/* * Copyright (C) 2011 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 #include #include #include #include #include #include #include #include #include #include #include #include #include "cutils/misc.h" #include "cutils/properties.h" #include #include #include #include #include #include #include #include #include "tw_reboot.h" #include "bootloader.h" #include "common.h" #include "extra-functions.h" #include "cutils/properties.h" #include "install.h" #include "minuitwrp/minui.h" #include "minzip/DirUtil.h" #include "minzip/Zip.h" #include "recovery_ui.h" #include "roots.h" #include "data.h" #include "variables.h" #include "install.h" //kang system() from bionic/libc/unistd and rename it __system() so we can be even more hackish :) #undef _PATH_BSHELL #define _PATH_BSHELL "/sbin/sh" static const char *SIDELOAD_TEMP_DIR = "/tmp/sideload"; extern char **environ; int __system(const char *command) { pid_t pid; sig_t intsave, quitsave; sigset_t mask, omask; int pstat; char *argp[] = {"sh", "-c", NULL, NULL}; if (!command) /* just checking... */ return(1); argp[2] = (char *)command; sigemptyset(&mask); sigaddset(&mask, SIGCHLD); sigprocmask(SIG_BLOCK, &mask, &omask); switch (pid = vfork()) { case -1: /* error */ sigprocmask(SIG_SETMASK, &omask, NULL); return(-1); case 0: /* child */ sigprocmask(SIG_SETMASK, &omask, NULL); execve(_PATH_BSHELL, argp, environ); _exit(127); } intsave = (sig_t) bsd_signal(SIGINT, SIG_IGN); quitsave = (sig_t) bsd_signal(SIGQUIT, SIG_IGN); pid = waitpid(pid, (int *)&pstat, 0); sigprocmask(SIG_SETMASK, &omask, NULL); (void)bsd_signal(SIGINT, intsave); (void)bsd_signal(SIGQUIT, quitsave); return (pid == -1 ? -1 : pstat); } static struct pid { struct pid *next; FILE *fp; pid_t pid; } *pidlist; FILE *__popen(const char *program, const char *type) { struct pid * volatile cur; FILE *iop; int pdes[2]; pid_t pid; if ((*type != 'r' && *type != 'w') || type[1] != '\0') { errno = EINVAL; return (NULL); } if ((cur = malloc(sizeof(struct pid))) == NULL) return (NULL); if (pipe(pdes) < 0) { free(cur); return (NULL); } switch (pid = vfork()) { case -1: /* Error. */ (void)close(pdes[0]); (void)close(pdes[1]); free(cur); return (NULL); /* NOTREACHED */ case 0: /* Child. */ { struct pid *pcur; /* * because vfork() instead of fork(), must leak FILE *, * but luckily we are terminally headed for an execl() */ for (pcur = pidlist; pcur; pcur = pcur->next) close(fileno(pcur->fp)); if (*type == 'r') { int tpdes1 = pdes[1]; (void) close(pdes[0]); /* * We must NOT modify pdes, due to the * semantics of vfork. */ if (tpdes1 != STDOUT_FILENO) { (void)dup2(tpdes1, STDOUT_FILENO); (void)close(tpdes1); tpdes1 = STDOUT_FILENO; } } else { (void)close(pdes[1]); if (pdes[0] != STDIN_FILENO) { (void)dup2(pdes[0], STDIN_FILENO); (void)close(pdes[0]); } } execl(_PATH_BSHELL, "sh", "-c", program, (char *)NULL); _exit(127); /* NOTREACHED */ } } /* Parent; assume fdopen can't fail. */ if (*type == 'r') { iop = fdopen(pdes[0], type); (void)close(pdes[1]); } else { iop = fdopen(pdes[1], type); (void)close(pdes[0]); } /* Link into list of file descriptors. */ cur->fp = iop; cur->pid = pid; cur->next = pidlist; pidlist = cur; return (iop); } /* * pclose -- * Pclose returns -1 if stream is not associated with a `popened' command, * if already `pclosed', or waitpid returns an error. */ int __pclose(FILE *iop) { struct pid *cur, *last; int pstat; pid_t pid; /* Find the appropriate file pointer. */ for (last = NULL, cur = pidlist; cur; last = cur, cur = cur->next) if (cur->fp == iop) break; if (cur == NULL) return (-1); (void)fclose(iop); do { pid = waitpid(cur->pid, &pstat, 0); } while (pid == -1 && errno == EINTR); /* Remove the entry from the linked list. */ if (last == NULL) pidlist = cur->next; else last->next = cur->next; free(cur); return (pid == -1 ? -1 : pstat); } char* sanitize_device_id(char* id) { const char* whitelist ="abcdefghijklmnopqrstuvwxyzABCDEFGHIJKLMNOPQRSTUVWXYZ1234567890-._"; char* c = id; char* str = (int*) calloc(50, sizeof *id); while (*c) { if (strchr(whitelist, *c)) { strncat(str, c, 1); } c++; } return str; } #define CMDLINE_SERIALNO "androidboot.serialno=" #define CMDLINE_SERIALNO_LEN (strlen(CMDLINE_SERIALNO)) #define CPUINFO_SERIALNO "Serial" #define CPUINFO_SERIALNO_LEN (strlen(CPUINFO_SERIALNO)) #define CPUINFO_HARDWARE "Hardware" #define CPUINFO_HARDWARE_LEN (strlen(CPUINFO_HARDWARE)) void get_device_id() { FILE *fp; char line[2048]; char hardware_id[32]; char* token; char* new_device_id; // Assign a blank device_id to start with device_id[0] = 0; // First, try the cmdline to see if the serial number was supplied fp = fopen("/proc/cmdline", "rt"); if (fp != NULL) { // First step, read the line. For cmdline, it's one long line fgets(line, sizeof(line), fp); fclose(fp); // Now, let's tokenize the string token = strtok(line, " "); // Let's walk through the line, looking for the CMDLINE_SERIALNO token while (token) { // We don't need to verify the length of token, because if it's too short, it will mismatch CMDLINE_SERIALNO at the NULL if (memcmp(token, CMDLINE_SERIALNO, CMDLINE_SERIALNO_LEN) == 0) { // We found the serial number! strcpy(device_id, token + CMDLINE_SERIALNO_LEN); new_device_id = sanitize_device_id(device_id); strcpy(device_id, new_device_id); free(new_device_id); return; } token = strtok(NULL, " "); } } // Now we'll try cpuinfo for a serial number fp = fopen("/proc/cpuinfo", "rt"); if (fp != NULL) { while (fgets(line, sizeof(line), fp) != NULL) { // First step, read the line. if (memcmp(line, CPUINFO_SERIALNO, CPUINFO_SERIALNO_LEN) == 0) // check the beginning of the line for "Serial" { // We found the serial number! token = line + CPUINFO_SERIALNO_LEN; // skip past "Serial" while ((*token > 0 && *token <= 32 ) || *token == ':') token++; // skip over all spaces and the colon if (*token != 0) { token[30] = 0; if (token[strlen(token)-1] == 10) { // checking for endline chars and dropping them from the end of the string if needed memset(device_id, 0, sizeof(device_id)); strncpy(device_id, token, strlen(token) - 1); } else { strcpy(device_id, token); } LOGI("=> serial from cpuinfo: '%s'\n", device_id); fclose(fp); new_device_id = sanitize_device_id(device_id); strcpy(device_id, new_device_id); free(new_device_id); return; } } else if (memcmp(line, CPUINFO_HARDWARE, CPUINFO_HARDWARE_LEN) == 0) {// We're also going to look for the hardware line in cpuinfo and save it for later in case we don't find the device ID // We found the hardware ID token = line + CPUINFO_HARDWARE_LEN; // skip past "Hardware" while ((*token > 0 && *token <= 32 ) || *token == ':') token++; // skip over all spaces and the colon if (*token != 0) { token[30] = 0; if (token[strlen(token)-1] == 10) { // checking for endline chars and dropping them from the end of the string if needed memset(hardware_id, 0, sizeof(hardware_id)); strncpy(hardware_id, token, strlen(token) - 1); } else { strcpy(hardware_id, token); } LOGI("=> hardware id from cpuinfo: '%s'\n", hardware_id); } } } fclose(fp); } if (hardware_id[0] != 0) { LOGW("\nusing hardware id for device id: '%s'\n", hardware_id); strcpy(device_id, hardware_id); new_device_id = sanitize_device_id(device_id); strcpy(device_id, new_device_id); free(new_device_id); return; } strcpy(device_id, "serialno"); LOGE("=> device id not found, using '%s'.", device_id); return; } char* get_path (char* path) { char *s; /* Go to the end of the string. */ s = path + strlen(path) - 1; /* Strip off trailing /s (unless it is also the leading /). */ while (path < s && s[0] == '/') s--; /* Strip the last component. */ while (path <= s && s[0] != '/') s--; while (path < s && s[0] == '/') s--; if (s < path) return "."; s[1] = '\0'; return path; } char* basename(char* name) { const char* base; for (base = name; *name; name++) { if(*name == '/') { base = name + 1; } } return (char *) base; } /* Checks md5 for a path Return values: -1 : MD5 does not exist 0 : Failed 1 : Success */ int check_md5(char* path) { int o; char cmd[PATH_MAX + 30]; char md5file[PATH_MAX + 40]; strcpy(md5file, path); strcat(md5file, ".md5"); char dirpath[PATH_MAX]; char* file; if (access(md5file, F_OK ) != -1) { strcpy(dirpath, md5file); get_path(dirpath); chdir(dirpath); file = basename(md5file); sprintf(cmd, "/sbin/busybox md5sum -c '%s'", file); FILE * cs = __popen(cmd, "r"); char cs_s[PATH_MAX + 50]; fgets(cs_s, PATH_MAX + 50, cs); char* OK = strstr(cs_s, "OK"); if (OK != NULL) { printf("MD5 is good. returning 1\n"); o = 1; } else { printf("MD5 is bad. return -2\n"); o = -2; } __pclose(cs); } else { //No md5 file printf("setting o to -1\n"); o = -1; } return o; } static int really_install_package(const char *path, int* wipe_cache) { //ui->SetBackground(RecoveryUI::INSTALLING); LOGI("Finding update package...\n"); //ui->SetProgressType(RecoveryUI::INDETERMINATE); LOGI("Update location: %s\n", path); if (ensure_path_mounted(path) != 0) { LOGE("Can't mount %s\n", path); return INSTALL_CORRUPT; } LOGI("Opening update package...\n"); int numKeys; /*RSAPublicKey* loadedKeys = load_keys(PUBLIC_KEYS_FILE, &numKeys); if (loadedKeys == NULL) { LOGE("Failed to load keys\n"); return INSTALL_CORRUPT; } LOGI("%d key(s) loaded from %s\n", numKeys, PUBLIC_KEYS_FILE);*/ // Give verification half the progress bar... LOGI("Verifying update package...\n"); //ui->SetProgressType(RecoveryUI::DETERMINATE); //ui->ShowProgress(VERIFICATION_PROGRESS_FRACTION, VERIFICATION_PROGRESS_TIME); int err; /*err = verify_file(path, loadedKeys, numKeys); free(loadedKeys); LOGI("verify_file returned %d\n", err); if (err != VERIFY_SUCCESS) { LOGE("signature verification failed\n"); return INSTALL_CORRUPT; }*/ /* Try to open the package. */ ZipArchive zip; err = mzOpenZipArchive(path, &zip); if (err != 0) { LOGE("Can't open %s\n(%s)\n", path, err != -1 ? strerror(err) : "bad"); return INSTALL_CORRUPT; } /* Verify and install the contents of the package. */ LOGI("Installing update...