/* post_fs_data.c - post-fs-data actions */ #include #include #include #include #include #include #include #include #include #include #include #include "magisk.h" #include "utils.h" #include "daemon.h" #include "resetprop.h" static char *buf, *buf2; static struct vector module_list; /****************** * Node structure * ******************/ // Precedence: MODULE > SKEL > DUMMY #define DO_NOTHING 0x0 /* intermediate node */ #define IS_DUMMY 0x1 /* mount from mirror */ #define IS_SKEL 0x2 /* mount from skeleton */ #define IS_MODULE 0x4 /* mount from module */ struct node_entry { const char *module; /* Only used when status & IS_MODULE */ char *name; uint8_t type; uint8_t status; struct node_entry *parent; struct vector *children; }; #define IS_DIR(n) (n->type == DT_DIR) #define IS_LNK(n) (n->type == DT_LNK) #define IS_REG(n) (n->type == DT_REG) /****************** * Image handling * ******************/ static char *loopsetup(const char *img) { char device[20]; struct loop_info64 info; int i, lfd, ffd; memset(&info, 0, sizeof(info)); // First get an empty loop device for (i = 0; i <= 7; ++i) { sprintf(device, "/dev/block/loop%d", i); lfd = xopen(device, O_RDWR); if (ioctl(lfd, LOOP_GET_STATUS64, &info) == -1) break; close(lfd); } if (i == 8) return NULL; ffd = xopen(img, O_RDWR); if (ioctl(lfd, LOOP_SET_FD, ffd) == -1) return NULL; strcpy((char *) info.lo_file_name, img); ioctl(lfd, LOOP_SET_STATUS64, &info); close(lfd); close(ffd); return strdup(device); } static char *mount_image(const char *img, const char *target) { char *device = loopsetup(img); if (device) xmount(device, target, "ext4", 0, NULL); return device; } static void umount_image(const char *target, const char *device) { xumount(target); int fd = xopen(device, O_RDWR); ioctl(fd, LOOP_CLR_FD); close(fd); } #define round_size(a) ((((a) / 32) + 2) * 32) static int merge_img(const char *source, const char *target) { if (access(source, F_OK) == -1) return 0; if (access(target, F_OK) == -1) { rename(source, target); return 0; } // resize target to worst case int s_used, s_total, t_used, t_total, n_total; get_img_size(source, &s_used, &s_total); get_img_size(target, &t_used, &t_total); n_total = round_size(s_used + t_used); if (n_total != t_total && resize_img(target, n_total)) return 1; xmkdir("/cache/source", 0755); xmkdir("/cache/target", 0755); char *s_loop, *t_loop; s_loop = mount_image(source, "/cache/source"); if (s_loop == NULL) return 1; t_loop = mount_image(target, "/cache/target"); if (t_loop == NULL) return 1; DIR *dir; struct dirent *entry; if (!(dir = opendir("/cache/source"))) return 1; while ((entry = xreaddir(dir))) { if (entry->d_type == DT_DIR) { if (strcmp(entry->d_name, ".") == 0 || strcmp(entry->d_name, "..") == 0 || strcmp(entry->d_name, ".core") == 0 || strcmp(entry->d_name, "lost+found") == 0) continue; // Cleanup old module snprintf(buf, PATH_MAX, "/cache/target/%s", entry->d_name); if (access(buf, F_OK) == 0) { LOGI("merge module %s\n", entry->d_name); rm_rf(buf); } } } closedir(dir); clone_dir("/cache/source", "/cache/target"); // Unmount all loop devices umount_image("/cache/source", s_loop); umount_image("/cache/target", t_loop); rmdir("/cache/source"); rmdir("/cache/target"); free(s_loop); free(t_loop); unlink(source); return 0; } static void trim_img(const char *img) { int used, total, new_size; get_img_size(img, &used, &total); new_size = round_size(used); if (new_size != total) resize_img(img, new_size); } /*********** * Scripts * ***********/ void exec_common_script(const char* stage) { DIR *dir; struct dirent *entry; snprintf(buf, PATH_MAX, "%s/%s.d", COREDIR, stage); if (!