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upx/src/p_lx_elf.cpp
John Reiser b8b983dded nrv2d decompressor for PackLinuxElf64amd
2006-07-17 15:02:37 -07:00

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/* p_lx_elf.cpp --
This file is part of the UPX executable compressor.
Copyright (C) 1996-2006 Markus Franz Xaver Johannes Oberhumer
Copyright (C) 1996-2006 Laszlo Molnar
Copyright (C) 2000-2006 John F. Reiser
All Rights Reserved.
UPX and the UCL library are free software; you can redistribute them
and/or modify them 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; see the file COPYING.
If not, write to the Free Software Foundation, Inc.,
59 Temple Place - Suite 330, Boston, MA 02111-1307, USA.
Markus F.X.J. Oberhumer Laszlo Molnar
<mfx@users.sourceforge.net> <ml1050@users.sourceforge.net>
John F. Reiser
<jreiser@users.sourceforge.net>
*/
#include "conf.h"
#include "file.h"
#include "filter.h"
#include "linker.h"
#include "packer.h"
#include "p_elf.h"
#include "p_unix.h"
#include "p_lx_exc.h"
#include "p_lx_elf.h"
#include "ui.h"
#define PT_LOAD32 Elf32_Phdr::PT_LOAD
#define PT_LOAD64 Elf64_Phdr::PT_LOAD
int
PackLinuxElf32::checkEhdr(Elf32_Ehdr const *ehdr) const
{
const unsigned char * const buf = ehdr->e_ident;
unsigned osabi0 = buf[Elf32_Ehdr::EI_OSABI];
if (0==osabi0) {
osabi0 = opt->o_unix.osabi0;
}
if (0!=memcmp(buf, "\x7f\x45\x4c\x46", 4) // "\177ELF"
|| buf[Elf32_Ehdr::EI_CLASS]!=ei_class
|| buf[Elf32_Ehdr::EI_DATA] !=ei_data
|| osabi0!=ei_osabi
) {
return -1;
}
if (!memcmp(buf+8, "FreeBSD", 7)) // branded
return 1;
int const type = get_native16(&ehdr->e_type);
if (type != Elf32_Ehdr::ET_EXEC && type != Elf32_Ehdr::ET_DYN)
return 2;
if (get_native16(&ehdr->e_machine) != e_machine)
return 3;
if (get_native32(&ehdr->e_version) != Elf32_Ehdr::EV_CURRENT)
return 4;
if (get_native16(&ehdr->e_phnum) < 1)
return 5;
if (get_native16(&ehdr->e_phentsize) != sizeof(Elf32_Phdr))
return 6;
// check for Linux kernels
unsigned const entry = get_native32(&ehdr->e_entry);
if (entry == 0xC0100000) // uncompressed vmlinux
return 1000;
if (entry == 0x00001000) // compressed vmlinux
return 1001;
if (entry == 0x00100000) // compressed bvmlinux
return 1002;
// FIXME: add more checks for kernels
// FIXME: add special checks for other ELF i386 formats, like
// NetBSD, OpenBSD, Solaris, ....
// success
return 0;
}
int
PackLinuxElf64::checkEhdr(Elf64_Ehdr const *ehdr) const
{
const unsigned char * const buf = ehdr->e_ident;
unsigned osabi0 = buf[Elf32_Ehdr::EI_OSABI];
if (0==osabi0) {
osabi0 = opt->o_unix.osabi0;
}
if (0!=memcmp(buf, "\x7f\x45\x4c\x46", 4) // "\177ELF"
|| buf[Elf64_Ehdr::EI_CLASS]!=ei_class
|| buf[Elf64_Ehdr::EI_DATA] !=ei_data
|| osabi0!=ei_osabi
) {
return -1;
}
if (!memcmp(buf+8, "FreeBSD", 7)) // branded
return 1;
if (get_native16(&ehdr->e_type) != Elf64_Ehdr::ET_EXEC)
return 2;
if (get_native16(&ehdr->e_machine) != e_machine)
return 3;
if (get_native32(&ehdr->e_version) != Elf64_Ehdr::EV_CURRENT)
return 4;
if (get_native16(&ehdr->e_phnum) < 1)
return 5;
if (get_native16(&ehdr->e_phentsize) != sizeof(Elf64_Phdr))
return 6;
// check for Linux kernels
acc_uint64l_t const entry = get_native64(&ehdr->e_entry);
if (entry == 0xC0100000) // uncompressed vmlinux
return 1000;
if (entry == 0x00001000) // compressed vmlinux
return 1001;
if (entry == 0x00100000) // compressed bvmlinux
return 1002;
// FIXME: add more checks for kernels
// FIXME: add special checks for other ELF i386 formats, like
// NetBSD, OpenBSD, Solaris, ....
// success
return 0;
}
PackLinuxElf::PackLinuxElf(InputFile *f)
: super(f), file_image(NULL), dynstr(NULL),
sz_phdrs(0), sz_elf_hdrs(0),
e_machine(0), ei_class(0), ei_data(0), ei_osabi(0)
{
}
PackLinuxElf::~PackLinuxElf()
{
delete[] file_image;
}
Linker *PackLinuxElf::newLinker() const
{
return new ElfLinker;
}
void PackLinuxElf::pack3(OutputFile *fo, Filter &ft)
{
unsigned disp;
unsigned const zero = 0;
unsigned len = fo->getBytesWritten();
fo->write(&zero, 3& -len); // ALIGN_UP
len += (3& -len);
set_native32(&disp, len); // FIXME? -(sz_elf_hdrs+sizeof(l_info)+sizeof(p_info))
fo->write(&disp, sizeof(disp));
sz_pack2 = 4+ len;
super::pack3(fo, ft);
}
void PackLinuxElf32::pack3(OutputFile *fo, Filter &ft)
{
super::pack3(fo, ft);
set_native32(&elfout.phdr[0].p_filesz, sz_pack2);
}
void PackLinuxElf64::pack3(OutputFile *fo, Filter &ft)
{
super::pack3(fo, ft);
set_native64(&elfout.phdr[0].p_filesz, sz_pack2);
}
void
PackLinuxElf::addStubEntrySections(Filter const *)
{
addLoader("ELFMAINX", NULL);
}
void
PackLinuxElf::addLinkerSymbols(Filter const *)
{
// empty
}
PackLinuxElf32::PackLinuxElf32(InputFile *f)
: super(f), phdri(NULL),
dynseg(NULL), hashtab(NULL), dynsym(NULL)
{
}
PackLinuxElf32::~PackLinuxElf32()
{
delete[] phdri;
}
PackLinuxElf64::PackLinuxElf64(InputFile *f)
: super(f), phdri(NULL)
{
}
PackLinuxElf64::~PackLinuxElf64()
{
delete[] phdri;
}
Linker* PackLinuxElf64amd::newLinker() const
{
return new ElfLinkerAMD64;
}
void PackLinuxElf64amd::addStubEntrySections(Filter const *)
{
addLoader("ELFMAINX", NULL);
//addLoader(getDecompressorSections(), NULL);
addLoader(
( M_IS_NRV2E(ph.method) ? "NRV_COMMON,NRV2E"
: M_IS_NRV2D(ph.method) ? "NRV_COMMON,NRV2D"
: M_IS_NRV2B(ph.method) ? "NRV_COMMON,NRV2B"
: M_IS_LZMA(ph.method) ? "LZMA_ELF00,LZMA_DEC20,LZMA_DEC30"
: NULL), NULL);
addLoader("ELFMAINY,IDENTSTR,ELFMAINZ,FOLDEXEC", NULL);
}
int const *
PackLinuxElf::getCompressionMethods(int method, int level) const
{
// No real dependency on LE32.
return Packer::getDefaultCompressionMethods_le32(method, level);
}
int const *
PackLinuxElf32armLe::getCompressionMethods(int /*method*/, int /*level*/) const
{
static const int m_nrv2e[] = { M_NRV2E_8, -1 };
return m_nrv2e;
}
int const *
PackLinuxElf32armBe::getCompressionMethods(int /*method*/, int /*level*/) const
{
static const int m_nrv2e[] = { M_NRV2E_8, -1 };
return m_nrv2e;
}
int const *
PackLinuxElf32ppc::getFilters() const
{
static const int filters[] = {
0xd0, -1
};
return filters;
}
int const *
PackLinuxElf64amd::getFilters() const
{
static const int filters[] = {
0x49, -1
};
return filters;
}
void PackLinuxElf32::patchLoader()
{
}
void PackLinuxElf64::patchLoader()
{
}
void PackLinuxElf32::updateLoader(OutputFile *fo)
{
set_native32(&elfout.ehdr.e_entry, fo->getBytesWritten() +
get_native32(&elfout.phdr[0].p_vaddr));
}
void PackLinuxElf64::updateLoader(OutputFile *fo)
{
set_native64(&elfout.ehdr.e_entry, fo->getBytesWritten() +
get_native64(&elfout.phdr[0].p_vaddr));
}
PackLinuxElf32ppc::PackLinuxElf32ppc(InputFile *f)
: super(f)
{
e_machine = Elf32_Ehdr::EM_PPC;
ei_class = Elf32_Ehdr::ELFCLASS32;
ei_data = Elf32_Ehdr::ELFDATA2MSB;
ei_osabi = Elf32_Ehdr::ELFOSABI_LINUX;
}
PackLinuxElf32ppc::~PackLinuxElf32ppc()
{
}
Linker* PackLinuxElf32ppc::newLinker() const
{
return new ElfLinkerPpc32;
}
PackLinuxElf64amd::PackLinuxElf64amd(InputFile *f)
: super(f)
{
e_machine = Elf64_Ehdr::EM_X86_64;
ei_class = Elf64_Ehdr::ELFCLASS64;
ei_data = Elf64_Ehdr::ELFDATA2LSB;
ei_osabi = Elf32_Ehdr::ELFOSABI_LINUX;
}
PackLinuxElf64amd::~PackLinuxElf64amd()
{
}
static unsigned
umax(unsigned a, unsigned b)
{
if (a <= b) {
return b;
}
return a;
}
void PackLinuxElf32x86::addStubEntrySections(Filter const *ft)
{
int const n_mru = ft->n_mru; // FIXME: belongs to filter? packerf?
