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|
#define _GNU_SOURCE
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <elf.h>
#include <sys/mman.h>
#include <sys/stat.h>
#include <sys/sysmacros.h>
#include <sys/types.h>
#include <link.h>
#include <unistd.h>
#include <errno.h>
#include "box64version.h"
#include "elfloader.h"
#include "debug.h"
#include "elfload_dump.h"
#include "elfloader_private.h"
#include "librarian.h"
#include "x64run.h"
#include "bridge.h"
#include "wrapper.h"
#include "box64context.h"
#include "library.h"
#include "x64emu.h"
#include "box64stack.h"
#include "callback.h"
#include "box64stack.h"
#include "custommem.h"
#include "wine_tools.h"
#include "dictionnary.h"
#include "symbols.h"
#ifdef DYNAREC
#include "dynablock.h"
#endif
#include "../emu/x64emu_private.h"
#include "x64tls.h"
void* my__IO_2_1_stderr_ = NULL;
void* my__IO_2_1_stdin_ = NULL;
void* my__IO_2_1_stdout_ = NULL;
// return the index of header (-1 if it doesn't exist)
int getElfIndex(box64context_t* ctx, elfheader_t* head) {
for (int i=0; i<ctx->elfsize; ++i)
if(ctx->elfs[i]==head)
return i;
return -1;
}
elfheader_t* LoadAndCheckElfHeader(FILE* f, const char* name, int exec)
{
elfheader_t *h = ParseElfHeader(f, name, exec);
if(!h)
return NULL;
if ((h->path = realpath(name, NULL)) == NULL) {
h->path = (char*)malloc(1);
h->path[0] = '\0';
}
return h;
}
void FreeElfHeader(elfheader_t** head)
{
if(!head || !*head)
return;
elfheader_t *h = *head;
#ifdef DYNAREC
/*if(h->text) {
dynarec_log(LOG_INFO, "Free Dynarec block for %s\n", h->path);
cleanDBFromAddressRange(my_context, h->text, h->textsz, 1);
}*/ // will be free at the end, no need to free it now
#endif
free(h->name);
free(h->path);
free(h->PHEntries);
free(h->SHEntries);
free(h->SHStrTab);
free(h->StrTab);
free(h->Dynamic);
free(h->DynStr);
free(h->SymTab);
free(h->DynSym);
FreeElfMemory(h);
free(h);
*head = NULL;
}
int CalcLoadAddr(elfheader_t* head)
{
head->memsz = 0;
head->paddr = head->vaddr = ~(uintptr_t)0;
head->align = 1;
for (size_t i=0; i<head->numPHEntries; ++i)
if(head->PHEntries[i].p_type == PT_LOAD) {
if(head->paddr > (uintptr_t)head->PHEntries[i].p_paddr)
head->paddr = (uintptr_t)head->PHEntries[i].p_paddr;
if(head->vaddr > (uintptr_t)head->PHEntries[i].p_vaddr)
head->vaddr = (uintptr_t)head->PHEntries[i].p_vaddr;
}
if(head->vaddr==~(uintptr_t)0 || head->paddr==~(uintptr_t)0) {
printf_log(LOG_NONE, "Error: v/p Addr for Elf Load not set\n");
return 1;
}
head->stacksz = 1024*1024; //1M stack size default?
head->stackalign = 16; // default align for stack
for (size_t i=0; i<head->numPHEntries; ++i) {
if(head->PHEntries[i].p_type == PT_LOAD) {
uintptr_t phend = head->PHEntries[i].p_vaddr - head->vaddr + head->PHEntries[i].p_memsz;
if(phend > head->memsz)
head->memsz = phend;
if(head->PHEntries[i].p_align > head->align)
head->align = head->PHEntries[i].p_align;
}
if(head->PHEntries[i].p_type == PT_GNU_STACK) {
if(head->stacksz < head->PHEntries[i].p_memsz)
head->stacksz = head->PHEntries[i].p_memsz;
if(head->stackalign < head->PHEntries[i].p_align)
head->stackalign = head->PHEntries[i].p_align;
}
if(head->PHEntries[i].p_type == PT_TLS) {
head->tlsaddr = head->PHEntries[i].p_vaddr;
head->tlssize = head->PHEntries[i].p_memsz;
head->tlsfilesize = head->PHEntries[i].p_filesz;
head->tlsalign = head->PHEntries[i].p_align;
// force alignement...
if(head->tlsalign>1)
while(head->tlssize&(head->tlsalign-1))
head->tlssize++;
}
}
printf_log(LOG_DEBUG, "Elf Addr(v/p)=%p/%p Memsize=0x%lx (align=0x%zx)\n", (void*)head->vaddr, (void*)head->paddr, head->memsz, head->align);
printf_log(LOG_DEBUG, "Elf Stack Memsize=%lu (align=%zu)\n", head->stacksz, head->stackalign);
printf_log(LOG_DEBUG, "Elf TLS Memsize=%lu (align=%zu)\n", head->tlssize, head->tlsalign);
return 0;
}
const char* ElfName(elfheader_t* head)
{
if(!head)
return "(noelf)";
return head->name;
}
int AllocElfMemory(box64context_t* context, elfheader_t* head, int mainbin)
{
uintptr_t offs = 0;
if(mainbin && head->vaddr==0) {
char* load_addr = getenv("BOX64_LOAD_ADDR");
if(load_addr)
if(sscanf(load_addr, "0x%lx", &offs)!=1)
offs = 0;
}
if(!offs)
offs = head->vaddr;
if(head->vaddr) {
head->multiblock_n = 0; // count PHEntrie with LOAD
for (size_t i=0; i<head->numPHEntries; ++i)
if(head->PHEntries[i].p_type == PT_LOAD && head->PHEntries[i].p_flags)
++head->multiblock_n;
head->multiblock_size = (uint64_t*)calloc(head->multiblock_n, sizeof(uint64_t));
head->multiblock_offs = (uintptr_t*)calloc(head->multiblock_n, sizeof(uintptr_t));
head->multiblock = (void**)calloc(head->multiblock_n, sizeof(void*));
// and now, create all individual blocks
head->memory = (char*)0xffffffffffffffff;
int n = 0;
for (size_t i=0; i<head->numPHEntries; ++i)
if(head->PHEntries[i].p_type == PT_LOAD && head->PHEntries[i].p_flags) {
Elf64_Phdr * e = &head->PHEntries[i];
uintptr_t bstart = e->p_vaddr;
uint64_t bsize = e->p_memsz;
uintptr_t balign = e->p_align;
if (balign) balign = balign-1; else balign = 1;
if(balign<4095) balign = 4095;
uintptr_t bend = (bstart + bsize + balign)&(~balign);
bstart &= ~balign;
int ok = 0;
for (int j=0; !ok && j<n; ++j) {
uintptr_t start = head->multiblock_offs[j];
uintptr_t end = head->multiblock_offs[j] + head->multiblock_size[j];
start &= ~balign;
if( (head->e_type == ET_DYN) ||
(((bstart>=start) && (bstart<=end)) || ((bend>=start) && (bend<=end)) || ((bstart<start) && (bend>end))))
{
// merge
ok = 1;
if(bstart<start)
head->multiblock_offs[j] = bstart;
head->multiblock_size[j] = ((bend>end)?bend:end) - head->multiblock_offs[j];
--head->multiblock_n;
}
}
if(!ok) {
head->multiblock_offs[n] = bstart;
head->multiblock_size[n] = bend - head->multiblock_offs[n];
++n;
}
}
head->multiblock_n = n; // might be less in fact
for (int i=0; i<head->multiblock_n; ++i) {
printf_log(LOG_DEBUG, "Allocating 0x%lx memory @%p for Elf \"%s\"\n", head->multiblock_size[i], (void*)head->multiblock_offs[i], head->name);
void* p = mmap((void*)head->multiblock_offs[i], head->multiblock_size[i]
, PROT_READ | PROT_WRITE | PROT_EXEC
, MAP_PRIVATE | MAP_ANONYMOUS /*| ((wine_preloaded)?MAP_FIXED:0)*/
, -1, 0);
if(p==MAP_FAILED) {
printf_log(LOG_NONE, "Cannot create memory map (@%p 0x%lx/0x%zx) for elf \"%s\"\n", (void*)head->multiblock_offs[i], head->multiblock_size[i], head->align, head->name);
return 1;
}
if(head->multiblock_offs[i] &&( p!=(void*)head->multiblock_offs[i])) {
if((head->e_type!=ET_DYN)) {
printf_log(LOG_NONE, "Error, memory map (@%p 0x%lx/0x%zx) for elf \"%s\" allocated @%p\n", (void*)head->multiblock_offs[i], head->multiblock_size[i], head->align, head->name, p);
return 1;
} else {
printf_log(LOG_INFO, "Allocated memory is not at hinted %p but %p (size %lx) \"%s\"\n", (void*)head->multiblock_offs[i], p, head->multiblock_size[i], head->name);
// need to adjust vaddr!
for (size_t j=0; j<head->numPHEntries; ++j)
if(head->PHEntries[j].p_type == PT_LOAD) {
Elf64_Phdr * e = &head->PHEntries[j];
if(e->p_vaddr>=head->multiblock_offs[j] && e->p_vaddr<(head->multiblock_offs[j]+head->multiblock_size[j])) {
e->p_vaddr = e->p_vaddr - head->multiblock_offs[j] + (uintptr_t)p;
if(!head->delta) head->delta = (intptr_t)p - (intptr_t)head->multiblock_offs[j];
}
}
}
}
setProtection((uintptr_t)p, head->multiblock_size[i], PROT_READ | PROT_WRITE | PROT_EXEC);
head->multiblock[i] = p;
if(p<(void*)head->memory)
head->memory = (char*)p;
}
} else {
// vaddr is 0, load everything has a One block
if(!offs && box64_wine)
offs = (uintptr_t)find47bitBlock(head->memsz); // limit to 47bits...
