thread, Stream &data)
{
RegisterContextSP reg_ctx_sp (thread->GetRegisterContext());
if (reg_ctx_sp)
{
RegisterContext *reg_ctx = reg_ctx_sp.get();
data.PutHex32 (GPRRegSet); // Flavor
data.PutHex32 (GPRWordCount);
WriteRegister (reg_ctx, "eax", NULL, 4, data);
WriteRegister (reg_ctx, "ebx", NULL, 4, data);
WriteRegister (reg_ctx, "ecx", NULL, 4, data);
WriteRegister (reg_ctx, "edx", NULL, 4, data);
WriteRegister (reg_ctx, "edi", NULL, 4, data);
WriteRegister (reg_ctx, "esi", NULL, 4, data);
WriteRegister (reg_ctx, "ebp", NULL, 4, data);
WriteRegister (reg_ctx, "esp", NULL, 4, data);
WriteRegister (reg_ctx, "ss", NULL, 4, data);
WriteRegister (reg_ctx, "eflags", NULL, 4, data);
WriteRegister (reg_ctx, "eip", NULL, 4, data);
WriteRegister (reg_ctx, "cs", NULL, 4, data);
WriteRegister (reg_ctx, "ds", NULL, 4, data);
WriteRegister (reg_ctx, "es", NULL, 4, data);
WriteRegister (reg_ctx, "fs", NULL, 4, data);
WriteRegister (reg_ctx, "gs", NULL, 4, data);
// Write out the EXC registers
data.PutHex32 (EXCRegSet);
data.PutHex32 (EXCWordCount);
WriteRegister (reg_ctx, "trapno", NULL, 4, data);
WriteRegister (reg_ctx, "err", NULL, 4, data);
WriteRegister (reg_ctx, "faultvaddr", NULL, 4, data);
return true;
}
return false;
}
protected:
int
DoReadGPR(lldb::tid_t tid, int flavor, GPR &gpr) override
{
return 0;
}
int
DoReadFPU(lldb::tid_t tid, int flavor, FPU &fpu) override
{
return 0;
}
int
DoReadEXC(lldb::tid_t tid, int flavor, EXC &exc) override
{
return 0;
}
int
DoWriteGPR(lldb::tid_t tid, int flavor, const GPR &gpr) override
{
return 0;
}
int
DoWriteFPU(lldb::tid_t tid, int flavor, const FPU &fpu) override
{
return 0;
}
int
DoWriteEXC(lldb::tid_t tid, int flavor, const EXC &exc) override
{
return 0;
}
};
class RegisterContextDarwin_arm_Mach : public RegisterContextDarwin_arm
{
public:
RegisterContextDarwin_arm_Mach (lldb_private::Thread &thread, const DataExtractor &data) :
RegisterContextDarwin_arm (thread, 0)
{
SetRegisterDataFrom_LC_THREAD (data);
}
void
InvalidateAllRegisters() override
{
// Do nothing... registers are always valid...
}
void
SetRegisterDataFrom_LC_THREAD (const DataExtractor &data)
{
lldb::offset_t offset = 0;
SetError (GPRRegSet, Read, -1);
SetError (FPURegSet, Read, -1);
SetError (EXCRegSet, Read, -1);
bool done = false;
while (!done)
{
int flavor = data.GetU32 (&offset);
uint32_t count = data.GetU32 (&offset);
lldb::offset_t next_thread_state = offset + (count * 4);
switch (flavor)
{
case GPRAltRegSet:
case GPRRegSet:
for (uint32_t i=0; i<count; ++i)
{
gpr.r[i] = data.GetU32(&offset);
}
// Note that gpr.cpsr is also copied by the above loop; this loop technically extends
// one element past the end of the gpr.r[] array.
SetError (GPRRegSet, Read, 0);
offset = next_thread_state;
break;
case FPURegSet:
{
uint8_t *fpu_reg_buf = (uint8_t*) &fpu.floats.s[0];
const int fpu_reg_buf_size = sizeof (fpu.floats);
if (data.ExtractBytes (offset, fpu_reg_buf_size, eByteOrderLittle, fpu_reg_buf) == fpu_reg_buf_size)
{
offset += fpu_reg_buf_size;
fpu.fpscr = data.GetU32(&offset);
SetError (FPURegSet, Read, 0);
}
else
{
done = true;
}
}
offset = next_thread_state;
break;
case EXCRegSet:
if (count == 3)
{
exc.exception = data.GetU32(&offset);
exc.fsr = data.GetU32(&offset);
exc.far = data.GetU32(&offset);
SetError (EXCRegSet, Read, 0);
}
done = true;
offset = next_thread_state;
break;
// Unknown register set flavor, stop trying to parse.
default:
done = true;
}
}
}
static size_t
WriteRegister (RegisterContext *reg_ctx, const char *name, const char *alt_name, size_t reg_byte_size, Stream &data)
{
const RegisterInfo *reg_info = reg_ctx->GetRegisterInfoByName(name);
if (reg_info == NULL)
reg_info = reg_ctx->GetRegisterInfoByName(alt_name);
if (reg_info)
{
lldb_private::RegisterValue reg_value;
if (reg_ctx->ReadRegister(reg_info, reg_value))
{
if (reg_info->byte_size >= reg_byte_size)
data.Write(reg_value.GetBytes(), reg_byte_size);
else
{
data.Write(reg_value.GetBytes(), reg_info->byte_size);
for (size_t i=0, n = reg_byte_size - reg_info->byte_size; i<n; ++ i)
data.PutChar(0);
}
return reg_byte_size;
}
}
// Just write zeros if all else fails
for (size_t i=0; i<reg_byte_size; ++ i)
data.PutChar(0);
return reg_byte_size;
}
static bool
Create_LC_THREAD (Thread *thread, Stream &data)
{
RegisterContextSP reg_ctx_sp (thread->GetRegisterContext());
if (reg_ctx_sp)
{
RegisterContext *reg_ctx = reg_ctx_sp.get();
data.PutHex32 (GPRRegSet); // Flavor
data.PutHex32 (GPRWordCount);
WriteRegister (reg_ctx, "r0", NULL, 4, data);
WriteRegister (reg_ctx, "r1", NULL, 4, data);
WriteRegister (reg_ctx, "r2", NULL, 4, data);
WriteRegister (reg_ctx, "r3", NULL, 4, data);
WriteRegister (reg_ctx, "r4", NULL, 4, data);
WriteRegister (reg_ctx, "r5", NULL, 4, data);
WriteRegister (reg_ctx, "r6", NULL, 4, data);
WriteRegister (reg_ctx, "r7", NULL, 4, data);
WriteRegister (reg_ctx, "r8", NULL, 4, data);
WriteRegister (reg_ctx, "r9", NULL, 4, data);
WriteRegister (reg_ctx, "r10", NULL, 4, data);
WriteRegister (reg_ctx, "r11", NULL, 4, data);
WriteRegister (reg_ctx, "r12", NULL, 4, data);
WriteRegister (reg_ctx, "sp", NULL, 4, data);
WriteRegister (reg_ctx, "lr", NULL, 4, data);
WriteRegister (reg_ctx, "pc", NULL, 4, data);
WriteRegister (reg_ctx, "cpsr", NULL, 4, data);
// Write out the EXC registers
// data.PutHex32 (EXCRegSet);
// data.PutHex32 (EXCWordCount);
// WriteRegister (reg_ctx, "exception", NULL, 4, data);
// WriteRegister (reg_ctx, "fsr", NULL, 4, data);
// WriteRegister (reg_ctx, "far", NULL, 4, data);
return true;
}
return false;
}
protected:
int
DoReadGPR(lldb::tid_t tid, int flavor, GPR &gpr) override
{
return -1;
}
int
DoReadFPU(lldb::tid_t tid, int flavor, FPU &fpu) override
{
return -1;
}
int
DoReadEXC(lldb::tid_t tid, int flavor, EXC &exc) override
{
return -1;
}
int
DoReadDBG(lldb::tid_t tid, int flavor, DBG &dbg) override
{
return -1;
}
int
DoWriteGPR(lldb::tid_t tid, int flavor, const GPR &gpr) override
{
return 0;
}
int
DoWriteFPU(lldb::tid_t tid, int flavor, const FPU &fpu) override
{
return 0;
}
int
DoWriteEXC(lldb::tid_t tid, int flavor, const EXC &exc) override
{
return 0;
}
int
DoWriteDBG(lldb::tid_t tid, int flavor, const DBG &dbg) override
{
return -1;
}
};
class RegisterContextDarwin_arm64_Mach : public RegisterContextDarwin_arm64
{
public:
RegisterContextDarwin_arm64_Mach (lldb_private::Thread &thread, const DataExtractor &data) :
RegisterContextDarwin_arm64 (thread, 0)
{
SetRegisterDataFrom_LC_THREAD (data);
}
void
InvalidateAllRegisters() override
{
// Do nothing... registers are always valid...
}
void
SetRegisterDataFrom_LC_THREAD (const DataExtractor &data)
{
lldb::offset_t offset = 0;
SetError (GPRRegSet, Read, -1);
SetError (FPURegSet, Read, -1);
SetError (EXCRegSet, Read, -1);
bool done = false;
while (!done)
{
int flavor = data.GetU32 (&offset);
uint32_t count = data.GetU32 (&offset);
lldb::offset_t next_thread_state = offset + (count * 4);
switch (flavor)
{
case GPRRegSet:
// x0-x29 + fp + lr + sp + pc (== 33 64-bit registers) plus cpsr (1 32-bit register)
if (count >= (33 * 2) + 1)
{
for (uint32_t i=0; i<33; ++i)
gpr.x[i] = data.GetU64(&offset);
gpr.cpsr = data.GetU32(&offset);
SetError (GPRRegSet, Read, 0);
}
offset = next_thread_state;
break;
case FPURegSet:
{
uint8_t *fpu_reg_buf = (uint8_t*) &fpu.v[0];
const int fpu_reg_buf_size = sizeof (fpu);
if (fpu_reg_buf_size == count
&& data.ExtractBytes (offset, fpu_reg_buf_size, eByteOrderLittle, fpu_reg_buf) == fpu_reg_buf_size)
{
SetError (FPURegSet, Read, 0);
}
else
{
done = true;
}
}
offset = next_thread_state;
break;
case EXCRegSet:
if (count == 4)
{
exc.far = data.GetU64(&offset);
exc.esr = data.GetU32(&offset);
exc.exception = data.GetU32(&offset);
SetError (EXCRegSet, Read, 0);
}
offset = next_thread_state;
break;
default:
done = true;
break;
}
}
}
static size_t
WriteRegister (RegisterContext *reg_ctx, const char *name, const char *alt_name, size_t reg_byte_size, Stream &data)
{
const RegisterInfo *reg_info = reg_ctx->GetRegisterInfoByName(name);
if (reg_info == NULL)
reg_info = reg_ctx->GetRegisterInfoByName(alt_name);
if (reg_info)
{
lldb_private::RegisterValue reg_value;
if (reg_ctx->ReadRegister(reg_info, reg_value))
{
if (reg_info->byte_size >= reg_byte_size)
data.Write(reg_value.GetBytes(), reg_byte_size);
else
{
data.Write(reg_value.GetBytes(), reg_info->byte_size);
for (size_t i=0, n = reg_byte_size - reg_info->byte_size; i<n; ++ i)
data.PutChar(0);
}
return reg_byte_size;
}
}
// Just write zeros if all else fails
for (size_t i=0; i<reg_byte_size; ++ i)
data.PutChar(0);
return reg_byte_size;
}
static bool
Create_LC_THREAD (Thread *thread, Stream &data)
{
RegisterContextSP reg_ctx_sp (thread->GetRegisterContext());
if (reg_ctx_sp)
{
RegisterContext *reg_ctx = reg_ctx_sp.get();
data.PutHex32 (GPRRegSet); // Flavor
data.PutHex32 (GPRWordCount);
WriteRegister (reg_ctx, "x0", NULL, 8, data);
WriteRegister (reg_ctx, "x1", NULL, 8, data);
WriteRegister (reg_ctx, "x2", NULL, 8, data);
WriteRegister (reg_ctx, "x3", NULL, 8, data);
WriteRegister (reg_ctx, "x4", NULL, 8, data);
WriteRegister (reg_ctx, "x5", NULL, 8, data);
WriteRegister (reg_ctx, "x6", NULL, 8, data);
WriteRegister (reg_ctx, "x7", NULL, 8, data);
WriteRegister (reg_ctx, "x8", NULL, 8, data);
WriteRegister (reg_ctx, "x9", NULL, 8, data);
WriteRegister (reg_ctx, "x10", NULL, 8, data);
WriteRegister (reg_ctx, "x11", NULL, 8, data);
WriteRegister (reg_ctx, "x12", NULL, 8, data);
WriteRegister (reg_ctx, "x13", NULL, 8, data);
WriteRegister (reg_ctx, "x14", NULL, 8, data);
WriteRegister (reg_ctx, "x15", NULL, 8, data);
WriteRegister (reg_ctx, "x16", NULL, 8, data);
WriteRegister (reg_ctx, "x17", NULL, 8, data);
WriteRegister (reg_ctx, "x18", NULL, 8, data);
WriteRegister (reg_ctx, "x19", NULL, 8, data);
WriteRegister (reg_ctx, "x20", NULL, 8, data);
WriteRegister (reg_ctx, "x21", NULL, 8, data);
WriteRegister (reg_ctx, "x22", NULL, 8, data);
WriteRegister (reg_ctx, "x23", NULL, 8, data);
WriteRegister (reg_ctx, "x24", NULL, 8, data);
WriteRegister (reg_ctx, "x25", NULL, 8, data);
WriteRegister (reg_ctx, "x26", NULL, 8, data);
WriteRegister (reg_ctx, "x27", NULL, 8, data);
WriteRegister (reg_ctx, "x28", NULL, 8, data);
WriteRegister (reg_ctx, "fp", NULL, 8, data);
WriteRegister (reg_ctx, "lr", NULL, 8, data);
WriteRegister (reg_ctx, "sp", NULL, 8, data);
WriteRegister (reg_ctx, "pc", NULL, 8, data);
WriteRegister (reg_ctx, "cpsr", NULL, 4, data);
// Write out the EXC registers
// data.PutHex32 (EXCRegSet);
// data.PutHex32 (EXCWordCount);
// WriteRegister (reg_ctx, "far", NULL, 8, data);
// WriteRegister (reg_ctx, "esr", NULL, 4, data);
// WriteRegister (reg_ctx, "exception", NULL, 4, data);
return true;
}
return false;
}
protected:
int
DoReadGPR(lldb::tid_t tid, int flavor, GPR &gpr) override
{
return -1;
}
int
DoReadFPU(lldb::tid_t tid, int flavor, FPU &fpu) override
{
return -1;
}
int
DoReadEXC(lldb::tid_t tid, int flavor, EXC &exc) override
{
return -1;
}
int
DoReadDBG(lldb::tid_t tid, int flavor, DBG &dbg) override
{
return -1;
}
int
DoWriteGPR(lldb::tid_t tid, int flavor, const GPR &gpr) override
{
return 0;
}
int
DoWriteFPU(lldb::tid_t tid, int flavor, const FPU &fpu) override
{
return 0;
}
int
DoWriteEXC(lldb::tid_t tid, int flavor, const EXC &exc) override
{
return 0;
}
int
DoWriteDBG(lldb::tid_t tid, int flavor, const DBG &dbg) override
{
return -1;
}
};
static uint32_t
MachHeaderSizeFromMagic(uint32_t magic)
{
switch (magic)
{
case MH_MAGIC:
case MH_CIGAM:
return sizeof(struct mach_header);
case MH_MAGIC_64:
case MH_CIGAM_64:
return sizeof(struct mach_header_64);
break;
default:
break;
}
return 0;
}
#define MACHO_NLIST_ARM_SYMBOL_IS_THUMB 0x0008
void
ObjectFileMachO::Initialize()
{
PluginManager::RegisterPlugin (GetPluginNameStatic(),
GetPluginDescriptionStatic(),
CreateInstance,
CreateMemoryInstance,
GetModuleSpecifications,
SaveCore);
}
void
ObjectFileMachO::Terminate()
{
PluginManager::UnregisterPlugin (CreateInstance);
}
lldb_private::ConstString
ObjectFileMachO::GetPluginNameStatic()
{
static ConstString g_name("mach-o");
return g_name;
}
const char *
ObjectFileMachO::GetPluginDescriptionStatic()
{
return "Mach-o object file reader (32 and 64 bit)";
}
ObjectFile *
ObjectFileMachO::CreateInstance (const lldb::ModuleSP &module_sp,
DataBufferSP& data_sp,
lldb::offset_t data_offset,
const FileSpec* file,
lldb::offset_t file_offset,
lldb::offset_t length)
{
if (!data_sp)
{
data_sp = file->MemoryMapFileContentsIfLocal(file_offset, length);
data_offset = 0;
}
if (ObjectFileMachO::MagicBytesMatch(data_sp, data_offset, length))
{
// Update the data to contain the entire file if it doesn't already
if (data_sp->GetByteSize() < length)
{
data_sp = file->MemoryMapFileContentsIfLocal(file_offset, length);
data_offset = 0;
}
std::unique_ptr<ObjectFile> objfile_ap(new ObjectFileMachO (module_sp, data_sp, data_offset, file, file_offset, length));
if (objfile_ap.get() && objfile_ap->ParseHeader())
return objfile_ap.release();
}
return NULL;
}
ObjectFile *
ObjectFileMachO::CreateMemoryInstance (const lldb::ModuleSP &module_sp,
DataBufferSP& data_sp,
const ProcessSP &process_sp,
lldb::addr_t header_addr)
{
if (ObjectFileMachO::MagicBytesMatch(data_sp, 0, data_sp->GetByteSize()))
{
std::unique_ptr<ObjectFile> objfile_ap(new ObjectFileMachO (module_sp, data_sp, process_sp, header_addr));
if (objfile_ap.get() && objfile_ap->ParseHeader())
return objfile_ap.release();
}
return NULL;
}
size_t
ObjectFileMachO::GetModuleSpecifications (const lldb_private::FileSpec& file,
lldb::DataBufferSP& data_sp,
lldb::offset_t data_offset,
lldb::offset_t file_offset,
lldb::offset_t length,
lldb_private::ModuleSpecList &specs)
{
const size_t initial_count = specs.GetSize();
if (ObjectFileMachO::MagicBytesMatch(data_sp, 0, data_sp->GetByteSize()))
{
DataExtractor data;
data.SetData(data_sp);
llvm::MachO::mach_header header;
if (ParseHeader (data, &data_offset, header))
{
size_t header_and_load_cmds = header.sizeofcmds + MachHeaderSizeFromMagic(header.magic);
if (header_and_load_cmds >= data_sp->GetByteSize())
{
data_sp = file.ReadFileContents(file_offset, header_and_load_cmds);
data.SetData(data_sp);
data_offset = MachHeaderSizeFromMagic(header.magic);
}
if (data_sp)
{
ModuleSpec spec;
spec.GetFileSpec() = file;
spec.SetObjectOffset(file_offset);
spec.SetObjectSize(length);
if (GetArchitecture (header, data, data_offset, spec.GetArchitecture()))
{
if (spec.GetArchitecture().IsValid())
{
GetUUID (header, data, data_offset, spec.GetUUID());
specs.Append(spec);
}
}
}
}
}
return specs.GetSize() - initial_count;
}
const ConstString &
ObjectFileMachO::GetSegmentNameTEXT()
{
static ConstString g_segment_name_TEXT ("__TEXT");
return g_segment_name_TEXT;
}
const ConstString &
ObjectFileMachO::GetSegmentNameDATA()
{
static ConstString g_segment_name_DATA ("__DATA");
return g_segment_name_DATA;
}
const ConstString &
ObjectFileMachO::GetSegmentNameDATA_DIRTY()
{
static ConstString g_segment_name ("__DATA_DIRTY");
return g_segment_name;
}
const ConstString &
ObjectFileMachO::GetSegmentNameDATA_CONST()
{
static ConstString g_segment_name ("__DATA_CONST");
return g_segment_name;
}
const ConstString &
ObjectFileMachO::GetSegmentNameOBJC()
{
static ConstString g_segment_name_OBJC ("__OBJC");
return g_segment_name_OBJC;
}
const ConstString &
ObjectFileMachO::GetSegmentNameLINKEDIT()
{
static ConstString g_section_name_LINKEDIT ("__LINKEDIT");
return g_section_name_LINKEDIT;
}
const ConstString &
ObjectFileMachO::GetSectionNameEHFrame()
{
static ConstString g_section_name_eh_frame ("__eh_frame");
return g_section_name_eh_frame;
}
bool
ObjectFileMachO::MagicBytesMatch (DataBufferSP& data_sp,
lldb::addr_t data_offset,
lldb::addr_t data_length)
{
DataExtractor data;
data.SetData (data_sp, data_offset, data_length);
lldb::offset_t offset = 0;
uint32_t magic = data.GetU32(&offset);
return MachHeaderSizeFromMagic(magic) != 0;
}
ObjectFileMachO::ObjectFileMachO(const lldb::ModuleSP &module_sp,
DataBufferSP& data_sp,
lldb::offset_t data_offset,
const FileSpec* file,
lldb::offset_t file_offset,
lldb::offset_t length) :
ObjectFile(module_sp, file, file_offset, length, data_sp, data_offset),
m_mach_segments(),
m_mach_sections(),
m_entry_point_address(),
m_thread_context_offsets(),
m_thread_context_offsets_valid(false)
{
::memset (&m_header, 0, sizeof(m_header));
::memset (&m_dysymtab, 0, sizeof(m_dysymtab));
}
ObjectFileMachO::ObjectFileMachO (const lldb::ModuleSP &module_sp,
lldb::DataBufferSP& header_data_sp,
const lldb::ProcessSP &process_sp,
lldb::addr_t header_addr) :
ObjectFile(module_sp, process_sp, header_addr, header_data_sp),
m_mach_segments(),
m_mach_sections(),
m_entry_point_address(),
m_thread_context_offsets(),
m_thread_context_offsets_valid(false)
{
::memset (&m_header, 0, sizeof(m_header));
::memset (&m_dysymtab, 0, sizeof(m_dysymtab));
}
bool
ObjectFileMachO::ParseHeader (DataExtractor &data,
lldb::offset_t *data_offset_ptr,
llvm::MachO::mach_header &header)
{
data.SetByteOrder (endian::InlHostByteOrder());
// Leave magic in the original byte order
header.magic = data.GetU32(data_offset_ptr);
bool can_parse = false;
bool is_64_bit = false;
switch (header.magic)
{
case MH_MAGIC:
data.SetByteOrder (endian::InlHostByteOrder());
data.SetAddressByteSize(4);
can_parse = true;
break;
case MH_MAGIC_64:
data.SetByteOrder (endian::InlHostByteOrder());
data.SetAddressByteSize(8);
can_parse = true;
is_64_bit = true;
break;
case MH_CIGAM:
data.SetByteOrder(endian::InlHostByteOrder() == eByteOrderBig ? eByteOrderLittle : eByteOrderBig);
data.SetAddressByteSize(4);
can_parse = true;
break;
case MH_CIGAM_64:
data.SetByteOrder(endian::InlHostByteOrder() == eByteOrderBig ? eByteOrderLittle : eByteOrderBig);
data.SetAddressByteSize(8);
is_64_bit = true;
can_parse = true;
break;
default:
break;
}
if (can_parse)
{
data.GetU32(data_offset_ptr, &header.cputype, 6);
if (is_64_bit)
*data_offset_ptr += 4;
return true;
}
else
{
memset(&header, 0, sizeof(header));
}
return false;
}
bool
ObjectFileMachO::ParseHeader ()
{
ModuleSP module_sp(GetModule());
if (module_sp)
{
lldb_private::Mutex::Locker locker(module_sp->GetMutex());
bool can_parse = false;
lldb::offset_t offset = 0;
m_data.SetByteOrder (endian::InlHostByteOrder());
// Leave magic in the original byte order
m_header.magic = m_data.GetU32(&offset);
switch (m_header.magic)
{
case MH_MAGIC:
m_data.SetByteOrder (endian::InlHostByteOrder());
m_data.SetAddressByteSize(4);
can_parse = true;
break;
case MH_MAGIC_64:
m_data.SetByteOrder (endian::InlHostByteOrder());
m_data.SetAddressByteSize(8);
can_parse = true;
break;
case MH_CIGAM:
m_data.SetByteOrder(endian::InlHostByteOrder() == eByteOrderBig ? eByteOrderLittle : eByteOrderBig);
m_data.SetAddressByteSize(4);
can_parse = true;
break;
case MH_CIGAM_64:
m_data.SetByteOrder(endian::InlHostByteOrder() == eByteOrderBig ? eByteOrderLittle : eByteOrderBig);
m_data.SetAddressByteSize(8);
can_parse = true;
break;
default:
break;
}
if (can_parse)
{
m_data.GetU32(&offset, &m_header.cputype, 6);
ArchSpec mach_arch;
if (GetArchitecture (mach_arch))
{
// Check if the module has a required architecture
const ArchSpec &module_arch = module_sp->GetArchitecture();
if (module_arch.IsValid() && !module_arch.IsCompatibleMatch(mach_arch))
return false;
if (SetModulesArchitecture (mach_arch))
{
const size_t header_and_lc_size = m_header.sizeofcmds + MachHeaderSizeFromMagic(m_header.magic);
if (m_data.GetByteSize() < header_and_lc_size)
{
DataBufferSP data_sp;
ProcessSP process_sp (m_process_wp.lock());
if (process_sp)
{
data_sp = ReadMemory (process_sp, m_memory_addr, header_and_lc_size);
}
else
{
// Read in all only the load command data from the file on disk
data_sp = m_file.ReadFileContents(m_file_offset, header_and_lc_size);
if (data_sp->GetByteSize() != header_and_lc_size)
return false;
}
if (data_sp)
m_data.SetData (data_sp);
}
}
return true;
}
}
else
{
memset(&m_header, 0, sizeof(struct mach_header));
}
}
return false;
}
ByteOrder
ObjectFileMachO::GetByteOrder () const
{
return m_data.GetByteOrder ();
}
bool
ObjectFileMachO::IsExecutable() const
{
return m_header.filetype == MH_EXECUTE;
}
uint32_t
ObjectFileMachO::GetAddressByteSize () const
{
return m_data.GetAddressByteSize ();
}
AddressClass
ObjectFileMachO::GetAddressClass (lldb::addr_t file_addr)
{
Symtab *symtab = GetSymtab();
if (symtab)
{
Symbol *symbol = symtab->FindSymbolContainingFileAddress(file_addr);
if (symbol)
{
if (symbol->ValueIsAddress())
{
SectionSP section_sp (symbol->GetAddressRef().GetSection());
if (section_sp)
{
const lldb::SectionType section_type = section_sp->GetType();
switch (section_type)
{
case eSectionTypeInvalid:
return eAddressClassUnknown;
case eSectionTypeCode:
if (m_header.cputype == llvm::MachO::CPU_TYPE_ARM)
{
// For ARM we have a bit in the n_desc field of the symbol
// that tells us ARM/Thumb which is bit 0x0008.
