#include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "allowlist.h" #include "arch.h" #include "klog.h" // IWYU pragma: keep #include "ksud.h" #include "kernel_compat.h" #include "selinux/selinux.h" static const char KERNEL_SU_RC[] = "\n" "on post-fs-data\n" " start logd\n" // We should wait for the post-fs-data finish " exec u:r:su:s0 root -- " KSUD_PATH " post-fs-data\n" "\n" "on nonencrypted\n" " exec u:r:su:s0 root -- " KSUD_PATH " services\n" "\n" "on property:vold.decrypt=trigger_restart_framework\n" " exec u:r:su:s0 root -- " KSUD_PATH " services\n" "\n" "on property:sys.boot_completed=1\n" " exec u:r:su:s0 root -- " KSUD_PATH " boot-completed\n" "\n" "\n"; static void stop_vfs_read_hook(); static void stop_execve_hook(); static void stop_input_hook(); #ifdef CONFIG_KPROBES static struct work_struct stop_vfs_read_work; static struct work_struct stop_execve_hook_work; static struct work_struct stop_input_hook_work; #else bool ksu_vfs_read_hook __read_mostly = true; bool ksu_execveat_hook __read_mostly = true; bool ksu_input_hook __read_mostly = true; #endif u32 ksu_devpts_sid; void on_post_fs_data(void) { static bool done = false; if (done) { pr_info("on_post_fs_data already done\n"); return; } done = true; pr_info("on_post_fs_data!\n"); ksu_load_allow_list(); // sanity check, this may influence the performance stop_input_hook(); ksu_devpts_sid = ksu_get_devpts_sid(); pr_info("devpts sid: %d\n", ksu_devpts_sid); } #define MAX_ARG_STRINGS 0x7FFFFFFF struct user_arg_ptr { #ifdef CONFIG_COMPAT bool is_compat; #endif union { const char __user *const __user *native; #ifdef CONFIG_COMPAT const compat_uptr_t __user *compat; #endif } ptr; }; static const char __user *get_user_arg_ptr(struct user_arg_ptr argv, int nr) { const char __user *native; #ifdef CONFIG_COMPAT if (unlikely(argv.is_compat)) { compat_uptr_t compat; if (get_user(compat, argv.ptr.compat + nr)) return ERR_PTR(-EFAULT); return compat_ptr(compat); } #endif if (get_user(native, argv.ptr.native + nr)) return ERR_PTR(-EFAULT); return native; } /* * count() counts the number of strings in array ARGV. */ /* * Make sure old GCC compiler can use __maybe_unused, * Test passed in 4.4.x ~ 4.9.x when use GCC. */ static int __maybe_unused count(struct user_arg_ptr argv, int max) { int i = 0; if (argv.ptr.native != NULL) { for (;;) { const char __user *p = get_user_arg_ptr(argv, i); if (!p) break; if (IS_ERR(p)) return -EFAULT; if (i >= max) return -E2BIG; ++i; if (fatal_signal_pending(current)) return -ERESTARTNOHAND; cond_resched(); } } return i; } // IMPORTANT NOTE: the call from execve_handler_pre WON'T provided correct value for envp and flags in GKI version int ksu_handle_execveat_ksud(int *fd, struct filename **filename_ptr, struct user_arg_ptr *argv, struct user_arg_ptr *envp, int *flags) { #ifndef CONFIG_KPROBES if (!ksu_execveat_hook) { return 0; } #endif struct filename *filename; static const char app_process[] = "/system/bin/app_process"; static bool first_app_process = true; /* This applies to versions Android 10+ */ static const char system_bin_init[] = "/system/bin/init"; /* This applies to versions between Android 6 ~ 9 */ static const char old_system_init[] = "/init"; static bool init_second_stage_executed = false; if (!filename_ptr) return 0; filename = *filename_ptr; if (IS_ERR(filename)) { return 0; } if (unlikely(!memcmp(filename->name, system_bin_init, sizeof(system_bin_init) - 