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loader.cpp
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loader.cpp
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/*
Source for Sk3wlDbg IdaPro plugin
Copyright (c) 2016 Chris Eagle
This program is free software; you can redistribute it and/or modify it
under the terms of the GNU General Public License as published by the Free
Software Foundation; either version 2 of the License, or (at your option)
any later version.
This program is distributed in the hope that it will be useful, but WITHOUT
ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for
more details.
You should have received a copy of the GNU General Public License along with
this program; if not, write to the Free Software Foundation, Inc., 59 Temple
Place, Suite 330, Boston, MA 02111-1307 USA
*/
#include "loader.h"
#include <ida.hpp>
#include <llong.hpp>
#include <nalt.hpp>
#include <segment.hpp>
#include "elf_local.h"
#include "pe_local.h"
#include "teb32.h"
#include "heap.h"
#pragma pack(push, 1)
struct SegmentDescriptor {
union {
struct {
#if __BYTE_ORDER == __LITTLE_ENDIAN
unsigned short limit0;
unsigned short base0;
unsigned char base1;
unsigned char type:4;
unsigned char system:1; /* S flag */
unsigned char dpl:2;
unsigned char present:1; /* P flag */
unsigned char limit1:4;
unsigned char avail:1;
unsigned char is_64_code:1; /* L flag */
unsigned char db:1; /* DB flag */
unsigned char granularity:1; /* G flag */
unsigned char base2;
#else
unsigned char base2;
unsigned char granularity:1; /* G flag */
unsigned char db:1; /* DB flag */
unsigned char is_64_code:1; /* L flag */
unsigned char avail:1;
unsigned char limit1:4;
unsigned char present:1; /* P flag */
unsigned char dpl:2;
unsigned char system:1; /* S flag */
unsigned char type:4;
unsigned char base1;
unsigned short base0;
unsigned short limit0;
#endif
};
uint64_t desc;
};
};
struct InterruptDescriptor32 {
union {
struct {
#if __BYTE_ORDER == __LITTLE_ENDIAN
unsigned short offset0;
unsigned short sel;
unsigned char zero;
unsigned char d:5;
unsigned char dpl:2;
unsigned char present:1; /* P flag */
unsigned short offset1;
#else
unsigned short offset1;
unsigned char present:1; /* P flag */
unsigned char dpl:2;
unsigned char d:5;
unsigned char zero;
unsigned short sel;
unsigned short offset0;
#endif
};
uint64_t desc;
};
};
struct InterruptDescriptor64 {
union {
struct {
#if __BYTE_ORDER == __LITTLE_ENDIAN
unsigned short offset0;
unsigned short sel;
unsigned char ist:3;
unsigned char pad0:5;
unsigned char type:4;
unsigned char pad1:1;
unsigned char dpl:2;
unsigned char present:1; /* P flag */
unsigned short offset1;
uint32_t offset2;
uint32_t pad2;
#else
uint32_t pad1;
uint32_t offset2;
unsigned short offset1;
unsigned char present:1; /* P flag */
unsigned char dpl:2;
unsigned char pad1:1;
unsigned char type:4;
unsigned char pad0:5;
unsigned char ist:3;
unsigned short sel;
unsigned short offset0;
#endif
};
struct {
#if __BYTE_ORDER == __LITTLE_ENDIAN
uint64_t desc0;
uint64_t desc1;
#else
uint64_t desc1;
uint64_t desc0;
#endif
};
};
};
#pragma pack(pop)
#define SEGBASE(d) ((uint32_t)((((d).desc >> 16) & 0xffffff) | (((d).desc >> 32) & 0xff000000)))
#define SEGLIMIT(d) ((d).limit0 | (((unsigned int)(d).limit1) << 16))
#define ISROFFS(d) ((uint32_t)((((d).desc >> 32) & 0xfffff0000) | ((d).offset0)))
#define ISROFFS64(d) ((uint64_t)((((d).desc1 & 0xffffffff) << 32) | (((d).desc0 >> 32) & 0xfffff0000) | ((d).offset0)))
#define ISRSEG(d) ((d).sel)
/* Unicorn perms IDA perms
0 UC_PROT_NONE 0
1 UC_PROT_READ SEGPERM_EXEC
2 UC_PROT_WRITE SEGPERM_WRITE
3 UC_PROT_WRITE | UC_PROT_READ SEGPERM_WRITE | SEGPERM_EXEC
4 UC_PROT_EXEC SEGPERM_READ
5 UC_PROT_EXEC | UC_PROT_READ SEGPERM_READ | SEGPERM_EXEC
6 UC_PROT_EXEC | UC_PROT_WRITE SEGPERM_READ | SEGPERM_WRITE
