platform_bionic/linker/linker_main.cpp

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/*
* Copyright (C) 2016 The Android Open Source Project
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
* * Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* * Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in
* the documentation and/or other materials provided with the
* distribution.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
* "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
* LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS
* FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE
* COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT,
* INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING,
* BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS
* OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED
* AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY,
* OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT
* OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
* SUCH DAMAGE.
*/
#include "linker_main.h"
#include <link.h>
#include <stdlib.h>
#include <sys/auxv.h>
#include <sys/prctl.h>
#include "linker.h"
#include "linker_auxv.h"
#include "linker_cfi.h"
#include "linker_debug.h"
#include "linker_debuggerd.h"
#include "linker_gdb_support.h"
#include "linker_globals.h"
#include "linker_phdr.h"
#include "linker_relocate.h"
#include "linker_relocs.h"
Reorganize static TLS memory for ELF TLS For ELF TLS "local-exec" accesses, the static linker assumes that an executable's TLS segment is located at a statically-known offset from the thread pointer (i.e. "variant 1" for ARM and "variant 2" for x86). Because these layouts are incompatible, Bionic generally needs to allocate its TLS slots differently between different architectures. To allow per-architecture TLS slots: - Replace the TLS_SLOT_xxx enumerators with macros. New ARM slots are generally negative, while new x86 slots are generally positive. - Define a bionic_tcb struct that provides two things: - a void* raw_slots_storage[BIONIC_TLS_SLOTS] field - an inline accessor function: void*& tls_slot(size_t tpindex); For ELF TLS, it's necessary to allocate a temporary TCB (i.e. TLS slots), because the runtime linker doesn't know how large the static TLS area is until after it has loaded all of the initial solibs. To accommodate Golang, it's necessary to allocate the pthread keys at a fixed, small, positive offset from the thread pointer. This CL moves the pthread keys into bionic_tls, then allocates a single mapping per thread that looks like so: - stack guard - stack [omitted for main thread and with pthread_attr_setstack] - static TLS: - bionic_tcb [exec TLS will either precede or succeed the TCB] - bionic_tls [prefixed by the pthread keys] - [solib TLS segments will be placed here] - guard page As before, if the new mapping includes a stack, the pthread_internal_t is allocated on it. At startup, Bionic allocates a temporary bionic_tcb object on the stack, then allocates a temporary bionic_tls object using mmap. This mmap is delayed because the linker can't currently call async_safe_fatal() before relocating itself. Later, Bionic allocates a stack-less thread mapping for the main thread, and copies slots from the temporary TCB to the new TCB. (See *::copy_from_bootstrap methods.) Bug: http://b/78026329 Test: bionic unit tests Test: verify that a Golang app still works Test: verify that a Golang app crashes if bionic_{tls,tcb} are swapped Merged-In: I6543063752f4ec8ef6dc9c7f2a06ce2a18fc5af3 Change-Id: I6543063752f4ec8ef6dc9c7f2a06ce2a18fc5af3 (cherry picked from commit 1e660b70da625fcbf1e43dfae09b7b4817fa1660)
2019-01-03 11:51:30 +01:00
#include "linker_tls.h"
#include "linker_utils.h"
#include "private/KernelArgumentBlock.h"
#include "private/bionic_call_ifunc_resolver.h"
#include "private/bionic_globals.h"
#include "private/bionic_tls.h"
#include "android-base/unique_fd.h"
#include "android-base/strings.h"
#include "android-base/stringprintf.h"
#include <async_safe/log.h>
#include <bionic/libc_init_common.h>
Reorganize static TLS memory for ELF TLS For ELF TLS "local-exec" accesses, the static linker assumes that an executable's TLS segment is located at a statically-known offset from the thread pointer (i.e. "variant 1" for ARM and "variant 2" for x86). Because these layouts are incompatible, Bionic generally needs to allocate its TLS slots differently between different architectures. To allow per-architecture TLS slots: - Replace the TLS_SLOT_xxx enumerators with macros. New ARM slots are generally negative, while new x86 slots are generally positive. - Define a bionic_tcb struct that provides two things: - a void* raw_slots_storage[BIONIC_TLS_SLOTS] field - an inline accessor function: void*& tls_slot(size_t tpindex); For ELF TLS, it's necessary to allocate a temporary TCB (i.e. TLS slots), because the runtime linker doesn't know how large the static TLS area is until after it has loaded all of the initial solibs. To accommodate Golang, it's necessary to allocate the pthread keys at a fixed, small, positive offset from the thread pointer. This CL moves the pthread keys into bionic_tls, then allocates a single mapping per thread that looks like so: - stack guard - stack [omitted for main thread and with pthread_attr_setstack] - static TLS: - bionic_tcb [exec TLS will either precede or succeed the TCB] - bionic_tls [prefixed by the pthread keys] - [solib TLS segments will be placed here] - guard page As before, if the new mapping includes a stack, the pthread_internal_t is allocated on it. At startup, Bionic allocates a temporary bionic_tcb object on the stack, then allocates a temporary bionic_tls object using mmap. This mmap is delayed because the linker can't currently call async_safe_fatal() before relocating itself. Later, Bionic allocates a stack-less thread mapping for the main thread, and copies slots from the temporary TCB to the new TCB. (See *::copy_from_bootstrap methods.) Bug: http://b/78026329 Test: bionic unit tests Test: verify that a Golang app still works Test: verify that a Golang app crashes if bionic_{tls,tcb} are swapped Merged-In: I6543063752f4ec8ef6dc9c7f2a06ce2a18fc5af3 Change-Id: I6543063752f4ec8ef6dc9c7f2a06ce2a18fc5af3 (cherry picked from commit 1e660b70da625fcbf1e43dfae09b7b4817fa1660)
2019-01-03 11:51:30 +01:00
#include <bionic/pthread_internal.h>
#include <vector>
__LIBC_HIDDEN__ extern "C" void _start();
static ElfW(Addr) get_elf_exec_load_bias(const ElfW(Ehdr)* elf);
static void get_elf_base_from_phdr(const ElfW(Phdr)* phdr_table, size_t phdr_count,
ElfW(Addr)* base, ElfW(Addr)* load_bias);
static void set_bss_vma_name(soinfo* si);
void __libc_init_mte(const memtag_dynamic_entries_t* memtag_dynamic_entries, const void* phdr_start,
size_t phdr_count, uintptr_t load_bias, void* stack_top);
// These should be preserved static to avoid emitting
// RELATIVE relocations for the part of the code running
// before linker links itself.