printf_log(LOG_DEBUG, "Allocating 0x%lx memory @%p for Elf \"%s\"\n", head->memsz, (void*)offs, head->name);
void* p = mmap((void*)offs, head->memsz
, PROT_READ | PROT_WRITE | PROT_EXEC
, MAP_PRIVATE | MAP_ANONYMOUS /*| (((offs&&wine_preloaded)?MAP_FIXED:0))*/
, -1, 0);
if(p==MAP_FAILED) {
printf_log(LOG_NONE, "Cannot create memory map (@%p 0x%lx/0x%zx) for elf \"%s\"\n", (void*)offs, head->memsz, head->align, head->name);
return 1;
}
if(offs && (p!=(void*)offs) && (head->e_type!=ET_DYN)) {
printf_log(LOG_NONE, "Error, memory map (@%p 0x%lx/0x%zx) for elf \"%s\" allocated @%p\n", (void*)offs, head->memsz, head->align, head->name, p);
return 1;
}
setProtection((uintptr_t)p, head->memsz, PROT_READ | PROT_WRITE | PROT_EXEC);
head->memory = p;
memset(p, 0, head->memsz);
head->delta = (intptr_t)p - (intptr_t)head->vaddr;
printf_log(LOG_DEBUG, "Got %p (delta=%p)\n", p, (void*)head->delta);
head->multiblock_n = 1;
head->multiblock_size = (uint64_t*)calloc(head->multiblock_n, sizeof(uint64_t));
head->multiblock_offs = (uintptr_t*)calloc(head->multiblock_n, sizeof(uintptr_t));
head->multiblock = (void**)calloc(head->multiblock_n, sizeof(void*));
head->multiblock_size[0] = head->memsz;
head->multiblock_offs[0] = (uintptr_t)p;
head->multiblock[0] = p;
}
head->tlsbase = AddTLSPartition(context, head->tlssize);
return 0;
}
void FreeElfMemory(elfheader_t* head)
{
if(head->multiblock_n) {
for(int i=0; i<head->multiblock_n; ++i)
munmap(head->multiblock[i], head->multiblock_size[i]);
free(head->multiblock);
free(head->multiblock_size);
free(head->multiblock_offs);
}
}
int LoadElfMemory(FILE* f, box64context_t* context, elfheader_t* head)
{
for (size_t i=0; i<head->numPHEntries; ++i) {
if(head->PHEntries[i].p_type == PT_LOAD) {
Elf64_Phdr * e = &head->PHEntries[i];
char* dest = (char*)e->p_paddr + head->delta;
printf_log(LOG_DEBUG, "Loading block #%zu @%p (0x%lx/0x%lx)\n", i, dest, e->p_filesz, e->p_memsz);
fseeko64(f, e->p_offset, SEEK_SET);
if(e->p_filesz) {
if(fread(dest, e->p_filesz, 1, f)!=1) {
printf_log(LOG_NONE, "Fail to read PT_LOAD part #%zu (size=%ld)\n", i, e->p_filesz);
return 1;
}
}
#ifdef DYNAREC
if(box64_dynarec && (e->p_flags & PF_X)) {
dynarec_log(LOG_DEBUG, "Add ELF eXecutable Memory %p:%p\n", dest, (void*)e->p_memsz);
addDBFromAddressRange((uintptr_t)dest, e->p_memsz);
}
#endif
// zero'd difference between filesz and memsz
/*if(e->p_filesz != e->p_memsz)
memset(dest+e->p_filesz, 0, e->p_memsz - e->p_filesz);*/ //block is already 0'd at creation
}
if(head->PHEntries[i].p_type == PT_TLS) {
Elf64_Phdr * e = &head->PHEntries[i];
char* dest = (char*)(context->tlsdata+context->tlssize+head->tlsbase);
printf_log(LOG_DEBUG, "Loading TLS block #%zu @%p (0x%lx/0x%lx)\n", i, dest, e->p_filesz, e->p_memsz);
if(e->p_filesz) {
fseeko64(f, e->p_offset, SEEK_SET);
if(fread(dest, e->p_filesz, 1, f)!=1) {
printf_log(LOG_NONE, "Fail to read PT_TLS part #%zu (size=%ld)\n", i, e->p_filesz);
return 1;
}
}
// zero'd difference between filesz and memsz
if(e->p_filesz != e->p_memsz)
memset(dest+e->p_filesz, 0, e->p_memsz - e->p_filesz);
}
}
return 0;
}
int ReloadElfMemory(FILE* f, box64context_t* context, elfheader_t* head)
{
(void)context;
for (size_t i=0; i<head->numPHEntries; ++i) {
if(head->PHEntries[i].p_type == PT_LOAD) {
Elf64_Phdr * e = &head->PHEntries[i];
char* dest = (char*)e->p_paddr + head->delta;
printf_log(LOG_DEBUG, "Re-loading block #%zu @%p (0x%lx/0x%lx)\n", i, dest, e->p_filesz, e->p_memsz);
int ret = fseeko64(f, e->p_offset, SEEK_SET);
if(ret==-1) {printf_log(LOG_NONE, "Fail to (re)seek PT_LOAD part #%zu (offset=%ld, errno=%d/%s)\n", i, e->p_offset, errno, strerror(errno)); return 1;}
#ifdef DYNAREC
cleanDBFromAddressRange((uintptr_t)dest, e->p_memsz, 0);
#endif
mprotect(dest, e->p_memsz, PROT_READ | PROT_WRITE | PROT_EXEC);
setProtection((uintptr_t)dest, e->p_memsz, PROT_READ | PROT_WRITE | PROT_EXEC);
if(e->p_filesz) {
ssize_t r = -1;
if((r=fread(dest, e->p_filesz, 1, f))!=1) {
printf_log(LOG_NONE, "Fail to (re)read PT_LOAD part #%zu (dest=%p, size=%ld, return=%ld, feof=%d/ferror=%d/%s)\n", i, dest, e->p_filesz, r, feof(f), ferror(f), strerror(ferror(f)));
return 1;
}
}
// zero'd difference between filesz and memsz
if(e->p_filesz != e->p_memsz)
memset(dest+e->p_filesz, 0, e->p_memsz - e->p_filesz);
}
}
// TLS data are just a copy, no need to re-load it
return 0;
}
int FindR64COPYRel(elfheader_t* h, const char* name, uintptr_t *offs, uint64_t** p, int version, const char* vername)
{
if(!h)
return 0;
Elf64_Rela * rel = (Elf64_Rela *)(h->rela + h->delta);
if(!h->rela)
return 0;
int cnt = h->relasz / h->relaent;
for (int i=0; i<cnt; ++i) {
int t = ELF64_R_TYPE(rel[i].r_info);
Elf64_Sym *sym = &h->DynSym[ELF64_R_SYM(rel[i].r_info)];
const char* symname = SymName(h, sym);
int version2 = h->VerSym?((Elf64_Half*)((uintptr_t)h->VerSym+h->delta))[ELF64_R_SYM(rel[i].r_info)]:-1;
if(version2!=-1) version2 &= 0x7fff;
if(version && !version2) version2=-1; // match a versionned symbol against a global "local" symbol
const char* vername2 = GetSymbolVersion(h, version2);
if(SameVersionnedSymbol(name, version, vername, symname, version2, vername2) && t==R_X86_64_COPY) {
*offs = sym->st_value + h->delta;
*p = (uint64_t*)(rel[i].r_offset + h->delta + rel[i].r_addend);
return 1;
}
}
return 0;
}
int RelocateElfREL(lib_t *maplib, lib_t *local_maplib, elfheader_t* head, int cnt, Elf64_Rel *rel)
{
for (int i=0; i<cnt; ++i) {
int t = ELF64_R_TYPE(rel[i].r_info);
Elf64_Sym *sym = &head->DynSym[ELF64_R_SYM(rel[i].r_info)];
int bind = ELF64_ST_BIND(sym->st_info);
const char* symname = SymName(head, sym);
//uint64_t ndx = sym->st_shndx;
uint64_t *p = (uint64_t*)(rel[i].r_offset + head->delta);
uintptr_t offs = 0;
uintptr_t end = 0;
//uintptr_t tmp = 0;
int version = head->VerSym?((Elf64_Half*)((uintptr_t)head->VerSym+head->delta))[ELF64_R_SYM(rel[i].r_info)]:-1;
if(version!=-1) version &=0x7fff;
const char* vername = GetSymbolVersion(head, version);
if(bind==STB_LOCAL) {
offs = sym->st_value + head->delta;
end = offs + sym->st_size;
} else {
// this is probably very very wrong. A proprer way to get reloc need to be writen, but this hack seems ok for now
// at least it work for half-life, unreal, ut99, zsnes, Undertale, ColinMcRae Remake, FTL, ShovelKnight...