1) && argv)) { // /system/bin/init executed int argc = count(*argv, MAX_ARG_STRINGS); pr_info("/system/bin/init argc: %d\n", argc); if (argc > 1 && !init_second_stage_executed) { const char __user *p = get_user_arg_ptr(*argv, 1); if (p && !IS_ERR(p)) { char first_arg[16]; ksu_strncpy_from_user_nofault( first_arg, p, sizeof(first_arg)); pr_info("/system/bin/init first arg: %s\n", first_arg); if (!strcmp(first_arg, "second_stage")) { pr_info("/system/bin/init second_stage executed\n"); apply_kernelsu_rules(); init_second_stage_executed = true; ksu_android_ns_fs_check(); } } else { pr_err("/system/bin/init parse args err!\n"); } } } else if (unlikely(!memcmp(filename->name, old_system_init, sizeof(old_system_init) - 1) && argv)) { // /init executed int argc = count(*argv, MAX_ARG_STRINGS); pr_info("/init argc: %d\n", argc); if (argc > 1 && !init_second_stage_executed) { /* This applies to versions between Android 6 ~ 7 */ const char __user *p = get_user_arg_ptr(*argv, 1); if (p && !IS_ERR(p)) { char first_arg[16]; ksu_strncpy_from_user_nofault( first_arg, p, sizeof(first_arg)); pr_info("/init first arg: %s\n", first_arg); if (!strcmp(first_arg, "--second-stage")) { pr_info("/init second_stage executed\n"); apply_kernelsu_rules(); init_second_stage_executed = true; ksu_android_ns_fs_check(); } } else { pr_err("/init parse args err!\n"); } } else if (argc == 1 && !init_second_stage_executed && envp) { /* This applies to versions between Android 8 ~ 9 */ int envc = count(*envp, MAX_ARG_STRINGS); if (envc > 0) { int n; for (n = 1; n <= envc; n++) { const char __user *p = get_user_arg_ptr(*envp, n); if (!p || IS_ERR(p)) { continue; } char env[256]; // Reading environment variable strings from user space if (ksu_strncpy_from_user_nofault( env, p, sizeof(env)) < 0) continue; // Parsing environment variable names and values char *env_name = env; char *env_value = strchr(env, '='); if (env_value == NULL) continue; // Replace equal sign with string terminator *env_value = '\0'; env_value++; // Check if the environment variable name and value are matching if (!strcmp(env_name, "INIT_SECOND_STAGE") && (!strcmp(env_value, "1") || !strcmp(env_value, "true"))) { pr_info("/init second_stage executed\n"); apply_kernelsu_rules(); init_second_stage_executed = true; ksu_android_ns_fs_check(); } } } } } if (unlikely(first_app_process && !memcmp(filename->name, app_process, sizeof(app_process) - 1))) { first_app_process = false; pr_info("exec app_process, /data prepared, second_stage: %d\n", init_second_stage_executed); on_post_fs_data(); // we keep this for old ksud stop_execve_hook(); } return 0; } static ssize_t (*orig_read)(struct file *, char __user *, size_t, loff_t *); static ssize_t (*orig_read_iter)(struct kiocb *, struct iov_iter *); static struct file_operations fops_proxy; static ssize_t read_count_append = 0; static ssize_t read_proxy(struct file *file, char __user *buf, size_t count, loff_t *pos) { bool first_read = file->f_pos == 0; ssize_t ret = orig_read(file, buf, count, pos); if (first_read) { pr_info("read_proxy append %ld + %ld\n", ret, read_count_append); ret += read_count_append; } return ret; } static ssize_t read_iter_proxy(struct kiocb *iocb, struct iov_iter *to) { bool first_read = iocb->ki_pos == 0; ssize_t ret = orig_read_iter(iocb, to); if (first_read) { pr_info("read_iter_proxy append %ld + %ld\n", ret, read_count_append); ret += read_count_append; } return ret; } int ksu_handle_vfs_read(struct file **file_ptr, char __user **buf_ptr, size_t *count_ptr, loff_t **pos) { #ifndef CONFIG_KPROBES if (!ksu_vfs_read_hook) { return 0; } #endif struct file *file; char __user *buf; size_t count; if (strcmp(current->comm, "init")) { // we are only interest in `init` process return 0; } file = *file_ptr; if (IS_ERR(file)) { return 0; } if (!d_is_reg(file->f_path.dentry)) { return 0; } const char *short_name = file->f_path.dentry->d_name.name; if (strcmp(short_name, "atrace.rc")) { // we are only interest `atrace.rc` file name file return 0; } char path[256]; char *dpath = d_path(&file->f_path, path, sizeof(path)); if (IS_ERR(dpath)) { return 0; } if (strcmp(dpath, "/system/etc/init/atrace.rc")) { return 0; } // we only process the first read static bool rc_inserted = false; if (rc_inserted) { // we don't need this kprobe, unregister it! stop_vfs_read_hook(); return 0; } rc_inserted = true; // now we can sure that the init process is reading // `/system/etc/init/atrace.rc` buf = *buf_ptr; count = *count_ptr; size_t rc_count = strlen(KERNEL_SU_RC); pr_info("vfs_read: %s, comm: %s, count: %zu, rc_count: %zu\n", dpath, current->comm, count, rc_count); if (count < rc_count) { pr_err("count: %zu < rc_count: %zu\n", count, rc_count); return 0; } size_t ret = copy_to_user(buf, KERNEL_SU_RC, rc_count); if (ret) { pr_err("copy ksud.rc failed: %zu\n", ret); return 0; } // we've succeed to insert ksud.rc, now we need to proxy the read and modify the result! // But, we can not modify the file_operations directly, because it's in read-only memory. // We just replace the whole file_operations with a proxy one. memcpy(&fops_proxy, file->f_op, sizeof(struct file_operations)); orig_read = file->f_op->read; if (orig_read) { fops_proxy.read = read_proxy; } orig_read_iter = file->f_op->read_iter; if (orig_read_iter) { fops_proxy.read_iter = read_iter_proxy; } // replace the file_operations file->f_op = &fops_proxy; read_count_append = rc_count; *buf_ptr = buf + rc_count; *count_ptr = count - rc_count; return 0; } int ksu_handle_sys_read(unsigned int fd, char __user **buf_ptr, size_t *count_ptr) { struct file *file = fget(fd); if (!file) { return 0; } int result = ksu_handle_vfs_read(&file, buf_ptr, count_ptr, NULL); fput(file); return result; } static unsigned int volumedown_pressed_count = 0; static bool is_volumedown_enough(unsigned int count) { return count >= 3; } int ksu_handle_input_handle_event(unsigned int *type, unsigned int *code, int *value) { #ifndef CONFIG_KPROBES if (!ksu_input_hook) { return 0; } #endif if (*type == EV_KEY && *code == KEY_VOLUMEDOWN) { int val = *value; pr_info("KEY_VOLUMEDOWN val: %d\n", val); if (val) { // key pressed, count it volumedown_pressed_count += 1; if (is_volumedown_enough(volumedown_pressed_count)) { stop_input_hook(); } } } return 0; } bool ksu_is_safe_mode() { static bool safe_mode = false; if (safe_mode) { // don't need to check again, userspace may call multiple times return true; } // stop hook first! stop_input_hook(); pr_info("volumedown_pressed_count: %d\n", volumedown_pressed_count); if (is_volumedown_enough(volumedown_pressed_count)) { // pressed over 3 times pr_info("KEY_VOLUMEDOWN pressed max times, safe mode detected!