summaryrefslogtreecommitdiff
path: root/doc/rfc/rfc6234.txt
diff options
context:
space:
mode:
Diffstat (limited to 'doc/rfc/rfc6234.txt')
-rw-r--r--doc/rfc/rfc6234.txt7115
1 files changed, 7115 insertions, 0 deletions
diff --git a/doc/rfc/rfc6234.txt b/doc/rfc/rfc6234.txt
new file mode 100644
index 0000000..814568a
--- /dev/null
+++ b/doc/rfc/rfc6234.txt
@@ -0,0 +1,7115 @@
+
+
+
+
+
+
+Internet Engineering Task Force (IETF) D. Eastlake 3rd
+Request for Comments: 6234 Huawei
+Obsoletes: 4634 T. Hansen
+Updates: 3174 AT&T Labs
+Category: Informational May 2011
+ISSN: 2070-1721
+
+
+ US Secure Hash Algorithms
+ (SHA and SHA-based HMAC and HKDF)
+
+Abstract
+
+ The United States of America has adopted a suite of Secure Hash
+ Algorithms (SHAs), including four beyond SHA-1, as part of a Federal
+ Information Processing Standard (FIPS), namely SHA-224, SHA-256,
+ SHA-384, and SHA-512. This document makes open source code
+ performing these SHA hash functions conveniently available to the
+ Internet community. The sample code supports input strings of
+ arbitrary bit length. Much of the text herein was adapted by the
+ authors from FIPS 180-2.
+
+ This document replaces RFC 4634, fixing errata and adding code for an
+ HMAC-based extract-and-expand Key Derivation Function, HKDF (RFC
+ 5869). As with RFC 4634, code to perform SHA-based Hashed Message
+ Authentication Codes (HMACs) is also included.
+
+Status of This Memo
+
+ This document is not an Internet Standards Track specification; it is
+ published for informational purposes.
+
+ This document is a product of the Internet Engineering Task Force
+ (IETF). It represents the consensus of the IETF community. It has
+ received public review and has been approved for publication by the
+ Internet Engineering Steering Group (IESG). Not all documents
+ approved by the IESG are a candidate for any level of Internet
+ Standard; see Section 2 of RFC 5741.
+
+ Information about the current status of this document, any errata,
+ and how to provide feedback on it may be obtained at
+ http://www.rfc-editor.org/info/rfc6234.
+
+
+
+
+
+
+
+
+
+Eastlake & Hansen Informational [Page 1]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+Copyright Notice
+
+ Copyright (c) 2011 IETF Trust and the persons identified as the
+ document authors. All rights reserved.
+
+ This document is subject to BCP 78 and the IETF Trust's Legal
+ Provisions Relating to IETF Documents
+ (http://trustee.ietf.org/license-info) in effect on the date of
+ publication of this document. Please review these documents
+ carefully, as they describe your rights and restrictions with respect
+ to this document. Code Components extracted from this document must
+ include Simplified BSD License text as described in Section 4.e of
+ the Trust Legal Provisions and are provided without warranty as
+ described in the Simplified BSD License.
