SELF - SPRX: Difference between revisions
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Extracting an ELF
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SELF stands for Signed Executable and Linkable Format. | |||
[[File:Self.png|thumb|alt=A screenshot of f0f's presentation at CCC2010.]] | |||
It is the format used by the executables on the PS3 | |||
It consists of an elf file encrypted using AES CTR and signed using ECDSA | |||
It has a specific header here called SCE header where it stores all the parameters for this process | |||
[[Category:Software]] | [[Category:Software]] | ||
''' Source: http://ps3wiki.lan.st/index.php?title=SELF_File_Format_and_Decryption ''' | ''' Source: http://ps3wiki.lan.st/index.php?title=SELF_File_Format_and_Decryption ''' |
Revision as of 20:29, 3 October 2011
SELF stands for Signed Executable and Linkable Format.
It is the format used by the executables on the PS3 It consists of an elf file encrypted using AES CTR and signed using ECDSA It has a specific header here called SCE header where it stores all the parameters for this process Source: http://ps3wiki.lan.st/index.php?title=SELF_File_Format_and_Decryption
File Format
Notes:
- Numbers are stored in big endian format.
SELF/SCE Header
typedef struct { uint32_t magic; // "SCE\0" uint32_t version; // 2 uint16_t attribute; // 0x8000 - fself uint16_t category; uint32_t metadataInfoOffset; uint64_t fileOffset; uint64_t fileSize; uint64_t unknown06; uint64_t programInfoOffset; uint64_t elfHeaderOffset; uint64_t elfProgramHeadersOffset; uint64_t elfSectionHeadersOffset; uint64_t sInfoOffset; uint64_t versionInfoOffset; uint64_t controlInfoOffset; uint64_t controlInfoSize; uint64_t unknown15; } SELFHEADER_t;
Program Info
typedef struct { uint64_t programAuthId; uint64_t unknown01; uint16_t programVersion[4]; uint64_t unknown03; } PROGRAMINFO_t;
ELF Header
See Spec here: ELF Header
Notes:
- e_type: ET_PS3PRX=0xFFA4
- EI_OSABI: ELFOSABI_CELL_LV2=0x66
ELF Program Headers
See Spec here: ELF Program Headers
Segment Information
typedef struct { uint64_t dataOffset; uint64_t dataSize; uint32_t compressed; //1:NO, 2:YES uint32_t unknown03; uint32_t unknown04; uint32_t encrypted; //0:NA, 1:YES, 2:NO } SEGMENTINFO_t;
Notes:
- There is one Segment Information for each ELF Program Header.
Control Information
typedef struct { uint32_t unknown00; uint32_t unknown01; uint32_t unknown02; uint32_t unknown03; uint32_t controlFlags[8]; uint32_t unknown05; uint32_t unknown06; uint32_t unknown07; uint32_t unknown08; char digest[64]; uint32_t unknown10; uint32_t unknown11; } CONTROLINFO_t;
Metadata Information
typedef struct { uint8_t unknown00[32]; uint8_t key[32]; uint8_t ivec[32]; } METADATAINFO_t;
Notes:
- The key and ivec fields are encrypted using AES256CBC.
- This is not present if it is an FSELF.
Metadata Header
typedef struct { uint64_t signatureInputLength; uint32_t unknown02; uint32_t sectionCount; uint32_t keyCount; uint32_t signatureInfoSize; uint32_t unknown06; uint32_t unknown07; } METADATAHEADER_t;
Notes:
- The metadata header is located after the metadata info in the SELF file.
- It is decrypted using AES128CTR with the key and ivec entries from the metadata information.
- The signature input length is the number of bytes which are used to generate the SHA-1 which is used to generate the ECDSA signature. The length should be eveything from the beginning until the signature itself. The decrypted version of the input data is used.
- This is only present if the metadata Information is present.
Metadata Section Headers
typedef struct { uint64_t dataOffset; uint64_t dataSize; uint32_t unknown02; uint32_t programIndex; uint32_t unknown04; uint32_t sha1Index; uint32_t encrypted; //1:NO, 3:YES uint32_t keyIndex; uint32_t ivecIndex; uint32_t compressed; //1:NO, 2:YES } METADATASECTIONHEADER_t;
Notes:
- The metadata section headers are located after the metadata header in the SELF file.
