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sr_srv_calc_ref.py

sr_srv_calc_ref.py 2.5 KB
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  1. # This is a reference implementation of the SRV calculation for prop250. We
    2. 

  2. # use it to generate a test vector for the test_sr_compute_srv() unittest.
    3. 

  3. # (./test shared-random/sr_compute_srv)
    4. 

  4. #
    5. 

  5. # Here is the SRV computation formula:
    6. 

  6. #
    7. 

  7. #      HASHED_REVEALS = H(ID_a | R_a | ID_b | R_b | ..)
    8. 

  8. #
    9. 

  9. #      SRV = SHA3-256("shared-random" | INT_8(reveal_num) | INT_4(version) |
    10. 

  10. #                     HASHED_REVEALS | previous_SRV)
    11. 

  11. #
    12. 

  12. 

  13. import sys
    14. 

  14. import hashlib
    15. 

  15. import struct
    16. 

  16. 

  17. # Python 3.6+, the SHA3 is available in hashlib natively. Else this requires
    18. 

  18. # the pysha3 package (pip install pysha3).
    19. 

  19. if sys.version_info < (3, 6):
    20. 

  20. 	import sha3
    21. 

  21. 

  22. # Test vector to make sure the right sha3 version will be used. pysha3 < 1.0
    23. 

  23. # used the old Keccak implementation. During the finalization of SHA3, NIST
    24. 

  24. # changed the delimiter suffix from 0x01 to 0x06. The Keccak sponge function
    25. 

  25. # stayed the same. pysha3 1.0 provides the previous Keccak hash, too.
    26. 

  26. TEST_VALUE = "e167f68d6563d75bb25f3aa49c29ef612d41352dc00606de7cbd630bb2665f51"
    27. 

  27. if TEST_VALUE != sha3.sha3_256(b"Hello World").hexdigest():
    28. 

  28.   print("pysha3 version is < 1.0. Please install from:")
    29. 

  29.   print("https://github.com/tiran/pysha3https://github.com/tiran/pysha3")
    30. 

  30.   sys.exit(1)
    31. 

  31. 

  32. # In this example, we use three reveal values.
    33. 

  33. reveal_num = 3
    34. 

  34. version = 1
    35. 

  35. 

  36. # We set directly the ascii value because memset(buf, 'A', 20) makes it to 20
    37. 

  37. # times "41" in the final string.
    38. 

  38. 

  39. # Identity and reveal value of dirauth a
    40. 

  40. ID_a = 20 * "41" # RSA identity of 40 base16 bytes.
    41. 

  41. R_a = 56 * 'A' # 56 base64 characters
    42. 

  42. 

  43. # Identity and reveal value of dirauth b
    44. 

  44. ID_b = 20 * "42" # RSA identity of 40 base16 bytes.
    45. 

  45. R_b = 56 * 'B' # 56 base64 characters
    46. 

  46. 

  47. # Identity and reveal value of dirauth c
    48. 

  48. ID_c = 20 * "43" # RSA identity of 40 base16 bytes.
    49. 

  49. R_c = 56 * 'C' # 56 base64 characters
    50. 

  50. 

  51. # Concatenate them all together and hash them to form HASHED_REVEALS.
    52. 

  52. REVEALS = (ID_a + R_a + ID_b + R_b + ID_c + R_c).encode()
    53. 

  53. hashed_reveals_object = hashlib.sha3_256(REVEALS)
    54. 

  54. hashed_reveals = hashed_reveals_object.digest()
    55. 

  55. 

  56. previous_SRV = (32 * 'Z').encode()
    57. 

  57. 

  58. # Now form the message.
    59. 

  59. #srv_msg = struct.pack('13sQL256ss', "shared-random", reveal_num, version,
    60. 

  60. #                      hashed_reveals, previous_SRV)
    61. 

  61. invariant_token = b"shared-random"
    62. 

  62. srv_msg = invariant_token + \
    63. 

  63.           struct.pack('!QL', reveal_num, version) + \
    64. 

  64.           hashed_reveals + \
    65. 

  65.           previous_SRV
    66. 

  66. 

  67. # Now calculate the HMAC
    68. 

  68. srv = hashlib.sha3_256(srv_msg)
    69. 

  69. print("%s" % srv.hexdigest().upper())
    70. 

  70. 

  71. # 2A9B1D6237DAB312A40F575DA85C147663E7ED3F80E9555395F15B515C74253D 
    72.