// Here is a quick summary of the format of the output file:
linker->setLoaderAlignOffset(
// Elf32_Edhr
sizeof(elfout.ehdr) +
// Elf32_Phdr: 1 for exec86, 2 for sh86, 3 for elf86
(get_native16(&elfout.ehdr.e_phentsize) * get_native16(&elfout.ehdr.e_phnum)) +
// checksum UPX! lsize version format
sizeof(l_info) +
// PT_DYNAMIC with DT_NEEDED "forwarded" from original file
((get_native16(&elfout.ehdr.e_phnum)==3)
? (unsigned) get_native32(&elfout.phdr[2].p_memsz)
: 0) +
// p_progid, p_filesize, p_blocksize
sizeof(p_info) +
// compressed data
b_len + ph.c_len );
// entry to stub
addLoader("LEXEC000", NULL);
if (ft->id) {
{ // decompr, unfilter are separate
addLoader("LXUNF000", NULL);
addLoader("LXUNF002", NULL);
if (0x80==(ft->id & 0xF0)) {
if (256==n_mru) {
addLoader("MRUBYTE0", NULL);
}
else if (n_mru) {
addLoader("LXMRU005", NULL);
}
if (n_mru) {
addLoader("LXMRU006", NULL);
}
else {
addLoader("LXMRU007", NULL);
}
}
else if (0x40==(ft->id & 0xF0)) {
addLoader("LXUNF008", NULL);
}
addLoader("LXUNF010", NULL);
}
if (n_mru) {
addLoader("LEXEC009", NULL);
}
}
addLoader("LEXEC010", NULL);
addLoader(getDecompressorSections(), NULL);
addLoader("LEXEC015", NULL);
if (ft->id) {
{ // decompr, unfilter are separate
if (0x80!=(ft->id & 0xF0)) {
addLoader("LXUNF042", NULL);
}
}
addFilter32(ft->id);
{ // decompr, unfilter are separate
if (0x80==(ft->id & 0xF0)) {
if (0==n_mru) {
addLoader("LXMRU058", NULL);
}
}
addLoader("LXUNF035", NULL);
}
}
else {
addLoader("LEXEC017", NULL);
}
addLoader("IDENTSTR", NULL);
addLoader("LEXEC020", NULL);
addLoader("FOLDEXEC", NULL);
}
void PackLinuxElf32x86::addLinkerSymbols(Filter const *ft)
{
upx_byte *ptr_cto = getLoader();
int sz_cto = getLoaderSize();
if (0x20==(ft->id & 0xF0) || 0x30==(ft->id & 0xF0)) { // push byte '?' ; cto8
patch_le16(ptr_cto, sz_cto, "\x6a?", 0x6a + (ft->cto << 8));
checkPatch(NULL, 0, 0, 0); // reset
}
}
int
PackLinuxElf32::buildLinuxLoader(
upx_byte const *const proto,
unsigned const szproto,
upx_byte const *const fold,
unsigned const szfold,
Filter const *ft
)
{
initLoader(proto, szproto);
struct b_info h; memset(&h, 0, sizeof(h));
unsigned fold_hdrlen = 0;
if (0 < szfold) {
cprElfHdr1 const *const hf = (cprElfHdr1 const *)fold;
fold_hdrlen = umax(0x80, sizeof(hf->ehdr) +
get_native16(&hf->ehdr.e_phentsize) * get_native16(&hf->ehdr.e_phnum) +
sizeof(l_info) );
h.sz_unc = ((szfold < fold_hdrlen) ? 0 : (szfold - fold_hdrlen));
h.b_method = (unsigned char) ph.method; // FIXME: endian trouble
h.b_ftid = (unsigned char) ph.filter;
h.b_cto8 = (unsigned char) ph.filter_cto;
}
unsigned char const *const uncLoader = fold_hdrlen + fold;
h.sz_cpr = MemBuffer::getSizeForCompression(h.sz_unc);
unsigned char *const cprLoader = new unsigned char[sizeof(h) + h.sz_cpr];
if (0 < szfold) {
int r = upx_compress(uncLoader, h.sz_unc, sizeof(h) + cprLoader, &h.sz_cpr,
NULL, ph.method, 10, NULL, NULL );
if (r != UPX_E_OK || h.sz_cpr >= h.sz_unc)
throwInternalError("loader compression failed");
#if 0 //{ debugging only
if (M_LZMA==ph.method) {
ucl_uint tmp_len = h.sz_unc; // LZMA uses this as EOF
unsigned char *tmp = new unsigned char[tmp_len];
memset(tmp, 0, tmp_len);
r = upx_decompress(sizeof(h) + cprLoader, h.sz_cpr, tmp, &tmp_len, h.b_method, NULL);
printf("\n%d %d: %d %d %d\n", h.b_method, r, h.sz_cpr, h.sz_unc, tmp_len);
for (unsigned j=0; j < h.sz_unc; ++j) if (tmp[j]!=uncLoader[j]) {
printf("%d: %x %x\n", j, tmp[j], uncLoader[j]);
}
delete[] tmp;
}
#endif //}
}
unsigned const sz_cpr = h.sz_cpr;
set_native32(&h.sz_cpr, h.sz_cpr);
set_native32(&h.sz_unc, h.sz_unc);
memcpy(cprLoader, &h, sizeof(h));
// This adds the definition to the "library", to be used later.
linker->addSection("FOLDEXEC", cprLoader, sizeof(h) + sz_cpr, 0);
delete [] cprLoader;
addStubEntrySections(ft);
freezeLoader();
addLinkerSymbols(ft);
linker->relocate();
return getLoaderSize();
}
int
PackLinuxElf64::buildLinuxLoader(
upx_byte const *const proto,
unsigned const szproto,
upx_byte const *const fold,
unsigned const szfold,
Filter const *ft
)
{
initLoader(proto, szproto);
struct b_info h; memset(&h, 0, sizeof(h));
unsigned fold_hdrlen = 0;
if (0 < szfold) {
cprElfHdr1 const *const hf = (cprElfHdr1 const *)fold;
fold_hdrlen = umax(0x80, sizeof(hf->ehdr) +
get_native16(&hf->ehdr.e_phentsize) * get_native16(&hf->ehdr.e_phnum) +
sizeof(l_info) );
h.sz_unc = ((szfold < fold_hdrlen) ? 0 : (szfold - fold_hdrlen));
h.b_method = (unsigned char) ph.method; // FIXME: endian trouble
h.b_ftid = (unsigned char) ph.filter;
h.b_cto8 = (unsigned char) ph.filter_cto;
}
unsigned char const *const uncLoader = fold_hdrlen + fold;
h.sz_cpr = MemBuffer::getSizeForCompression(h.sz_unc);
unsigned char *const cprLoader = new unsigned char[sizeof(h) + h.sz_cpr];
if (0 < szfold) {
int r = upx_compress(uncLoader, h.sz_unc, sizeof(h) + cprLoader, &h.sz_cpr,
NULL, ph.method, 10, NULL, NULL );
if (r != UPX_E_OK || h.sz_cpr >= h.sz_unc)
throwInternalError("loader compression failed");
}
unsigned const sz_cpr = h.sz_cpr;
set_native32(&h.sz_cpr, h.sz_cpr);
set_native32(&h.sz_unc, h.sz_unc);
memcpy(cprLoader, &h, sizeof(h));
// This adds the definition to the "library", to be used later.
linker->addSection("FOLDEXEC", cprLoader, sizeof(h) + sz_cpr, 0);
delete [] cprLoader;
addStubEntrySections(ft);
freezeLoader();
addLinkerSymbols(ft);
linker->relocate();
return getLoaderSize();
}
void
PackLinuxElf64amd::addLinkerSymbols(Filter const *)
{
unsigned const hlen = sz_elf_hdrs + sizeof(l_info) + sizeof(p_info);
unsigned len = sz_pack2;
#define PAGE_MASK (~0u<<12)
#define PAGE_SIZE (-PAGE_MASK)
lsize = /*getLoaderSize()*/ 64 * 1024; // upper bound; avoid circularity
acc_uint64l_t const lo_va_user = 0x400000; // XXX
acc_uint64l_t lo_va_stub = elfout.phdr[0].p_vaddr;
acc_uint64l_t adrc;
acc_uint64l_t adrm;
acc_uint64l_t adru;
acc_uint64l_t adrx;
unsigned cntc;
unsigned lenm;
unsigned lenu;
len += (7&-lsize) + lsize;
bool const is_big = (lo_va_user < (lo_va_stub + len + 2*PAGE_SIZE));
if (is_big) {
set_native64( &elfout.ehdr.e_entry,
get_native64(&elfout.ehdr.e_entry) + lo_va_user - lo_va_stub);
set_native64(&elfout.phdr[0].p_vaddr, lo_va_user);
set_native64(&elfout.phdr[0].p_paddr, lo_va_user);
lo_va_stub = lo_va_user;
adrc = lo_va_stub;
adrm = getbrk(phdri, get_native16(&ehdri.e_phnum));
adru = PAGE_MASK & (~PAGE_MASK + adrm); // round up to page boundary
adrx = adru + hlen;
lenm = PAGE_SIZE + len;
lenu = PAGE_SIZE + len;
cntc = len >> 3;
}
else {
adrm = lo_va_stub + len;
adrc = adrm;
adru = lo_va_stub;
adrx = lo_va_stub + hlen;
lenm = PAGE_SIZE;
lenu = PAGE_SIZE + len;
cntc = 0;
}
adrm = PAGE_MASK & (~PAGE_MASK + adrm); // round up to page boundary
adrc = PAGE_MASK & (~PAGE_MASK + adrc); // round up to page boundary
//avoid circularity linker->defineSymbol("LENX", sz_pack2 - hlen);
linker->defineSymbol("ADRX", adrx); // compressed input for eXpansion
linker->defineSymbol("CNTC", cntc); // count for copy
linker->defineSymbol("LENU", lenu); // len for unmap
linker->defineSymbol("ADRC", adrc); // addr for copy
linker->defineSymbol("ADRU", adru); // addr for unmap
linker->defineSymbol("JMPU", 12 + lo_va_user); // trampoline for unmap
linker->defineSymbol("LENM", lenm); // len for map
linker->defineSymbol("ADRM", adrm); // addr for map
#undef PAGE_SIZE
#undef PAGE_MASK
}
static const
#include "stub/i386-linux.elf-entry.h"
static const
#include "stub/i386-linux.elf-fold.h"
int
PackLinuxElf32x86::buildLoader(const Filter *ft)
{
unsigned char tmp[sizeof(linux_i386elf_fold)];
memcpy(tmp, linux_i386elf_fold, sizeof(linux_i386elf_fold));
checkPatch(NULL, 0, 0, 0); // reset
if (opt->o_unix.is_ptinterp) {
unsigned j;
for (j = 0; j < sizeof(linux_i386elf_fold)-1; ++j) {
if (0x60==tmp[ j]
&& 0x47==tmp[1+j] ) {
/* put INC EDI before PUSHA: inhibits auxv_up for PT_INTERP */
tmp[ j] = 0x47;
tmp[1+j] = 0x60;
break;
}
}
}
return buildLinuxLoader(
linux_i386elf_loader, sizeof(linux_i386elf_loader),
tmp, sizeof(linux_i386elf_fold), ft );
}
static const
#include "stub/i386-bsd.elf-entry.h"
static const
#include "stub/i386-bsd.elf-fold.h"
int
PackBSDElf32x86::buildLoader(const Filter *ft)
{
unsigned char tmp[sizeof(bsd_i386elf_fold)];
memcpy(tmp, bsd_i386elf_fold, sizeof(bsd_i386elf_fold));
checkPatch(NULL, 0, 0, 0); // reset
if (opt->o_unix.is_ptinterp) {
unsigned j;
for (j = 0; j < sizeof(bsd_i386elf_fold)-1; ++j) {
if (0x60==tmp[ j]
&& 0x47==tmp[1+j] ) {
/* put INC EDI before PUSHA: inhibits auxv_up for PT_INTERP */
tmp[ j] = 0x47;
tmp[1+j] = 0x60;
break;
}
}
}
return buildLinuxLoader(
bsd_i386elf_loader, sizeof(bsd_i386elf_loader),
tmp, sizeof(bsd_i386elf_fold), ft );
}
#if 0 //{ re-use for OpenBSD, too
static const
#include "stub/i386-bsd.elf-entry.h"
#endif //}
static const
#include "stub/i386-openbsd.elf-fold.h"
int
PackOpenBSDElf32x86::buildLoader(const Filter *ft)
{
unsigned char tmp[sizeof(openbsd_i386elf_fold)];
memcpy(tmp, openbsd_i386elf_fold, sizeof(openbsd_i386elf_fold));
checkPatch(NULL, 0, 0, 0); // reset
if (opt->o_unix.is_ptinterp) {
unsigned j;
for (j = 0; j < sizeof(openbsd_i386elf_fold)-1; ++j) {
if (0x60==tmp[ j]
&& 0x47==tmp[1+j] ) {
/* put INC EDI before PUSHA: inhibits auxv_up for PT_INTERP */
tmp[ j] = 0x47;
tmp[1+j] = 0x60;
break;
}
}
}
return buildLinuxLoader(
bsd_i386elf_loader, sizeof(bsd_i386elf_loader),
tmp, sizeof(openbsd_i386elf_fold), ft );
}
static const
#include "stub/arm-linux.elf-entry.h"
static const
#include "stub/arm-linux.elf-fold.h"
#include "mem.h"
static void brev(
unsigned char *const dst,
unsigned char const *const src,
unsigned len
)
{
assert(0==(3 & len));
// Detect overlap which over-writes src before it is used.
