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android / platform / bionic / ea11be0cc / . / tests / dlfcn_test.cpp
blob: d815dba5eb61de6117f120e9ae0eba5c710324f6 [file] [log] [blame]
/*
* Copyright (C) 2012 The Android Open Source Project
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
#include <gtest/gtest.h>
#include <dlfcn.h>
#include <limits.h>
#include <stdio.h>
#include <stdint.h>
#include <string.h>
#if __has_include(<sys/auxv.h>)
#include <sys/auxv.h>
#endif
#include <sys/user.h>
#include <string>
#include <thread>
#include <android-base/file.h>
#include <android-base/scopeguard.h>
#include "gtest_globals.h"
#include "gtest_utils.h"
#include "dlfcn_symlink_support.h"
#include "utils.h"
#if defined(__BIONIC__) && (defined(__arm__) || defined(__i386__))
#pragma clang diagnostic push
#pragma clang diagnostic ignored "-Wunused-parameter"
#include <llvm/ADT/StringRef.h>
#include <llvm/Object/Binary.h>
#include <llvm/Object/ELFObjectFile.h>
#include <llvm/Object/ObjectFile.h>
#pragma clang diagnostic pop
#endif // defined(__ANDROID__) && (defined(__arm__) || defined(__i386__))
// Declared manually because the macro definitions in <elf.h> conflict with LLVM headers.
#ifdef __arm__
typedef uintptr_t _Unwind_Ptr;
extern "C" _Unwind_Ptr dl_unwind_find_exidx(_Unwind_Ptr, int*);
#endif
#define ASSERT_SUBSTR(needle, haystack) \
ASSERT_PRED_FORMAT2(::testing::IsSubstring, needle, haystack)
static bool g_called = false;
extern "C" void DlSymTestFunction() {
g_called = true;
}
static int g_ctor_function_called = 0;
static int g_ctor_argc = 0;
static char** g_ctor_argv = reinterpret_cast<char**>(0xDEADBEEF);
static char** g_ctor_envp = g_ctor_envp;
extern "C" void ctor_function(int argc, char** argv, char** envp) __attribute__ ((constructor));
extern "C" void ctor_function(int argc, char** argv, char** envp) {
g_ctor_function_called = 17;
g_ctor_argc = argc;
g_ctor_argv = argv;
g_ctor_envp = envp;
}
TEST(dlfcn, ctor_function_call) {
ASSERT_EQ(17, g_ctor_function_called);
ASSERT_TRUE(g_ctor_argc = GetArgc());
ASSERT_TRUE(g_ctor_argv = GetArgv());
ASSERT_TRUE(g_ctor_envp = GetEnvp());
}
TEST(dlfcn, dlsym_in_executable) {
dlerror(); // Clear any pending errors.
void* self = dlopen(nullptr, RTLD_NOW);
ASSERT_TRUE(self != nullptr);
ASSERT_TRUE(dlerror() == nullptr);
void* sym = dlsym(self, "DlSymTestFunction");
ASSERT_TRUE(sym != nullptr);
void (*function)() = reinterpret_cast<void(*)()>(sym);
g_called = false;
function();
ASSERT_TRUE(g_called);
ASSERT_EQ(0, dlclose(self));
}
TEST(dlfcn, dlsym_from_sofile) {
void* handle = dlopen("libtest_dlsym_from_this.so", RTLD_LAZY | RTLD_LOCAL);
ASSERT_TRUE(handle != nullptr) << dlerror();
// check that we can't find '_test_dlsym_symbol' via dlsym(RTLD_DEFAULT)
void* symbol = dlsym(RTLD_DEFAULT, "test_dlsym_symbol");
ASSERT_TRUE(symbol == nullptr);
ASSERT_SUBSTR("undefined symbol: test_dlsym_symbol", dlerror());
typedef int* (*fn_t)();
fn_t lookup_dlsym_symbol_using_RTLD_DEFAULT =
reinterpret_cast<fn_t>(dlsym(handle, "lookup_dlsym_symbol_using_RTLD_DEFAULT"));
ASSERT_TRUE(lookup_dlsym_symbol_using_RTLD_DEFAULT != nullptr) << dlerror();
int* ptr = lookup_dlsym_symbol_using_RTLD_DEFAULT();
ASSERT_TRUE(ptr != nullptr) << dlerror();
ASSERT_EQ(42, *ptr);
fn_t lookup_dlsym_symbol2_using_RTLD_DEFAULT =
reinterpret_cast<fn_t>(dlsym(handle, "lookup_dlsym_symbol2_using_RTLD_DEFAULT"));
ASSERT_TRUE(lookup_dlsym_symbol2_using_RTLD_DEFAULT != nullptr) << dlerror();
ptr = lookup_dlsym_symbol2_using_RTLD_DEFAULT();
ASSERT_TRUE(ptr != nullptr) << dlerror();
ASSERT_EQ(44, *ptr);
fn_t lookup_dlsym_symbol_using_RTLD_NEXT =
reinterpret_cast<fn_t>(dlsym(handle, "lookup_dlsym_symbol_using_RTLD_NEXT"));
ASSERT_TRUE(lookup_dlsym_symbol_using_RTLD_NEXT != nullptr) << dlerror();
ptr = lookup_dlsym_symbol_using_RTLD_NEXT();
ASSERT_TRUE(ptr != nullptr) << dlerror();
ASSERT_EQ(43, *ptr);
dlclose(handle);
}
TEST(dlfcn, dlsym_from_sofile_with_preload) {
void* preload = dlopen("libtest_dlsym_from_this_grandchild.so", RTLD_NOW | RTLD_LOCAL);
ASSERT_TRUE(preload != nullptr) << dlerror();
void* handle = dlopen("libtest_dlsym_from_this.so", RTLD_NOW | RTLD_LOCAL);
ASSERT_TRUE(handle != nullptr) << dlerror();
// check that we can't find '_test_dlsym_symbol' via dlsym(RTLD_DEFAULT)
void* symbol = dlsym(RTLD_DEFAULT, "test_dlsym_symbol");
ASSERT_TRUE(symbol == nullptr);
ASSERT_SUBSTR("undefined symbol: test_dlsym_symbol", dlerror());
typedef int* (*fn_t)();
fn_t lookup_dlsym_symbol_using_RTLD_DEFAULT =
reinterpret_cast<fn_t>(dlsym(handle, "lookup_dlsym_symbol_using_RTLD_DEFAULT"));
ASSERT_TRUE(lookup_dlsym_symbol_using_RTLD_DEFAULT != nullptr) << dlerror();
int* ptr = lookup_dlsym_symbol_using_RTLD_DEFAULT();
ASSERT_TRUE(ptr != nullptr) << dlerror();
ASSERT_EQ(42, *ptr);
fn_t lookup_dlsym_symbol2_using_RTLD_DEFAULT =
reinterpret_cast<fn_t>(dlsym(handle, "lookup_dlsym_symbol2_using_RTLD_DEFAULT"));
ASSERT_TRUE(lookup_dlsym_symbol2_using_RTLD_DEFAULT != nullptr) << dlerror();
ptr = lookup_dlsym_symbol2_using_RTLD_DEFAULT();
ASSERT_TRUE(ptr != nullptr) << dlerror();
ASSERT_EQ(44, *ptr);
fn_t lookup_dlsym_symbol_using_RTLD_NEXT =
reinterpret_cast<fn_t>(dlsym(handle, "lookup_dlsym_symbol_using_RTLD_NEXT"));
ASSERT_TRUE(lookup_dlsym_symbol_using_RTLD_NEXT != nullptr) << dlerror();
ptr = lookup_dlsym_symbol_using_RTLD_NEXT();
ASSERT_TRUE(ptr != nullptr) << dlerror();
ASSERT_EQ(43, *ptr);
dlclose(handle);
dlclose(preload);
}
TEST(dlfcn, dlsym_handle_global_sym) {
// check that we do not look into global group
// when looking up symbol by handle
void* handle = dlopen("libtest_empty.so", RTLD_NOW);
dlopen("libtest_with_dependency.so", RTLD_NOW | RTLD_GLOBAL);
void* sym = dlsym(handle, "getRandomNumber");
ASSERT_TRUE(sym == nullptr);
ASSERT_SUBSTR("undefined symbol: getRandomNumber", dlerror());
sym = dlsym(handle, "DlSymTestFunction");
ASSERT_TRUE(sym == nullptr);
ASSERT_SUBSTR("undefined symbol: DlSymTestFunction", dlerror());
dlclose(handle);
}
TEST(dlfcn, dlsym_handle_empty_symbol) {
// check that dlsym of an empty symbol fails (see http://b/33530622)
void* handle = dlopen("libtest_dlsym_from_this.so", RTLD_NOW);
ASSERT_TRUE(handle != nullptr) << dlerror();
void* sym = dlsym(handle, "");
ASSERT_TRUE(sym == nullptr);
ASSERT_SUBSTR("undefined symbol: ", dlerror());
dlclose(handle);
}
TEST(dlfcn, dlsym_with_dependencies) {
void* handle = dlopen("libtest_with_dependency.so", RTLD_NOW);
ASSERT_TRUE(handle != nullptr);
dlerror();
// This symbol is in DT_NEEDED library.