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+Eastlake & Hansen Informational [Page 2]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+Table of Contents
+
+ 1. Overview of Contents ............................................4
+ 2. Notation for Bit Strings and Integers ...........................5
+ 3. Operations on Words .............................................6
+ 4. Message Padding and Parsing .....................................8
+ 4.1. SHA-224 and SHA-256 ........................................8
+ 4.2. SHA-384 and SHA-512 ........................................9
+ 5. Functions and Constants Used ...................................10
+ 5.1. SHA-224 and SHA-256 .......................................10
+ 5.2. SHA-384 and SHA-512 .......................................11
+ 6. Computing the Message Digest ...................................12
+ 6.1. SHA-224 and SHA-256 Initialization ........................12
+ 6.2. SHA-224 and SHA-256 Processing ............................13
+ 6.3. SHA-384 and SHA-512 Initialization ........................14
+ 6.4. SHA-384 and SHA-512 Processing ............................15
+ 7. HKDF- and SHA-Based HMACs ......................................17
+ 7.1. SHA-Based HMACs ...........................................17
+ 7.2. HKDF ......................................................17
+ 8. C Code for SHAs, HMAC, and HKDF ................................17
+ 8.1. The Header Files ..........................................21
+ 8.1.1. The .h file ........................................21
+ 8.1.2. stdint-example.h ...................................29
+ 8.1.3. sha-private.h ......................................29
+ 8.2. The SHA Code ..............................................30
+ 8.2.1. sha1.c .............................................30
+ 8.2.2. sha224-256.c .......................................39
+ 8.2.3. sha384-512.c .......................................51
+ 8.2.4. usha.c .............................................73
+ 8.3. The HMAC Code .............................................79
+ 8.4. The HKDF Code .............................................84
+ 8.5. The Test Driver ...........................................91
+ 9. Security Considerations .......................................123
+ 10. Acknowledgements .............................................123
+ 11. References ...................................................124
+ 11.1. Normative References ....................................124
+ 11.2. Informative References ..................................124
+ Appendix: Changes from RFC 4634...................................126
+
+
+
+
+
+
+
+
+
+
+
+
+
+Eastlake & Hansen Informational [Page 3]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+1. Overview of Contents
+
+ This document includes specifications for the United States of
+ America (USA) Federal Information Processing Standard (FIPS) Secure
+ Hash Algorithms (SHAs), code to implement the SHAs, code to implement
+ HMAC (Hashed Message Authentication Code, [RFC2104]) based on the
+ SHAs, and code to implement HKDF (HMAC-based Key Derivation Function,
+ [RFC5869]) based on HMAC. Specifications for HMAC and HKDF are not
+ included as they appear elsewhere in the RFC series [RFC2104]
+ [RFC5869].
+
+ NOTE: Much of the text below is taken from [SHS], and the assertions
+ of the security of the hash algorithms described therein are made by
+ the US Government, the author of [SHS], not by the listed authors of
+ this document. See also [RFC6194] concerning the security of SHA-1.
+
+ The text below specifies Secure Hash Algorithms, SHA-224 [RFC3874],
+ SHA-256, SHA-384, and SHA-512, for computing a condensed
+ representation of a message or a data file. (SHA-1 is specified in
+ [RFC3174].) When a message of any length < 2^64 bits (for SHA-224 and
+ SHA-256) or < 2^128 bits (for SHA-384 and SHA-512) is input to one of
+ these algorithms, the result is an output called a message digest.
+ The message digests range in length from 224 to 512 bits, depending
+ on the algorithm. Secure Hash Algorithms are typically used with
+ other cryptographic algorithms, such as digital signature algorithms
+ and keyed-hash authentication codes, the generation of random numbers
+ [RFC4086], or in key derivation functions.
+
+ The algorithms specified in this document are called secure because
+ it is computationally infeasible to (1) find a message that
+ corresponds to a given message digest, or (2) find two different
+ messages that produce the same message digest. Any change to a
+ message in transit will, with very high probability, result in a
+ different message digest. This will result in a verification failure
+ when the Secure Hash Algorithm is used with a digital signature
+ algorithm or a keyed-hash message authentication algorithm.
+
+ The code provided herein supports input strings of arbitrary bit
+ length. SHA-1's sample code from [RFC3174] has also been updated to
+ handle input strings of arbitrary bit length. Permission is granted
+ for all uses, commercial and non-commercial, of this code.
+
+ This document obsoletes [RFC4634], and the changes from that RFC are
+ summarized in the Appendix.
+
+
+
+
+
+
+
+Eastlake & Hansen Informational [Page 4]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+ ASN.1 OIDs (Object Identifiers) for the SHA algorithms, taken from
+ [RFC4055], are as follows:
+
+ id-sha1 OBJECT IDENTIFIER ::= { iso(1)
+ identified-organization(3) oiw(14)
+ secsig(3) algorithms(2) 26 }
+ id-sha224 OBJECT IDENTIFIER ::= {{ joint-iso-itu-t(2)
+ country(16) us(840) organization(1) gov(101)
+ csor(3) nistalgorithm(4) hashalgs(2) 4 }
+ id-sha256 OBJECT IDENTIFIER ::= { joint-iso-itu-t(2)
+ country(16) us(840) organization(1) gov(101)
+ csor(3) nistalgorithm(4) hashalgs(2) 1 }
+ id-sha384 OBJECT IDENTIFIER ::= { joint-iso-itu-t(2)
+ country(16) us(840) organization(1) gov(101)
+ csor(3) nistalgorithm(4) hashalgs(2) 2 }
+ id-sha512 OBJECT IDENTIFIER ::= { joint-iso-itu-t(2)
+ country(16) us(840) organization(1) gov(101)
+ csor(3) nistalgorithm(4) hashalgs(2) 3 }
+
+ Section 2 below defines the terminology and functions used as
+ building blocks to form these algorithms. Section 3 describes the
+ fundamental operations on words from which these algorithms are
+ built. Section 4 describes how messages are padded up to an integral
+ multiple of the required block size and then parsed into blocks.