// TODO (dimtiry): remove somain, rename solist to solist_head
static soinfo* solist;
static soinfo* sonext;
static soinfo* somain; // main process, always the one after libdl_info
static soinfo* solinker;
static soinfo* vdso; // vdso if present
void solist_add_soinfo(soinfo* si) {
sonext->next = si;
sonext = si;
}
bool solist_remove_soinfo(soinfo* si) {
soinfo *prev = nullptr, *trav;
for (trav = solist; trav != nullptr; trav = trav->next) {
if (trav == si) {
break;
}
prev = trav;
}
if (trav == nullptr) {
// si was not in solist
PRINT("name \"%s\"@%p is not in solist!", si->get_realpath(), si);
return false;
}
// prev will never be null, because the first entry in solist is
// always the static libdl_info.
CHECK(prev != nullptr);
prev->next = si->next;
if (si == sonext) {
sonext = prev;
}
return true;
}
soinfo* solist_get_head() {
return solist;
}
soinfo* solist_get_somain() {
return somain;
}
soinfo* solist_get_vdso() {
return vdso;
}
bool g_is_ldd;
int g_ld_debug_verbosity;
static std::vector<std::string> g_ld_preload_names;
static std::vector<soinfo*> g_ld_preloads;
static void parse_path(const char* path, const char* delimiters,
std::vector<std::string>* resolved_paths) {
std::vector<std::string> paths;
split_path(path, delimiters, &paths);
resolve_paths(paths, resolved_paths);
}
static void parse_LD_LIBRARY_PATH(const char* path) {
std::vector<std::string> ld_libary_paths;
parse_path(path, ":", &ld_libary_paths);
g_default_namespace.set_ld_library_paths(std::move(ld_libary_paths));
}
static void parse_LD_PRELOAD(const char* path) {
g_ld_preload_names.clear();
if (path != nullptr) {
// We have historically supported ':' as well as ' ' in LD_PRELOAD.
g_ld_preload_names = android::base::Split(path, " :");
g_ld_preload_names.erase(std::remove_if(g_ld_preload_names.begin(), g_ld_preload_names.end(),
[](const std::string& s) { return s.empty(); }),
g_ld_preload_names.end());
}
}
// An empty list of soinfos
static soinfo_list_t g_empty_list;
static void add_vdso() {
ElfW(Ehdr)* ehdr_vdso = reinterpret_cast<ElfW(Ehdr)*>(getauxval(AT_SYSINFO_EHDR));
if (ehdr_vdso == nullptr) {
return;
}
soinfo* si = soinfo_alloc(&g_default_namespace, "[vdso]", nullptr, 0, 0);
si->phdr = reinterpret_cast<ElfW(Phdr)*>(reinterpret_cast<char*>(ehdr_vdso) + ehdr_vdso->e_phoff);
si->phnum = ehdr_vdso->e_phnum;
si->base = reinterpret_cast<ElfW(Addr)>(ehdr_vdso);
si->size = phdr_table_get_load_size(si->phdr, si->phnum);
si->load_bias = get_elf_exec_load_bias(ehdr_vdso);
si->prelink_image();
si->link_image(SymbolLookupList(si), si, nullptr, nullptr);
// prevents accidental unloads...
si->set_dt_flags_1(si->get_dt_flags_1() | DF_1_NODELETE);
si->set_linked();
si->call_constructors();
vdso = si;
}
// Initializes an soinfo's link_map_head field using other fields from the
// soinfo (phdr, phnum, load_bias). The soinfo's realpath must not change after
// this function is called.