void* sym = dlsym(handle, "getRandomNumber");
ASSERT_TRUE(sym != nullptr) << dlerror();
int (*fn)(void);
fn = reinterpret_cast<int (*)(void)>(sym);
EXPECT_EQ(4, fn());
dlclose(handle);
}
TEST(dlfcn, dlopen_noload) {
void* handle = dlopen("libtest_simple.so", RTLD_NOW | RTLD_NOLOAD);
ASSERT_TRUE(handle == nullptr);
handle = dlopen("libtest_simple.so", RTLD_NOW);
void* handle2 = dlopen("libtest_simple.so", RTLD_NOW | RTLD_NOLOAD);
ASSERT_TRUE(handle != nullptr);
ASSERT_TRUE(handle2 != nullptr);
ASSERT_TRUE(handle == handle2);
ASSERT_EQ(0, dlclose(handle));
ASSERT_EQ(0, dlclose(handle2));
}
TEST(dlfcn, dlopen_by_soname) {
static const char* soname = "libdlext_test_soname.so";
static const char* filename = "libdlext_test_different_soname.so";
// 1. Make sure there is no library with soname in default search path
void* handle = dlopen(soname, RTLD_NOW);
ASSERT_TRUE(handle == nullptr);
// 2. Load a library using filename
handle = dlopen(filename, RTLD_NOW);
ASSERT_TRUE(handle != nullptr) << dlerror();
// 3. Find library by soname
void* handle_soname = dlopen(soname, RTLD_NOW | RTLD_NOLOAD);
ASSERT_TRUE(handle_soname != nullptr) << dlerror();
ASSERT_EQ(handle, handle_soname);
// 4. RTLD_NOLOAD should still work with filename
void* handle_filename = dlopen(filename, RTLD_NOW | RTLD_NOLOAD);
ASSERT_TRUE(handle_filename != nullptr) << dlerror();
ASSERT_EQ(handle, handle_filename);
dlclose(handle_filename);
dlclose(handle_soname);
dlclose(handle);
}
TEST(dlfcn, dlopen_vdso) {
#if __has_include(<sys/auxv.h>)
if (getauxval(AT_SYSINFO_EHDR) == 0) {
GTEST_SKIP() << "getauxval(AT_SYSINFO_EHDR) == 0, skipping this test";
}
#endif
const char* vdso_name = "linux-vdso.so.1";
#if defined(__i386__)
vdso_name = "linux-gate.so.1";
#endif
void* handle = dlopen(vdso_name, RTLD_NOW);
ASSERT_TRUE(handle != nullptr) << dlerror();
dlclose(handle);
}
// mips doesn't support ifuncs
#if !defined(__mips__)
TEST(dlfcn, ifunc_variable) {
typedef const char* (*fn_ptr)();
// ifunc's choice depends on whether IFUNC_CHOICE has a value
// first check the set case
setenv("IFUNC_CHOICE", "set", 1);
// preload libtest_ifunc_variable_impl.so
void* handle_impl = dlopen("libtest_ifunc_variable_impl.so", RTLD_NOW);
void* handle = dlopen("libtest_ifunc_variable.so", RTLD_NOW);
ASSERT_TRUE(handle != nullptr) << dlerror();
const char** foo_ptr = reinterpret_cast<const char**>(dlsym(handle, "foo"));
fn_ptr foo_library_ptr = reinterpret_cast<fn_ptr>(dlsym(handle, "foo_library"));
ASSERT_TRUE(foo_ptr != nullptr) << dlerror();
ASSERT_TRUE(foo_library_ptr != nullptr) << dlerror();
ASSERT_EQ(strncmp("set", *foo_ptr, 3), 0);
ASSERT_EQ(strncmp("set", foo_library_ptr(), 3), 0);
dlclose(handle);
dlclose(handle_impl);
// then check the unset case
unsetenv("IFUNC_CHOICE");
handle_impl = dlopen("libtest_ifunc_variable_impl.so", RTLD_NOW);
handle = dlopen("libtest_ifunc_variable.so", RTLD_NOW);
ASSERT_TRUE(handle != nullptr) << dlerror();
foo_ptr = reinterpret_cast<const char**>(dlsym(handle, "foo"));
foo_library_ptr = reinterpret_cast<fn_ptr>(dlsym(handle, "foo_library"));
ASSERT_TRUE(foo_ptr != nullptr) << dlerror();
ASSERT_TRUE(foo_library_ptr != nullptr) << dlerror();
ASSERT_EQ(strncmp("unset", *foo_ptr, 5), 0);
ASSERT_EQ(strncmp("unset", foo_library_ptr(), 5), 0);
dlclose(handle);
dlclose(handle_impl);
}
TEST(dlfcn, ifunc) {
typedef const char* (*fn_ptr)();
// ifunc's choice depends on whether IFUNC_CHOICE has a value
// first check the set case
setenv("IFUNC_CHOICE", "set", 1);
void* handle = dlopen("libtest_ifunc.so", RTLD_NOW);
ASSERT_TRUE(handle != nullptr) << dlerror();
fn_ptr foo_ptr = reinterpret_cast<fn_ptr>(dlsym(handle, "foo"));
fn_ptr foo_library_ptr = reinterpret_cast<fn_ptr>(dlsym(handle, "foo_library"));
ASSERT_TRUE(foo_ptr != nullptr) << dlerror();
ASSERT_TRUE(foo_library_ptr != nullptr) << dlerror();
ASSERT_EQ(strncmp("set", foo_ptr(), 3), 0);
ASSERT_EQ(strncmp("set", foo_library_ptr(), 3), 0);
dlclose(handle);
// then check the unset case
unsetenv("IFUNC_CHOICE");
handle = dlopen("libtest_ifunc.so", RTLD_NOW);
ASSERT_TRUE(handle != nullptr) << dlerror();
foo_ptr = reinterpret_cast<fn_ptr>(dlsym(handle, "foo"));
foo_library_ptr = reinterpret_cast<fn_ptr>(dlsym(handle, "foo_library"));
ASSERT_TRUE(foo_ptr != nullptr) << dlerror();
ASSERT_TRUE(foo_library_ptr != nullptr) << dlerror();
ASSERT_EQ(strncmp("unset", foo_ptr(), 5), 0);
ASSERT_EQ(strncmp("unset", foo_library_ptr(), 5), 0);
dlclose(handle);
}
TEST(dlfcn, ifunc_ctor_call) {
typedef const char* (*fn_ptr)();
void* handle = dlopen("libtest_ifunc.so", RTLD_NOW);
ASSERT_TRUE(handle != nullptr) << dlerror();
fn_ptr is_ctor_called = reinterpret_cast<fn_ptr>(dlsym(handle, "is_ctor_called_irelative"));
ASSERT_TRUE(is_ctor_called != nullptr) << dlerror();
ASSERT_STREQ("false", is_ctor_called());
is_ctor_called = reinterpret_cast<fn_ptr>(dlsym(handle, "is_ctor_called_jump_slot"));
ASSERT_TRUE(is_ctor_called != nullptr) << dlerror();
ASSERT_STREQ("true", is_ctor_called());
dlclose(handle);
}
TEST(dlfcn, ifunc_ctor_call_rtld_lazy) {
typedef const char* (*fn_ptr)();
void* handle = dlopen("libtest_ifunc.so", RTLD_LAZY);
ASSERT_TRUE(handle != nullptr) << dlerror();
fn_ptr is_ctor_called = reinterpret_cast<fn_ptr>(dlsym(handle, "is_ctor_called_irelative"));
ASSERT_TRUE(is_ctor_called != nullptr) << dlerror();
ASSERT_STREQ("false", is_ctor_called());
is_ctor_called = reinterpret_cast<fn_ptr>(dlsym(handle, "is_ctor_called_jump_slot"));
ASSERT_TRUE(is_ctor_called != nullptr) << dlerror();
ASSERT_STREQ("true", is_ctor_called());
dlclose(handle);
}
#endif
TEST(dlfcn, dlopen_check_relocation_dt_needed_order) {
// This is the structure of the test library and
// its dt_needed libraries
// libtest_relo_check_dt_needed_order.so
// |
// +-> libtest_relo_check_dt_needed_order_1.so
// |
// +-> libtest_relo_check_dt_needed_order_2.so
//
// The root library references relo_test_get_answer_lib - which is defined
// in both dt_needed libraries, the correct relocation should
// use the function defined in libtest_relo_check_dt_needed_order_1.so
void* handle = nullptr;
auto guard = android::base::make_scope_guard([&]() { dlclose(handle); });
handle = dlopen("libtest_relo_check_dt_needed_order.so", RTLD_NOW);
ASSERT_TRUE(handle != nullptr) << dlerror();
typedef int (*fn_t) (void);
fn_t fn = reinterpret_cast<fn_t>(dlsym(handle, "relo_test_get_answer"));
ASSERT_TRUE(fn != nullptr) << dlerror();
ASSERT_EQ(1, fn());
}
TEST(dlfcn, dlopen_check_order_dlsym) {
// Here is how the test library and its dt_needed
// libraries are arranged
//
// libtest_check_order_children.so
// |
// +-> ..._1_left.so
// | |
// | +-> ..._a.so
// | |
// | +-> ...r_b.so
// |
// +-> ..._2_right.so
// | |
// | +-> ..._d.so
// | |
// | +-> ..._b.so
// |
// +-> ..._3_c.so
//
// load order should be (1, 2, 3, a, b, d)
//
// get_answer() is defined in (2, 3, a, b, c)
// get_answer2() is defined in (b, d)
void* sym = dlsym(RTLD_DEFAULT, "check_order_dlsym_get_answer");
ASSERT_TRUE(sym == nullptr);
void* handle = dlopen("libtest_check_order_dlsym.so", RTLD_NOW | RTLD_GLOBAL);
ASSERT_TRUE(handle != nullptr) << dlerror();
typedef int (*fn_t) (void);
fn_t fn, fn2;
fn = reinterpret_cast<fn_t>(dlsym(RTLD_DEFAULT, "check_order_dlsym_get_answer"));
ASSERT_TRUE(fn != nullptr) << dlerror();
fn2 = reinterpret_cast<fn_t>(dlsym(RTLD_DEFAULT, "check_order_dlsym_get_answer2"));
ASSERT_TRUE(fn2 != nullptr) << dlerror();
ASSERT_EQ(42, fn());
ASSERT_EQ(43, fn2());
dlclose(handle);
}
TEST(dlfcn, dlopen_check_order_reloc_siblings) {
// This is how this one works:
// we lookup and call get_answer which is defined in '_2.so'
// and in turn calls external get_answer_impl() defined in _1.so and in '_[a-f].so'
// the correct _impl() is implemented by '_a.so';
//
// Note that this is test for RTLD_LOCAL (TODO: test for GLOBAL?)