+ Section 5 defines the constants and the composite functions used to
+ specify the hash algorithms. Section 6 gives the actual
+ specification for the SHA-224, SHA-256, SHA-384, and SHA-512
+ functions. Section 7 provides pointers to the specification of HMAC
+ keyed message authentication codes and to the specification of an
+ extract-and-expand key derivation function based on HMAC.
+
+ Section 8 gives sample code for the SHA algorithms, for SHA-based
+ HMACs, and for HMAC-based extract-and-expand key derivation function.
+
+2. Notation for Bit Strings and Integers
+
+ The following terminology related to bit strings and integers will be
+ used:
+
+ a. A hex digit is an element of the set {0, 1, ... , 9, A, ... , F}.
+ A hex digit is the representation of a 4-bit string. Examples: 7
+ = 0111, A = 1010.
+
+ b. A word equals a 32-bit or 64-bit string that may be represented
+ as a sequence of 8 or 16 hex digits, respectively. To convert a
+ word to hex digits, each 4-bit string is converted to its hex
+ equivalent as described in (a) above. Example:
+
+
+
+
+Eastlake & Hansen Informational [Page 5]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+ 1010 0001 0000 0011 1111 1110 0010 0011 = A103FE23.
+
+ Throughout this document, the "big-endian" convention is used when
+ expressing both 32-bit and 64-bit words, so that within each word
+ the most significant bit is shown in the leftmost bit position.
+
+ c. An integer may be represented as a word or pair of words.
+
+ An integer between 0 and 2^32 - 1 inclusive may be represented as
+ a 32-bit word. The least significant four bits of the integer are
+ represented by the rightmost hex digit of the word representation.
+ Example: the integer 291 = 2^8+2^5+2^1+2^0 = 256+32+2+1 is
+ represented by the hex word 00000123.
+
+ The same holds true for an integer between 0 and 2^64-1 inclusive,
+ which may be represented as a 64-bit word.
+
+ If Z is an integer, 0 <= z < 2^64, then z = (2^32)x + y where
+ 0 <= x < 2^32 and 0 <= y < 2^32. Since x and y can be represented
+ as words X and Y, respectively, z can be represented as the pair
+ of words (X,Y).
+
+ Again, the "big-endian" convention is used and the most
+ significant word is in the leftmost word position for values
+ represented by multiple-words.
+
+ d. block = 512-bit or 1024-bit string. A block (e.g., B) may be
+ represented as a sequence of 32-bit or 64-bit words.
+
+3. Operations on Words
+
+ The following logical operators will be applied to words in all four
+ hash operations specified herein. SHA-224 and SHA-256 operate on
+ 32-bit words while SHA-384 and SHA-512 operate on 64-bit words.
+
+ In the operations below, x<<n is obtained as follows: discard the
+ leftmost n bits of x and then pad the result with n zeroed bits on
+ the right (the result will still be the same number of bits).
+ Similarly, x>>n is obtained as follows: discard the rightmost n bits
+ of x and then prepend the result with n zeroed bits on the left (the
+ result will still be the same number of bits).
+
+ a. Bitwise logical word operations
+
+ X AND Y = bitwise logical "and" of X and Y.
+
+ X OR Y = bitwise logical "inclusive-or" of X and Y.
+
+
+
+
+Eastlake & Hansen Informational [Page 6]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+ X XOR Y = bitwise logical "exclusive-or" of X and Y.
+
+ NOT X = bitwise logical "complement" of X.
+
+ Example:
+ 01101100101110011101001001111011
+ XOR 01100101110000010110100110110111
+ --------------------------------
+ = 00001001011110001011101111001100
+
+ b. The operation X + Y is defined as follows: words X and Y represent
+ w-bit integers x and y, where 0 <= x < 2^w and 0 <= y < 2^w. For
+ positive integers n and m, let
+
+ n mod m
+
+ be the remainder upon dividing n by m. Compute
+
+ z = (x + y) mod 2^w.