\n"); return try_update_binary(path, &zip, wipe_cache); } static void set_sdcard_update_bootloader_message() { struct bootloader_message boot; memset(&boot, 0, sizeof(boot)); strlcpy(boot.command, "boot-recovery", sizeof(boot.command)); strlcpy(boot.recovery, "recovery\n", sizeof(boot.recovery)); set_bootloader_message(&boot); } static char* copy_sideloaded_package(const char* original_path) { if (ensure_path_mounted(original_path) != 0) { LOGE("Can't mount %s\n", original_path); return NULL; } if (ensure_path_mounted(SIDELOAD_TEMP_DIR) != 0) { LOGE("Can't mount %s\n", SIDELOAD_TEMP_DIR); return NULL; } if (mkdir(SIDELOAD_TEMP_DIR, 0700) != 0) { if (errno != EEXIST) { LOGE("Can't mkdir %s (%s)\n", SIDELOAD_TEMP_DIR, strerror(errno)); return NULL; } } // verify that SIDELOAD_TEMP_DIR is exactly what we expect: a // directory, owned by root, readable and writable only by root. struct stat st; if (stat(SIDELOAD_TEMP_DIR, &st) != 0) { LOGE("failed to stat %s (%s)\n", SIDELOAD_TEMP_DIR, strerror(errno)); return NULL; } if (!S_ISDIR(st.st_mode)) { LOGE("%s isn't a directory\n", SIDELOAD_TEMP_DIR); return NULL; } if ((st.st_mode & 0777) != 0700) { LOGE("%s has perms %o\n", SIDELOAD_TEMP_DIR, st.st_mode); return NULL; } if (st.st_uid != 0) { LOGE("%s owned by %lu; not root\n", SIDELOAD_TEMP_DIR, st.st_uid); return NULL; } char copy_path[PATH_MAX]; strcpy(copy_path, SIDELOAD_TEMP_DIR); strcat(copy_path, "/package.zip"); char* buffer = malloc(BUFSIZ); if (buffer == NULL) { LOGE("Failed to allocate buffer\n"); return NULL; } size_t read; FILE* fin = fopen(original_path, "rb"); if (fin == NULL) { LOGE("Failed to open %s (%s)\n", original_path, strerror(errno)); return NULL; } FILE* fout = fopen(copy_path, "wb"); if (fout == NULL) { LOGE("Failed to open %s (%s)\n", copy_path, strerror(errno)); return NULL; } while ((read = fread(buffer, 1, BUFSIZ, fin)) > 0) { if (fwrite(buffer, 1, read, fout) != read) { LOGE("Short write of %s (%s)\n", copy_path, strerror(errno)); return NULL; } } free(buffer); if (fclose(fout) != 0) { LOGE("Failed to close %s (%s)\n", copy_path, strerror(errno)); return NULL; } if (fclose(fin) != 0) { LOGE("Failed to close %s (%s)\n", original_path, strerror(errno)); return NULL; } // "adb push" is happy to overwrite read-only files when it's // running as root, but we'll try anyway. if (chmod(copy_path, 0400) != 0) { LOGE("Failed to chmod %s (%s)\n", copy_path, strerror(errno)); return NULL; } return strdup(copy_path); } int install_zip_package(const char* zip_path_filename) { int result = 0; //mount_current_storage(); int md5_req = DataManager_GetIntValue(TW_FORCE_MD5_CHECK_VAR); if (md5_req == 1) { ui_print("\n-- Verify md5 for %s", zip_path_filename); int md5chk = check_md5((char*) zip_path_filename); if (md5chk == 1) { ui_print("\n-- Md5 verified, continue"); result = 0; } else if (md5chk == -1) { if (md5_req == 1) { ui_print("\n-- No md5 file found!"); ui_print("\n-- Aborting install"); result = INSTALL_ERROR; } else { ui_print("\n-- No md5 file found, ignoring"); } } else if (md5chk == -2) { ui_print("\n-- md5 file doesn't match!"); ui_print("\n-- Aborting install"); result = INSTALL_ERROR; } printf("%d\n", result); } if (result != INSTALL_ERROR) { ui_print("\n-- Install %s ...