if (symbol->GetFlags() & MACHO_NLIST_ARM_SYMBOL_IS_THUMB)
return eAddressClassCodeAlternateISA;
}
return eAddressClassCode;
case eSectionTypeContainer:
return eAddressClassUnknown;
case eSectionTypeData:
case eSectionTypeDataCString:
case eSectionTypeDataCStringPointers:
case eSectionTypeDataSymbolAddress:
case eSectionTypeData4:
case eSectionTypeData8:
case eSectionTypeData16:
case eSectionTypeDataPointers:
case eSectionTypeZeroFill:
case eSectionTypeDataObjCMessageRefs:
case eSectionTypeDataObjCCFStrings:
case eSectionTypeGoSymtab:
return eAddressClassData;
case eSectionTypeDebug:
case eSectionTypeDWARFDebugAbbrev:
case eSectionTypeDWARFDebugAddr:
case eSectionTypeDWARFDebugAranges:
case eSectionTypeDWARFDebugFrame:
case eSectionTypeDWARFDebugInfo:
case eSectionTypeDWARFDebugLine:
case eSectionTypeDWARFDebugLoc:
case eSectionTypeDWARFDebugMacInfo:
case eSectionTypeDWARFDebugMacro:
case eSectionTypeDWARFDebugPubNames:
case eSectionTypeDWARFDebugPubTypes:
case eSectionTypeDWARFDebugRanges:
case eSectionTypeDWARFDebugStr:
case eSectionTypeDWARFDebugStrOffsets:
case eSectionTypeDWARFAppleNames:
case eSectionTypeDWARFAppleTypes:
case eSectionTypeDWARFAppleNamespaces:
case eSectionTypeDWARFAppleObjC:
return eAddressClassDebug;
case eSectionTypeEHFrame:
case eSectionTypeARMexidx:
case eSectionTypeARMextab:
case eSectionTypeCompactUnwind:
return eAddressClassRuntime;
case eSectionTypeAbsoluteAddress:
case eSectionTypeELFSymbolTable:
case eSectionTypeELFDynamicSymbols:
case eSectionTypeELFRelocationEntries:
case eSectionTypeELFDynamicLinkInfo:
case eSectionTypeOther:
return eAddressClassUnknown;
}
}
}
const SymbolType symbol_type = symbol->GetType();
switch (symbol_type)
{
case eSymbolTypeAny: return eAddressClassUnknown;
case eSymbolTypeAbsolute: return eAddressClassUnknown;
case eSymbolTypeCode:
case eSymbolTypeTrampoline:
case eSymbolTypeResolver:
if (m_header.cputype == llvm::MachO::CPU_TYPE_ARM)
{
// For ARM we have a bit in the n_desc field of the symbol
// that tells us ARM/Thumb which is bit 0x0008.
if (symbol->GetFlags() & MACHO_NLIST_ARM_SYMBOL_IS_THUMB)
return eAddressClassCodeAlternateISA;
}
return eAddressClassCode;
case eSymbolTypeData: return eAddressClassData;
case eSymbolTypeRuntime: return eAddressClassRuntime;
case eSymbolTypeException: return eAddressClassRuntime;
case eSymbolTypeSourceFile: return eAddressClassDebug;
case eSymbolTypeHeaderFile: return eAddressClassDebug;
case eSymbolTypeObjectFile: return eAddressClassDebug;
case eSymbolTypeCommonBlock: return eAddressClassDebug;
case eSymbolTypeBlock: return eAddressClassDebug;
case eSymbolTypeLocal: return eAddressClassData;
case eSymbolTypeParam: return eAddressClassData;
case eSymbolTypeVariable: return eAddressClassData;
case eSymbolTypeVariableType: return eAddressClassDebug;
case eSymbolTypeLineEntry: return eAddressClassDebug;
case eSymbolTypeLineHeader: return eAddressClassDebug;
case eSymbolTypeScopeBegin: return eAddressClassDebug;
case eSymbolTypeScopeEnd: return eAddressClassDebug;
case eSymbolTypeAdditional: return eAddressClassUnknown;
case eSymbolTypeCompiler: return eAddressClassDebug;
case eSymbolTypeInstrumentation:return eAddressClassDebug;
case eSymbolTypeUndefined: return eAddressClassUnknown;
case eSymbolTypeObjCClass: return eAddressClassRuntime;
case eSymbolTypeObjCMetaClass: return eAddressClassRuntime;
case eSymbolTypeObjCIVar: return eAddressClassRuntime;
case eSymbolTypeReExported: return eAddressClassRuntime;
}
}
}
return eAddressClassUnknown;
}
Symtab *
ObjectFileMachO::GetSymtab()
{
ModuleSP module_sp(GetModule());
if (module_sp)
{
lldb_private::Mutex::Locker locker(module_sp->GetMutex());
if (m_symtab_ap.get() == NULL)
{
m_symtab_ap.reset(new Symtab(this));
Mutex::Locker symtab_locker (m_symtab_ap->GetMutex());
ParseSymtab ();
m_symtab_ap->Finalize ();
}
}
return m_symtab_ap.get();
}
bool
ObjectFileMachO::IsStripped ()
{
if (m_dysymtab.cmd == 0)
{
ModuleSP module_sp(GetModule());
if (module_sp)
{
lldb::offset_t offset = MachHeaderSizeFromMagic(m_header.magic);
for (uint32_t i=0; i<m_header.ncmds; ++i)
{
const lldb::offset_t load_cmd_offset = offset;
load_command lc;
if (m_data.GetU32(&offset, &lc.cmd, 2) == NULL)
break;
if (lc.cmd == LC_DYSYMTAB)
{
m_dysymtab.cmd = lc.cmd;
m_dysymtab.cmdsize = lc.cmdsize;
if (m_data.GetU32 (&offset, &m_dysymtab.ilocalsym, (sizeof(m_dysymtab) / sizeof(uint32_t)) - 2) == NULL)
{
// Clear m_dysymtab if we were unable to read all items from the load command
::memset (&m_dysymtab, 0, sizeof(m_dysymtab));
}
}
offset = load_cmd_offset + lc.cmdsize;
}
}
}
if (m_dysymtab.cmd)
return m_dysymtab.nlocalsym <= 1;
return false;
}
void
ObjectFileMachO::CreateSections (SectionList &unified_section_list)
{
if (!m_sections_ap.get())
{
m_sections_ap.reset(new SectionList());
const bool is_dsym = (m_header.filetype == MH_DSYM);
lldb::user_id_t segID = 0;
lldb::user_id_t sectID = 0;
lldb::offset_t offset = MachHeaderSizeFromMagic(m_header.magic);
uint32_t i;
const bool is_core = GetType() == eTypeCoreFile;
//bool dump_sections = false;
ModuleSP module_sp (GetModule());
// First look up any LC_ENCRYPTION_INFO load commands
typedef RangeArray<uint32_t, uint32_t, 8> EncryptedFileRanges;
EncryptedFileRanges encrypted_file_ranges;
encryption_info_command encryption_cmd;
for (i=0; i<m_header.ncmds; ++i)
{
const lldb::offset_t load_cmd_offset = offset;
if (m_data.GetU32(&offset, &encryption_cmd, 2) == NULL)
break;
// LC_ENCRYPTION_INFO and LC_ENCRYPTION_INFO_64 have the same sizes for
// the 3 fields we care about, so treat them the same.
if (encryption_cmd.cmd == LC_ENCRYPTION_INFO || encryption_cmd.cmd == LC_ENCRYPTION_INFO_64)
{
if (m_data.GetU32(&offset, &encryption_cmd.cryptoff, 3))
{
if (encryption_cmd.cryptid != 0)
{
EncryptedFileRanges::Entry entry;
entry.SetRangeBase(encryption_cmd.cryptoff);
entry.SetByteSize(encryption_cmd.cryptsize);
encrypted_file_ranges.Append(entry);
}
}
}
offset = load_cmd_offset + encryption_cmd.cmdsize;
}
bool section_file_addresses_changed = false;
offset = MachHeaderSizeFromMagic(m_header.magic);
struct segment_command_64 load_cmd;
for (i=0; i<m_header.ncmds; ++i)
{
const lldb::offset_t load_cmd_offset = offset;
if (m_data.GetU32(&offset, &load_cmd, 2) == NULL)
break;
if (load_cmd.cmd == LC_SEGMENT || load_cmd.cmd == LC_SEGMENT_64)
{
if (m_data.GetU8(&offset, (uint8_t*)load_cmd.segname, 16))
{
bool add_section = true;
bool add_to_unified = true;
ConstString const_segname (load_cmd.segname, std::min<size_t>(strlen(load_cmd.segname), sizeof(load_cmd.segname)));
SectionSP unified_section_sp(unified_section_list.FindSectionByName(const_segname));
if (is_dsym && unified_section_sp)
{
if (const_segname == GetSegmentNameLINKEDIT())
{
// We need to keep the __LINKEDIT segment private to this object file only
add_to_unified = false;
}
else
{
// This is the dSYM file and this section has already been created by
// the object file, no need to create it.
add_section = false;
}
}
load_cmd.vmaddr = m_data.GetAddress(&offset);
load_cmd.vmsize = m_data.GetAddress(&offset);
load_cmd.fileoff = m_data.GetAddress(&offset);
load_cmd.filesize = m_data.GetAddress(&offset);
if (m_length != 0 && load_cmd.filesize != 0)
{
if (load_cmd.fileoff > m_length)
{
// We have a load command that says it extends past the end of the file. This is likely
// a corrupt file. We don't have any way to return an error condition here (this method
// was likely invoked from something like ObjectFile::GetSectionList()) -- all we can do
// is null out the SectionList vector and if a process has been set up, dump a message
// to stdout. The most common case here is core file debugging with a truncated file.
const char *lc_segment_name = load_cmd.cmd == LC_SEGMENT_64 ? "LC_SEGMENT_64" : "LC_SEGMENT";
module_sp->ReportWarning("load command %u %s has a fileoff (0x%" PRIx64 ") that extends beyond the end of the file (0x%" PRIx64 "), ignoring this section",
i,
lc_segment_name,
load_cmd.fileoff,
m_length);
load_cmd.fileoff = 0;
load_cmd.filesize = 0;
}
if (load_cmd.fileoff + load_cmd.filesize > m_length)
{
// We have a load command that says it extends past the end of the file. This is likely
// a corrupt file. We don't have any way to return an error condition here (this method
// was likely invoked from something like ObjectFile::GetSectionList()) -- all we can do
// is null out the SectionList vector and if a process has been set up, dump a message
// to stdout. The most common case here is core file debugging with a truncated file.
const char *lc_segment_name = load_cmd.cmd == LC_SEGMENT_64 ? "LC_SEGMENT_64" : "LC_SEGMENT";
GetModule()->ReportWarning("load command %u %s has a fileoff + filesize (0x%" PRIx64 ") that extends beyond the end of the file (0x%" PRIx64 "), the segment will be truncated to match",
i,
lc_segment_name,
load_cmd.fileoff + load_cmd.filesize,
m_length);
// Tuncase the length
load_cmd.filesize = m_length - load_cmd.fileoff;
}
}
if (m_data.GetU32(&offset, &load_cmd.maxprot, 4))
{
const bool segment_is_encrypted = (load_cmd.flags & SG_PROTECTED_VERSION_1) != 0;
// Keep a list of mach segments around in case we need to
// get at data that isn't stored in the abstracted Sections.
m_mach_segments.push_back (load_cmd);
// Use a segment ID of the segment index shifted left by 8 so they
// never conflict with any of the sections.
SectionSP segment_sp;
if (add_section && (const_segname || is_core))
{
segment_sp.reset(new Section (module_sp, // Module to which this section belongs
this, // Object file to which this sections belongs
++segID << 8, // Section ID is the 1 based segment index shifted right by 8 bits as not to collide with any of the 256 section IDs that are possible
const_segname, // Name of this section
eSectionTypeContainer, // This section is a container of other sections.
load_cmd.vmaddr, // File VM address == addresses as they are found in the object file
load_cmd.vmsize, // VM size in bytes of this section
load_cmd.fileoff, // Offset to the data for this section in the file
load_cmd.filesize, // Size in bytes of this section as found in the file
0, // Segments have no alignment information
load_cmd.flags)); // Flags for this section
segment_sp->SetIsEncrypted (segment_is_encrypted);
m_sections_ap->AddSection(segment_sp);
if (add_to_unified)
unified_section_list.AddSection(segment_sp);
}
else if (unified_section_sp)
{
if (is_dsym && unified_section_sp->GetFileAddress() != load_cmd.vmaddr)
{
// Check to see if the module was read from memory?
if (module_sp->GetObjectFile()->GetHeaderAddress().IsValid())
{
// We have a module that is in memory and needs to have its
// file address adjusted. We need to do this because when we
// load a file from memory, its addresses will be slid already,
// yet the addresses in the new symbol file will still be unslid.
// Since everything is stored as section offset, this shouldn't
// cause any problems.
// Make sure we've parsed the symbol table from the
// ObjectFile before we go around changing its Sections.
module_sp->GetObjectFile()->GetSymtab();
// eh_frame would present the same problems but we parse that on
// a per-function basis as-needed so it's more difficult to
// remove its use of the Sections. Realistically, the environments
// where this code path will be taken will not have eh_frame sections.
unified_section_sp->SetFileAddress(load_cmd.vmaddr);
// Notify the module that the section addresses have been changed once
// we're done so any file-address caches can be updated.
section_file_addresses_changed = true;
}
}
m_sections_ap->AddSection(unified_section_sp);
}
struct section_64 sect64;
::memset (&sect64, 0, sizeof(sect64));
// Push a section into our mach sections for the section at
// index zero (NO_SECT) if we don't have any mach sections yet...
if (m_mach_sections.empty())
m_mach_sections.push_back(sect64);
uint32_t segment_sect_idx;
const lldb::user_id_t first_segment_sectID = sectID + 1;
const uint32_t num_u32s = load_cmd.cmd == LC_SEGMENT ? 7 : 8;
for (segment_sect_idx=0; segment_sect_idx<load_cmd.nsects; ++segment_sect_idx)
{
if (m_data.GetU8(&offset, (uint8_t*)sect64.sectname, sizeof(sect64.sectname)) == NULL)
break;
if (m_data.GetU8(&offset, (uint8_t*)sect64.segname, sizeof(sect64.segname)) == NULL)
break;
sect64.addr = m_data.GetAddress(&offset);
sect64.size = m_data.GetAddress(&offset);
if (m_data.GetU32(&offset, &sect64.offset, num_u32s) == NULL)
break;
// Keep a list of mach sections around in case we need to
// get at data that isn't stored in the abstracted Sections.
m_mach_sections.push_back (sect64);
if (add_section)
{
ConstString section_name (sect64.sectname, std::min<size_t>(strlen(sect64.sectname), sizeof(sect64.sectname)));
if (!const_segname)
{
// We have a segment with no name so we need to conjure up
// segments that correspond to the section's segname if there
// isn't already such a section. If there is such a section,
// we resize the section so that it spans all sections.
// We also mark these sections as fake so address matches don't
// hit if they land in the gaps between the child sections.
const_segname.SetTrimmedCStringWithLength(sect64.segname, sizeof(sect64.segname));
segment_sp = unified_section_list.FindSectionByName (const_segname);
if (segment_sp.get())
{
Section *segment = segment_sp.get();
// Grow the section size as needed.
const lldb::addr_t sect64_min_addr = sect64.addr;
const lldb::addr_t sect64_max_addr = sect64_min_addr + sect64.size;
const lldb::addr_t curr_seg_byte_size = segment->GetByteSize();
const lldb::addr_t curr_seg_min_addr = segment->GetFileAddress();
const lldb::addr_t curr_seg_max_addr = curr_seg_min_addr + curr_seg_byte_size;
if (sect64_min_addr >= curr_seg_min_addr)
{
const lldb::addr_t new_seg_byte_size = sect64_max_addr - curr_seg_min_addr;
// Only grow the section size if needed
if (new_seg_byte_size > curr_seg_byte_size)
segment->SetByteSize (new_seg_byte_size);
}
else
{
// We need to change the base address of the segment and
// adjust the child section offsets for all existing children.
const lldb::addr_t slide_amount = sect64_min_addr - curr_seg_min_addr;
segment->Slide(slide_amount, false);
segment->GetChildren().Slide(-slide_amount, false);
segment->SetByteSize (curr_seg_max_addr - sect64_min_addr);
}
// Grow the section size as needed.
if (sect64.offset)
{
const lldb::addr_t segment_min_file_offset = segment->GetFileOffset();
const lldb::addr_t segment_max_file_offset = segment_min_file_offset + segment->GetFileSize();
const lldb::addr_t section_min_file_offset = sect64.offset;
const lldb::addr_t section_max_file_offset = section_min_file_offset + sect64.size;
const lldb::addr_t new_file_offset = std::min (section_min_file_offset, segment_min_file_offset);
const lldb::addr_t new_file_size = std::max (section_max_file_offset, segment_max_file_offset) - new_file_offset;
segment->SetFileOffset (new_file_offset);
segment->SetFileSize (new_file_size);
}
}
else
{
// Create a fake section for the section's named segment
segment_sp.reset(new Section (segment_sp, // Parent section
module_sp, // Module to which this section belongs
this, // Object file to which this section belongs
++segID << 8, // Section ID is the 1 based segment index shifted right by 8 bits as not to collide with any of the 256 section IDs that are possible
const_segname, // Name of this section
eSectionTypeContainer, // This section is a container of other sections.