assert(!((4+ src)<=dst && dst < (len + src)));
for (unsigned j = 0; j < len; j += 4) {
// Simple way (and somewhat slow) to allow in-place brev().
unsigned char tmp[4];
memcpy(tmp, j + src, 4);
dst[0+ j] = tmp[3];
dst[1+ j] = tmp[2];
dst[2+ j] = tmp[1];
dst[3+ j] = tmp[0];
}
}
static void
ehdr_bele(Elf_BE32_Ehdr *const ehdr_be, Elf_LE32_Ehdr const *const ehdr_le)
{
memcpy(&ehdr_be->e_ident, &ehdr_le->e_ident, sizeof(ehdr_be->e_ident));
ehdr_be->e_ident[Elf32_Ehdr::EI_DATA] = Elf32_Ehdr::ELFDATA2MSB;
ehdr_be->e_type = ehdr_le->e_type;
ehdr_be->e_machine = ehdr_le->e_machine;
ehdr_be->e_version = ehdr_le->e_version;
ehdr_be->e_entry = ehdr_le->e_entry;
ehdr_be->e_phoff = ehdr_le->e_phoff;
ehdr_be->e_shoff = ehdr_le->e_shoff;
ehdr_be->e_flags = ehdr_le->e_flags;
ehdr_be->e_ehsize = ehdr_le->e_ehsize;
ehdr_be->e_phentsize = ehdr_le->e_phentsize;
ehdr_be->e_phnum = ehdr_le->e_phnum;
ehdr_be->e_shentsize = ehdr_le->e_shentsize;
ehdr_be->e_shnum = ehdr_le->e_shnum;
ehdr_be->e_shstrndx = ehdr_le->e_shstrndx;
}
static void
ehdr_lebe(Elf_LE32_Ehdr *const ehdr_le, Elf_BE32_Ehdr const *const ehdr_be)
{
memcpy(&ehdr_le->e_ident, &ehdr_be->e_ident, sizeof(ehdr_le->e_ident));
ehdr_le->e_ident[Elf32_Ehdr::EI_DATA] = Elf32_Ehdr::ELFDATA2LSB;
ehdr_le->e_type = ehdr_be->e_type;
ehdr_le->e_machine = ehdr_be->e_machine;
ehdr_le->e_version = ehdr_be->e_version;
ehdr_le->e_entry = ehdr_be->e_entry;
ehdr_le->e_phoff = ehdr_be->e_phoff;
ehdr_le->e_shoff = ehdr_be->e_shoff;
ehdr_le->e_flags = ehdr_be->e_flags;
ehdr_le->e_ehsize = ehdr_be->e_ehsize;
ehdr_le->e_phentsize = ehdr_be->e_phentsize;
ehdr_le->e_phnum = ehdr_be->e_phnum;
ehdr_le->e_shentsize = ehdr_be->e_shentsize;
ehdr_le->e_shnum = ehdr_be->e_shnum;
ehdr_le->e_shstrndx = ehdr_be->e_shstrndx;
}
int
PackLinuxElf32armBe::buildLoader(Filter const *ft)
{
return ARM_buildLoader(ft, true);
}
int
PackLinuxElf32armLe::buildLoader(Filter const *ft)
{
return ARM_buildLoader(ft, false);
}
static const
#include "stub/powerpc-linux.elf-entry.h"
static const
#include "stub/powerpc-linux.elf-fold.h"
int
PackLinuxElf32ppc::buildLoader(const Filter *ft)
{
return buildLinuxLoader(
linux_elfppc32_loader, sizeof(linux_elfppc32_loader),
linux_elfppc32_fold, sizeof(linux_elfppc32_fold), ft );
}
void
PackLinuxElf32ppc::addStubEntrySections(Filter const *)
{
addLoader("ELFMAINX", NULL);
//addLoader(getDecompressorSections(), NULL);
addLoader(
( M_IS_NRV2E(ph.method) ? "NRV_HEAD,NRV2E,NRV_TAIL"
: M_IS_NRV2D(ph.method) ? "NRV_HEAD,NRV2D,NRV_TAIL"
: M_IS_NRV2B(ph.method) ? "NRV_HEAD,NRV2B,NRV_TAIL"
: M_IS_LZMA(ph.method) ? "LZMA_ELF00,LZMA_DEC20,LZMA_DEC30"
: NULL), NULL);
addLoader("ELFMAINY,IDENTSTR,+40,ELFMAINZ,FOLDEXEC", NULL);
}
void
PackLinuxElf32ppc::addLinkerSymbols(Filter const *)
{
// empty
}
static const
#include "stub/amd64-linux.elf-entry.h"
static const
#include "stub/amd64-linux.elf-fold.h"
int
PackLinuxElf64amd::buildLoader(const Filter *ft)
{
return buildLinuxLoader(
linux_elf64amd_loader, sizeof(linux_elf64amd_loader),
linux_elf64amd_fold, sizeof(linux_elf64amd_fold), ft );
}
bool PackLinuxElf32::canPack()
{
unsigned char buf[sizeof(Elf32_Ehdr) + 14*sizeof(Elf32_Phdr)];
COMPILE_TIME_ASSERT(sizeof(buf) <= 512);
fi->seek(0, SEEK_SET);
fi->readx(buf, sizeof(buf));
fi->seek(0, SEEK_SET);
Elf32_Ehdr const *const ehdr = (Elf32_Ehdr const *)buf;
// now check the ELF header
if (checkEhdr(ehdr) != 0)
return false;
// additional requirements for linux/elf386
if (get_native16(&ehdr->e_ehsize) != sizeof(*ehdr)) {
throwCantPack("invalid Ehdr e_ehsize; try `--force-execve'");
return false;
}
unsigned const e_phoff = get_native32(&ehdr->e_phoff);
if (e_phoff != sizeof(*ehdr)) {// Phdrs not contiguous with Ehdr
throwCantPack("non-contiguous Ehdr/Phdr; try `--force-execve'");
return false;
}
// The first PT_LOAD32 must cover the beginning of the file (0==p_offset).
unsigned const e_phnum = get_native16(&ehdr->e_phnum);
Elf32_Phdr const *phdr = (Elf32_Phdr const *)(buf + e_phoff);
for (unsigned j=0; j < e_phnum; ++phdr, ++j) {
if (j >= 14)
return false;
if (phdr->PT_LOAD32 == get_native32(&phdr->p_type)) {
if (phdr->p_offset != 0) {
throwCantPack("invalid Phdr p_offset; try `--force-execve'");
return false;
}
exetype = 1;
break;
}
}
// We want to compress position-independent executable (gcc -pie)
// main programs, but compressing a shared library must be avoided
// because the result is no longer usable. In theory, there is no way
// to tell them apart: both are just ET_DYN. Also in theory,
// neither the presence nor the absence of any particular symbol name
// can be used to tell them apart; there are counterexamples.
// However, we will use the following heuristic suggested by
// Peter S. Mazinger <ps.m@gmx.net> September 2005:
// If a ET_DYN has __libc_start_main as a global undefined symbol,
// then the file is a position-independent executable main program
// (that depends on libc.so.6) and is eligible to be compressed.
// Otherwise (no __libc_start_main as global undefined): skip it.