(dir = opendir(buf))) return; while ((entry = xreaddir(dir))) { if (entry->d_type == DT_REG) { snprintf(buf2, PATH_MAX, "%s/%s", buf, entry->d_name); if (access(buf2, X_OK) == -1) continue; LOGI("%s.d: exec [%s]\n", stage, entry->d_name); char *const command[] = { "sh", buf2, NULL }; int pid = run_command(0, NULL, "/system/bin/sh", command); if (pid != -1) waitpid(pid, NULL, 0); } } closedir(dir); } void exec_module_script(const char* stage) { char *module; vec_for_each(&module_list, module) { snprintf(buf, PATH_MAX, "%s/%s/%s.sh", MOUNTPOINT, module, stage); if (access(buf, F_OK) == -1) continue; LOGI("%s: exec [%s.sh]\n", module, stage); char *const command[] = { "sh", buf, NULL }; int pid = run_command(0, NULL, "/system/bin/sh", command); if (pid != -1) waitpid(pid, NULL, 0); } } /*************** * Magic Mount * ***************/ static char *get_full_path(struct node_entry *node) { char buffer[PATH_MAX], temp[PATH_MAX]; // Concat the paths struct node_entry *cur = node; strcpy(buffer, node->name); while (cur->parent) { strcpy(temp, buffer); snprintf(buffer, sizeof(buffer), "%s/%s", cur->parent->name, temp); cur = cur->parent; } return strdup(buffer); } // Free the node static void destroy_node(struct node_entry *node) { free(node->name); vec_destroy(node->children); free(node->children); free(node); } // Free the node and all children recursively static void destroy_subtree(struct node_entry *node) { // Never free parent, since it shall be freed by themselves struct node_entry *e; vec_for_each(node->children, e) { destroy_subtree(e); } destroy_node(node); } // Return the child static struct node_entry *insert_child(struct node_entry *p, struct node_entry *c) { c->parent = p; if (p->children == NULL) { p->children = xmalloc(sizeof(struct vector)); vec_init(p->children); } struct node_entry *e; vec_for_each(p->children, e) { if (strcmp(e->name, c->name) == 0) { // Exist duplicate if (c->status > e->status) { // Precedence is higher, replace with new node c->children = e->children; // Preserve all children free(e->name); free(e); vec_entry(p->children)[_] = c; return c; } else { // Free the new entry, return old destroy_node(c); return e; } } } // New entry, push back vec_push_back(p->children, c); return c; } static void construct_tree(const char *module, struct node_entry *parent) { DIR *dir; struct dirent *entry; struct node_entry *node; char *parent_path = get_full_path(parent); snprintf(buf, PATH_MAX, "%s/%s%s", MOUNTPOINT, module, parent_path); if (!(dir = opendir(buf))) goto cleanup; while ((entry = xreaddir(dir))) { if (strcmp(entry->d_name, ".") == 0 || strcmp(entry->d_name, "..") == 0) continue; // Create new node node = xcalloc(sizeof(*node), 1); node->module = module; node->name = strdup(entry->d_name); node->type = entry->d_type; snprintf(buf, PATH_MAX, "%s/%s", parent_path, node->name); // Check if the entry has a correspond target if (IS_LNK(node) || access(buf, F_OK) == -1) { // Mark the parent folder as a skeleton parent->status |= IS_SKEL; node->status |= IS_MODULE; } else if (IS_DIR(node)) { // Check if marked as replace snprintf(buf2, PATH_MAX, "%s/%s%s/.replace", MOUNTPOINT, module, buf); if (access(buf2, F_OK) == 0) { // Replace everything, mark as leaf node->status |= IS_MODULE; } } else if (IS_REG(node)) { // This is a leaf, mark as target node->status |= IS_MODULE; } node = insert_child(parent, node); if (IS_DIR(node) && !