7 UC_PROT_ALL SEGPERM_READ | SEGPERM_WRITE | SEGPERM_EXEC
*/
uint32_t ida_to_uc_perms_map[] = {
UC_PROT_NONE, UC_PROT_EXEC, UC_PROT_WRITE, UC_PROT_EXEC | UC_PROT_WRITE,
UC_PROT_READ, UC_PROT_EXEC | UC_PROT_READ, UC_PROT_READ | UC_PROT_WRITE, UC_PROT_ALL
};
uint32_t ida_to_uc_perms_map_win[] = {
UC_PROT_NONE, UC_PROT_EXEC, UC_PROT_READ, UC_PROT_EXEC | UC_PROT_READ,
UC_PROT_WRITE, UC_PROT_EXEC | UC_PROT_WRITE, UC_PROT_READ | UC_PROT_WRITE, UC_PROT_ALL
};
uint32_t uc_to_ida_perms_map[] = {
0, SEGPERM_READ, SEGPERM_WRITE, SEGPERM_READ | SEGPERM_WRITE,
SEGPERM_EXEC, SEGPERM_EXEC | SEGPERM_READ, SEGPERM_EXEC | SEGPERM_WRITE, SEGPERM_EXEC | SEGPERM_WRITE | SEGPERM_READ
};
const char *win_xp_env[] = {
"ALLUSERSPROFILE=C:\\Documents and Settings\\All Users",
"APPDATA=C:\\Documents and Settings\\$USER\\Application Data",
"CLIENTNAME=Console",
"CommonProgramFiles=C:\\Program Files\\Common Files",
"COMPUTERNAME=$HOST",
"ComSpec=C:\\WINDOWS\\system32\\cmd.exe",
"FP_NO_HOST_CHECK=NO",
"HOMEDRIVE=C:",
"HOMEPATH=\\Documents and Settings\\$USER",
"LOGONSERVER=\\\\$HOST",
"NUMBER_OF_PROCESSORS=1",
"OS=Windows_NT",
"Path=C:\\WINDOWS\\system32;C:\\WINDOWS;C:\\WINDOWS\\System32\\Wbem",
"PATHEXT=.COM;.EXE;.BAT;.CMD;.VBS;.VBE;.JS;.JSE;.WSF;.WSH",
"PROCESSOR_ARCHITECTURE=x86",
"PROCESSOR_IDENTIFIER=x86 Family 6 Model 23 Stepping 10, GenuineIntel",
"PROCESSOR_LEVEL=6",
"PROCESSOR_REVISION=170a",
"ProgramFiles=C:\\Program Files",
"PROMPT=$P$G",
"SESSIONNAME=Console",
"SystemDrive=C:",
"SystemRoot=C:\\WINDOWS",
"TEMP=C:\\DOCUME~1\\$DOSUSER\\LOCALS~1\\Temp",
"TMP=C:\\DOCUME~1\\$DOSUSER\\LOCALS~1\\Temp",
"USERDOMAIN=$HOST",
"USERNAME=$USER",
"USERPROFILE=C:\\Documents and Settings\\$USER",
"windir=C:\\WINDOWS",
NULL
};
const char *linux_env[] = {
"HOSTNAME=$HOST",
"TERM=vt100",
"SHELL=/bin/bash",
"HISTSIZE=1000",
"USER=$USER",
"MAIL=/var/spool/mail/$USER",
"PATH=/usr/local/sbin:/usr/local/bin:/sbin:/bin:/usr/sbin:/usr/bin",
"PWD=/home/$USER",
"LANG=en_US.UTF-8",
"HISTCONTROL=ignoredups",
"SHLVL=1",
"HOME=/home/$USER",
"LOGNAME=$USER",
"LESSOPEN=|/usr/bin/lesspipe.sh %s",
"G_BROKEN_FILENAMES=1",
"OLDPWD=/tmp",
NULL
};
uint64_t alignsgm(uint64_t addr)
{
return (addr + 0xfff) & ~0xfff;
}
qstring *make_env(const char *env[], const char *userName, const char *hostName, bool windows = true) {
qstring *res = new qstring();
for (int i = 0; env[i]; i++) {
qstring ev(env[i]);
ev.replace("$USER", userName);
ev.replace("$HOST", hostName);
if (windows) {
if (strlen(userName) > 8) {
char buf[10];
::qstrncpy(buf, userName, 6);
::qstrncpy(buf + 6, "~1", 3);
ev.replace("$DOSUSER", buf);
}
else {
ev.replace("$DOSUSER", userName);
}
}
*res += ev;
*res += '\x00';
}
*res += '\x00';
return res;
}
#define BITS_16 0
#define BITS_32 1
#define BITS_64 2
//VERY basic descriptor init function, sets many fields to user space sane defaults
static void init_intr_descriptor(InterruptDescriptor32 *desc, uint32_t offset, uint16_t sel, uint8_t dpl, uint8_t size) {
desc->desc = 0; //clear the descriptor
desc->sel = sel;
desc->offset0 = (uint16_t)offset;
desc->offset1 = offset >> 16;
desc->dpl = dpl;
desc->present = 1;
desc->d = size ? 0xe : 6; //interrupt gate (trap gate would be 0xf : 7)
}
//VERY basic descriptor init function, sets many fields to user space sane defaults
static void init_intr_descriptor(InterruptDescriptor64 *desc, uint64_t offset, uint16_t sel, uint8_t dpl) {
desc->desc0 = 0; //clear the descriptor
desc->desc1 = 0; //clear the descriptor
desc->sel = sel;
desc->offset0 = (uint16_t)offset;
desc->offset1 = (uint16_t)(offset >> 16);
desc->offset2 = (uint32_t)(offset >> 32);
desc->dpl = dpl;
desc->present = 1;
desc->type = 0xe; //interrupt gate, trap gate is 0xf
}
//VERY basic descriptor init function, sets many fields to user space sane defaults