+
+ Then 0 <= z < 2^w. Convert z to a word, Z, and define Z = X + Y.
+
+ c. The right shift operation SHR^n(x), where x is a w-bit word and n
+ is an integer with 0 <= n < w, is defined by
+
+ SHR^n(x) = x>>n
+
+ d. The rotate right (circular right shift) operation ROTR^n(x), where
+ x is a w-bit word and n is an integer with 0 <= n < w, is defined
+ by
+
+ ROTR^n(x) = (x>>n) OR (x<<(w-n))
+
+ e. The rotate left (circular left shift) operation ROTL^n(x), where x
+ is a w-bit word and n is an integer with 0 <= n < w, is defined by
+
+ ROTL^n(X) = (x<<n) OR (x>>(w-n))
+
+ Note the following equivalence relationships, where w is fixed in
+ each relationship:
+
+ ROTL^n(x) = ROTR^(w-n)(x)
+
+ ROTR^n(x) = ROTL^(w-n)(x)
+
+
+
+
+
+
+
+Eastlake & Hansen Informational [Page 7]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+4. Message Padding and Parsing
+
+ The hash functions specified herein are used to compute a message
+ digest for a message or data file that is provided as input. The
+ message or data file should be considered to be a bit string. The
+ length of the message is the number of bits in the message (the empty
+ message has length 0). If the number of bits in a message is a
+ multiple of 8, for compactness we can represent the message in hex.
+ The purpose of message padding is to make the total length of a
+ padded message a multiple of 512 for SHA-224 and SHA-256 or a
+ multiple of 1024 for SHA-384 and SHA-512.
+
+ The following specifies how this padding shall be performed. As a
+ summary, a "1" followed by m "0"s followed by a 64-bit or 128-bit
+ integer are appended to the end of the message to produce a padded
+ message of length 512*n or 1024*n. The appended integer is the
+ length of the original message. The padded message is then processed
+ by the hash function as n 512-bit or 1024-bit blocks.
+
+4.1. SHA-224 and SHA-256
+
+ Suppose a message has length L < 2^64. Before it is input to the
+ hash function, the message is padded on the right as follows:
+
+ a. "1" is appended. Example: if the original message is "01010000",
+ this is padded to "010100001".
+
+ b. K "0"s are appended where K is the smallest, non-negative solution
+ to the equation
+
+ ( L + 1 + K ) mod 512 = 448
+
+ c. Then append the 64-bit block that is L in binary representation.
+ After appending this block, the length of the message will be a
+ multiple of 512 bits.
+
+ Example: Suppose the original message is the bit string
+
+ 01100001 01100010 01100011 01100100 01100101
+
+ After step (a) this gives
+
+ 01100001 01100010 01100011 01100100 01100101 1
+
+
+
+
+
+
+
+
+Eastlake & Hansen Informational [Page 8]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+ Since L = 40, the number of bits in the above is 41 and K = 407
+ "0"s are appended, making the total now 448. This gives the
+ following in hex:
+
+ 61626364 65800000 00000000 00000000
+ 00000000 00000000 00000000 00000000
+ 00000000 00000000 00000000 00000000
+ 00000000 00000000
+
+ The 64-bit representation of L = 40 is hex 00000000 00000028.
+ Hence the final padded message is the following hex
+
+ 61626364 65800000 00000000 00000000
+ 00000000 00000000 00000000 00000000
+ 00000000 00000000 00000000 00000000
+ 00000000 00000000 00000000 00000028
+
+4.2. SHA-384 and SHA-512
+
+ Suppose a message has length L < 2^128. Before it is input to the
+ hash function, the message is padded on the right as follows:
+
+ a. "1" is appended. Example: if the original message is "01010000",
+ this is padded to "010100001".
+
+ b. K "0"s are appended where K is the smallest, non-negative solution
+ to the equation
+
+ ( L + 1 + K ) mod 1024 = 896
+
+ c. Then append the 128-bit block that is L in binary representation.
+ After appending this block, the length of the message will be a
+ multiple of 1024 bits.
