ladybird/Userland/crash.cpp
Lenny Maiorani 765936ebae
Everywhere: Switch from (void) to [[maybe_unused]] (#4473)
Problem:
- `(void)` simply casts the expression to void. This is understood to
  indicate that it is ignored, but this is really a compiler trick to
  get the compiler to not generate a warning.

Solution:
- Use the `[[maybe_unused]]` attribute to indicate the value is unused.

Note:
- Functions taking a `(void)` argument list have also been changed to
  `()` because this is not needed and shows up in the same grep
  command.
2020-12-21 00:09:48 +01:00

358 lines
14 KiB
C++

/*
* Copyright (c) 2018-2020, Andreas Kling <kling@serenityos.org>
* Copyright (c) 2019-2020, Shannon Booth <shannon.ml.booth@gmail.com>
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
*
* 1. Redistributions of source code must retain the above copyright notice, this
* list of conditions and the following disclaimer.
*
* 2. 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 HOLDER 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 <AK/Function.h>
#include <AK/String.h>
#include <Kernel/API/Syscall.h>
#include <Kernel/IO.h>
#include <LibCore/ArgsParser.h>
#include <stdio.h>
#include <stdlib.h>
#include <sys/mman.h>
#include <sys/wait.h>
#pragma GCC optimize("O0")
class Crash {
public:
enum class RunType {
UsingChildProcess,
UsingCurrentProcess,
};
enum class Failure {
DidNotCrash,
UnexpectedError,
};
Crash(String test_type, Function<Crash::Failure()> crash_function)
: m_type(test_type)
, m_crash_function(move(crash_function))
{
}
void run(RunType run_type)
{
printf("\x1B[33mTesting\x1B[0m: \"%s\"\n", m_type.characters());
auto run_crash_and_print_if_error = [this]() {
auto failure = m_crash_function();
// If we got here something went wrong
printf("\x1B[31mFAIL\x1B[0m: ");
switch (failure) {
case Failure::DidNotCrash:
printf("Did not crash!\n");
break;
case Failure::UnexpectedError:
printf("Unexpected error!\n");
break;
default:
ASSERT_NOT_REACHED();
}
};
if (run_type == RunType::UsingCurrentProcess) {
run_crash_and_print_if_error();
} else {
// Run the test in a child process so that we do not crash the crash program :^)
pid_t pid = fork();
if (pid < 0) {
perror("fork");
ASSERT_NOT_REACHED();
} else if (pid == 0) {
run_crash_and_print_if_error();
exit(0);
}
int status;
waitpid(pid, &status, 0);
if (WIFSIGNALED(status))
printf("\x1B[32mPASS\x1B[0m: Terminated with signal %d\n", WTERMSIG(status));
}
}
private:
String m_type;
Function<Crash::Failure()> m_crash_function;
};
int main(int argc, char** argv)
{
bool do_all_crash_types = false;
bool do_segmentation_violation = false;
bool do_division_by_zero = false;
bool do_illegal_instruction = false;
bool do_abort = false;
bool do_write_to_uninitialized_malloc_memory = false;
bool do_write_to_freed_memory = false;
bool do_write_to_read_only_memory = false;
bool do_read_from_uninitialized_malloc_memory = false;
bool do_read_from_freed_memory = false;
bool do_invalid_stack_pointer_on_syscall = false;
bool do_invalid_stack_pointer_on_page_fault = false;
bool do_syscall_from_writeable_memory = false;
bool do_write_to_freed_memory_still_cached_by_malloc = false;
bool do_read_from_freed_memory_still_cached_by_malloc = false;
bool do_execute_non_executable_memory = false;
bool do_trigger_user_mode_instruction_prevention = false;
bool do_use_io_instruction = false;
bool do_read_cpu_counter = false;
auto args_parser = Core::ArgsParser();
args_parser.set_general_help(
"Exercise error-handling paths of the execution environment "
"(i.e., Kernel or UE) by crashing in many different ways.");
args_parser.add_option(do_all_crash_types, "Test that all of the following crash types crash as expected", nullptr, 'A');
args_parser.add_option(do_segmentation_violation, "Perform a segmentation violation by dereferencing an invalid pointer", nullptr, 's');
args_parser.add_option(do_division_by_zero, "Perform a division by zero", nullptr, 'd');
args_parser.add_option(do_illegal_instruction, "Execute an illegal CPU instruction", nullptr, 'i');
args_parser.add_option(do_abort, "Call `abort()`", nullptr, 'a');
args_parser.add_option(do_read_from_uninitialized_malloc_memory, "Read a pointer from uninitialized malloc memory, then read from it", nullptr, 'm');