static void init_descriptor(SegmentDescriptor *desc, uint32_t base, uint32_t limit, uint8_t is_code, int bitness = BITS_32) {
desc->desc = 0; //clear the descriptor
desc->base0 = base & 0xffff;
desc->base1 = (base >> 16) & 0xff;
desc->base2 = base >> 24;
if (limit > 0xfffff) {
//need Giant granularity
limit >>= 12;
desc->granularity = 1;
}
desc->limit0 = limit & 0xffff;
desc->limit1 = limit >> 16;
//some sane defaults
desc->dpl = 3;
desc->present = 1;
if (is_code) {
if (bitness == 1) {
desc->db = 1; //32 bit
}
else if (bitness == 2) {
desc->is_64_code = 1; //64 bit
}
}
else {
desc->db = 1; //32 bit
}
desc->type = is_code ? 0xb : 3;
desc->system = 1; //code or data
}
#define DESC_IDX(reg) (reg >> 3)
void build_sane_gdt(sk3wldbg *uc, uint32_t fs_base, uint64_t init_pc, uint64_t user_sp) {
uc_err err;
uc_x86_mmr gdtr = {0, 0, 0, 0};
uint64_t gdt_address = 0x80000000;
//unicorn starts w/ cpl == 0
//initial sp, this will point to iret data to get us to ring 3
uint64_t init_sp = gdt_address + 0xf00;
//initial pc, this will point to an iret to kick us up to ring 3
uint64_t kernel_pc = gdt_address + 0xc00;
int cpl0_cs = 0x10; //ring 0 cs we will iret from
int cpl0_ss = 0x18; //ring 0 ss we will iret from
int user_cs_32 = 0x23; //32-bit ring 3 cs we will iret to
int user_cs_64 = 0x33; //64-bit ring 3 cs
int user_ss = 0x2b; //ring 3 ss we will iret to, need this because we can't set a ring 3 ss directly in unicorn
int r_ds = 0x2b;
int r_es = 0x2b;
int r_fs = 0x53; //32-bit teb
int r_gs = 0x2b; //64-bit teb, need to configure w/ wrmsr in ring 0 before transistion to ring 3
int max_desc = 0x53;
int ndescs = (max_desc >> 3) + 1;
uint32_t gdt_size = sizeof(SegmentDescriptor) * ndescs;
// map GDT
uint8_t *block = (uint8_t*)uc->map_mem_zero(gdt_address, gdt_address + 0x1000, UC_PROT_WRITE | UC_PROT_READ | UC_PROT_EXEC, SDB_MAP_FIXED);
SegmentDescriptor *gdt = (SegmentDescriptor *)block;
//store the iret opcode into memory (initial pc will point here)
block[0xc00] = 0xcf; //iret
//setup stack for iret
*(uint32_t*)(block + 0xf00) = (uint32_t)init_pc; //initial ring 3 eip
*(uint32_t*)(block + 0xf04) = user_cs_32; //rpl 3 cs
*(uint32_t*)(block + 0xf08) = (0 << 12) | 0x202; //iitial eflags, w/ IOPL 0
*(uint32_t*)(block + 0xf0c) = (uint32_t)user_sp; //initial ring 3 esp
*(uint32_t*)(block + 0xf10) = user_ss; //rpl 3 ss
err = uc_reg_write(uc->uc, UC_X86_REG_ESP, &init_sp);
err = uc_reg_write(uc->uc, UC_X86_REG_EIP, &kernel_pc);
gdtr.base = gdt_address;
gdtr.limit = gdt_size - 1;
//setup dpl 0 descriptor for initial rpl 0 cs
init_descriptor(&gdt[DESC_IDX(cpl0_cs)], 0, 0xfffff000, 1); //code segment
gdt[DESC_IDX(cpl0_cs)].dpl = 0; //set descriptor privilege level
//setup dpl 3 descriptor for eventual rpl 3 cs
init_descriptor(&gdt[DESC_IDX(user_cs_32)], 0, 0xfffff000, 1); //code segment
//setup dpl 3 descriptor for 64-bit
init_descriptor(&gdt[DESC_IDX(user_cs_64)], 0, 0xfffff000, 1, BITS_64); //code segment
init_descriptor(&gdt[DESC_IDX(r_fs)], fs_base, 0xfff, 0); //one page data segment simulate fs
// when setting SS, need rpl == cpl && dpl == cpl
// unicorn starts with cpl == 0, so we need a dpl 0 descriptor and rpl 0 selector
// We get to ring 3 using an iret
init_descriptor(&gdt[DESC_IDX(cpl0_ss)], 0, 0xfffff000, 0); //ring 0 data
gdt[DESC_IDX(cpl0_ss)].dpl = 0; //set descriptor privilege level
//setup dpl 3 descriptor for eventual rpl 3 ss (also ds, es, gs)
init_descriptor(&gdt[DESC_IDX(user_ss)], 0, 0xfffff000, 0); //data segment
//set up a GDT BEFORE you manipulate any segment registers
err = uc_reg_write(uc->uc, UC_X86_REG_GDTR, &gdtr);
// when setting SS, need rpl == cpl && dpl == cpl
// unicorn starts with cpl == 0, so we need a dpl 0 descriptor and rpl 0 selector
// this precludes us from initially using a rpl 3 seg_reg such as 0x2b for ss
err = uc_reg_write(uc->uc, UC_X86_REG_SS, &cpl0_ss);