+
+ Example: Suppose the original message is the bit string
+
+ 01100001 01100010 01100011 01100100 01100101
+
+ After step (a) this gives
+
+ 01100001 01100010 01100011 01100100 01100101 1
+
+
+
+
+
+
+
+
+
+
+Eastlake & Hansen Informational [Page 9]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+ Since L = 40, the number of bits in the above is 41 and K = 855
+ "0"s are appended, making the total now 896. This gives the
+ following in hex:
+
+ 61626364 65800000 00000000 00000000
+ 00000000 00000000 00000000 00000000
+ 00000000 00000000 00000000 00000000
+ 00000000 00000000 00000000 00000000
+ 00000000 00000000 00000000 00000000
+ 00000000 00000000 00000000 00000000
+ 00000000 00000000 00000000 00000000
+
+ The 128-bit representation of L = 40 is hex 00000000 00000000
+ 00000000 00000028. Hence the final padded message is the
+ following hex:
+
+ 61626364 65800000 00000000 00000000
+ 00000000 00000000 00000000 00000000
+ 00000000 00000000 00000000 00000000
+ 00000000 00000000 00000000 00000000
+ 00000000 00000000 00000000 00000000
+ 00000000 00000000 00000000 00000000
+ 00000000 00000000 00000000 00000000
+ 00000000 00000000 00000000 00000028
+
+5. Functions and Constants Used
+
+ The following subsections give the six logical functions and the
+ table of constants used in each of the hash functions.
+
+5.1. SHA-224 and SHA-256
+
+ SHA-224 and SHA-256 use six logical functions, where each function
+ operates on 32-bit words, which are represented as x, y, and z. The
+ result of each function is a new 32-bit word.
+
+ CH( x, y, z) = (x AND y) XOR ( (NOT x) AND z)
+
+ MAJ( x, y, z) = (x AND y) XOR (x AND z) XOR (y AND z)
+
+ BSIG0(x) = ROTR^2(x) XOR ROTR^13(x) XOR ROTR^22(x)
+
+ BSIG1(x) = ROTR^6(x) XOR ROTR^11(x) XOR ROTR^25(x)
+
+ SSIG0(x) = ROTR^7(x) XOR ROTR^18(x) XOR SHR^3(x)
+
+ SSIG1(x) = ROTR^17(x) XOR ROTR^19(x) XOR SHR^10(x)
+
+
+
+
+Eastlake & Hansen Informational [Page 10]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+ SHA-224 and SHA-256 use the same sequence of sixty-four constant
+ 32-bit words, K0, K1, ..., K63. These words represent the first 32
+ bits of the fractional parts of the cube roots of the first sixty-
+ four prime numbers. In hex, these constant words are as follows
+ (from left to right):
+
+ 428a2f98 71374491 b5c0fbcf e9b5dba5
+ 3956c25b 59f111f1 923f82a4 ab1c5ed5
+ d807aa98 12835b01 243185be 550c7dc3
+ 72be5d74 80deb1fe 9bdc06a7 c19bf174
+ e49b69c1 efbe4786 0fc19dc6 240ca1cc
+ 2de92c6f 4a7484aa 5cb0a9dc 76f988da
+ 983e5152 a831c66d b00327c8 bf597fc7
+ c6e00bf3 d5a79147 06ca6351 14292967
+ 27b70a85 2e1b2138 4d2c6dfc 53380d13
+ 650a7354 766a0abb 81c2c92e 92722c85
+ a2bfe8a1 a81a664b c24b8b70 c76c51a3
+ d192e819 d6990624 f40e3585 106aa070
+ 19a4c116 1e376c08 2748774c 34b0bcb5
+ 391c0cb3 4ed8aa4a 5b9cca4f 682e6ff3
+ 748f82ee 78a5636f 84c87814 8cc70208
+ 90befffa a4506ceb bef9a3f7 c67178f2
+
+5.2. SHA-384 and SHA-512
+
+ SHA-384 and SHA-512 each use six logical functions, where each
+ function operates on 64-bit words, which are represented as x, y, and
+ z. The result of each function is a new 64-bit word.