sect64.addr, // File VM address == addresses as they are found in the object file
sect64.size, // VM size in bytes of this section
sect64.offset, // Offset to the data for this section in the file
sect64.offset ? sect64.size : 0, // Size in bytes of this section as found in the file
sect64.align,
load_cmd.flags)); // Flags for this section
segment_sp->SetIsFake(true);
m_sections_ap->AddSection(segment_sp);
if (add_to_unified)
unified_section_list.AddSection(segment_sp);
segment_sp->SetIsEncrypted (segment_is_encrypted);
}
}
assert (segment_sp.get());
lldb::SectionType sect_type = eSectionTypeOther;
if (sect64.flags & (S_ATTR_PURE_INSTRUCTIONS | S_ATTR_SOME_INSTRUCTIONS))
sect_type = eSectionTypeCode;
else
{
uint32_t mach_sect_type = sect64.flags & SECTION_TYPE;
static ConstString g_sect_name_objc_data ("__objc_data");
static ConstString g_sect_name_objc_msgrefs ("__objc_msgrefs");
static ConstString g_sect_name_objc_selrefs ("__objc_selrefs");
static ConstString g_sect_name_objc_classrefs ("__objc_classrefs");
static ConstString g_sect_name_objc_superrefs ("__objc_superrefs");
static ConstString g_sect_name_objc_const ("__objc_const");
static ConstString g_sect_name_objc_classlist ("__objc_classlist");
static ConstString g_sect_name_cfstring ("__cfstring");
static ConstString g_sect_name_dwarf_debug_abbrev ("__debug_abbrev");
static ConstString g_sect_name_dwarf_debug_aranges ("__debug_aranges");
static ConstString g_sect_name_dwarf_debug_frame ("__debug_frame");
static ConstString g_sect_name_dwarf_debug_info ("__debug_info");
static ConstString g_sect_name_dwarf_debug_line ("__debug_line");
static ConstString g_sect_name_dwarf_debug_loc ("__debug_loc");
static ConstString g_sect_name_dwarf_debug_macinfo ("__debug_macinfo");
static ConstString g_sect_name_dwarf_debug_pubnames ("__debug_pubnames");
static ConstString g_sect_name_dwarf_debug_pubtypes ("__debug_pubtypes");
static ConstString g_sect_name_dwarf_debug_ranges ("__debug_ranges");
static ConstString g_sect_name_dwarf_debug_str ("__debug_str");
static ConstString g_sect_name_dwarf_apple_names ("__apple_names");
static ConstString g_sect_name_dwarf_apple_types ("__apple_types");
static ConstString g_sect_name_dwarf_apple_namespaces ("__apple_namespac");
static ConstString g_sect_name_dwarf_apple_objc ("__apple_objc");
static ConstString g_sect_name_eh_frame ("__eh_frame");
static ConstString g_sect_name_compact_unwind ("__unwind_info");
static ConstString g_sect_name_text ("__text");
static ConstString g_sect_name_data ("__data");
static ConstString g_sect_name_go_symtab ("__gosymtab");
if (section_name == g_sect_name_dwarf_debug_abbrev)
sect_type = eSectionTypeDWARFDebugAbbrev;
else if (section_name == g_sect_name_dwarf_debug_aranges)
sect_type = eSectionTypeDWARFDebugAranges;
else if (section_name == g_sect_name_dwarf_debug_frame)
sect_type = eSectionTypeDWARFDebugFrame;
else if (section_name == g_sect_name_dwarf_debug_info)
sect_type = eSectionTypeDWARFDebugInfo;
else if (section_name == g_sect_name_dwarf_debug_line)
sect_type = eSectionTypeDWARFDebugLine;
else if (section_name == g_sect_name_dwarf_debug_loc)
sect_type = eSectionTypeDWARFDebugLoc;
else if (section_name == g_sect_name_dwarf_debug_macinfo)
sect_type = eSectionTypeDWARFDebugMacInfo;
else if (section_name == g_sect_name_dwarf_debug_pubnames)
sect_type = eSectionTypeDWARFDebugPubNames;
else if (section_name == g_sect_name_dwarf_debug_pubtypes)
sect_type = eSectionTypeDWARFDebugPubTypes;
else if (section_name == g_sect_name_dwarf_debug_ranges)
sect_type = eSectionTypeDWARFDebugRanges;
else if (section_name == g_sect_name_dwarf_debug_str)
sect_type = eSectionTypeDWARFDebugStr;
else if (section_name == g_sect_name_dwarf_apple_names)
sect_type = eSectionTypeDWARFAppleNames;
else if (section_name == g_sect_name_dwarf_apple_types)
sect_type = eSectionTypeDWARFAppleTypes;
else if (section_name == g_sect_name_dwarf_apple_namespaces)
sect_type = eSectionTypeDWARFAppleNamespaces;
else if (section_name == g_sect_name_dwarf_apple_objc)
sect_type = eSectionTypeDWARFAppleObjC;
else if (section_name == g_sect_name_objc_selrefs)
sect_type = eSectionTypeDataCStringPointers;
else if (section_name == g_sect_name_objc_msgrefs)
sect_type = eSectionTypeDataObjCMessageRefs;
else if (section_name == g_sect_name_eh_frame)
sect_type = eSectionTypeEHFrame;
else if (section_name == g_sect_name_compact_unwind)
sect_type = eSectionTypeCompactUnwind;
else if (section_name == g_sect_name_cfstring)
sect_type = eSectionTypeDataObjCCFStrings;
else if (section_name == g_sect_name_go_symtab)
sect_type = eSectionTypeGoSymtab;
else if (section_name == g_sect_name_objc_data ||
section_name == g_sect_name_objc_classrefs ||
section_name == g_sect_name_objc_superrefs ||
section_name == g_sect_name_objc_const ||
section_name == g_sect_name_objc_classlist)
{
sect_type = eSectionTypeDataPointers;
}
if (sect_type == eSectionTypeOther)
{
switch (mach_sect_type)
{
// TODO: categorize sections by other flags for regular sections
case S_REGULAR:
if (section_name == g_sect_name_text)
sect_type = eSectionTypeCode;
else if (section_name == g_sect_name_data)
sect_type = eSectionTypeData;
else
sect_type = eSectionTypeOther;
break;
case S_ZEROFILL: sect_type = eSectionTypeZeroFill; break;
case S_CSTRING_LITERALS: sect_type = eSectionTypeDataCString; break; // section with only literal C strings
case S_4BYTE_LITERALS: sect_type = eSectionTypeData4; break; // section with only 4 byte literals
case S_8BYTE_LITERALS: sect_type = eSectionTypeData8; break; // section with only 8 byte literals
case S_LITERAL_POINTERS: sect_type = eSectionTypeDataPointers; break; // section with only pointers to literals
case S_NON_LAZY_SYMBOL_POINTERS: sect_type = eSectionTypeDataPointers; break; // section with only non-lazy symbol pointers
case S_LAZY_SYMBOL_POINTERS: sect_type = eSectionTypeDataPointers; break; // section with only lazy symbol pointers
case S_SYMBOL_STUBS: sect_type = eSectionTypeCode; break; // section with only symbol stubs, byte size of stub in the reserved2 field
case S_MOD_INIT_FUNC_POINTERS: sect_type = eSectionTypeDataPointers; break; // section with only function pointers for initialization
case S_MOD_TERM_FUNC_POINTERS: sect_type = eSectionTypeDataPointers; break; // section with only function pointers for termination
case S_COALESCED: sect_type = eSectionTypeOther; break;
case S_GB_ZEROFILL: sect_type = eSectionTypeZeroFill; break;
case S_INTERPOSING: sect_type = eSectionTypeCode; break; // section with only pairs of function pointers for interposing
case S_16BYTE_LITERALS: sect_type = eSectionTypeData16; break; // section with only 16 byte literals
case S_DTRACE_DOF: sect_type = eSectionTypeDebug; break;
case S_LAZY_DYLIB_SYMBOL_POINTERS: sect_type = eSectionTypeDataPointers; break;
default: break;
}
}
}
SectionSP section_sp(new Section (segment_sp,
module_sp,
this,
++sectID,
section_name,
sect_type,
sect64.addr - segment_sp->GetFileAddress(),
sect64.size,
sect64.offset,
sect64.offset == 0 ? 0 : sect64.size,
sect64.align,
sect64.flags));
// Set the section to be encrypted to match the segment
bool section_is_encrypted = false;
if (!segment_is_encrypted && load_cmd.filesize != 0)
section_is_encrypted = encrypted_file_ranges.FindEntryThatContains(sect64.offset) != NULL;
section_sp->SetIsEncrypted (segment_is_encrypted || section_is_encrypted);
segment_sp->GetChildren().AddSection(section_sp);
if (segment_sp->IsFake())
{
segment_sp.reset();
const_segname.Clear();
}
}
}
if (segment_sp && is_dsym)
{
if (first_segment_sectID <= sectID)
{
lldb::user_id_t sect_uid;
for (sect_uid = first_segment_sectID; sect_uid <= sectID; ++sect_uid)
{
SectionSP curr_section_sp(segment_sp->GetChildren().FindSectionByID (sect_uid));
SectionSP next_section_sp;
if (sect_uid + 1 <= sectID)
next_section_sp = segment_sp->GetChildren().FindSectionByID (sect_uid+1);
if (curr_section_sp.get())
{
if (curr_section_sp->GetByteSize() == 0)
{
if (next_section_sp.get() != NULL)
curr_section_sp->SetByteSize ( next_section_sp->GetFileAddress() - curr_section_sp->GetFileAddress() );
else
curr_section_sp->SetByteSize ( load_cmd.vmsize );
}
}
}
}
}
}
}
}
else if (load_cmd.cmd == LC_DYSYMTAB)
{
m_dysymtab.cmd = load_cmd.cmd;
m_dysymtab.cmdsize = load_cmd.cmdsize;
m_data.GetU32 (&offset, &m_dysymtab.ilocalsym, (sizeof(m_dysymtab) / sizeof(uint32_t)) - 2);
}
offset = load_cmd_offset + load_cmd.cmdsize;
}
if (section_file_addresses_changed && module_sp.get())
{
module_sp->SectionFileAddressesChanged();
}
}
}
class MachSymtabSectionInfo
{
public:
MachSymtabSectionInfo (SectionList *section_list) :
m_section_list (section_list),
m_section_infos()
{
// Get the number of sections down to a depth of 1 to include
// all segments and their sections, but no other sections that
// may be added for debug map or
m_section_infos.resize(section_list->GetNumSections(1));
}
SectionSP
GetSection (uint8_t n_sect, addr_t file_addr)
{
if (n_sect == 0)
return SectionSP();
if (n_sect < m_section_infos.size())
{
if (!m_section_infos[n_sect].section_sp)
{
SectionSP section_sp (m_section_list->FindSectionByID (n_sect));
m_section_infos[n_sect].section_sp = section_sp;
if (section_sp)
{
m_section_infos[n_sect].vm_range.SetBaseAddress (section_sp->GetFileAddress());
m_section_infos[n_sect].vm_range.SetByteSize (section_sp->GetByteSize());
}
else
{
Host::SystemLog (Host::eSystemLogError, "error: unable to find section for section %u\n", n_sect);
}
}
if (m_section_infos[n_sect].vm_range.Contains(file_addr))
{
// Symbol is in section.
return m_section_infos[n_sect].section_sp;
}
else if (m_section_infos[n_sect].vm_range.GetByteSize () == 0 &&
m_section_infos[n_sect].vm_range.GetBaseAddress() == file_addr)
{
// Symbol is in section with zero size, but has the same start
// address as the section. This can happen with linker symbols
// (symbols that start with the letter 'l' or 'L'.
return m_section_infos[n_sect].section_sp;
}
}
return m_section_list->FindSectionContainingFileAddress(file_addr);
}
protected:
struct SectionInfo
{
SectionInfo () :
vm_range(),
section_sp ()
{
}
VMRange vm_range;
SectionSP section_sp;
};
SectionList *m_section_list;
std::vector<SectionInfo> m_section_infos;
};
struct TrieEntry
{
TrieEntry () :
name(),
address(LLDB_INVALID_ADDRESS),
flags (0),
other(0),
import_name()
{
}
void
Clear ()
{
name.Clear();
address = LLDB_INVALID_ADDRESS;
flags = 0;
other = 0;
import_name.Clear();
}
void
Dump () const
{
printf ("0x%16.16llx 0x%16.16llx 0x%16.16llx \"%s\"",
static_cast<unsigned long long>(address),
static_cast<unsigned long long>(flags),
static_cast<unsigned long long>(other), name.GetCString());
if (import_name)
printf (" -> \"%s\"\n", import_name.GetCString());
else
printf ("\n");
}
ConstString name;
uint64_t address;
uint64_t flags;
uint64_t other;
ConstString import_name;
};
struct TrieEntryWithOffset
{
lldb::offset_t nodeOffset;
TrieEntry entry;
TrieEntryWithOffset (lldb::offset_t offset) :
nodeOffset (offset),
entry()
{
}
void
Dump (uint32_t idx) const
{
printf ("[%3u] 0x%16.16llx: ", idx,
static_cast<unsigned long long>(nodeOffset));
entry.Dump();
}
bool
operator<(const TrieEntryWithOffset& other) const
{
return ( nodeOffset < other.nodeOffset );
}
};
static bool
ParseTrieEntries (DataExtractor &data,
lldb::offset_t offset,
const bool is_arm,
std::vector<llvm::StringRef> &nameSlices,
std::set<lldb::addr_t> &resolver_addresses,
std::vector<TrieEntryWithOffset>& output)
{
if (!data.ValidOffset(offset))
return true;
const uint64_t terminalSize = data.GetULEB128(&offset);
lldb::offset_t children_offset = offset + terminalSize;
if ( terminalSize != 0 ) {
TrieEntryWithOffset e (offset);
e.entry.flags = data.GetULEB128(&offset);
const char *import_name = NULL;
if ( e.entry.flags & EXPORT_SYMBOL_FLAGS_REEXPORT ) {
e.entry.address = 0;
e.entry.other = data.GetULEB128(&offset); // dylib ordinal
import_name = data.GetCStr(&offset);
}
else {
e.entry.address = data.GetULEB128(&offset);
if ( e.entry.flags & EXPORT_SYMBOL_FLAGS_STUB_AND_RESOLVER )
{
e.entry.other = data.GetULEB128(&offset);
uint64_t resolver_addr = e.entry.other;
if (is_arm)
resolver_addr &= THUMB_ADDRESS_BIT_MASK;
resolver_addresses.insert(resolver_addr);
}
else
e.entry.other = 0;
}
// Only add symbols that are reexport symbols with a valid import name
if (EXPORT_SYMBOL_FLAGS_REEXPORT & e.entry.flags && import_name && import_name[0])
{
std::string name;
if (!nameSlices.empty())
{
for (auto name_slice: nameSlices)
name.append(name_slice.data(), name_slice.size());
}
if (name.size() > 1)
{
// Skip the leading '_'
e.entry.name.SetCStringWithLength(name.c_str() + 1,name.size() - 1);
}
if (import_name)
{
// Skip the leading '_'
e.entry.import_name.SetCString(import_name+1);
}
output.push_back(e);
}
}
const uint8_t childrenCount = data.GetU8(&children_offset);
for (uint8_t i=0; i < childrenCount; ++i) {
const char *cstr = data.GetCStr(&children_offset);
if (cstr)
nameSlices.push_back(llvm::StringRef(cstr));
else
return false; // Corrupt data
lldb::offset_t childNodeOffset = data.GetULEB128(&children_offset);
if (childNodeOffset)
{
if (!ParseTrieEntries(data,
childNodeOffset,
is_arm,
nameSlices,
resolver_addresses,
output))
{
return false;
}
}
nameSlices.pop_back();
}
return true;
}
// Read the UUID out of a dyld_shared_cache file on-disk.
UUID
ObjectFileMachO::GetSharedCacheUUID (FileSpec dyld_shared_cache, const ByteOrder byte_order, const uint32_t addr_byte_size)
{
UUID dsc_uuid;
DataBufferSP dsc_data_sp = dyld_shared_cache.MemoryMapFileContentsIfLocal(0, sizeof(struct lldb_copy_dyld_cache_header_v1));
if (dsc_data_sp)
{
DataExtractor dsc_header_data (dsc_data_sp, byte_order, addr_byte_size);
char version_str[7];
lldb::offset_t offset = 0;
memcpy (version_str, dsc_header_data.GetData (&offset, 6), 6);
version_str[6] = '\0';
if (strcmp (version_str, "dyld_v") == 0)
{
offset = offsetof (struct lldb_copy_dyld_cache_header_v1, uuid);
uint8_t uuid_bytes[sizeof (uuid_t)];
memcpy (uuid_bytes, dsc_header_data.GetData (&offset, sizeof (uuid_t)), sizeof (uuid_t));
dsc_uuid.SetBytes (uuid_bytes);
}
}
return dsc_uuid;
}
size_t
ObjectFileMachO::ParseSymtab ()
{
Timer scoped_timer(__PRETTY_FUNCTION__,
"ObjectFileMachO::ParseSymtab () module = %s",
m_file.GetFilename().AsCString(""));
ModuleSP module_sp (GetModule());
if (!module_sp)
return 0;
struct symtab_command symtab_load_command = { 0, 0, 0, 0, 0, 0 };
struct linkedit_data_command function_starts_load_command = { 0, 0, 0, 0 };
struct dyld_info_command dyld_info = { 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0 };
typedef AddressDataArray<lldb::addr_t, bool, 100> FunctionStarts;
FunctionStarts function_starts;
lldb::offset_t offset = MachHeaderSizeFromMagic(m_header.magic);
uint32_t i;
FileSpecList dylib_files;
Log *log(lldb_private::GetLogIfAllCategoriesSet (LIBLLDB_LOG_SYMBOLS));
static const llvm::StringRef g_objc_v2_prefix_class ("_OBJC_CLASS_$_");
static const llvm::StringRef g_objc_v2_prefix_metaclass ("_OBJC_METACLASS_$_");
static const llvm::StringRef g_objc_v2_prefix_ivar ("_OBJC_IVAR_$_");
for (i=0; i<m_header.ncmds; ++i)
{
const lldb::offset_t cmd_offset = offset;
// Read in the load command and load command size
struct load_command lc;
if (m_data.GetU32(&offset, &lc, 2) == NULL)
break;
// Watch for the symbol table load command
switch (lc.cmd)
{
case LC_SYMTAB:
symtab_load_command.cmd = lc.cmd;
symtab_load_command.cmdsize = lc.cmdsize;
// Read in the rest of the symtab load command
if (m_data.GetU32(&offset, &symtab_load_command.symoff, 4) == 0) // fill in symoff, nsyms, stroff, strsize fields
return 0;
if (symtab_load_command.symoff == 0)
{
if (log)
module_sp->LogMessage(log, "LC_SYMTAB.symoff == 0");
return 0;
}
if (symtab_load_command.stroff == 0)
{
if (log)
module_sp->LogMessage(log, "LC_SYMTAB.stroff == 0");
return 0;
}
if (symtab_load_command.nsyms == 0)
{
if (log)
module_sp->LogMessage(log, "LC_SYMTAB.nsyms == 0");
return 0;
}
if (symtab_load_command.strsize == 0)
{
if (log)
module_sp->LogMessage(log, "LC_SYMTAB.strsize == 0");
return 0;
}
break;
case LC_DYLD_INFO:
case LC_DYLD_INFO_ONLY:
if (m_data.GetU32(&offset, &dyld_info.rebase_off, 10))
{
dyld_info.cmd = lc.cmd;
dyld_info.cmdsize = lc.cmdsize;
}
else
{
memset (&dyld_info, 0, sizeof(dyld_info));
}
break;
case LC_LOAD_DYLIB:
case LC_LOAD_WEAK_DYLIB:
case LC_REEXPORT_DYLIB:
case LC_LOADFVMLIB:
case LC_LOAD_UPWARD_DYLIB:
{
uint32_t name_offset = cmd_offset + m_data.GetU32(&offset);
const char *path = m_data.PeekCStr(name_offset);
if (path)
{
FileSpec file_spec(path, false);
// Strip the path if there is @rpath, @executable, etc so we just use the basename
if (path[0] == '@')
file_spec.GetDirectory().Clear();
if (lc.cmd == LC_REEXPORT_DYLIB)
{
m_reexported_dylibs.AppendIfUnique(file_spec);
}
dylib_files.Append(file_spec);
}
}
break;
case LC_FUNCTION_STARTS:
function_starts_load_command.cmd = lc.cmd;
function_starts_load_command.cmdsize = lc.cmdsize;
if (m_data.GetU32(&offset, &function_starts_load_command.dataoff, 2) == NULL) // fill in symoff, nsyms, stroff, strsize fields
memset (&function_starts_load_command, 0, sizeof(function_starts_load_command));
break;
default:
break;
}
offset = cmd_offset + lc.cmdsize;
}
if (symtab_load_command.cmd)
{
Symtab *symtab = m_symtab_ap.get();
SectionList *section_list = GetSectionList();
if (section_list == NULL)
return 0;
const uint32_t addr_byte_size = m_data.GetAddressByteSize();
const ByteOrder byte_order = m_data.GetByteOrder();
bool bit_width_32 = addr_byte_size == 4;
const size_t nlist_byte_size = bit_width_32 ? sizeof(struct nlist) : sizeof(struct nlist_64);
DataExtractor nlist_data (NULL, 0, byte_order, addr_byte_size);
DataExtractor strtab_data (NULL, 0, byte_order, addr_byte_size);
DataExtractor function_starts_data (NULL, 0, byte_order, addr_byte_size);
DataExtractor indirect_symbol_index_data (NULL, 0, byte_order, addr_byte_size);
DataExtractor dyld_trie_data (NULL, 0, byte_order, addr_byte_size);
const addr_t nlist_data_byte_size = symtab_load_command.nsyms * nlist_byte_size;
const addr_t strtab_data_byte_size = symtab_load_command.strsize;
addr_t strtab_addr = LLDB_INVALID_ADDRESS;
ProcessSP process_sp (m_process_wp.lock());
Process *process = process_sp.get();
uint32_t memory_module_load_level = eMemoryModuleLoadLevelComplete;
if (process && m_header.filetype != llvm::MachO::MH_OBJECT)
{
Target &target = process->GetTarget();
memory_module_load_level = target.GetMemoryModuleLoadLevel();
SectionSP linkedit_section_sp(section_list->FindSectionByName(GetSegmentNameLINKEDIT()));
// Reading mach file from memory in a process or core file...
if (linkedit_section_sp)
{
addr_t linkedit_load_addr = linkedit_section_sp->GetLoadBaseAddress(&target);
if (linkedit_load_addr == LLDB_INVALID_ADDRESS)
{
// We might be trying to access the symbol table before the __LINKEDIT's load
// address has been set in the target. We can't fail to read the symbol table,
// so calculate the right address manually
linkedit_load_addr = CalculateSectionLoadAddressForMemoryImage(m_memory_addr, GetMachHeaderSection(), linkedit_section_sp.get());
}
const addr_t linkedit_file_offset = linkedit_section_sp->GetFileOffset();
const addr_t symoff_addr = linkedit_load_addr + symtab_load_command.symoff - linkedit_file_offset;
strtab_addr = linkedit_load_addr + symtab_load_command.stroff - linkedit_file_offset;
bool data_was_read = false;
#if defined (__APPLE__) && (defined (__arm__) || defined (__arm64__) || defined (__aarch64__))
if (m_header.flags & 0x80000000u && process->GetAddressByteSize() == sizeof (void*))
{
// This mach-o memory file is in the dyld shared cache. If this
// program is not remote and this is iOS, then this process will
// share the same shared cache as the process we are debugging and
// we can read the entire __LINKEDIT from the address space in this
// process. This is a needed optimization that is used for local iOS
// debugging only since all shared libraries in the shared cache do
// not have corresponding files that exist in the file system of the
// device. They have been combined into a single file. This means we
// always have to load these files from memory. All of the symbol and
// string tables from all of the __LINKEDIT sections from the shared
// libraries in the shared cache have been merged into a single large
// symbol and string table. Reading all of this symbol and string table
// data across can slow down debug launch times, so we optimize this by
// reading the memory for the __LINKEDIT section from this process.
UUID lldb_shared_cache(GetLLDBSharedCacheUUID());
UUID process_shared_cache(GetProcessSharedCacheUUID(process));
bool use_lldb_cache = true;
if (lldb_shared_cache.IsValid() && process_shared_cache.IsValid() && lldb_shared_cache != process_shared_cache)
{
use_lldb_cache = false;
ModuleSP module_sp (GetModule());
if (module_sp)
module_sp->ReportWarning ("shared cache in process does not match lldb's own shared cache, startup will be slow.");
}
PlatformSP platform_sp (target.GetPlatform());
if (platform_sp && platform_sp->IsHost() && use_lldb_cache)
{
data_was_read = true;
nlist_data.SetData((void *)symoff_addr, nlist_data_byte_size, eByteOrderLittle);
strtab_data.SetData((void *)strtab_addr, strtab_data_byte_size, eByteOrderLittle);
if (function_starts_load_command.cmd)
{
const addr_t func_start_addr = linkedit_load_addr + function_starts_load_command.dataoff - linkedit_file_offset;
function_starts_data.SetData ((void *)func_start_addr, function_starts_load_command.datasize, eByteOrderLittle);
}
}
}
#endif
if (!data_was_read)
{
if (memory_module_load_level == eMemoryModuleLoadLevelComplete)
{
DataBufferSP nlist_data_sp (ReadMemory (process_sp, symoff_addr, nlist_data_byte_size));
if (nlist_data_sp)
nlist_data.SetData (nlist_data_sp, 0, nlist_data_sp->GetByteSize());
// Load strings individually from memory when loading from memory since shared cache
// string tables contain strings for all symbols from all shared cached libraries
//DataBufferSP strtab_data_sp (ReadMemory (process_sp, strtab_addr, strtab_data_byte_size));
//if (strtab_data_sp)
// strtab_data.SetData (strtab_data_sp, 0, strtab_data_sp->GetByteSize());
if (m_dysymtab.nindirectsyms != 0)
{
const addr_t indirect_syms_addr = linkedit_load_addr + m_dysymtab.indirectsymoff - linkedit_file_offset;
DataBufferSP indirect_syms_data_sp (ReadMemory (process_sp, indirect_syms_addr, m_dysymtab.nindirectsyms * 4));
if (indirect_syms_data_sp)
indirect_symbol_index_data.SetData (indirect_syms_data_sp, 0, indirect_syms_data_sp->GetByteSize());
}
}
if (memory_module_load_level >= eMemoryModuleLoadLevelPartial)
{
if (function_starts_load_command.cmd)
{
const addr_t func_start_addr = linkedit_load_addr + function_starts_load_command.dataoff - linkedit_file_offset;
DataBufferSP func_start_data_sp (ReadMemory (process_sp, func_start_addr, function_starts_load_command.datasize));
if (func_start_data_sp)
function_starts_data.SetData (func_start_data_sp, 0, func_start_data_sp->GetByteSize());
}
}
}
}
}
else
{
nlist_data.SetData (m_data,
symtab_load_command.symoff,
nlist_data_byte_size);
strtab_data.SetData (m_data,
symtab_load_command.stroff,
strtab_data_byte_size);
if (dyld_info.export_size > 0)
{
dyld_trie_data.SetData (m_data,
dyld_info.export_off,
dyld_info.export_size);
}
if (m_dysymtab.nindirectsyms != 0)
{
indirect_symbol_index_data.SetData (m_data,
m_dysymtab.indirectsymoff,
m_dysymtab.nindirectsyms * 4);
}
if (function_starts_load_command.cmd)
{
function_starts_data.SetData (m_data,
function_starts_load_command.dataoff,
function_starts_load_command.datasize);
}
}
if (nlist_data.GetByteSize() == 0 && memory_module_load_level == eMemoryModuleLoadLevelComplete)
{
if (log)
module_sp->LogMessage(log, "failed to read nlist data");
return 0;
}
const bool have_strtab_data = strtab_data.GetByteSize() > 0;
if (!have_strtab_data)
{
if (process)
{
if (strtab_addr == LLDB_INVALID_ADDRESS)
{
if (log)
module_sp->LogMessage(log, "failed to locate the strtab in memory");
return 0;
}
}
else
{
if (log)
module_sp->LogMessage(log, "failed to read strtab data");
return 0;
}
}
const ConstString &g_segment_name_TEXT = GetSegmentNameTEXT();
const ConstString &g_segment_name_DATA = GetSegmentNameDATA();
const ConstString &g_segment_name_DATA_DIRTY = GetSegmentNameDATA_DIRTY();
const ConstString &g_segment_name_DATA_CONST = GetSegmentNameDATA_CONST();
const ConstString &g_segment_name_OBJC = GetSegmentNameOBJC();
const ConstString &g_section_name_eh_frame = GetSectionNameEHFrame();
SectionSP text_section_sp(section_list->FindSectionByName(g_segment_name_TEXT));
SectionSP data_section_sp(section_list->FindSectionByName(g_segment_name_DATA));
SectionSP data_dirty_section_sp(section_list->FindSectionByName(g_segment_name_DATA_DIRTY));
SectionSP data_const_section_sp(section_list->FindSectionByName(g_segment_name_DATA_CONST));
SectionSP objc_section_sp(section_list->FindSectionByName(g_segment_name_OBJC));
SectionSP eh_frame_section_sp;
if (text_section_sp.get())
eh_frame_section_sp = text_section_sp->GetChildren().FindSectionByName (g_section_name_eh_frame);
else
eh_frame_section_sp = section_list->FindSectionByName (g_section_name_eh_frame);
const bool is_arm = (m_header.cputype == llvm::MachO::CPU_TYPE_ARM);
// lldb works best if it knows the start address of all functions in a module.
// Linker symbols or debug info are normally the best source of information for start addr / size but
// they may be stripped in a released binary.