\n"); safe_mode = true; return true; } return false; } #ifdef CONFIG_KPROBES static int sys_execve_handler_pre(struct kprobe *p, struct pt_regs *regs) { struct pt_regs *real_regs = PT_REAL_REGS(regs); const char __user **filename_user = (const char **)&PT_REGS_PARM1(real_regs); const char __user *const __user *__argv = (const char __user *const __user *)PT_REGS_PARM2(real_regs); struct user_arg_ptr argv = { .ptr.native = __argv }; struct filename filename_in, *filename_p; char path[32]; if (!filename_user) return 0; memset(path, 0, sizeof(path)); ksu_strncpy_from_user_nofault(path, *filename_user, 32); filename_in.name = path; filename_p = &filename_in; return ksu_handle_execveat_ksud(AT_FDCWD, &filename_p, &argv, NULL, NULL); } static int sys_read_handler_pre(struct kprobe *p, struct pt_regs *regs) { struct pt_regs *real_regs = PT_REAL_REGS(regs); unsigned int fd = PT_REGS_PARM1(real_regs); char __user **buf_ptr = (char __user **)&PT_REGS_PARM2(real_regs); size_t count_ptr = (size_t *)&PT_REGS_PARM3(real_regs); return ksu_handle_sys_read(fd, buf_ptr, count_ptr); } static int input_handle_event_handler_pre(struct kprobe *p, struct pt_regs *regs) { unsigned int *type = (unsigned int *)&PT_REGS_PARM2(regs); unsigned int *code = (unsigned int *)&PT_REGS_PARM3(regs); int *value = (int *)&PT_REGS_CCALL_PARM4(regs); return ksu_handle_input_handle_event(type, code, value); } static struct kprobe execve_kp = { .symbol_name = SYS_EXECVE_SYMBOL, .pre_handler = sys_execve_handler_pre, }; static struct kprobe vfs_read_kp = { .symbol_name = SYS_READ_SYMBOL, .pre_handler = sys_read_handler_pre, }; static struct kprobe input_event_kp = { .symbol_name = "input_event", .pre_handler = input_handle_event_handler_pre, }; static void do_stop_vfs_read_hook(struct work_struct *work) { unregister_kprobe(&vfs_read_kp); } static void do_stop_execve_hook(struct work_struct *work) { unregister_kprobe(&execve_kp); } static void do_stop_input_hook(struct work_struct *work) { unregister_kprobe(&input_event_kp); } #endif static void stop_vfs_read_hook() { #ifdef CONFIG_KPROBES bool ret = schedule_work(&stop_vfs_read_work); pr_info("unregister vfs_read kprobe: %d!\n", ret); #else ksu_vfs_read_hook = false; pr_info("stop vfs_read_hook\n"); #endif } static void stop_execve_hook() { #ifdef CONFIG_KPROBES bool ret = schedule_work(&stop_execve_hook_work); pr_info("unregister execve kprobe: %d!\n", ret); #else ksu_execveat_hook = false; pr_info("stop execve_hook\n"); #endif } static void stop_input_hook() { static bool input_hook_stopped = false; if (input_hook_stopped) { return; } input_hook_stopped = true; #ifdef CONFIG_KPROBES bool ret = schedule_work(&stop_input_hook_work); pr_info("unregister input kprobe: %d!\n", ret); #else ksu_input_hook = false; pr_info("stop input_hook\n"); #endif } // ksud: module support void ksu_ksud_init() { #ifdef CONFIG_KPROBES int ret; ret = register_kprobe(&execve_kp); pr_info("ksud: execve_kp: %d\n", ret); ret = register_kprobe(&vfs_read_kp); pr_info("ksud: vfs_read_kp: %d\n", ret); ret = register_kprobe(&input_event_kp); pr_info("ksud: input_event_kp: %d\n", ret); INIT_WORK(&stop_vfs_read_work, do_stop_vfs_read_hook); INIT_WORK(&stop_execve_hook_work, do_stop_execve_hook); INIT_WORK(&stop_input_hook_work, do_stop_input_hook); #endif } void ksu_ksud_exit() { #ifdef CONFIG_KPROBES unregister_kprobe(&execve_kp); // this should be done before unregister vfs_read_kp // unregister_kprobe(&vfs_read_kp); unregister_kprobe(&input_event_kp); #endif }