static void init_link_map_head(soinfo& info) {
auto& map = info.link_map_head;
map.l_addr = info.load_bias;
map.l_name = const_cast<char*>(info.get_realpath());
phdr_table_get_dynamic_section(info.phdr, info.phnum, info.load_bias, &map.l_ld, nullptr);
}
extern "C" int __system_properties_init(void);
struct ExecutableInfo {
std::string path;
struct stat file_stat;
const ElfW(Phdr)* phdr;
size_t phdr_count;
ElfW(Addr) entry_point;
bool should_pad_segments;
};
static ExecutableInfo get_executable_info(const char* arg_path) {
ExecutableInfo result = {};
char const* exe_path = "/proc/self/exe";
// Stat "/proc/self/exe" instead of executable_path because
// the executable could be unlinked by this point and it should
// not cause a crash (see http://b/31084669)
if (TEMP_FAILURE_RETRY(stat(exe_path, &result.file_stat) == -1)) {
// Fallback to argv[0] for the case where /proc isn't available
if (TEMP_FAILURE_RETRY(stat(arg_path, &result.file_stat) == -1)) {
async_safe_fatal("unable to stat either \"/proc/self/exe\" or \"%s\": %s",
arg_path, strerror(errno));
}
exe_path = arg_path;
}
// Path might be a symlink; we need the target so that we get the right
// linker configuration later.
char sym_path[PATH_MAX];
result.path = std::string(realpath(exe_path, sym_path) != nullptr ? sym_path : exe_path);
result.phdr = reinterpret_cast<const ElfW(Phdr)*>(getauxval(AT_PHDR));
result.phdr_count = getauxval(AT_PHNUM);
result.entry_point = getauxval(AT_ENTRY);
return result;
}
#if defined(__LP64__)
static char kFallbackLinkerPath[] = "/system/bin/linker64";
#else
static char kFallbackLinkerPath[] = "/system/bin/linker";
#endif
__printflike(1, 2)
static void __linker_error(const char* fmt, ...) {
va_list ap;
va_start(ap, fmt);
async_safe_format_fd_va_list(STDERR_FILENO, fmt, ap);
va_end(ap);
va_start(ap, fmt);
async_safe_format_log_va_list(ANDROID_LOG_FATAL, "linker", fmt, ap);
va_end(ap);
_exit(EXIT_FAILURE);
}
static void __linker_cannot_link(const char* argv0) {
__linker_error("CANNOT LINK EXECUTABLE \"%s\": %s\n",
argv0,
linker_get_error_buffer());
}
// Load an executable. Normally the kernel has already loaded the executable when the linker
// starts. The linker can be invoked directly on an executable, though, and then the linker must
// load it. This function doesn't load dependencies or resolve relocations.
static ExecutableInfo load_executable(const char* orig_path) {
ExecutableInfo result = {};
if (orig_path[0] != '/') {
__linker_error("error: expected absolute path: \"%s\"\n", orig_path);
}
off64_t file_offset;
android::base::unique_fd fd(open_executable(orig_path, &file_offset, &result.path));
if (fd.get() == -1) {
__linker_error("error: unable to open file \"%s\"\n", orig_path);
}
if (TEMP_FAILURE_RETRY(fstat(fd.get(), &result.file_stat)) == -1) {
__linker_error("error: unable to stat \"%s\": %s\n", result.path.c_str(), strerror(errno));
}
ElfReader elf_reader;
if (!elf_reader.Read(result.path.c_str(), fd.get(), file_offset, result.file_stat.st_size)) {
__linker_error("error: %s\n", linker_get_error_buffer());
}
address_space_params address_space;
if (!elf_reader.Load(&address_space)) {
__linker_error("error: %s\n", linker_get_error_buffer());
}
result.phdr = elf_reader.loaded_phdr();
result.phdr_count = elf_reader.phdr_count();
result.entry_point = elf_reader.entry_point();
result.should_pad_segments = elf_reader.should_pad_segments();
return result;
}
static void platform_properties_init() {
#if defined(__aarch64__)
const unsigned long hwcap2 = getauxval(AT_HWCAP2);
g_platform_properties.bti_supported = (hwcap2 & HWCAP2_BTI) != 0;
#endif
}
static ElfW(Addr) linker_main(KernelArgumentBlock& args, const char* exe_to_load) {
ProtectedDataGuard guard;
#if TIMING
struct timeval t0, t1;
gettimeofday(&t0, 0);
#endif
// Sanitize the environment.
__libc_init_AT_SECURE(args.envp);
// Initialize system properties
__system_properties_init(); // may use 'environ'
// Initialize platform properties.
platform_properties_init();
// Register the debuggerd signal handler.
linker_debuggerd_init();
g_linker_logger.ResetState();
// Enable debugging logs?
const char* LD_DEBUG = getenv("LD_DEBUG");
if (LD_DEBUG != nullptr) {
g_ld_debug_verbosity = atoi(LD_DEBUG);
}
if (getenv("LD_SHOW_AUXV") != nullptr) ld_show_auxv(args.auxv);
#if defined(__LP64__)
INFO("[ Android dynamic linker (64-bit) ]");
#else
INFO("[ Android dynamic linker (32-bit) ]");
#endif
// These should have been sanitized by __libc_init_AT_SECURE, but the test
// doesn't cost us anything.