// Also allow __uClibc_main and __uClibc_start_main .
if (Elf32_Ehdr::ET_DYN==get_native16(&ehdr->e_type)) {
// The DT_STRTAB has no designated length. Read the whole file.
file_image = new char[file_size];
fi->seek(0, SEEK_SET);
fi->readx(file_image, file_size);
ehdri= *ehdr;
phdri= (Elf32_Phdr *)(get_native32(&ehdr->e_phoff) + file_image); // do not free() !!
int j= get_native16(&ehdr->e_phnum);
phdr= phdri;
for (; --j>=0; ++phdr) if (Elf32_Phdr::PT_DYNAMIC==get_native32(&phdr->p_type)) {
dynseg= (Elf32_Dyn const *)(get_native32(&phdr->p_offset) + file_image);
break;
}
// elf_find_dynamic() returns 0 if 0==dynseg.
hashtab= (unsigned int const *)elf_find_dynamic(Elf32_Dyn::DT_HASH);
dynstr= (char const *)elf_find_dynamic(Elf32_Dyn::DT_STRTAB);
dynsym= (Elf32_Sym const *)elf_find_dynamic(Elf32_Dyn::DT_SYMTAB);
char const *const run_start[]= {
"__libc_start_main", "__uClibc_main", "__uClibc_start_main",
};
for (j=0; j<3; ++j) {
// elf_lookup() returns 0 if any required table is missing.
Elf32_Sym const *const lsm = elf_lookup(run_start[j]);
if (lsm && get_native16(&lsm->st_shndx)==Elf32_Sym::SHN_UNDEF
&& get_native16(&lsm->st_info)==lsm->Elf32_Sym::St_info(Elf32_Sym::STB_GLOBAL, Elf32_Sym::STT_FUNC)
&& get_native16(&lsm->st_other)==Elf32_Sym::STV_DEFAULT ) {
break;
}
}
phdri = 0; // done "borrowing" this member
if (3<=j) {
return false;
}
}
// XXX Theoretically the following test should be first,
// but PackUnix::canPack() wants 0!=exetype ?
if (!super::canPack())
return false;
assert(exetype == 1);
exetype = 0;
// set options
opt->o_unix.blocksize = blocksize = file_size;
return true;
}
bool
PackLinuxElf64amd::canPack()
{
unsigned char buf[sizeof(Elf64_Ehdr) + 14*sizeof(Elf64_Phdr)];
COMPILE_TIME_ASSERT(sizeof(buf) <= 1024);
fi->readx(buf, sizeof(buf));
fi->seek(0, SEEK_SET);
Elf64_Ehdr const *const ehdr = (Elf64_Ehdr const *)buf;
// now check the ELF header
if (checkEhdr(ehdr) != 0)
return false;
// additional requirements for linux/elf386
if (get_native16(&ehdr->e_ehsize) != sizeof(*ehdr)) {
throwCantPack("invalid Ehdr e_ehsize; try `--force-execve'");
return false;
}
acc_uint64l_t const e_phoff = get_native64(&ehdr->e_phoff);
if (e_phoff != sizeof(*ehdr)) {// Phdrs not contiguous with Ehdr
throwCantPack("non-contiguous Ehdr/Phdr; try `--force-execve'");
return false;
}
// The first PT_LOAD64 must cover the beginning of the file (0==p_offset).
unsigned const e_phnum = get_native16(&ehdr->e_phnum);
Elf64_Phdr const *phdr = (Elf64_Phdr const *)(buf + e_phoff);
for (unsigned j=0; j < e_phnum; ++phdr, ++j) {
if (j >= 14)
return false;
if (phdr->PT_LOAD64 == get_native32(&phdr->p_type)) {
// Just avoid the "rewind" when unpacking?
//if (phdr->p_offset != 0) {
// throwCantPack("invalid Phdr p_offset; try `--force-execve'");
// return false;
//}
exetype = 1;
break;
}
}
if (!super::canPack())
return false;
assert(exetype == 1);
exetype = 0;
// set options
opt->o_unix.blocksize = blocksize = file_size;
return true;
}
off_t
PackLinuxElf32::getbrk(const Elf32_Phdr *phdr, int e_phnum) const
{
off_t brka = 0;
for (int j = 0; j < e_phnum; ++phdr, ++j) {
if (PT_LOAD32 == get_native32(&phdr->p_type)) {
off_t b = get_native32(&phdr->p_vaddr) + get_native32(&phdr->p_memsz);
if (b > brka)
brka = b;
}
}
return brka;
}
off_t
PackLinuxElf32::getbase(const Elf32_Phdr *phdr, int e_phnum) const
{
off_t base = ~0u;
for (int j = 0; j < e_phnum; ++phdr, ++j) {
if (phdr->PT_LOAD == phdr->p_type) {
if (phdr->p_vaddr < (unsigned) base)
base = phdr->p_vaddr;
}
}
if (0!=base) {
return base;
}
return 0x12000;
}
off_t
PackLinuxElf64::getbrk(const Elf64_Phdr *phdr, int e_phnum) const
{
off_t brka = 0;
for (int j = 0; j < e_phnum; ++phdr, ++j) {
if (PT_LOAD64 == get_native32(&phdr->p_type)) {
off_t b = get_native64(&phdr->p_vaddr) + get_native64(&phdr->p_memsz);
if (b > brka)
brka = b;
}
}
return brka;
}
void
PackLinuxElf32::generateElfHdr(
OutputFile *fo,
void const *proto,
unsigned const brka
)
{
cprElfHdr2 *const h2 = (cprElfHdr2 *)&elfout;
cprElfHdr3 *const h3 = (cprElfHdr3 *)&elfout;
memcpy(h3, proto, sizeof(*h3)); // reads beyond, but OK
h3->ehdr.e_ident[Elf32_Ehdr::EI_OSABI] = ei_osabi;
assert(get_native32(&h2->ehdr.e_phoff) == sizeof(Elf32_Ehdr));
h2->ehdr.e_shoff = 0;
assert(get_native16(&h2->ehdr.e_ehsize) == sizeof(Elf32_Ehdr));
assert(get_native16(&h2->ehdr.e_phentsize) == sizeof(Elf32_Phdr));
h2->ehdr.e_shentsize = 0;
h2->ehdr.e_shnum = 0;
h2->ehdr.e_shstrndx = 0;
#if 0 //{
unsigned identsize;
char const *const ident = getIdentstr(&identsize);
#endif //}
sz_elf_hdrs = sizeof(*h2) - sizeof(linfo); // default
set_native32(&h2->phdr[0].p_filesz, sizeof(*h2)); // + identsize;
h2->phdr[0].p_memsz = h2->phdr[0].p_filesz;
// Info for OS kernel to set the brk()
if (brka) {
#define PAGE_MASK (~0u<<12)
// linux-2.6.14 binfmt_elf.c: SIGKILL if (0==.p_memsz) on a page boundary
unsigned const brkb = brka | ((0==(~PAGE_MASK & brka)) ? 0x20 : 0);
set_native32(&h2->phdr[1].p_type, PT_LOAD32); // be sure
set_native32(&h2->phdr[1].p_offset, ~PAGE_MASK & brkb);
set_native32(&h2->phdr[1].p_vaddr, brkb);
set_native32(&h2->phdr[1].p_paddr, brkb);
h2->phdr[1].p_filesz = 0;
h2->phdr[1].p_memsz = 0;
set_native32(&h2->phdr[1].p_flags, Elf32_Phdr::PF_R | Elf32_Phdr::PF_W);
#undef PAGE_MASK
}
if (ph.format==getFormat()) {
assert(2==get_native16(&h2->ehdr.e_phnum));
set_native32(&h2->phdr[0].p_flags, ~Elf32_Phdr::PF_W & get_native32(&h2->phdr[0].p_flags));
memset(&h2->linfo, 0, sizeof(h2->linfo));
fo->write(h2, sizeof(*h2));
}
else {
assert(false); // unknown ph.format, PackLinuxElf32
}
}
void
PackOpenBSDElf32x86::generateElfHdr(
OutputFile *fo,
void const *proto,
unsigned const brka
)
{
cprElfHdr3 *const h3 = (cprElfHdr3 *)&elfout;
memcpy(h3, proto, sizeof(*h3)); // reads beyond, but OK
h3->ehdr.e_ident[Elf32_Ehdr::EI_OSABI] = ei_osabi;
assert(2==get_native16(&h3->ehdr.e_phnum));
set_native16(&h3->ehdr.e_phnum, 3);
assert(get_native32(&h3->ehdr.e_phoff) == sizeof(Elf32_Ehdr));
h3->ehdr.e_shoff = 0;
assert(get_native16(&h3->ehdr.e_ehsize) == sizeof(Elf32_Ehdr));
assert(get_native16(&h3->ehdr.e_phentsize) == sizeof(Elf32_Phdr));
h3->ehdr.e_shentsize = 0;
h3->ehdr.e_shnum = 0;
h3->ehdr.e_shstrndx = 0;
#if 0 //{
unsigned identsize;
char const *const ident = getIdentstr(&identsize);
#endif //}
sz_elf_hdrs = sizeof(*h3) - sizeof(linfo);
unsigned const note_offset = sz_elf_hdrs;
set_native32(&h3->phdr[0].p_filesz, sizeof(*h3)+sizeof(elfnote)); // + identsize;
h3->phdr[0].p_memsz = h3->phdr[0].p_filesz;
#define PAGE_MASK (~0u<<12)
unsigned const brkb = brka | ((0==(~PAGE_MASK & brka)) ? 0x20 : 0);
set_native32(&h3->phdr[1].p_type, PT_LOAD32); // be sure
set_native32(&h3->phdr[1].p_offset, ~PAGE_MASK & brkb);
set_native32(&h3->phdr[1].p_vaddr, brkb);
set_native32(&h3->phdr[1].p_paddr, brkb);
h3->phdr[1].p_filesz = 0;
h3->phdr[1].p_memsz = 0;
set_native32(&h3->phdr[1].p_flags, Elf32_Phdr::PF_R | Elf32_Phdr::PF_W);
#undef PAGE_MASK
set_native32(&h3->phdr[2].p_type, Elf32_Phdr::PT_NOTE);
set_native32(&h3->phdr[2].p_offset, note_offset);
set_native32(&h3->phdr[2].p_vaddr, note_offset);
set_native32(&h3->phdr[2].p_paddr, note_offset);
set_native32(&h3->phdr[2].p_filesz, sizeof(elfnote));
set_native32(&h3->phdr[2].p_memsz, sizeof(elfnote));
set_native32(&h3->phdr[2].p_flags, Elf32_Phdr::PF_R);
set_native32(&h3->phdr[2].p_align, 4);
set_native32(&elfnote.namesz, 8);