err = uc_reg_write(uc->uc, UC_X86_REG_CS, &cpl0_cs);
//for these we must pass: if (dpl < cpl || dpl < rpl) {
/*
if (dpl < cpl || dpl < rpl) {
raise_exception_err(env, EXCP0D_GPF, selector & 0xfffc);
}
*/
//we're fine with dpl == rpl
err = uc_reg_write(uc->uc, UC_X86_REG_DS, &r_ds);
err = uc_reg_write(uc->uc, UC_X86_REG_ES, &r_es);
err = uc_reg_write(uc->uc, UC_X86_REG_FS, &r_fs);
err = uc_reg_write(uc->uc, UC_X86_REG_GS, &r_gs);
}
//var must have been allocated using qalloc
ea_t load_pe_sections(sk3wldbg *uc, void *img, ea_t base, size_t hdr_sz, IMAGE_SECTION_HEADER_ *sections, uint32_t nsect) {
//load the PE headers
void *buf = uc->map_mem_zero(base, base + hdr_sz, UC_PROT_READ | UC_PROT_WRITE, SDB_MAP_FIXED);
ea_t max = ((base + hdr_sz) + 0xfff) & ~0xfff;
msg("Copying bytes 0x%x:0x%x into block\n", 0, hdr_sz);
memcpy(buf, img, hdr_sz);
//Now load the sections
for (uint32_t s = 0; s < nsect; s++) {
ea_t vaddr = base + sections[s].VirtualAddress;
uint32_t perms = sections[s].Characteristics >> 29;
uint32_t file_off = sections[s].PointerToRawData;
uint32_t filesz = sections[s].SizeOfRawData;
void *block = uc->map_mem_zero(vaddr, vaddr + sections[s].VirtualSize, ida_to_uc_perms_map_win[perms], SDB_MAP_FIXED);
if (filesz) {
msg("Copying bytes 0x%x:0x%x into block\n", file_off, file_off + filesz);
memcpy(block, file_off + (char*)img, filesz);
// uc_err err = uc_mem_write(uc->uc, vaddr, file_off + (char*)img, filesz);
}
max = ((vaddr + sections[s].VirtualSize) + 0xfff) & ~0xfff;
}
return max;
}
bool loadPE64(sk3wldbg *uc, void *img, size_t /*sz*/, const char * /*args*/, uint64_t init_pc) {
IMAGE_DOS_HEADER_ *dos = (IMAGE_DOS_HEADER_*)img;
if (dos->e_magic != DOS_MAGIC) {
msg("bad MZ magic\n");
return false;
}
IMAGE_NT_HEADERS64_ *pe = (IMAGE_NT_HEADERS64_*)(dos->e_lfanew + (char*)dos);
if (pe->Signature != PE_MAGIC) {
msg("bad PE signature\n");
return false;
}
if (init_pc == BADADDR) {
init_pc = pe->OptionalHeader.AddressOfEntryPoint + pe->OptionalHeader.ImageBase;
}
uc->init_memmgr(0x130000 - 0x100000, 0x800000000000ll);
IMAGE_SECTION_HEADER_ *sections = (IMAGE_SECTION_HEADER_*)(sizeof(pe->Signature) + sizeof(IMAGE_FILE_HEADER_) +
pe->FileHeader.SizeOfOptionalHeader +(char*)pe);
ea_t image_end = load_pe_sections(uc, img, (ea_t)pe->OptionalHeader.ImageBase, pe->OptionalHeader.SizeOfHeaders,
sections, pe->FileHeader.NumberOfSections);
//PE stack
uint32_t stack_top = 0x130000;
uc->map_mem_zero(stack_top - 0x100000, stack_top, UC_PROT_READ | UC_PROT_WRITE | UC_PROT_EXEC, SDB_MAP_FIXED);
stack_top -= 16;
uc->set_sp(stack_top);
ea_t heap_addr = image_end + 0x1000;
void *heap_mem = uc->map_mem_zero(heap_addr, heap_addr + 0x100000, UC_PROT_READ | UC_PROT_WRITE, SDB_MAP_FIXED);
heap<uint64_t> *_heap = new heap<uint64_t>(heap_mem, heap_addr, 0x100000);
_heap->malloc(30);
return true;
}
TEB_ *create_teb_peb32(sk3wldbg *uc, PEB_ **ppeb) {
uint32_t rnd;
uc->getRandomBytes(&rnd, sizeof(rnd));
rnd %= (0x100000 - 0x3000);
rnd &= ~0xfff;
uint32_t teb = 0x203000 + rnd;
uint32_t peb = teb - 0x3000;
TEB_ *pteb = (TEB_*)uc->map_mem_zero(teb, teb + sizeof(TEB_), UC_PROT_READ | UC_PROT_WRITE, SDB_MAP_FIXED);
*ppeb = (PEB_*)uc->map_mem_zero(peb, peb + sizeof(PEB_), UC_PROT_READ | UC_PROT_WRITE, SDB_MAP_FIXED);
pteb->Self = (TEB_p)teb;
pteb->ProcessEnvironmentBlock = (PEB_p)peb;
return pteb;
}
bool loadPE32(sk3wldbg *uc, void *img, size_t /*sz*/, const char * /*args*/, uint64_t init_pc) {
IMAGE_DOS_HEADER_ *dos = (IMAGE_DOS_HEADER_*)img;
if (dos->e_magic != DOS_MAGIC) {
msg("bad MZ magic\n");
return false;
}
IMAGE_NT_HEADERS32_ *pe = (IMAGE_NT_HEADERS32_*)(dos->e_lfanew + (char*)dos);
if (pe->Signature != PE_MAGIC) {
msg("bad PE signature\n");
return false;
}
if (init_pc == BADADDR) {
init_pc = pe->OptionalHeader.AddressOfEntryPoint + pe->OptionalHeader.ImageBase;