const char* ldpath_env = nullptr;
const char* ldpreload_env = nullptr;
if (!getauxval(AT_SECURE)) {
ldpath_env = getenv("LD_LIBRARY_PATH");
if (ldpath_env != nullptr) {
INFO("[ LD_LIBRARY_PATH set to \"%s\" ]", ldpath_env);
}
ldpreload_env = getenv("LD_PRELOAD");
if (ldpreload_env != nullptr) {
INFO("[ LD_PRELOAD set to \"%s\" ]", ldpreload_env);
}
}
const ExecutableInfo exe_info = exe_to_load ? load_executable(exe_to_load) :
get_executable_info(args.argv[0]);
INFO("[ Linking executable \"%s\" ]", exe_info.path.c_str());
// Initialize the main exe's soinfo.
soinfo* si = soinfo_alloc(&g_default_namespace,
exe_info.path.c_str(), &exe_info.file_stat,
0, RTLD_GLOBAL);
somain = si;
si->phdr = exe_info.phdr;
si->phnum = exe_info.phdr_count;
si->set_should_pad_segments(exe_info.should_pad_segments);
get_elf_base_from_phdr(si->phdr, si->phnum, &si->base, &si->load_bias);
si->size = phdr_table_get_load_size(si->phdr, si->phnum);
si->dynamic = nullptr;
si->set_main_executable();
init_link_map_head(*si);
set_bss_vma_name(si);
// Use the executable's PT_INTERP string as the solinker filename in the
// dynamic linker's module list. gdb reads both PT_INTERP and the module list,
// and if the paths for the linker are different, gdb will report that the
// PT_INTERP linker path was unloaded once the module list is initialized.
// There are three situations to handle:
// - the APEX linker (/system/bin/linker[64] -> /apex/.../linker[64])
// - the ASAN linker (/system/bin/linker_asan[64] -> /apex/.../linker[64])
// - the bootstrap linker (/system/bin/bootstrap/linker[64])
const char *interp = phdr_table_get_interpreter_name(somain->phdr, somain->phnum,
somain->load_bias);
if (interp == nullptr) {
// This case can happen if the linker attempts to execute itself
// (e.g. "linker64 /system/bin/linker64").
interp = kFallbackLinkerPath;
}
solinker->set_realpath(interp);
init_link_map_head(*solinker);
#if defined(__aarch64__)
if (exe_to_load == nullptr) {
// Kernel does not add PROT_BTI to executable pages of the loaded ELF.
// Apply appropriate protections here if it is needed.
auto note_gnu_property = GnuPropertySection(somain);
if (note_gnu_property.IsBTICompatible() &&
(phdr_table_protect_segments(somain->phdr, somain->phnum, somain->load_bias,
somain->should_pad_segments(), &note_gnu_property) < 0)) {
__linker_error("error: can't protect segments for \"%s\": %s", exe_info.path.c_str(),
strerror(errno));
}
}
#endif
// Register the main executable and the linker upfront to have
// gdb aware of them before loading the rest of the dependency
// tree.
//
// gdb expects the linker to be in the debug shared object list.
// Without this, gdb has trouble locating the linker's ".text"
// and ".plt" sections. Gdb could also potentially use this to
// relocate the offset of our exported 'rtld_db_dlactivity' symbol.
//
insert_link_map_into_debug_map(&si->link_map_head);
insert_link_map_into_debug_map(&solinker->link_map_head);
add_vdso();
ElfW(Ehdr)* elf_hdr = reinterpret_cast<ElfW(Ehdr)*>(si->base);
// For security reasons we dropped non-PIE support in API level 21,
// and the NDK no longer supports earlier API levels.
if (elf_hdr->e_type != ET_DYN) {
__linker_error("error: %s: Android only supports position-independent "
"executables (-fPIE)\n", exe_info.path.c_str());
}
// Use LD_LIBRARY_PATH and LD_PRELOAD (but only if we aren't setuid/setgid).
parse_LD_LIBRARY_PATH(ldpath_env);
parse_LD_PRELOAD(ldpreload_env);
std::vector<android_namespace_t*> namespaces = init_default_namespaces(exe_info.path.c_str());
if (!si->prelink_image()) __linker_cannot_link(g_argv[0]);
// add somain to global group
si->set_dt_flags_1(si->get_dt_flags_1() | DF_1_GLOBAL);
// ... and add it to all other linked namespaces
for (auto linked_ns : namespaces) {
if (linked_ns != &g_default_namespace) {
linked_ns->add_soinfo(somain);
somain->add_secondary_namespace(linked_ns);
}
}
linker_setup_exe_static_tls(g_argv[0]);
// Load ld_preloads and dependencies.
std::vector<const char*> needed_library_name_list;
size_t ld_preloads_count = 0;
for (const auto& ld_preload_name : g_ld_preload_names) {
needed_library_name_list.push_back(ld_preload_name.c_str());
++ld_preloads_count;
}
for_each_dt_needed(si, [&](const char* name) {
needed_library_name_list.push_back(name);
});
const char** needed_library_names = &needed_library_name_list[0];
size_t needed_libraries_count = needed_library_name_list.size();
if (needed_libraries_count > 0 &&
!find_libraries(&g_default_namespace,
si,
needed_library_names,
needed_libraries_count,
nullptr,
&g_ld_preloads,
ld_preloads_count,
RTLD_GLOBAL,
nullptr,
true /* add_as_children */,
&namespaces)) {
__linker_cannot_link(g_argv[0]);
} else if (needed_libraries_count == 0) {
if (!si->link_image(SymbolLookupList(si), si, nullptr, nullptr)) {
__linker_cannot_link(g_argv[0]);
}
si->increment_ref_count();
}
// Exit early for ldd. We don't want to run the code that was loaded, so skip
// the constructor calls. Skip CFI setup because it would call __cfi_init in
// libdl.so.
if (g_is_ldd) _exit(EXIT_SUCCESS);
#if defined(__aarch64__)
// This has to happen after the find_libraries, which will have collected any possible
// libraries that request memtag_stack in the dynamic section.