\n", zip_path_filename); set_sdcard_update_bootloader_message(); char* copy; if (DataManager_GetIntValue(TW_FLASH_ZIP_IN_PLACE) == 1 && strlen(zip_path_filename) > 6 && strncmp(zip_path_filename, "/cache", 6) != 0) { copy = strdup(zip_path_filename); } else { copy = copy_sideloaded_package(zip_path_filename); //unmount_current_storage(); } if (copy) { result = really_install_package(copy, 0); free(copy); //update_system_details(); } else { result = INSTALL_ERROR; } } //mount_current_storage(); //finish_recovery(NULL); return result; } //partial kangbang from system/vold #ifndef CUSTOM_LUN_FILE #define CUSTOM_LUN_FILE "/sys/devices/platform/usb_mass_storage/lun%d/file" #endif int usb_storage_enable(void) { int fd; char lun_file[255]; if (DataManager_GetIntValue(TW_HAS_DUAL_STORAGE) == 1 && DataManager_GetIntValue(TW_HAS_DATA_MEDIA) == 0) { Volume *vol = volume_for_path(DataManager_GetSettingsStoragePath()); if (!vol) { LOGE("Unable to locate volume information."); return -1; } sprintf(lun_file, CUSTOM_LUN_FILE, 0); if ((fd = open(lun_file, O_WRONLY)) < 0) { LOGE("Unable to open ums lunfile '%s': (%s)\n", lun_file, strerror(errno)); return -1; } if ((write(fd, vol->device, strlen(vol->device)) < 0) && (!vol->device2 || (write(fd, vol->device, strlen(vol->device2)) < 0))) { LOGE("Unable to write to ums lunfile '%s': (%s)\n", lun_file, strerror(errno)); close(fd); return -1; } close(fd); Volume *vol2 = volume_for_path(DataManager_GetStrValue(TW_EXTERNAL_PATH)); if (!vol) { LOGE("Unable to locate volume information.\n"); return -1; } sprintf(lun_file, CUSTOM_LUN_FILE, 1); if ((fd = open(lun_file, O_WRONLY)) < 0) { LOGE("Unable to open ums lunfile '%s': (%s)\n", lun_file, strerror(errno)); return -1; } if ((write(fd, vol2->device, strlen(vol2->device)) < 0) && (!vol2->device2 || (write(fd, vol2->device, strlen(vol2->device2)) < 0))) { LOGE("Unable to write to ums lunfile '%s': (%s)\n", lun_file, strerror(errno)); close(fd); return -1; } close(fd); } else { if (DataManager_GetIntValue(TW_HAS_DATA_MEDIA) == 0) strcpy(lun_file, DataManager_GetCurrentStoragePath()); else strcpy(lun_file, DataManager_GetStrValue(TW_EXTERNAL_PATH)); Volume *vol = volume_for_path(lun_file); if (!vol) { LOGE("Unable to locate volume information.\n"); return -1; } sprintf(lun_file, CUSTOM_LUN_FILE, 0); if ((fd = open(lun_file, O_WRONLY)) < 0) { LOGE("Unable to open ums lunfile '%s': (%s)\n", lun_file, strerror(errno)); return -1; } if ((write(fd, vol->device, strlen(vol->device)) < 0) && (!vol->device2 || (write(fd, vol->device, strlen(vol->device2)) < 0))) { LOGE("Unable to write to ums lunfile '%s': (%s)\n", lun_file, strerror(errno)); close(fd); return -1; } close(fd); } return 0; } int usb_storage_disable(void) { int fd, index; char lun_file[255]; for (index=0; index<2; index++) { sprintf(lun_file, CUSTOM_LUN_FILE, index); if ((fd = open(lun_file, O_WRONLY)) < 0) { if (index == 0) LOGE("Unable to open ums lunfile '%s': (%s)", lun_file, strerror(errno)); return -1; } char ch = 0; if (write(fd, &ch, 1) < 0) { if (index == 0) LOGE("Unable to write to ums lunfile '%s': (%s)", lun_file, strerror(errno)); close(fd); return -1; } close(fd); } return 0; } void wipe_dalvik_cache() { //ui_set_background(BACKGROUND_ICON_WIPE); ensure_path_mounted("/data"); ensure_path_mounted("/cache"); ui_print("\n-- Wiping Dalvik Cache Directories...\n"); __system("rm -rf /data/dalvik-cache"); ui_print("Cleaned: /data/dalvik-cache...\n"); __system("rm -rf /cache/dalvik-cache"); ui_print("Cleaned: /cache/dalvik-cache...