//
// Here is the picture:
//
// libtest_check_order_reloc_siblings.so
// |
// +-> ..._1.so <- empty
// | |
// | +-> ..._a.so <- exports correct answer_impl()
// | |
// | +-> ..._b.so <- every other letter exporting incorrect one.
// |
// +-> ..._2.so <- empty
// | |
// | +-> ..._c.so
// | |
// | +-> ..._d.so
// |
// +-> ..._3.so <- empty
// |
// +-> ..._e.so
// |
// +-> ..._f.so <- exports get_answer() that calls get_anser_impl();
// implements incorrect get_answer_impl()
void* handle = dlopen("libtest_check_order_reloc_siblings.so", RTLD_NOW | RTLD_NOLOAD);
ASSERT_TRUE(handle == nullptr);
#ifdef __BIONIC__
// TODO: glibc returns nullptr on dlerror() here. Is it bug?
ASSERT_STREQ("dlopen failed: library \"libtest_check_order_reloc_siblings.so\" wasn't loaded and RTLD_NOLOAD prevented it", dlerror());
#endif
handle = dlopen("libtest_check_order_reloc_siblings.so", RTLD_NOW | RTLD_LOCAL);
ASSERT_TRUE(handle != nullptr) << dlerror();
typedef int (*fn_t) (void);
fn_t fn = reinterpret_cast<fn_t>(dlsym(handle, "check_order_reloc_get_answer"));
ASSERT_TRUE(fn != nullptr) << dlerror();
ASSERT_EQ(42, fn());
ASSERT_EQ(0, dlclose(handle));
}
TEST(dlfcn, dlopen_check_order_reloc_siblings_with_preload) {
// This test uses the same library as dlopen_check_order_reloc_siblings.
// Unlike dlopen_check_order_reloc_siblings it preloads
// libtest_check_order_reloc_siblings_1.so (first dependency) prior to
// dlopen(libtest_check_order_reloc_siblings.so)
void* handle = dlopen("libtest_check_order_reloc_siblings.so", RTLD_NOW | RTLD_NOLOAD);
ASSERT_TRUE(handle == nullptr);
handle = dlopen("libtest_check_order_reloc_siblings_1.so", RTLD_NOW | RTLD_NOLOAD);
ASSERT_TRUE(handle == nullptr);
void* handle_for_1 = dlopen("libtest_check_order_reloc_siblings_1.so", RTLD_NOW | RTLD_LOCAL);
ASSERT_TRUE(handle_for_1 != nullptr) << dlerror();
handle = dlopen("libtest_check_order_reloc_siblings.so", RTLD_NOW | RTLD_LOCAL);
ASSERT_TRUE(handle != nullptr) << dlerror();
ASSERT_EQ(0, dlclose(handle_for_1));
typedef int (*fn_t) (void);
fn_t fn = reinterpret_cast<fn_t>(dlsym(handle, "check_order_reloc_get_answer"));
ASSERT_TRUE(fn != nullptr) << dlerror();
ASSERT_EQ(42, fn());
ASSERT_EQ(0, dlclose(handle));
}
TEST(dlfcn, dlopen_check_order_reloc_grandchild) {
// This is how this one works:
// we lookup and call grandchild_get_answer which is defined in '_2.so'
// and in turn calls external get_answer_impl() defined in '_c_1.so and _c_2.so'
// the correct _impl() is implemented by '_c_1.so';
//
// Here is the picture of subtree:
//
// libtest_check_order_reloc_siblings.so
// |
// +-> ..._2.so <- grandchild_get_answer()
// |
// +-> ..._c.so <- empty
// | |
// | +-> _c_1.so <- exports correct answer_impl()
// | |
// | +-> _c_2.so <- exports incorrect answer_impl()
// |
// +-> ..._d.so <- empty
void* handle = dlopen("libtest_check_order_reloc_siblings.so", RTLD_NOW | RTLD_NOLOAD);
ASSERT_TRUE(handle == nullptr);
#ifdef __BIONIC__
// TODO: glibc returns nullptr on dlerror() here. Is it bug?
ASSERT_STREQ("dlopen failed: library \"libtest_check_order_reloc_siblings.so\" wasn't loaded and RTLD_NOLOAD prevented it", dlerror());
#endif
handle = dlopen("libtest_check_order_reloc_siblings.so", RTLD_NOW | RTLD_LOCAL);
ASSERT_TRUE(handle != nullptr) << dlerror();
typedef int (*fn_t) (void);
fn_t fn = reinterpret_cast<fn_t>(dlsym(handle, "check_order_reloc_grandchild_get_answer"));
ASSERT_TRUE(fn != nullptr) << dlerror();
ASSERT_EQ(42, fn());
ASSERT_EQ(0, dlclose(handle));
}
TEST(dlfcn, dlopen_check_order_reloc_nephew) {
// This is how this one works:
// we lookup and call nephew_get_answer which is defined in '_2.so'
// and in turn calls external get_answer_impl() defined in '_[a-f].so'
// the correct _impl() is implemented by '_a.so';
//
// Here is the picture:
//
// libtest_check_order_reloc_siblings.so
// |
// +-> ..._1.so <- empty
// | |
// | +-> ..._a.so <- exports correct answer_impl()
// | |
// | +-> ..._b.so <- every other letter exporting incorrect one.
// |
// +-> ..._2.so <- empty
// | |
// | +-> ..._c.so
// | |
// | +-> ..._d.so
// |
// +-> ..._3.so <- nephew_get_answer() that calls get_answer_impl();
// |
// +-> ..._e.so
// |
// +-> ..._f.so
void* handle = dlopen("libtest_check_order_reloc_siblings.so", RTLD_NOW | RTLD_NOLOAD);
ASSERT_TRUE(handle == nullptr);
#ifdef __BIONIC__
// TODO: glibc returns nullptr on dlerror() here. Is it bug?
ASSERT_STREQ("dlopen failed: library \"libtest_check_order_reloc_siblings.so\" wasn't loaded and RTLD_NOLOAD prevented it", dlerror());
#endif
handle = dlopen("libtest_check_order_reloc_siblings.so", RTLD_NOW | RTLD_LOCAL);
ASSERT_TRUE(handle != nullptr) << dlerror();
typedef int (*fn_t) (void);
fn_t fn = reinterpret_cast<fn_t>(dlsym(handle, "check_order_reloc_nephew_get_answer"));
ASSERT_TRUE(fn != nullptr) << dlerror();
ASSERT_EQ(42, fn());
ASSERT_EQ(0, dlclose(handle));
}
TEST(dlfcn, check_unload_after_reloc) {
// This is how this one works:
// libtest_two_parents_parent1 <- answer_impl() used by libtest_two_parents_child
// |
// +-> libtest_two_parents_child
//
// libtest_two_parents_parent2 <- answer_impl() not used by libtest_two_parents_child
// |
// +-> libtest_two_parents_child
//
// Test dlopens parent1 which loads and relocates libtest_two_parents_child.so
// as a second step it dlopens parent2 and dlcloses parent1...
void* handle = dlopen("libtest_two_parents_parent1.so", RTLD_NOW | RTLD_LOCAL);
ASSERT_TRUE(handle != nullptr) << dlerror();
void* handle2 = dlopen("libtest_two_parents_parent2.so", RTLD_NOW | RTLD_LOCAL);
ASSERT_TRUE(handle2 != nullptr) << dlerror();
typedef int (*fn_t) (void);
fn_t fn = reinterpret_cast<fn_t>(dlsym(handle2, "check_order_reloc_get_answer"));
ASSERT_TRUE(fn != nullptr) << dlerror();
ASSERT_EQ(42, fn());
ASSERT_EQ(0, dlclose(handle));
handle = dlopen("libtest_two_parents_parent1.so", RTLD_NOW | RTLD_LOCAL | RTLD_NOLOAD);
ASSERT_TRUE(handle != nullptr);
ASSERT_EQ(0, dlclose(handle));
fn = reinterpret_cast<fn_t>(dlsym(handle2, "check_order_reloc_get_answer"));
ASSERT_TRUE(fn != nullptr) << dlerror();
ASSERT_EQ(42, fn());
ASSERT_EQ(0, dlclose(handle2));
handle = dlopen("libtest_two_parents_parent1.so", RTLD_NOW | RTLD_LOCAL | RTLD_NOLOAD);
ASSERT_TRUE(handle == nullptr);
}
extern "C" int check_order_reloc_root_get_answer_impl() {
return 42;
}
TEST(dlfcn, dlopen_check_order_reloc_main_executable) {
// This is how this one works:
// we lookup and call get_answer3 which is defined in 'root.so'
// and in turn calls external root_get_answer_impl() defined in _2.so and
// above the correct _impl() is one in the executable.
//
// libtest_check_order_reloc_root.so
// |
// +-> ..._1.so <- empty
// |
// +-> ..._2.so <- gives incorrect answer for answer_main_impl()
//
void* handle = dlopen("libtest_check_order_reloc_root.so", RTLD_NOW | RTLD_NOLOAD);
ASSERT_TRUE(handle == nullptr);
#ifdef __BIONIC__
// TODO: glibc returns nullptr on dlerror() here. Is it bug?