set_native32(&elfnote.descsz, 4);
set_native32(&elfnote.type, 1);
strcpy(elfnote.text, "OpenBSD");
elfnote.end = 0;
if (ph.format==getFormat()) {
memset(&h3->linfo, 0, sizeof(h3->linfo));
fo->write(h3, sizeof(*h3) - sizeof(h3->linfo));
fo->write(&elfnote, sizeof(elfnote));
fo->write(&h3->linfo, sizeof(h3->linfo));
}
else {
assert(false); // unknown ph.format, PackLinuxElf32
}
}
void
PackLinuxElf64::generateElfHdr(
OutputFile *fo,
void const *proto,
unsigned const brka
)
{
cprElfHdr2 *const h2 = (cprElfHdr2 *)&elfout;
cprElfHdr3 *const h3 = (cprElfHdr3 *)&elfout;
memcpy(h3, proto, sizeof(*h3)); // reads beyond, but OK
h3->ehdr.e_ident[Elf32_Ehdr::EI_OSABI] = ei_osabi;
assert(get_native32(&h2->ehdr.e_phoff) == sizeof(Elf64_Ehdr));
h2->ehdr.e_shoff = 0;
assert(get_native16(&h2->ehdr.e_ehsize) == sizeof(Elf64_Ehdr));
assert(get_native16(&h2->ehdr.e_phentsize) == sizeof(Elf64_Phdr));
h2->ehdr.e_shentsize = 0;
h2->ehdr.e_shnum = 0;
h2->ehdr.e_shstrndx = 0;
#if 0 //{
unsigned identsize;
char const *const ident = getIdentstr(&identsize);
#endif //}
sz_elf_hdrs = sizeof(*h2) - sizeof(linfo); // default
set_native64(&h2->phdr[0].p_filesz, sizeof(*h2)); // + identsize;
h2->phdr[0].p_memsz = h2->phdr[0].p_filesz;
// Info for OS kernel to set the brk()
if (brka) {
#define PAGE_MASK (~0ul<<12)
// linux-2.6.14 binfmt_elf.c: SIGKILL if (0==.p_memsz) on a page boundary
unsigned const brkb = brka | ((0==(~PAGE_MASK & brka)) ? 0x20 : 0);
set_native32(&h2->phdr[1].p_type, PT_LOAD32); // be sure
set_native64(&h2->phdr[1].p_offset, ~PAGE_MASK & brkb);
set_native64(&h2->phdr[1].p_vaddr, brkb);
set_native64(&h2->phdr[1].p_paddr, brkb);
h2->phdr[1].p_filesz = 0;
h2->phdr[1].p_memsz = 0;
#undef PAGE_MASK
}
if (ph.format==getFormat()) {
assert(2==get_native16(&h2->ehdr.e_phnum));
set_native32(&h2->phdr[0].p_flags, ~Elf64_Phdr::PF_W & get_native32(&h2->phdr[0].p_flags));
memset(&h2->linfo, 0, sizeof(h2->linfo));
fo->write(h2, sizeof(*h2));
}
else {
assert(false); // unknown ph.format, PackLinuxElf64
}
}
void PackLinuxElf32::pack1(OutputFile */*fo*/, Filter &/*ft*/)
{
fi->seek(0, SEEK_SET);
fi->readx(&ehdri, sizeof(ehdri));
unsigned const e_phoff = get_native32(&ehdri.e_phoff);
unsigned const e_phnum = get_native16(&ehdri.e_phnum);
assert(e_phoff == sizeof(Elf32_Ehdr)); // checked by canPack()
sz_phdrs = e_phnum * get_native16(&ehdri.e_phentsize);
phdri = new Elf32_Phdr[e_phnum];
fi->seek(e_phoff, SEEK_SET);
fi->readx(phdri, sz_phdrs);
progid = 0; // getRandomId(); not useful, so do not clutter
}
void PackLinuxElf32x86::pack1(OutputFile *fo, Filter &ft)
{
PackLinuxElf32::pack1(fo, ft);
generateElfHdr(fo, linux_i386elf_fold, getbrk(phdri, get_native16(&ehdri.e_phnum)) );
}
void PackBSDElf32x86::pack1(OutputFile *fo, Filter &ft)
{
PackLinuxElf32::pack1(fo, ft);
generateElfHdr(fo, bsd_i386elf_fold, getbrk(phdri, get_native16(&ehdri.e_phnum)) );
}
void PackLinuxElf32::ARM_pack1(OutputFile *fo, bool const isBE)
{
Elf32_Ehdr const *const fold = (Elf32_Ehdr const *)&linux_elf32arm_fold;
cprElfHdr3 h3;
// We need Elf32_Ehdr and Elf32_Phdr with byte gender of target.
// The stub may have been compiled differently.
if (this->ei_data==fold->e_ident[Elf32_Ehdr::EI_DATA]) {
memcpy(&h3, (void const *)linux_elf32arm_fold,
sizeof(Elf32_Ehdr) + 2*sizeof(Elf32_Phdr) );
}
else {
(isBE ? (void (*)(void *, void const *))ehdr_bele
: (void (*)(void *, void const *))ehdr_lebe)
((void *)&h3.ehdr, (void const *)linux_elf32arm_fold);
brev((unsigned char *)&h3.phdr[0],
sizeof(Elf32_Ehdr) + (unsigned char const *)&linux_elf32arm_fold,
3*sizeof(Elf32_Phdr) );
}
generateElfHdr(fo, &h3, getbrk(phdri, get_native16(&ehdri.e_phnum)) );
}
void PackLinuxElf32armLe::pack1(OutputFile *fo, Filter &ft)
{
super::pack1(fo, ft);
ARM_pack1(fo, false);
}
void PackLinuxElf32armBe::pack1(OutputFile *fo, Filter &ft) // FIXME
{
super::pack1(fo, ft);
ARM_pack1(fo, true);
}
void PackLinuxElf32ppc::pack1(OutputFile *fo, Filter &ft)
{
super::pack1(fo, ft);
generateElfHdr(fo, linux_elfppc32_fold, getbrk(phdri, get_native16(&ehdri.e_phnum)) );
}
void PackLinuxElf64::pack1(OutputFile */*fo*/, Filter &/*ft*/)
{
fi->seek(0, SEEK_SET);
fi->readx(&ehdri, sizeof(ehdri));
unsigned const e_phoff = get_native32(&ehdri.e_phoff);
unsigned const e_phnum = get_native16(&ehdri.e_phnum);
assert(e_phoff == sizeof(Elf64_Ehdr)); // checked by canPack()
sz_phdrs = e_phnum * get_native16(&ehdri.e_phentsize);
phdri = new Elf64_Phdr[e_phnum];
fi->seek(e_phoff, SEEK_SET);
fi->readx(phdri, sz_phdrs);
progid = 0; // getRandomId(); not useful, so do not clutter
}
void PackLinuxElf64amd::pack1(OutputFile *fo, Filter &ft)
{
super::pack1(fo, ft);
generateElfHdr(fo, linux_elf64amd_fold, getbrk(phdri, get_native16(&ehdri.e_phnum)) );
}
// Determine length of gap between PT_LOAD phdr[k] and closest PT_LOAD
// which follows in the file (or end-of-file). Optimize for common case
// where the PT_LOAD are adjacent ascending by .p_offset. Assume no overlap.
unsigned PackLinuxElf32::find_LOAD_gap(
Elf32_Phdr const *const phdr,
unsigned const k,
unsigned const e_phnum
)
{
if (PT_LOAD32!=get_native32(&phdr[k].p_type)) {
return 0;
}
unsigned const hi = get_native32(&phdr[k].p_offset) +
get_native32(&phdr[k].p_filesz);
unsigned lo = ph.u_file_size;
unsigned j = k;
for (;;) { // circular search, optimize for adjacent ascending
++j;
if (e_phnum==j) {
j = 0;
}
if (k==j) {
break;
}
if (PT_LOAD32==get_native32(&phdr[j].p_type)) {
unsigned const t = get_native32(&phdr[j].p_offset);
if ((t - hi) < (lo - hi)) {
lo = t;
if (hi==lo) {
break;
}
}
}
}
return lo - hi;
}
void PackLinuxElf32::pack2(OutputFile *fo, Filter &ft)
{
Extent x;
unsigned k;
// count passes, set ptload vars
uip->ui_total_passes = 0;
unsigned const e_phnum = get_native16(&ehdri.e_phnum);
for (k = 0; k < e_phnum; ++k) {
if (PT_LOAD32 == get_native32(&phdri[k].p_type)) {
uip->ui_total_passes++;
if (find_LOAD_gap(phdri, k, e_phnum)) {
uip->ui_total_passes++;
}
}
}
// compress extents
unsigned total_in = 0;
unsigned total_out = 0;
unsigned hdr_u_len = sizeof(Elf32_Ehdr) + sz_phdrs;
uip->ui_pass = 0;
ft.addvalue = 0;
int nx = 0;
for (k = 0; k < e_phnum; ++k) if (PT_LOAD32==get_native32(&phdri[k].p_type)) {
if (ft.id < 0x40) {
// FIXME: ?? ft.addvalue = phdri[k].p_vaddr;
}
x.offset = get_native32(&phdri[k].p_offset);
x.size = get_native32(&phdri[k].p_filesz);
if (0 == nx) { // 1st PT_LOAD32 must cover Ehdr at 0==p_offset
unsigned const delta = sizeof(Elf32_Ehdr) + sz_phdrs;
if (ft.id < 0x40) {
// FIXME: ?? ft.addvalue += delta;
}
x.offset += delta;
x.size -= delta;
}
// compressWithFilters() always assumes a "loader", so would
// throw NotCompressible for small .data Extents, which PowerPC
// sometimes marks as PF_X anyway. So filter only first segment.
packExtent(x, total_in, total_out,
((0==nx && (Elf32_Phdr::PF_X & get_native32(&phdri[k].p_flags)))
? &ft : 0 ), fo, hdr_u_len);
hdr_u_len = 0;
++nx;
}
for (k = 0; k < e_phnum; ++k) {
x.size = find_LOAD_gap(phdri, k, e_phnum);
if (x.size) {
x.offset = get_native32(&phdri[k].p_offset) +
get_native32(&phdri[k].p_filesz);
packExtent(x, total_in, total_out, 0, fo);
}
}
if ((off_t)total_in != file_size)
throwEOFException();
}
// Determine length of gap between PT_LOAD phdr[k] and closest PT_LOAD
// which follows in the file (or end-of-file). Optimize for common case
// where the PT_LOAD are adjacent ascending by .p_offset. Assume no overlap.
