Decrypting Firmwares

iOS contains many layers of encryption. This page details how to remove the encryption wrapper around each file in the IPSW file.

Ramdisks
This section details the decryption of the ramdisks in an IPSW file. The listed console commands are applicable to the IMG2 or IMG3 files under  also.

1.0.x
With the release of the iPhone, the ramdisks weren't encrypted. So, in order to mount them, all you need to do is remove some data from the beginning. You can either open up a hex editor and remove ##### bytes from the beginning, or open up a console and run []: dd if=ramdisk.dmg of=ramdisk.stripped.dmg bs=512 skip=4 count=37464 conv=sync
 * where ramdisk.dmg is the filename of the restore ramdisk (ex: the iPhone 2G 1.0 firmware (1A543a) would be )
 * where ramdisk.stripped.dmg is the output file name

Once the data has been stripped, you can then mount ramdisk.stripped.dmg in Finder on OS X, or with any other program. If you encounter errors after mounting the stripped ramdisk, you can safely ignore them.

1.1.x - 2.0b3
With the release of the iPod touch, Apple added a layer of encryption around the ramdisks. The decryption key wasn't obscured however, and a simple analysis of iBoot by Zibri revealed the 0x837 key. At first, its purpose wasn't known. After a while, geohot discovered its purpose.

In order to decrypt them, all you need to do is remove the  byte (2 kibibytes) header, then open a console and run  []: openssl enc -d -in ramdisk.dmg -out ramdisk.decrypted.dmg -aes-128-cbc -K 188458a6d15034dfe386f23b61d43774 -iv 0
 * where ramdisk.dmg is the filename of the ramdisk you are decrypting (ex: the iPhone 2G 1.1.1 firmware (3A109a) would be either  or  )
 * where ramdisk.decrypted.dmg is the output file name

2.0b4 - 3.0b5
With the fourth beta of 2.0, Apple introduced the IMG3 file format, replacing the broken IMG2 file format. This format was soon reversed and img3decrypt [src] was created by Steven Smith (@stroughtonsmith). His code was later implemented into xpwntool [src]. In order to decrypt the ramdisk, open a console and run one of the commands depending on your program choice: img3decrypt e ramdisk.dmg ramdisk.decrypted.dmg iv key xpwntool ramdisk.dmg ramdisk.decrypted.dmg -k key -iv iv
 * where ramdisk.dmg is the filename of the ramdisk you are decrypting (ex: the iPhone 3G 2.0 firmware (5A347) would be )
 * where ramdisk.decrypted.dmg is the output file name
 * where iv is the initialization vector (IV) of the ramdisk you are decrypting (ex: the iPhone 3G 2.0 firmware (5A347) would be )
 * where key is the key of the ramdisk you are decrypting (ex: the iPhone 3G 2.0 firmware (5A347) would be )

The IV and key for a specified firmware is available through the Firmware Keys page or from the  file underneath PwnageTool's   folder.

3.0GM/3.0
OS X Snow Leopard introduced the HFS compressed disk image. With 3.0 (what beta?), Apple began using Snow Leopard to package the ramdisks. This results in some zero sized files in the disk image if you don't use Snow Leopard or newer. A discussion on extracting those files is available on the talk page. With 3.0 (what beta?), Apple started using Snow Leopard to package the ramdisks.

S5L8900
With the 3.0 Golden Master (7A341), Apple messed up and, instead of using the application processor-specific GID Key, used a pseudo-GID of 5f650295e1fffc97ce77abd49dd955b3 to encrypt the KBAG. This makes obtaining the keys for this version dead simple. Once you have decrypted the KBAG, decryption using the keys in it is the same as above.

S5L8720
Business as usual, but keys and IVs have to be decrypted on the device still, unlike with the new S5L8900 KBAGs. Apple incorrectly assumed that by encrypting iBEC and iBSS they were being sly. They were not. You can decrypt those on a 2.2.1 aes setup no problem whatsoever.

S5L8920
The iPhone 3GS firmware files are interesting. They have two KBAGs, which use AES-256 instead of the S5L8900 and S5L8720 that are using AES-128 still. The first KBAG has an identifier in it's header indicating that it is to be decrypted with the gid key, and the second is not known. For those that don't know how AES256 works, this now means that the first 0x10 bytes are the IV, and the remaining 0x20 bytes (not 0x10 anymore!) are the key.