/*if(bind==STB_GLOBAL && (ndx==10 || ndx==19) && t!=R_X86_64_GLOB_DAT) {
offs = sym->st_value + head->delta;
end = offs + sym->st_size;
}*/
// so weak symbol are the one left
if(!offs && !end) {
if(!offs && !end && local_maplib)
GetGlobalSymbolStartEnd(local_maplib, symname, &offs, &end, head, version, vername);
if(!offs && !end && local_maplib)
GetGlobalSymbolStartEnd(maplib, symname, &offs, &end, head, version, vername);
}
}
uintptr_t globoffs, globend;
uint64_t* globp;
switch(t) {
case R_X86_64_NONE:
// can be ignored
printf_dump(LOG_NEVER, "Ignoring %s @%p (%p)\n", DumpRelType(t), p, (void*)(p?(*p):0));
break;
case R_X86_64_PC32:
if (!offs) {
printf_log(LOG_NONE, "Error: Global Symbol %s not found, cannot apply R_X86_64_PC32 @%p (%p) in %s\n", symname, p, *(void**)p, head->name);
}
offs = (offs - (uintptr_t)p);
if(!offs)
printf_dump(LOG_NEVER, "Apply %s R_X86_64_PC32 @%p with sym=%s (%p -> %p)\n", (bind==STB_LOCAL)?"Local":"Global", p, symname, *(void**)p, (void*)(*(uintptr_t*)p+offs));
*p += offs;
break;
case R_X86_64_GLOB_DAT:
if(head!=my_context->elfs[0] && !IsGlobalNoWeakSymbolInNative(maplib, symname, version, vername) && FindR64COPYRel(my_context->elfs[0], symname, &globoffs, &globp, version, vername)) {
// set global offs / size for the symbol
offs = sym->st_value + head->delta;
end = offs + sym->st_size;
if(sym->st_size) {
printf_dump(LOG_NEVER, "Apply %s R_X86_64_GLOB_DAT with R_X86_64_COPY @%p/%p (%p/%p -> %p/%p) size=%ld on sym=%s \n", (bind==STB_LOCAL)?"Local":"Global", p, globp, (void*)(p?(*p):0), (void*)(globp?(*globp):0), (void*)offs, (void*)globoffs, sym->st_size, symname);
//memmove((void*)globoffs, (void*)offs, sym->st_size); // preapply to copy part from lib to main elf
AddWeakSymbol(GetGlobalData(maplib), symname, offs, sym->st_size, version, vername);
} else {
printf_dump(LOG_NEVER, "Apply %s R_X86_64_GLOB_DAT with R_X86_64_COPY @%p/%p (%p/%p -> %p/%p) null sized on sym=%s \n", (bind==STB_LOCAL)?"Local":"Global", p, globp, (void*)(p?(*p):0), (void*)(globp?(*globp):0), (void*)offs, (void*)globoffs, symname);
}
*p = globoffs;
} else {
// Look for same symbol already loaded but not in self (so no need for local_maplib here)
if (GetGlobalNoWeakSymbolStartEnd(local_maplib?local_maplib:maplib, symname, &globoffs, &globend, version, vername)) {
offs = globoffs;
end = globend;
}
if (!offs) {
if(strcmp(symname, "__gmon_start__"))
printf_log(LOG_NONE, "Error: Global Symbol %s not found, cannot apply R_X86_64_GLOB_DAT @%p (%p) in %s\n", symname, p, *(void**)p, head->name);
} else {
printf_dump(LOG_NEVER, "Apply %s R_X86_64_GLOB_DAT @%p (%p -> %p) on sym=%s (ver=%d/%s)\n", (bind==STB_LOCAL)?"Local":"Global", p, (void*)(p?(*p):0), (void*)offs, symname, version, vername?vername:"(none)");
*p = offs;
}
}
break;
case R_X86_64_COPY:
if(offs) {
uintptr_t old_offs = offs;
uintptr_t old_end = end;
offs = 0;
GetSymbolStartEnd(GetGlobalData(maplib), symname, &offs, &end, version, vername, 1); // try globaldata symbols first
if(offs==0) {
GetNoSelfSymbolStartEnd(maplib, symname, &offs, &end, head, version, vername); // get original copy if any
if(!offs && local_maplib)
GetNoSelfSymbolStartEnd(local_maplib, symname, &offs, &end, head, version, vername);
}
if(!offs) {
offs = old_offs;
end = old_end;
}
printf_dump(LOG_NEVER, "Apply %s R_X86_64_COPY @%p with sym=%s, @%p size=%ld (", (bind==STB_LOCAL)?"Local":"Global", p, symname, (void*)offs, sym->st_size);
memmove(p, (void*)offs, sym->st_size);
if(box64_dump) {
uint64_t *k = (uint64_t*)p;
for (unsigned j=0; j<((sym->st_size>128u)?128u:sym->st_size); j+=8, ++k)
printf_dump(LOG_NEVER, "%s0x%016lX", j?" ":"", *k);
printf_dump(LOG_NEVER, "%s)\n", (sym->st_size>128u)?" ...":"");
}
} else {
printf_log(LOG_NONE, "Error: Symbol %s not found, cannot apply R_X86_64_COPY @%p (%p) in %s\n", symname, p, *(void**)p, head->name);
}
break;
case R_X86_64_RELATIVE:
printf_dump(LOG_NEVER, "Apply %s R_X86_64_RELATIVE @%p (%p -> %p)\n", (bind==STB_LOCAL)?"Local":"Global", p, *(void**)p, (void*)((*p)+head->delta));
*p += head->delta;
break;
case R_X86_64_64:
if (!offs) {
printf_log(LOG_NONE, "Error: Symbol %s not found, cannot apply R_X86_64_64 @%p (%p) in %s\n", symname, p, *(void**)p, head->name);
// return -1;
} else {
printf_dump(LOG_NEVER, "Apply %s R_X86_64_64 @%p with sym=%s (%p -> %p)\n", (bind==STB_LOCAL)?"Local":"Global", p, symname, *(void**)p, (void*)(offs+*(uint64_t*)p));
*p += offs;
}
break;
#if 0
case R_X86_64_JUMP_SLOT:
// apply immediatly for gobject closure marshal or for LOCAL binding. Also, apply immediatly if it doesn't jump in the got
tmp = (uintptr_t)(*p);
if (bind==STB_LOCAL
|| ((symname && strstr(symname, "g_cclosure_marshal_")==symname))
|| !tmp
|| !((tmp>=head->plt && tmp<head->plt_end) || (tmp>=head->gotplt && tmp<head->gotplt_end))
) {
if (!offs) {
if(bind==STB_WEAK) {
printf_log(LOG_INFO, "Warning: Weak Symbol %s not found, cannot apply R_X86_64_JUMP_SLOT @%p (%p)\n", symname, p, *(void**)p);
} else {
printf_log(LOG_NONE, "Error: Symbol %s not found, cannot apply R_X86_64_JUMP_SLOT @%p (%p) in %s\n", symname, p, *(void**)p, head->name);
}
// return -1;
} else {
if(p) {
printf_dump(LOG_NEVER, "Apply %s R_X86_64_JUMP_SLOT @%p with sym=%s (%p -> %p)\n", (bind==STB_LOCAL)?"Local":"Global", p, symname, *(void**)p, (void*)offs);
*p = offs;
} else {
printf_log(LOG_NONE, "Warning, Symbol %s found, but Jump Slot Offset is NULL \n", symname);
}
}
} else {
printf_dump(LOG_NEVER, "Preparing (if needed) %s R_X86_64_JUMP_SLOT @%p (0x%lx->0x%0lx) with sym=%s to be apply later\n", (bind==STB_LOCAL)?"Local":"Global", p, *p, *p+head->delta, symname);
*p += head->delta;
}
break;
#endif
default:
printf_log(LOG_INFO, "Warning, don't know how to handle rel #%d %s (%p)\n", i, DumpRelType(ELF64_R_TYPE(rel[i].r_info)), p);
}
}
return 0;
}
struct tlsdesc
{
uintptr_t entry;
uintptr_t arg;
};
uintptr_t tlsdescUndefweak = 0;
uintptr_t GetSegmentBaseEmu(x64emu_t* emu, int seg);
EXPORT uintptr_t _dl_tlsdesc_undefweak(x64emu_t* emu)
{
printf_log(LOG_DEBUG, "_dl_tlsdesc_undefweak, rax=%p\n", (void*)R_RAX);
struct tlsdesc *td = (struct tlsdesc *)R_RAX;
return td->arg;
}
int RelocateElfRELA(lib_t *maplib, lib_t *local_maplib, elfheader_t* head, int cnt, Elf64_Rela *rela, int* need_resolv)
{
for (int i=0; i<cnt; ++i) {
int t = ELF64_R_TYPE(rela[i].r_info);
Elf64_Sym *sym = &head->DynSym[ELF64_R_SYM(rela[i].r_info)];
int bind = ELF64_ST_BIND(sym->st_info);
//uint64_t ndx = sym->st_shndx;
const char* symname = SymName(head, sym);
uint64_t *p = (uint64_t*)(rela[i].r_offset + head->delta);
uintptr_t offs = 0;
uintptr_t end = 0;
elfheader_t* h_tls = head;
int version = head->VerSym?((Elf64_Half*)((uintptr_t)head->VerSym+head->delta))[ELF64_R_SYM(rela[i].r_info)]:-1;
if(version!=-1) version &=0x7fff;
const char* vername = GetSymbolVersion(head, version);
if(bind==STB_LOCAL) {
offs = sym->st_value + head->delta;
end = offs + sym->st_size;
} else {
// this is probably very very wrong. A proprer way to get reloc need to be writen, but this hack seems ok for now
// at least it work for half-life, unreal, ut99, zsnes, Undertale, ColinMcRae Remake, FTL, ShovelKnight...