}
uc->init_memmgr(0x130000 - 0x100000, 0x80010000);
PEB_ *peb;
TEB_ *teb = create_teb_peb32(uc, &peb);
ea_t teb_addr = (ea_t)teb->Self;
ea_t peb_addr = (ea_t)teb->ProcessEnvironmentBlock;
// msg("peb addr: 0x%x, peb->ImageBase addr: 0x%x, peb->Mutant addr: 0x%x\n", (uint32_t)peb, (uint32_t)&peb->ImageBaseAddress, (uint32_t)&peb->Mutant);
IMAGE_SECTION_HEADER_ *sections = (IMAGE_SECTION_HEADER_*)(sizeof(pe->Signature) + sizeof(IMAGE_FILE_HEADER_) +
pe->FileHeader.SizeOfOptionalHeader +(char*)pe);
ea_t image_end = load_pe_sections(uc, img, pe->OptionalHeader.ImageBase, pe->OptionalHeader.SizeOfHeaders,
sections, pe->FileHeader.NumberOfSections);
//PE stack
uint32_t stack_top = 0x130000;
uc->map_mem_zero(stack_top - 0x100000, stack_top, UC_PROT_READ | UC_PROT_WRITE | UC_PROT_EXEC, SDB_MAP_FIXED);
stack_top -= 16;
uc->set_sp(stack_top);
teb->StackBase = (voidp)stack_top;
teb->StackLimit = (voidp)(stack_top - 0x100000);
uint32_t heap_addr = (uint32_t)image_end + 0x1000;
void *heap_mem = uc->map_mem_zero(heap_addr, heap_addr + 0x100000, UC_PROT_READ | UC_PROT_WRITE, SDB_MAP_FIXED);
heap<uint32_t> *_heap = new heap<uint32_t>(heap_mem, heap_addr, 0x100000);
peb->ImageBaseAddress = (voidp)pe->OptionalHeader.ImageBase;
peb->ProcessHeap = (voidp)heap_addr;
peb->NumberOfHeaps = 1;
peb->MaximumNumberOfHeaps = 16;
//the following two fields are in ntdll's bss **** TODO build a page in ntdll to hold these
peb->ProcessHeaps = (voidp)heap_addr; //array of MaximumNumberOfHeaps heap pointers
//first entry in this array is ProcessHeap
peb->Ldr = (PEB_LDR_DATA_p)heap_addr; //PEB_LDR_DATA_
uint16_t pid;
uc->getRandomBytes(&pid, sizeof(pid));
pid = (pid % 3000) + 1000;
teb->ClientId.ProcessId = pid;
uint16_t tid;
uc->getRandomBytes(&tid, sizeof(tid));
tid = (tid % 3000) + 1000;
teb->ClientId.ThreadId = tid;
qstring *env = make_env(win_xp_env, "bgates", "apollo");
//copy env into process heap
delete env;
build_sane_gdt(uc, teb_addr, init_pc, stack_top);
return true;
}
//IDA only runs on little-endian platforms
uint16_t get_elf_16(void *pdata, bool big_endian) {
uint16_t *d = (uint16_t*)pdata;
return big_endian ? swap16(*d) : *d;
}
uint32_t get_elf_32(void *pdata, bool big_endian) {
uint32_t *d = (uint32_t*)pdata;
return big_endian ? swap32(*d) : *d;
}
uint64_t get_elf_64(void *pdata, bool big_endian) {
uint64_t *d = (uint64_t*)pdata;
return big_endian ? swap64((ulonglong)*d) : *d;
}
static uint64_t uc_push_8(sk3wldbg *uc, uint64_t sp, uint8_t val) {
sp -= 1;
uc_mem_write(uc->uc, sp, &val, 1);
return sp;
}
static uint64_t uc_push_32(sk3wldbg *uc, uint64_t sp, uint32_t val, bool big_endian) {
sp -= sizeof(val);
if (big_endian) {
val = swap32(val);
}
uc_mem_write(uc->uc, sp, &val, sizeof(val));
return sp;
}
static uint64_t uc_push_64(sk3wldbg *uc, uint64_t sp, uint64_t val, bool big_endian) {
sp -= sizeof(val);
if (big_endian) {
val = swap64((ulonglong)val);
}
uc_mem_write(uc->uc, sp, &val, sizeof(val));
return sp;
}
static uint64_t uc_push(sk3wldbg *uc, uint64_t sp, uint64_t val, bool is_64, bool big_endian) {
if (is_64) {
return uc_push_64(uc, sp, val, big_endian);
}
return uc_push_32(uc, sp, (uint32_t)val, big_endian);
}
static uint64_t uc_push_buf(sk3wldbg *uc, uint64_t sp, void *val, uint32_t sz) {
sp -= sz;
uc_mem_write(uc->uc, sp, val, sz);
return sp;
}
static uint64_t uc_push_str(sk3wldbg *uc, uint64_t sp, const char *val, bool with_null = true) {
size_t sz = strlen(val);
if (with_null) {
sz++;
}
return uc_push_buf(uc, sp, (void*)val, (uint32_t)sz);
}
void build_sane_elf64_gdt(sk3wldbg *uc, uint64_t fs_base, uint64_t init_pc, uint64_t user_sp) {
uc_err err;
uc_x86_mmr gdtr = {0, 0, 0, 0};
uc_x86_mmr idtr = {0, 0, 0, 0};
uint64_t gdt_address = 0xFFFF800000000000;
uint64_t idt_address = gdt_address + 0x400;
//unicorn starts w/ cpl == 0