+
+ CH( x, y, z) = (x AND y) XOR ( (NOT x) AND z)
+
+ MAJ( x, y, z) = (x AND y) XOR (x AND z) XOR (y AND z)
+
+ BSIG0(x) = ROTR^28(x) XOR ROTR^34(x) XOR ROTR^39(x)
+
+ BSIG1(x) = ROTR^14(x) XOR ROTR^18(x) XOR ROTR^41(x)
+
+ SSIG0(x) = ROTR^1(x) XOR ROTR^8(x) XOR SHR^7(x)
+
+ SSIG1(x) = ROTR^19(x) XOR ROTR^61(x) XOR SHR^6(x)
+
+ SHA-384 and SHA-512 use the same sequence of eighty constant 64-bit
+ words, K0, K1, ... K79. These words represent the first 64 bits of
+ the fractional parts of the cube roots of the first eighty prime
+ numbers. In hex, these constant words are as follows (from left to
+ right):
+
+
+
+
+
+Eastlake & Hansen Informational [Page 11]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+ 428a2f98d728ae22 7137449123ef65cd b5c0fbcfec4d3b2f e9b5dba58189dbbc
+ 3956c25bf348b538 59f111f1b605d019 923f82a4af194f9b ab1c5ed5da6d8118
+ d807aa98a3030242 12835b0145706fbe 243185be4ee4b28c 550c7dc3d5ffb4e2
+ 72be5d74f27b896f 80deb1fe3b1696b1 9bdc06a725c71235 c19bf174cf692694
+ e49b69c19ef14ad2 efbe4786384f25e3 0fc19dc68b8cd5b5 240ca1cc77ac9c65
+ 2de92c6f592b0275 4a7484aa6ea6e483 5cb0a9dcbd41fbd4 76f988da831153b5
+ 983e5152ee66dfab a831c66d2db43210 b00327c898fb213f bf597fc7beef0ee4
+ c6e00bf33da88fc2 d5a79147930aa725 06ca6351e003826f 142929670a0e6e70
+ 27b70a8546d22ffc 2e1b21385c26c926 4d2c6dfc5ac42aed 53380d139d95b3df
+ 650a73548baf63de 766a0abb3c77b2a8 81c2c92e47edaee6 92722c851482353b
+ a2bfe8a14cf10364 a81a664bbc423001 c24b8b70d0f89791 c76c51a30654be30
+ d192e819d6ef5218 d69906245565a910 f40e35855771202a 106aa07032bbd1b8
+ 19a4c116b8d2d0c8 1e376c085141ab53 2748774cdf8eeb99 34b0bcb5e19b48a8
+ 391c0cb3c5c95a63 4ed8aa4ae3418acb 5b9cca4f7763e373 682e6ff3d6b2b8a3
+ 748f82ee5defb2fc 78a5636f43172f60 84c87814a1f0ab72 8cc702081a6439ec
+ 90befffa23631e28 a4506cebde82bde9 bef9a3f7b2c67915 c67178f2e372532b
+ ca273eceea26619c d186b8c721c0c207 eada7dd6cde0eb1e f57d4f7fee6ed178
+ 06f067aa72176fba 0a637dc5a2c898a6 113f9804bef90dae 1b710b35131c471b
+ 28db77f523047d84 32caab7b40c72493 3c9ebe0a15c9bebc 431d67c49c100d4c
+ 4cc5d4becb3e42b6 597f299cfc657e2a 5fcb6fab3ad6faec 6c44198c4a475817
+
+6. Computing the Message Digest
+
+ The output of each of the secure hash functions, after being applied
+ to a message of N blocks, is the hash quantity H(N). For SHA-224 and
+ SHA-256, H(i) can be considered to be eight 32-bit words, H(i)0,
+ H(i)1, ... H(i)7. For SHA-384 and SHA-512, it can be considered to
+ be eight 64-bit words, H(i)0, H(i)1, ..., H(i)7.
+
+ As described below, the hash words are initialized, modified as each
+ message block is processed, and finally concatenated after processing
+ the last block to yield the output. For SHA-256 and SHA-512, all of
+ the H(N) variables are concatenated while the SHA-224 and SHA-384
+ hashes are produced by omitting some from the final concatenation.