/*if(bind==STB_GLOBAL && (ndx==10 || ndx==19) && t!=R_X86_64_GLOB_DAT) {
offs = sym->st_value + head->delta;
end = offs + sym->st_size;
}*/
// so weak symbol are the one left
if(!offs && !end) {
GetGlobalSymbolStartEnd(maplib, symname, &offs, &end, head, version, vername);
if(!offs && !end && local_maplib) {
GetGlobalSymbolStartEnd(local_maplib, symname, &offs, &end, head, version, vername);
}
}
}
uintptr_t globoffs, globend;
uint64_t* globp;
uintptr_t tmp = 0;
intptr_t delta;
switch(ELF64_R_TYPE(rela[i].r_info)) {
case R_X86_64_NONE:
break;
case R_X86_64_PC32:
// should be "S + A - P" with S=symbol offset, A=addend and P=place of the storage unit, write a word32
// can be ignored
break;
case R_X86_64_RELATIVE:
printf_dump(LOG_NEVER, "Apply %s R_X86_64_RELATIVE @%p (%p -> %p)\n", (bind==STB_LOCAL)?"Local":"Global", p, *(void**)p, (void*)(head->delta+ rela[i].r_addend));
*p = head->delta+ rela[i].r_addend;
break;
case R_X86_64_COPY:
globoffs = offs;
globend = end;
offs = end = 0;
GetSymbolStartEnd(GetGlobalData(maplib), symname, &offs, &end, version, vername, 1); // try globaldata symbols first
if(!offs && local_maplib)
GetNoSelfSymbolStartEnd(local_maplib, symname, &offs, &end, head, version, vername);
if(!offs)
GetNoSelfSymbolStartEnd(maplib, symname, &offs, &end, head, version, vername);
if(!offs) {offs = globoffs; end = globend;}
if(offs) {
// add r_addend to p?
printf_dump(LOG_NEVER, "Apply R_X86_64_COPY @%p with sym=%s (ver=%d/%s), @%p+0x%lx size=%ld\n", p, symname, version, vername?vername:"(none)", (void*)offs, rela[i].r_addend, sym->st_size);
if(p!=(void*)(offs+rela[i].r_addend))
memmove(p, (void*)(offs+rela[i].r_addend), sym->st_size);
} else {
printf_log(LOG_NONE, "Error: Symbol %s not found, cannot apply RELA R_X86_64_COPY @%p (%p) in %s\n", symname, p, *(void**)p, head->name);
}
break;
case R_X86_64_GLOB_DAT:
if(head!=my_context->elfs[0] && !IsGlobalNoWeakSymbolInNative(maplib, symname, version, vername) && FindR64COPYRel(my_context->elfs[0], symname, &globoffs, &globp, version, vername)) {
// set global offs / size for the symbol
offs = sym->st_value + head->delta;
end = offs + sym->st_size;
if(sym->st_size) {
printf_dump(LOG_NEVER, "Apply %s R_X86_64_GLOB_DAT with R_X86_64_COPY @%p/%p (%p/%p -> %p/%p) size=%ld on sym=%s (ver=%d/%s) \n",
(bind==STB_LOCAL)?"Local":"Global", p, globp, (void*)(p?(*p):0),
(void*)(globp?(*globp):0), (void*)offs, (void*)globoffs, sym->st_size, symname, version, vername?vername:"(none)");
//memmove((void*)globoffs, (void*)offs, sym->st_size); // preapply to copy part from lib to main elf
AddWeakSymbol(GetGlobalData(maplib), symname, offs, sym->st_size, version, vername);
} else {
printf_dump(LOG_NEVER, "Apply %s R_X86_64_GLOB_DAT with R_X86_64_COPY @%p/%p (%p/%p -> %p/%p) null sized on sym=%s (ver=%d/%s)\n",
(bind==STB_LOCAL)?"Local":"Global", p, globp, (void*)(p?(*p):0),
(void*)(globp?(*globp):0), (void*)offs, (void*)globoffs, symname, version, vername?vername:"(none)");
}
*p = globoffs;
} else {
// Look for same symbol already loaded but not in self (so no need for local_maplib here)
if (GetGlobalNoWeakSymbolStartEnd(local_maplib?local_maplib:maplib, symname, &globoffs, &globend, version, vername)) {
offs = globoffs;
end = globend;
}
if (!offs) {
if(strcmp(symname, "__gmon_start__"))
printf_log(LOG_NONE, "Error: Global Symbol %s not found, cannot apply R_X86_64_GLOB_DAT @%p (%p) in %s\n", symname, p, *(void**)p, head->name);
} else {
printf_dump(LOG_NEVER, "Apply %s R_X86_64_GLOB_DAT @%p (%p -> %p) on sym=%s (ver=%d/%s)\n", (bind==STB_LOCAL)?"Local":"Global", p, (void*)(p?(*p):0), (void*)offs, symname, version, vername?vername:"(none)");
*p = offs/* + rela[i].r_addend*/; // not addend it seems
}
}
break;
case R_X86_64_JUMP_SLOT:
// apply immediatly for gobject closure marshal or for LOCAL binding. Also, apply immediatly if it doesn't jump in the got
tmp = (uintptr_t)(*p);
if (bind==STB_LOCAL
|| ((symname && strstr(symname, "g_cclosure_marshal_")==symname))
|| ((symname && strstr(symname, "__pthread_unwind_next")==symname))
|| !tmp
|| !((tmp>=head->plt && tmp<head->plt_end) || (tmp>=head->gotplt && tmp<head->gotplt_end))
|| !need_resolv
) {
if (!offs) {
if(bind==STB_WEAK) {
printf_log(LOG_INFO, "Warning: Weak Symbol %s not found, cannot apply R_X86_64_JUMP_SLOT @%p (%p)\n", symname, p, *(void**)p);
} else {
printf_log(LOG_NONE, "Error: Symbol %s not found, cannot apply R_X86_64_JUMP_SLOT @%p (%p) in %s\n", symname, p, *(void**)p, head->name);
}
// return -1;
} else {
if(p) {
printf_dump(LOG_NEVER, "Apply %s R_X86_64_JUMP_SLOT @%p with sym=%s (%p -> %p)\n",
(bind==STB_LOCAL)?"Local":"Global", p, symname, *(void**)p, (void*)(offs+rela[i].r_addend));
*p = offs + rela[i].r_addend;
} else {
printf_log(LOG_NONE, "Warning, Symbol %s found, but Jump Slot Offset is NULL \n", symname);
}
}
} else {
printf_dump(LOG_NEVER, "Preparing (if needed) %s R_X86_64_JUMP_SLOT @%p (0x%lx->0x%0lx) with sym=%s to be apply later (addend=%ld)\n",
(bind==STB_LOCAL)?"Local":"Global", p, *p, *p+head->delta, symname, rela[i].r_addend);
*p += head->delta;
*need_resolv = 1;
}
break;
case R_X86_64_64:
if (!offs) {
printf_log(LOG_NONE, "Error: Symbol %s not found, cannot apply R_X86_64_64 @%p (%p) in %s\n", symname, p, *(void**)p, head->name);
// return -1;
} else {
printf_dump(LOG_NEVER, "Apply %s R_X86_64_64 @%p with sym=%s (ver=%d/%s) addend=0x%lx (%p -> %p)\n",
(bind==STB_LOCAL)?"Local":"Global", p, symname, version, vername?vername:"(none)", rela[i].r_addend, *(void**)p, (void*)(offs+rela[i].r_addend/*+*(uint64_t*)p*/));
*p /*+*/= offs+rela[i].r_addend;
}
break;
case R_X86_64_TPOFF64:
// Negated offset in static TLS block
{
//if(h_tls) {
// offs = sym->st_value;
//} else
{
h_tls = NULL;
if(local_maplib)
h_tls = GetGlobalSymbolElf(local_maplib, symname, version, vername);
if(!h_tls)
h_tls = GetGlobalSymbolElf(maplib, symname, version, vername);
}
if(h_tls) {
delta = *(int64_t*)p;
printf_dump(LOG_NEVER, "Applying %s %s on %s @%p (%ld -> %ld+%ld+%ld, size=%ld)\n", (bind==STB_LOCAL)?"Local":"Global", DumpRelType(t), symname, p, delta, h_tls->tlsbase, (int64_t)offs, rela[i].r_addend, end-offs);
*p = (uintptr_t)((int64_t)offs + rela[i].r_addend + h_tls->tlsbase);
} else {
printf_log(LOG_INFO, "Warning, cannot apply %s %s on %s @%p (%ld), no elf_header found\n", (bind==STB_LOCAL)?"Local":"Global", DumpRelType(t), symname, p, (int64_t)offs);
}
}
break;
case R_X86_64_DTPMOD64:
// ID of module containing symbol
if(!symname || symname[0]=='\0' || bind==STB_LOCAL)
offs = getElfIndex(my_context, head);
else {
if(!h_tls) {
if(local_maplib)
h_tls = GetGlobalSymbolElf(local_maplib, symname, version, vername);
if(!h_tls)
h_tls = GetGlobalSymbolElf(maplib, symname, version, vername);
}
offs = getElfIndex(my_context, h_tls);
}
if(p) {
printf_dump(LOG_NEVER, "Apply %s %s @%p with sym=%s (%p -> %p)\n", "R_X86_64_DTPMOD64", (bind==STB_LOCAL)?"Local":"Global", p, symname, *(void**)p, (void*)offs);