ASSERT_STREQ("dlopen failed: library \"libtest_check_order_reloc_root.so\" wasn't loaded and RTLD_NOLOAD prevented it", dlerror());
#endif
handle = dlopen("libtest_check_order_reloc_root.so", RTLD_NOW | RTLD_LOCAL);
ASSERT_TRUE(handle != nullptr) << dlerror();
typedef int (*fn_t) (void);
fn_t fn = reinterpret_cast<fn_t>(dlsym(handle, "check_order_reloc_root_get_answer"));
ASSERT_TRUE(fn != nullptr) << dlerror();
ASSERT_EQ(42, fn());
ASSERT_EQ(0, dlclose(handle));
}
TEST(dlfcn, dlopen_check_rtld_local) {
void* sym = dlsym(RTLD_DEFAULT, "dlopen_testlib_simple_func");
ASSERT_TRUE(sym == nullptr);
// implicit RTLD_LOCAL
void* handle = dlopen("libtest_simple.so", RTLD_NOW);
sym = dlsym(RTLD_DEFAULT, "dlopen_testlib_simple_func");
ASSERT_TRUE(sym == nullptr);
ASSERT_SUBSTR("undefined symbol: dlopen_testlib_simple_func", dlerror());
sym = dlsym(handle, "dlopen_testlib_simple_func");
ASSERT_TRUE(sym != nullptr);
ASSERT_TRUE(reinterpret_cast<bool (*)(void)>(sym)());
dlclose(handle);
// explicit RTLD_LOCAL
handle = dlopen("libtest_simple.so", RTLD_NOW | RTLD_LOCAL);
sym = dlsym(RTLD_DEFAULT, "dlopen_testlib_simple_func");
ASSERT_TRUE(sym == nullptr);
ASSERT_SUBSTR("undefined symbol: dlopen_testlib_simple_func", dlerror());
sym = dlsym(handle, "dlopen_testlib_simple_func");
ASSERT_TRUE(sym != nullptr);
ASSERT_TRUE(reinterpret_cast<bool (*)(void)>(sym)());
dlclose(handle);
}
TEST(dlfcn, dlopen_check_rtld_global) {
void* sym = dlsym(RTLD_DEFAULT, "dlopen_testlib_simple_func");
ASSERT_TRUE(sym == nullptr);
void* handle = dlopen("libtest_simple.so", RTLD_NOW | RTLD_GLOBAL);
ASSERT_TRUE(handle != nullptr) << dlerror();
sym = dlsym(RTLD_DEFAULT, "dlopen_testlib_simple_func");
ASSERT_TRUE(sym != nullptr) << dlerror();
ASSERT_TRUE(reinterpret_cast<bool (*)(void)>(sym)());
dlclose(handle);
// RTLD_GLOBAL implies RTLD_NODELETE, let's check that
void* sym_after_dlclose = dlsym(RTLD_DEFAULT, "dlopen_testlib_simple_func");
ASSERT_EQ(sym, sym_after_dlclose);
// Check if dlsym() for main program's handle searches RTLD_GLOBAL
// shared libraries after symbol was not found in the main executable
// and dependent libraries.
void* handle_for_main_executable = dlopen(nullptr, RTLD_NOW);
sym = dlsym(handle_for_main_executable, "dlopen_testlib_simple_func");
ASSERT_TRUE(sym != nullptr) << dlerror();
dlclose(handle_for_main_executable);
}
// libtest_with_dependency_loop.so -> libtest_with_dependency_loop_a.so ->
// libtest_with_dependency_loop_b.so -> libtest_with_dependency_loop_c.so ->
// libtest_with_dependency_loop_a.so
TEST(dlfcn, dlopen_check_loop) {
void* handle = dlopen("libtest_with_dependency_loop.so", RTLD_NOW);
ASSERT_TRUE(handle != nullptr) << dlerror();
void* f = dlsym(handle, "dlopen_test_loopy_function");
ASSERT_TRUE(f != nullptr) << dlerror();
EXPECT_TRUE(reinterpret_cast<bool (*)(void)>(f)());
ASSERT_EQ(0, dlclose(handle));
// dlopen second time to make sure that the library was unloaded correctly
handle = dlopen("libtest_with_dependency_loop.so", RTLD_NOW | RTLD_NOLOAD);
ASSERT_TRUE(handle == nullptr);
#ifdef __BIONIC__
ASSERT_STREQ("dlopen failed: library \"libtest_with_dependency_loop.so\" wasn't loaded and RTLD_NOLOAD prevented it", dlerror());
#else
// TODO: glibc returns nullptr on dlerror() here. Is it bug?
ASSERT_TRUE(dlerror() == nullptr);
#endif
handle = dlopen("libtest_with_dependency_a.so", RTLD_NOW | RTLD_NOLOAD);
ASSERT_TRUE(handle == nullptr);
}
TEST(dlfcn, dlopen_nodelete) {
static bool is_unloaded = false;
void* handle = dlopen("libtest_nodelete_1.so", RTLD_NOW | RTLD_NODELETE);
ASSERT_TRUE(handle != nullptr) << dlerror();
void (*set_unload_flag_ptr)(bool*);
set_unload_flag_ptr = reinterpret_cast<void (*)(bool*)>(dlsym(handle, "dlopen_nodelete_1_set_unload_flag_ptr"));
ASSERT_TRUE(set_unload_flag_ptr != nullptr) << dlerror();
set_unload_flag_ptr(&is_unloaded);
uint32_t* taxicab_number = reinterpret_cast<uint32_t*>(dlsym(handle, "dlopen_nodelete_1_taxicab_number"));
ASSERT_TRUE(taxicab_number != nullptr) << dlerror();
ASSERT_EQ(1729U, *taxicab_number);
*taxicab_number = 2;
dlclose(handle);
ASSERT_TRUE(!is_unloaded);
uint32_t* taxicab_number_after_dlclose = reinterpret_cast<uint32_t*>(dlsym(handle, "dlopen_nodelete_1_taxicab_number"));
ASSERT_EQ(taxicab_number_after_dlclose, taxicab_number);
ASSERT_EQ(2U, *taxicab_number_after_dlclose);
handle = dlopen("libtest_nodelete_1.so", RTLD_NOW);
uint32_t* taxicab_number2 = reinterpret_cast<uint32_t*>(dlsym(handle, "dlopen_nodelete_1_taxicab_number"));
ASSERT_EQ(taxicab_number2, taxicab_number);
ASSERT_EQ(2U, *taxicab_number2);
dlclose(handle);
ASSERT_TRUE(!is_unloaded);
}
TEST(dlfcn, dlopen_nodelete_on_second_dlopen) {
static bool is_unloaded = false;
void* handle = dlopen("libtest_nodelete_2.so", RTLD_NOW);
ASSERT_TRUE(handle != nullptr) << dlerror();
void (*set_unload_flag_ptr)(bool*);
set_unload_flag_ptr = reinterpret_cast<void (*)(bool*)>(dlsym(handle, "dlopen_nodelete_2_set_unload_flag_ptr"));
ASSERT_TRUE(set_unload_flag_ptr != nullptr) << dlerror();
set_unload_flag_ptr(&is_unloaded);
uint32_t* taxicab_number = reinterpret_cast<uint32_t*>(dlsym(handle, "dlopen_nodelete_2_taxicab_number"));
ASSERT_TRUE(taxicab_number != nullptr) << dlerror();
ASSERT_EQ(1729U, *taxicab_number);
*taxicab_number = 2;
// This RTLD_NODELETE should be ignored
void* handle1 = dlopen("libtest_nodelete_2.so", RTLD_NOW | RTLD_NODELETE);
ASSERT_TRUE(handle1 != nullptr) << dlerror();
ASSERT_EQ(handle, handle1);
dlclose(handle1);
dlclose(handle);
ASSERT_TRUE(is_unloaded);
}
TEST(dlfcn, dlopen_nodelete_dt_flags_1) {
static bool is_unloaded = false;
void* handle = dlopen("libtest_nodelete_dt_flags_1.so", RTLD_NOW);
ASSERT_TRUE(handle != nullptr) << dlerror();
void (*set_unload_flag_ptr)(bool*);
set_unload_flag_ptr = reinterpret_cast<void (*)(bool*)>(dlsym(handle, "dlopen_nodelete_dt_flags_1_set_unload_flag_ptr"));
ASSERT_TRUE(set_unload_flag_ptr != nullptr) << dlerror();
set_unload_flag_ptr(&is_unloaded);
dlclose(handle);
ASSERT_TRUE(!is_unloaded);
}
TEST(dlfcn, dlsym_df_1_global) {
void* handle = dlopen("libtest_dlsym_df_1_global.so", RTLD_NOW);
ASSERT_TRUE(handle != nullptr) << dlerror();
int (*get_answer)();
get_answer = reinterpret_cast<int (*)()>(dlsym(handle, "dl_df_1_global_get_answer"));
ASSERT_TRUE(get_answer != nullptr) << dlerror();
ASSERT_EQ(42, get_answer());
ASSERT_EQ(0, dlclose(handle));
}
TEST(dlfcn, dlopen_failure) {
void* self = dlopen("/does/not/exist", RTLD_NOW);
ASSERT_TRUE(self == nullptr);
#if defined(__BIONIC__)
ASSERT_STREQ("dlopen failed: library \"/does/not/exist\" not found", dlerror());
#else
ASSERT_STREQ("/does/not/exist: cannot open shared object file: No such file or directory", dlerror());
#endif
}
TEST(dlfcn, dlclose_unload) {
void* handle = dlopen("libtest_simple.so", RTLD_NOW);
ASSERT_TRUE(handle != nullptr) << dlerror();
uint32_t* taxicab_number = static_cast<uint32_t*>(dlsym(handle, "dlopen_testlib_taxicab_number"));
ASSERT_TRUE(taxicab_number != nullptr) << dlerror();
EXPECT_EQ(1729U, *taxicab_number);
dlclose(handle);
// Making sure that the library has been unmapped as part of library unload
// process. Note that mprotect somewhat counter-intuitively returns ENOMEM in
// this case.
uintptr_t page_start = reinterpret_cast<uintptr_t>(taxicab_number) & ~(PAGE_SIZE - 1);
ASSERT_TRUE(mprotect(reinterpret_cast<void*>(page_start), PAGE_SIZE, PROT_NONE) != 0);
ASSERT_EQ(ENOMEM, errno) << strerror(errno);
}
static void ConcurrentDlErrorFn(std::string& error) {
ASSERT_TRUE(dlerror() == nullptr);
void* handle = dlopen("/child/thread", RTLD_NOW);
ASSERT_TRUE(handle == nullptr);
const char* err = dlerror();
ASSERT_TRUE(err != nullptr);
error = err;
}
TEST(dlfcn, dlerror_concurrent_buffer) {
void* handle = dlopen("/main/thread", RTLD_NOW);
ASSERT_TRUE(handle == nullptr);
const char* main_thread_error = dlerror();
ASSERT_TRUE(main_thread_error != nullptr);
ASSERT_SUBSTR("/main/thread", main_thread_error);
std::string child_thread_error;
std::thread t(ConcurrentDlErrorFn, std::ref(child_thread_error));
t.join();
ASSERT_SUBSTR("/child/thread", child_thread_error.c_str());
// Check that main thread local buffer was not modified.