+
+6.1. SHA-224 and SHA-256 Initialization
+
+ For SHA-224, the initial hash value, H(0), consists of the following
+ 32-bit words in hex:
+
+ H(0)0 = c1059ed8
+ H(0)1 = 367cd507
+ H(0)2 = 3070dd17
+ H(0)3 = f70e5939
+ H(0)4 = ffc00b31
+ H(0)5 = 68581511
+ H(0)6 = 64f98fa7
+ H(0)7 = befa4fa4
+
+
+
+Eastlake & Hansen Informational [Page 12]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+ For SHA-256, the initial hash value, H(0), consists of the following
+ eight 32-bit words, in hex. These words were obtained by taking the
+ first 32 bits of the fractional parts of the square roots of the
+ first eight prime numbers.
+
+ H(0)0 = 6a09e667
+ H(0)1 = bb67ae85
+ H(0)2 = 3c6ef372
+ H(0)3 = a54ff53a
+ H(0)4 = 510e527f
+ H(0)5 = 9b05688c
+ H(0)6 = 1f83d9ab
+ H(0)7 = 5be0cd19
+
+6.2. SHA-224 and SHA-256 Processing
+
+ SHA-224 and SHA-256 perform identical processing on message blocks
+ and differ only in how H(0) is initialized and how they produce their
+ final output. They may be used to hash a message, M, having a length
+ of L bits, where 0 <= L < 2^64. The algorithm uses (1) a message
+ schedule of sixty-four 32-bit words, (2) eight working variables of
+ 32 bits each, and (3) a hash value of eight 32-bit words.
+
+ The words of the message schedule are labeled W0, W1, ..., W63. The
+ eight working variables are labeled a, b, c, d, e, f, g, and h. The
+ words of the hash value are labeled H(i)0, H(i)1, ..., H(i)7, which
+ will hold the initial hash value, H(0), replaced by each successive
+ intermediate hash value (after each message block is processed),
+ H(i), and ending with the final hash value, H(N), after all N blocks
+ are processed. They also use two temporary words, T1 and T2.
+
+ The input message is padded as described in Section 4.1 above, then
+ parsed into 512-bit blocks that are considered to be composed of
+ sixteen 32-bit words M(i)0, M(i)1, ..., M(i)15. The following
+ computations are then performed for each of the N message blocks.
+ All addition is performed modulo 2^32.
+
+ For i = 1 to N
+
+ 1. Prepare the message schedule W:
+ For t = 0 to 15
+ Wt = M(i)t
+ For t = 16 to 63
+ Wt = SSIG1(W(t-2)) + W(t-7) + SSIG0(w(t-15)) + W(t-16)
+
+
+
+
+
+
+
+Eastlake & Hansen Informational [Page 13]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+ 2. Initialize the working variables:
+ a = H(i-1)0
+ b = H(i-1)1
+ c = H(i-1)2
+ d = H(i-1)3
+ e = H(i-1)4
+ f = H(i-1)5
+ g = H(i-1)6
+ h = H(i-1)7
+
+ 3. Perform the main hash computation:
+ For t = 0 to 63
+ T1 = h + BSIG1(e) + CH(e,f,g) + Kt + Wt
+ T2 = BSIG0(a) + MAJ(a,b,c)
+ h = g
+ g = f
+ f = e
+ e = d + T1
+ d = c
+ c = b
+ b = a
+ a = T1 + T2
+
+ 4. Compute the intermediate hash value H(i)
+ H(i)0 = a + H(i-1)0
+ H(i)1 = b + H(i-1)1
+ H(i)2 = c + H(i-1)2
+ H(i)3 = d + H(i-1)3
+ H(i)4 = e + H(i-1)4
+ H(i)5 = f + H(i-1)5
+ H(i)6 = g + H(i-1)6
+ H(i)7 = h + H(i-1)7
+
+ After the above computations have been sequentially performed for all
+ of the blocks in the message, the final output is calculated. For
+ SHA-256, this is the concatenation of all of H(N)0, H(N)1, through
+ H(N)7. For SHA-224, this is the concatenation of H(N)0, H(N)1,
+ through H(N)6.
+
+6.3. SHA-384 and SHA-512 Initialization
+
+ For SHA-384, the initial hash value, H(0), consists of the following
+ eight 64-bit words, in hex. These words were obtained by taking the
+ first 64 bits of the fractional parts of the square roots of the
+ ninth through sixteenth prime numbers.