\n"); __system("rm -rf /cache/dc"); ui_print("Cleaned: /cache/dc\n"); struct stat st; LOGE("TODO: Re-implement wipe dalvik into Partition Manager!\n"); if (1) //if (0 != stat(sde.blk, &st)) { ui_print("/sd-ext not present, skipping\n"); } else { __system("mount /sd-ext"); LOGI("Mounting /sd-ext\n"); if (stat("/sd-ext/dalvik-cache",&st) == 0) { __system("rm -rf /sd-ext/dalvik-cache"); ui_print("Cleaned: /sd-ext/dalvik-cache...\n"); } } ensure_path_unmounted("/data"); ui_print("-- Dalvik Cache Directories Wipe Complete!\n\n"); //ui_set_background(BACKGROUND_ICON_MAIN); //if (!ui_text_visible()) return; } // BATTERY STATS void wipe_battery_stats() { ensure_path_mounted("/data"); struct stat st; if (0 != stat("/data/system/batterystats.bin", &st)) { ui_print("No Battery Stats Found. No Need To Wipe.\n"); } else { //ui_set_background(BACKGROUND_ICON_WIPE); remove("/data/system/batterystats.bin"); ui_print("Cleared: Battery Stats...\n"); ensure_path_unmounted("/data"); } } // ROTATION SETTINGS void wipe_rotate_data() { //ui_set_background(BACKGROUND_ICON_WIPE); ensure_path_mounted("/data"); __system("rm -r /data/misc/akmd*"); __system("rm -r /data/misc/rild*"); ui_print("Cleared: Rotatation Data...\n"); ensure_path_unmounted("/data"); } void fix_perms() { ensure_path_mounted("/data"); ensure_path_mounted("/system"); //ui_show_progress(1,30); ui_print("\n-- Fixing Permissions\n"); ui_print("This may take a few minutes.\n"); __system("./sbin/fix_permissions.sh"); ui_print("-- Done.\n\n"); //ui_reset_progress(); } int get_battery_level(void) { static int lastVal = -1; static time_t nextSecCheck = 0; struct timeval curTime; gettimeofday(&curTime, NULL); if (curTime.tv_sec > nextSecCheck) { char cap_s[4]; FILE * cap = fopen("/sys/class/power_supply/battery/capacity","rt"); if (cap) { fgets(cap_s, 4, cap); fclose(cap); lastVal = atoi(cap_s); if (lastVal > 100) lastVal = 101; if (lastVal < 0) lastVal = 0; } nextSecCheck = curTime.tv_sec + 60; } return lastVal; } char* print_batt_cap() { char* full_cap_s = (char*)malloc(30); char full_cap_a[30]; int cap_i = get_battery_level(); //int len = strlen(cap_s); //if (cap_s[len-1] == '\n') { // cap_s[len-1] = 0; //} // Get a usable time struct tm *current; time_t now; now = time(0); current = localtime(&now); sprintf(full_cap_a, "Battery Level: %i%% @ %02D:%02D", cap_i, current->tm_hour, current->tm_min); strcpy(full_cap_s, full_cap_a); return full_cap_s; } void update_tz_environment_variables() { setenv("TZ", DataManager_GetStrValue(TW_TIME_ZONE_VAR), 1); tzset(); } void run_script(const char *str1, const char *str2, const char *str3, const char *str4, const char *str5, const char *str6, const char *str7, int request_confirm) { ui_print("%s", str1); //ui_clear_key_queue(); ui_print("\nPress Power to confirm,"); ui_print("\nany other key to abort.\n"); int confirm; /*if (request_confirm) // this option is used to skip the confirmation when the gui is in use confirm = ui_wait_key(); else*/ confirm = KEY_POWER; if (confirm == BTN_MOUSE || confirm == KEY_POWER || confirm == SELECT_ITEM) { ui_print("%s", str2); pid_t pid = fork(); if (pid == 0) { char *args[] = { "/sbin/sh", "-c", (char*)str3, "1>&2", NULL }; execv("/sbin/sh", args); fprintf(stderr, str4, strerror(errno)); _exit(-1); } int status; while (waitpid(pid, &status, WNOHANG) == 0) { ui_print("."); sleep(1); } ui_print("\n"); if (!WIFEXITED(status) || (WEXITSTATUS(status) != 0)) { ui_print("%s", str5); } else { ui_print("%s", str6); } } else { ui_print("%s", str7); } //if (!ui_text_visible()) return; } void install_htc_dumlock(void) { struct statfs fs1, fs2; int need_libs = 0; ui_print("Installing HTC Dumlock to system...