ASSERT_SUBSTR("/main/thread", main_thread_error);
}
TEST(dlfcn, dlerror_concurrent) {
void* handle = dlopen("/main/thread", RTLD_NOW);
ASSERT_TRUE(handle == nullptr);
std::string child_thread_error;
std::thread t(ConcurrentDlErrorFn, std::ref(child_thread_error));
t.join();
ASSERT_SUBSTR("/child/thread", child_thread_error.c_str());
const char* main_thread_error = dlerror();
ASSERT_TRUE(main_thread_error != nullptr);
ASSERT_SUBSTR("/main/thread", main_thread_error);
}
TEST(dlfcn, dlsym_failures) {
dlerror(); // Clear any pending errors.
void* self = dlopen(nullptr, RTLD_NOW);
ASSERT_TRUE(self != nullptr);
ASSERT_TRUE(dlerror() == nullptr);
void* sym;
#if defined(__BIONIC__) && !defined(__LP64__)
// RTLD_DEFAULT in lp32 bionic is not (void*)0
// so it can be distinguished from the NULL handle.
sym = dlsym(nullptr, "test");
ASSERT_TRUE(sym == nullptr);
ASSERT_STREQ("dlsym failed: library handle is null", dlerror());
#endif
// Symbol that doesn't exist.
sym = dlsym(self, "ThisSymbolDoesNotExist");
ASSERT_TRUE(sym == nullptr);
ASSERT_SUBSTR("undefined symbol: ThisSymbolDoesNotExist", dlerror());
ASSERT_EQ(0, dlclose(self));
}
TEST(dlfcn, dladdr_executable) {
dlerror(); // Clear any pending errors.
void* self = dlopen(nullptr, RTLD_NOW);
ASSERT_TRUE(self != nullptr);
ASSERT_TRUE(dlerror() == nullptr);
void* sym = dlsym(self, "DlSymTestFunction");
ASSERT_TRUE(sym != nullptr);
// Deliberately ask dladdr for an address inside a symbol, rather than the symbol base address.
void* addr = reinterpret_cast<void*>(reinterpret_cast<uintptr_t>(sym) + 2);
Dl_info info;
int rc = dladdr(addr, &info);
ASSERT_NE(rc, 0); // Zero on error, non-zero on success.
// Get the name of this executable.
const std::string executable_path = android::base::GetExecutablePath();
// The filename should be that of this executable.
char dli_realpath[PATH_MAX];
ASSERT_TRUE(realpath(info.dli_fname, dli_realpath) != nullptr);
ASSERT_STREQ(executable_path.c_str(), dli_realpath);
// The symbol name should be the symbol we looked up.
ASSERT_STREQ(info.dli_sname, "DlSymTestFunction");
// The address should be the exact address of the symbol.
ASSERT_EQ(info.dli_saddr, sym);
std::vector<map_record> maps;
ASSERT_TRUE(Maps::parse_maps(&maps));
void* base_address = nullptr;
for (const map_record& rec : maps) {
if (executable_path == rec.pathname) {
base_address = reinterpret_cast<void*>(rec.addr_start);
break;
}
}
// The base address should be the address we were loaded at.
ASSERT_EQ(info.dli_fbase, base_address);
ASSERT_EQ(0, dlclose(self));
}
TEST(dlfcn, dlopen_executable_by_absolute_path) {
void* handle1 = dlopen(nullptr, RTLD_NOW);
ASSERT_TRUE(handle1 != nullptr) << dlerror();
void* handle2 = dlopen(android::base::GetExecutablePath().c_str(), RTLD_NOW);
ASSERT_TRUE(handle2 != nullptr) << dlerror();
#if defined(__BIONIC__)
ASSERT_EQ(handle1, handle2);
#else
GTEST_SKIP() << "Skipping ASSERT_EQ(handle1, handle2) for glibc: "
"it loads a separate copy of the main executable "
"on dlopen by absolute path";
#endif
}
#if defined (__aarch64__)
#define ALTERNATE_PATH_TO_SYSTEM_LIB "/system/lib64/arm64/"
#elif defined (__arm__)
#define ALTERNATE_PATH_TO_SYSTEM_LIB "/system/lib/arm/"
#elif defined (__i386__)
#define ALTERNATE_PATH_TO_SYSTEM_LIB "/system/lib/x86/"
#elif defined (__x86_64__)
#define ALTERNATE_PATH_TO_SYSTEM_LIB "/system/lib64/x86_64/"
#elif defined (__mips__)
#if defined(__LP64__)
#define ALTERNATE_PATH_TO_SYSTEM_LIB "/system/lib64/mips64/"
#else
#define ALTERNATE_PATH_TO_SYSTEM_LIB "/system/lib/mips/"
#endif
#else
#error "Unknown architecture"
#endif
#define PATH_TO_LIBC PATH_TO_SYSTEM_LIB "libc.so"
#define PATH_TO_BOOTSTRAP_LIBC PATH_TO_SYSTEM_LIB "bootstrap/libc.so"
#define ALTERNATE_PATH_TO_LIBC ALTERNATE_PATH_TO_SYSTEM_LIB "libc.so"
TEST(dlfcn, dladdr_libc) {
#if defined(__GLIBC__)
GTEST_SKIP() << "glibc returns libc.so's ldconfig path, which is a symlink (not a realpath)";
#endif
Dl_info info;
void* addr = reinterpret_cast<void*>(puts); // well-known libc function
ASSERT_TRUE(dladdr(addr, &info) != 0);
char libc_realpath[PATH_MAX];
// Check if libc is in canonical path or in alternate path.
if (strncmp(ALTERNATE_PATH_TO_SYSTEM_LIB,
info.dli_fname,
sizeof(ALTERNATE_PATH_TO_SYSTEM_LIB) - 1) == 0) {
// Platform with emulated architecture. Symlink on ARC++.
ASSERT_TRUE(realpath(ALTERNATE_PATH_TO_LIBC, libc_realpath) == libc_realpath);
} else if (strncmp(PATH_TO_BOOTSTRAP_LIBC, info.dli_fname,
sizeof(PATH_TO_BOOTSTRAP_LIBC) - 1) == 0) {
ASSERT_TRUE(realpath(PATH_TO_BOOTSTRAP_LIBC, libc_realpath) == libc_realpath);
} else {
// /system/lib is symlink when this test is executed on host.
ASSERT_TRUE(realpath(PATH_TO_LIBC, libc_realpath) == libc_realpath);
}
ASSERT_STREQ(libc_realpath, info.dli_fname);
// TODO: add check for dfi_fbase
ASSERT_STREQ("puts", info.dli_sname);
ASSERT_EQ(addr, info.dli_saddr);
}
TEST(dlfcn, dladdr_invalid) {
Dl_info info;
dlerror(); // Clear any pending errors.
// No symbol corresponding to NULL.
ASSERT_EQ(dladdr(nullptr, &info), 0); // Zero on error, non-zero on success.
ASSERT_TRUE(dlerror() == nullptr); // dladdr(3) doesn't set dlerror(3).
// No symbol corresponding to a stack address.
ASSERT_EQ(dladdr(&info, &info), 0); // Zero on error, non-zero on success.
ASSERT_TRUE(dlerror() == nullptr); // dladdr(3) doesn't set dlerror(3).
}
// GNU-style ELF hash tables are incompatible with the MIPS ABI.
// MIPS requires .dynsym to be sorted to match the GOT but GNU-style requires sorting by hash code.
