/* init.cpp - Pre-init Magisk support * * This code has to be compiled statically to work properly. * * To unify Magisk support for both legacy "normal" devices and new skip_initramfs devices, * magisk binary compilation is split into two parts - first part only compiles "magisk". * The python build script will load the magisk main binary and compress with lzma2, dumping * the results into "dump.h". The "magisk" binary is embedded into this binary, and will * get extracted to the overlay folder along with init.magisk.rc. * * This tool does all pre-init operations to setup a Magisk environment, which pathces rootfs * on the fly, providing fundamental support such as init, init.rc, and sepolicy patching. * * Magiskinit is also responsible for constructing a proper rootfs on skip_initramfs devices. * On skip_initramfs devices, it will parse kernel cmdline, mount sysfs, parse through * uevent files to make the system (or vendor if available) block device node, then copy * rootfs files from system. * * This tool will be replaced with the real init to continue the boot process, but hardlinks are * preserved as it also provides CLI for sepolicy patching (magiskpolicy) */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "binaries.h" #ifdef USE_64BIT #include "binaries_arch64.h" #else #include "binaries_arch.h" #endif #include "magiskrc.h" #define DEFAULT_DT_DIR "/proc/device-tree/firmware/android" static int test_main(int argc, char *argv[]); constexpr const char *init_applet[] = { "magiskpolicy", "supolicy", "init_test", nullptr }; constexpr int (*init_applet_main[])(int, char *[]) = { magiskpolicy_main, magiskpolicy_main, test_main, nullptr }; struct cmdline { bool system_as_root; char slot[3]; char dt_dir[128]; }; struct device { dev_t major; dev_t minor; char devname[32]; char partname[32]; char path[64]; }; struct raw_data { void *buf; size_t sz; }; static bool unxz(int fd, const uint8_t *buf, size_t size) { uint8_t out[8192]; xz_crc32_init(); struct xz_dec *dec = xz_dec_init(XZ_DYNALLOC, 1 << 26); struct xz_buf b = { .in = buf, .in_pos = 0, .in_size = size, .out = out, .out_pos = 0, .out_size = sizeof(out) }; enum xz_ret ret; do { ret = xz_dec_run(dec, &b); if (ret != XZ_OK && ret != XZ_STREAM_END) return false; write(fd, out, b.out_pos); b.out_pos = 0; } while (b.in_pos != size); return true; } static void decompress_ramdisk() { constexpr char tmp[] = "tmp.cpio"; constexpr char ramdisk_xz[] = "ramdisk.cpio.xz"; if (access(ramdisk_xz, F_OK)) return; uint8_t *buf; size_t sz; mmap_ro(ramdisk_xz, buf, sz); int fd = open(tmp, O_WRONLY | O_CREAT | O_TRUNC | O_CLOEXEC); unxz(fd, buf, sz); munmap(buf, sz); close(fd); cpio_mmap cpio(tmp); cpio.extract(); unlink(tmp); unlink(ramdisk_xz); } static int dump_magisk(const char *path, mode_t mode) { int fd = open(path, O_WRONLY | O_CREAT | O_TRUNC | O_CLOEXEC, mode); if (fd < 0) return 1; if (!unxz(fd, magisk_xz, sizeof(magisk_xz))) return 1; close(fd); return 0; } static int dump_manager(const char *path, mode_t mode) { int fd = open(path, O_WRONLY | O_CREAT | O_TRUNC | O_CLOEXEC, mode); if (fd < 0) return 1; if (!unxz(fd, manager_xz, sizeof(manager_xz))) return 1; close(fd); return 0; } class MagiskInit { private: cmdline cmd{}; raw_data init{}; raw_data