\n"); ensure_path_mounted("/system"); __system("cp /res/htcd/htcdumlocksys /system/bin/htcdumlock && chmod 755 /system/bin/htcdumlock"); if (statfs("/system/bin/flash_image", &fs1) != 0) { ui_print("Installing flash_image...\n"); __system("cp /res/htcd/flash_imagesys /system/bin/flash_image && chmod 755 /system/bin/flash_image"); need_libs = 1; } else ui_print("flash_image is already installed, skipping...\n"); if (statfs("/system/bin/dump_image", &fs2) != 0) { ui_print("Installing dump_image...\n"); __system("cp /res/htcd/dump_imagesys /system/bin/dump_image && chmod 755 /system/bin/dump_image"); need_libs = 1; } else ui_print("dump_image is already installed, skipping...\n"); if (need_libs) { ui_print("Installing libs needed for flash_image and dump_image...\n"); __system("cp /res/htcd/libbmlutils.so /system/lib && chmod 755 /system/lib/libbmlutils.so"); __system("cp /res/htcd/libflashutils.so /system/lib && chmod 755 /system/lib/libflashutils.so"); __system("cp /res/htcd/libmmcutils.so /system/lib && chmod 755 /system/lib/libmmcutils.so"); __system("cp /res/htcd/libmtdutils.so /system/lib && chmod 755 /system/lib/libmtdutils.so"); } ui_print("Installing HTC Dumlock app...\n"); ensure_path_mounted("/data"); mkdir("/data/app", 0777); __system("rm /data/app/com.teamwin.htcdumlock*"); __system("cp /res/htcd/HTCDumlock.apk /data/app/com.teamwin.htcdumlock.apk"); sync(); ui_print("HTC Dumlock is installed.\n"); } void htc_dumlock_restore_original_boot(void) { ui_print("Restoring original boot...\n"); __system("htcdumlock restore"); ui_print("Original boot restored.\n"); } void htc_dumlock_reflash_recovery_to_boot(void) { ui_print("Reflashing recovery to boot...\n"); __system("htcdumlock recovery noreboot"); ui_print("Recovery is flashed to boot.\n"); } void check_and_run_script(const char* script_file, const char* display_name) { // Check for and run startup script if script exists struct statfs st; if (statfs(script_file, &st) == 0) { ui_print("Running %s script...\n", display_name); char command[255]; strcpy(command, "chmod 755 "); strcat(command, script_file); __system(command); __system(script_file); ui_print("\nFinished running %s script.\n", display_name); } } int check_backup_name(int show_error) { // Check the backup name to ensure that it is the correct size and contains only valid characters // and that a backup with that name doesn't already exist char backup_name[MAX_BACKUP_NAME_LEN]; char backup_loc[255], tw_image_dir[255]; int copy_size = strlen(DataManager_GetStrValue(TW_BACKUP_NAME)); int index, cur_char; struct statfs st; // Check size if (copy_size > MAX_BACKUP_NAME_LEN) { if (show_error) LOGE("Backup name is too long.\n"); return -2; } // Check characters strncpy(backup_name, DataManager_GetStrValue(TW_BACKUP_NAME), copy_size); if (strcmp(backup_name, "0") == 0) return 0; // A "0" (zero) means to use the current timestamp for the backup name for (index=0; index= 48 && cur_char <= 57) || (cur_char >= 65 && cur_char <= 91) || cur_char == 93 || cur_char == 95 || (cur_char >= 97 && cur_char <= 123) || cur_char == 125 || cur_char == 45 || cur_char == 46) { // These are valid characters // Numbers // Upper case letters // Lower case letters // and -_.