//initial sp, this will point to iret data to get us to ring 3
uint64_t init_sp = gdt_address + 0xf00;
//initial pc, this will point to an iret to kick us up to ring 3
uint64_t kernel_pc = gdt_address + 0xc00;
uint64_t int3_pc = gdt_address + 0x800;
int cpl0_cs = 0x10; //ring 0 cs we will iret from
int cpl0_ss = 0x18; //ring 0 ss we will iret from
int user_cs_32 = 0x23; //32-bit ring 3 cs we will iret to
int user_cs_64 = 0x33; //64-bit ring 3 cs
int user_ss = 0x2b; //ring 3 ss we will iret to, need this because we can't set a ring 3 ss directly in unicorn
int r_ds = 0;
int r_es = 0;
int r_fs = 0;
int r_gs = 0; //this is 0x63 in 32-bit code used for tls info, need to set w/ wrmsr
int intr_seg = 0x40;
uint64_t ia32_star = cpl0_cs;
ia32_star <<= 32;
int max_desc = 0x53;
int ndescs = (max_desc >> 3) + 1;
uint32_t gdt_size = sizeof(SegmentDescriptor) * ndescs;
// map GDT
uint8_t *block = (uint8_t*)uc->map_mem_zero(gdt_address, gdt_address + 0x1000, UC_PROT_WRITE | UC_PROT_READ | UC_PROT_EXEC, SDB_MAP_FIXED);
qstring sname;
sname.sprnt("debug_%p", gdt_address);
createNewSegment(sname.c_str(), gdt_address, 0x1000, uc_to_ida_perms_map[UC_PROT_WRITE | UC_PROT_READ | UC_PROT_EXEC], 2);
//a small kernel space stack
uint8_t *kstack = (uint8_t*)uc->map_mem_zero(gdt_address + 0x1000, gdt_address + 0x2000, UC_PROT_WRITE | UC_PROT_READ, SDB_MAP_FIXED);
sname.sprnt("debug_%p", gdt_address + 0x1000);
createNewSegment(sname.c_str(), gdt_address + 0x1000, 0x1000, uc_to_ida_perms_map[UC_PROT_WRITE | UC_PROT_READ], 2);
SegmentDescriptor *gdt = (SegmentDescriptor *)block;
InterruptDescriptor64 *idt = (InterruptDescriptor64 *)(block + 0x400);
//some ring 0 code to both kick us up to ring 3 after unicorn launch and handle
//any syscall instructions encountered in ring 3.
char kern[] =
"\x48\xb8\x41\x41\x41\x41\x41\x41\x41\x41\xe8\x26\x00\x00\x00\x48"
"\x8d\x05\x80\x00\x00\x00\xe8\x70\x00\x00\x00\x48\xb8\x00\x00\x00"
"\x00\x10\x00\x23\x00\xe8\x56\x00\x00\x00\x48\x31\xc0\x48\x31\xd2"
"\x48\x31\xc9\x48\xcf\xb9\x00\x01\x00\xc0\xe8\x34\x00\x00\x00\xc3"
"\xb9\x00\x01\x00\xc0\xe8\x33\x00\x00\x00\x48\xc1\xe0\x20\x48\x0f"
"\xac\xd0\x20\xc3\xb9\x01\x01\x00\xc0\xe8\x15\x00\x00\x00\xc3\xb9"
"\x01\x01\x00\xc0\xe8\x14\x00\x00\x00\x48\xc1\xe0\x20\x48\x0f\xac"
"\xd0\x20\xc3\x48\x89\xc2\x48\xc1\xea\x20\x0f\x30\xc3\x0f\x32\xc3"
"\xb9\x81\x00\x00\xc0\xe8\xe9\xff\xff\xff\xc3\xb9\x82\x00\x00\xc0"
"\xe8\xde\xff\xff\xff\xc3\x48\x89\x25\x5b\x13\x00\x00\x48\x8d\x25"
"\x54\x13\x00\x00\x51\x41\x53\x57\x56\x52\x41\x52\x41\x50\x41\x51"
"\x3d\x9e\x00\x00\x00\x75\x57\x81\xff\x02\x10\x00\x00\x75\x0a\x48"
"\x89\xf0\xe8\x6e\xff\xff\xff\xeb\x40\x81\xff\x03\x10\x00\x00\x75"
"\x0a\xe8\x6a\xff\xff\xff\x48\x89\x06\xeb\x2e\x81\xff\x01\x10\x00"
"\x00\x75\x0a\x48\x89\xf0\xe8\x69\xff\xff\xff\xeb\x1c\x81\xff\x04"
"\x10\x00\x00\x75\x0a\xe8\x65\xff\xff\xff\x48\x89\x06\xeb\x0a\xb8"
"\x16\x00\x00\x00\x48\xf7\xd8\xeb\x06\x48\x31\xc0\xeb\x01\x90\x41"
"\x59\x41\x58\x41\x5a\x5a\x5e\x5f\x41\x5b\x59\x5c\x48\x0f\x07\x90";
*(uint64_t*)(kern + 2) = 0x00007FFFFFEFC880; //fs_base;
memcpy(block + 0xc00, kern, sizeof(kern)); //setup fs msr and iret
//setup stack for iret
*(uint64_t*)(block + 0xf00) = init_pc; //initial ring 3 eip
*(uint64_t*)(block + 0xf08) = user_cs_64; //rpl 3 cs
*(uint64_t*)(block + 0xf10) = (0 << 12) | 0x202; //iitial eflags, w/ IOPL 0
*(uint64_t*)(block + 0xf18) = user_sp; //initial ring 3 esp
*(uint64_t*)(block + 0xf20) = user_ss; //rpl 3 ss
err = uc_reg_write(uc->uc, UC_X86_REG_RSP, &init_sp);
err = uc_reg_write(uc->uc, UC_X86_REG_RIP, &kernel_pc);
gdtr.base = gdt_address;
gdtr.limit = gdt_size - 1;
//setup dpl 0 descriptor for initial rpl 0 cs
init_descriptor(&gdt[DESC_IDX(cpl0_cs)], 0, 0xfffff000, 1); //code segment
gdt[DESC_IDX(cpl0_cs)].dpl = 0; //set descriptor privilege level