TEST(dlfcn, dlopen_library_with_only_gnu_hash) {
#if !defined(__mips__)
dlerror(); // Clear any pending errors.
void* handle = dlopen("libgnu-hash-table-library.so", RTLD_NOW);
ASSERT_TRUE(handle != nullptr) << dlerror();
auto guard = android::base::make_scope_guard([&]() { dlclose(handle); });
void* sym = dlsym(handle, "getRandomNumber");
ASSERT_TRUE(sym != nullptr) << dlerror();
int (*fn)(void);
fn = reinterpret_cast<int (*)(void)>(sym);
EXPECT_EQ(4, fn());
Dl_info dlinfo;
ASSERT_TRUE(0 != dladdr(reinterpret_cast<void*>(fn), &dlinfo));
ASSERT_TRUE(fn == dlinfo.dli_saddr);
ASSERT_STREQ("getRandomNumber", dlinfo.dli_sname);
ASSERT_SUBSTR("libgnu-hash-table-library.so", dlinfo.dli_fname);
#else
GTEST_SKIP() << "mips toolchain does not support '--hash-style=gnu'";
#endif
}
TEST(dlfcn, dlopen_library_with_only_sysv_hash) {
void* handle = dlopen("libsysv-hash-table-library.so", RTLD_NOW);
ASSERT_TRUE(handle != nullptr) << dlerror();
auto guard = android::base::make_scope_guard([&]() { dlclose(handle); });
void* sym = dlsym(handle, "getRandomNumber");
ASSERT_TRUE(sym != nullptr) << dlerror();
int (*fn)(void);
fn = reinterpret_cast<int (*)(void)>(sym);
EXPECT_EQ(4, fn());
Dl_info dlinfo;
ASSERT_TRUE(0 != dladdr(reinterpret_cast<void*>(fn), &dlinfo));
ASSERT_TRUE(fn == dlinfo.dli_saddr);
ASSERT_STREQ("getRandomNumber", dlinfo.dli_sname);
ASSERT_SUBSTR("libsysv-hash-table-library.so", dlinfo.dli_fname);
}
TEST(dlfcn, dlopen_bad_flags) {
dlerror(); // Clear any pending errors.
void* handle;
#if defined(__GLIBC__)
// glibc was smart enough not to define RTLD_NOW as 0, so it can detect missing flags.
handle = dlopen(nullptr, 0);
ASSERT_TRUE(handle == nullptr);
ASSERT_SUBSTR("invalid", dlerror());
#endif
handle = dlopen(nullptr, 0xffffffff);
ASSERT_TRUE(handle == nullptr);
ASSERT_SUBSTR("invalid", dlerror());
// glibc actually allows you to choose both RTLD_NOW and RTLD_LAZY at the same time, and so do we.
handle = dlopen(nullptr, RTLD_NOW|RTLD_LAZY);
ASSERT_TRUE(handle != nullptr);
ASSERT_SUBSTR(nullptr, dlerror());
}
TEST(dlfcn, rtld_default_unknown_symbol) {
void* addr = dlsym(RTLD_DEFAULT, "ANY_UNKNOWN_SYMBOL_NAME");
ASSERT_TRUE(addr == nullptr);
}
TEST(dlfcn, rtld_default_known_symbol) {
void* addr = dlsym(RTLD_DEFAULT, "fopen");
ASSERT_TRUE(addr != nullptr);
}
TEST(dlfcn, rtld_next_unknown_symbol) {
void* addr = dlsym(RTLD_NEXT, "ANY_UNKNOWN_SYMBOL_NAME");
ASSERT_TRUE(addr == nullptr);
}
TEST(dlfcn, rtld_next_known_symbol) {
void* addr = dlsym(RTLD_NEXT, "fopen");
ASSERT_TRUE(addr != nullptr);
}
// Check that RTLD_NEXT of a libc symbol works in dlopened library
TEST(dlfcn, rtld_next_from_library) {
void* library_with_fclose = dlopen("libtest_check_rtld_next_from_library.so", RTLD_NOW | RTLD_GLOBAL);
ASSERT_TRUE(library_with_fclose != nullptr) << dlerror();
void* expected_addr = dlsym(RTLD_DEFAULT, "fclose");
ASSERT_TRUE(expected_addr != nullptr) << dlerror();
typedef void* (*get_libc_fclose_ptr_fn_t)();
get_libc_fclose_ptr_fn_t get_libc_fclose_ptr =
reinterpret_cast<get_libc_fclose_ptr_fn_t>(dlsym(library_with_fclose, "get_libc_fclose_ptr"));
ASSERT_TRUE(get_libc_fclose_ptr != nullptr) << dlerror();
ASSERT_EQ(expected_addr, get_libc_fclose_ptr());
dlclose(library_with_fclose);
}
TEST(dlfcn, dlsym_weak_func) {
dlerror();
void* handle = dlopen("libtest_dlsym_weak_func.so", RTLD_NOW);
ASSERT_TRUE(handle != nullptr);
int (*weak_func)();
weak_func = reinterpret_cast<int (*)()>(dlsym(handle, "weak_func"));
ASSERT_TRUE(weak_func != nullptr) << "dlerror: " << dlerror();
EXPECT_EQ(42, weak_func());
dlclose(handle);
}
TEST(dlfcn, dlopen_undefined_weak_func) {
void* handle = dlopen("libtest_dlopen_weak_undefined_func.so", RTLD_NOW);
ASSERT_TRUE(handle != nullptr) << dlerror();
int (*weak_func)();
weak_func = reinterpret_cast<int (*)()>(dlsym(handle, "use_weak_undefined_func"));
ASSERT_TRUE(weak_func != nullptr) << dlerror();
EXPECT_EQ(6551, weak_func());
dlclose(handle);
}
TEST(dlfcn, dlopen_symlink) {
DlfcnSymlink symlink("dlopen_symlink");
const std::string symlink_name = basename(symlink.get_symlink_path().c_str());
void* handle1 = dlopen("libdlext_test.so", RTLD_NOW);
void* handle2 = dlopen(symlink_name.c_str(), RTLD_NOW);
ASSERT_TRUE(handle1 != nullptr);
ASSERT_TRUE(handle2 != nullptr);
ASSERT_EQ(handle1, handle2);
dlclose(handle1);
dlclose(handle2);
}
// libtest_dlopen_from_ctor_main.so depends on
// libtest_dlopen_from_ctor.so which has a constructor
// that calls dlopen(libc...). This is to test the situation
// described in b/7941716.
TEST(dlfcn, dlopen_dlopen_from_ctor) {
#if defined(__GLIBC__)
GTEST_SKIP() << "glibc segfaults if you try to call dlopen from a constructor";
#endif
void* handle = dlopen("libtest_dlopen_from_ctor_main.so", RTLD_NOW);
ASSERT_TRUE(handle != nullptr) << dlerror();
dlclose(handle);
}
static std::string g_fini_call_order_str;
static void register_fini_call(const char* s) {
g_fini_call_order_str += s;
}
static void test_init_fini_call_order_for(const char* libname) {
g_fini_call_order_str.clear();
void* handle = dlopen(libname, RTLD_NOW);
ASSERT_TRUE(handle != nullptr) << dlerror();
typedef int (*get_init_order_number_t)();
get_init_order_number_t get_init_order_number =
reinterpret_cast<get_init_order_number_t>(dlsym(handle, "get_init_order_number"));
ASSERT_EQ(321, get_init_order_number());
typedef void (*set_fini_callback_t)(void (*f)(const char*));
set_fini_callback_t set_fini_callback =
reinterpret_cast<set_fini_callback_t>(dlsym(handle, "set_fini_callback"));
set_fini_callback(register_fini_call);
dlclose(handle);
ASSERT_EQ("(root)(child)(grandchild)", g_fini_call_order_str);
}
TEST(dlfcn, init_fini_call_order) {
test_init_fini_call_order_for("libtest_init_fini_order_root.so");
test_init_fini_call_order_for("libtest_init_fini_order_root2.so");
}
TEST(dlfcn, symbol_versioning_use_v1) {
void* handle = dlopen("libtest_versioned_uselibv1.so", RTLD_NOW);
ASSERT_TRUE(handle != nullptr) << dlerror();
typedef int (*fn_t)();
fn_t fn = reinterpret_cast<fn_t>(dlsym(handle, "get_function_version"));
ASSERT_TRUE(fn != nullptr) << dlerror();
ASSERT_EQ(1, fn());
dlclose(handle);
}
TEST(dlfcn, symbol_versioning_use_v2) {
void* handle = dlopen("libtest_versioned_uselibv2.so", RTLD_NOW);
ASSERT_TRUE(handle != nullptr) << dlerror();
typedef int (*fn_t)();
fn_t fn = reinterpret_cast<fn_t>(dlsym(handle, "get_function_version"));
ASSERT_TRUE(fn != nullptr) << dlerror();
ASSERT_EQ(2, fn());
dlclose(handle);
}
TEST(dlfcn, symbol_versioning_use_other_v2) {
void* handle = dlopen("libtest_versioned_uselibv2_other.so", RTLD_NOW);
ASSERT_TRUE(handle != nullptr) << dlerror();
typedef int (*fn_t)();
fn_t fn = reinterpret_cast<fn_t>(dlsym(handle, "get_function_version"));
ASSERT_TRUE(fn != nullptr) << dlerror();
ASSERT_EQ(20, fn());
dlclose(handle);
}
TEST(dlfcn, symbol_versioning_use_other_v3) {
void* handle = dlopen("libtest_versioned_uselibv3_other.so", RTLD_NOW);
ASSERT_TRUE(handle != nullptr) << dlerror();
typedef int (*fn_t)();
fn_t fn = reinterpret_cast<fn_t>(dlsym(handle, "get_function_version"));
ASSERT_TRUE(fn != nullptr) << dlerror();
ASSERT_EQ(3, fn());
dlclose(handle);
}
TEST(dlfcn, symbol_versioning_default_via_dlsym) {
void* handle = dlopen("libtest_versioned_lib.so", RTLD_NOW);
ASSERT_TRUE(handle != nullptr) << dlerror();
typedef int (*fn_t)();
fn_t fn = reinterpret_cast<fn_t>(dlsym(handle, "versioned_function"));
ASSERT_TRUE(fn != nullptr) << dlerror();
ASSERT_EQ(3, fn()); // the default version is 3
dlclose(handle);
}
TEST(dlfcn, dlvsym_smoke) {
void* handle = dlopen("libtest_versioned_lib.so", RTLD_NOW);