*p = offs;
} else {
printf_log(LOG_NONE, "Warning, Symbol %s or Elf not found, but R_X86_64_DTPMOD64 Slot Offset is NULL \n", symname);
}
break;
case R_X86_64_DTPOFF64:
// Offset in TLS block
if (!offs && !end) {
if(bind==STB_WEAK) {
printf_log(LOG_INFO, "Warning: Weak Symbol %s not found, cannot apply R_X86_64_DTPOFF64 @%p (%p)\n", symname, p, *(void**)p);
} else {
printf_log(LOG_NONE, "Error: Symbol %s not found, cannot apply R_X86_64_DTPOFF64 @%p (%p) in %s\n", symname, p, *(void**)p, head->name);
}
// return -1;
} else {
if(h_tls)
offs = sym->st_value;
if(p) {
int64_t tlsoffset = offs; // it's not an offset in elf memory
printf_dump(LOG_NEVER, "Apply %s R_X86_64_DTPOFF64 @%p with sym=%s (%p -> %p)\n", (bind==STB_LOCAL)?"Local":"Global", p, symname, (void*)tlsoffset, (void*)offs);
*p = tlsoffset;
} else {
printf_log(LOG_NONE, "Warning, Symbol %s found, but R_X86_64_DTPOFF64 Slot Offset is NULL \n", symname);
}
}
break;
case R_X86_64_TLSDESC:
if(!symname || !symname[0]) {
printf_dump(LOG_NEVER, "Apply %s R_X86_64_TLSDESC @%p with addend=%zu\n", (bind==STB_LOCAL)?"Local":"Global", p, rela[i].r_addend);
struct tlsdesc volatile *td = (struct tlsdesc volatile *)p;
if(!tlsdescUndefweak)
tlsdescUndefweak = AddBridge(my_context->system, pFE, _dl_tlsdesc_undefweak, 0, "_dl_tlsdesc_undefweak");
td->entry = tlsdescUndefweak;
td->arg = (uintptr_t)(head->tlsbase + rela[i].r_addend);
} else {
printf_log(LOG_NONE, "Warning, R_X86_64_TLSDESC used with Symbol %s(%p) not supported for now \n", symname, sym);
}
break;
default:
printf_log(LOG_INFO, "Warning, don't know of to handle rela #%d %s on %s\n", i, DumpRelType(ELF64_R_TYPE(rela[i].r_info)), symname);
}
}
return 0;
}
int RelocateElf(lib_t *maplib, lib_t *local_maplib, elfheader_t* head)
{
if(head->rel) {
int cnt = head->relsz / head->relent;
DumpRelTable(head, cnt, (Elf64_Rel *)(head->rel + head->delta), "Rel");
printf_dump(LOG_DEBUG, "Applying %d Relocation(s) for %s\n", cnt, head->name);
if(RelocateElfREL(maplib, local_maplib, head, cnt, (Elf64_Rel *)(head->rel + head->delta)))
return -1;
}
if(head->rela) {
int cnt = head->relasz / head->relaent;
DumpRelATable(head, cnt, (Elf64_Rela *)(head->rela + head->delta), "RelA");
printf_dump(LOG_DEBUG, "Applying %d Relocation(s) with Addend for %s\n", cnt, head->name);
if(RelocateElfRELA(maplib, local_maplib, head, cnt, (Elf64_Rela *)(head->rela + head->delta), NULL))
return -1;
}
return 0;
}
int RelocateElfPlt(lib_t *maplib, lib_t *local_maplib, elfheader_t* head)
{
int need_resolver = 0;
if(head->pltrel) {
int cnt = head->pltsz / head->pltent;
if(head->pltrel==DT_REL) {
DumpRelTable(head, cnt, (Elf64_Rel *)(head->jmprel + head->delta), "PLT");
printf_dump(LOG_DEBUG, "Applying %d PLT Relocation(s) for %s\n", cnt, head->name);
if(RelocateElfREL(maplib, local_maplib, head, cnt, (Elf64_Rel *)(head->jmprel + head->delta)))
return -1;
} else if(head->pltrel==DT_RELA) {
DumpRelATable(head, cnt, (Elf64_Rela *)(head->jmprel + head->delta), "PLT");
printf_dump(LOG_DEBUG, "Applying %d PLT Relocation(s) with Addend for %s\n", cnt, head->name);
if(RelocateElfRELA(maplib, local_maplib, head, cnt, (Elf64_Rela *)(head->jmprel + head->delta), &need_resolver))
return -1;
}
if(need_resolver) {
if(pltResolver==~0LL) {
pltResolver = AddBridge(my_context->system, vFE, PltResolver, 0, "PltResolver");
}
if(head->pltgot) {
*(uintptr_t*)(head->pltgot+head->delta+16) = pltResolver;
*(uintptr_t*)(head->pltgot+head->delta+8) = (uintptr_t)head;
printf_dump(LOG_DEBUG, "PLT Resolver injected in plt.got at %p\n", (void*)(head->pltgot+head->delta+16));
} else if(head->got) {
*(uintptr_t*)(head->got+head->delta+16) = pltResolver;
*(uintptr_t*)(head->got+head->delta+8) = (uintptr_t)head;
printf_dump(LOG_DEBUG, "PLT Resolver injected in got at %p\n", (void*)(head->got+head->delta+16));
}
}
}
return 0;
}
void CalcStack(elfheader_t* elf, uint64_t* stacksz, size_t* stackalign)
{
if(*stacksz < elf->stacksz)
*stacksz = elf->stacksz;
if(*stackalign < elf->stackalign)
*stackalign = elf->stackalign;
}
Elf64_Sym* GetFunction(elfheader_t* h, const char* name)
{
// TODO: create a hash on named to avoid this loop
for (size_t i=0; i<h->numSymTab; ++i) {
int type = ELF64_ST_TYPE(h->SymTab[i].st_info);
if(type==STT_FUNC) {
const char * symname = h->StrTab+h->SymTab[i].st_name;
if(strcmp(symname, name)==0) {
return h->SymTab+i;
}
}
}
return NULL;
}
Elf64_Sym* GetElfObject(elfheader_t* h, const char* name)
{
for (size_t i=0; i<h->numSymTab; ++i) {
int type = ELF64_ST_TYPE(h->SymTab[i].st_info);
if(type==STT_OBJECT) {
const char * symname = h->StrTab+h->SymTab[i].st_name;
if(strcmp(symname, name)==0) {
return h->SymTab+i;
}
}
}
return NULL;
}
uintptr_t GetFunctionAddress(elfheader_t* h, const char* name)
{
Elf64_Sym* sym = GetFunction(h, name);
if(sym) return sym->st_value;
return 0;
}
uintptr_t GetEntryPoint(lib_t* maplib, elfheader_t* h)
{
(void)maplib;
uintptr_t ep = h->entrypoint + h->delta;
printf_log(LOG_DEBUG, "Entry Point is %p\n", (void*)ep);
if(box64_dump) {
printf_dump(LOG_NEVER, "(short) Dump of Entry point\n");
int sz = 64;
uintptr_t lastbyte = GetLastByte(h);
if (ep + sz > lastbyte)
sz = lastbyte - ep;
DumpBinary((char*)ep, sz);
}
return ep;
}
uintptr_t GetLastByte(elfheader_t* h)
{
return (uintptr_t)h->memory/* + h->delta*/ + h->memsz;
}
void AddSymbols(lib_t *maplib, kh_mapsymbols_t* mapsymbols, kh_mapsymbols_t* weaksymbols, kh_mapsymbols_t* localsymbols, elfheader_t* h)
{
if(box64_dump && h->DynSym) DumpDynSym(h);
int libcef = (strstr(h->name, "libcef.so"))?1:0;
//libcef.so is linked with tcmalloc staticaly, but this cannot be easily supported in box64, so hacking some "unlink" here
const char* avoid_libcef[] = {"malloc", "realloc", "free", "calloc", "cfree",
"__libc_calloc", "__libc_cfree", "__libc_memallign", "__liv_pvalloc",
"__libcrealloc", "__libc_valloc", "__posix_memalign",
"valloc", "pvalloc", "posix_memalign", "malloc_stats", "malloc_usable_size",
/*"mallopt",*/ "localtime_r",
//c++ symbol from libstdc++ too
//"_ZnwmRKSt9nothrow_t", "_ZdaPv", // operator new(unsigned long, std::nothrow_t const&), operator delete[](void*)
//"_Znwm", "_ZdlPv", "_Znam", // operator new(unsigned long), operator delete(void*), operator new[](unsigned long)
//"_ZnwmSt11align_val_t", "_ZnwmSt11align_val_tRKSt9nothrow_t", // operator new(unsigned long, std::align_val_t)
//"_ZnamSt11align_val_t", "_ZnamSt11align_val_tRKSt9nothrow_t", // operator new[](unsigned long, std::align_val_t)
//"_ZdlPvRKSt9nothrow_t", "_ZdaPvSt11align_val_tRKSt9nothrow_t", // more delete operators
//"_ZdlPvmSt11align_val_t", "_ZdaPvRKSt9nothrow_t",
//"_ZdaPvSt11align_val_t", "_ZdlPvSt11align_val_t",
};
printf_dump(LOG_NEVER, "Will look for Symbol to add in SymTable(%zu)\n", h->numSymTab);
for (size_t i=0; i<h->numSymTab; ++i) {