//setup dpl 3 descriptor for eventual rpl 3 cs
init_descriptor(&gdt[DESC_IDX(user_cs_32)], 0, 0xfffff000, 1); //code segment
//setup dpl 3 descriptor for 64-bit
init_descriptor(&gdt[DESC_IDX(user_cs_64)], 0, 0xfffff000, 1, BITS_64); //code segment
// when setting SS, need rpl == cpl && dpl == cpl
// unicorn starts with cpl == 0, so we need a dpl 0 descriptor and rpl 0 selector
// We get to ring 3 using an iret
init_descriptor(&gdt[DESC_IDX(cpl0_ss)], 0, 0xfffff000, 0); //ring 0 data
gdt[DESC_IDX(cpl0_ss)].dpl = 0; //set descriptor privilege level
//setup dpl 3 descriptor for eventual rpl 3 ss (also ds, es, gs)
init_descriptor(&gdt[DESC_IDX(user_ss)], 0, 0xfffff000, 0); //data segment
//set up a GDT BEFORE you manipulate any segment registers
err = uc_reg_write(uc->uc, UC_X86_REG_GDTR, &gdtr);
//beginnings of an IDT. TODO: finish this up. Need to setup tss for this to work
int num_intr = 16;
uint32_t idt_size = sizeof(InterruptDescriptor64) * num_intr;
idtr.base = idt_address;
idtr.limit = idt_size - 1;
init_intr_descriptor(&idt[3], int3_pc, cpl0_cs, 0);
// err = uc_reg_write(uc->uc, UC_X86_REG_IDTR, &idtr); //TODO: not ready for this yet
// when setting SS, need rpl == cpl && dpl == cpl
// unicorn starts with cpl == 0, so we need a dpl 0 descriptor and rpl 0 selector
// this precludes us from initially using a rpl 3 seg_reg such as 0x2b for ss
err = uc_reg_write(uc->uc, UC_X86_REG_SS, &cpl0_ss);
err = uc_reg_write(uc->uc, UC_X86_REG_CS, &cpl0_cs);
//for these we must pass: if (dpl < cpl || dpl < rpl) {
/*
if (dpl < cpl || dpl < rpl) {
raise_exception_err(env, EXCP0D_GPF, selector & 0xfffc);
}
*/
//we're fine with dpl == rpl
err = uc_reg_write(uc->uc, UC_X86_REG_DS, &r_ds);
err = uc_reg_write(uc->uc, UC_X86_REG_ES, &r_es);
err = uc_reg_write(uc->uc, UC_X86_REG_FS, &r_fs);
err = uc_reg_write(uc->uc, UC_X86_REG_GS, &r_gs);
}
static uint64_t create_elf_env(sk3wldbg *uc, uint64_t sp, elf_aux *av, const char *args, bool is_64, bool big_endian) {
char bin[256];
qvector<uint64_t> env;
qvector<uint64_t> argv;
qvector<qstring> arguments;
ssize_t bin_len = get_root_filename(bin, sizeof(bin));
sp = uc_push(uc, sp, 0, is_64, big_endian);
sp = uc_push_str(uc, sp, bin);
sp = uc_push_str(uc, sp, "_=./", false);
uint64_t at_execfn = sp + 2;
env.push_back(sp);
sp = uc_push_str(uc, sp, "HOME=/home/user");
env.push_back(sp);
sp = uc_push_str(uc, sp, "PWD=/home/user");
env.push_back(sp);
sp = uc_push_str(uc, sp, "PATH=/usr/local/sbin:/usr/local/bin:/usr/sbin:/usr/bin:/sbin:/bin");
env.push_back(sp);
sp = uc_push_str(uc, sp, "SHELL=/bin/bash");
env.push_back(sp);
qstring argv_0 = "./";
argv_0 += bin;
arguments.push_back(argv_0);
const char *p1 = args;
while (true) {
while (isspace(*p1)) p1++;
qstring arg;
if (*p1) {
char quote = 0;
if (*p1 == '"' || *p1 == '\'') {
quote = *p1++;
}
while (*p1) {
if (*p1 == '\\') {
//need better escape handling, only handling escaped quotes for now
p1++;
if (*p1 == 0) {
p1--;
}
}
else if (quote) {
if (*p1 == quote) {
p1++;
break;
}
}
else if (isspace(*p1)) {
break;
}
arg += *p1++;
}
if (arg.length() > 0) {
arguments.push_back(arg);
}
}
else {
break;
}
}
while (arguments.size() > 0) {
qstring &a = arguments.back();
sp = uc_push_str(uc, sp, a.c_str());
argv.push_back(sp);
arguments.pop_back();
}
sp &= is_64 ? ~7 : ~3; //align sp to 4 or 8 bytes
sp = uc_push_str(uc, sp, "x86_64");
uint64_t at_platform = sp;
uint8_t at_random_buf[16];
uc->getRandomBytes(at_random_buf, sizeof(at_random_buf));
sp = uc_push_buf(uc, sp, at_random_buf, sizeof(at_random_buf));
uint64_t at_random = sp;
sp &= is_64 ? ~7 : ~3; //align sp to 4 or 8 bytes
//need to build an AUX vector here
qvector<uint64_t> aux;
aux.push_back(_AT_SYSINFO_EHDR);
aux.push_back(av->vdso);
aux.push_back(_AT_HWCAP);
aux.push_back(0xfabfbff);
aux.push_back(_AT_PAGESZ);
