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Difference between revisions of "Baseband TEA Keys"
(→Hardware Thumbprint Generation) |
(→Hardware Thumbprint Generation) |
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==Key A Generation== |
==Key A Generation== |
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− | //return unique phone key (key A), this key is used for security zone encryption/decryption |
+ | // return unique phone key (key A), this key is used for security zone encryption/decryption |
− | void get_keyA(u8 *A){ |
+ | void get_keyA(u8 *A) { |
SHA1Context ctx; |
SHA1Context ctx; |
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SHA1Reset(&ctx); |
SHA1Reset(&ctx); |
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− | SHA1Input(&ctx,[[NORID|dep1_norid]],0x10); |
+ | SHA1Input(&ctx, [[NORID|dep1_norid]], 0x10); |
− | SHA1Input(&ctx,[[CHIPID|dep2_chipid]],0x10); |
+ | SHA1Input(&ctx, [[CHIPID|dep2_chipid]], 0x10); |
SHA1Result(&ctx); |
SHA1Result(&ctx); |
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− | memcpy(A,(u8*)ctx.Message_Digest,0x14); |
+ | memcpy(A, (u8*)ctx.Message_Digest, 0x14); |
} |
} |
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==NCK Key Generation== |
==NCK Key Generation== |
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//ulc_mix_lock_unlock_key((u8*)A,(u8*)ctx.Message_Digest,dep1_norid,dep2_chipid,(u8*)B); |
//ulc_mix_lock_unlock_key((u8*)A,(u8*)ctx.Message_Digest,dep1_norid,dep2_chipid,(u8*)B); |
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− | void ulc_mix_lock_unlock_key(u8 *keyA, u8 *keyNCK,u8 *norid,u8 *chipid,u8 *keyB){ |
+ | void ulc_mix_lock_unlock_key(u8 *keyA, u8 *keyNCK, u8 *norid, u8 *chipid, u8 *keyB) { |
u8 out_iv[8]; |
u8 out_iv[8]; |
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tea_3_round_encipher(norid,keyNCK,keyA,keyB,out_iv); //norid, keyNCK, SP+4, SP+0x14, SP+0x34 |
tea_3_round_encipher(norid,keyNCK,keyA,keyB,out_iv); //norid, keyNCK, SP+4, SP+0x14, SP+0x34 |
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tea_3_round_encipher(chipid,keyNCK,out_iv,keyB+8,out_iv); //chipid, keyNCK, SP+4, SP+0x14, SP+0x34 |
tea_3_round_encipher(chipid,keyNCK,out_iv,keyB+8,out_iv); //chipid, keyNCK, SP+4, SP+0x14, SP+0x34 |
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} |
} |
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+ | |||
// auxilary function for nck key generation |
// auxilary function for nck key generation |
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− | void tea_3_round_encipher(u8 *in,u8 *key,u8 *iv,u8 *out,u8 *out_iv){ |
+ | void tea_3_round_encipher(u8 *in, u8 *key, u8 *iv, u8 *out, u8 *out_iv){ |
− | u32 tmpin[2],nexttea[2]; |
+ | u32 tmpin[2], nexttea[2]; |
− | tea_encipher((u32*)in,tmpin,(u32*)key); |
+ | tea_encipher((u32*)in, tmpin, (u32*)key); |
nexttea[0] = tmpin[0]^((u32*)iv)[0]; |
nexttea[0] = tmpin[0]^((u32*)iv)[0]; |
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nexttea[1] = tmpin[1]^((u32*)iv)[1]; |
nexttea[1] = tmpin[1]^((u32*)iv)[1]; |
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− | tea_encipher(nexttea,(u32*)out,(u32*)key); |
+ | tea_encipher(nexttea, (u32*)out, (u32*)key); |
nexttea[0] = tmpin[0]^((u32*)out)[0]; |
nexttea[0] = tmpin[0]^((u32*)out)[0]; |
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nexttea[1] = tmpin[1]^((u32*)out)[1]; |
nexttea[1] = tmpin[1]^((u32*)out)[1]; |
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− | tea_encipher(nexttea,(u32*)out_iv,(u32*)key); |
+ | tea_encipher(nexttea, (u32*)out_iv, (u32*)key); |
} |
} |
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==Hardware Thumbprint Generation== |
==Hardware Thumbprint Generation== |
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− | u8 salt[20] = { |
+ | u8 salt[20] = { |
+ | 0x03, 0x5E, 0x20, 0x03, |
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− | 0xBB, 0x2D, 0x59, 0x28, 0xBF, 0x10, 0xAE, 0xB9, |
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+ | 0xA9, 0x74, 0xFC, 0x57, |
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− | 0x00, 0x00, 0x00, 0x00 |
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+ | 0xBB, 0x2D, 0x59, 0x28, |
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− | } ; |
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+ | 0xBF, 0x10, 0xAE, 0xB9, |
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+ | 0x00, 0x00, 0x00, 0x00 |
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+ | }; |
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void getHardwareThumbPrint(u8 *hwTP){ |
void getHardwareThumbPrint(u8 *hwTP){ |
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SHA1Context ctx; |
SHA1Context ctx; |
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SHA1Reset(&ctx); |
SHA1Reset(&ctx); |
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− | SHA1Input(&ctx,[[CHIPID|chipid]],16); |
+ | SHA1Input(&ctx, [[CHIPID|chipid]], 16); |
− | SHA1Input(&ctx,[[NORID|norid]],16); |
+ | SHA1Input(&ctx, [[NORID|norid]], 16); |
− | SHA1Input(&ctx,imei,16); //nibble encoded |
+ | SHA1Input(&ctx, imei, 16); //nibble encoded |
− | SHA1Input(&ctx,salt,20); |
+ | SHA1Input(&ctx, salt, 20); |
SHA1Result(&ctx); |
SHA1Result(&ctx); |
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− | memcpy(hwTP,(u8*)ctx.Message_Digest,0x14); |
+ | memcpy(hwTP, (u8*)ctx.Message_Digest, 0x14); |
} |
} |
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− | Apple calls this "BasebandThumbprint". |
+ | Apple calls this "BasebandThumbprint". It can be obtained from the baseband serial port with [[Baseband Commands|at+xthumb?]]. |
==[[Wildcard Ticket]] Key Generation== |
==[[Wildcard Ticket]] Key Generation== |
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− | void getWildcardKey(u8 *wKey){ |
+ | void getWildcardKey(u8 *wKey) { |
u8 hwTP[20]; |
u8 hwTP[20]; |
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getHardwareThumbPrint(&hwTP); |
getHardwareThumbPrint(&hwTP); |
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SHA1Context ctx; |
SHA1Context ctx; |
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SHA1Reset(&ctx); |
SHA1Reset(&ctx); |
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− | SHA1Input(&ctx,hwTP,20); |
+ | SHA1Input(&ctx, hwTP, 20); |
− | SHA1Input(&ctx,salt,20); |
+ | SHA1Input(&ctx, salt, 20); |
SHA1Result(&ctx); |
SHA1Result(&ctx); |
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− | memcpy(wKey,(u8*)ctx.Message_Digest,0x14); |
+ | memcpy(wKey, (u8*)ctx.Message_Digest, 0x14); |
} |
} |
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− | + | This generates the key which can be used to encrypt/decrypt the wildcard ticket - the [[CHIPID|chipID]]/[[NORID|norID]] are NOT required. |
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[[Category:Baseband]] |
[[Category:Baseband]] |
Latest revision as of 19:51, 29 April 2012
The baseband generates TEA keys based of the CHIPID and NORID.
Contents
Key A Generation
// return unique phone key (key A), this key is used for security zone encryption/decryption void get_keyA(u8 *A) { SHA1Context ctx; SHA1Reset(&ctx); SHA1Input(&ctx, dep1_norid, 0x10); SHA1Input(&ctx, dep2_chipid, 0x10); SHA1Result(&ctx); memcpy(A, (u8*)ctx.Message_Digest, 0x14); }
NCK Key Generation
//ulc_mix_lock_unlock_key((u8*)A,(u8*)ctx.Message_Digest,dep1_norid,dep2_chipid,(u8*)B); void ulc_mix_lock_unlock_key(u8 *keyA, u8 *keyNCK, u8 *norid, u8 *chipid, u8 *keyB) { u8 out_iv[8]; tea_3_round_encipher(norid,keyNCK,keyA,keyB,out_iv); //norid, keyNCK, SP+4, SP+0x14, SP+0x34 tea_3_round_encipher(chipid,keyNCK,out_iv,keyB+8,out_iv); //chipid, keyNCK, SP+4, SP+0x14, SP+0x34 } // auxilary function for nck key generation void tea_3_round_encipher(u8 *in, u8 *key, u8 *iv, u8 *out, u8 *out_iv){ u32 tmpin[2], nexttea[2]; tea_encipher((u32*)in, tmpin, (u32*)key); nexttea[0] = tmpin[0]^((u32*)iv)[0]; nexttea[1] = tmpin[1]^((u32*)iv)[1]; tea_encipher(nexttea, (u32*)out, (u32*)key); nexttea[0] = tmpin[0]^((u32*)out)[0]; nexttea[1] = tmpin[1]^((u32*)out)[1]; tea_encipher(nexttea, (u32*)out_iv, (u32*)key); }
Hardware Thumbprint Generation
u8 salt[20] = { 0x03, 0x5E, 0x20, 0x03, 0xA9, 0x74, 0xFC, 0x57, 0xBB, 0x2D, 0x59, 0x28, 0xBF, 0x10, 0xAE, 0xB9, 0x00, 0x00, 0x00, 0x00 };
void getHardwareThumbPrint(u8 *hwTP){ SHA1Context ctx; SHA1Reset(&ctx); SHA1Input(&ctx, chipid, 16); SHA1Input(&ctx, norid, 16); SHA1Input(&ctx, imei, 16); //nibble encoded SHA1Input(&ctx, salt, 20); SHA1Result(&ctx); memcpy(hwTP, (u8*)ctx.Message_Digest, 0x14); }
Apple calls this "BasebandThumbprint". It can be obtained from the baseband serial port with at+xthumb?.
Wildcard Ticket Key Generation
void getWildcardKey(u8 *wKey) { u8 hwTP[20]; getHardwareThumbPrint(&hwTP); SHA1Context ctx; SHA1Reset(&ctx); SHA1Input(&ctx, hwTP, 20); SHA1Input(&ctx, salt, 20); SHA1Result(&ctx); memcpy(wKey, (u8*)ctx.Message_Digest, 0x14); }
This generates the key which can be used to encrypt/decrypt the wildcard ticket - the chipID/norID are NOT required.