args_parser.add_option(do_read_from_freed_memory, "Read a pointer from memory freed using `free()`, then read from it", nullptr, 'f');
args_parser.add_option(do_write_to_uninitialized_malloc_memory, "Read a pointer from uninitialized malloc memory, then write to it", nullptr, 'M');
args_parser.add_option(do_write_to_freed_memory, "Read a pointer from memory freed using `free()`, then write to it", nullptr, 'F');
args_parser.add_option(do_write_to_read_only_memory, "Write to read-only memory", nullptr, 'r');
args_parser.add_option(do_invalid_stack_pointer_on_syscall, "Make a syscall while using an invalid stack pointer", nullptr, 'T');
args_parser.add_option(do_invalid_stack_pointer_on_page_fault, "Trigger a page fault while using an invalid stack pointer", nullptr, 't');
args_parser.add_option(do_syscall_from_writeable_memory, "Make a syscall from writeable memory", nullptr, 'S');
args_parser.add_option(do_write_to_freed_memory_still_cached_by_malloc, "Read from recently freed memory (tests an opportunistic malloc guard)", nullptr, 'x');
args_parser.add_option(do_read_from_freed_memory_still_cached_by_malloc, "Write to recently free memory (tests an opportunistic malloc guard)", nullptr, 'y');
args_parser.add_option(do_execute_non_executable_memory, "Attempt to execute non-executable memory (not mapped with PROT_EXEC)", nullptr, 'X');
args_parser.add_option(do_trigger_user_mode_instruction_prevention, "Attempt to trigger an x86 User Mode Instruction Prevention fault", nullptr, 'U');
args_parser.add_option(do_use_io_instruction, "Use an x86 I/O instruction in userspace", nullptr, 'I');
args_parser.add_option(do_read_cpu_counter, "Read the x86 TSC (Time Stamp Counter) directly", nullptr, 'c');
if (argc != 2) {
args_parser.print_usage(stderr, argv[0]);
exit(1);
}
args_parser.parse(argc, argv);
Crash::RunType run_type = do_all_crash_types ? Crash::RunType::UsingChildProcess
: Crash::RunType::UsingCurrentProcess;
if (do_segmentation_violation || do_all_crash_types) {
Crash("Segmentation violation", []() {
volatile int* crashme = nullptr;
*crashme = 0xbeef;
return Crash::Failure::DidNotCrash;
}).run(run_type);
}
if (do_division_by_zero || do_all_crash_types) {
Crash("Division by zero", []() {
volatile int lala = 10;
volatile int zero = 0;
[[maybe_unused]] volatile int test = lala / zero;
return Crash::Failure::DidNotCrash;
}).run(run_type);
}
if (do_illegal_instruction || do_all_crash_types) {
Crash("Illegal instruction", []() {
asm volatile("ud2");
return Crash::Failure::DidNotCrash;
}).run(run_type);
}
if (do_abort || do_all_crash_types) {
Crash("Abort", []() {
abort();
return Crash::Failure::DidNotCrash;
}).run(run_type);
}
if (do_read_from_uninitialized_malloc_memory || do_all_crash_types) {
Crash("Read from uninitialized malloc memory", []() {
auto* uninitialized_memory = (volatile u32**)malloc(1024);
if (!uninitialized_memory)
return Crash::Failure::UnexpectedError;
[[maybe_unused]] volatile auto x = uninitialized_memory[0][0];
return Crash::Failure::DidNotCrash;
}).run(run_type);
}
if (do_read_from_uninitialized_malloc_memory || do_all_crash_types) {
Crash("Read from freed memory", []() {
auto* uninitialized_memory = (volatile u32**)malloc(1024);
if (!uninitialized_memory)
return Crash::Failure::UnexpectedError;
free(uninitialized_memory);
[[maybe_unused]] volatile auto x = uninitialized_memory[4][0];
return Crash::Failure::DidNotCrash;
}).run(run_type);
}
if (do_write_to_uninitialized_malloc_memory || do_all_crash_types) {
Crash("Write to uninitialized malloc memory", []() {
auto* uninitialized_memory = (volatile u32**)malloc(1024);
if (!uninitialized_memory)
return Crash::Failure::UnexpectedError;
uninitialized_memory[4][0] = 1;
return Crash::Failure::DidNotCrash;
}).run(run_type);
}
if (do_write_to_freed_memory || do_all_crash_types) {
Crash("Write to freed memory", []() {
auto* uninitialized_memory = (volatile u32**)malloc(1024);
if (!uninitialized_memory)
return Crash::Failure::UnexpectedError;
free(uninitialized_memory);
uninitialized_memory[4][0] = 1;
return Crash::Failure::DidNotCrash;
}).run(run_type);
}
if (do_write_to_read_only_memory || do_all_crash_types) {
Crash("Write to read only memory", []() {
auto* ptr = (u8*)mmap(nullptr, 4096, PROT_READ | PROT_WRITE, MAP_ANON, 0, 0);
if (ptr != MAP_FAILED)
return Crash::Failure::UnexpectedError;
*ptr = 'x'; // This should work fine.