__libc_init_mte(somain->memtag_dynamic_entries(), somain->phdr, somain->phnum, somain->load_bias,
args.argv);
#endif
linker_finalize_static_tls();
Reorganize static TLS memory for ELF TLS For ELF TLS "local-exec" accesses, the static linker assumes that an executable's TLS segment is located at a statically-known offset from the thread pointer (i.e. "variant 1" for ARM and "variant 2" for x86). Because these layouts are incompatible, Bionic generally needs to allocate its TLS slots differently between different architectures. To allow per-architecture TLS slots: - Replace the TLS_SLOT_xxx enumerators with macros. New ARM slots are generally negative, while new x86 slots are generally positive. - Define a bionic_tcb struct that provides two things: - a void* raw_slots_storage[BIONIC_TLS_SLOTS] field - an inline accessor function: void*& tls_slot(size_t tpindex); For ELF TLS, it's necessary to allocate a temporary TCB (i.e. TLS slots), because the runtime linker doesn't know how large the static TLS area is until after it has loaded all of the initial solibs. To accommodate Golang, it's necessary to allocate the pthread keys at a fixed, small, positive offset from the thread pointer. This CL moves the pthread keys into bionic_tls, then allocates a single mapping per thread that looks like so: - stack guard - stack [omitted for main thread and with pthread_attr_setstack] - static TLS: - bionic_tcb [exec TLS will either precede or succeed the TCB] - bionic_tls [prefixed by the pthread keys] - [solib TLS segments will be placed here] - guard page As before, if the new mapping includes a stack, the pthread_internal_t is allocated on it. At startup, Bionic allocates a temporary bionic_tcb object on the stack, then allocates a temporary bionic_tls object using mmap. This mmap is delayed because the linker can't currently call async_safe_fatal() before relocating itself. Later, Bionic allocates a stack-less thread mapping for the main thread, and copies slots from the temporary TCB to the new TCB. (See *::copy_from_bootstrap methods.) Bug: http://b/78026329 Test: bionic unit tests Test: verify that a Golang app still works Test: verify that a Golang app crashes if bionic_{tls,tcb} are swapped Merged-In: I6543063752f4ec8ef6dc9c7f2a06ce2a18fc5af3 Change-Id: I6543063752f4ec8ef6dc9c7f2a06ce2a18fc5af3 (cherry picked from commit 1e660b70da625fcbf1e43dfae09b7b4817fa1660)
2019-01-03 11:51:30 +01:00
__libc_init_main_thread_final();
if (!get_cfi_shadow()->InitialLinkDone(solist)) __linker_cannot_link(g_argv[0]);
si->call_pre_init_constructors();
si->call_constructors();
#if TIMING
gettimeofday(&t1, nullptr);
PRINT("LINKER TIME: %s: %d microseconds", g_argv[0],
static_cast<int>(((static_cast<long long>(t1.tv_sec) * 1000000LL) +
static_cast<long long>(t1.tv_usec)) -
((static_cast<long long>(t0.tv_sec) * 1000000LL) +
static_cast<long long>(t0.tv_usec))));
#endif
#if STATS
print_linker_stats();
#endif
#if TIMING || STATS
fflush(stdout);
#endif
// We are about to hand control over to the executable loaded. We don't want
// to leave dirty pages behind unnecessarily.
purge_unused_memory();
ElfW(Addr) entry = exe_info.entry_point;
TRACE("[ Ready to execute \"%s\" @ %p ]", si->get_realpath(), reinterpret_cast<void*>(entry));
return entry;
}
/* Compute the load-bias of an existing executable. This shall only
* be used to compute the load bias of an executable or shared library
* that was loaded by the kernel itself.
*
* Input:
* elf -> address of ELF header, assumed to be at the start of the file.
* Return:
* load bias, i.e. add the value of any p_vaddr in the file to get
* the corresponding address in memory.
*/
static ElfW(Addr) get_elf_exec_load_bias(const ElfW(Ehdr)* elf) {
ElfW(Addr) offset = elf->e_phoff;
const ElfW(Phdr)* phdr_table =
reinterpret_cast<const ElfW(Phdr)*>(reinterpret_cast<uintptr_t>(elf) + offset);
const ElfW(Phdr)* phdr_end = phdr_table + elf->e_phnum;
for (const ElfW(Phdr)* phdr = phdr_table; phdr < phdr_end; phdr++) {
if (phdr->p_type == PT_LOAD) {
return reinterpret_cast<ElfW(Addr)>(elf) + phdr->p_offset - phdr->p_vaddr;
}
}
return 0;
}
/* Find the load bias and base address of an executable or shared object loaded
* by the kernel. The ELF file's PHDR table must have a PT_PHDR entry.