ASSERT_TRUE(handle != nullptr) << dlerror();
typedef int (*fn_t)();
{
fn_t fn = reinterpret_cast<fn_t>(dlvsym(handle, "versioned_function", "nonversion"));
ASSERT_TRUE(fn == nullptr);
ASSERT_SUBSTR("undefined symbol: versioned_function, version nonversion", dlerror());
}
{
fn_t fn = reinterpret_cast<fn_t>(dlvsym(handle, "versioned_function", "TESTLIB_V2"));
ASSERT_TRUE(fn != nullptr) << dlerror();
ASSERT_EQ(2, fn());
}
dlclose(handle);
}
// This preempts the implementation from libtest_versioned_lib.so
extern "C" int version_zero_function() {
return 0;
}
// This preempts the implementation from libtest_versioned_uselibv*.so
extern "C" int version_zero_function2() {
return 0;
}
TEST(dlfcn, dt_runpath_smoke) {
void* handle = dlopen("libtest_dt_runpath_d.so", RTLD_NOW);
ASSERT_TRUE(handle != nullptr) << dlerror();
typedef void *(* dlopen_b_fn)();
dlopen_b_fn fn = (dlopen_b_fn)dlsym(handle, "dlopen_b");
ASSERT_TRUE(fn != nullptr) << dlerror();
void *p = fn();
ASSERT_TRUE(p != nullptr);
dlclose(handle);
}
TEST(dlfcn, dt_runpath_absolute_path) {
std::string libpath = GetTestlibRoot() + "/libtest_dt_runpath_d.so";
void* handle = dlopen(libpath.c_str(), RTLD_NOW);
ASSERT_TRUE(handle != nullptr) << dlerror();
typedef void *(* dlopen_b_fn)();
dlopen_b_fn fn = (dlopen_b_fn)dlsym(handle, "dlopen_b");
ASSERT_TRUE(fn != nullptr) << dlerror();
void *p = fn();
ASSERT_TRUE(p != nullptr);
dlclose(handle);
}
static void test_dlclose_after_thread_local_dtor(const char* library_name) {
bool is_dtor_triggered = false;
auto f = [](void* handle, bool* is_dtor_triggered) {
typedef void (*fn_t)(bool*);
fn_t fn = reinterpret_cast<fn_t>(dlsym(handle, "init_thread_local_variable"));
ASSERT_TRUE(fn != nullptr) << dlerror();
fn(is_dtor_triggered);
ASSERT_TRUE(!*is_dtor_triggered);
};
void* handle = dlopen(library_name, RTLD_NOW | RTLD_NOLOAD);
ASSERT_TRUE(handle == nullptr);
handle = dlopen(library_name, RTLD_NOW);
ASSERT_TRUE(handle != nullptr) << dlerror();
std::thread t(f, handle, &is_dtor_triggered);
t.join();
ASSERT_TRUE(is_dtor_triggered);
dlclose(handle);
handle = dlopen(library_name, RTLD_NOW | RTLD_NOLOAD);
ASSERT_TRUE(handle == nullptr);
}
TEST(dlfcn, dlclose_after_thread_local_dtor) {
test_dlclose_after_thread_local_dtor("libtest_thread_local_dtor.so");
}
TEST(dlfcn, dlclose_after_thread_local_dtor_indirect) {
test_dlclose_after_thread_local_dtor("libtest_indirect_thread_local_dtor.so");
}
static void test_dlclose_before_thread_local_dtor(const char* library_name) {
bool is_dtor_triggered = false;
auto f = [library_name](bool* is_dtor_triggered) {
void* handle = dlopen(library_name, RTLD_NOW | RTLD_NOLOAD);
ASSERT_TRUE(handle == nullptr);
handle = dlopen(library_name, RTLD_NOW);
ASSERT_TRUE(handle != nullptr) << dlerror();
typedef void (*fn_t)(bool*);
fn_t fn = reinterpret_cast<fn_t>(dlsym(handle, "init_thread_local_variable"));
ASSERT_TRUE(fn != nullptr) << dlerror();
fn(is_dtor_triggered);
dlclose(handle);
ASSERT_TRUE(!*is_dtor_triggered);
// Since we have thread_atexit dtors associated with handle - the library should
// still be availabe.
handle = dlopen(library_name, RTLD_NOW | RTLD_NOLOAD);
ASSERT_TRUE(handle != nullptr) << dlerror();
dlclose(handle);
};
void* handle = dlopen(library_name, RTLD_NOW);
ASSERT_TRUE(handle != nullptr) << dlerror();
dlclose(handle);
handle = dlopen(library_name, RTLD_NOW | RTLD_NOLOAD);
ASSERT_TRUE(handle == nullptr);
std::thread t(f, &is_dtor_triggered);
t.join();
#if defined(__BIONIC__)
// ld-android.so unloads unreferenced libraries on pthread_exit()
ASSERT_TRUE(is_dtor_triggered);
handle = dlopen(library_name, RTLD_NOW | RTLD_NOLOAD);
ASSERT_TRUE(handle == nullptr);
#else
// GLIBC does not unload libraries with ref_count = 0 on pthread_exit
ASSERT_TRUE(is_dtor_triggered);
handle = dlopen(library_name, RTLD_NOW | RTLD_NOLOAD);
ASSERT_TRUE(handle != nullptr) << dlerror();
#endif
}
TEST(dlfcn, dlclose_before_thread_local_dtor) {
test_dlclose_before_thread_local_dtor("libtest_thread_local_dtor.so");
}
TEST(dlfcn, dlclose_before_thread_local_dtor_indirect) {
test_dlclose_before_thread_local_dtor("libtest_indirect_thread_local_dtor.so");
}
TEST(dlfcn, dlclose_before_thread_local_dtor_multiple_dsos) {
const constexpr char* library_name = "libtest_indirect_thread_local_dtor.so";
bool is_dtor1_triggered = false;
bool is_dtor2_triggered = false;
std::mutex mtx;
std::condition_variable cv;
void* library_handle = nullptr;
bool thread1_dlopen_complete = false;
bool thread2_thread_local_dtor_initialized = false;
bool thread1_complete = false;
auto f1 = [&]() {
void* handle = dlopen(library_name, RTLD_NOW | RTLD_NOLOAD);
ASSERT_TRUE(handle == nullptr);
handle = dlopen(library_name, RTLD_NOW);
ASSERT_TRUE(handle != nullptr) << dlerror();
std::unique_lock<std::mutex> lock(mtx);
thread1_dlopen_complete = true;
library_handle = handle;
lock.unlock();
cv.notify_one();
typedef void (*fn_t)(bool*);
fn_t fn = reinterpret_cast<fn_t>(dlsym(handle, "init_thread_local_variable"));
ASSERT_TRUE(fn != nullptr) << dlerror();
fn(&is_dtor1_triggered);
lock.lock();
cv.wait(lock, [&] { return thread2_thread_local_dtor_initialized; });
lock.unlock();
dlclose(handle);
ASSERT_TRUE(!is_dtor1_triggered);
// Since we have thread_atexit dtors associated with handle - the library should
// still be availabe.
handle = dlopen(library_name, RTLD_NOW | RTLD_NOLOAD);
ASSERT_TRUE(handle != nullptr) << dlerror();
dlclose(handle);
};
auto f2 = [&]() {
std::unique_lock<std::mutex> lock(mtx);
cv.wait(lock, [&] { return thread1_dlopen_complete; });
void* handle = library_handle;
lock.unlock();
typedef void (*fn_t)(bool*);
fn_t fn = reinterpret_cast<fn_t>(dlsym(handle, "init_thread_local_variable2"));
ASSERT_TRUE(fn != nullptr) << dlerror();
fn(&is_dtor2_triggered);
lock.lock();
thread2_thread_local_dtor_initialized = true;
lock.unlock();
cv.notify_one();
lock.lock();
cv.wait(lock, [&] { return thread1_complete; });
lock.unlock();
ASSERT_TRUE(!is_dtor2_triggered);
};
void* handle = dlopen(library_name, RTLD_NOW);
ASSERT_TRUE(handle != nullptr) << dlerror();
dlclose(handle);
handle = dlopen(library_name, RTLD_NOW | RTLD_NOLOAD);
ASSERT_TRUE(handle == nullptr);
std::thread t1(f1);
std::thread t2(f2);
t1.join();
ASSERT_TRUE(is_dtor1_triggered);
ASSERT_TRUE(!is_dtor2_triggered);
handle = dlopen(library_name, RTLD_NOW | RTLD_NOLOAD);
ASSERT_TRUE(handle != nullptr) << dlerror();
dlclose(handle);
std::unique_lock<std::mutex> lock(mtx);
thread1_complete = true;
lock.unlock();
cv.notify_one();
t2.join();
ASSERT_TRUE(is_dtor2_triggered);
#if defined(__BIONIC__)
// ld-android.so unloads unreferenced libraries on pthread_exit()
handle = dlopen(library_name, RTLD_NOW | RTLD_NOLOAD);
ASSERT_TRUE(handle == nullptr);
#else
// GLIBC does not unload libraries with ref_count = 0 on pthread_exit
handle = dlopen(library_name, RTLD_NOW | RTLD_NOLOAD);
ASSERT_TRUE(handle != nullptr) << dlerror();
#endif
}
TEST(dlfcn, RTLD_macros) {
#if !defined(RTLD_LOCAL)
#error no RTLD_LOCAL
#elif !defined(RTLD_LAZY)
#error no RTLD_LAZY
#elif !defined(RTLD_NOW)
#error no RTLD_NOW
#elif !defined(RTLD_NOLOAD)
#error no RTLD_NOLOAD
#elif !defined(RTLD_GLOBAL)
#error no RTLD_GLOBAL
#elif !defined(RTLD_NODELETE)
#error no RTLD_NODELETE
#endif
}
// Bionic specific tests
#if defined(__BIONIC__)
#if defined(__arm__)
const llvm::ELF::Elf32_Dyn* to_dynamic_table(const char* p) {
return reinterpret_cast<const llvm::ELF::Elf32_Dyn*>(p);
}
// Duplicate these definitions here because they are android specific
// - note that we cannot include <elf.h> because #defines conflict with
// enum names provided by LLVM.