// Two additional sources of information exist in Mach-O binaries:
// LC_FUNCTION_STARTS - a list of ULEB128 encoded offsets of each function's start address in the
// binary, relative to the text section.
// eh_frame - the eh_frame FDEs have the start addr & size of each function
// LC_FUNCTION_STARTS is the fastest source to read in, and is present on all modern binaries.
// Binaries built to run on older releases may need to use eh_frame information.
if (text_section_sp && function_starts_data.GetByteSize())
{
FunctionStarts::Entry function_start_entry;
function_start_entry.data = false;
lldb::offset_t function_start_offset = 0;
function_start_entry.addr = text_section_sp->GetFileAddress();
uint64_t delta;
while ((delta = function_starts_data.GetULEB128(&function_start_offset)) > 0)
{
// Now append the current entry
function_start_entry.addr += delta;
function_starts.Append(function_start_entry);
}
}
else
{
// If m_type is eTypeDebugInfo, then this is a dSYM - it will have the load command claiming an eh_frame
// but it doesn't actually have the eh_frame content. And if we have a dSYM, we don't need to do any
// of this fill-in-the-missing-symbols works anyway - the debug info should give us all the functions in
// the module.
if (text_section_sp.get() && eh_frame_section_sp.get() && m_type != eTypeDebugInfo)
{
DWARFCallFrameInfo eh_frame(*this, eh_frame_section_sp, eRegisterKindEHFrame, true);
DWARFCallFrameInfo::FunctionAddressAndSizeVector functions;
eh_frame.GetFunctionAddressAndSizeVector (functions);
addr_t text_base_addr = text_section_sp->GetFileAddress();
size_t count = functions.GetSize();
for (size_t i = 0; i < count; ++i)
{
const DWARFCallFrameInfo::FunctionAddressAndSizeVector::Entry *func = functions.GetEntryAtIndex (i);
if (func)
{
FunctionStarts::Entry function_start_entry;
function_start_entry.addr = func->base - text_base_addr;
function_starts.Append(function_start_entry);
}
}
}
}
const size_t function_starts_count = function_starts.GetSize();
const user_id_t TEXT_eh_frame_sectID =
eh_frame_section_sp.get() ? eh_frame_section_sp->GetID()
: static_cast<user_id_t>(NO_SECT);
lldb::offset_t nlist_data_offset = 0;
uint32_t N_SO_index = UINT32_MAX;
MachSymtabSectionInfo section_info (section_list);
std::vector<uint32_t> N_FUN_indexes;
std::vector<uint32_t> N_NSYM_indexes;
std::vector<uint32_t> N_INCL_indexes;
std::vector<uint32_t> N_BRAC_indexes;
std::vector<uint32_t> N_COMM_indexes;
typedef std::multimap <uint64_t, uint32_t> ValueToSymbolIndexMap;
typedef std::map <uint32_t, uint32_t> NListIndexToSymbolIndexMap;
typedef std::map <const char *, uint32_t> ConstNameToSymbolIndexMap;
ValueToSymbolIndexMap N_FUN_addr_to_sym_idx;
ValueToSymbolIndexMap N_STSYM_addr_to_sym_idx;
ConstNameToSymbolIndexMap N_GSYM_name_to_sym_idx;
// Any symbols that get merged into another will get an entry
// in this map so we know
NListIndexToSymbolIndexMap m_nlist_idx_to_sym_idx;
uint32_t nlist_idx = 0;
Symbol *symbol_ptr = NULL;
uint32_t sym_idx = 0;
Symbol *sym = NULL;
size_t num_syms = 0;
std::string memory_symbol_name;
uint32_t unmapped_local_symbols_found = 0;
std::vector<TrieEntryWithOffset> trie_entries;
std::set<lldb::addr_t> resolver_addresses;
if (dyld_trie_data.GetByteSize() > 0)
{
std::vector<llvm::StringRef> nameSlices;
ParseTrieEntries (dyld_trie_data,
0,
is_arm,
nameSlices,
resolver_addresses,
trie_entries);
ConstString text_segment_name ("__TEXT");
SectionSP text_segment_sp = GetSectionList()->FindSectionByName(text_segment_name);
if (text_segment_sp)
{
const lldb::addr_t text_segment_file_addr = text_segment_sp->GetFileAddress();
if (text_segment_file_addr != LLDB_INVALID_ADDRESS)
{
for (auto &e : trie_entries)
e.entry.address += text_segment_file_addr;
}
}
}
typedef std::set<ConstString> IndirectSymbols;
IndirectSymbols indirect_symbol_names;
#if defined (__APPLE__) && (defined (__arm__) || defined (__arm64__) || defined (__aarch64__))
// Some recent builds of the dyld_shared_cache (hereafter: DSC) have been optimized by moving LOCAL
// symbols out of the memory mapped portion of the DSC. The symbol information has all been retained,
// but it isn't available in the normal nlist data. However, there *are* duplicate entries of *some*
// LOCAL symbols in the normal nlist data. To handle this situation correctly, we must first attempt
// to parse any DSC unmapped symbol information. If we find any, we set a flag that tells the normal
// nlist parser to ignore all LOCAL symbols.
if (m_header.flags & 0x80000000u)
{
// Before we can start mapping the DSC, we need to make certain the target process is actually
// using the cache we can find.
// Next we need to determine the correct path for the dyld shared cache.
ArchSpec header_arch;
GetArchitecture(header_arch);
char dsc_path[PATH_MAX];
char dsc_path_development[PATH_MAX];
snprintf(dsc_path, sizeof(dsc_path), "%s%s%s",
"/System/Library/Caches/com.apple.dyld/", /* IPHONE_DYLD_SHARED_CACHE_DIR */
"dyld_shared_cache_", /* DYLD_SHARED_CACHE_BASE_NAME */
header_arch.GetArchitectureName());
snprintf(dsc_path_development, sizeof(dsc_path), "%s%s%s%s",
"/System/Library/Caches/com.apple.dyld/", /* IPHONE_DYLD_SHARED_CACHE_DIR */
"dyld_shared_cache_", /* DYLD_SHARED_CACHE_BASE_NAME */
header_arch.GetArchitectureName(),
".development");
FileSpec dsc_nondevelopment_filespec(dsc_path, false);
FileSpec dsc_development_filespec(dsc_path_development, false);
FileSpec dsc_filespec;
UUID dsc_uuid;
UUID process_shared_cache_uuid;
if (process)
{
process_shared_cache_uuid = GetProcessSharedCacheUUID(process);
}
// First see if we can find an exact match for the inferior process shared cache UUID in
// the development or non-development shared caches on disk.
if (process_shared_cache_uuid.IsValid())
{
if (dsc_development_filespec.Exists())
{
UUID dsc_development_uuid = GetSharedCacheUUID (dsc_development_filespec, byte_order, addr_byte_size);
if (dsc_development_uuid.IsValid() && dsc_development_uuid == process_shared_cache_uuid)
{
dsc_filespec = dsc_development_filespec;
dsc_uuid = dsc_development_uuid;
}
}
if (!dsc_uuid.IsValid() && dsc_nondevelopment_filespec.Exists())
{
UUID dsc_nondevelopment_uuid = GetSharedCacheUUID (dsc_nondevelopment_filespec, byte_order, addr_byte_size);
if (dsc_nondevelopment_uuid.IsValid() && dsc_nondevelopment_uuid == process_shared_cache_uuid)
{
dsc_filespec = dsc_nondevelopment_filespec;
dsc_uuid = dsc_nondevelopment_uuid;
}
}
}
// Failing a UUID match, prefer the development dyld_shared cache if both are present.
if (!dsc_filespec.Exists())
{
if (dsc_development_filespec.Exists())
{
dsc_filespec = dsc_development_filespec;
}
else
{
dsc_filespec = dsc_nondevelopment_filespec;
}
}
/* The dyld_cache_header has a pointer to the dyld_cache_local_symbols_info structure (localSymbolsOffset).
The dyld_cache_local_symbols_info structure gives us three things:
1. The start and count of the nlist records in the dyld_shared_cache file
2. The start and size of the strings for these nlist records
3. The start and count of dyld_cache_local_symbols_entry entries
There is one dyld_cache_local_symbols_entry per dylib/framework in the dyld shared cache.
The "dylibOffset" field is the Mach-O header of this dylib/framework in the dyld shared cache.
The dyld_cache_local_symbols_entry also lists the start of this dylib/framework's nlist records
and the count of how many nlist records there are for this dylib/framework.
*/
// Process the dyld shared cache header to find the unmapped symbols
DataBufferSP dsc_data_sp = dsc_filespec.MemoryMapFileContentsIfLocal(0, sizeof(struct lldb_copy_dyld_cache_header_v1));
if (!dsc_uuid.IsValid())
{
dsc_uuid = GetSharedCacheUUID (dsc_filespec, byte_order, addr_byte_size);
}
if (dsc_data_sp)
{
DataExtractor dsc_header_data (dsc_data_sp, byte_order, addr_byte_size);
bool uuid_match = true;
if (dsc_uuid.IsValid() && process)
{
if (process_shared_cache_uuid.IsValid() && dsc_uuid != process_shared_cache_uuid)
{
// The on-disk dyld_shared_cache file is not the same as the one in this
// process' memory, don't use it.
uuid_match = false;
ModuleSP module_sp (GetModule());
if (module_sp)
module_sp->ReportWarning ("process shared cache does not match on-disk dyld_shared_cache file, some symbol names will be missing.");
}
}
offset = offsetof (struct lldb_copy_dyld_cache_header_v1, mappingOffset);
uint32_t mappingOffset = dsc_header_data.GetU32(&offset);
// If the mappingOffset points to a location inside the header, we've
// opened an old dyld shared cache, and should not proceed further.
if (uuid_match && mappingOffset >= sizeof(struct lldb_copy_dyld_cache_header_v1))
{
DataBufferSP dsc_mapping_info_data_sp = dsc_filespec.MemoryMapFileContentsIfLocal(mappingOffset, sizeof (struct lldb_copy_dyld_cache_mapping_info));
DataExtractor dsc_mapping_info_data(dsc_mapping_info_data_sp, byte_order, addr_byte_size);
offset = 0;
// The File addresses (from the in-memory Mach-O load commands) for the shared libraries
// in the shared library cache need to be adjusted by an offset to match up with the
// dylibOffset identifying field in the dyld_cache_local_symbol_entry's. This offset is
// recorded in mapping_offset_value.
const uint64_t mapping_offset_value = dsc_mapping_info_data.GetU64(&offset);
offset = offsetof (struct lldb_copy_dyld_cache_header_v1, localSymbolsOffset);
uint64_t localSymbolsOffset = dsc_header_data.GetU64(&offset);
uint64_t localSymbolsSize = dsc_header_data.GetU64(&offset);
if (localSymbolsOffset && localSymbolsSize)
{
// Map the local symbols
if (DataBufferSP dsc_local_symbols_data_sp = dsc_filespec.MemoryMapFileContentsIfLocal(localSymbolsOffset, localSymbolsSize))
{
DataExtractor dsc_local_symbols_data(dsc_local_symbols_data_sp, byte_order, addr_byte_size);
offset = 0;
typedef std::map<ConstString, uint16_t> UndefinedNameToDescMap;
typedef std::map<uint32_t, ConstString> SymbolIndexToName;
UndefinedNameToDescMap undefined_name_to_desc;
SymbolIndexToName reexport_shlib_needs_fixup;
// Read the local_symbols_infos struct in one shot
struct lldb_copy_dyld_cache_local_symbols_info local_symbols_info;
dsc_local_symbols_data.GetU32(&offset, &local_symbols_info.nlistOffset, 6);
SectionSP text_section_sp(section_list->FindSectionByName(GetSegmentNameTEXT()));
uint32_t header_file_offset = (text_section_sp->GetFileAddress() - mapping_offset_value);
offset = local_symbols_info.entriesOffset;
for (uint32_t entry_index = 0; entry_index < local_symbols_info.entriesCount; entry_index++)
{
struct lldb_copy_dyld_cache_local_symbols_entry local_symbols_entry;
local_symbols_entry.dylibOffset = dsc_local_symbols_data.GetU32(&offset);
local_symbols_entry.nlistStartIndex = dsc_local_symbols_data.GetU32(&offset);
local_symbols_entry.nlistCount = dsc_local_symbols_data.GetU32(&offset);
if (header_file_offset == local_symbols_entry.dylibOffset)
{
unmapped_local_symbols_found = local_symbols_entry.nlistCount;
// The normal nlist code cannot correctly size the Symbols array, we need to allocate it here.
sym = symtab->Resize (symtab_load_command.nsyms + m_dysymtab.nindirectsyms + unmapped_local_symbols_found - m_dysymtab.nlocalsym);
num_syms = symtab->GetNumSymbols();
nlist_data_offset = local_symbols_info.nlistOffset + (nlist_byte_size * local_symbols_entry.nlistStartIndex);
uint32_t string_table_offset = local_symbols_info.stringsOffset;
for (uint32_t nlist_index = 0; nlist_index < local_symbols_entry.nlistCount; nlist_index++)
{
/////////////////////////////
{
struct nlist_64 nlist;
if (!dsc_local_symbols_data.ValidOffsetForDataOfSize(nlist_data_offset, nlist_byte_size))
break;
nlist.n_strx = dsc_local_symbols_data.GetU32_unchecked(&nlist_data_offset);
nlist.n_type = dsc_local_symbols_data.GetU8_unchecked (&nlist_data_offset);
nlist.n_sect = dsc_local_symbols_data.GetU8_unchecked (&nlist_data_offset);
nlist.n_desc = dsc_local_symbols_data.GetU16_unchecked (&nlist_data_offset);
nlist.n_value = dsc_local_symbols_data.GetAddress_unchecked (&nlist_data_offset);
SymbolType type = eSymbolTypeInvalid;
const char *symbol_name = dsc_local_symbols_data.PeekCStr(string_table_offset + nlist.n_strx);
if (symbol_name == NULL)
{
// No symbol should be NULL, even the symbols with no
// string values should have an offset zero which points
// to an empty C-string
Host::SystemLog (Host::eSystemLogError,
"error: DSC unmapped local symbol[%u] has invalid string table offset 0x%x in %s, ignoring symbol\n",
entry_index,
nlist.n_strx,
module_sp->GetFileSpec().GetPath().c_str());
continue;
}
if (symbol_name[0] == '\0')
symbol_name = NULL;
const char *symbol_name_non_abi_mangled = NULL;
SectionSP symbol_section;
uint32_t symbol_byte_size = 0;
bool add_nlist = true;
bool is_debug = ((nlist.n_type & N_STAB) != 0);
bool demangled_is_synthesized = false;
bool is_gsym = false;
bool set_value = true;
assert (sym_idx < num_syms);
sym[sym_idx].SetDebug (is_debug);
if (is_debug)
{
switch (nlist.n_type)
{
case N_GSYM:
// global symbol: name,,NO_SECT,type,0
// Sometimes the N_GSYM value contains the address.
// FIXME: In the .o files, we have a GSYM and a debug symbol for all the ObjC data. They
// have the same address, but we want to ensure that we always find only the real symbol,
// 'cause we don't currently correctly attribute the GSYM one to the ObjCClass/Ivar/MetaClass
// symbol type. This is a temporary hack to make sure the ObjectiveC symbols get treated
// correctly. To do this right, we should coalesce all the GSYM & global symbols that have the
// same address.
is_gsym = true;
sym[sym_idx].SetExternal(true);
if (symbol_name && symbol_name[0] == '_' && symbol_name[1] == 'O')
{
llvm::StringRef symbol_name_ref(symbol_name);
if (symbol_name_ref.startswith(g_objc_v2_prefix_class))
{
symbol_name_non_abi_mangled = symbol_name + 1;
symbol_name = symbol_name + g_objc_v2_prefix_class.size();
type = eSymbolTypeObjCClass;
demangled_is_synthesized = true;
}
else if (symbol_name_ref.startswith(g_objc_v2_prefix_metaclass))
{
symbol_name_non_abi_mangled = symbol_name + 1;
symbol_name = symbol_name + g_objc_v2_prefix_metaclass.size();
type = eSymbolTypeObjCMetaClass;
demangled_is_synthesized = true;
}
else if (symbol_name_ref.startswith(g_objc_v2_prefix_ivar))
{
symbol_name_non_abi_mangled = symbol_name + 1;
symbol_name = symbol_name + g_objc_v2_prefix_ivar.size();
type = eSymbolTypeObjCIVar;
demangled_is_synthesized = true;
}
}
else
{
if (nlist.n_value != 0)
symbol_section = section_info.GetSection (nlist.n_sect, nlist.n_value);
type = eSymbolTypeData;
}
break;
case N_FNAME:
// procedure name (f77 kludge): name,,NO_SECT,0,0
type = eSymbolTypeCompiler;
break;
case N_FUN:
// procedure: name,,n_sect,linenumber,address
if (symbol_name)
{
type = eSymbolTypeCode;
symbol_section = section_info.GetSection (nlist.n_sect, nlist.n_value);
N_FUN_addr_to_sym_idx.insert(std::make_pair(nlist.n_value, sym_idx));
// We use the current number of symbols in the symbol table in lieu of
// using nlist_idx in case we ever start trimming entries out
N_FUN_indexes.push_back(sym_idx);
}
else
{
type = eSymbolTypeCompiler;
if ( !N_FUN_indexes.empty() )
{
// Copy the size of the function into the original STAB entry so we don't have
// to hunt for it later
symtab->SymbolAtIndex(N_FUN_indexes.back())->SetByteSize(nlist.n_value);
N_FUN_indexes.pop_back();
// We don't really need the end function STAB as it contains the size which
// we already placed with the original symbol, so don't add it if we want a
// minimal symbol table
add_nlist = false;
}
}
break;
case N_STSYM:
// static symbol: name,,n_sect,type,address
N_STSYM_addr_to_sym_idx.insert(std::make_pair(nlist.n_value, sym_idx));
symbol_section = section_info.GetSection (nlist.n_sect, nlist.n_value);
if (symbol_name && symbol_name[0])
{
type = ObjectFile::GetSymbolTypeFromName(symbol_name+1, eSymbolTypeData);
}
break;
case N_LCSYM:
// .lcomm symbol: name,,n_sect,type,address
symbol_section = section_info.GetSection (nlist.n_sect, nlist.n_value);
type = eSymbolTypeCommonBlock;
break;
case N_BNSYM:
// We use the current number of symbols in the symbol table in lieu of
// using nlist_idx in case we ever start trimming entries out
// Skip these if we want minimal symbol tables
add_nlist = false;
break;
case N_ENSYM:
// Set the size of the N_BNSYM to the terminating index of this N_ENSYM
// so that we can always skip the entire symbol if we need to navigate
// more quickly at the source level when parsing STABS
// Skip these if we want minimal symbol tables
add_nlist = false;
break;
case N_OPT:
// emitted with gcc2_compiled and in gcc source
type = eSymbolTypeCompiler;
break;
case N_RSYM:
// register sym: name,,NO_SECT,type,register
type = eSymbolTypeVariable;
break;
case N_SLINE:
// src line: 0,,n_sect,linenumber,address
symbol_section = section_info.GetSection (nlist.n_sect, nlist.n_value);
type = eSymbolTypeLineEntry;
break;
case N_SSYM:
// structure elt: name,,NO_SECT,type,struct_offset
type = eSymbolTypeVariableType;
break;
case N_SO:
// source file name
type = eSymbolTypeSourceFile;
if (symbol_name == NULL)
{
add_nlist = false;
if (N_SO_index != UINT32_MAX)
{
// Set the size of the N_SO to the terminating index of this N_SO
// so that we can always skip the entire N_SO if we need to navigate
// more quickly at the source level when parsing STABS
symbol_ptr = symtab->SymbolAtIndex(N_SO_index);
symbol_ptr->SetByteSize(sym_idx);
symbol_ptr->SetSizeIsSibling(true);
}
N_NSYM_indexes.clear();
N_INCL_indexes.clear();
N_BRAC_indexes.clear();
N_COMM_indexes.clear();
N_FUN_indexes.clear();
N_SO_index = UINT32_MAX;
}
else
{
// We use the current number of symbols in the symbol table in lieu of
// using nlist_idx in case we ever start trimming entries out
const bool N_SO_has_full_path = symbol_name[0] == '/';
if (N_SO_has_full_path)
{
if ((N_SO_index == sym_idx - 1) && ((sym_idx - 1) < num_syms))
{
// We have two consecutive N_SO entries where the first contains a directory
// and the second contains a full path.
sym[sym_idx - 1].GetMangled().SetValue(ConstString(symbol_name), false);
m_nlist_idx_to_sym_idx[nlist_idx] = sym_idx - 1;
add_nlist = false;
}
else
{
// This is the first entry in a N_SO that contains a directory or
// a full path to the source file
N_SO_index = sym_idx;
}
}
else if ((N_SO_index == sym_idx - 1) && ((sym_idx - 1) < num_syms))
{
// This is usually the second N_SO entry that contains just the filename,
// so here we combine it with the first one if we are minimizing the symbol table
const char *so_path = sym[sym_idx - 1].GetMangled().GetDemangledName(lldb::eLanguageTypeUnknown).AsCString();
if (so_path && so_path[0])
{
std::string full_so_path (so_path);
const size_t double_slash_pos = full_so_path.find("//");
if (double_slash_pos != std::string::npos)
{
// The linker has been generating bad N_SO entries with doubled up paths
// in the format "%s%s" where the first string in the DW_AT_comp_dir,
// and the second is the directory for the source file so you end up with
// a path that looks like "/tmp/src//tmp/src/"
FileSpec so_dir(so_path, false);
if (!so_dir.Exists())
{
so_dir.SetFile(&full_so_path[double_slash_pos + 1], false);
if (so_dir.Exists())
{
// Trim off the incorrect path
full_so_path.erase(0, double_slash_pos + 1);
}
}
}
if (*full_so_path.rbegin() != '/')
full_so_path += '/';
full_so_path += symbol_name;
sym[sym_idx - 1].GetMangled().SetValue(ConstString(full_so_path.c_str()), false);
add_nlist = false;
m_nlist_idx_to_sym_idx[nlist_idx] = sym_idx - 1;
}
}
else
{
// This could be a relative path to a N_SO
N_SO_index = sym_idx;
}
}
break;
case N_OSO:
// object file name: name,,0,0,st_mtime
type = eSymbolTypeObjectFile;
break;
case N_LSYM:
// local sym: name,,NO_SECT,type,offset
type = eSymbolTypeLocal;
break;
//----------------------------------------------------------------------
// INCL scopes
//----------------------------------------------------------------------
case N_BINCL:
// include file beginning: name,,NO_SECT,0,sum
// We use the current number of symbols in the symbol table in lieu of
// using nlist_idx in case we ever start trimming entries out
N_INCL_indexes.push_back(sym_idx);
type = eSymbolTypeScopeBegin;
break;
case N_EINCL:
// include file end: name,,NO_SECT,0,0
// Set the size of the N_BINCL to the terminating index of this N_EINCL
// so that we can always skip the entire symbol if we need to navigate
// more quickly at the source level when parsing STABS
if ( !N_INCL_indexes.empty() )
{
symbol_ptr = symtab->SymbolAtIndex(N_INCL_indexes.back());
symbol_ptr->SetByteSize(sym_idx + 1);
symbol_ptr->SetSizeIsSibling(true);
N_INCL_indexes.pop_back();
}
type = eSymbolTypeScopeEnd;
break;
case N_SOL:
// #included file name: name,,n_sect,0,address
type = eSymbolTypeHeaderFile;
// We currently don't use the header files on darwin
add_nlist = false;
break;
case N_PARAMS:
// compiler parameters: name,,NO_SECT,0,0
type = eSymbolTypeCompiler;
break;
case N_VERSION:
// compiler version: name,,NO_SECT,0,0
type = eSymbolTypeCompiler;
break;
case N_OLEVEL:
// compiler -O level: name,,NO_SECT,0,0
type = eSymbolTypeCompiler;
break;
case N_PSYM:
// parameter: name,,NO_SECT,type,offset
type = eSymbolTypeVariable;
break;
case N_ENTRY:
// alternate entry: name,,n_sect,linenumber,address
symbol_section = section_info.GetSection (nlist.n_sect, nlist.n_value);
type = eSymbolTypeLineEntry;
break;
//----------------------------------------------------------------------
// Left and Right Braces
//----------------------------------------------------------------------
case N_LBRAC:
// left bracket: 0,,NO_SECT,nesting level,address
// We use the current number of symbols in the symbol table in lieu of
// using nlist_idx in case we ever start trimming entries out
symbol_section = section_info.GetSection (nlist.n_sect, nlist.n_value);
N_BRAC_indexes.push_back(sym_idx);
type = eSymbolTypeScopeBegin;
break;
case N_RBRAC:
// right bracket: 0,,NO_SECT,nesting level,address
// Set the size of the N_LBRAC to the terminating index of this N_RBRAC
// so that we can always skip the entire symbol if we need to navigate
// more quickly at the source level when parsing STABS
symbol_section = section_info.GetSection (nlist.n_sect, nlist.n_value);
if ( !N_BRAC_indexes.empty() )
{
symbol_ptr = symtab->SymbolAtIndex(N_BRAC_indexes.back());
symbol_ptr->SetByteSize(sym_idx + 1);
symbol_ptr->SetSizeIsSibling(true);
N_BRAC_indexes.pop_back();
}
type = eSymbolTypeScopeEnd;
break;
case N_EXCL:
// deleted include file: name,,NO_SECT,0,sum
type = eSymbolTypeHeaderFile;
break;
//----------------------------------------------------------------------
// COMM scopes
//----------------------------------------------------------------------
case N_BCOMM:
// begin common: name,,NO_SECT,0,0
// We use the current number of symbols in the symbol table in lieu of
// using nlist_idx in case we ever start trimming entries out
type = eSymbolTypeScopeBegin;
N_COMM_indexes.push_back(sym_idx);
break;
case N_ECOML:
// end common (local name): 0,,n_sect,0,address
symbol_section = section_info.GetSection (nlist.n_sect, nlist.n_value);
// Fall through
case N_ECOMM:
// end common: name,,n_sect,0,0
// Set the size of the N_BCOMM to the terminating index of this N_ECOMM/N_ECOML
// so that we can always skip the entire symbol if we need to navigate
// more quickly at the source level when parsing STABS
if ( !N_COMM_indexes.empty() )
{
symbol_ptr = symtab->SymbolAtIndex(N_COMM_indexes.back());
symbol_ptr->SetByteSize(sym_idx + 1);
symbol_ptr->SetSizeIsSibling(true);
N_COMM_indexes.pop_back();
}
type = eSymbolTypeScopeEnd;
break;
case N_LENG:
// second stab entry with length information
type = eSymbolTypeAdditional;
break;
default: break;
}
}
else
{
//uint8_t n_pext = N_PEXT & nlist.n_type;
uint8_t n_type = N_TYPE & nlist.n_type;
sym[sym_idx].SetExternal((N_EXT & nlist.n_type) != 0);
switch (n_type)
{
case N_INDR:
{
const char *reexport_name_cstr = strtab_data.PeekCStr(nlist.n_value);
if (reexport_name_cstr && reexport_name_cstr[0])
{
type = eSymbolTypeReExported;
ConstString reexport_name(reexport_name_cstr + ((reexport_name_cstr[0] == '_') ? 1 : 0));
sym[sym_idx].SetReExportedSymbolName(reexport_name);
set_value = false;
reexport_shlib_needs_fixup[sym_idx] = reexport_name;
indirect_symbol_names.insert(ConstString(symbol_name + ((symbol_name[0] == '_') ? 1 : 0)));
}
else
type = eSymbolTypeUndefined;
}
break;
case N_UNDF:
if (symbol_name && symbol_name[0])
{
ConstString undefined_name(symbol_name + ((symbol_name[0] == '_') ? 1 : 0));
undefined_name_to_desc[undefined_name] = nlist.n_desc;
}
// Fall through
case N_PBUD:
type = eSymbolTypeUndefined;
break;
case N_ABS:
type = eSymbolTypeAbsolute;
break;
case N_SECT:
{
symbol_section = section_info.GetSection (nlist.n_sect, nlist.n_value);
if (symbol_section == NULL)
{
// TODO: warn about this?