*
* A VDSO doesn't have a PT_PHDR entry in its PHDR table.
*/
static void get_elf_base_from_phdr(const ElfW(Phdr)* phdr_table, size_t phdr_count,
ElfW(Addr)* base, ElfW(Addr)* load_bias) {
for (size_t i = 0; i < phdr_count; ++i) {
if (phdr_table[i].p_type == PT_PHDR) {
*load_bias = reinterpret_cast<ElfW(Addr)>(phdr_table) - phdr_table[i].p_vaddr;
*base = reinterpret_cast<ElfW(Addr)>(phdr_table) - phdr_table[i].p_offset;
return;
}
}
async_safe_fatal("Could not find a PHDR: broken executable?");
}
/*
* Set anonymous VMA name for .bss section. For DSOs loaded by the linker, this
* is done by ElfReader. This function is here for DSOs loaded by the kernel,
* namely the linker itself and the main executable.
*/
static void set_bss_vma_name(soinfo* si) {
for (size_t i = 0; i < si->phnum; ++i) {
auto phdr = &si->phdr[i];
if (phdr->p_type != PT_LOAD) {
continue;
}
ElfW(Addr) seg_start = phdr->p_vaddr + si->load_bias;
ElfW(Addr) seg_page_end = page_end(seg_start + phdr->p_memsz);
ElfW(Addr) seg_file_end = page_end(seg_start + phdr->p_filesz);
if (seg_page_end > seg_file_end) {
prctl(PR_SET_VMA, PR_SET_VMA_ANON_NAME,
reinterpret_cast<void*>(seg_file_end), seg_page_end - seg_file_end,
".bss");
}
}
}
#if defined(USE_RELA)
using RelType = ElfW(Rela);
const unsigned kRelTag = DT_RELA;
const unsigned kRelSzTag = DT_RELASZ;
#else
using RelType = ElfW(Rel);
const unsigned kRelTag = DT_REL;
const unsigned kRelSzTag = DT_RELSZ;
#endif
extern __LIBC_HIDDEN__ ElfW(Ehdr) __ehdr_start;
static void call_ifunc_resolvers_for_section(RelType* begin, RelType* end) {
auto ehdr = reinterpret_cast<ElfW(Addr)>(&__ehdr_start);
for (RelType *r = begin; r != end; ++r) {
if (ELFW(R_TYPE)(r->r_info) != R_GENERIC_IRELATIVE) {
continue;
}
ElfW(Addr)* offset = reinterpret_cast<ElfW(Addr)*>(ehdr + r->r_offset);
#if defined(USE_RELA)
ElfW(Addr) resolver = ehdr + r->r_addend;
#else
ElfW(Addr) resolver = ehdr + *offset;
#endif
*offset = __bionic_call_ifunc_resolver(resolver);
}
}
static void relocate_linker() {
// The linker should only have relative relocations (in RELR) and IRELATIVE
// relocations. Find the IRELATIVE relocations using the DT_JMPREL and
// DT_PLTRELSZ, or DT_RELA/DT_RELASZ (DT_REL/DT_RELSZ on ILP32).
auto ehdr = reinterpret_cast<ElfW(Addr)>(&__ehdr_start);
auto* phdr = reinterpret_cast<ElfW(Phdr)*>(ehdr + __ehdr_start.e_phoff);
for (size_t i = 0; i != __ehdr_start.e_phnum; ++i) {
if (phdr[i].p_type != PT_DYNAMIC) {
continue;
}
auto *dyn = reinterpret_cast<ElfW(Dyn)*>(ehdr + phdr[i].p_vaddr);
ElfW(Addr) relr = 0, relrsz = 0, pltrel = 0, pltrelsz = 0, rel = 0, relsz = 0;
for (size_t j = 0, size = phdr[i].p_filesz / sizeof(ElfW(Dyn)); j != size; ++j) {
const auto tag = dyn[j].d_tag;
const auto val = dyn[j].d_un.d_ptr;
// We don't currently handle IRELATIVE relocations in DT_ANDROID_REL[A].
// We disabled DT_ANDROID_REL[A] at build time; verify that it was actually disabled.
CHECK(tag != DT_ANDROID_REL && tag != DT_ANDROID_RELA);
if (tag == DT_RELR || tag == DT_ANDROID_RELR) {
relr = val;
} else if (tag == DT_RELRSZ || tag == DT_ANDROID_RELRSZ) {
relrsz = val;
} else if (tag == DT_JMPREL) {
pltrel = val;
} else if (tag == DT_PLTRELSZ) {
pltrelsz = val;
} else if (tag == kRelTag) {
rel = val;
} else if (tag == kRelSzTag) {
relsz = val;
}
}
// Apply RELR relocations first so that the GOT is initialized for ifunc
// resolvers.
if (relr && relrsz) {
relocate_relr(reinterpret_cast<ElfW(Relr*)>(ehdr + relr),
reinterpret_cast<ElfW(Relr*)>(ehdr + relr + relrsz), ehdr);
}
if (pltrel && pltrelsz) {
call_ifunc_resolvers_for_section(reinterpret_cast<RelType*>(ehdr + pltrel),
reinterpret_cast<RelType*>(ehdr + pltrel + pltrelsz));
}
if (rel && relsz) {
call_ifunc_resolvers_for_section(reinterpret_cast<RelType*>(ehdr + rel),
reinterpret_cast<RelType*>(ehdr + rel + relsz));
}
}
}
// Usable before ifunc resolvers have been called. This function is compiled with -ffreestanding.
static void linker_memclr(void* dst, size_t cnt) {
for (size_t i = 0; i < cnt; ++i) {
reinterpret_cast<char*>(dst)[i] = '\0';
}
}
// Detect an attempt to run the linker on itself. e.g.:
// /system/bin/linker64 /system/bin/linker64
// Use priority-1 to run this constructor before other constructors.