{}[] } else { if (show_error) LOGE("Backup name '%s' contains invalid character: '%c'\n", backup_name, (char)cur_char); return -3; } } // Check to make sure that a backup with this name doesn't already exist strcpy(backup_loc, DataManager_GetStrValue(TW_BACKUPS_FOLDER_VAR)); sprintf(tw_image_dir,"%s/%s/.", backup_loc, backup_name); if (statfs(tw_image_dir, &st) == 0) { if (show_error) LOGE("A backup with this name already exists.\n"); return -4; } // No problems found, return 0 return 0; } static const char *COMMAND_FILE = "/cache/recovery/command"; static const char *INTENT_FILE = "/cache/recovery/intent"; static const char *LOG_FILE = "/cache/recovery/log"; static const char *LAST_LOG_FILE = "/cache/recovery/last_log"; static const char *LAST_INSTALL_FILE = "/cache/recovery/last_install"; static const char *CACHE_ROOT = "/cache"; static const char *SDCARD_ROOT = "/sdcard"; static const char *TEMPORARY_LOG_FILE = "/tmp/recovery.log"; static const char *TEMPORARY_INSTALL_FILE = "/tmp/last_install"; // close a file, log an error if the error indicator is set static void check_and_fclose(FILE *fp, const char *name) { fflush(fp); if (ferror(fp)) LOGE("Error in %s\n(%s)\n", name, strerror(errno)); fclose(fp); } static void copy_log_file(const char* source, const char* destination, int append) { FILE *log = fopen_path(destination, append ? "a" : "w"); if (log == NULL) { LOGE("Can't open %s\n", destination); } else { FILE *tmplog = fopen(source, "r"); if (tmplog != NULL) { if (append) { fseek(tmplog, tmplog_offset, SEEK_SET); // Since last write } char buf[4096]; while (fgets(buf, sizeof(buf), tmplog)) fputs(buf, log); if (append) { tmplog_offset = ftell(tmplog); } check_and_fclose(tmplog, source); } check_and_fclose(log, destination); } } // clear the recovery command and prepare to boot a (hopefully working) system, // copy our log file to cache as well (for the system to read), and // record any intent we were asked to communicate back to the system. // this function is idempotent: call it as many times as you like. void twfinish_recovery(const char *send_intent) { // By this point, we're ready to return to the main system... if (send_intent != NULL) { FILE *fp = fopen_path(INTENT_FILE, "w"); if (fp == NULL) { LOGE("Can't open %s\n", INTENT_FILE); } else { fputs(send_intent, fp); check_and_fclose(fp, INTENT_FILE); } } // Copy logs to cache so the system can find out what happened. copy_log_file(TEMPORARY_LOG_FILE, LOG_FILE, true); copy_log_file(TEMPORARY_LOG_FILE, LAST_LOG_FILE, false); copy_log_file(TEMPORARY_INSTALL_FILE, LAST_INSTALL_FILE, false); chmod(LOG_FILE, 0600); chown(LOG_FILE, 1000, 1000); // system user chmod(LAST_LOG_FILE, 0640); chmod(LAST_INSTALL_FILE, 0644); // Reset to normal system boot so recovery won't cycle indefinitely. struct bootloader_message boot; memset(&boot, 0, sizeof(boot)); set_bootloader_message(&boot); // Remove the command file, so recovery won't repeat indefinitely. if (ensure_path_mounted(COMMAND_FILE) != 0 || (unlink(COMMAND_FILE) && errno != ENOENT)) { LOGW("Can't unlink %s\n", COMMAND_FILE); } ensure_path_unmounted(CACHE_ROOT); sync(); // For good measure. }