add_nlist = false;
break;
}
if (TEXT_eh_frame_sectID == nlist.n_sect)
{
type = eSymbolTypeException;
}
else
{
uint32_t section_type = symbol_section->Get() & SECTION_TYPE;
switch (section_type)
{
case S_CSTRING_LITERALS: type = eSymbolTypeData; break; // section with only literal C strings
case S_4BYTE_LITERALS: type = eSymbolTypeData; break; // section with only 4 byte literals
case S_8BYTE_LITERALS: type = eSymbolTypeData; break; // section with only 8 byte literals
case S_LITERAL_POINTERS: type = eSymbolTypeTrampoline; break; // section with only pointers to literals
case S_NON_LAZY_SYMBOL_POINTERS: type = eSymbolTypeTrampoline; break; // section with only non-lazy symbol pointers
case S_LAZY_SYMBOL_POINTERS: type = eSymbolTypeTrampoline; break; // section with only lazy symbol pointers
case S_SYMBOL_STUBS: type = eSymbolTypeTrampoline; break; // section with only symbol stubs, byte size of stub in the reserved2 field
case S_MOD_INIT_FUNC_POINTERS: type = eSymbolTypeCode; break; // section with only function pointers for initialization
case S_MOD_TERM_FUNC_POINTERS: type = eSymbolTypeCode; break; // section with only function pointers for termination
case S_INTERPOSING: type = eSymbolTypeTrampoline; break; // section with only pairs of function pointers for interposing
case S_16BYTE_LITERALS: type = eSymbolTypeData; break; // section with only 16 byte literals
case S_DTRACE_DOF: type = eSymbolTypeInstrumentation; break;
case S_LAZY_DYLIB_SYMBOL_POINTERS: type = eSymbolTypeTrampoline; break;
default:
switch (symbol_section->GetType())
{
case lldb::eSectionTypeCode:
type = eSymbolTypeCode;
break;
case eSectionTypeData:
case eSectionTypeDataCString: // Inlined C string data
case eSectionTypeDataCStringPointers: // Pointers to C string data
case eSectionTypeDataSymbolAddress: // Address of a symbol in the symbol table
case eSectionTypeData4:
case eSectionTypeData8:
case eSectionTypeData16:
type = eSymbolTypeData;
break;
default:
break;
}
break;
}
if (type == eSymbolTypeInvalid)
{
const char *symbol_sect_name = symbol_section->GetName().AsCString();
if (symbol_section->IsDescendant (text_section_sp.get()))
{
if (symbol_section->IsClear(S_ATTR_PURE_INSTRUCTIONS |
S_ATTR_SELF_MODIFYING_CODE |
S_ATTR_SOME_INSTRUCTIONS))
type = eSymbolTypeData;
else
type = eSymbolTypeCode;
}
else if (symbol_section->IsDescendant(data_section_sp.get()) ||
symbol_section->IsDescendant(data_dirty_section_sp.get()) ||
symbol_section->IsDescendant(data_const_section_sp.get()))
{
if (symbol_sect_name && ::strstr (symbol_sect_name, "__objc") == symbol_sect_name)
{
type = eSymbolTypeRuntime;
if (symbol_name)
{
llvm::StringRef symbol_name_ref(symbol_name);
if (symbol_name_ref.startswith("_OBJC_"))
{
static const llvm::StringRef g_objc_v2_prefix_class ("_OBJC_CLASS_$_");
static const llvm::StringRef g_objc_v2_prefix_metaclass ("_OBJC_METACLASS_$_");
static const llvm::StringRef g_objc_v2_prefix_ivar ("_OBJC_IVAR_$_");
if (symbol_name_ref.startswith(g_objc_v2_prefix_class))
{
symbol_name_non_abi_mangled = symbol_name + 1;
symbol_name = symbol_name + g_objc_v2_prefix_class.size();
type = eSymbolTypeObjCClass;
demangled_is_synthesized = true;
}
else if (symbol_name_ref.startswith(g_objc_v2_prefix_metaclass))
{
symbol_name_non_abi_mangled = symbol_name + 1;
symbol_name = symbol_name + g_objc_v2_prefix_metaclass.size();
type = eSymbolTypeObjCMetaClass;
demangled_is_synthesized = true;
}
else if (symbol_name_ref.startswith(g_objc_v2_prefix_ivar))
{
symbol_name_non_abi_mangled = symbol_name + 1;
symbol_name = symbol_name + g_objc_v2_prefix_ivar.size();
type = eSymbolTypeObjCIVar;
demangled_is_synthesized = true;
}
}
}
}
else if (symbol_sect_name && ::strstr (symbol_sect_name, "__gcc_except_tab") == symbol_sect_name)
{
type = eSymbolTypeException;
}
else
{
type = eSymbolTypeData;
}
}
else if (symbol_sect_name && ::strstr (symbol_sect_name, "__IMPORT") == symbol_sect_name)
{
type = eSymbolTypeTrampoline;
}
else if (symbol_section->IsDescendant(objc_section_sp.get()))
{
type = eSymbolTypeRuntime;
if (symbol_name && symbol_name[0] == '.')
{
llvm::StringRef symbol_name_ref(symbol_name);
static const llvm::StringRef g_objc_v1_prefix_class (".objc_class_name_");
if (symbol_name_ref.startswith(g_objc_v1_prefix_class))
{
symbol_name_non_abi_mangled = symbol_name;
symbol_name = symbol_name + g_objc_v1_prefix_class.size();
type = eSymbolTypeObjCClass;
demangled_is_synthesized = true;
}
}
}
}
}
}
break;
}
}
if (add_nlist)
{
uint64_t symbol_value = nlist.n_value;
if (symbol_name_non_abi_mangled)
{
sym[sym_idx].GetMangled().SetMangledName (ConstString(symbol_name_non_abi_mangled));
sym[sym_idx].GetMangled().SetDemangledName (ConstString(symbol_name));
}
else
{
bool symbol_name_is_mangled = false;
if (symbol_name && symbol_name[0] == '_')
{
symbol_name_is_mangled = symbol_name[1] == '_';
symbol_name++; // Skip the leading underscore
}
if (symbol_name)
{
ConstString const_symbol_name(symbol_name);
sym[sym_idx].GetMangled().SetValue(const_symbol_name, symbol_name_is_mangled);
if (is_gsym && is_debug)
{
const char *gsym_name = sym[sym_idx].GetMangled().GetName(lldb::eLanguageTypeUnknown, Mangled::ePreferMangled).GetCString();
if (gsym_name)
N_GSYM_name_to_sym_idx[gsym_name] = sym_idx;
}
}
}
if (symbol_section)
{
const addr_t section_file_addr = symbol_section->GetFileAddress();
if (symbol_byte_size == 0 && function_starts_count > 0)
{
addr_t symbol_lookup_file_addr = nlist.n_value;
// Do an exact address match for non-ARM addresses, else get the closest since
// the symbol might be a thumb symbol which has an address with bit zero set
FunctionStarts::Entry *func_start_entry = function_starts.FindEntry (symbol_lookup_file_addr, !is_arm);
if (is_arm && func_start_entry)
{
// Verify that the function start address is the symbol address (ARM)
// or the symbol address + 1 (thumb)
if (func_start_entry->addr != symbol_lookup_file_addr &&
func_start_entry->addr != (symbol_lookup_file_addr + 1))
{
// Not the right entry, NULL it out...
func_start_entry = NULL;
}
}
if (func_start_entry)
{
func_start_entry->data = true;
addr_t symbol_file_addr = func_start_entry->addr;
uint32_t symbol_flags = 0;
if (is_arm)
{
if (symbol_file_addr & 1)
symbol_flags = MACHO_NLIST_ARM_SYMBOL_IS_THUMB;
symbol_file_addr &= THUMB_ADDRESS_BIT_MASK;
}
const FunctionStarts::Entry *next_func_start_entry = function_starts.FindNextEntry (func_start_entry);
const addr_t section_end_file_addr = section_file_addr + symbol_section->GetByteSize();
if (next_func_start_entry)
{
addr_t next_symbol_file_addr = next_func_start_entry->addr;
// Be sure the clear the Thumb address bit when we calculate the size
// from the current and next address
if (is_arm)
next_symbol_file_addr &= THUMB_ADDRESS_BIT_MASK;
symbol_byte_size = std::min<lldb::addr_t>(next_symbol_file_addr - symbol_file_addr, section_end_file_addr - symbol_file_addr);
}
else
{
symbol_byte_size = section_end_file_addr - symbol_file_addr;
}
}
}
symbol_value -= section_file_addr;
}
if (is_debug == false)
{
if (type == eSymbolTypeCode)
{
// See if we can find a N_FUN entry for any code symbols.
// If we do find a match, and the name matches, then we
// can merge the two into just the function symbol to avoid
// duplicate entries in the symbol table
std::pair<ValueToSymbolIndexMap::const_iterator, ValueToSymbolIndexMap::const_iterator> range;
range = N_FUN_addr_to_sym_idx.equal_range(nlist.n_value);
if (range.first != range.second)
{
bool found_it = false;
for (ValueToSymbolIndexMap::const_iterator pos = range.first; pos != range.second; ++pos)
{
if (sym[sym_idx].GetMangled().GetName(lldb::eLanguageTypeUnknown, Mangled::ePreferMangled) == sym[pos->second].GetMangled().GetName(lldb::eLanguageTypeUnknown, Mangled::ePreferMangled))
{
m_nlist_idx_to_sym_idx[nlist_idx] = pos->second;
// We just need the flags from the linker symbol, so put these flags
// into the N_FUN flags to avoid duplicate symbols in the symbol table
sym[pos->second].SetExternal(sym[sym_idx].IsExternal());
sym[pos->second].SetFlags (nlist.n_type << 16 | nlist.n_desc);
if (resolver_addresses.find(nlist.n_value) != resolver_addresses.end())
sym[pos->second].SetType (eSymbolTypeResolver);
sym[sym_idx].Clear();
found_it = true;
break;
}
}
if (found_it)
continue;
}
else
{
if (resolver_addresses.find(nlist.n_value) != resolver_addresses.end())
type = eSymbolTypeResolver;
}
}
else if (type == eSymbolTypeData ||
type == eSymbolTypeObjCClass ||
type == eSymbolTypeObjCMetaClass ||
type == eSymbolTypeObjCIVar )
{
// See if we can find a N_STSYM entry for any data symbols.
// If we do find a match, and the name matches, then we
// can merge the two into just the Static symbol to avoid
// duplicate entries in the symbol table
std::pair<ValueToSymbolIndexMap::const_iterator, ValueToSymbolIndexMap::const_iterator> range;
range = N_STSYM_addr_to_sym_idx.equal_range(nlist.n_value);
if (range.first != range.second)
{
bool found_it = false;
for (ValueToSymbolIndexMap::const_iterator pos = range.first; pos != range.second; ++pos)
{
if (sym[sym_idx].GetMangled().GetName(lldb::eLanguageTypeUnknown, Mangled::ePreferMangled) == sym[pos->second].GetMangled().GetName(lldb::eLanguageTypeUnknown, Mangled::ePreferMangled))
{
m_nlist_idx_to_sym_idx[nlist_idx] = pos->second;
// We just need the flags from the linker symbol, so put these flags
// into the N_STSYM flags to avoid duplicate symbols in the symbol table
sym[pos->second].SetExternal(sym[sym_idx].IsExternal());
sym[pos->second].SetFlags (nlist.n_type << 16 | nlist.n_desc);
sym[sym_idx].Clear();
found_it = true;
break;
}
}
if (found_it)
continue;
}
else
{
const char *gsym_name = sym[sym_idx].GetMangled().GetName(lldb::eLanguageTypeUnknown, Mangled::ePreferMangled).GetCString();
if (gsym_name)
{
// Combine N_GSYM stab entries with the non stab symbol
ConstNameToSymbolIndexMap::const_iterator pos = N_GSYM_name_to_sym_idx.find(gsym_name);
if (pos != N_GSYM_name_to_sym_idx.end())
{
const uint32_t GSYM_sym_idx = pos->second;
m_nlist_idx_to_sym_idx[nlist_idx] = GSYM_sym_idx;
// Copy the address, because often the N_GSYM address has an invalid address of zero
// when the global is a common symbol
sym[GSYM_sym_idx].GetAddressRef().SetSection (symbol_section);
sym[GSYM_sym_idx].GetAddressRef().SetOffset (symbol_value);
// We just need the flags from the linker symbol, so put these flags
// into the N_GSYM flags to avoid duplicate symbols in the symbol table
sym[GSYM_sym_idx].SetFlags (nlist.n_type << 16 | nlist.n_desc);
sym[sym_idx].Clear();
continue;
}
}
}
}
}
sym[sym_idx].SetID (nlist_idx);
sym[sym_idx].SetType (type);
if (set_value)
{
sym[sym_idx].GetAddressRef().SetSection (symbol_section);
sym[sym_idx].GetAddressRef().SetOffset (symbol_value);
}
sym[sym_idx].SetFlags (nlist.n_type << 16 | nlist.n_desc);
if (symbol_byte_size > 0)
sym[sym_idx].SetByteSize(symbol_byte_size);
if (demangled_is_synthesized)
sym[sym_idx].SetDemangledNameIsSynthesized(true);
++sym_idx;
}
else
{
sym[sym_idx].Clear();
}
}
/////////////////////////////
}
break; // No more entries to consider
}
}
for (const auto &pos :reexport_shlib_needs_fixup)
{
const auto undef_pos = undefined_name_to_desc.find(pos.second);
if (undef_pos != undefined_name_to_desc.end())
{
const uint8_t dylib_ordinal = llvm::MachO::GET_LIBRARY_ORDINAL(undef_pos->second);
if (dylib_ordinal > 0 && dylib_ordinal < dylib_files.GetSize())
sym[pos.first].SetReExportedSymbolSharedLibrary(dylib_files.GetFileSpecAtIndex(dylib_ordinal-1));
}
}
}
}
}
}
}
// Must reset this in case it was mutated above!
nlist_data_offset = 0;
#endif
if (nlist_data.GetByteSize() > 0)
{
// If the sym array was not created while parsing the DSC unmapped
// symbols, create it now.
if (sym == NULL)
{
sym = symtab->Resize (symtab_load_command.nsyms + m_dysymtab.nindirectsyms);
num_syms = symtab->GetNumSymbols();
}
if (unmapped_local_symbols_found)
{
assert(m_dysymtab.ilocalsym == 0);
nlist_data_offset += (m_dysymtab.nlocalsym * nlist_byte_size);
nlist_idx = m_dysymtab.nlocalsym;
}
else
{
nlist_idx = 0;
}
typedef std::map<ConstString, uint16_t> UndefinedNameToDescMap;
typedef std::map<uint32_t, ConstString> SymbolIndexToName;
UndefinedNameToDescMap undefined_name_to_desc;
SymbolIndexToName reexport_shlib_needs_fixup;
for (; nlist_idx < symtab_load_command.nsyms; ++nlist_idx)
{
struct nlist_64 nlist;
if (!nlist_data.ValidOffsetForDataOfSize(nlist_data_offset, nlist_byte_size))
break;
nlist.n_strx = nlist_data.GetU32_unchecked(&nlist_data_offset);
nlist.n_type = nlist_data.GetU8_unchecked (&nlist_data_offset);
nlist.n_sect = nlist_data.GetU8_unchecked (&nlist_data_offset);
nlist.n_desc = nlist_data.GetU16_unchecked (&nlist_data_offset);
nlist.n_value = nlist_data.GetAddress_unchecked (&nlist_data_offset);
SymbolType type = eSymbolTypeInvalid;
const char *symbol_name = NULL;
if (have_strtab_data)
{
symbol_name = strtab_data.PeekCStr(nlist.n_strx);
if (symbol_name == NULL)
{
// No symbol should be NULL, even the symbols with no
// string values should have an offset zero which points
// to an empty C-string
Host::SystemLog (Host::eSystemLogError,
"error: symbol[%u] has invalid string table offset 0x%x in %s, ignoring symbol\n",
nlist_idx,
nlist.n_strx,
module_sp->GetFileSpec().GetPath().c_str());
continue;
}
if (symbol_name[0] == '\0')
symbol_name = NULL;
}
else
{
const addr_t str_addr = strtab_addr + nlist.n_strx;
Error str_error;
if (process->ReadCStringFromMemory(str_addr, memory_symbol_name, str_error))
symbol_name = memory_symbol_name.c_str();
}
const char *symbol_name_non_abi_mangled = NULL;
SectionSP symbol_section;
lldb::addr_t symbol_byte_size = 0;
bool add_nlist = true;
bool is_gsym = false;
bool is_debug = ((nlist.n_type & N_STAB) != 0);
bool demangled_is_synthesized = false;
bool set_value = true;
assert (sym_idx < num_syms);
sym[sym_idx].SetDebug (is_debug);
if (is_debug)
{
switch (nlist.n_type)
{
case N_GSYM:
// global symbol: name,,NO_SECT,type,0
// Sometimes the N_GSYM value contains the address.
// FIXME: In the .o files, we have a GSYM and a debug symbol for all the ObjC data. They
// have the same address, but we want to ensure that we always find only the real symbol,
// 'cause we don't currently correctly attribute the GSYM one to the ObjCClass/Ivar/MetaClass
// symbol type. This is a temporary hack to make sure the ObjectiveC symbols get treated
// correctly. To do this right, we should coalesce all the GSYM & global symbols that have the
// same address.
is_gsym = true;
sym[sym_idx].SetExternal(true);
if (symbol_name && symbol_name[0] == '_' && symbol_name[1] == 'O')
{
llvm::StringRef symbol_name_ref(symbol_name);
if (symbol_name_ref.startswith(g_objc_v2_prefix_class))
{
symbol_name_non_abi_mangled = symbol_name + 1;
symbol_name = symbol_name + g_objc_v2_prefix_class.size();
type = eSymbolTypeObjCClass;
demangled_is_synthesized = true;
}
else if (symbol_name_ref.startswith(g_objc_v2_prefix_metaclass))
{
symbol_name_non_abi_mangled = symbol_name + 1;
symbol_name = symbol_name + g_objc_v2_prefix_metaclass.size();
type = eSymbolTypeObjCMetaClass;
demangled_is_synthesized = true;
}
else if (symbol_name_ref.startswith(g_objc_v2_prefix_ivar))
{
symbol_name_non_abi_mangled = symbol_name + 1;
symbol_name = symbol_name + g_objc_v2_prefix_ivar.size();
type = eSymbolTypeObjCIVar;
demangled_is_synthesized = true;
}
}
else
{
if (nlist.n_value != 0)
symbol_section = section_info.GetSection (nlist.n_sect, nlist.n_value);
type = eSymbolTypeData;
}
break;
case N_FNAME:
// procedure name (f77 kludge): name,,NO_SECT,0,0
type = eSymbolTypeCompiler;
break;
case N_FUN:
// procedure: name,,n_sect,linenumber,address
if (symbol_name)
{
type = eSymbolTypeCode;
symbol_section = section_info.GetSection (nlist.n_sect, nlist.n_value);
N_FUN_addr_to_sym_idx.insert(std::make_pair(nlist.n_value, sym_idx));
// We use the current number of symbols in the symbol table in lieu of
// using nlist_idx in case we ever start trimming entries out
N_FUN_indexes.push_back(sym_idx);
}
else
{
type = eSymbolTypeCompiler;
if ( !N_FUN_indexes.empty() )
{
// Copy the size of the function into the original STAB entry so we don't have
// to hunt for it later
symtab->SymbolAtIndex(N_FUN_indexes.back())->SetByteSize(nlist.n_value);
N_FUN_indexes.pop_back();
// We don't really need the end function STAB as it contains the size which
// we already placed with the original symbol, so don't add it if we want a
// minimal symbol table
add_nlist = false;
}
}
break;
case N_STSYM:
// static symbol: name,,n_sect,type,address
N_STSYM_addr_to_sym_idx.insert(std::make_pair(nlist.n_value, sym_idx));
symbol_section = section_info.GetSection (nlist.n_sect, nlist.n_value);
if (symbol_name && symbol_name[0])
{
type = ObjectFile::GetSymbolTypeFromName(symbol_name+1, eSymbolTypeData);
}
break;
case N_LCSYM:
// .lcomm symbol: name,,n_sect,type,address
symbol_section = section_info.GetSection (nlist.n_sect, nlist.n_value);
type = eSymbolTypeCommonBlock;
break;
case N_BNSYM:
// We use the current number of symbols in the symbol table in lieu of
// using nlist_idx in case we ever start trimming entries out
// Skip these if we want minimal symbol tables
add_nlist = false;
break;
case N_ENSYM:
// Set the size of the N_BNSYM to the terminating index of this N_ENSYM
// so that we can always skip the entire symbol if we need to navigate
// more quickly at the source level when parsing STABS
// Skip these if we want minimal symbol tables
add_nlist = false;
break;
case N_OPT:
// emitted with gcc2_compiled and in gcc source
type = eSymbolTypeCompiler;
break;
case N_RSYM:
// register sym: name,,NO_SECT,type,register
type = eSymbolTypeVariable;
break;
case N_SLINE:
// src line: 0,,n_sect,linenumber,address
symbol_section = section_info.GetSection (nlist.n_sect, nlist.n_value);
type = eSymbolTypeLineEntry;
break;
case N_SSYM:
// structure elt: name,,NO_SECT,type,struct_offset
type = eSymbolTypeVariableType;
break;
case N_SO:
// source file name
type = eSymbolTypeSourceFile;
if (symbol_name == NULL)
{
add_nlist = false;
if (N_SO_index != UINT32_MAX)
{
// Set the size of the N_SO to the terminating index of this N_SO
// so that we can always skip the entire N_SO if we need to navigate
// more quickly at the source level when parsing STABS
symbol_ptr = symtab->SymbolAtIndex(N_SO_index);
symbol_ptr->SetByteSize(sym_idx);
symbol_ptr->SetSizeIsSibling(true);
}
N_NSYM_indexes.clear();
N_INCL_indexes.clear();
N_BRAC_indexes.clear();
N_COMM_indexes.clear();
N_FUN_indexes.clear();
N_SO_index = UINT32_MAX;
}
else
{
// We use the current number of symbols in the symbol table in lieu of
// using nlist_idx in case we ever start trimming entries out
const bool N_SO_has_full_path = symbol_name[0] == '/';
if (N_SO_has_full_path)
{
if ((N_SO_index == sym_idx - 1) && ((sym_idx - 1) < num_syms))
{
// We have two consecutive N_SO entries where the first contains a directory
// and the second contains a full path.