(node->status & IS_MODULE)) { // Intermediate node, travel deeper construct_tree(module, node); } } closedir(dir); cleanup: free(parent_path); } static void clone_skeleton(struct node_entry *node) { DIR *dir; struct dirent *entry; struct node_entry *dummy, *child; // Clone the structure char *full_path = get_full_path(node); if (!(dir = opendir(full_path))) goto cleanup; while ((entry = xreaddir(dir))) { if (strcmp(entry->d_name, ".") == 0 || strcmp(entry->d_name, "..") == 0) continue; // Create dummy node dummy = xcalloc(sizeof(*dummy), 1); dummy->name = strdup(entry->d_name); dummy->type = entry->d_type; dummy->status |= IS_DUMMY; insert_child(node, dummy); } closedir(dir); snprintf(buf, PATH_MAX, "%s%s", DUMMDIR, full_path); mkdir_p(buf, 0755); clone_attr(full_path, buf); bind_mount(buf, full_path); vec_for_each(node->children, child) { snprintf(buf, PATH_MAX, "%s%s/%s", DUMMDIR, full_path, child->name); // Create the dummy file/directory if (IS_DIR(child)) xmkdir(buf, 0755); else if (IS_REG(child)) close(open_new(buf)); if (child->status & IS_MODULE) { // Mount from module file to dummy file snprintf(buf2, PATH_MAX, "%s/%s%s/%s", MOUNTPOINT, child->module, full_path, child->name); } else if (child->status & IS_SKEL) { // It's another skeleton, recursive call and end clone_skeleton(child); continue; } else if (child->status & IS_DUMMY) { // Mount from mirror to dummy file snprintf(buf2, PATH_MAX, "%s%s/%s", MIRRDIR, full_path, child->name); } if (IS_LNK(child)) { // Symlink special treatments char *temp = xmalloc(PATH_MAX); xreadlink(buf2, temp, PATH_MAX); symlink(temp, buf); free(temp); LOGI("cplink: %s -> %s\n", buf2, buf); } else { snprintf(buf, PATH_MAX, "%s/%s", full_path, child->name); bind_mount(buf2, buf); } } cleanup: free(full_path); } static void magic_mount(struct node_entry *node) { char *real_path; struct node_entry *child; if (strcmp(node->name, "vendor") == 0 && strcmp(node->parent->name, "/system") == 0) { snprintf(buf, PATH_MAX, "%s/%s/system/vendor", MOUNTPOINT, node->module); snprintf(buf2, PATH_MAX, "%s/%s/vendor", MOUNTPOINT, node->module); unlink(buf2); symlink(buf, buf2); return; } if (node->status) { if (node->status & IS_MODULE) { // The real deal, mount module item real_path = get_full_path(node); snprintf(buf, PATH_MAX, "%s/%s%s", MOUNTPOINT, node->module, real_path); bind_mount(buf, real_path); free(real_path); } else if (node->status & IS_SKEL) { // The node is labeled to be cloned with skeleton, lets do it clone_skeleton(node); } // We should not see dummies, so no need to handle it here } else { // It's an intermediate node, travel deeper vec_for_each(node->children, child) magic_mount(child); } } /**************** * Simple Mount * ****************/ static void simple_mount(const char *path) { DIR *dir; struct dirent *entry; snprintf(buf, PATH_MAX, "%s%s", CACHEMOUNT, path); if (!(dir = opendir(buf))) return; while ((entry = xreaddir(dir))) { if (strcmp(entry->d_name, ".") == 0 || strcmp(entry->d_name, "..") == 0) continue; // Target file path snprintf(buf2, PATH_MAX, "%s/%s", path, entry->d_name); // Only mount existing file if (access(buf2, F_OK) == -1) continue; if (entry->d_type == DT_DIR) { char *new_path = strdup(buf2); simple_mount(new_path); free(new_path); } else if (entry->d_type == DT_REG) { // Actual file path snprintf(buf, PATH_MAX, "%s/%s", buf, entry->d_name); // Clone all attributes clone_attr(buf2, buf); // Finally, mount the file bind_mount(buf, buf2); } } closedir(dir); } /**************** * Entry points * ****************/ static void *start_magisk_hide(void *args) { launch_magiskhide(-1); return NULL; } static void unblock_boot_process() { close(open(UNBLOCKFILE, O_RDONLY | O_CREAT)); pthread_exit(NULL); } void post_fs(int client) { // Error handler err_handler = unblock_boot_process; // Start log monitor monitor_logs(); LOGI("** post-fs mode running\n"); // ack write_int(client, 0); close(client); // Uninstall or core only mode if (access(UNINSTALLER, F_OK) == 0 || access(DISABLEFILE, F_OK) == 0) goto unblock; // Allocate buffer buf = xmalloc(PATH_MAX); buf2 = xmalloc(PATH_MAX); simple_mount("/system"); simple_mount("/vendor"); unblock: unblock_boot_process(); } void post_fs_data(int client) { // Error handler err_handler = unblock_boot_process; // ack write_int(client, 0); close(client); if (!check_data()) goto unblock; LOGI("** post-fs-data mode running\n"); // uninstaller if (access(UNINSTALLER, F_OK) == 0) { close(open(UNBLOCKFILE, O_RDONLY | O_CREAT)); system("(BOOTMODE=true sh " UNINSTALLER ") &"); return; } // Allocate buffer if (buf == NULL) buf = xmalloc(PATH_MAX); if (buf2 == NULL) buf2 = xmalloc(PATH_MAX); // Cache support if (access("/cache/data_bin", F_OK) == 0) { rm_rf(DATABIN); rename("/cache/data_bin", DATABIN); } // Magisk Manual Injector support if (access("/data/local/tmp/magisk", F_OK) == 0) { rm_rf(DATABIN); rename("/data/local/tmp/magisk", DATABIN); } // Lazy.... use shell blob system("mv /data/magisk/stock_boot* /data;"); // Merge images if (merge_img("/cache/magisk.img", MAINIMG)) goto unblock; if (merge_img("/data/magisk_merge.img", MAINIMG)) goto unblock; int new_img = 0; if (access(MAINIMG, F_OK) == -1) { if (create_img(MAINIMG, 64)) goto unblock; new_img = 1; } // Initialize resetprop for the daemon init_resetprop(); LOGI("* Mounting " MAINIMG "\n"); // Mounting magisk image char *magiskloop = mount_image(MAINIMG, MOUNTPOINT); if (magiskloop == NULL) goto unblock; if (new_img) { mkdir(COREDIR, 0755); mkdir(COREDIR "/post-fs-data.d", 0755); mkdir(COREDIR "/service.d", 0755); mkdir(COREDIR "/props", 0755); } // Run common scripts LOGI("* Running post-fs-data.d scripts\n"); exec_common_script("post-fs-data"); // Core only mode if (access(DISABLEFILE, F_OK) == 0) goto unblock; DIR *dir; struct dirent *entry; char *module; struct node_entry *sys_root, *ven_root = NULL, *child; dir = xopendir(MOUNTPOINT); // Create the system root entry sys_root = xcalloc(sizeof(*sys_root), 1); sys_root->name = strdup("/system"); int has_modules = 0; // Travel through each modules vec_init(&module_list); LOGI("* Loading modules\n"); while ((entry = xreaddir(dir))) { if (entry->d_type == DT_DIR) { if (strcmp(entry->d_name, ".") == 0 || strcmp(entry->d_name, "..") == 0 || strcmp(entry->d_name, ".core") == 0 || strcmp(entry->d_name, "lost+found") == 0) continue; snprintf(buf, PATH_MAX, "%s/%s", MOUNTPOINT, entry->d_name); // Check whether remove snprintf(buf2, PATH_MAX, "%s/remove", buf); if (access(buf2, F_OK) == 0) { rm_rf(buf); continue; } // Check whether disable snprintf(buf2, PATH_MAX, "%s/disable", buf); if (access(buf2, F_OK) == 0) continue; // Add the module to list module = strdup(entry->d_name); vec_push_back(&module_list, module); // Read props snprintf(buf2, PATH_MAX, "%s/system.prop", buf); if (access(buf2, F_OK) == 0) { LOGI("%s: loading [system.prop]\n", module); read_prop_file(buf2, 0); } // Check whether enable auto_mount snprintf(buf2, PATH_MAX, "%s/auto_mount", buf); if (access(buf2, F_OK) == -1) continue; // Double check whether the system folder exists