unsigned PackLinuxElf64::find_LOAD_gap(
Elf64_Phdr const *const phdr,
unsigned const k,
unsigned const e_phnum
)
{
if (PT_LOAD64!=get_native32(&phdr[k].p_type)) {
return 0;
}
unsigned const hi = get_native64(&phdr[k].p_offset) +
get_native64(&phdr[k].p_filesz);
unsigned lo = ph.u_file_size;
unsigned j = k;
for (;;) { // circular search, optimize for adjacent ascending
++j;
if (e_phnum==j) {
j = 0;
}
if (k==j) {
break;
}
if (PT_LOAD64==get_native32(&phdr[j].p_type)) {
unsigned const t = get_native64(&phdr[j].p_offset);
if ((t - hi) < (lo - hi)) {
lo = t;
if (hi==lo) {
break;
}
}
}
}
return lo - hi;
}
void PackLinuxElf64::pack2(OutputFile *fo, Filter &ft)
{
Extent x;
unsigned k;
// count passes, set ptload vars
uip->ui_total_passes = 0;
unsigned const e_phnum = get_native16(&ehdri.e_phnum);
for (k = 0; k < e_phnum; ++k) {
if (PT_LOAD64==get_native32(&phdri[k].p_type)) {
uip->ui_total_passes++;
if (find_LOAD_gap(phdri, k, e_phnum)) {
uip->ui_total_passes++;
}
}
}
// compress extents
unsigned total_in = 0;
unsigned total_out = 0;
unsigned hdr_u_len = sizeof(Elf64_Ehdr) + sz_phdrs;
uip->ui_pass = 0;
ft.addvalue = 0;
int nx = 0;
for (k = 0; k < e_phnum; ++k) if (PT_LOAD64==get_native32(&phdri[k].p_type)) {
if (ft.id < 0x40) {
// FIXME: ?? ft.addvalue = phdri[k].p_vaddr;
}
x.offset = get_native64(&phdri[k].p_offset);
x.size = get_native64(&phdri[k].p_filesz);
if (0 == nx) { // 1st PT_LOAD64 must cover Ehdr at 0==p_offset
unsigned const delta = sizeof(Elf64_Ehdr) + sz_phdrs;
if (ft.id < 0x40) {
// FIXME: ?? ft.addvalue += delta;
}
x.offset += delta;
x.size -= delta;
}
// compressWithFilters() always assumes a "loader", so would
// throw NotCompressible for small .data Extents, which PowerPC
// sometimes marks as PF_X anyway. So filter only first segment.
packExtent(x, total_in, total_out,
((0==nx && (Elf64_Phdr::PF_X & get_native64(&phdri[k].p_flags)))
? &ft : 0 ), fo, hdr_u_len);
hdr_u_len = 0;
++nx;
}
for (k = 0; k < e_phnum; ++k) {
x.size = find_LOAD_gap(phdri, k, e_phnum);
if (x.size) {
x.offset = get_native64(&phdri[k].p_offset) +
get_native64(&phdri[k].p_filesz);
packExtent(x, total_in, total_out, 0, fo);
}
}
if ((off_t)total_in != file_size)
throwEOFException();
}
#include "bele.h"
using namespace NBELE;
// Filter 0x50, 0x51 assume HostPolicy::isLE
static const int *
ARM_getFilters(bool const isBE)
{
static const int f50[] = { 0x50, -1 };
static const int f51[] = { 0x51, -1 };
if (HostPolicy::isBE ^ isBE)
return f51;
return f50;
}
const int *
PackLinuxElf32armBe::getFilters() const
{
return ARM_getFilters(true);
}
const int *
PackLinuxElf32armLe::getFilters() const
{
return ARM_getFilters(false);
}
int
PackLinuxElf32::ARM_buildLoader(const Filter *ft, bool const isBE)
{
unsigned const sz_loader = sizeof(linux_elf32arm_loader);
unsigned const sz_fold = sizeof(linux_elf32arm_fold);
// Was ARM code assembled for same endianness as the target?
bool const asm_brev = (this->ei_data
!= ((Elf32_Ehdr const *)linux_elf32arm_fold)->e_ident[Elf32_Ehdr::EI_DATA] );
MemBuffer tmp_fold(sz_fold);
memcpy(tmp_fold, linux_elf32arm_fold, sz_fold);
// 0xe3530050 is "cmp fid,#0x50" with fid .req r3
if (HostPolicy::isBE ^ isBE) { // change filter 0x50 to filter 0x51
if (HostPolicy::isBE ^ isBE ^ asm_brev) { // find 0xe3530050 big-endian
checkPatch(NULL,0,0,0); // reset
patch_be32(tmp_fold, sz_fold, "\xe3\x53\x00\x50", 0xe3530051);
checkPatch(NULL,0,0,0); // reset
}
else { // find 0xe3530050 little-endian
checkPatch(NULL,0,0,0); // reset
patch_le32(tmp_fold, sz_fold, "\x50\x00\x53\xe3", 0xe3530051);
checkPatch(NULL,0,0,0); // reset
}
}
if (!asm_brev) { // was assembled to match target
return buildLinuxLoader(linux_elf32arm_loader, sz_loader,
tmp_fold, sz_fold, ft );
}
else { // was assembled brev() from target
// linux_elf32arm_loader[] is all instructions, except for two strings
// at the end: the copyright message, and the SELinux message.
// The copyright message begins and ends with '\n', and the SELinux
// message ends with '\n'. So copy back to the third '\n' from the end,
// and apply brev() only before that point.
MemBuffer brev_loader(sz_loader);
int nl = 0;
int j;
for (j= sz_loader; --j>=0; ) {
unsigned char const c = linux_elf32arm_loader[j];
brev_loader[j] = c;
if ('\n'==c) {
if (3==++nl) {
break;
}
}
}
brev(brev_loader, linux_elf32arm_loader, j);
(isBE ? (void (*)(void *, void const *))ehdr_bele
: (void (*)(void *, void const *))ehdr_lebe)
(tmp_fold.getVoidPtr(), (void const *)linux_elf32arm_fold);
return buildLinuxLoader(brev_loader, sz_loader, tmp_fold, sz_fold, ft);
}
}
void PackLinuxElf32::ARM_pack3(OutputFile *fo, Filter &ft, bool isBE)
{
unsigned const hlen = sz_elf_hdrs + sizeof(l_info) + sizeof(p_info);
unsigned const len0 = fo->getBytesWritten();
unsigned len = len0;
unsigned const zero = 0;
fo->write(&zero, 3& -len); // align to 0 mod 4
len += (3& -len);
#define PAGE_MASK (~0u<<12)
#define PAGE_SIZE (-PAGE_MASK)
upx_byte *const p = getLoader();
lsize = getLoaderSize();
unsigned const lo_va_user = 0x8000; // XXX
unsigned lo_va_stub = get_native32(&elfout.phdr[0].p_vaddr);
unsigned adrc;
unsigned adrm;
unsigned adrx;
unsigned cntc;
unsigned lenm;
len += lsize;
bool const is_big = true;
if (is_big) {
set_native32( &elfout.ehdr.e_entry,
get_native32(&elfout.ehdr.e_entry) + lo_va_user - lo_va_stub);
set_native32(&elfout.phdr[0].p_vaddr, lo_va_user);
set_native32(&elfout.phdr[0].p_paddr, lo_va_user);
lo_va_stub = lo_va_user;
adrc = lo_va_stub;
adrm = getbrk(phdri, get_native16(&ehdri.e_phnum));
adrx = hlen + (PAGE_MASK & (~PAGE_MASK + adrm)); // round up to page boundary
lenm = PAGE_SIZE + len;
cntc = len >> 5;
}
else {
adrm = lo_va_stub + len;
adrc = adrm;
adrx = lo_va_stub + hlen;
lenm = PAGE_SIZE;
cntc = 0;
}
adrm = PAGE_MASK & (~PAGE_MASK + adrm); // round up to page boundary
adrc = PAGE_MASK & (~PAGE_MASK + adrc); // round up to page boundary
// Patch in order of descending address.
//
// Because Packer::patch_be32 is overloaded, it is impossible
// to choose the right one to initialize a pointer to function.
// Therefore, write either patch_be32 or patch_le32 literally.
//
// ::ARM_buildLoader() put the stub into native order.
// util.c::find() uses host order.
int const swap = (HostPolicy::isBE ^ isBE);
if (isBE) {
patch_be32(p,lsize, 4*swap + "ADRXXRDA", adrx); // compressed input for eXpansion
patch_be32(p,lsize, 4*swap + "LENXXNEL", len0 - hlen);
patch_be32(p,lsize, 4*swap + "CNTCCTNC", cntc); // count for copy
patch_be32(p,lsize, 4*swap + "ADRCCRDA", adrc); // addr for copy
patch_be32(p,lsize, 4*swap + "LENMMNEL", lenm); // len for map
patch_be32(p,lsize, 4*swap + "ADRMMRDA", adrm); // addr for map
}
else {
patch_le32(p,lsize, 4*swap + "ADRXXRDA", adrx); // compressed input for eXpansion
patch_le32(p,lsize, 4*swap + "LENXXNEL", len0 - hlen);
patch_le32(p,lsize, 4*swap + "CNTCCTNC", cntc); // count for copy
patch_le32(p,lsize, 4*swap + "ADRCCRDA", adrc); // addr for copy
patch_le32(p,lsize, 4*swap + "LENMMNEL", lenm); // len for map
patch_le32(p,lsize, 4*swap + "ADRMMRDA", adrm); // addr for map
}
#undef PAGE_SIZE
#undef PAGE_MASK
super::pack3(fo, ft);
}
void PackLinuxElf32armLe::pack3(OutputFile *fo, Filter &ft)
{
ARM_pack3(fo, ft, false);
}
void PackLinuxElf32armBe::pack3(OutputFile *fo, Filter &ft)
{
ARM_pack3(fo, ft, true);
}
void PackLinuxElf32::pack4(OutputFile *fo, Filter &ft)
{
overlay_offset = sz_elf_hdrs + sizeof(linfo);
unsigned const zero = 0;
unsigned len = fo->getBytesWritten();
fo->write(&zero, 3& -len); // align to 0 mod 4
len += 3& -len;
set_native32(&elfout.phdr[0].p_filesz, len);
super::pack4(fo, ft); // write PackHeader and overlay_offset
// Cannot pre-round .p_memsz. If .p_filesz < .p_memsz, then kernel
// tries to make .bss, which requires PF_W.