sym[sym_idx - 1].GetMangled().SetValue(ConstString(symbol_name), false);
m_nlist_idx_to_sym_idx[nlist_idx] = sym_idx - 1;
add_nlist = false;
}
else
{
// This is the first entry in a N_SO that contains a directory or
// a full path to the source file
N_SO_index = sym_idx;
}
}
else if ((N_SO_index == sym_idx - 1) && ((sym_idx - 1) < num_syms))
{
// This is usually the second N_SO entry that contains just the filename,
// so here we combine it with the first one if we are minimizing the symbol table
const char *so_path = sym[sym_idx - 1].GetMangled().GetDemangledName(lldb::eLanguageTypeUnknown).AsCString();
if (so_path && so_path[0])
{
std::string full_so_path (so_path);
const size_t double_slash_pos = full_so_path.find("//");
if (double_slash_pos != std::string::npos)
{
// The linker has been generating bad N_SO entries with doubled up paths
// in the format "%s%s" where the first string in the DW_AT_comp_dir,
// and the second is the directory for the source file so you end up with
// a path that looks like "/tmp/src//tmp/src/"
FileSpec so_dir(so_path, false);
if (!so_dir.Exists())
{
so_dir.SetFile(&full_so_path[double_slash_pos + 1], false);
if (so_dir.Exists())
{
// Trim off the incorrect path
full_so_path.erase(0, double_slash_pos + 1);
}
}
}
if (*full_so_path.rbegin() != '/')
full_so_path += '/';
full_so_path += symbol_name;
sym[sym_idx - 1].GetMangled().SetValue(ConstString(full_so_path.c_str()), false);
add_nlist = false;
m_nlist_idx_to_sym_idx[nlist_idx] = sym_idx - 1;
}
}
else
{
// This could be a relative path to a N_SO
N_SO_index = sym_idx;
}
}
break;
case N_OSO:
// object file name: name,,0,0,st_mtime
type = eSymbolTypeObjectFile;
break;
case N_LSYM:
// local sym: name,,NO_SECT,type,offset
type = eSymbolTypeLocal;
break;
//----------------------------------------------------------------------
// INCL scopes
//----------------------------------------------------------------------
case N_BINCL:
// include file beginning: name,,NO_SECT,0,sum
// We use the current number of symbols in the symbol table in lieu of
// using nlist_idx in case we ever start trimming entries out
N_INCL_indexes.push_back(sym_idx);
type = eSymbolTypeScopeBegin;
break;
case N_EINCL:
// include file end: name,,NO_SECT,0,0
// Set the size of the N_BINCL to the terminating index of this N_EINCL
// so that we can always skip the entire symbol if we need to navigate
// more quickly at the source level when parsing STABS
if ( !N_INCL_indexes.empty() )
{
symbol_ptr = symtab->SymbolAtIndex(N_INCL_indexes.back());
symbol_ptr->SetByteSize(sym_idx + 1);
symbol_ptr->SetSizeIsSibling(true);
N_INCL_indexes.pop_back();
}
type = eSymbolTypeScopeEnd;
break;
case N_SOL:
// #included file name: name,,n_sect,0,address
type = eSymbolTypeHeaderFile;
// We currently don't use the header files on darwin
add_nlist = false;
break;
case N_PARAMS:
// compiler parameters: name,,NO_SECT,0,0
type = eSymbolTypeCompiler;
break;
case N_VERSION:
// compiler version: name,,NO_SECT,0,0
type = eSymbolTypeCompiler;
break;
case N_OLEVEL:
// compiler -O level: name,,NO_SECT,0,0
type = eSymbolTypeCompiler;
break;
case N_PSYM:
// parameter: name,,NO_SECT,type,offset
type = eSymbolTypeVariable;
break;
case N_ENTRY:
// alternate entry: name,,n_sect,linenumber,address
symbol_section = section_info.GetSection (nlist.n_sect, nlist.n_value);
type = eSymbolTypeLineEntry;
break;
//----------------------------------------------------------------------
// Left and Right Braces
//----------------------------------------------------------------------
case N_LBRAC:
// left bracket: 0,,NO_SECT,nesting level,address
// We use the current number of symbols in the symbol table in lieu of
// using nlist_idx in case we ever start trimming entries out
symbol_section = section_info.GetSection (nlist.n_sect, nlist.n_value);
N_BRAC_indexes.push_back(sym_idx);
type = eSymbolTypeScopeBegin;
break;
case N_RBRAC:
// right bracket: 0,,NO_SECT,nesting level,address
// Set the size of the N_LBRAC to the terminating index of this N_RBRAC
// so that we can always skip the entire symbol if we need to navigate
// more quickly at the source level when parsing STABS
symbol_section = section_info.GetSection (nlist.n_sect, nlist.n_value);
if ( !N_BRAC_indexes.empty() )
{
symbol_ptr = symtab->SymbolAtIndex(N_BRAC_indexes.back());
symbol_ptr->SetByteSize(sym_idx + 1);
symbol_ptr->SetSizeIsSibling(true);
N_BRAC_indexes.pop_back();
}
type = eSymbolTypeScopeEnd;
break;
case N_EXCL:
// deleted include file: name,,NO_SECT,0,sum
type = eSymbolTypeHeaderFile;
break;
//----------------------------------------------------------------------
// COMM scopes
//----------------------------------------------------------------------
case N_BCOMM:
// begin common: name,,NO_SECT,0,0
// We use the current number of symbols in the symbol table in lieu of
// using nlist_idx in case we ever start trimming entries out
type = eSymbolTypeScopeBegin;
N_COMM_indexes.push_back(sym_idx);
break;
case N_ECOML:
// end common (local name): 0,,n_sect,0,address
symbol_section = section_info.GetSection (nlist.n_sect, nlist.n_value);
LLVM_FALLTHROUGH;
case N_ECOMM:
// end common: name,,n_sect,0,0
// Set the size of the N_BCOMM to the terminating index of this N_ECOMM/N_ECOML
// so that we can always skip the entire symbol if we need to navigate
// more quickly at the source level when parsing STABS
if ( !N_COMM_indexes.empty() )
{
symbol_ptr = symtab->SymbolAtIndex(N_COMM_indexes.back());
symbol_ptr->SetByteSize(sym_idx + 1);
symbol_ptr->SetSizeIsSibling(true);
N_COMM_indexes.pop_back();
}
type = eSymbolTypeScopeEnd;
break;
case N_LENG:
// second stab entry with length information
type = eSymbolTypeAdditional;
break;
default: break;
}
}
else
{
//uint8_t n_pext = N_PEXT & nlist.n_type;
uint8_t n_type = N_TYPE & nlist.n_type;
sym[sym_idx].SetExternal((N_EXT & nlist.n_type) != 0);
switch (n_type)
{
case N_INDR:
{
const char *reexport_name_cstr = strtab_data.PeekCStr(nlist.n_value);
if (reexport_name_cstr && reexport_name_cstr[0])
{
type = eSymbolTypeReExported;
ConstString reexport_name(reexport_name_cstr + ((reexport_name_cstr[0] == '_') ? 1 : 0));
sym[sym_idx].SetReExportedSymbolName(reexport_name);
set_value = false;
reexport_shlib_needs_fixup[sym_idx] = reexport_name;
indirect_symbol_names.insert(ConstString(symbol_name + ((symbol_name[0] == '_') ? 1 : 0)));
}
else
type = eSymbolTypeUndefined;
}
break;
case N_UNDF:
if (symbol_name && symbol_name[0])
{
ConstString undefined_name(symbol_name + ((symbol_name[0] == '_') ? 1 : 0));
undefined_name_to_desc[undefined_name] = nlist.n_desc;
}
LLVM_FALLTHROUGH;
case N_PBUD:
type = eSymbolTypeUndefined;
break;
case N_ABS:
type = eSymbolTypeAbsolute;
break;
case N_SECT:
{
symbol_section = section_info.GetSection (nlist.n_sect, nlist.n_value);
if (!symbol_section)
{
// TODO: warn about this?
add_nlist = false;
break;
}
if (TEXT_eh_frame_sectID == nlist.n_sect)
{
type = eSymbolTypeException;
}
else
{
uint32_t section_type = symbol_section->Get() & SECTION_TYPE;
switch (section_type)
{
case S_CSTRING_LITERALS: type = eSymbolTypeData; break; // section with only literal C strings
case S_4BYTE_LITERALS: type = eSymbolTypeData; break; // section with only 4 byte literals
case S_8BYTE_LITERALS: type = eSymbolTypeData; break; // section with only 8 byte literals
case S_LITERAL_POINTERS: type = eSymbolTypeTrampoline; break; // section with only pointers to literals
case S_NON_LAZY_SYMBOL_POINTERS: type = eSymbolTypeTrampoline; break; // section with only non-lazy symbol pointers
case S_LAZY_SYMBOL_POINTERS: type = eSymbolTypeTrampoline; break; // section with only lazy symbol pointers
case S_SYMBOL_STUBS: type = eSymbolTypeTrampoline; break; // section with only symbol stubs, byte size of stub in the reserved2 field
case S_MOD_INIT_FUNC_POINTERS: type = eSymbolTypeCode; break; // section with only function pointers for initialization
case S_MOD_TERM_FUNC_POINTERS: type = eSymbolTypeCode; break; // section with only function pointers for termination
case S_INTERPOSING: type = eSymbolTypeTrampoline; break; // section with only pairs of function pointers for interposing
case S_16BYTE_LITERALS: type = eSymbolTypeData; break; // section with only 16 byte literals
case S_DTRACE_DOF: type = eSymbolTypeInstrumentation; break;
case S_LAZY_DYLIB_SYMBOL_POINTERS: type = eSymbolTypeTrampoline; break;
default:
switch (symbol_section->GetType())
{
case lldb::eSectionTypeCode:
type = eSymbolTypeCode;
break;
case eSectionTypeData:
case eSectionTypeDataCString: // Inlined C string data
case eSectionTypeDataCStringPointers: // Pointers to C string data
case eSectionTypeDataSymbolAddress: // Address of a symbol in the symbol table
case eSectionTypeData4:
case eSectionTypeData8:
case eSectionTypeData16:
type = eSymbolTypeData;
break;
default:
break;
}
break;
}
if (type == eSymbolTypeInvalid)
{
const char *symbol_sect_name = symbol_section->GetName().AsCString();
if (symbol_section->IsDescendant (text_section_sp.get()))
{
if (symbol_section->IsClear(S_ATTR_PURE_INSTRUCTIONS |
S_ATTR_SELF_MODIFYING_CODE |
S_ATTR_SOME_INSTRUCTIONS))
type = eSymbolTypeData;
else
type = eSymbolTypeCode;
}
else
if (symbol_section->IsDescendant(data_section_sp.get()) ||
symbol_section->IsDescendant(data_dirty_section_sp.get()) ||
symbol_section->IsDescendant(data_const_section_sp.get()))
{
if (symbol_sect_name && ::strstr (symbol_sect_name, "__objc") == symbol_sect_name)
{
type = eSymbolTypeRuntime;
if (symbol_name)
{
llvm::StringRef symbol_name_ref(symbol_name);
if (symbol_name_ref.startswith("_OBJC_"))
{
static const llvm::StringRef g_objc_v2_prefix_class ("_OBJC_CLASS_$_");
static const llvm::StringRef g_objc_v2_prefix_metaclass ("_OBJC_METACLASS_$_");
static const llvm::StringRef g_objc_v2_prefix_ivar ("_OBJC_IVAR_$_");
if (symbol_name_ref.startswith(g_objc_v2_prefix_class))
{
symbol_name_non_abi_mangled = symbol_name + 1;
symbol_name = symbol_name + g_objc_v2_prefix_class.size();
type = eSymbolTypeObjCClass;
demangled_is_synthesized = true;
}
else if (symbol_name_ref.startswith(g_objc_v2_prefix_metaclass))
{
symbol_name_non_abi_mangled = symbol_name + 1;
symbol_name = symbol_name + g_objc_v2_prefix_metaclass.size();
type = eSymbolTypeObjCMetaClass;
demangled_is_synthesized = true;
}
else if (symbol_name_ref.startswith(g_objc_v2_prefix_ivar))
{
symbol_name_non_abi_mangled = symbol_name + 1;
symbol_name = symbol_name + g_objc_v2_prefix_ivar.size();
type = eSymbolTypeObjCIVar;
demangled_is_synthesized = true;
}
}
}
}
else
if (symbol_sect_name && ::strstr (symbol_sect_name, "__gcc_except_tab") == symbol_sect_name)
{
type = eSymbolTypeException;
}
else
{
type = eSymbolTypeData;
}
}
else
if (symbol_sect_name && ::strstr (symbol_sect_name, "__IMPORT") == symbol_sect_name)
{
type = eSymbolTypeTrampoline;
}
else
if (symbol_section->IsDescendant(objc_section_sp.get()))
{
type = eSymbolTypeRuntime;
if (symbol_name && symbol_name[0] == '.')
{
llvm::StringRef symbol_name_ref(symbol_name);
static const llvm::StringRef g_objc_v1_prefix_class (".objc_class_name_");
if (symbol_name_ref.startswith(g_objc_v1_prefix_class))
{
symbol_name_non_abi_mangled = symbol_name;
symbol_name = symbol_name + g_objc_v1_prefix_class.size();
type = eSymbolTypeObjCClass;
demangled_is_synthesized = true;
}
}
}
}
}
}
break;
}
}
if (add_nlist)
{
uint64_t symbol_value = nlist.n_value;
if (symbol_name_non_abi_mangled)
{
sym[sym_idx].GetMangled().SetMangledName (ConstString(symbol_name_non_abi_mangled));
sym[sym_idx].GetMangled().SetDemangledName (ConstString(symbol_name));
}
else
{
bool symbol_name_is_mangled = false;
if (symbol_name && symbol_name[0] == '_')
{
symbol_name_is_mangled = symbol_name[1] == '_';
symbol_name++; // Skip the leading underscore
}
if (symbol_name)
{
ConstString const_symbol_name(symbol_name);
sym[sym_idx].GetMangled().SetValue(const_symbol_name, symbol_name_is_mangled);
}
}
if (is_gsym)
{
const char *gsym_name = sym[sym_idx].GetMangled().GetName(lldb::eLanguageTypeUnknown, Mangled::ePreferMangled).GetCString();
if (gsym_name)
N_GSYM_name_to_sym_idx[gsym_name] = sym_idx;
}
if (symbol_section)
{
const addr_t section_file_addr = symbol_section->GetFileAddress();
if (symbol_byte_size == 0 && function_starts_count > 0)
{
addr_t symbol_lookup_file_addr = nlist.n_value;
// Do an exact address match for non-ARM addresses, else get the closest since
// the symbol might be a thumb symbol which has an address with bit zero set
FunctionStarts::Entry *func_start_entry = function_starts.FindEntry (symbol_lookup_file_addr, !is_arm);
if (is_arm && func_start_entry)
{
// Verify that the function start address is the symbol address (ARM)
// or the symbol address + 1 (thumb)
if (func_start_entry->addr != symbol_lookup_file_addr &&
func_start_entry->addr != (symbol_lookup_file_addr + 1))
{
// Not the right entry, NULL it out...
func_start_entry = NULL;
}
}
if (func_start_entry)
{
func_start_entry->data = true;
addr_t symbol_file_addr = func_start_entry->addr;
if (is_arm)
symbol_file_addr &= THUMB_ADDRESS_BIT_MASK;
const FunctionStarts::Entry *next_func_start_entry = function_starts.FindNextEntry (func_start_entry);
const addr_t section_end_file_addr = section_file_addr + symbol_section->GetByteSize();
if (next_func_start_entry)
{
addr_t next_symbol_file_addr = next_func_start_entry->addr;
// Be sure the clear the Thumb address bit when we calculate the size
// from the current and next address
if (is_arm)
next_symbol_file_addr &= THUMB_ADDRESS_BIT_MASK;
symbol_byte_size = std::min<lldb::addr_t>(next_symbol_file_addr - symbol_file_addr, section_end_file_addr - symbol_file_addr);
}
else
{
symbol_byte_size = section_end_file_addr - symbol_file_addr;
}
}
}
symbol_value -= section_file_addr;
}
if (is_debug == false)
{
if (type == eSymbolTypeCode)
{
// See if we can find a N_FUN entry for any code symbols.
// If we do find a match, and the name matches, then we
// can merge the two into just the function symbol to avoid
// duplicate entries in the symbol table
std::pair<ValueToSymbolIndexMap::const_iterator, ValueToSymbolIndexMap::const_iterator> range;
range = N_FUN_addr_to_sym_idx.equal_range(nlist.n_value);
if (range.first != range.second)
{
bool found_it = false;
for (ValueToSymbolIndexMap::const_iterator pos = range.first; pos != range.second; ++pos)
{
if (sym[sym_idx].GetMangled().GetName(lldb::eLanguageTypeUnknown, Mangled::ePreferMangled) == sym[pos->second].GetMangled().GetName(lldb::eLanguageTypeUnknown, Mangled::ePreferMangled))
{
m_nlist_idx_to_sym_idx[nlist_idx] = pos->second;
// We just need the flags from the linker symbol, so put these flags
// into the N_FUN flags to avoid duplicate symbols in the symbol table
sym[pos->second].SetExternal(sym[sym_idx].IsExternal());
sym[pos->second].SetFlags (nlist.n_type << 16 | nlist.n_desc);
if (resolver_addresses.find(nlist.n_value) != resolver_addresses.end())
sym[pos->second].SetType (eSymbolTypeResolver);
sym[sym_idx].Clear();
found_it = true;
break;
}
}
if (found_it)
continue;
}
else
{
if (resolver_addresses.find(nlist.n_value) != resolver_addresses.end())
type = eSymbolTypeResolver;
}
}
else if (type == eSymbolTypeData ||
type == eSymbolTypeObjCClass ||
type == eSymbolTypeObjCMetaClass ||
type == eSymbolTypeObjCIVar )
{
// See if we can find a N_STSYM entry for any data symbols.
// If we do find a match, and the name matches, then we
// can merge the two into just the Static symbol to avoid
// duplicate entries in the symbol table
std::pair<ValueToSymbolIndexMap::const_iterator, ValueToSymbolIndexMap::const_iterator> range;
range = N_STSYM_addr_to_sym_idx.equal_range(nlist.n_value);
if (range.first != range.second)
{
bool found_it = false;
for (ValueToSymbolIndexMap::const_iterator pos = range.first; pos != range.second; ++pos)
{
if (sym[sym_idx].GetMangled().GetName(lldb::eLanguageTypeUnknown, Mangled::ePreferMangled) == sym[pos->second].GetMangled().GetName(lldb::eLanguageTypeUnknown, Mangled::ePreferMangled))
{
m_nlist_idx_to_sym_idx[nlist_idx] = pos->second;
// We just need the flags from the linker symbol, so put these flags
// into the N_STSYM flags to avoid duplicate symbols in the symbol table
sym[pos->second].SetExternal(sym[sym_idx].IsExternal());
sym[pos->second].SetFlags (nlist.n_type << 16 | nlist.n_desc);
sym[sym_idx].Clear();
found_it = true;
break;
}
}
if (found_it)
continue;
}
else
{
// Combine N_GSYM stab entries with the non stab symbol
const char *gsym_name = sym[sym_idx].GetMangled().GetName(lldb::eLanguageTypeUnknown, Mangled::ePreferMangled).GetCString();
if (gsym_name)
{
ConstNameToSymbolIndexMap::const_iterator pos = N_GSYM_name_to_sym_idx.find(gsym_name);
if (pos != N_GSYM_name_to_sym_idx.end())
{
const uint32_t GSYM_sym_idx = pos->second;
m_nlist_idx_to_sym_idx[nlist_idx] = GSYM_sym_idx;
// Copy the address, because often the N_GSYM address has an invalid address of zero
// when the global is a common symbol
sym[GSYM_sym_idx].GetAddressRef().SetSection (symbol_section);
sym[GSYM_sym_idx].GetAddressRef().SetOffset (symbol_value);
// We just need the flags from the linker symbol, so put these flags
// into the N_GSYM flags to avoid duplicate symbols in the symbol table
sym[GSYM_sym_idx].SetFlags (nlist.n_type << 16 | nlist.n_desc);
sym[sym_idx].Clear();
continue;
}
}
}
}
}
sym[sym_idx].SetID (nlist_idx);
sym[sym_idx].SetType (type);
if (set_value)
{
sym[sym_idx].GetAddressRef().SetSection (symbol_section);
sym[sym_idx].GetAddressRef().SetOffset (symbol_value);
}
sym[sym_idx].SetFlags (nlist.n_type << 16 | nlist.n_desc);
if (symbol_byte_size > 0)
sym[sym_idx].SetByteSize(symbol_byte_size);
if (demangled_is_synthesized)
sym[sym_idx].SetDemangledNameIsSynthesized(true);
++sym_idx;
}
else
{
sym[sym_idx].Clear();
}
}
for (const auto &pos :reexport_shlib_needs_fixup)
{
const auto undef_pos = undefined_name_to_desc.find(pos.second);
if (undef_pos != undefined_name_to_desc.end())
{
const uint8_t dylib_ordinal = llvm::MachO::GET_LIBRARY_ORDINAL(undef_pos->second);
if (dylib_ordinal > 0 && dylib_ordinal < dylib_files.GetSize())
sym[pos.first].SetReExportedSymbolSharedLibrary(dylib_files.GetFileSpecAtIndex(dylib_ordinal-1));
}
}
}
uint32_t synthetic_sym_id = symtab_load_command.nsyms;
if (function_starts_count > 0)
{
uint32_t num_synthetic_function_symbols = 0;
for (i=0; i<function_starts_count; ++i)
{
if (function_starts.GetEntryRef (i).data == false)
++num_synthetic_function_symbols;
}
if (num_synthetic_function_symbols > 0)
{
if (num_syms < sym_idx + num_synthetic_function_symbols)
{
num_syms = sym_idx + num_synthetic_function_symbols;
sym = symtab->Resize (num_syms);
}
for (i=0; i<function_starts_count; ++i)
{
const FunctionStarts::Entry *func_start_entry = function_starts.GetEntryAtIndex (i);
if (func_start_entry->data == false)
{
addr_t symbol_file_addr = func_start_entry->addr;
uint32_t symbol_flags = 0;
if (is_arm)
{
if (symbol_file_addr & 1)
symbol_flags = MACHO_NLIST_ARM_SYMBOL_IS_THUMB;
symbol_file_addr &= THUMB_ADDRESS_BIT_MASK;
}
Address symbol_addr;
if (module_sp->ResolveFileAddress (symbol_file_addr, symbol_addr))
{
SectionSP symbol_section (symbol_addr.GetSection());
uint32_t symbol_byte_size = 0;
if (symbol_section)
{
const addr_t section_file_addr = symbol_section->GetFileAddress();
const FunctionStarts::Entry *next_func_start_entry = function_starts.FindNextEntry (func_start_entry);
const addr_t section_end_file_addr = section_file_addr + symbol_section->GetByteSize();
if (next_func_start_entry)
{
addr_t next_symbol_file_addr = next_func_start_entry->addr;
if (is_arm)
next_symbol_file_addr &= THUMB_ADDRESS_BIT_MASK;
symbol_byte_size = std::min<lldb::addr_t>(next_symbol_file_addr - symbol_file_addr, section_end_file_addr - symbol_file_addr);
}
else
{
symbol_byte_size = section_end_file_addr - symbol_file_addr;
}
sym[sym_idx].SetID (synthetic_sym_id++);
sym[sym_idx].GetMangled().SetDemangledName(GetNextSyntheticSymbolName());
sym[sym_idx].SetType (eSymbolTypeCode);
sym[sym_idx].SetIsSynthetic (true);
sym[sym_idx].GetAddressRef() = symbol_addr;
if (symbol_flags)
sym[sym_idx].SetFlags (symbol_flags);
if (symbol_byte_size)
sym[sym_idx].SetByteSize (symbol_byte_size);
++sym_idx;
}
}
}
}
}
}
// Trim our symbols down to just what we ended up with after
// removing any symbols.