const char * symname = h->StrTab+h->SymTab[i].st_name;
int bind = ELF64_ST_BIND(h->SymTab[i].st_info);
int type = ELF64_ST_TYPE(h->SymTab[i].st_info);
int vis = h->SymTab[i].st_other&0x3;
uint64_t sz = h->SymTab[i].st_size;
if((type==STT_OBJECT || type==STT_FUNC || type==STT_COMMON || type==STT_TLS || type==STT_NOTYPE)
&& (vis==STV_DEFAULT || vis==STV_PROTECTED) && (h->SymTab[i].st_shndx!=0)) {
if(sz && strstr(symname, "@@")) {
char symnameversionned[strlen(symname)+1];
strcpy(symnameversionned, symname);
// extact symname@@vername
char* p = strchr(symnameversionned, '@');
*p=0;
p+=2;
symname = AddDictionnary(my_context->versym, symnameversionned);
const char* vername = AddDictionnary(my_context->versym, p);
if((bind==STB_GNU_UNIQUE /*|| (bind==STB_GLOBAL && type==STT_FUNC)*/) && FindGlobalSymbol(maplib, symname, 2, p))
continue;
uintptr_t offs = (type==STT_TLS)?h->SymTab[i].st_value:(h->SymTab[i].st_value + h->delta);
printf_dump(LOG_NEVER, "Adding Default Versionned Symbol(bind=%s) \"%s@%s\" with offset=%p sz=%zu\n", (bind==STB_LOCAL)?"LOCAL":((bind==STB_WEAK)?"WEAK":"GLOBAL"), symname, vername, (void*)offs, sz);
if(bind==STB_LOCAL)
AddSymbol(localsymbols, symname, offs, sz, 2, vername);
else // add in local and global map
if(bind==STB_WEAK) {
AddSymbol(weaksymbols, symname, offs, sz, 2, vername);
} else {
AddSymbol(mapsymbols, symname, offs, sz, 2, vername);
}
} else {
int to_add = 1;
if(libcef) {
if(strstr(symname, "_Zn")==symname || strstr(symname, "_Zd")==symname)
to_add = 0;
for(int j=0; j<sizeof(avoid_libcef)/sizeof(avoid_libcef[0]) && to_add; ++j)
if(!strcmp(symname, avoid_libcef[j]))
to_add = 0;
}
if(!to_add || (bind==STB_GNU_UNIQUE && FindGlobalSymbol(maplib, symname, -1, NULL)))
continue;
uintptr_t offs = (type==STT_TLS)?h->SymTab[i].st_value:(h->SymTab[i].st_value + h->delta);
printf_dump(LOG_NEVER, "Adding Symbol(bind=%s) \"%s\" with offset=%p sz=%zu\n", (bind==STB_LOCAL)?"LOCAL":((bind==STB_WEAK)?"WEAK":"GLOBAL"), symname, (void*)offs, sz);
if(bind==STB_LOCAL)
AddSymbol(localsymbols, symname, offs, sz, 1, NULL);
else // add in local and global map
if(bind==STB_WEAK) {
AddSymbol(weaksymbols, symname, offs, sz, 1, NULL);
} else {
AddSymbol(mapsymbols, symname, offs, sz, 1, NULL);
}
}
}
}
printf_dump(LOG_NEVER, "Will look for Symbol to add in DynSym (%zu)\n", h->numDynSym);
for (size_t i=0; i<h->numDynSym; ++i) {
const char * symname = h->DynStr+h->DynSym[i].st_name;
int bind = ELF64_ST_BIND(h->DynSym[i].st_info);
int type = ELF64_ST_TYPE(h->DynSym[i].st_info);
int vis = h->DynSym[i].st_other&0x3;
if((type==STT_OBJECT || type==STT_FUNC || type==STT_COMMON || type==STT_TLS || type==STT_NOTYPE)
&& (vis==STV_DEFAULT || vis==STV_PROTECTED) && (h->DynSym[i].st_shndx!=0 && h->DynSym[i].st_shndx<=65521)) {
uintptr_t offs = (type==STT_TLS)?h->DynSym[i].st_value:(h->DynSym[i].st_value + h->delta);
uint64_t sz = h->DynSym[i].st_size;
int version = h->VerSym?((Elf64_Half*)((uintptr_t)h->VerSym+h->delta))[i]:-1;
if(version!=-1) version &= 0x7fff;
const char* vername = GetSymbolVersion(h, version);
int to_add = 1;
if(libcef) {
if(strstr(symname, "_Zn")==symname || strstr(symname, "_Zd")==symname)
to_add = 0;
for(int j=0; j<sizeof(avoid_libcef)/sizeof(avoid_libcef[0]) && to_add; ++j)
if(!strcmp(symname, avoid_libcef[j]))
to_add = 0;
}
if(!to_add || (bind==STB_GNU_UNIQUE && FindGlobalSymbol(maplib, symname, version, vername)))
continue;
printf_dump(LOG_NEVER, "Adding Versionned Symbol(bind=%s) \"%s\" (ver=%d/%s) with offset=%p sz=%zu\n", (bind==STB_LOCAL)?"LOCAL":((bind==STB_WEAK)?"WEAK":"GLOBAL"), symname, version, vername?vername:"(none)", (void*)offs, sz);
if(bind==STB_LOCAL)
AddSymbol(localsymbols, symname, offs, sz, version, vername);
else // add in local and global map
if(bind==STB_WEAK) {
AddSymbol(weaksymbols, symname, offs, sz, version, vername);
} else {
AddSymbol(mapsymbols, symname, offs, sz, version, vername);
}
}
}
}
/*
$ORIGIN – Provides the directory the object was loaded from. This token is typical
used for locating dependencies in unbundled packages. For more details of this
token expansion, see “Locating Associated Dependencies”
$OSNAME – Expands to the name of the operating system (see the uname(1) man
page description of the -s option). For more details of this token expansion, see
“System Specific Shared Objects”
$OSREL – Expands to the operating system release level (see the uname(1) man
page description of the -r option). For more details of this token expansion, see
“System Specific Shared Objects”
$PLATFORM – Expands to the processor type of the current machine (see the
uname(1) man page description of the -i option). For more details of this token
expansion, see “System Specific Shared Objects”
*/
int LoadNeededLibs(elfheader_t* h, lib_t *maplib, needed_libs_t* neededlibs, library_t *deplib, int local, box64context_t *box64, x64emu_t* emu)
{
DumpDynamicRPath(h);
// update RPATH first
for (size_t i=0; i<h->numDynamic; ++i)
if(h->Dynamic[i].d_tag==DT_RPATH || h->Dynamic[i].d_tag==DT_RUNPATH) {
char *rpathref = h->DynStrTab+h->delta+h->Dynamic[i].d_un.d_val;
char* rpath = rpathref;
while(strstr(rpath, "$ORIGIN")) {
char* origin = strdup(h->path);
char* p = strrchr(origin, '/');
if(p) *p = '\0'; // remove file name to have only full path, without last '/'
char* tmp = (char*)calloc(1, strlen(rpath)-strlen("$ORIGIN")+strlen(origin)+1);
p = strstr(rpath, "$ORIGIN");
memcpy(tmp, rpath, p-rpath);
strcat(tmp, origin);
strcat(tmp, p+strlen("$ORIGIN"));
if(rpath!=rpathref)
free(rpath);
rpath = tmp;
free(origin);
}
while(strstr(rpath, "${ORIGIN}")) {
char* origin = strdup(h->path);
char* p = strrchr(origin, '/');
if(p) *p = '\0'; // remove file name to have only full path, without last '/'
char* tmp = (char*)calloc(1, strlen(rpath)-strlen("${ORIGIN}")+strlen(origin)+1);
p = strstr(rpath, "${ORIGIN}");
memcpy(tmp, rpath, p-rpath);
strcat(tmp, origin);
strcat(tmp, p+strlen("${ORIGIN}"));
if(rpath!=rpathref)
free(rpath);
rpath = tmp;
free(origin);
}
if(strchr(rpath, '$')) {
printf_log(LOG_INFO, "BOX64: Warning, RPATH with $ variable not supported yet (%s)\n", rpath);
} else {
printf_log(LOG_DEBUG, "Prepending path \"%s\" to BOX64_LD_LIBRARY_PATH\n", rpath);
PrependList(&box64->box64_ld_lib, rpath, 1);
}
if(rpath!=rpathref)
free(rpath);
}
if(!h->neededlibs && neededlibs)
h->neededlibs = neededlibs;
DumpDynamicNeeded(h);
int cnt = 0;
for (int i=0; i<h->numDynamic; ++i)
if(h->Dynamic[i].d_tag==DT_NEEDED)
++cnt;
const char* nlibs[cnt];
int j=0;
for (int i=0; i<h->numDynamic; ++i)
if(h->Dynamic[i].d_tag==DT_NEEDED)
nlibs[j++] = h->DynStrTab+h->delta+h->Dynamic[i].d_un.d_val;
// TODO: Add LD_LIBRARY_PATH and RPATH handling
if(AddNeededLib(maplib, neededlibs, deplib, local, nlibs, cnt, box64, emu)) {
printf_log(LOG_INFO, "Error loading one of needed lib\n");
if(!allow_missing_libs)
return 1; //error...