// But strict SELinux (or PaX, grSecurity) disallows PF_W with PF_X.
#if 0 /*{*/
#define PAGE_MASK (~0u<<12)
// pre-calculate for benefit of runtime disappearing act via munmap()
set_native32(&elfout.phdr[0].p_memsz, PAGE_MASK & (~PAGE_MASK + len));
#undef PAGE_MASK
#else /*}{*/
set_native32(&elfout.phdr[0].p_memsz, len);
#endif /*}*/
// rewrite Elf header
if (Elf32_Ehdr::ET_DYN==get_native16(&ehdri.e_type)) {
unsigned const base= get_native32(&elfout.phdr[0].p_vaddr);
set_native16(&elfout.ehdr.e_type, Elf32_Ehdr::ET_DYN);
set_native16(&elfout.ehdr.e_phnum, 1);
set_native32( &elfout.ehdr.e_entry,
get_native32(&elfout.ehdr.e_entry) - base);
set_native32(&elfout.phdr[0].p_vaddr, get_native32(&elfout.phdr[0].p_vaddr) - base);
set_native32(&elfout.phdr[0].p_paddr, get_native32(&elfout.phdr[0].p_paddr) - base);
// Strict SELinux (or PaX, grSecurity) disallows PF_W with PF_X
//elfout.phdr[0].p_flags |= Elf32_Phdr::PF_W;
}
fo->seek(0, SEEK_SET);
if (Elf32_Phdr::PT_NOTE==get_native32(&elfout.phdr[2].p_type)) {
unsigned const reloc = get_native32(&elfout.phdr[0].p_vaddr);
set_native32( &elfout.phdr[2].p_vaddr,
reloc + get_native32(&elfout.phdr[2].p_vaddr));
set_native32( &elfout.phdr[2].p_paddr,
reloc + get_native32(&elfout.phdr[2].p_paddr));
fo->rewrite(&elfout, sz_elf_hdrs);
fo->rewrite(&elfnote, sizeof(elfnote));
}
else {
fo->rewrite(&elfout, sz_elf_hdrs);
}
fo->rewrite(&linfo, sizeof(linfo));
}
void PackLinuxElf64::pack4(OutputFile *fo, Filter &ft)
{
overlay_offset = sz_elf_hdrs + sizeof(linfo);
unsigned const zero = 0;
unsigned len = fo->getBytesWritten();
fo->write(&zero, 3& -len); // align to 0 mod 4
len += 3& -len;
set_native64(&elfout.phdr[0].p_filesz, len);
super::pack4(fo, ft); // write PackHeader and overlay_offset
// Cannot pre-round .p_memsz. If .p_filesz < .p_memsz, then kernel
// tries to make .bss, which requires PF_W.
// But strict SELinux (or PaX, grSecurity) disallows PF_W with PF_X.
#if 0 /*{*/
#define PAGE_MASK (~0u<<12)
// pre-calculate for benefit of runtime disappearing act via munmap()
set_native64(&elfout.phdr[0].p_memsz, PAGE_MASK & (~PAGE_MASK + len));
#undef PAGE_MASK
#else /*}{*/
set_native64(&elfout.phdr[0].p_memsz, len);
#endif /*}*/
// rewrite Elf header
fo->seek(0, SEEK_SET);
fo->rewrite(&elfout, sz_elf_hdrs);
fo->rewrite(&linfo, sizeof(linfo));
}
void PackLinuxElf32::unpack(OutputFile *fo)
{
#define MAX_ELF_HDR 512
char bufehdr[MAX_ELF_HDR];
Elf32_Ehdr *const ehdr = (Elf32_Ehdr *)bufehdr;
Elf32_Phdr const *phdr = (Elf32_Phdr *)(1+ehdr);
unsigned szb_info = sizeof(b_info);
{
fi->seek(0, SEEK_SET);
fi->readx(bufehdr, MAX_ELF_HDR);
unsigned const e_entry = get_native32(&ehdr->e_entry);
if (e_entry < 0x401180
&& ehdr->e_machine==Elf32_Ehdr::EM_386) { /* old style, 8-byte b_info */
szb_info = 2*sizeof(unsigned);
}
}
fi->seek(overlay_offset, SEEK_SET);
p_info hbuf;
fi->readx(&hbuf, sizeof(hbuf));
unsigned orig_file_size = get_native32(&hbuf.p_filesize);
blocksize = get_native32(&hbuf.p_blocksize);
if (file_size > (off_t)orig_file_size || blocksize > orig_file_size)
throwCantUnpack("file header corrupted");
ibuf.alloc(blocksize + OVERHEAD);
b_info bhdr; memset(&bhdr, 0, sizeof(bhdr));
fi->readx(&bhdr, szb_info);
ph.u_len = get_native32(&bhdr.sz_unc);
ph.c_len = get_native32(&bhdr.sz_cpr);
ph.filter_cto = bhdr.b_cto8;
// Uncompress Ehdr and Phdrs.
fi->readx(ibuf, ph.c_len);
decompress(ibuf, (upx_byte *)ehdr, false);
unsigned total_in = 0;
unsigned total_out = 0;
unsigned c_adler = upx_adler32(NULL, 0);
unsigned u_adler = upx_adler32(NULL, 0);
// decompress PT_LOAD32
bool first_PF_X = true;
unsigned const phnum = get_native16(&ehdr->e_phnum);
fi->seek(- (off_t) (szb_info + ph.c_len), SEEK_CUR);
for (unsigned j=0; j < phnum; ++phdr, ++j) {
if (PT_LOAD32==get_native32(&phdr->p_type)) {
unsigned const filesz = get_native32(&phdr->p_filesz);
unsigned const offset = get_native32(&phdr->p_offset);
if (fo)
fo->seek(offset, SEEK_SET);
if (Elf32_Phdr::PF_X & get_native32(&phdr->p_flags)) {
unpackExtent(filesz, fo, total_in, total_out,
c_adler, u_adler, first_PF_X, szb_info);
first_PF_X = false;
}
else {
unpackExtent(filesz, fo, total_in, total_out,
c_adler, u_adler, false, szb_info);
}
}
}
phdr = (Elf32_Phdr *)(1+ehdr);
for (unsigned j = 0; j < phnum; ++j) {
unsigned const size = find_LOAD_gap(phdr, j, phnum);
if (size) {
unsigned const where = get_native32(&phdr[j].p_offset) +
get_native32(&phdr[j].p_filesz);
if (fo)
fo->seek(where, SEEK_SET);
unpackExtent(size, fo, total_in, total_out,
c_adler, u_adler, false, szb_info);
}
}
// check for end-of-file
fi->readx(&bhdr, szb_info);
unsigned const sz_unc = ph.u_len = get_native32(&bhdr.sz_unc);
if (sz_unc == 0) { // uncompressed size 0 -> EOF
// note: magic is always stored le32
unsigned const sz_cpr = get_le32(&bhdr.sz_cpr);
if (sz_cpr != UPX_MAGIC_LE32) // sz_cpr must be h->magic
throwCompressedDataViolation();
}
else { // extra bytes after end?
throwCompressedDataViolation();
}
// update header with totals
ph.c_len = total_in;
ph.u_len = total_out;
// all bytes must be written
if (total_out != orig_file_size)
throwEOFException();
// finally test the checksums
if (ph.c_adler != c_adler || ph.u_adler != u_adler)
throwChecksumError();
#undef MAX_ELF_HDR
}
void PackLinuxElf64::unpack(OutputFile *fo)
{
#define MAX_ELF_HDR 1024
char bufehdr[MAX_ELF_HDR];
Elf64_Ehdr *const ehdr = (Elf64_Ehdr *)bufehdr;
Elf64_Phdr const *phdr = (Elf64_Phdr *)(1+ehdr);
unsigned szb_info = sizeof(b_info);
{
fi->seek(0, SEEK_SET);
fi->readx(bufehdr, MAX_ELF_HDR);
acc_uint64l_t const e_entry = get_native64(&ehdr->e_entry);
if (e_entry < 0x401180
&& ehdr->e_machine==Elf64_Ehdr::EM_386) { /* old style, 8-byte b_info */
szb_info = 2*sizeof(unsigned);
}
}
fi->seek(overlay_offset, SEEK_SET);
p_info hbuf;
fi->readx(&hbuf, sizeof(hbuf));
unsigned orig_file_size = get_native32(&hbuf.p_filesize);
blocksize = get_native32(&hbuf.p_blocksize);
if (file_size > (off_t)orig_file_size || blocksize > orig_file_size)
throwCantUnpack("file header corrupted");
ibuf.alloc(blocksize + OVERHEAD);
b_info bhdr; memset(&bhdr, 0, sizeof(bhdr));
fi->readx(&bhdr, szb_info);
ph.u_len = get_native32(&bhdr.sz_unc);
ph.c_len = get_native32(&bhdr.sz_cpr);
ph.filter_cto = bhdr.b_cto8;
// Uncompress Ehdr and Phdrs.
fi->readx(ibuf, ph.c_len);
decompress(ibuf, (upx_byte *)ehdr, false);
unsigned total_in = 0;
unsigned total_out = 0;
unsigned c_adler = upx_adler32(NULL, 0);
unsigned u_adler = upx_adler32(NULL, 0);
// decompress PT_LOAD32
bool first_PF_X = true;
unsigned const phnum = get_native16(&ehdr->e_phnum);
fi->seek(- (off_t) (szb_info + ph.c_len), SEEK_CUR);
for (unsigned j=0; j < phnum; ++phdr, ++j) {
if (PT_LOAD32==get_native32(&phdr->p_type)) {
acc_uint64l_t const filesz = get_native64(&phdr->p_filesz);
acc_uint64l_t const offset = get_native64(&phdr->p_offset);
if (fo)
fo->seek(offset, SEEK_SET);
if (Elf64_Phdr::PF_X & get_native32(&phdr->p_flags)) {
unpackExtent(filesz, fo, total_in, total_out,
c_adler, u_adler, first_PF_X, szb_info);
first_PF_X = false;
}
else {
unpackExtent(filesz, fo, total_in, total_out,
c_adler, u_adler, false, szb_info);
}
}
}
phdr = (Elf64_Phdr *)(1+ehdr);
for (unsigned j = 0; j < phnum; ++j) {
unsigned const size = find_LOAD_gap(phdr, j, phnum);
if (size) {
unsigned const where = get_native64(&phdr[j].p_offset) +
get_native64(&phdr[j].p_filesz);
if (fo)
fo->seek(where, SEEK_SET);
unpackExtent(size, fo, total_in, total_out,
c_adler, u_adler, false, szb_info);
}
}
// check for end-of-file
fi->readx(&bhdr, szb_info);
unsigned const sz_unc = ph.u_len = get_native32(&bhdr.sz_unc);
if (sz_unc == 0) { // uncompressed size 0 -> EOF
// note: magic is always stored le32
unsigned const sz_cpr = get_le32(&bhdr.sz_cpr);
if (sz_cpr != UPX_MAGIC_LE32) // sz_cpr must be h->magic
throwCompressedDataViolation();
}
else { // extra bytes after end?