if (sym_idx < num_syms)
{
num_syms = sym_idx;
sym = symtab->Resize (num_syms);
}
// Now synthesize indirect symbols
if (m_dysymtab.nindirectsyms != 0)
{
if (indirect_symbol_index_data.GetByteSize())
{
NListIndexToSymbolIndexMap::const_iterator end_index_pos = m_nlist_idx_to_sym_idx.end();
for (uint32_t sect_idx = 1; sect_idx < m_mach_sections.size(); ++sect_idx)
{
if ((m_mach_sections[sect_idx].flags & SECTION_TYPE) == S_SYMBOL_STUBS)
{
uint32_t symbol_stub_byte_size = m_mach_sections[sect_idx].reserved2;
if (symbol_stub_byte_size == 0)
continue;
const uint32_t num_symbol_stubs = m_mach_sections[sect_idx].size / symbol_stub_byte_size;
if (num_symbol_stubs == 0)
continue;
const uint32_t symbol_stub_index_offset = m_mach_sections[sect_idx].reserved1;
for (uint32_t stub_idx = 0; stub_idx < num_symbol_stubs; ++stub_idx)
{
const uint32_t symbol_stub_index = symbol_stub_index_offset + stub_idx;
const lldb::addr_t symbol_stub_addr = m_mach_sections[sect_idx].addr + (stub_idx * symbol_stub_byte_size);
lldb::offset_t symbol_stub_offset = symbol_stub_index * 4;
if (indirect_symbol_index_data.ValidOffsetForDataOfSize(symbol_stub_offset, 4))
{
const uint32_t stub_sym_id = indirect_symbol_index_data.GetU32 (&symbol_stub_offset);
if (stub_sym_id & (INDIRECT_SYMBOL_ABS | INDIRECT_SYMBOL_LOCAL))
continue;
NListIndexToSymbolIndexMap::const_iterator index_pos = m_nlist_idx_to_sym_idx.find (stub_sym_id);
Symbol *stub_symbol = NULL;
if (index_pos != end_index_pos)
{
// We have a remapping from the original nlist index to
// a current symbol index, so just look this up by index
stub_symbol = symtab->SymbolAtIndex (index_pos->second);
}
else
{
// We need to lookup a symbol using the original nlist
// symbol index since this index is coming from the
// S_SYMBOL_STUBS
stub_symbol = symtab->FindSymbolByID (stub_sym_id);
}
if (stub_symbol)
{
Address so_addr(symbol_stub_addr, section_list);
if (stub_symbol->GetType() == eSymbolTypeUndefined)
{
// Change the external symbol into a trampoline that makes sense
// These symbols were N_UNDF N_EXT, and are useless to us, so we
// can re-use them so we don't have to make up a synthetic symbol
// for no good reason.
if (resolver_addresses.find(symbol_stub_addr) == resolver_addresses.end())
stub_symbol->SetType (eSymbolTypeTrampoline);
else
stub_symbol->SetType (eSymbolTypeResolver);
stub_symbol->SetExternal (false);
stub_symbol->GetAddressRef() = so_addr;
stub_symbol->SetByteSize (symbol_stub_byte_size);
}
else
{
// Make a synthetic symbol to describe the trampoline stub
Mangled stub_symbol_mangled_name(stub_symbol->GetMangled());
if (sym_idx >= num_syms)
{
sym = symtab->Resize (++num_syms);
stub_symbol = NULL; // this pointer no longer valid
}
sym[sym_idx].SetID (synthetic_sym_id++);
sym[sym_idx].GetMangled() = stub_symbol_mangled_name;
if (resolver_addresses.find(symbol_stub_addr) == resolver_addresses.end())
sym[sym_idx].SetType (eSymbolTypeTrampoline);
else
sym[sym_idx].SetType (eSymbolTypeResolver);
sym[sym_idx].SetIsSynthetic (true);
sym[sym_idx].GetAddressRef() = so_addr;
sym[sym_idx].SetByteSize (symbol_stub_byte_size);
++sym_idx;
}
}
else
{
if (log)
log->Warning ("symbol stub referencing symbol table symbol %u that isn't in our minimal symbol table, fix this!!!", stub_sym_id);
}
}
}
}
}
}
}
if (!trie_entries.empty())
{
for (const auto &e : trie_entries)
{
if (e.entry.import_name)
{
// Only add indirect symbols from the Trie entries if we
// didn't have a N_INDR nlist entry for this already
if (indirect_symbol_names.find(e.entry.name) == indirect_symbol_names.end())
{
// Make a synthetic symbol to describe re-exported symbol.
if (sym_idx >= num_syms)
sym = symtab->Resize (++num_syms);
sym[sym_idx].SetID (synthetic_sym_id++);
sym[sym_idx].GetMangled() = Mangled(e.entry.name);
sym[sym_idx].SetType (eSymbolTypeReExported);
sym[sym_idx].SetIsSynthetic (true);
sym[sym_idx].SetReExportedSymbolName(e.entry.import_name);
if (e.entry.other > 0 && e.entry.other <= dylib_files.GetSize())
{
sym[sym_idx].SetReExportedSymbolSharedLibrary(dylib_files.GetFileSpecAtIndex(e.entry.other-1));
}
++sym_idx;
}
}
}
}
// StreamFile s(stdout, false);
// s.Printf ("Symbol table before CalculateSymbolSizes():\n");
// symtab->Dump(&s, NULL, eSortOrderNone);
// Set symbol byte sizes correctly since mach-o nlist entries don't have sizes
symtab->CalculateSymbolSizes();
// s.Printf ("Symbol table after CalculateSymbolSizes():\n");
// symtab->Dump(&s, NULL, eSortOrderNone);
return symtab->GetNumSymbols();
}
return 0;
}
void
ObjectFileMachO::Dump (Stream *s)
{
ModuleSP module_sp(GetModule());
if (module_sp)
{
lldb_private::Mutex::Locker locker(module_sp->GetMutex());
s->Printf("%p: ", static_cast<void*>(this));
s->Indent();
if (m_header.magic == MH_MAGIC_64 || m_header.magic == MH_CIGAM_64)
s->PutCString("ObjectFileMachO64");
else
s->PutCString("ObjectFileMachO32");
ArchSpec header_arch;
GetArchitecture(header_arch);
*s << ", file = '" << m_file << "', arch = " << header_arch.GetArchitectureName() << "\n";
SectionList *sections = GetSectionList();
if (sections)
sections->Dump(s, NULL, true, UINT32_MAX);
if (m_symtab_ap.get())
m_symtab_ap->Dump(s, NULL, eSortOrderNone);
}
}
bool
ObjectFileMachO::GetUUID (const llvm::MachO::mach_header &header,
const lldb_private::DataExtractor &data,
lldb::offset_t lc_offset,
lldb_private::UUID& uuid)
{
uint32_t i;
struct uuid_command load_cmd;
lldb::offset_t offset = lc_offset;
for (i=0; i<header.ncmds; ++i)
{
const lldb::offset_t cmd_offset = offset;
if (data.GetU32(&offset, &load_cmd, 2) == NULL)
break;
if (load_cmd.cmd == LC_UUID)
{
const uint8_t *uuid_bytes = data.PeekData(offset, 16);
if (uuid_bytes)
{
// OpenCL on Mac OS X uses the same UUID for each of its object files.
// We pretend these object files have no UUID to prevent crashing.
const uint8_t opencl_uuid[] = { 0x8c, 0x8e, 0xb3, 0x9b,
0x3b, 0xa8,
0x4b, 0x16,
0xb6, 0xa4,
0x27, 0x63, 0xbb, 0x14, 0xf0, 0x0d };
if (!memcmp(uuid_bytes, opencl_uuid, 16))
return false;
uuid.SetBytes (uuid_bytes);
return true;
}
return false;
}
offset = cmd_offset + load_cmd.cmdsize;
}
return false;
}
bool
ObjectFileMachO::GetArchitecture (const llvm::MachO::mach_header &header,
const lldb_private::DataExtractor &data,
lldb::offset_t lc_offset,
ArchSpec &arch)
{
arch.SetArchitecture (eArchTypeMachO, header.cputype, header.cpusubtype);
if (arch.IsValid())
{
llvm::Triple &triple = arch.GetTriple();
// Set OS to an unspecified unknown or a "*" so it can match any OS
triple.setOS(llvm::Triple::UnknownOS);
triple.setOSName(llvm::StringRef());
if (header.filetype == MH_PRELOAD)
{
if (header.cputype == CPU_TYPE_ARM)
{
// If this is a 32-bit arm binary, and it's a standalone binary,
// force the Vendor to Apple so we don't accidentally pick up
// the generic armv7 ABI at runtime. Apple's armv7 ABI always uses
// r7 for the frame pointer register; most other armv7 ABIs use a
// combination of r7 and r11.
triple.setVendor(llvm::Triple::Apple);
}
else
{
// Set vendor to an unspecified unknown or a "*" so it can match any vendor
// This is required for correct behavior of EFI debugging on x86_64
triple.setVendor(llvm::Triple::UnknownVendor);
triple.setVendorName(llvm::StringRef());
}
return true;
}
else
{
struct load_command load_cmd;
lldb::offset_t offset = lc_offset;
for (uint32_t i=0; i<header.ncmds; ++i)
{
const lldb::offset_t cmd_offset = offset;
if (data.GetU32(&offset, &load_cmd, 2) == NULL)
break;
switch (load_cmd.cmd)
{
case llvm::MachO::LC_VERSION_MIN_IPHONEOS:
triple.setOS (llvm::Triple::IOS);
return true;
case llvm::MachO::LC_VERSION_MIN_MACOSX:
triple.setOS (llvm::Triple::MacOSX);
return true;
case llvm::MachO::LC_VERSION_MIN_TVOS:
triple.setOS (llvm::Triple::TvOS);
return true;
case llvm::MachO::LC_VERSION_MIN_WATCHOS:
triple.setOS (llvm::Triple::WatchOS);
return true;
default:
break;
}
offset = cmd_offset + load_cmd.cmdsize;
}
if (header.filetype != MH_KEXT_BUNDLE)
{
// We didn't find a LC_VERSION_MIN load command and this isn't a KEXT
// so lets not say our Vendor is Apple, leave it as an unspecified unknown
triple.setVendor(llvm::Triple::UnknownVendor);
triple.setVendorName(llvm::StringRef());
}
}
}
return arch.IsValid();
}
bool
ObjectFileMachO::GetUUID (lldb_private::UUID* uuid)
{
ModuleSP module_sp(GetModule());
if (module_sp)
{
lldb_private::Mutex::Locker locker(module_sp->GetMutex());
lldb::offset_t offset = MachHeaderSizeFromMagic(m_header.magic);
return GetUUID (m_header, m_data, offset, *uuid);
}
return false;
}
uint32_t
ObjectFileMachO::GetDependentModules (FileSpecList& files)
{
uint32_t count = 0;
ModuleSP module_sp(GetModule());
if (module_sp)
{
lldb_private::Mutex::Locker locker(module_sp->GetMutex());
struct load_command load_cmd;
lldb::offset_t offset = MachHeaderSizeFromMagic(m_header.magic);
std::vector<std::string> rpath_paths;
std::vector<std::string> rpath_relative_paths;
const bool resolve_path = false; // Don't resolve the dependent file paths since they may not reside on this system
uint32_t i;
for (i=0; i<m_header.ncmds; ++i)
{
const uint32_t cmd_offset = offset;
if (m_data.GetU32(&offset, &load_cmd, 2) == NULL)
break;
switch (load_cmd.cmd)
{
case LC_RPATH:
case LC_LOAD_DYLIB:
case LC_LOAD_WEAK_DYLIB:
case LC_REEXPORT_DYLIB:
case LC_LOAD_DYLINKER:
case LC_LOADFVMLIB:
case LC_LOAD_UPWARD_DYLIB:
{
uint32_t name_offset = cmd_offset + m_data.GetU32(&offset);
const char *path = m_data.PeekCStr(name_offset);
if (path)
{
if (load_cmd.cmd == LC_RPATH)
rpath_paths.push_back(path);
else
{
if (path[0] == '@')
{
if (strncmp(path, "@rpath", strlen("@rpath")) == 0)
rpath_relative_paths.push_back(path + strlen("@rpath"));
}
else
{
FileSpec file_spec(path, resolve_path);
if (files.AppendIfUnique(file_spec))
count++;
}
}
}
}
break;
default:
break;
}
offset = cmd_offset + load_cmd.cmdsize;
}
if (!rpath_paths.empty())
{
// Fixup all LC_RPATH values to be absolute paths
FileSpec this_file_spec(m_file);
this_file_spec.ResolvePath();
std::string loader_path("@loader_path");
std::string executable_path("@executable_path");
for (auto &rpath : rpath_paths)
{
if (rpath.find(loader_path) == 0)
{
rpath.erase(0, loader_path.size());
rpath.insert(0, this_file_spec.GetDirectory().GetCString());
}
else if (rpath.find(executable_path) == 0)
{
rpath.erase(0, executable_path.size());
rpath.insert(0, this_file_spec.GetDirectory().GetCString());
}
}
for (const auto &rpath_relative_path : rpath_relative_paths)
{
for (const auto &rpath : rpath_paths)
{
std::string path = rpath;
path += rpath_relative_path;
// It is OK to resolve this path because we must find a file on
// disk for us to accept it anyway if it is rpath relative.
FileSpec file_spec(path, true);
// Remove any redundant parts of the path (like "../foo") since
// LC_RPATH values often contain "..".
file_spec.NormalizePath ();
if (file_spec.Exists() && files.AppendIfUnique(file_spec))
{
count++;
break;
}
}
}
}
}
return count;
}
lldb_private::Address
ObjectFileMachO::GetEntryPointAddress ()
{
// If the object file is not an executable it can't hold the entry point. m_entry_point_address
// is initialized to an invalid address, so we can just return that.
// If m_entry_point_address is valid it means we've found it already, so return the cached value.
if (!IsExecutable() || m_entry_point_address.IsValid())
return m_entry_point_address;
// Otherwise, look for the UnixThread or Thread command. The data for the Thread command is given in
// /usr/include/mach-o.h, but it is basically:
//
// uint32_t flavor - this is the flavor argument you would pass to thread_get_state
// uint32_t count - this is the count of longs in the thread state data
// struct XXX_thread_state state - this is the structure from <machine/thread_status.h> corresponding to the flavor.
// <repeat this trio>
//
// So we just keep reading the various register flavors till we find the GPR one, then read the PC out of there.
// FIXME: We will need to have a "RegisterContext data provider" class at some point that can get all the registers
// out of data in this form & attach them to a given thread. That should underlie the MacOS X User process plugin,
// and we'll also need it for the MacOS X Core File process plugin. When we have that we can also use it here.
//
// For now we hard-code the offsets and flavors we need:
//
//
ModuleSP module_sp(GetModule());
if (module_sp)
{
lldb_private::Mutex::Locker locker(module_sp->GetMutex());
struct load_command load_cmd;
lldb::offset_t offset = MachHeaderSizeFromMagic(m_header.magic);
uint32_t i;
lldb::addr_t start_address = LLDB_INVALID_ADDRESS;
bool done = false;
for (i=0; i<m_header.ncmds; ++i)
{
const lldb::offset_t cmd_offset = offset;
if (m_data.GetU32(&offset, &load_cmd, 2) == NULL)
break;
switch (load_cmd.cmd)
{
case LC_UNIXTHREAD:
case LC_THREAD:
{
while (offset < cmd_offset + load_cmd.cmdsize)
{
uint32_t flavor = m_data.GetU32(&offset);
uint32_t count = m_data.GetU32(&offset);
if (count == 0)
{
// We've gotten off somehow, log and exit;
return m_entry_point_address;
}
switch (m_header.cputype)
{
case llvm::MachO::CPU_TYPE_ARM:
if (flavor == 1 || flavor == 9) // ARM_THREAD_STATE/ARM_THREAD_STATE32 from mach/arm/thread_status.h
{
offset += 60; // This is the offset of pc in the GPR thread state data structure.
start_address = m_data.GetU32(&offset);
done = true;
}
break;
case llvm::MachO::CPU_TYPE_ARM64:
if (flavor == 6) // ARM_THREAD_STATE64 from mach/arm/thread_status.h
{
offset += 256; // This is the offset of pc in the GPR thread state data structure.
start_address = m_data.GetU64(&offset);
done = true;
}
break;
case llvm::MachO::CPU_TYPE_I386:
if (flavor == 1) // x86_THREAD_STATE32 from mach/i386/thread_status.h
{
offset += 40; // This is the offset of eip in the GPR thread state data structure.
start_address = m_data.GetU32(&offset);
done = true;
}
break;
case llvm::MachO::CPU_TYPE_X86_64:
if (flavor == 4) // x86_THREAD_STATE64 from mach/i386/thread_status.h
{
offset += 16 * 8; // This is the offset of rip in the GPR thread state data structure.
start_address = m_data.GetU64(&offset);
done = true;
}
break;
default:
return m_entry_point_address;
}
// Haven't found the GPR flavor yet, skip over the data for this flavor:
if (done)
break;
offset += count * 4;
}
}
break;
case LC_MAIN:
{
ConstString text_segment_name ("__TEXT");
uint64_t entryoffset = m_data.GetU64(&offset);
SectionSP text_segment_sp = GetSectionList()->FindSectionByName(text_segment_name);
if (text_segment_sp)
{
done = true;
start_address = text_segment_sp->GetFileAddress() + entryoffset;
}
}
break;
default:
break;
}
if (done)
break;
// Go to the next load command:
offset = cmd_offset + load_cmd.cmdsize;
}
if (start_address != LLDB_INVALID_ADDRESS)
{
// We got the start address from the load commands, so now resolve that address in the sections
// of this ObjectFile:
if (!m_entry_point_address.ResolveAddressUsingFileSections (start_address, GetSectionList()))
{
m_entry_point_address.Clear();
}
}
else
{
// We couldn't read the UnixThread load command - maybe it wasn't there. As a fallback look for the
// "start" symbol in the main executable.
ModuleSP module_sp (GetModule());
if (module_sp)
{
SymbolContextList contexts;
SymbolContext context;
if (module_sp->FindSymbolsWithNameAndType(ConstString ("start"), eSymbolTypeCode, contexts))
{
if (contexts.GetContextAtIndex(0, context))
m_entry_point_address = context.symbol->GetAddress();
}
}
}
}
return m_entry_point_address;
}
lldb_private::Address
ObjectFileMachO::GetHeaderAddress ()
{
lldb_private::Address header_addr;
SectionList *section_list = GetSectionList();
if (section_list)
{
SectionSP text_segment_sp (section_list->FindSectionByName (GetSegmentNameTEXT()));
if (text_segment_sp)
{
header_addr.SetSection (text_segment_sp);
header_addr.SetOffset (0);
}
}
return header_addr;
}
uint32_t
ObjectFileMachO::GetNumThreadContexts ()
{
ModuleSP module_sp(GetModule());
if (module_sp)
{
lldb_private::Mutex::Locker locker(module_sp->GetMutex());
if (!m_thread_context_offsets_valid)
{
m_thread_context_offsets_valid = true;
lldb::offset_t offset = MachHeaderSizeFromMagic(m_header.magic);
FileRangeArray::Entry file_range;
thread_command thread_cmd;
for (uint32_t i=0; i<m_header.ncmds; ++i)
{
const uint32_t cmd_offset = offset;
if (m_data.GetU32(&offset, &thread_cmd, 2) == NULL)
break;
if (thread_cmd.cmd == LC_THREAD)
{
file_range.SetRangeBase (offset);
file_range.SetByteSize (thread_cmd.cmdsize - 8);
m_thread_context_offsets.Append (file_range);
}
offset = cmd_offset + thread_cmd.cmdsize;
}
}
}
return m_thread_context_offsets.GetSize();
}
lldb::RegisterContextSP
ObjectFileMachO::GetThreadContextAtIndex (uint32_t idx, lldb_private::Thread &thread)
{
lldb::RegisterContextSP reg_ctx_sp;
ModuleSP module_sp(GetModule());
if (module_sp)
{
lldb_private::Mutex::Locker locker(module_sp->GetMutex());
if (!m_thread_context_offsets_valid)
GetNumThreadContexts ();
const FileRangeArray::Entry *thread_context_file_range = m_thread_context_offsets.GetEntryAtIndex (idx);
if (thread_context_file_range)
{
DataExtractor data (m_data,
thread_context_file_range->GetRangeBase(),
thread_context_file_range->GetByteSize());
switch (m_header.cputype)
{
case llvm::MachO::CPU_TYPE_ARM64:
reg_ctx_sp.reset (new RegisterContextDarwin_arm64_Mach (thread, data));
break;
case llvm::MachO::CPU_TYPE_ARM:
reg_ctx_sp.reset (new RegisterContextDarwin_arm_Mach (thread, data));
break;
case llvm::MachO::CPU_TYPE_I386:
reg_ctx_sp.reset (new RegisterContextDarwin_i386_Mach (thread, data));
break;
case llvm::MachO::CPU_TYPE_X86_64:
reg_ctx_sp.reset (new RegisterContextDarwin_x86_64_Mach (thread, data));
break;
}
}
}
return reg_ctx_sp;
}
ObjectFile::Type
ObjectFileMachO::CalculateType()
{
switch (m_header.filetype)
{
case MH_OBJECT: // 0x1u
if (GetAddressByteSize () == 4)
{
// 32 bit kexts are just object files, but they do have a valid
// UUID load command.
UUID uuid;
if (GetUUID(&uuid))
{
// this checking for the UUID load command is not enough
// we could eventually look for the symbol named
// "OSKextGetCurrentIdentifier" as this is required of kexts
if (m_strata == eStrataInvalid)
m_strata = eStrataKernel;
return eTypeSharedLibrary;
}
}
return eTypeObjectFile;
case MH_EXECUTE: return eTypeExecutable; // 0x2u
case MH_FVMLIB: return eTypeSharedLibrary; // 0x3u
case MH_CORE: return eTypeCoreFile; // 0x4u
case MH_PRELOAD: return eTypeSharedLibrary; // 0x5u
case MH_DYLIB: return eTypeSharedLibrary; // 0x6u
case MH_DYLINKER: return eTypeDynamicLinker; // 0x7u
case MH_BUNDLE: return eTypeSharedLibrary; // 0x8u
case MH_DYLIB_STUB: return eTypeStubLibrary; // 0x9u
case MH_DSYM: return eTypeDebugInfo; // 0xAu
case MH_KEXT_BUNDLE: return eTypeSharedLibrary; // 0xBu
default:
break;
}
return eTypeUnknown;
}
ObjectFile::Strata
ObjectFileMachO::CalculateStrata()
{
switch (m_header.filetype)
{
case MH_OBJECT: // 0x1u
{
// 32 bit kexts are just object files, but they do have a valid
// UUID load command.
UUID uuid;
if (GetUUID(&uuid))
{
// this checking for the UUID load command is not enough
// we could eventually look for the symbol named
// "OSKextGetCurrentIdentifier" as this is required of kexts
if (m_type == eTypeInvalid)
m_type = eTypeSharedLibrary;
return eStrataKernel;
}
}
return eStrataUnknown;
case MH_EXECUTE: // 0x2u
// Check for the MH_DYLDLINK bit in the flags
if (m_header.flags & MH_DYLDLINK)
{
return eStrataUser;
}
else
{
SectionList *section_list = GetSectionList();
if (section_list)
{
static ConstString g_kld_section_name ("__KLD");
if (section_list->FindSectionByName(g_kld_section_name))
return eStrataKernel;
}
}
return eStrataRawImage;
case MH_FVMLIB: return eStrataUser; // 0x3u
case MH_CORE: return eStrataUnknown; // 0x4u
case MH_PRELOAD: return eStrataRawImage; // 0x5u
case MH_DYLIB: return eStrataUser; // 0x6u
case MH_DYLINKER: return eStrataUser; // 0x7u
case MH_BUNDLE: return eStrataUser; // 0x8u
case MH_DYLIB_STUB: return eStrataUser; // 0x9u
case MH_DSYM: return eStrataUnknown; // 0xAu
case MH_KEXT_BUNDLE: return eStrataKernel; // 0xBu
default:
break;
}
return eStrataUnknown;
}
uint32_t
ObjectFileMachO::GetVersion (uint32_t *versions, uint32_t num_versions)
{
ModuleSP module_sp(GetModule());
if (module_sp)
{
lldb_private::Mutex::Locker locker(module_sp->GetMutex());
struct dylib_command load_cmd;
lldb::offset_t offset = MachHeaderSizeFromMagic(m_header.magic);
uint32_t version_cmd = 0;
uint64_t version = 0;
uint32_t i;
for (i=0; i<m_header.ncmds; ++i)
{
const lldb::offset_t cmd_offset = offset;
if (m_data.GetU32(&offset, &load_cmd, 2) == NULL)
break;
if (load_cmd.cmd == LC_ID_DYLIB)
{
if (version_cmd == 0)
{
version_cmd = load_cmd.cmd;
if (m_data.GetU32(&offset, &load_cmd.dylib, 4) == NULL)
break;
version = load_cmd.dylib.current_version;
}
break; // Break for now unless there is another more complete version
// number load command in the future.