config{}; int root = -1; char **argv; bool load_sepol = false; bool mnt_system = false; bool mnt_vendor = false; bool mnt_product = false; bool mnt_odm = false; void load_kernel_info(); void preset(); void early_mount(); void setup_rootfs(); bool read_dt_fstab(const char *mnt_point, char *partname, char *partfs); bool patch_sepolicy(); void cleanup(); public: explicit MagiskInit(char *argv[]) : argv(argv) {} void setup_overlay(); void re_exec_init(); void start(); void test(); }; static inline void parse_cmdline(const std::function &fn) { char cmdline[4096]; int fd = open("/proc/cmdline", O_RDONLY | O_CLOEXEC); cmdline[read(fd, cmdline, sizeof(cmdline))] = '\0'; close(fd); char *tok, *eql, *tmp, *saveptr; saveptr = cmdline; while ((tok = strtok_r(nullptr, " \n", &saveptr)) != nullptr) { eql = strchr(tok, '='); if (eql) { *eql = '\0'; if (eql[1] == '"') { tmp = strchr(saveptr, '"'); if (tmp != nullptr) { *tmp = '\0'; saveptr[-1] = ' '; saveptr = tmp + 1; eql++; } } fn(tok, eql + 1); } else { fn(tok, ""); } } } void MagiskInit::load_kernel_info() { // Communicate with kernel using procfs and sysfs mkdir("/proc", 0755); xmount("proc", "/proc", "proc", 0, nullptr); mkdir("/sys", 0755); xmount("sysfs", "/sys", "sysfs", 0, nullptr); char cmdline[4096]; int fd = open("/proc/cmdline", O_RDONLY | O_CLOEXEC); cmdline[read(fd, cmdline, sizeof(cmdline))] = '\0'; close(fd); bool skip_initramfs = false; bool enter_recovery = false; bool kirin = false; parse_cmdline([&](auto key, auto value) -> void { LOGD("cmdline: [%s]=[%s]\n", key.data(), value); if (key == "androidboot.slot_suffix") { strcpy(cmd.slot, value); } else if (key == "androidboot.slot") { cmd.slot[0] = '_'; strcpy(cmd.slot + 1, value); } else if (key == "skip_initramfs") { skip_initramfs = true; } else if (key == "androidboot.android_dt_dir") { strcpy(cmd.dt_dir, value); } else if (key == "enter_recovery") { enter_recovery = value[0] == '1'; } else if (key == "androidboot.hardware") { kirin = strstr(value, "kirin") || strstr(value, "hi3660"); } }); parse_prop_file("/.backup/.magisk", [&](auto key, auto value) -> bool { if (key == "RECOVERYMODE" && value == "true") cmd.system_as_root = true; return true; }); if (kirin && enter_recovery) { // Inform that we are actually booting as recovery if (!cmd.system_as_root) { if (FILE *f = fopen("/.backup/.magisk", "ae"); f) { fprintf(f, "RECOVERYMODE=true\n"); fclose(f); } cmd.system_as_root = true; } } cmd.system_as_root |= skip_initramfs; if (cmd.dt_dir[0] == '\0') strcpy(cmd.dt_dir, DEFAULT_DT_DIR); LOGD("system_as_root[%d] slot[%s] dt_dir[%s]\n", cmd.system_as_root, cmd.slot, cmd.dt_dir); } void MagiskInit::preset() { root = open("/", O_RDONLY | O_CLOEXEC); if (cmd.system_as_root) { // Clear rootfs const char *excl[] = { "overlay", "proc", "sys", nullptr }; excl_list = excl; frm_rf(root); excl_list = nullptr; } else { decompress_ramdisk(); // Revert original init binary rename("/.backup/init", "/init"); rm_rf("/.backup"); // Do not go further if device is booting into recovery if (access("/sbin/recovery", F_OK) == 0) re_exec_init(); } } static inline void parse_device(struct device *dev, const char *uevent) { dev->partname[0] = '\0'; FILE *fp = xfopen(uevent, "r"); char buf[64]; while (fgets(buf, sizeof(buf), fp)) { if (strncmp(buf, "MAJOR", 5) == 0) { sscanf(buf, "MAJOR=%ld", (long*) &dev->major); } else if (strncmp(buf, "MINOR", 5) == 0) { sscanf(buf, "MINOR=%ld", (long*) &dev->minor); } else if (strncmp(buf, "DEVNAME", 7) == 0) { sscanf(buf, "DEVNAME=%s", dev->devname); } else if (strncmp(buf, "PARTNAME", 8) == 0) { sscanf(buf, "PARTNAME=%s", dev->partname); } } fclose(fp); LOGD("%s [%s] (%u, %u)\n", dev->devname, dev->partname, (unsigned) dev->major, (unsigned) dev->minor); } static bool setup_block(struct device *dev, const char *partname) { char path[128]; struct dirent *entry; DIR *dir = opendir("/sys/dev/block"); if (dir == nullptr) return false; bool found = false; while ((entry = readdir(dir))) { if (strcmp(entry->d_name, ".") == 0 || strcmp(entry->d_name, "..") == 0) continue; sprintf(path, "/sys/dev/block/%s/uevent", entry->d_name); parse_device(dev, path); if (strcasecmp(dev->partname, partname) == 0) { sprintf(dev->path, "/dev/block/%s", dev->devname); found = true; break; } } closedir(dir); if (!found) return false; mkdir("/dev", 0755); mkdir("/dev/block", 0755); mknod(dev->path, S_IFBLK | 0600, makedev(dev->major, dev->minor)); return true; } static inline bool is_lnk(const char *name) { struct stat st; if (lstat(name, &st)) return false; return S_ISLNK(st.st_mode); } #define link_root(part) \ if (is_lnk("/system_root" part)) \ cp_afc("/system_root" part, part) #define mount_root(part) \ if (!is_lnk("/" #part) && read_dt_fstab(#part, partname, fstype)) { \ setup_block(&dev, partname); \ xmkdir("/" #part, 0755); \ xmount(dev.path, "/" #part, fstype, MS_RDONLY, nullptr); \ mnt_##part = true; \ } void MagiskInit::early_mount() { struct device dev; char partname[32]; char fstype[32]; if (cmd.system_as_root) { sprintf(partname, "system%s", cmd.slot); setup_block(&dev, partname); xmkdir("/system_root", 0755); xmount(dev.path, "/system_root", "ext4", MS_RDONLY, nullptr); xmkdir("/system", 0755); xmount("/system_root/system", "/system", nullptr, MS_BIND, nullptr); // Android Q if (is_lnk("/system_root/init")) load_sepol = true; // System-as-root with monolithic sepolicy if (access("/system_root/sepolicy", F_OK) == 0) cp_afc("/system_root/sepolicy", "/sepolicy"); // Copy if these partitions are symlinks link_root("/vendor"); link_root("/product"); link_root("/odm"); } else { mount_root(system); } mount_root(vendor); mount_root(product); mount_root(odm); } void MagiskInit::setup_rootfs() { bool patch_init = patch_sepolicy(); if (cmd.system_as_root) { // Clone rootfs except /system int system_root = open("/system_root", O_RDONLY | O_CLOEXEC); const char *excl[] = { "system", nullptr }; excl_list = excl; clone_dir(system_root, root); close(system_root); excl_list = nullptr; } // Override /sepolicy if exist rename("/magisk_sepolicy", "/sepolicy"); if (patch_init) { constexpr char SYSTEM_INIT[] = "/system/bin/init"; // If init is symlink, copy it to rootfs so we can patch struct stat st; lstat("/init", &st); if (S_ISLNK(st.st_mode)) cp_afc(SYSTEM_INIT, "/init"); char *addr; size_t size; mmap_rw("/init", addr, size); for (char *p = addr; p < addr + size; ++p) { if (memcmp(p, SPLIT_PLAT_CIL, sizeof(SPLIT_PLAT_CIL)) == 0) { // Force init to load /sepolicy memset(p, 