// - we also don't use llvm::ELF::DT_LOOS because its value is 0x60000000
// rather than the 0x6000000d we expect
#define DT_LOOS 0x6000000d
#define DT_ANDROID_REL (DT_LOOS + 2)
#define DT_ANDROID_RELA (DT_LOOS + 4)
template<typename ELFT>
void validate_compatibility_of_native_library(const std::string& soname,
const std::string& path, ELFT* elf) {
bool has_elf_hash = false;
bool has_android_rel = false;
bool has_rel = false;
// Find dynamic section and check that DT_HASH and there is no DT_ANDROID_REL
for (auto it = elf->section_begin(); it != elf->section_end(); ++it) {
const llvm::object::ELFSectionRef& section_ref = *it;
if (section_ref.getType() == llvm::ELF::SHT_DYNAMIC) {
llvm::StringRef data;
ASSERT_TRUE(!it->getContents(data)) << "unable to get SHT_DYNAMIC section data";
for (auto d = to_dynamic_table(data.data()); d->d_tag != llvm::ELF::DT_NULL; ++d) {
if (d->d_tag == llvm::ELF::DT_HASH) {
has_elf_hash = true;
} else if (d->d_tag == DT_ANDROID_REL || d->d_tag == DT_ANDROID_RELA) {
has_android_rel = true;
} else if (d->d_tag == llvm::ELF::DT_REL || d->d_tag == llvm::ELF::DT_RELA) {
has_rel = true;
}
}
break;
}
}
ASSERT_TRUE(has_elf_hash) << path.c_str() << ": missing elf hash (DT_HASH)";
ASSERT_TRUE(!has_android_rel) << path.c_str() << ": has packed relocations";
// libdl.so is simple enough that it might not have any relocations, so
// exempt it from the DT_REL/DT_RELA check.
if (soname != "libdl.so") {
ASSERT_TRUE(has_rel) << path.c_str() << ": missing DT_REL/DT_RELA";
}
}
void validate_compatibility_of_native_library(const std::string& soname) {
// On the systems with emulation system libraries would be of different
// architecture. Try to use alternate paths first.
std::string path = std::string(ALTERNATE_PATH_TO_SYSTEM_LIB) + soname;
auto binary_or_error = llvm::object::createBinary(path);
if (!binary_or_error) {
path = std::string(PATH_TO_SYSTEM_LIB) + soname;
binary_or_error = llvm::object::createBinary(path);
}
ASSERT_FALSE(!binary_or_error);
llvm::object::Binary* binary = binary_or_error.get().getBinary();
auto obj = llvm::dyn_cast<llvm::object::ObjectFile>(binary);
ASSERT_TRUE(obj != nullptr);
auto elf = llvm::dyn_cast<llvm::object::ELF32LEObjectFile>(obj);
ASSERT_TRUE(elf != nullptr);
validate_compatibility_of_native_library(soname, path, elf);
}
// This is a test for app compatibility workaround for arm apps
// affected by http://b/24465209
TEST(dlext, compat_elf_hash_and_relocation_tables) {
validate_compatibility_of_native_library("libc.so");
validate_compatibility_of_native_library("liblog.so");
validate_compatibility_of_native_library("libstdc++.so");
validate_compatibility_of_native_library("libdl.so");
validate_compatibility_of_native_library("libm.so");
validate_compatibility_of_native_library("libz.so");
validate_compatibility_of_native_library("libjnigraphics.so");
}
#endif // defined(__arm__)
TEST(dlfcn, dlopen_invalid_rw_load_segment) {
const std::string libpath = GetTestlibRoot() +
"/" + kPrebuiltElfDir +
"/libtest_invalid-rw_load_segment.so";
void* handle = dlopen(libpath.c_str(), RTLD_NOW);
ASSERT_TRUE(handle == nullptr);
std::string expected_dlerror = std::string("dlopen failed: \"") + libpath + "\": W+E load segments are not allowed";
ASSERT_STREQ(expected_dlerror.c_str(), dlerror());
}
TEST(dlfcn, dlopen_invalid_unaligned_shdr_offset) {
const std::string libpath = GetTestlibRoot() +
"/" + kPrebuiltElfDir +
"/libtest_invalid-unaligned_shdr_offset.so";
void* handle = dlopen(libpath.c_str(), RTLD_NOW);
ASSERT_TRUE(handle == nullptr);
std::string expected_dlerror = std::string("dlopen failed: \"") + libpath + "\" has invalid shdr offset/size: ";
ASSERT_SUBSTR(expected_dlerror.c_str(), dlerror());
}
TEST(dlfcn, dlopen_invalid_zero_shentsize) {
const std::string libpath = GetTestlibRoot() +
"/" + kPrebuiltElfDir +
"/libtest_invalid-zero_shentsize.so";
void* handle = dlopen(libpath.c_str(), RTLD_NOW);
ASSERT_TRUE(handle == nullptr);
std::string expected_dlerror = std::string("dlopen failed: \"") + libpath + "\" has unsupported e_shentsize: 0x0 (expected 0x";
ASSERT_SUBSTR(expected_dlerror.c_str(), dlerror());
}
TEST(dlfcn, dlopen_invalid_zero_shstrndx) {
const std::string libpath = GetTestlibRoot() +
"/" + kPrebuiltElfDir +
"/libtest_invalid-zero_shstrndx.so";
void* handle = dlopen(libpath.c_str(), RTLD_NOW);
ASSERT_TRUE(handle == nullptr);
std::string expected_dlerror = std::string("dlopen failed: \"") + libpath + "\" has invalid e_shstrndx";
ASSERT_STREQ(expected_dlerror.c_str(), dlerror());
}
TEST(dlfcn, dlopen_invalid_empty_shdr_table) {
const std::string libpath = GetTestlibRoot() +
"/" + kPrebuiltElfDir +
"/libtest_invalid-empty_shdr_table.so";
void* handle = dlopen(libpath.c_str(), RTLD_NOW);
ASSERT_TRUE(handle == nullptr);
std::string expected_dlerror = std::string("dlopen failed: \"") + libpath + "\" has no section headers";
ASSERT_STREQ(expected_dlerror.c_str(), dlerror());
}
TEST(dlfcn, dlopen_invalid_zero_shdr_table_offset) {
const std::string libpath = GetTestlibRoot() +
"/" + kPrebuiltElfDir +
"/libtest_invalid-zero_shdr_table_offset.so";
void* handle = dlopen(libpath.c_str(), RTLD_NOW);
ASSERT_TRUE(handle == nullptr);
std::string expected_dlerror = std::string("dlopen failed: \"") + libpath + "\" has invalid shdr offset/size: 0/";
ASSERT_SUBSTR(expected_dlerror.c_str(), dlerror());
}
TEST(dlfcn, dlopen_invalid_zero_shdr_table_content) {
const std::string libpath = GetTestlibRoot() +
"/" + kPrebuiltElfDir +
"/libtest_invalid-zero_shdr_table_content.so";
void* handle = dlopen(libpath.c_str(), RTLD_NOW);
ASSERT_TRUE(handle == nullptr);
std::string expected_dlerror = std::string("dlopen failed: \"") + libpath + "\" .dynamic section header was not found";
ASSERT_SUBSTR(expected_dlerror.c_str(), dlerror());
}
TEST(dlfcn, dlopen_invalid_textrels) {
const std::string libpath = GetTestlibRoot() +
"/" + kPrebuiltElfDir +
"/libtest_invalid-textrels.so";
void* handle = dlopen(libpath.c_str(), RTLD_NOW);
ASSERT_TRUE(handle == nullptr);
std::string expected_dlerror = std::string("dlopen failed: \"") + libpath + "\" has text relocations";
ASSERT_SUBSTR(expected_dlerror.c_str(), dlerror());
}
TEST(dlfcn, dlopen_invalid_textrels2) {
const std::string libpath = GetTestlibRoot() +
"/" + kPrebuiltElfDir +
"/libtest_invalid-textrels2.so";
void* handle = dlopen(libpath.c_str(), RTLD_NOW);
ASSERT_TRUE(handle == nullptr);
std::string expected_dlerror = std::string("dlopen failed: \"") + libpath + "\" has text relocations";
ASSERT_SUBSTR(expected_dlerror.c_str(), dlerror());
}
TEST(dlfcn, dlopen_df_1_global) {
void* handle = dlopen("libtest_dlopen_df_1_global.so", RTLD_NOW);
ASSERT_TRUE(handle != nullptr) << dlerror();
}
TEST(dlfcn, segment_gap) {
void* handle = dlopen("libsegment_gap_outer.so", RTLD_NOW);
ASSERT_TRUE(handle != nullptr) << dlerror();
auto get_inner = reinterpret_cast<void* (*)()>(dlsym(handle, "get_inner"));
void* inner = get_inner();
(void)inner;
#if __arm__
int count;
_Unwind_Ptr outer_exidx = dl_unwind_find_exidx(reinterpret_cast<_Unwind_Ptr>(get_inner), &count);
_Unwind_Ptr inner_exidx = dl_unwind_find_exidx(reinterpret_cast<_Unwind_Ptr>(inner), &count);
EXPECT_NE(0u, outer_exidx);
EXPECT_NE(0u, inner_exidx);
EXPECT_NE(inner_exidx, outer_exidx);
#endif
Dl_info info;
int rc = dladdr(inner, &info);
ASSERT_NE(rc, 0);
EXPECT_NE(nullptr, strstr(info.dli_fname, "libsegment_gap_inner.so"));
}
#endif