[go: up one dir, main page]

Skip to content

d4rkc0nd0r/WebRCE

 
 

Repository files navigation

WebRCE

This repository contains code supporting the Signal-iOS research presented in Margin Research's 'You Can't Spell WebRTC without RCE' blog series.

Part 1

Instructions for following along with Part 1 of the blog series.

Building

Building requires downloading Google's depot_tools and setting an environment variable:

git clone https://chromium.googlesource.com/chromium/tools/depot_tools
export DEPOT_TOOLS=`pwd`/depot_tools"

You'll also need rustup for building on all platforms and coreutils which can be downloaded on macOS from brew:

brew install coreutils

This POC uses the following versions:

  • Target: Signal-iOS v7.13.0.131, RingRTC v2.42.0, WebRTC tag 6261i (with injected WebRTC vulns)
  • Thrower: Signal-Android v7.10.3 (with debug symbols) emulated using Google Pixel 6, Android 11, API 30 from Android Studio devices
  • Frida-server v16.3.3

iOS

Build the app with debug symbols for deployment in Xcode's Simulator to follow along with injecting and triggering the vulnerabilities in Part 1 of the blog. Set the DEPOT_TOOLS environment variable as outlined above and run make build-ios-debug. This will fetch Signal-iOS, download dependencies, patch WebRTC, and recompile Signal-iOS with the injected vulnerabilities. Load the resulting Signal-iOS-debug project in Xcode and boot the app in a Simulator of your choice.

Android

The "Thrower" can be any device with Signal installed including WebRTC debug symbols, and it is easiest to do this by compiling Signal-Android from source. Compilation must occur on a Linux device.

Set the DEPOT_TOOLS environment variable as noted above and run make build-android-debug. This will fetch Signal v7.10.3 and build from source using Docker reproducible builds. It will also handle creating a signing keychain and signing the APK. Once complete, the signed APK in $(PWD)/Signal-Android-play-prod-arm64-v8a-debug-7.10.3_signed_aligned.apk can be installed in an emulated Android device by dragging and dropping. Android Studio devices, such as the Pixel 6 device noted in this README's intro, work just fine for this purpose.

Running

Ensure the target device is running in Xcode's Simulator. Ensure both devices have Signal installed (the iOS Simulator should have the debug build including injected vulnerabilities) with registered unique phone numbers.

Send a message from one device to the other and accept the receipt so both users are in one another's contact book. The Target device must accept messages from the attacker for this POC to work.

Frida

Install Frida using pip with pip install frida-tools.

Download a precompiled frida-server and load onto the throwing device with adb push <path to frida-server> "/data/local/tmp/"

Start Frida on the Android thrower using:

adb root
adb shell
/data/local/tmp/frida-server-16.3.3-android-arm64 &

Note the thrower device name for the thrower by running frida-ls-devices. The exploit will default to the first USB-connected device, however this might not be desired if there is more than one device connected via USB. For example, the desired Android device from the list below is emulator-5554.

$ frida-ls-devices
Id                                        Type    Name                    OS
----------------------------------------  ------  ----------------------  --------------
emulator-5554                             usb     Android Emulator 5554   Android 11
00008120-AC5747734D9A2596                 usb     iPhone                  iPhone OS 16.0
00008030-0015581A0C50802E                 usb     webrtc-vuln             iPhone OS 16.4
barebone                                  remote  GDB Remote Stub
socket                                    remote  Local Socket

Throwing

Navigate to the frida-scripts directory and trigger the read and write vulnerabilities using the following commands:

python3 trigger.py -D emulator-5554 -t read -n <target number>
# or
python3 trigger.py -D emulator-5554 -t write -n <target number>

Part 2

Instructions for following along with Part 2 of the blog series.

Building

Install the dependencies and set the DEPOT_TOOLS environment variable as outlined in the beginning of Part 1's "Building" section.

iOS

Create an Apple Developer account that allows for signing of compiled .ipa files. Update Xcode to recognize this account.

Set the DEPOT_TOOLS environment variable as outlined in Part 1 and run make build-ios-archive. This will fetch Signal-iOS, download dependencies, patch WebRTC, and recompile Signal-iOS with the injected vulnerabilities. Load the resulting Signal-iOS project in Xcode and change the following project settings.

In the Signal app project settings:

  • Build Settings -> SIGNAL_BUNDLEID_PREFIX: change to a new prefix, preferably one associated with the group/company of the Apple Developer account
  • Target Signal -> Signing & Capabilities: change the Team profile to the Apple Developer account or the account's company name. This is required for Debug and Testable Release configurations
  • Target SignalNSE -> Signing & Capabilities: change the Team profile to the Apple Developer account or the account's company name. This is required for Debug and Testable Release configurations
  • Target SignalShareExtension -> Signing & Capabilities: change the Team profile to the Apple Developer account or the account's company name. This is required for Debug and Testable Release configurations
  • Target Signal -> Signing & Capabilities -> Entitlements: delete the Apple Pay, Communication Notifications, and Data Protection entitlements
  • Do the same as above for the SignalShareExtension and SignalNSE targets

Edit the project scheme for Archiving to be Testable Release.

Set the target device to Any iOS Device (arm64) and build the program. Select the Debugging distribution as the final output. Choose a storage location on disk for the archived .ipa file.

Android

Build the Android thrower as outlined in Part 1. No further modification are necessary.

Running

Corellium

Register for a Corellium account and create the target iPhone device: iPhone 14 Pro running iOS 16.4 (20E247). Install the compiled application on the virtualized device by dragging and dropping into the Apps pane after booting. Turn off Background Refresh in Settings -> General -> Background App Refresh -> Signal and Disable Notifications in Settings -> Signal -> Notifications. Failing to perform these actions will prevent the device from registering a phone number. Register a victim phone number and send a text message to the attacking phone number so they are in one another's address book.

An alternative to Corellium is to jailbreak a real device to allow for installation of the vulnerable app. This blog does not cover jailbreaking.

Android Thrower

Perform the same tasks as outlined in Part 1 to boot the Android thrower device with Frida-server running in the background.

Throwing

Fetching Target Files

Fetch the appropriate iOS ipsw using Blacktop's ipsw tool. For example, fetch iOS 16.4 for the iPhone 14 Pro (using a list of device numbers maintained by Adam Wolf):

ipsw download --device iPhone15,2 --build 20E247 ipsw
# downloads file iPhone15,2_16.4_20E247_Restore.ipsw

Triggering RCE

Navigate to the frida-scripts directory and throw the payload using the following command:

cd frida_spython3 exploit.py -l call.js,exploit.js -n <number> -D <emulator> \
    -c <path to iPhone15,2_16.4_20E247_Restore.ipsw> \
    -s <path to target Signal.ipa> \
    -g ./gadgets.json

About

No description, website, or topics provided.

Resources

Stars

Watchers

Forks

Releases

No releases published

Packages

No packages published

Languages

  • Python 62.2%
  • JavaScript 31.5%
  • Makefile 6.3%