throwCompressedDataViolation();
}
// update header with totals
ph.c_len = total_in;
ph.u_len = total_out;
// all bytes must be written
if (total_out != orig_file_size)
throwEOFException();
// finally test the checksums
if (ph.c_adler != c_adler || ph.u_adler != u_adler)
throwChecksumError();
#undef MAX_ELF_HDR
}
/*************************************************************************
//
**************************************************************************/
PackLinuxElf32x86::PackLinuxElf32x86(InputFile *f) : super(f)
{
e_machine = Elf32_Ehdr::EM_386;
ei_class = Elf32_Ehdr::ELFCLASS32;
ei_data = Elf32_Ehdr::ELFDATA2LSB;
ei_osabi = Elf32_Ehdr::ELFOSABI_LINUX;
}
PackLinuxElf32x86::~PackLinuxElf32x86()
{
}
Linker* PackLinuxElf32x86::newLinker() const
{
return new ElfLinkerX86;
}
PackBSDElf32x86::PackBSDElf32x86(InputFile *f) : super(f)
{
e_machine = Elf32_Ehdr::EM_386;
ei_class = Elf32_Ehdr::ELFCLASS32;
ei_data = Elf32_Ehdr::ELFDATA2LSB;
}
PackBSDElf32x86::~PackBSDElf32x86()
{
}
PackFreeBSDElf32x86::PackFreeBSDElf32x86(InputFile *f) : super(f)
{
ei_osabi = Elf32_Ehdr::ELFOSABI_FREEBSD;
}
PackFreeBSDElf32x86::~PackFreeBSDElf32x86()
{
}
PackNetBSDElf32x86::PackNetBSDElf32x86(InputFile *f) : super(f)
{
ei_osabi = Elf32_Ehdr::ELFOSABI_NETBSD;
}
PackNetBSDElf32x86::~PackNetBSDElf32x86()
{
}
PackOpenBSDElf32x86::PackOpenBSDElf32x86(InputFile *f) : super(f)
{
ei_osabi = Elf32_Ehdr::ELFOSABI_OPENBSD;
}
PackOpenBSDElf32x86::~PackOpenBSDElf32x86()
{
}
int const *
PackLinuxElf32x86::getFilters() const
{
static const int filters[] = {
0x49, 0x46,
// FIXME 2002-11-11: We use stub/fold_elf86.asm, which calls the
// decompressor multiple times, and unfilter is independent of decompress.
// Currently only filters 0x49, 0x46, 0x80..0x87 can handle this;
// and 0x80..0x87 are regarded as "untested".
#if 0
0x26, 0x24, 0x11, 0x14, 0x13, 0x16, 0x25, 0x15, 0x12,
#endif
#if 0
0x83, 0x36, 0x26,
0x86, 0x80,
0x84, 0x87, 0x81,
0x82, 0x85,
0x24, 0x16, 0x13, 0x14, 0x11, 0x25, 0x15, 0x12,
#endif
-1 };
return filters;
}
PackLinuxElf32armLe::PackLinuxElf32armLe(InputFile *f) : super(f)
{
e_machine = Elf32_Ehdr::EM_ARM;
ei_class = Elf32_Ehdr::ELFCLASS32;
ei_data = Elf32_Ehdr::ELFDATA2LSB;
ei_osabi = Elf32_Ehdr::ELFOSABI_ARM;
}
PackLinuxElf32armLe::~PackLinuxElf32armLe()
{
}
PackLinuxElf32armBe::PackLinuxElf32armBe(InputFile *f) : super(f)
{
e_machine = Elf32_Ehdr::EM_ARM;
ei_class = Elf32_Ehdr::ELFCLASS32;
ei_data = Elf32_Ehdr::ELFDATA2MSB;
ei_osabi = Elf32_Ehdr::ELFOSABI_ARM;
}
PackLinuxElf32armBe::~PackLinuxElf32armBe()
{
}
unsigned
PackLinuxElf32::elf_get_offset_from_address(unsigned const addr) const
{
Elf32_Phdr const *phdr = phdri;
int j = get_native16(&ehdri.e_phnum);
for (; --j>=0; ++phdr) if (PT_LOAD32 == get_native32(&phdr->p_type)) {
unsigned const t = addr - get_native32(&phdr->p_vaddr);
if (t < get_native32(&phdr->p_filesz)) {
return t + get_native32(&phdr->p_offset);
}
}
return 0;
}
void const *
PackLinuxElf32::elf_find_dynamic(unsigned int const key) const
{
Elf32_Dyn const *dynp= dynseg;
if (dynp)
for (; Elf32_Dyn::DT_NULL!=dynp->d_tag; ++dynp) if (get_native32(&dynp->d_tag)==key) {
unsigned const t= elf_get_offset_from_address(get_native32(&dynp->d_val));
if (t) {
return t + file_image;
}
break;
}
return 0;
}
unsigned PackLinuxElf32::elf_hash(char const *p)
{
unsigned h;
for (h= 0; 0!=*p; ++p) {
h = *p + (h<<4);
{
unsigned const t = 0xf0000000u & h;
h &= ~t;
h ^= t>>24;
}
}
return h;
}
Elf32_Sym const *PackLinuxElf32::elf_lookup(char const *name) const
{
if (hashtab && dynsym && dynstr) {
unsigned const nbucket = get_native32(&hashtab[0]);
unsigned const *const buckets = &hashtab[2];
unsigned const *const chains = &buckets[nbucket];
unsigned const m = elf_hash(name) % nbucket;
unsigned si;
for (si= get_native32(&buckets[m]); 0!=si; si= get_native32(&chains[si])) {
char const *const p= dynsym[si].st_name + dynstr;
if (0==strcmp(name, p)) {
return &dynsym[si];
}
}
}
return 0;
}
void PackLinuxElf32x86::unpack(OutputFile *fo)
{
#define MAX_ELF_HDR 512
char bufehdr[MAX_ELF_HDR];
Elf32_Ehdr *const ehdr = (Elf32_Ehdr *)bufehdr;
Elf32_Phdr const *phdr = (Elf32_Phdr *)(1+ehdr);
unsigned szb_info = sizeof(b_info);
{
fi->seek(0, SEEK_SET);
fi->readx(bufehdr, MAX_ELF_HDR);
unsigned const e_entry = get_native32(&ehdr->e_entry);
unsigned const e_type = get_native16(&ehdr->e_type);
if (e_entry < 0x401180 && Elf32_Ehdr::ET_EXEC==e_type) {
// beware ET_DYN.e_entry==0x10f0 or so
/* old style, 8-byte b_info */
szb_info = 2*sizeof(unsigned);
}
}
fi->seek(overlay_offset, SEEK_SET);
p_info hbuf;
fi->readx(&hbuf, sizeof(hbuf));
unsigned orig_file_size = get_native32(&hbuf.p_filesize);
blocksize = get_native32(&hbuf.p_blocksize);
if (file_size > (off_t)orig_file_size || blocksize > orig_file_size)
throwCantUnpack("file header corrupted");
ibuf.alloc(blocksize + OVERHEAD);
b_info bhdr; memset(&bhdr, 0, sizeof(bhdr));
fi->readx(&bhdr, szb_info);
ph.u_len = get_native32(&bhdr.sz_unc);
ph.c_len = get_native32(&bhdr.sz_cpr);
ph.filter_cto = bhdr.b_cto8;
// Uncompress Ehdr and Phdrs.
fi->readx(ibuf, ph.c_len);
decompress(ibuf, (upx_byte *)ehdr, false);
unsigned total_in = 0;
unsigned total_out = 0;
unsigned c_adler = upx_adler32(NULL, 0);
unsigned u_adler = upx_adler32(NULL, 0);
// decompress PT_LOAD32
bool first_PF_X = true;
fi->seek(- (off_t) (szb_info + ph.c_len), SEEK_CUR);
unsigned const phnum = get_native16(&ehdr->e_phnum);
for (unsigned j=0; j < phnum; ++phdr, ++j) {
if (PT_LOAD32==get_native32(&phdr->p_type)) {
if (fo)
fo->seek(get_native32(&phdr->p_offset), SEEK_SET);
if (Elf32_Phdr::PF_X & phdr->p_flags) {
unpackExtent(get_native32(&phdr->p_filesz), fo, total_in, total_out,
c_adler, u_adler, first_PF_X, szb_info);
first_PF_X = false;
}
else {
unpackExtent(get_native32(&phdr->p_filesz), fo, total_in, total_out,
c_adler, u_adler, false, szb_info);
}
}
}
phdr = (Elf32_Phdr *)(1+ehdr);
for (unsigned j = 0; j < phnum; ++j) {
unsigned const size = find_LOAD_gap(phdr, j, phnum);
if (size) {
unsigned const where = get_native32(&phdr[j].p_offset) +
get_native32(&phdr[j].p_filesz);
if (fo)
fo->seek(where, SEEK_SET);
unpackExtent(size, fo, total_in, total_out,
c_adler, u_adler, false, szb_info);
}
}
// check for end-of-file
fi->readx(&bhdr, szb_info);
unsigned const sz_unc = ph.u_len = get_native32(&bhdr.sz_unc);
if (sz_unc == 0) { // uncompressed size 0 -> EOF
// note: magic is always stored le32
unsigned const sz_cpr = get_le32(&bhdr.sz_cpr);
if (sz_cpr != UPX_MAGIC_LE32) // sz_cpr must be h->magic
throwCompressedDataViolation();
}
else { // extra bytes after end?
throwCompressedDataViolation();
}
// update header with totals
ph.c_len = total_in;
ph.u_len = total_out;
// all bytes must be written
if (total_out != orig_file_size)
throwEOFException();
// finally test the checksums
if (ph.c_adler != c_adler || ph.u_adler != u_adler)
throwChecksumError();
#undef MAX_ELF_HDR
}
/*
vi:ts=4:et
*/
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