| Offset | Size | Field | Example Value | |--------|------|---------------|-------------------| | 0x00 | 4 | ih_magic | 0x27051956 | | 0x04 | 4 | ih_hcrc | Checksum | | 0x08 | 4 | ih_time | Timestamp | | 0x0C | 4 | ih_size | Data size | | 0x10 | 4 | ih_load | Load address | | 0x14 | 4 | ih_ep | Entry point | | 0x18 | 4 | ih_dcrc | Data checksum | | 0x1C | 1 | ih_os | OS type | | 0x1D | 1 | ih_arch | Architecture | | 0x1E | 1 | ih_type | Image type | | 0x1F | 1 | ih_comp | Compression | | 0x20 | 16 | ih_name | Image name |
If you’ve ever run binwalk on a HiLink firmware update (e.g., from an E3372, B310, or AR series router) and seen only high entropy data with no recognizable UImage magic ( 0x27051956 ), you’ve likely encountered this encrypted header.
This article explains what it is, how it works, and practical methods to decrypt and analyze it. A normal, unencrypted UImage header (64 bytes) looks like this: encrypted hilink uimage firmware header
Key for E3372 (v1): 0x4A,0x6F,0x6B,0x65,0x72,0x73,0x43,0x6F,0x6D,0x65,0x74,0x21,0x2A,0x2A,0x2A,0x00 Key for B310: Derived from serial number + static seed : Modern HiLink devices (2020+) use device-unique keys, making extraction harder but not impossible via hardware glitching. 3.3 Header Structure After Decryption Once decrypted, the header reverts to a standard UImage header with one twist: the ih_name field often contains a secondary signature or a plaintext marker like "SECURE_HILINK_V1" .
binwalk -E firmware.bin If the first 1 MB shows high entropy (>0.98) with no known signatures, suspect encryption. | Offset | Size | Field | Example
cipher = AES.new(key, AES.MODE_CBC, iv) dec_header = cipher.decrypt(enc_header)
strings u-boot.bin | grep -i "aes" Look for key arrays in rodata section. If the magic appears, you have the correct key
If the magic appears, you have the correct key. The rest of the firmware may be encrypted in blocks. Many HiLink images encrypt only the header + first block. The remaining data may be plain or compressed. After decryption, run: