I'm trying to read the EF.COM file from an ePassport (a.k.a MRTD).
What I have successfully done:
-Selected the ePassport application using the AID 0xA0,0x00,0x00,0x02,0x47,0x10,0x01 -Requested a challenge nonce from the epassport chip -Successfully authenticated by responding to that challenge as per doc9303 appendix 5. Doc 9303 can be viewed here: http://www.icao.int/publications/Documents/9303_p1_v2_cons_en.pdf
It worked and now I am attempting to read the EF.COM file using the secure messaging protocol as per ISO 7816-4 and I used the doc9303 appendix 6 examples as a guide.
What my secure messaging code does correctly as per the examples in doc9303:
-It generates the exact same secure APDUs, byte for byte, as those in the doc9303 examples given the same inputs. -I have verified that my encryption (3DES w/CBC) is working, as is my MAC algorithm
What I have tried:
So I searched and found two open source implementations of the ePassport/MRTD/doc9303. One in Python (pyPassport-1.0) and the other in Java (JMRTD). I ordered the ACR122 reader (uses the same NFC chipset - PN532) to try it and it does work. So I then looked at the code JMRTD and pyPassport use to generate the secure messaging APDUs and it appears as though I am doing the same thing. Thankfully the JMRTD comes with an option to dump/trace the APDUs to a log file. Sure enough I am creating the secure messaging APDUs exactly as JMRTD is, I even reverse engineered a session (decrypted the RND.IFD, RND.ICC, K.ICC, session keys, etc..), created a test case and my code does in fact generate the same secure APDU output.
So I think I am constructing the secure messaging APDUs and DOs (Data Objects) correctly, but after I perform BAC and authenticate and try to read the EF.COM file with a protected APDU I keep getting a 69 88 error (Incorrect secure messaging (SM) data object). This is similar to the problem reported here although I am not using Android but my own embedded NFC stack: Android NFC read data from ePassport
I think it may be a setting in the PN532 (NXP NFC Chip) that I need to change but I doubt that since I am authenticating correctly and sending and transmitting data without PN532 errors. I tried raising the baud rate to 424 kbits/s but that did not fix it.
Here is an example of a secure (protected) APDU that my code generates.
Raw (unsecured) APDU:
00 A4 02 0C 02 01 1E
Protected (secure) APDU: 0C A4 02 0C 15 87 09 01 5B B0 63 B9 2A 0D 71 C0 8E 08 E0 B6 68 D2 14 4F 28 B5 00
So as per the doc9303 I am constructing a DO87 since command parameters are present, and a DO8E since there is a checksum (MAC) present, but no DO97 since no response payload is expected. I am using 87 09 01 for the DO87 since the 01 means padding type 80 00 00... and the L is 09 (I guess it includes the 01 - padding indicator byte, this is what is in the examples and APDU traces from JMRTD.)
I have tried removing the Le=0x00 from the end since some language in the 7816-4 doc suggests that, as well as making Lc' 0x16 rather than 0x15 as shown above. I have also tried making to DO87 to be 87 08 01 instead of 87 09 01 as shown above. None of that has worked.
I am really desperate here, I've been working on this for some time and just can't figure it out. Is there something wrong with my protected APDU structure? Is there a low level PN532 setting I need to change?
UPDATE ON 19-March-2014 Here is the PN532 command/response trace (I annotated it so it's less gobedy gook):
-> GetFirmwareVersion (test command to verify PN532 is awake and online): 00FF02FED4022A0000 0000FF00FF0000 ->ACK -> Response to GetFirwareVersion: 00FF06FAD50332010607E80000 -> Diagnose, NumTst=0x00: 00FF12EED400000102030405060708090A0B0C0D0E0FB40000 00FF00FF0000 ->ACK -> Successfull diagnostic (Data returned): 00FF12EED501000102030405060708090A0B0C0D0E0FB20000 -> Diagnose NumTst=0x01: 00FF03FDD400012B0000 00FF00FF0000 ->ACK -> Successfull diagnostic (0x00): 00FF03FDD501002A0000 -> Diagnose NumTst=0x02: 00FF03FDD400022A0000 00FF00FF0000 ->ACK -> Successfull diagnostic (0x00): 00FF03FDD501002A0000 -> InListPassiveTarget (max targets one, 106kbit/s Type A anticollision) 00FF04FCD44A0100E10000 00FF00FF0000 ->ACK -> Found one target, Tg=0x01, SENS_RES=0x07,0x04, SEL_RES=0x20 -> UID = 0x08,0x8B,0x05,0xCF, ATS = 0x05,0x78,0x77,0xB4,0x02 DCS=0x9E: 00FF11EFD54B010107042004088B05CF057877B4029E0000 -> inPSL (change baud to 424kbits/s) 00FF05FBD44E010202D90000 00FF00FF0000 -> ACK 00FF03FDD54F00DC0000 -> Status = 0x00, success -> inDataExchange (select ePassport application w/ AID in doc9303): 00FF0FF1D4400100A4040C07A0000002471001360000 00FF00FF0000 -> ACK 00FF05FBD5410090005A0000 -> SW1SW2 = 9000 (success) -> inDataExchange (get nonce/challenge) 00FF08F8D4400100840000085F0000 00FF00FF0000 -> ACK 00FF0DF3D541008EAF826F89F1E5259000A80000 -> SW1SW2 = 9000 (success), RND.ICC = 0x8E,0xAF,0x82,0x6F,0x89,0xF1,0xE5,0x25 -> inDataExchange (mutual authenticate) 00FF31CFD4400100820000284782B1700DD4F60373DA6632FCD1AB1E500D46FA11DEBDF9B88C39FCA7FDF8DBBE51F41D52D4B87928310000 00FF00FF0000 -> ACK 00FF2DD3D5410055A930856698D46C2AEF3CEDF3C56E71668150F2FECC75E28F42AB2A57CD2BA2F42727AE656CB3F49000470000 -> SW1SW2 = 9000 (success) -> inDataExchange (select EF.COM) 00FF1EE2D440010CA4020C158709012CA8E7AB995D13248E0810061DDC725A159300DB0000 00FF00FF0000 ->ACK 00FF05FBD541006988F90000 -> SW1SW2 = 6988 (Incorrect SM Data Objects)..BAH!!
The Session details are below:
MRZ = GF043591<586012072309062 Computed values from MRZ: Kenc = BA 43 43 3B F4 7A AE F8 75 23 4F DF 32 08 20 6D Kmac = EA 64 45 CD 62 2C EA EC BF 7C 9B 7C B0 20 B9 5D RND.ICC = 8E AF 82 6F 89 F1 E5 25 RND.IFD = 23 E8 5A 99 3A 9A C5 B4 K.IFD = 75 DC 87 E5 0C 8E F3 00 47 D0 B5 32 5E 83 20 4D SSC = 89 F1 E5 25 3A 9A C5 B4 The computed E.IFD = 47 82 B1 70 0D D4 F6 03 73 DA 66 32 FC D1 AB 1E 50 0D 46 FA 11 DE BD F9 B8 8C 39 FC A7 FD F8 DB The computed MAC of the above = BE 51 F4 1D 52 D4 B8 79 The tag's response to the mutual authenticate was: E[Kenc](RND.ICC) = 55 A9 30 85 66 98 D4 6C E[Kenc](RND.IFD) = 2A EF 3C ED F3 C5 6E 71 E[Kenc](K.ICC) = 66 81 50 F2 FE CC 75 E2 8F 42 AB 2A 57 CD 2B A2 MAC = F4 27 27 AE 65 6C B3 F4 The computed session keys: KSenc = 4C E6 EF A8 3D 3E DA FB FB 02 1A F2 D5 E0 6E 4F KSmac = EA C7 5B 64 D9 80 52 23 4F 64 7A 51 45 7F 40 1A