int rc = mprotect(ptr, 4096, PROT_READ);
if (rc != 0 || *ptr != 'x')
return Crash::Failure::UnexpectedError;
*ptr = 'y'; // This should crash!
return Crash::Failure::DidNotCrash;
}).run(run_type);
}
if (do_invalid_stack_pointer_on_syscall || do_all_crash_types) {
Crash("Invalid stack pointer on syscall", []() {
u8* makeshift_stack = (u8*)mmap(nullptr, 0, PROT_READ | PROT_WRITE, MAP_ANONYMOUS | MAP_PRIVATE | MAP_STACK, 0, 0);
if (!makeshift_stack)
return Crash::Failure::UnexpectedError;
u8* makeshift_esp = makeshift_stack + 2048;
asm volatile("mov %%eax, %%esp" ::"a"(makeshift_esp));
getuid();
dbgprintf("Survived syscall with MAP_STACK stack\n");
u8* bad_stack = (u8*)mmap(nullptr, PAGE_SIZE, PROT_READ | PROT_WRITE, MAP_ANONYMOUS | MAP_PRIVATE, 0, 0);
if (!bad_stack)
return Crash::Failure::UnexpectedError;
u8* bad_esp = bad_stack + 2048;
asm volatile("mov %%eax, %%esp" ::"a"(bad_esp));
getuid();
return Crash::Failure::DidNotCrash;
}).run(run_type);
}
if (do_invalid_stack_pointer_on_page_fault || do_all_crash_types) {
Crash("Invalid stack pointer on page fault", []() {
u8* bad_stack = (u8*)mmap(nullptr, PAGE_SIZE, PROT_READ | PROT_WRITE, MAP_ANONYMOUS | MAP_PRIVATE, 0, 0);
if (!bad_stack)
return Crash::Failure::UnexpectedError;
u8* bad_esp = bad_stack + 2048;
asm volatile("mov %%eax, %%esp" ::"a"(bad_esp));
asm volatile("pushl $0");
return Crash::Failure::DidNotCrash;
}).run(run_type);
}
if (do_syscall_from_writeable_memory || do_all_crash_types) {
Crash("Syscall from writable memory", []() {
u8 buffer[] = { 0xb8, Syscall::SC_getuid, 0, 0, 0, 0xcd, 0x82 };
((void (*)())buffer)();
return Crash::Failure::DidNotCrash;
}).run(run_type);
}
if (do_read_from_freed_memory_still_cached_by_malloc || do_all_crash_types) {
Crash("Read from memory still cached by malloc", []() {
auto* ptr = (u8*)malloc(1024);
if (!ptr)
return Crash::Failure::UnexpectedError;
free(ptr);
dbgprintf("ptr = %p\n", ptr);
[[maybe_unused]] volatile auto foo = *ptr;
return Crash::Failure::DidNotCrash;
}).run(run_type);
}
if (do_write_to_freed_memory_still_cached_by_malloc || do_all_crash_types) {
Crash("Write to freed memory still cached by malloc", []() {
auto* ptr = (u8*)malloc(1024);
if (!ptr)
return Crash::Failure::UnexpectedError;
free(ptr);
dbgprintf("ptr = %p\n", ptr);
*ptr = 'x';
return Crash::Failure::DidNotCrash;
}).run(run_type);
}
if (do_execute_non_executable_memory || do_all_crash_types) {
Crash("Execute non executable memory", []() {
auto* ptr = (u8*)mmap(nullptr, PAGE_SIZE, PROT_READ | PROT_WRITE, MAP_ANONYMOUS | MAP_PRIVATE, 0, 0);
if (ptr == MAP_FAILED)
return Crash::Failure::UnexpectedError;
ptr[0] = 0xc3; // ret
typedef void* (*CrashyFunctionPtr)();
((CrashyFunctionPtr)ptr)();
return Crash::Failure::DidNotCrash;
}).run(run_type);
}
if (do_trigger_user_mode_instruction_prevention || do_all_crash_types) {
Crash("Trigger x86 User Mode Instruction Prevention", []() {
asm volatile("str %eax");
return Crash::Failure::DidNotCrash;
}).run(run_type);
}
if (do_use_io_instruction || do_all_crash_types) {
Crash("Attempt to use an I/O instruction", [] {
u8 keyboard_status = IO::in8(0x64);
printf("Keyboard status: %#02x\n", keyboard_status);
return Crash::Failure::DidNotCrash;
}).run(run_type);
}
if (do_read_cpu_counter || do_all_crash_types) {
Crash("Read the CPU timestamp counter", [] {
asm volatile("rdtsc");
return Crash::Failure::DidNotCrash;
}).run(run_type);
}
return 0;
}