}
return 0;
}
int ElfCheckIfUseTCMallocMinimal(elfheader_t* h)
{
if(!h)
return 0;
for (size_t i=0; i<h->numDynamic; ++i)
if(h->Dynamic[i].d_tag==DT_NEEDED) {
char *needed = h->DynStrTab+h->delta+h->Dynamic[i].d_un.d_val;
if(!strcmp(needed, "libtcmalloc_minimal.so.4")) // tcmalloc needs to be the 1st lib loaded
return 1;
else
return 0;
}
return 0;
}
void RunElfInit(elfheader_t* h, x64emu_t *emu)
{
if(!h || h->init_done)
return;
// reset Segs Cache
memset(emu->segs_serial, 0, sizeof(emu->segs_serial));
uintptr_t p = h->initentry + h->delta;
box64context_t* context = GetEmuContext(emu);
if(context->deferedInit) {
if(context->deferedInitSz==context->deferedInitCap) {
context->deferedInitCap += 4;
context->deferedInitList = (elfheader_t**)realloc(context->deferedInitList, context->deferedInitCap*sizeof(elfheader_t*));
}
context->deferedInitList[context->deferedInitSz++] = h;
return;
}
// Refresh no-file part of TLS in case default value changed
if(h->tlsfilesize) {
char* dest = (char*)(my_context->tlsdata+my_context->tlssize+h->tlsbase);
printf_dump(LOG_DEBUG, "Refreshing main TLS block @%p from %p:0x%lx\n", dest, (void*)h->tlsaddr, h->tlsfilesize);
memcpy(dest, (void*)(h->tlsaddr+h->delta), h->tlsfilesize);
tlsdatasize_t* ptr;
if ((ptr = (tlsdatasize_t*)pthread_getspecific(my_context->tlskey)) != NULL)
if(ptr->tlssize==my_context->tlssize) {
// refresh in tlsdata too
dest = (char*)(ptr->tlsdata+ptr->tlssize+h->tlsbase);
printf_dump(LOG_DEBUG, "Refreshing active TLS block @%p from %p:0x%lx\n", dest, (void*)h->tlsaddr, h->tlssize-h->tlsfilesize);
memcpy(dest, (void*)(h->tlsaddr+h->delta), h->tlsfilesize);
}
}
printf_log(LOG_DEBUG, "Calling Init for %s @%p\n", ElfName(h), (void*)p);
if(h->initentry)
RunFunctionWithEmu(emu, 0, p, 3, context->argc, context->argv, context->envv);
printf_log(LOG_DEBUG, "Done Init for %s\n", ElfName(h));
// and check init array now
Elf64_Addr *addr = (Elf64_Addr*)(h->initarray + h->delta);
for (size_t i=0; i<h->initarray_sz; ++i) {
if(addr[i]) {
printf_log(LOG_DEBUG, "Calling Init[%zu] for %s @%p\n", i, ElfName(h), (void*)addr[i]);
RunFunctionWithEmu(emu, 0, (uintptr_t)addr[i], 3, context->argc, context->argv, context->envv);
}
}
h->init_done = 1;
h->fini_done = 0; // can be fini'd now (in case it was re-inited)
printf_log(LOG_DEBUG, "All Init Done for %s\n", ElfName(h));
return;
}
EXPORTDYN
void RunDeferedElfInit(x64emu_t *emu)
{
box64context_t* context = GetEmuContext(emu);
if(!context->deferedInit)
return;
context->deferedInit = 0;
if(!context->deferedInitList)
return;
int Sz = context->deferedInitSz;
elfheader_t** List = context->deferedInitList;
context->deferedInitList = NULL;
context->deferedInitCap = context->deferedInitSz = 0;
for (int i=0; i<Sz; ++i)
RunElfInit(List[i], emu);
free(List);
}
void RunElfFini(elfheader_t* h, x64emu_t *emu)
{
if(!h || h->fini_done)
return;
h->fini_done = 1;
// first check fini array
Elf64_Addr *addr = (Elf64_Addr*)(h->finiarray + h->delta);
for (int i=h->finiarray_sz-1; i>=0; --i) {
printf_log(LOG_DEBUG, "Calling Fini[%d] for %s @%p\n", i, ElfName(h), (void*)addr[i]);
RunFunctionWithEmu(emu, 0, (uintptr_t)addr[i], 0);
}
// then the "old-style" fini
if(h->finientry) {
uintptr_t p = h->finientry + h->delta;
printf_log(LOG_DEBUG, "Calling Fini for %s @%p\n", ElfName(h), (void*)p);
RunFunctionWithEmu(emu, 0, p, 0);
}
h->init_done = 0; // can be re-inited again...
return;
}
uintptr_t GetElfInit(elfheader_t* h)
{
return h->initentry + h->delta;
}
uintptr_t GetElfFini(elfheader_t* h)
{
return h->finientry + h->delta;
}
void* GetBaseAddress(elfheader_t* h)
{
return h->memory;
}
void* GetElfDelta(elfheader_t* h)
{
return (void*)h->delta;
}
uint32_t GetBaseSize(elfheader_t* h)
{
return h->memsz;
}
int IsAddressInElfSpace(elfheader_t* h, uintptr_t addr)
{
if(!h)
return 0;
for(int i=0; i<h->multiblock_n; ++i) {
uintptr_t base = h->multiblock_offs[i];
uintptr_t end = h->multiblock_offs[i] + h->multiblock_size[i] - 1;
if(addr>=base && addr<=end)
return 1;
}
return 0;
}
elfheader_t* FindElfAddress(box64context_t *context, uintptr_t addr)
{
for (int i=0; i<context->elfsize; ++i)
if(IsAddressInElfSpace(context->elfs[i], addr))
return context->elfs[i];
return NULL;
}
const char* FindNearestSymbolName(elfheader_t* h, void* p, uintptr_t* start, uint64_t* sz)
{
uintptr_t addr = (uintptr_t)p;
uint32_t distance = 0x7fffffff;
const char* ret = NULL;
uintptr_t s = 0;
uint64_t size = 0;
if(!h || h->fini_done)
return ret;
for (size_t i=0; i<h->numSymTab && distance!=0; ++i) {
const char * symname = h->StrTab+h->SymTab[i].st_name;
uintptr_t offs = h->SymTab[i].st_value + h->delta;
if(offs<=addr) {
if(distance>addr-offs) {
distance = addr-offs;
ret = symname;
s = offs;
size = h->SymTab[i].st_size;
}
}
}
for (size_t i=0; i<h->numDynSym && distance!=0; ++i) {
const char * symname = h->DynStr+h->DynSym[i].st_name;
uintptr_t offs = h->DynSym[i].st_value + h->delta;
if(offs<=addr) {
if(distance>addr-offs) {
distance = addr-offs;
ret = symname;
s = offs;
size = h->DynSym[i].st_size;
}
}
}
if(start)
*start = s;
if(sz)
*sz = size;
return ret;
}
const char* VersionnedName(const char* name, int ver, const char* vername)
{
if(ver==-1)
return name;
const char *v=NULL;
if(ver==0)
v="";
if(ver==1)
v="*";
if(!v && !vername)
return name;
if(ver>1)
v = vername;
char buf[strlen(name)+strlen(v)+1+1];
strcpy(buf, name);
strcat(buf, "@");
strcat(buf, v);
return AddDictionnary(my_context->versym, buf);
}
int SameVersionnedSymbol(const char* name1, int ver1, const char* vername1, const char* name2, int ver2, const char* vername2)
{
if(strcmp(name1, name2)) //name are different, no need to go further
return 0;
if(ver1==-1 || ver2==-1) // don't check version, so ok
return 1;
if(ver1==ver2 && ver1<2) // same ver (local or global), ok
return 1;
if(ver1==0 || ver2==0) // one is local, the other is not, no match
return 0;
if(ver1==1 || ver2==1) // one if global, ok
return 1;
if(!strcmp(vername1, vername2)) // same vername
return 1;
return 0;
}
void* GetDTatOffset(box64context_t* context, unsigned long int index, unsigned long int offset)
{
return (void*)((char*)GetTLSPointer(context, context->elfs[index])+offset);
}
int32_t GetTLSBase(elfheader_t* h)
{
return h->tlsbase;
}
uint32_t GetTLSSize(elfheader_t* h)
{
return h->tlssize;
}
void* GetTLSPointer(box64context_t* context, elfheader_t* h)
{
if(!h->tlssize)
return NULL;
tlsdatasize_t* ptr;
if ((ptr = (tlsdatasize_t*)pthread_getspecific(context->tlskey)) == NULL) {
ptr = (tlsdatasize_t*)fillTLSData(context);
}
if(ptr->tlssize != context->tlssize)
ptr = (tlsdatasize_t*)resizeTLSData(context, ptr);
return ptr->tlsdata+(ptr->tlssize+h->tlsbase);
}
#ifdef DYNAREC
dynablocklist_t* GetDynablocksFromAddress(box64context_t *context, uintptr_t addr)
{
(void)context;
// if we are here, the there is not block in standard "space"
/*dynablocklist_t* ret = getDBFromAddress(addr);
if(ret) {
return ret;
}*/
if(box64_dynarec_forced) {
addDBFromAddressRange(addr, 1);
return getDB(addr>>DYNAMAP_SHIFT);
}
//check if address is in an elf... if yes, grant a block (should I warn)
Dl_info info;
if(dladdr((void*)addr, &info)) {
dynarec_log(LOG_INFO, "Address %p is in a native Elf memory space (function \"%s\" in %s)\n", (void*)addr, info.dli_sname, info.dli_fname);
return NULL;
}
dynarec_log(LOG_INFO, "Address %p not found in Elf memory and is not a native call wrapper\n", (void*)addr);
return NULL;
}
#endif
typedef struct my_dl_phdr_info_s {
void* dlpi_addr;
const char* dlpi_name;
Elf64_Phdr* dlpi_phdr;
Elf64_Half dlpi_phnum;
} my_dl_phdr_info_t;
static int dl_iterate_phdr_callback(x64emu_t *emu, void* F, my_dl_phdr_info_t *info, size_t size, void* data)
{
int ret = RunFunctionWithEmu(emu, 0, (uintptr_t)F, 3, info, size, data);
return ret;
}
#define SUPER() \
GO(0) \
GO(1) \
GO(2) \
GO(3) \
GO(4)
// dl_iterate_phdr ...