snprintf(buf2, PATH_MAX, "%s/system", buf); if (access(buf2, F_OK) == -1) continue; // Construct structure has_modules = 1; LOGI("%s: constructing magic mount structure\n", module); construct_tree(module, sys_root); } } closedir(dir); // Trim image umount_image(MOUNTPOINT, magiskloop); free(magiskloop); trim_img(MAINIMG); // Remount them back :) magiskloop = mount_image(MAINIMG, MOUNTPOINT); free(magiskloop); if (has_modules) { // Mount mirrors LOGI("* Mounting system/vendor mirrors"); int seperate_vendor = 0; struct vector mounts; vec_init(&mounts); file_to_vector("/proc/mounts", &mounts); char *line; vec_for_each(&mounts, line) { if (strstr(line, " /system ")) { sscanf(line, "%s", buf); snprintf(buf2, PATH_MAX, "%s/system", MIRRDIR); xmkdir_p(buf2, 0755); xmount(buf, buf2, "ext4", MS_RDONLY, NULL); LOGI("mount: %s -> %s\n", buf, buf2); continue; } if (strstr(line, " /vendor ")) { seperate_vendor = 1; sscanf(line, "%s", buf); snprintf(buf2, PATH_MAX, "%s/vendor", MIRRDIR); xmkdir_p(buf2, 0755); xmount(buf, buf2, "ext4", MS_RDONLY, NULL); LOGI("mount: %s -> %s\n", buf, buf2); continue; } } vec_deep_destroy(&mounts); if (!seperate_vendor) { snprintf(buf, PATH_MAX, "%s/system/vendor", MIRRDIR); snprintf(buf2, PATH_MAX, "%s/vendor", MIRRDIR); symlink(buf, buf2); LOGI("link: %s -> %s\n", buf, buf2); } // Magic!! magic_mount(sys_root); // Get the vendor node if exists vec_for_each(sys_root->children, child) { if (strcmp(child->name, "vendor") == 0) { ven_root = child; free(ven_root->name); ven_root->name = strdup("/vendor"); ven_root->parent = NULL; break; } } if (ven_root) magic_mount(ven_root); } // Cleanup memory destroy_subtree(sys_root); // Execute module scripts LOGI("* Running module post-fs-data scripts\n"); exec_module_script("post-fs-data"); // Systemless hosts if (access(HOSTSFILE, F_OK) == 0) { LOGI("* Enabling systemless hosts file support"); bind_mount(HOSTSFILE, "/system/etc/hosts"); } // Start magiskhide if enabled char *hide_prop = getprop(MAGISKHIDE_PROP); if (hide_prop) { if (strcmp(hide_prop, "1") == 0) { pthread_t thread; xpthread_create(&thread, NULL, start_magisk_hide, NULL); pthread_detach(thread); } free(hide_prop); } unblock: unblock_boot_process(); } void late_start(int client) { LOGI("** late_start service mode running\n"); // ack write_int(client, 0); close(client); // Allocate buffer if (buf == NULL) buf = xmalloc(PATH_MAX); if (buf2 == NULL) buf2 = xmalloc(PATH_MAX); // Wait till the full patch is done pthread_join(sepol_patch, NULL); // Run scripts after full patch, most reliable way to run scripts LOGI("* Running service.d scripts\n"); exec_common_script("service"); LOGI("* Running module service scripts\n"); exec_module_script("service"); // Install Magisk Manager if exists if (access(MANAGERAPK, F_OK) == 0) { while(1) { sleep(5); char *const command[] = { "sh", "-c", "CLASSPATH=/system/framework/pm.jar " "/system/bin/app_process /system/bin " "com.android.commands.pm.Pm install -r " MANAGERAPK, NULL }; int apk_res = 0, pid; pid = run_command(1, &apk_res, "/system/bin/sh", command); waitpid(pid, NULL, 0); fdgets(buf, PATH_MAX, apk_res); close(apk_res); // Keep trying until pm is started if (strstr(buf, "Error:") == NULL) break; } unlink(MANAGERAPK); } // All boot stage done, cleanup everything free(buf); free(buf2); vec_deep_destroy(&module_list); #ifdef DEBUG // Stop recording the boot logcat after every boot task is done extern int debug_log_pid, debug_log_fd; kill(debug_log_pid, SIGTERM); waitpid(debug_log_pid, NULL, 0); close(debug_log_fd); #endif }