'x', sizeof(SPLIT_PLAT_CIL) - 1); p += sizeof(SPLIT_PLAT_CIL) - 1; } else if (memcmp(p, SYSTEM_INIT, sizeof(SYSTEM_INIT)) == 0) { // Force execute /init instead of /system/bin/init strcpy(p, "/init"); p += sizeof(SYSTEM_INIT) - 1; } } munmap(addr, size); } // Handle ramdisk overlays int fd = open("/overlay", O_RDONLY | O_CLOEXEC); if (fd >= 0) { mv_dir(fd, root); close(fd); rmdir("/overlay"); } // Patch init.rc FILE *rc = xfopen("/init.p.rc", "we"); file_readline("/init.rc", [&](auto line) -> bool { // Do not start vaultkeeper if (str_contains(line, "start vaultkeeper")) return true; // Do not run flash_recovery if (str_starts(line, "service flash_recovery")) { fprintf(rc, "service flash_recovery /system/bin/xxxxx\n"); return true; } // Else just write the line fprintf(rc, "%s", line.data()); return true; }); char pfd_svc[8], ls_svc[8]; gen_rand_str(pfd_svc, sizeof(pfd_svc)); do { gen_rand_str(ls_svc, sizeof(ls_svc)); } while (strcmp(pfd_svc, ls_svc) == 0); fprintf(rc, magiskrc, pfd_svc, pfd_svc, ls_svc); fclose(rc); clone_attr("/init.rc", "/init.p.rc"); rename("/init.p.rc", "/init.rc"); // Don't let init run in init yet lsetfilecon("/init", "u:object_r:rootfs:s0"); // Create hardlink mirror of /sbin to /root mkdir("/root", 0750); clone_attr("/sbin", "/root"); int rootdir = xopen("/root", O_RDONLY | O_CLOEXEC); int sbin = xopen("/sbin", O_RDONLY | O_CLOEXEC); link_dir(sbin, rootdir); } bool MagiskInit::patch_sepolicy() { bool patch_init = false; if (access(SPLIT_PLAT_CIL, R_OK) == 0) patch_init = true; /* Split sepolicy */ else if (access("/sepolicy", R_OK) == 0) load_policydb("/sepolicy"); /* Monolithic sepolicy */ else return false; /* No SELinux */ // Mount selinuxfs to communicate with kernel xmount("selinuxfs", SELINUX_MNT, "selinuxfs", 0, nullptr); if (patch_init) load_split_cil(); sepol_magisk_rules(); sepol_allow(SEPOL_PROC_DOMAIN, ALL, ALL, ALL); dump_policydb("/magisk_sepolicy"); // Load policy to kernel so we can label rootfs if (load_sepol) dump_policydb(SELINUX_LOAD); // Remove OnePlus stupid debug sepolicy and use our own if (access("/sepolicy_debug", F_OK) == 0) { unlink("/sepolicy_debug"); link("/magisk_sepolicy", "/sepolicy_debug"); } // Enable selinux functions selinux_builtin_impl(); return patch_init; } bool MagiskInit::read_dt_fstab(const char *mnt_point, char *partname, char *partfs) { char path[128]; int fd; sprintf(path, "%s/fstab/%s/dev", cmd.dt_dir, mnt_point); if ((fd = xopen(path, O_RDONLY | O_CLOEXEC)) >= 0) { read(fd, path, sizeof(path)); close(fd); char *name = rtrim(strrchr(path, '/') + 1); sprintf(partname, "%s%s", name, strend(name, cmd.slot) ? cmd.slot : ""); sprintf(path, "%s/fstab/%s/type", cmd.dt_dir, mnt_point); if ((fd = xopen(path, O_RDONLY | O_CLOEXEC)) >= 0) { read(fd, partfs, 32); close(fd); return true; } } return false; } #define umount_root(part) \ if (mnt_##part) \ umount("/" #part); void MagiskInit::cleanup() { umount(SELINUX_MNT); umount("/sys"); umount("/proc"); umount_root(system); umount_root(vendor); umount_root(product); umount_root(odm); } static inline void patch_socket_name(const char *path) { uint8_t *buf; char name[sizeof(MAIN_SOCKET)]; size_t size; mmap_rw(path, buf, size); for (int i = 0; i < size; ++i) { if (memcmp(buf + i, MAIN_SOCKET, sizeof(MAIN_SOCKET)) == 0) { gen_rand_str(name, sizeof(name)); memcpy(buf + i, name, sizeof(name)); i += sizeof(name); } if (memcmp(buf + i, LOG_SOCKET, sizeof(LOG_SOCKET)) == 0) { gen_rand_str(name, sizeof(name)); memcpy(buf + i, name, sizeof(name)); i += sizeof(name); } } munmap(buf, size); } void MagiskInit::setup_overlay() { char path[128]; int fd; // Wait for early-init start while (access(EARLYINIT, F_OK) != 0) usleep(10); setcon("u:r:" SEPOL_PROC_DOMAIN ":s0"); unlink(EARLYINIT); // Mount the /sbin tmpfs overlay xmount("tmpfs", "/sbin", "tmpfs", 0, nullptr); chmod("/sbin", 0755); setfilecon("/sbin", "u:object_r:rootfs:s0"); // Dump binaries mkdir(MAGISKTMP, 0755); fd = xopen(MAGISKTMP "/config", O_WRONLY | O_CREAT, 0000); write(fd, config.buf, config.sz); close(fd); fd = xopen("/sbin/magiskinit", O_WRONLY | O_CREAT, 0755); write(fd, init.buf, init.sz); close(fd); dump_magisk("/sbin/magisk", 0755); patch_socket_name("/sbin/magisk"); setfilecon("/sbin/magisk", "u:object_r:" SEPOL_FILE_DOMAIN ":s0"); setfilecon("/sbin/magiskinit", "u:object_r:" SEPOL_FILE_DOMAIN ":s0"); // Create applet symlinks for (int i = 0; applet_names[i]; ++i) { sprintf(path, "/sbin/%s", applet_names[i]); xsymlink("/sbin/magisk", path); } for (int i = 0; init_applet[i]; ++i) { sprintf(path, "/sbin/%s", init_applet[i]); xsymlink("/sbin/magiskinit", path); } // Create symlinks pointing back to /root DIR *dir = xopendir("/root"); struct dirent *entry; fd = xopen("/sbin", O_RDONLY); while((entry = xreaddir(dir))) { if (strcmp(entry->d_name, ".") == 0 || strcmp(entry->d_name, "..") == 0) continue; snprintf(path, PATH_MAX, "/root/%s", entry->d_name); xsymlinkat(path, fd, entry->d_name); } closedir(dir); close(fd); close(xopen(EARLYINITDONE, O_RDONLY | O_CREAT, 0)); exit(0); } void MagiskInit::re_exec_init() { cleanup(); execv("/init", argv); exit(1); } void MagiskInit::start() { // Prevent file descriptor confusion mknod("/null", S_IFCHR | 0666, makedev(1, 3)); int null = open("/null", O_RDWR | O_CLOEXEC); unlink("/null"); xdup3(null, STDIN_FILENO, O_CLOEXEC); xdup3(null, STDOUT_FILENO, O_CLOEXEC); xdup3(null, STDERR_FILENO, O_CLOEXEC); if (null > STDERR_FILENO) close(null); load_kernel_info(); full_read("/init", &init.buf, &init.sz); full_read("/.backup/.magisk", &config.buf, &config.sz); preset(); early_mount(); setup_rootfs(); } void MagiskInit::test() { cmdline_logging(); log_cb.ex = nop_ex; chdir(dirname(argv[0])); chroot("."); chdir("/"); load_kernel_info(); preset(); early_mount(); setup_rootfs(); cleanup(); } static int test_main(int argc, char *argv[]) { MagiskInit init(argv); init.test(); return 0; } int main(int argc, char *argv[]) { umask(0); for (int i = 0; init_applet[i]; ++i) { if (strcmp(basename(argv[0]), init_applet[i]) == 0) return (*init_applet_main[i])(argc, argv); } if (argc > 1 && strcmp(argv[1], "-x") == 0) { if (strcmp(argv[2], "magisk") == 0) return dump_magisk(argv[3], 0755); else if (strcmp(argv[2], "manager") == 0) return dump_manager(argv[3], 0644); } MagiskInit init(argv); // Run the main routine init.start(); // Close all file descriptors for (int i = 0; i < 30; ++i) close(i); // Launch daemon to setup overlay if (fork_dont_care() == 0) init.setup_overlay(); init.re_exec_init(); }