}
offset = cmd_offset + load_cmd.cmdsize;
}
if (version_cmd == LC_ID_DYLIB)
{
if (versions != NULL && num_versions > 0)
{
if (num_versions > 0)
versions[0] = (version & 0xFFFF0000ull) >> 16;
if (num_versions > 1)
versions[1] = (version & 0x0000FF00ull) >> 8;
if (num_versions > 2)
versions[2] = (version & 0x000000FFull);
// Fill in an remaining version numbers with invalid values
for (i=3; i<num_versions; ++i)
versions[i] = UINT32_MAX;
}
// The LC_ID_DYLIB load command has a version with 3 version numbers
// in it, so always return 3
return 3;
}
}
return false;
}
bool
ObjectFileMachO::GetArchitecture (ArchSpec &arch)
{
ModuleSP module_sp(GetModule());
if (module_sp)
{
lldb_private::Mutex::Locker locker(module_sp->GetMutex());
return GetArchitecture (m_header, m_data, MachHeaderSizeFromMagic(m_header.magic), arch);
}
return false;
}
UUID
ObjectFileMachO::GetProcessSharedCacheUUID (Process *process)
{
UUID uuid;
if (process)
{
addr_t all_image_infos = process->GetImageInfoAddress();
// The address returned by GetImageInfoAddress may be the address of dyld (don't want)
// or it may be the address of the dyld_all_image_infos structure (want). The first four
// bytes will be either the version field (all_image_infos) or a Mach-O file magic constant.
// Version 13 and higher of dyld_all_image_infos is required to get the sharedCacheUUID field.
Error err;
uint32_t version_or_magic = process->ReadUnsignedIntegerFromMemory (all_image_infos, 4, -1, err);
if (version_or_magic != static_cast<uint32_t>(-1)
&& version_or_magic != MH_MAGIC
&& version_or_magic != MH_CIGAM
&& version_or_magic != MH_MAGIC_64
&& version_or_magic != MH_CIGAM_64
&& version_or_magic >= 13)
{
addr_t sharedCacheUUID_address = LLDB_INVALID_ADDRESS;
int wordsize = process->GetAddressByteSize();
if (wordsize == 8)
{
sharedCacheUUID_address = all_image_infos + 160; // sharedCacheUUID <mach-o/dyld_images.h>
}
if (wordsize == 4)
{
sharedCacheUUID_address = all_image_infos + 84; // sharedCacheUUID <mach-o/dyld_images.h>
}
if (sharedCacheUUID_address != LLDB_INVALID_ADDRESS)
{
uuid_t shared_cache_uuid;
if (process->ReadMemory (sharedCacheUUID_address, shared_cache_uuid, sizeof (uuid_t), err) == sizeof (uuid_t))
{
uuid.SetBytes (shared_cache_uuid);
}
}
}
}
return uuid;
}
UUID
ObjectFileMachO::GetLLDBSharedCacheUUID ()
{
UUID uuid;
#if defined (__APPLE__) && (defined (__arm__) || defined (__arm64__) || defined (__aarch64__))
uint8_t *(*dyld_get_all_image_infos)(void);
dyld_get_all_image_infos = (uint8_t*(*)()) dlsym (RTLD_DEFAULT, "_dyld_get_all_image_infos");
if (dyld_get_all_image_infos)
{
uint8_t *dyld_all_image_infos_address = dyld_get_all_image_infos();
if (dyld_all_image_infos_address)
{
uint32_t *version = (uint32_t*) dyld_all_image_infos_address; // version <mach-o/dyld_images.h>
if (*version >= 13)
{
uuid_t *sharedCacheUUID_address = 0;
int wordsize = sizeof (uint8_t *);
if (wordsize == 8)
{
sharedCacheUUID_address = (uuid_t*) ((uint8_t*) dyld_all_image_infos_address + 160); // sharedCacheUUID <mach-o/dyld_images.h>
}
else
{
sharedCacheUUID_address = (uuid_t*) ((uint8_t*) dyld_all_image_infos_address + 84); // sharedCacheUUID <mach-o/dyld_images.h>
}
uuid.SetBytes (sharedCacheUUID_address);
}
}
}
#endif
return uuid;
}
uint32_t
ObjectFileMachO::GetMinimumOSVersion (uint32_t *versions, uint32_t num_versions)
{
if (m_min_os_versions.empty())
{
lldb::offset_t offset = MachHeaderSizeFromMagic(m_header.magic);
bool success = false;
for (uint32_t i=0; success == false && i < m_header.ncmds; ++i)
{
const lldb::offset_t load_cmd_offset = offset;
version_min_command lc;
if (m_data.GetU32(&offset, &lc.cmd, 2) == NULL)
break;
if (lc.cmd == llvm::MachO::LC_VERSION_MIN_MACOSX
|| lc.cmd == llvm::MachO::LC_VERSION_MIN_IPHONEOS
|| lc.cmd == llvm::MachO::LC_VERSION_MIN_TVOS
|| lc.cmd == llvm::MachO::LC_VERSION_MIN_WATCHOS)
{
if (m_data.GetU32 (&offset, &lc.version, (sizeof(lc) / sizeof(uint32_t)) - 2))
{
const uint32_t xxxx = lc.version >> 16;
const uint32_t yy = (lc.version >> 8) & 0xffu;
const uint32_t zz = lc.version & 0xffu;
if (xxxx)
{
m_min_os_versions.push_back(xxxx);
m_min_os_versions.push_back(yy);
m_min_os_versions.push_back(zz);
}
success = true;
}
}
offset = load_cmd_offset + lc.cmdsize;
}
if (success == false)
{
// Push an invalid value so we don't keep trying to
m_min_os_versions.push_back(UINT32_MAX);
}
}
if (m_min_os_versions.size() > 1 || m_min_os_versions[0] != UINT32_MAX)
{
if (versions != NULL && num_versions > 0)
{
for (size_t i=0; i<num_versions; ++i)
{
if (i < m_min_os_versions.size())
versions[i] = m_min_os_versions[i];
else
versions[i] = 0;
}
}
return m_min_os_versions.size();
}
// Call the superclasses version that will empty out the data
return ObjectFile::GetMinimumOSVersion (versions, num_versions);
}
uint32_t
ObjectFileMachO::GetSDKVersion(uint32_t *versions, uint32_t num_versions)
{
if (m_sdk_versions.empty())
{
lldb::offset_t offset = MachHeaderSizeFromMagic(m_header.magic);
bool success = false;
for (uint32_t i=0; success == false && i < m_header.ncmds; ++i)
{
const lldb::offset_t load_cmd_offset = offset;
version_min_command lc;
if (m_data.GetU32(&offset, &lc.cmd, 2) == NULL)
break;
if (lc.cmd == llvm::MachO::LC_VERSION_MIN_MACOSX
|| lc.cmd == llvm::MachO::LC_VERSION_MIN_IPHONEOS
|| lc.cmd == llvm::MachO::LC_VERSION_MIN_TVOS
|| lc.cmd == llvm::MachO::LC_VERSION_MIN_WATCHOS)
{
if (m_data.GetU32 (&offset, &lc.version, (sizeof(lc) / sizeof(uint32_t)) - 2))
{
const uint32_t xxxx = lc.sdk >> 16;
const uint32_t yy = (lc.sdk >> 8) & 0xffu;
const uint32_t zz = lc.sdk & 0xffu;
if (xxxx)
{
m_sdk_versions.push_back(xxxx);
m_sdk_versions.push_back(yy);
m_sdk_versions.push_back(zz);
}
success = true;
}
}
offset = load_cmd_offset + lc.cmdsize;
}
if (success == false)
{
// Push an invalid value so we don't keep trying to
m_sdk_versions.push_back(UINT32_MAX);
}
}
if (m_sdk_versions.size() > 1 || m_sdk_versions[0] != UINT32_MAX)
{
if (versions != NULL && num_versions > 0)
{
for (size_t i=0; i<num_versions; ++i)
{
if (i < m_sdk_versions.size())
versions[i] = m_sdk_versions[i];
else
versions[i] = 0;
}
}
return m_sdk_versions.size();
}
// Call the superclasses version that will empty out the data
return ObjectFile::GetSDKVersion (versions, num_versions);
}
bool
ObjectFileMachO::GetIsDynamicLinkEditor()
{
return m_header.filetype == llvm::MachO::MH_DYLINKER;
}
//------------------------------------------------------------------
// PluginInterface protocol
//------------------------------------------------------------------
lldb_private::ConstString
ObjectFileMachO::GetPluginName()
{
return GetPluginNameStatic();
}
uint32_t
ObjectFileMachO::GetPluginVersion()
{
return 1;
}
Section *
ObjectFileMachO::GetMachHeaderSection()
{
// Find the first address of the mach header which is the first non-zero
// file sized section whose file offset is zero. This is the base file address
// of the mach-o file which can be subtracted from the vmaddr of the other
// segments found in memory and added to the load address
ModuleSP module_sp = GetModule();
if (module_sp)
{
SectionList *section_list = GetSectionList ();
if (section_list)
{
lldb::addr_t mach_base_file_addr = LLDB_INVALID_ADDRESS;
const size_t num_sections = section_list->GetSize();
for (size_t sect_idx = 0;
sect_idx < num_sections && mach_base_file_addr == LLDB_INVALID_ADDRESS;
++sect_idx)
{
Section *section = section_list->GetSectionAtIndex (sect_idx).get();
if (section &&
section->GetFileSize() > 0 &&
section->GetFileOffset() == 0 &&
section->IsThreadSpecific() == false &&
module_sp.get() == section->GetModule().get())
{
return section;
}
}
}
}
return nullptr;
}
lldb::addr_t
ObjectFileMachO::CalculateSectionLoadAddressForMemoryImage(lldb::addr_t mach_header_load_address, const Section *mach_header_section, const Section *section)
{
ModuleSP module_sp = GetModule();
if (module_sp && mach_header_section && section && mach_header_load_address != LLDB_INVALID_ADDRESS)
{
lldb::addr_t mach_header_file_addr = mach_header_section->GetFileAddress();
if (mach_header_file_addr != LLDB_INVALID_ADDRESS)
{
if (section &&
section->GetFileSize() > 0 &&
section->IsThreadSpecific() == false &&
module_sp.get() == section->GetModule().get())
{
// Ignore __LINKEDIT and __DWARF segments
if (section->GetName() == GetSegmentNameLINKEDIT())
{
// Only map __LINKEDIT if we have an in memory image and this isn't
// a kernel binary like a kext or mach_kernel.
const bool is_memory_image = (bool)m_process_wp.lock();
const Strata strata = GetStrata();
if (is_memory_image == false || strata == eStrataKernel)
return LLDB_INVALID_ADDRESS;
}
return section->GetFileAddress() - mach_header_file_addr + mach_header_load_address;
}
}
}
return LLDB_INVALID_ADDRESS;
}
bool
ObjectFileMachO::SetLoadAddress (Target &target,
lldb::addr_t value,
bool value_is_offset)
{
ModuleSP module_sp = GetModule();
if (module_sp)
{
size_t num_loaded_sections = 0;
SectionList *section_list = GetSectionList ();
if (section_list)
{
const size_t num_sections = section_list->GetSize();
if (value_is_offset)
{
// "value" is an offset to apply to each top level segment
for (size_t sect_idx = 0; sect_idx < num_sections; ++sect_idx)
{
// Iterate through the object file sections to find all
// of the sections that size on disk (to avoid __PAGEZERO)
// and load them
SectionSP section_sp (section_list->GetSectionAtIndex (sect_idx));
if (section_sp &&
section_sp->GetFileSize() > 0 &&
section_sp->IsThreadSpecific() == false &&
module_sp.get() == section_sp->GetModule().get())
{
// Ignore __LINKEDIT and __DWARF segments
if (section_sp->GetName() == GetSegmentNameLINKEDIT())
{
// Only map __LINKEDIT if we have an in memory image and this isn't
// a kernel binary like a kext or mach_kernel.
const bool is_memory_image = (bool)m_process_wp.lock();
const Strata strata = GetStrata();
if (is_memory_image == false || strata == eStrataKernel)
continue;
}
if (target.GetSectionLoadList().SetSectionLoadAddress (section_sp, section_sp->GetFileAddress() + value))
++num_loaded_sections;
}
}
}
else
{
// "value" is the new base address of the mach_header, adjust each
// section accordingly
Section *mach_header_section = GetMachHeaderSection();
if (mach_header_section)
{
for (size_t sect_idx = 0; sect_idx < num_sections; ++sect_idx)
{
SectionSP section_sp (section_list->GetSectionAtIndex (sect_idx));
lldb::addr_t section_load_addr = CalculateSectionLoadAddressForMemoryImage(value, mach_header_section, section_sp.get());
if (section_load_addr != LLDB_INVALID_ADDRESS)
{
if (target.GetSectionLoadList().SetSectionLoadAddress (section_sp, section_load_addr))
++num_loaded_sections;
}
}
}
}
}
return num_loaded_sections > 0;
}
return false;
}
bool
ObjectFileMachO::SaveCore (const lldb::ProcessSP &process_sp,
const FileSpec &outfile,
Error &error)
{
if (process_sp)
{
Target &target = process_sp->GetTarget();
const ArchSpec target_arch = target.GetArchitecture();
const llvm::Triple &target_triple = target_arch.GetTriple();
if (target_triple.getVendor() == llvm::Triple::Apple &&
(target_triple.getOS() == llvm::Triple::MacOSX
|| target_triple.getOS() == llvm::Triple::IOS
|| target_triple.getOS() == llvm::Triple::WatchOS
|| target_triple.getOS() == llvm::Triple::TvOS))
{
bool make_core = false;
switch (target_arch.GetMachine())
{
case llvm::Triple::aarch64:
case llvm::Triple::arm:
case llvm::Triple::thumb:
case llvm::Triple::x86:
case llvm::Triple::x86_64:
make_core = true;
break;
default:
error.SetErrorStringWithFormat ("unsupported core architecture: %s", target_triple.str().c_str());
break;
}
if (make_core)
{
std::vector<segment_command_64> segment_load_commands;
// uint32_t range_info_idx = 0;
MemoryRegionInfo range_info;
Error range_error = process_sp->GetMemoryRegionInfo(0, range_info);
const uint32_t addr_byte_size = target_arch.GetAddressByteSize();
const ByteOrder byte_order = target_arch.GetByteOrder();
if (range_error.Success())
{
while (range_info.GetRange().GetRangeBase() != LLDB_INVALID_ADDRESS)
{
const addr_t addr = range_info.GetRange().GetRangeBase();
const addr_t size = range_info.GetRange().GetByteSize();
if (size == 0)
break;
// Calculate correct protections
uint32_t prot = 0;
if (range_info.GetReadable() == MemoryRegionInfo::eYes)
prot |= VM_PROT_READ;
if (range_info.GetWritable() == MemoryRegionInfo::eYes)
prot |= VM_PROT_WRITE;
if (range_info.GetExecutable() == MemoryRegionInfo::eYes)
prot |= VM_PROT_EXECUTE;
// printf ("[%3u] [0x%16.16" PRIx64 " - 0x%16.16" PRIx64 ") %c%c%c\n",
// range_info_idx,
// addr,
// size,
// (prot & VM_PROT_READ ) ? 'r' : '-',
// (prot & VM_PROT_WRITE ) ? 'w' : '-',
// (prot & VM_PROT_EXECUTE) ? 'x' : '-');
if (prot != 0)
{
uint32_t cmd_type = LC_SEGMENT_64;
uint32_t segment_size = sizeof (segment_command_64);
if (addr_byte_size == 4)
{
cmd_type = LC_SEGMENT;
segment_size = sizeof (segment_command);
}
segment_command_64 segment = {
cmd_type, // uint32_t cmd;
segment_size, // uint32_t cmdsize;
{0}, // char segname[16];
addr, // uint64_t vmaddr; // uint32_t for 32-bit Mach-O
size, // uint64_t vmsize; // uint32_t for 32-bit Mach-O
0, // uint64_t fileoff; // uint32_t for 32-bit Mach-O
size, // uint64_t filesize; // uint32_t for 32-bit Mach-O
prot, // uint32_t maxprot;
prot, // uint32_t initprot;
0, // uint32_t nsects;
0 }; // uint32_t flags;
segment_load_commands.push_back(segment);
}
else
{
// No protections and a size of 1 used to be returned from old
// debugservers when we asked about a region that was past the
// last memory region and it indicates the end...
if (size == 1)
break;
}
range_error = process_sp->GetMemoryRegionInfo(range_info.GetRange().GetRangeEnd(), range_info);
if (range_error.Fail())
break;
}
StreamString buffer (Stream::eBinary,
addr_byte_size,
byte_order);
mach_header_64 mach_header;
if (addr_byte_size == 8)
{
mach_header.magic = MH_MAGIC_64;
}
else
{
mach_header.magic = MH_MAGIC;
}
mach_header.cputype = target_arch.GetMachOCPUType();
mach_header.cpusubtype = target_arch.GetMachOCPUSubType();
mach_header.filetype = MH_CORE;
mach_header.ncmds = segment_load_commands.size();
mach_header.flags = 0;
mach_header.reserved = 0;
ThreadList &thread_list = process_sp->GetThreadList();
const uint32_t num_threads = thread_list.GetSize();
// Make an array of LC_THREAD data items. Each one contains
// the contents of the LC_THREAD load command. The data doesn't
// contain the load command + load command size, we will
// add the load command and load command size as we emit the data.
std::vector<StreamString> LC_THREAD_datas(num_threads);
for (auto &LC_THREAD_data : LC_THREAD_datas)
{
LC_THREAD_data.GetFlags().Set(Stream::eBinary);
LC_THREAD_data.SetAddressByteSize(addr_byte_size);
LC_THREAD_data.SetByteOrder(byte_order);
}
for (uint32_t thread_idx = 0; thread_idx < num_threads; ++thread_idx)
{
ThreadSP thread_sp (thread_list.GetThreadAtIndex(thread_idx));
if (thread_sp)
{
switch (mach_header.cputype)
{
case llvm::MachO::CPU_TYPE_ARM64:
RegisterContextDarwin_arm64_Mach::Create_LC_THREAD (thread_sp.get(), LC_THREAD_datas[thread_idx]);
break;
case llvm::MachO::CPU_TYPE_ARM:
RegisterContextDarwin_arm_Mach::Create_LC_THREAD (thread_sp.get(), LC_THREAD_datas[thread_idx]);
break;
case llvm::MachO::CPU_TYPE_I386:
RegisterContextDarwin_i386_Mach::Create_LC_THREAD (thread_sp.get(), LC_THREAD_datas[thread_idx]);
break;
case llvm::MachO::CPU_TYPE_X86_64:
RegisterContextDarwin_x86_64_Mach::Create_LC_THREAD (thread_sp.get(), LC_THREAD_datas[thread_idx]);
break;
}
}
}
// The size of the load command is the size of the segments...
if (addr_byte_size == 8)
{
mach_header.sizeofcmds = segment_load_commands.size() * sizeof (struct segment_command_64);
}
else
{
mach_header.sizeofcmds = segment_load_commands.size() * sizeof (struct segment_command);
}
// and the size of all LC_THREAD load command
for (const auto &LC_THREAD_data : LC_THREAD_datas)
{
++mach_header.ncmds;
mach_header.sizeofcmds += 8 + LC_THREAD_data.GetSize();
}
printf ("mach_header: 0x%8.8x 0x%8.8x 0x%8.8x 0x%8.8x 0x%8.8x 0x%8.8x 0x%8.8x 0x%8.8x\n",
mach_header.magic,
mach_header.cputype,
mach_header.cpusubtype,
mach_header.filetype,
mach_header.ncmds,
mach_header.sizeofcmds,
mach_header.flags,
mach_header.reserved);
// Write the mach header
buffer.PutHex32(mach_header.magic);
buffer.PutHex32(mach_header.cputype);
buffer.PutHex32(mach_header.cpusubtype);
buffer.PutHex32(mach_header.filetype);
buffer.PutHex32(mach_header.ncmds);
buffer.PutHex32(mach_header.sizeofcmds);
buffer.PutHex32(mach_header.flags);
if (addr_byte_size == 8)
{
buffer.PutHex32(mach_header.reserved);
}
// Skip the mach header and all load commands and align to the next
// 0x1000 byte boundary
addr_t file_offset = buffer.GetSize() + mach_header.sizeofcmds;
if (file_offset & 0x00000fff)
{
file_offset += 0x00001000ull;
file_offset &= (~0x00001000ull + 1);
}
for (auto &segment : segment_load_commands)
{
segment.fileoff = file_offset;
file_offset += segment.filesize;
}
// Write out all of the LC_THREAD load commands
for (const auto &LC_THREAD_data : LC_THREAD_datas)
{
const size_t LC_THREAD_data_size = LC_THREAD_data.GetSize();
buffer.PutHex32(LC_THREAD);
buffer.PutHex32(8 + LC_THREAD_data_size); // cmd + cmdsize + data
buffer.Write(LC_THREAD_data.GetData(), LC_THREAD_data_size);
}
// Write out all of the segment load commands
for (const auto &segment : segment_load_commands)
{
printf ("0x%8.8x 0x%8.8x [0x%16.16" PRIx64 " - 0x%16.16" PRIx64 ") [0x%16.16" PRIx64 " 0x%16.16" PRIx64 ") 0x%8.8x 0x%8.8x 0x%8.8x 0x%8.8x]\n",
segment.cmd,
segment.cmdsize,
segment.vmaddr,
segment.vmaddr + segment.vmsize,
segment.fileoff,
segment.filesize,
segment.maxprot,
segment.initprot,
segment.nsects,
segment.flags);
buffer.PutHex32(segment.cmd);
buffer.PutHex32(segment.cmdsize);
buffer.PutRawBytes(segment.segname, sizeof(segment.segname));
if (addr_byte_size == 8)
{
buffer.PutHex64(segment.vmaddr);
buffer.PutHex64(segment.vmsize);
buffer.PutHex64(segment.fileoff);
buffer.PutHex64(segment.filesize);
}
else
{
buffer.PutHex32(static_cast<uint32_t>(segment.vmaddr));
buffer.PutHex32(static_cast<uint32_t>(segment.vmsize));
buffer.PutHex32(static_cast<uint32_t>(segment.fileoff));
buffer.PutHex32(static_cast<uint32_t>(segment.filesize));
}
buffer.PutHex32(segment.maxprot);
buffer.PutHex32(segment.initprot);
buffer.PutHex32(segment.nsects);
buffer.PutHex32(segment.flags);
}
File core_file;
std::string core_file_path(outfile.GetPath());
error = core_file.Open(core_file_path.c_str(),
File::eOpenOptionWrite |
File::eOpenOptionTruncate |
File::eOpenOptionCanCreate);
if (error.Success())
{
// Read 1 page at a time
uint8_t bytes[0x1000];
// Write the mach header and load commands out to the core file
size_t bytes_written = buffer.GetString().size();
error = core_file.Write(buffer.GetString().data(), bytes_written);
if (error.Success())
{
// Now write the file data for all memory segments in the process
for (const auto &segment : segment_load_commands)
{
if (core_file.SeekFromStart(segment.fileoff) == -1)
{
error.SetErrorStringWithFormat("unable to seek to offset 0x%" PRIx64 " in '%s'", segment.fileoff, core_file_path.c_str());
break;
}
printf ("Saving %" PRId64 " bytes of data for memory region at 0x%" PRIx64 "\n", segment.vmsize, segment.vmaddr);
addr_t bytes_left = segment.vmsize;
addr_t addr = segment.vmaddr;
Error memory_read_error;
while (bytes_left > 0 && error.Success())
{
const size_t bytes_to_read = bytes_left > sizeof(bytes) ? sizeof(bytes) : bytes_left;
const size_t bytes_read = process_sp->ReadMemory(addr, bytes, bytes_to_read, memory_read_error);
if (bytes_read == bytes_to_read)
{
size_t bytes_written = bytes_read;
error = core_file.Write(bytes, bytes_written);
bytes_left -= bytes_read;
addr += bytes_read;
}
else
{
// Some pages within regions are not readable, those
// should be zero filled
memset (bytes, 0, bytes_to_read);
size_t bytes_written = bytes_to_read;
error = core_file.Write(bytes, bytes_written);
bytes_left -= bytes_to_read;
addr += bytes_to_read;
}
}
}
}
}
}
else
{
error.SetErrorString("process doesn't support getting memory region info");
}
}
return true; // This is the right plug to handle saving core files for this process
}
}
return false;
}
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