- The number of sections is indicated by the sectionCount entry in the metadata header.
- They are decrypted using AES128CTR with the key and ivec entries from the metadata information.
- Section data is decrypted using AES128CTR with the key and ivec from the metadata keys specified by keyIndex and ivecIndex.
- Section data will also need to be uncompressed using zlib.
- The dataOffsets of the metadata section headers match in general the segment information dataOffsets.
- This is only present if the metadata header is present.
Metadata Keys
typedef uint8_t METADATAKEY_t [16];
Notes:
- The metadata keys are located after the metadata section headers in the SELF file.
- The number of keys is indicated by the keyCount entry in the metadata header.
- They are decrypted using AES128CTR with the key and ivec entries from the metadata information.
- If the sha1Index points to a key, then key[sha1Index] and key[sha1Index+1] form the 160-bit hash. key[sha1Index+2] to key[key[sha1Index+6] form the 512-bit key for the HMAC-SHA1. The HMAC-SHA1 is calculated on the decrypted data and before the decompression.
Signature Information
typedef struct { uint32_t unknown00; uint32_t signatureSize; uint64_t unknown02; uint64_t unknown03; uint64_t unknown04; uint64_t unknown05; uint32_t unknown06; uint32_t unknown07; } SIGNATUREINFO_t;
Notes:
- The signature information is located after the metadata keys in the SELF file.
- It is only present if the signatureInfoSize in the metadata header is not zero.
- It is decrypted using AES128CTR with the key and ivec entries from the metadata information.
Signature
typedef struct { uint8_t r[21]; uint8_t s[21]; uint8_t padding[6]; } SIGNATURE_t;
Notes:
- The signature is located after the the signature information in the SELF file.
- It is even present if the signature information is not present.
- It is decrypted using AES128CTR with the key and ivec entries from the metadata information.
Extracting an ELF
ELF Header
Elf64_Ehdr elfHeader; fseek ( selfFile, fix64 ( selfHeader.elfHeaderOffset ), SEEK_SET ); fread ( &elfHeader, sizeof ( Elf64_Ehdr ), 1, selfFile ); fseek ( elfFile, 0, SEEK_SET ); fwrite ( &elfHeader, sizeof ( Elf64_Ehdr ), 1, elfFile );
Section Headers
Elf64_Shdr elfSectionHeaders[100]; fseek ( selfFile, fix64 ( selfHeader.elfSectionHeadersOffset ), SEEK_SET ); fread ( elfSectionHeaders, sizeof ( Elf64_Shdr ), fix16 ( elfHeader.e_shnum ), selfFile ); fseek ( elfFile, fix64 ( elfHeader.e_shoff ), SEEK_SET ); fwrite ( elfSectionHeaders, sizeof ( Elf64_Shdr ), fix16 ( elfHeader.e_shnum ), elfFile );
Section Data
Notes:
- Unknown, manually copying the data over works for now.
- There should be a section data offset somewhere.
Program Headers
Elf64_Phdr elfProgramHeaders[100]; fseek ( selfFile, fix64 ( selfHeader.elfProgramHeadersOffset ), SEEK_SET ); fread ( elfProgramHeaders, sizeof ( Elf64_Phdr ), fix16 ( elfHeader.e_phnum ), selfFile ); fseek ( elfFile, fix64 ( elfHeader.e_phoff ), SEEK_SET ); fwrite ( elfProgramHeaders, sizeof ( Elf64_Phdr ), fix16 ( elfHeader.e_phnum ), elfFile );
Program Data
Notes:
- Load the metadata information and decrypt the key and ivec entries using AES256CBC using erk and riv.
- Load the metadata header and decrypt it using AES128CTR with the key and ivec entries from the metadata information.
- Load sectionCount metadata section headers and decrypt them using AES128CTR with the key and ivec entries from the metadata information.
- Load keyCount metadata keys and decrypt them using AES128CTR with the key and ivec entries from the metadata information.
- For each metadata section:
- In the SELF file, fseek to dataOffset and read in dataSize bytes.
- Decrypt the data using AES128CTR with the key and ivec from the metadata keys specified by keyIndex and ivecIndex from the metadata section header.
- Uncompress the data using zlib.
- Write it to the ELF file as the program section specified by section Index in the metadata section header.