__attribute__((constructor(1))) static void detect_self_exec() {
// Normally, the linker initializes the auxv global before calling its
// constructors. If the linker loads itself, though, the first loader calls
// the second loader's constructors before calling __linker_init.
if (__libc_shared_globals()->auxv != nullptr) {
return;
}
#if defined(__i386__)
// We don't have access to the auxv struct from here, so use the int 0x80
// fallback.
__libc_sysinfo = reinterpret_cast<void*>(__libc_int0x80);
#endif
__linker_error("error: linker cannot load itself\n");
}
static ElfW(Addr) __attribute__((noinline))
__linker_init_post_relocation(KernelArgumentBlock& args, soinfo& linker_so);
/*
* This is the entry point for the linker, called from begin.S. This
* method is responsible for fixing the linker's own relocations, and
* then calling __linker_init_post_relocation().
*
* Because this method is called before the linker has fixed it's own
* relocations, any attempt to reference an extern variable, extern
* function, or other GOT reference will generate a segfault.
*/
extern "C" ElfW(Addr) __linker_init(void* raw_args) {
// Unlock the loader mutex immediately before transferring to the executable's
// entry point. This must happen after destructors are called in this function
// (e.g. ~soinfo), so declare this variable very early.
struct DlMutexUnlocker {
~DlMutexUnlocker() { pthread_mutex_unlock(&g_dl_mutex); }
} unlocker;
// Initialize TLS early so system calls and errno work.
KernelArgumentBlock args(raw_args);
bionic_tcb temp_tcb __attribute__((uninitialized));
linker_memclr(&temp_tcb, sizeof(temp_tcb));
Reorganize static TLS memory for ELF TLS For ELF TLS "local-exec" accesses, the static linker assumes that an executable's TLS segment is located at a statically-known offset from the thread pointer (i.e. "variant 1" for ARM and "variant 2" for x86). Because these layouts are incompatible, Bionic generally needs to allocate its TLS slots differently between different architectures. To allow per-architecture TLS slots: - Replace the TLS_SLOT_xxx enumerators with macros. New ARM slots are generally negative, while new x86 slots are generally positive. - Define a bionic_tcb struct that provides two things: - a void* raw_slots_storage[BIONIC_TLS_SLOTS] field - an inline accessor function: void*& tls_slot(size_t tpindex); For ELF TLS, it's necessary to allocate a temporary TCB (i.e. TLS slots), because the runtime linker doesn't know how large the static TLS area is until after it has loaded all of the initial solibs. To accommodate Golang, it's necessary to allocate the pthread keys at a fixed, small, positive offset from the thread pointer. This CL moves the pthread keys into bionic_tls, then allocates a single mapping per thread that looks like so: - stack guard - stack [omitted for main thread and with pthread_attr_setstack] - static TLS: - bionic_tcb [exec TLS will either precede or succeed the TCB] - bionic_tls [prefixed by the pthread keys] - [solib TLS segments will be placed here] - guard page As before, if the new mapping includes a stack, the pthread_internal_t is allocated on it. At startup, Bionic allocates a temporary bionic_tcb object on the stack, then allocates a temporary bionic_tls object using mmap. This mmap is delayed because the linker can't currently call async_safe_fatal() before relocating itself. Later, Bionic allocates a stack-less thread mapping for the main thread, and copies slots from the temporary TCB to the new TCB. (See *::copy_from_bootstrap methods.) Bug: http://b/78026329 Test: bionic unit tests Test: verify that a Golang app still works Test: verify that a Golang app crashes if bionic_{tls,tcb} are swapped Merged-In: I6543063752f4ec8ef6dc9c7f2a06ce2a18fc5af3 Change-Id: I6543063752f4ec8ef6dc9c7f2a06ce2a18fc5af3 (cherry picked from commit 1e660b70da625fcbf1e43dfae09b7b4817fa1660)
2019-01-03 11:51:30 +01:00
__libc_init_main_thread_early(args, &temp_tcb);
// When the linker is run by itself (rather than as an interpreter for
// another program), AT_BASE is 0.
ElfW(Addr) linker_addr = getauxval(AT_BASE);
if (linker_addr == 0) {
// The AT_PHDR and AT_PHNUM aux values describe this linker instance, so use
// the phdr to find the linker's base address.
ElfW(Addr) load_bias;
get_elf_base_from_phdr(
reinterpret_cast<ElfW(Phdr)*>(getauxval(AT_PHDR)), getauxval(AT_PHNUM),
&linker_addr, &load_bias);
}
ElfW(Ehdr)* elf_hdr = reinterpret_cast<ElfW(Ehdr)*>(linker_addr);
ElfW(Phdr)* phdr = reinterpret_cast<ElfW(Phdr)*>(linker_addr + elf_hdr->e_phoff);
// Relocate the linker. This step will initialize the GOT, which is needed for
// accessing non-hidden global variables. (On some targets, the stack
// protector uses GOT accesses rather than TLS.) Relocating the linker will
// also call the linker's ifunc resolvers so that string.h functions can be
// used.
relocate_linker();
soinfo tmp_linker_so(nullptr, nullptr, nullptr, 0, 0);
tmp_linker_so.base = linker_addr;
tmp_linker_so.size = phdr_table_get_load_size(phdr, elf_hdr->e_phnum);
tmp_linker_so.load_bias = get_elf_exec_load_bias(elf_hdr);
tmp_linker_so.dynamic = nullptr;
tmp_linker_so.phdr = phdr;
tmp_linker_so.phnum = elf_hdr->e_phnum;
tmp_linker_so.set_linker_flag();
if (!tmp_linker_so.prelink_image()) __linker_cannot_link(args.argv[0]);
if (!tmp_linker_so.link_image(SymbolLookupList(&tmp_linker_so), &tmp_linker_so, nullptr, nullptr)) __linker_cannot_link(args.argv[0]);
return __linker_init_post_relocation(args, tmp_linker_so);
}
/*
* This code is called after the linker has linked itself and fixed its own
* GOT. It is safe to make references to externs and other non-local data at
* this point. The compiler sometimes moves GOT references earlier in a
* function, so avoid inlining this function (http://b/80503879).
*/
static ElfW(Addr) __attribute__((noinline))
__linker_init_post_relocation(KernelArgumentBlock& args, soinfo& tmp_linker_so) {
// Finish initializing the main thread.
__libc_init_main_thread_late();
// We didn't protect the linker's RELRO pages in link_image because we
// couldn't make system calls on x86 at that point, but we can now...
if (!tmp_linker_so.protect_relro()) __linker_cannot_link(args.argv[0]);
// And we can set VMA name for the bss section now
set_bss_vma_name(&tmp_linker_so);
// Initialize the linker's static libc's globals
__libc_init_globals();
// A constructor could spawn a thread that calls into the loader, so as soon
// as we've called a constructor, we need to hold the lock until transferring
// to the entry point.
pthread_mutex_lock(&g_dl_mutex);
// Initialize the linker's own global variables
tmp_linker_so.call_constructors();
// Setting the linker soinfo's soname can allocate heap memory, so delay it until here.
for (const ElfW(Dyn)* d = tmp_linker_so.dynamic; d->d_tag != DT_NULL; ++d) {
if (d->d_tag == DT_SONAME) {
tmp_linker_so.set_soname(tmp_linker_so.get_string(d->d_un.d_val));
}
}
// When the linker is run directly rather than acting as PT_INTERP, parse
// arguments and determine the executable to load. When it's instead acting
// as PT_INTERP, AT_ENTRY will refer to the loaded executable rather than the
// linker's _start.
const char* exe_to_load = nullptr;
if (getauxval(AT_ENTRY) == reinterpret_cast<uintptr_t>(&_start)) {
if (args.argc == 3 && !strcmp(args.argv[1], "--list")) {
// We're being asked to behave like ldd(1).
g_is_ldd = true;
exe_to_load = args.argv[2];
} else if (args.argc <= 1 || !strcmp(args.argv[1], "--help")) {
async_safe_format_fd(STDOUT_FILENO,
"Usage: %s [--list] PROGRAM [ARGS-FOR-PROGRAM...]\n"
" %s [--list] path.zip!/PROGRAM [ARGS-FOR-PROGRAM...]\n"
"\n"
"A helper program for linking dynamic executables. Typically, the kernel loads\n"
"this program because it's the PT_INTERP of a dynamic executable.\n"
"\n"
"This program can also be run directly to load and run a dynamic executable. The\n"
"executable can be inside a zip file if it's stored uncompressed and at a\n"
"page-aligned offset.\n"
"\n"
"The --list option gives behavior equivalent to ldd(1) on other systems.\n",
args.argv[0], args.argv[0]);
_exit(EXIT_SUCCESS);
} else {
exe_to_load = args.argv[1];
__libc_shared_globals()->initial_linker_arg_count = 1;
}
}
// store argc/argv/envp to use them for calling constructors
g_argc = args.argc - __libc_shared_globals()->initial_linker_arg_count;
g_argv = args.argv + __libc_shared_globals()->initial_linker_arg_count;
g_envp = args.envp;
__libc_shared_globals()->init_progname = g_argv[0];
// Initialize static variables. Note that in order to
// get correct libdl_info we need to call constructors
// before get_libdl_info().
sonext = solist = solinker = get_libdl_info(tmp_linker_so);
g_default_namespace.add_soinfo(solinker);
ElfW(Addr) start_address = linker_main(args, exe_to_load);
INFO("[ Jumping to _start (%p)... ]", reinterpret_cast<void*>(start_address));
// Return the address that the calling assembly stub should jump to.
return start_address;
}