aux.push_back(0x1000);
aux.push_back(_AT_CLKTCK);
aux.push_back(0x64);
aux.push_back(_AT_PHDR);
aux.push_back(av->phdr);
aux.push_back(_AT_PHENT);
aux.push_back(av->phent);
aux.push_back(_AT_PHNUM);
aux.push_back(av->phnum);
aux.push_back(_AT_BASE); //base address of ELF interpreter (ld-linux)
aux.push_back(0);
aux.push_back(_AT_FLAGS);
aux.push_back(0);
aux.push_back(_AT_ENTRY);
aux.push_back(av->entry);
aux.push_back(_AT_UID);
aux.push_back(av->uid);
aux.push_back(_AT_EUID);
aux.push_back(av->euid);
aux.push_back(_AT_GID);
aux.push_back(av->gid);
aux.push_back(_AT_EGID);
aux.push_back(av->egid);
aux.push_back(_AT_SECURE);
aux.push_back(0);
aux.push_back(_AT_RANDOM);
aux.push_back(at_random);
aux.push_back(_AT_EXECFN);
aux.push_back(at_execfn);
aux.push_back(_AT_PLATFORM);
aux.push_back(at_platform);
aux.push_back(_AT_NULL); //AT_NULL entry
aux.push_back(0); //AT_NULL value
for (int i = aux.size(); i > 0; i--) {
sp = uc_push(uc, sp, aux[i - 1], is_64, big_endian);
}
//null terminate envp array
sp = uc_push(uc, sp, 0, is_64, big_endian);
//push envp pointers
for (qvector<uint64_t>::iterator i = env.begin(); i != env.end(); i++) {
sp = uc_push(uc, sp, *i, is_64, big_endian);
}
//null terminate argv array
sp = uc_push(uc, sp, 0, is_64, big_endian);
//remember argc
uint32_t argc = (uint32_t)argv.size();
//push argv pointers
for (qvector<uint64_t>::iterator i = argv.begin(); i != argv.end(); i++) {
sp = uc_push(uc, sp, *i, is_64, big_endian);
}
//push argc
sp = uc_push(uc, sp, argc, is_64, big_endian);
return sp;
}
uint64_t get_maprange(std::vector <std::pair<uint64_t, uint64_t>>& sgms, uint64_t vaddr, uint64_t &vend_addr)
{
for (uint16_t i = 0; i < sgms.size(); i++)
{
if (vaddr >= sgms[i].first && vend_addr <= sgms[i].second)
{
vend_addr = sgms[i].second;
return sgms[i].first;
}
}
return 0;
}
bool loadElf64(sk3wldbg *uc, void *img, uint64_t sz, const char *args, uint64_t init_pc) {
Elf64_Ehdr *elf = (Elf64_Ehdr*)img;
uint32_t exec_stack = UC_PROT_EXEC;
bool big_endian = false;
if (memcmp(elf->e_ident, "\x7f" "ELF", 4) != 0) {
msg("bad ELF magic: 0x%x\n", *(uint32_t*)elf->e_ident);
return false;
}
if (elf->e_ident[EI_DATA] == 2) {
big_endian = true;
}
uint64_t e_phoff = get_elf_64(&elf->e_phoff, big_endian);
if (e_phoff > (sz - sizeof(Elf64_Phdr))) {
msg("bad e_phoff\n");
return false;
}
if (init_pc == BADADDR) {
init_pc = elf->e_entry;
}
Elf64_Phdr *phdr = (Elf64_Phdr*)(e_phoff + (char*)img);
Elf64_Phdr *h = phdr;
uint16_t e_phnum = get_elf_16(&elf->e_phnum, big_endian);
//check for execstack so we can map the stack first
//also find base address of binary
uint64_t elf_base = 0xffffffffffffffffll;
std::vector <std::pair<uint64_t, uint64_t>> load_info;
for (uint16_t i = 0; i < e_phnum; i++, h++) {
uint32_t p_type = get_elf_32(&h->p_type, big_endian);
uint32_t p_flags = get_elf_32(&h->p_flags, big_endian);
if (p_type == PT_GNU_STACK) {
if ((p_flags & PF_X) == 0) {
//stack marked NX
exec_stack = 0;
}
}
else if (p_type == PT_LOAD) {
uint64_t p_vaddr_o = get_elf_64(&phdr->p_vaddr, big_endian);
uint64_t p_vaddr = ALIGN_PAGE_DOWN(p_vaddr_o);
uint64_t p_vsize = alignsgm(get_elf_64(&phdr->p_memsz, big_endian));
int last_idx = load_info.size() - 1;
if (last_idx >= 0 && (load_info[last_idx].first + load_info[last_idx].second >= p_vaddr))
load_info[last_idx].second += p_vsize + ALIGN_PAGE_UP(p_vaddr_o) - p_vaddr;
else
load_info.push_back(std::make_pair(p_vaddr, p_vsize));
if (p_vaddr < elf_base) {
elf_base = p_vaddr;
}
}
phdr++;
}
//ELF stack
uint64_t stack_max = 0x7ffffffff000ll;
uint64_t stack_min = 0x7ffffffff000ll - 0x100000;
uint64_t fs_base = stack_min - 0x3000;
uint64_t vdso_base = stack_min - 0x4000;
uc->init_memmgr(0, 0xffff800000002000); //allow mapping zero page
uc->map_mem_zero(stack_min, stack_max, UC_PROT_READ | UC_PROT_WRITE | exec_stack);