#define GO(A) \
static uintptr_t my_dl_iterate_phdr_fct_##A = 0; \
static int my_dl_iterate_phdr_##A(struct dl_phdr_info* a, size_t b, void* c)\
{ \
if(!a->dlpi_name) \
return 0; \
if(!a->dlpi_name[0]) /*don't send informations about box64 itself*/ \
return 0; \
return RunFunction(my_context, my_dl_iterate_phdr_fct_##A, 3, a, b, c); \
}
SUPER()
#undef GO
static void* find_dl_iterate_phdr_Fct(void* fct)
{
if(!fct) return fct;
if(GetNativeFnc((uintptr_t)fct)) return GetNativeFnc((uintptr_t)fct);
#define GO(A) if(my_dl_iterate_phdr_fct_##A == (uintptr_t)fct) return my_dl_iterate_phdr_##A;
SUPER()
#undef GO
#define GO(A) if(my_dl_iterate_phdr_fct_##A == 0) {my_dl_iterate_phdr_fct_##A = (uintptr_t)fct; return my_dl_iterate_phdr_##A; }
SUPER()
#undef GO
printf_log(LOG_NONE, "Warning, no more slot for elfloader dl_iterate_phdr callback\n");
return NULL;
}
#undef SUPER
EXPORT int my_dl_iterate_phdr(x64emu_t *emu, void* F, void *data) {
printf_log(LOG_DEBUG, "Call to partially implemented dl_iterate_phdr(%p, %p)\n", F, data);
box64context_t *context = GetEmuContext(emu);
const char* empty = "";
int ret = 0;
for (int idx=0; idx<context->elfsize; ++idx) {
my_dl_phdr_info_t info;
info.dlpi_addr = GetElfDelta(context->elfs[idx]);
info.dlpi_name = idx?context->elfs[idx]->name:empty; //1st elf is program, and this one doesn't get a name
info.dlpi_phdr = context->elfs[idx]->PHEntries;
info.dlpi_phnum = context->elfs[idx]->numPHEntries;
if((ret = dl_iterate_phdr_callback(emu, F, &info, sizeof(info), data))) {
return ret;
}
}
// and now, go on native version
ret = dl_iterate_phdr(find_dl_iterate_phdr_Fct(F), data);
return ret;
}
void ResetSpecialCaseMainElf(elfheader_t* h)
{
Elf64_Sym *sym = NULL;
for (size_t i=0; i<h->numDynSym; ++i) {
if(h->DynSym[i].st_info == 17) {
sym = h->DynSym+i;
const char * symname = h->DynStr+sym->st_name;
if(strcmp(symname, "_IO_2_1_stderr_")==0 && ((void*)sym->st_value+h->delta)) {
memcpy((void*)sym->st_value+h->delta, stderr, sym->st_size);
my__IO_2_1_stderr_ = (void*)sym->st_value+h->delta;
printf_log(LOG_DEBUG, "BOX64: Set @_IO_2_1_stderr_ to %p\n", my__IO_2_1_stderr_);
} else
if(strcmp(symname, "_IO_2_1_stdin_")==0 && ((void*)sym->st_value+h->delta)) {
memcpy((void*)sym->st_value+h->delta, stdin, sym->st_size);
my__IO_2_1_stdin_ = (void*)sym->st_value+h->delta;
printf_log(LOG_DEBUG, "BOX64: Set @_IO_2_1_stdin_ to %p\n", my__IO_2_1_stdin_);
} else
if(strcmp(symname, "_IO_2_1_stdout_")==0 && ((void*)sym->st_value+h->delta)) {
memcpy((void*)sym->st_value+h->delta, stdout, sym->st_size);
my__IO_2_1_stdout_ = (void*)sym->st_value+h->delta;
printf_log(LOG_DEBUG, "BOX64: Set @_IO_2_1_stdout_ to %p\n", my__IO_2_1_stdout_);
} else
if(strcmp(symname, "_IO_stderr_")==0 && ((void*)sym->st_value+h->delta)) {
memcpy((void*)sym->st_value+h->delta, stderr, sym->st_size);
my__IO_2_1_stderr_ = (void*)sym->st_value+h->delta;
printf_log(LOG_DEBUG, "BOX64: Set @_IO_stderr_ to %p\n", my__IO_2_1_stderr_);
} else
if(strcmp(symname, "_IO_stdin_")==0 && ((void*)sym->st_value+h->delta)) {
memcpy((void*)sym->st_value+h->delta, stdin, sym->st_size);
my__IO_2_1_stdin_ = (void*)sym->st_value+h->delta;
printf_log(LOG_DEBUG, "BOX64: Set @_IO_stdin_ to %p\n", my__IO_2_1_stdin_);
} else
if(strcmp(symname, "_IO_stdout_")==0 && ((void*)sym->st_value+h->delta)) {
memcpy((void*)sym->st_value+h->delta, stdout, sym->st_size);
my__IO_2_1_stdout_ = (void*)sym->st_value+h->delta;
printf_log(LOG_DEBUG, "BOX64: Set @_IO_stdout_ to %p\n", my__IO_2_1_stdout_);
}
}
}
}
void CreateMemorymapFile(box64context_t* context, int fd)
{
char buff[1024];
struct stat st;
int dummy;
(void)dummy;
elfheader_t *h = context->elfs[0];
if (stat(h->path, &st)) {
printf_log(LOG_INFO, "Failed to stat file %s (creating memory maps \"file\")!", h->path);
// Some constants, to have "valid" values
st.st_dev = makedev(0x03, 0x00);
st.st_ino = 0;
}
for (size_t i=0; i<h->numPHEntries; ++i) {
if (h->PHEntries[i].p_memsz == 0) continue;
sprintf(buff, "%016lx-%016lx %c%c%c%c %016lx %02x:%02x %ld %s\n", (uintptr_t)h->PHEntries[i].p_vaddr + h->delta,
(uintptr_t)h->PHEntries[i].p_vaddr + h->PHEntries[i].p_memsz + h->delta,
(h->PHEntries[i].p_type & (PF_R|PF_X) ? 'r':'-'), (h->PHEntries[i].p_type & PF_W ? 'w':'-'),
(h->PHEntries[i].p_type & PF_X ? 'x':'-'), 'p', // p for private or s for shared
(uintptr_t)h->PHEntries[i].p_offset,
major(st.st_dev), minor(st.st_dev), st.st_ino, h->path);
dummy = write(fd, buff, strlen(buff));
}
}
void ElfAttachLib(elfheader_t* head, library_t* lib)
{
if(!head)
return;
head->lib = lib;
}
uintptr_t pltResolver = ~0LL;
EXPORT void PltResolver(x64emu_t* emu)
{
uintptr_t addr = Pop64(emu);
int slot = (int)Pop64(emu);
elfheader_t *h = (elfheader_t*)addr;
printf_dump(LOG_DEBUG, "PltResolver: Addr=%p, Slot=%d Return=%p: elf is %s (VerSym=%p)\n", (void*)addr, slot, *(void**)(R_RSP), h->name, h->VerSym);
Elf64_Rela * rel = (Elf64_Rela *)(h->jmprel + h->delta) + slot;
Elf64_Sym *sym = &h->DynSym[ELF64_R_SYM(rel->r_info)];
int bind = ELF64_ST_BIND(sym->st_info);
const char* symname = SymName(h, sym);
int version = h->VerSym?((Elf64_Half*)((uintptr_t)h->VerSym+h->delta))[ELF64_R_SYM(rel->r_info)]:-1;
if(version!=-1) version &= 0x7fff;
const char* vername = GetSymbolVersion(h, version);
uint64_t *p = (uint64_t*)(rel->r_offset + h->delta);
uintptr_t offs = 0;
uintptr_t end = 0;
library_t* lib = h->lib;
lib_t* local_maplib = GetMaplib(lib);
GetGlobalSymbolStartEnd(my_context->maplib, symname, &offs, &end, h, version, vername);
if(!offs && !end && local_maplib) {
GetGlobalSymbolStartEnd(local_maplib, symname, &offs, &end, h, version, vername);
}
if(!offs && !end && !version)
GetGlobalSymbolStartEnd(my_context->maplib, symname, &offs, &end, h, -1, NULL);
if (!offs) {
printf_log(LOG_NONE, "Error: PltResolver: Symbol %s(ver %d: %s%s%s) not found, cannot apply R_X86_64_JUMP_SLOT %p (%p) in %s\n", symname, version, symname, vername?"@":"", vername?vername:"", p, *(void**)p, h->name);
emu->quit = 1;
return;
} else {
if(p) {
printf_dump(LOG_DEBUG, " Apply %s R_X86_64_JUMP_SLOT %p with sym=%s(ver %d: %s%s%s) (%p -> %p / %s)\n", (bind==STB_LOCAL)?"Local":"Global", p, symname, version, symname, vername?"@":"", vername?vername:"",*(void**)p, (void*)offs, ElfName(FindElfAddress(my_context, offs)));
*p = offs;
} else {
printf_log(LOG_NONE, "PltResolver: Warning, Symbol %s(ver %d: %s%s%s) found, but Jump Slot Offset is NULL \n", symname, version, symname, vername?"@":"", vername?vername:"");
}
}
// jmp to function
R_RIP = offs;
}
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