+
+
+
+
+
+
+Eastlake & Hansen Informational [Page 14]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+ H(0)0 = cbbb9d5dc1059ed8
+ H(0)1 = 629a292a367cd507
+ H(0)2 = 9159015a3070dd17
+ H(0)3 = 152fecd8f70e5939
+ H(0)4 = 67332667ffc00b31
+ H(0)5 = 8eb44a8768581511
+ H(0)6 = db0c2e0d64f98fa7
+ H(0)7 = 47b5481dbefa4fa4
+
+ For SHA-512, the initial hash value, H(0), consists of the following
+ eight 64-bit words, in hex. These words were obtained by taking the
+ first 64 bits of the fractional parts of the square roots of the
+ first eight prime numbers.
+
+ H(0)0 = 6a09e667f3bcc908
+ H(0)1 = bb67ae8584caa73b
+ H(0)2 = 3c6ef372fe94f82b
+ H(0)3 = a54ff53a5f1d36f1
+ H(0)4 = 510e527fade682d1
+ H(0)5 = 9b05688c2b3e6c1f
+ H(0)6 = 1f83d9abfb41bd6b
+ H(0)7 = 5be0cd19137e2179
+
+6.4. SHA-384 and SHA-512 Processing
+
+ SHA-384 and SHA-512 perform identical processing on message blocks
+ and differ only in how H(0) is initialized and how they produce their
+ final output. They may be used to hash a message, M, having a length
+ of L bits, where 0 <= L < 2^128. The algorithm uses (1) a message
+ schedule of eighty 64-bit words, (2) eight working variables of 64
+ bits each, and (3) a hash value of eight 64-bit words.
+
+ The words of the message schedule are labeled W0, W1, ..., W79. The
+ eight working variables are labeled a, b, c, d, e, f, g, and h. The
+ words of the hash value are labeled H(i)0, H(i)1, ..., H(i)7, which
+ will hold the initial hash value, H(0), replaced by each successive
+ intermediate hash value (after each message block is processed),
+ H(i), and ending with the final hash value, H(N) after all N blocks
+ are processed.
+
+ The input message is padded as described in Section 4.2 above, then
+ parsed into 1024-bit blocks that are considered to be composed of
+ sixteen 64-bit words M(i)0, M(i)1, ..., M(i)15. The following
+ computations are then performed for each of the N message blocks.
+ All addition is performed modulo 2^64.
+
+
+
+
+
+
+Eastlake & Hansen Informational [Page 15]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+ For i = 1 to N
+
+ 1. Prepare the message schedule W:
+ For t = 0 to 15
+ Wt = M(i)t
+ For t = 16 to 79
+ Wt = SSIG1(W(t-2)) + W(t-7) + SSIG0(W(t-15)) + W(t-16)
+
+ 2. Initialize the working variables:
+ a = H(i-1)0
+ b = H(i-1)1
+ c = H(i-1)2
+ d = H(i-1)3
+ e = H(i-1)4
+ f = H(i-1)5
+ g = H(i-1)6
+ h = H(i-1)7
+
+ 3. Perform the main hash computation:
+ For t = 0 to 79
+ T1 = h + BSIG1(e) + CH(e,f,g) + Kt + Wt
+ T2 = BSIG0(a) + MAJ(a,b,c)
+ h = g
+ g = f
+ f = e
+ e = d + T1
+ d = c
+ c = b
+ b = a
+ a = T1 + T2
+
+ 4. Compute the intermediate hash value H(i)
+ H(i)0 = a + H(i-1)0
+ H(i)1 = b + H(i-1)1
+ H(i)2 = c + H(i-1)2
+ H(i)3 = d + H(i-1)3
+ H(i)4 = e + H(i-1)4
+ H(i)5 = f + H(i-1)5
+ H(i)6 = g + H(i-1)6
+ H(i)7 = h + H(i-1)7
+
+ After the above computations have been sequentially performed for all
+ of the blocks in the message, the final output is calculated. For
+ SHA-512, this is the concatenation of all of H(N)0, H(N)1, through
+ H(N)7. For SHA-384, this is the concatenation of H(N)0, H(N)1,
+ through H(N)5.
+
+
+
+
+
+Eastlake & Hansen Informational [Page 16]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+7. HKDF- and SHA-Based HMACs
+
+ Below are brief descriptions and pointers to more complete
+ descriptions and code for (1) SHA-based HMACs and (2) an HMAC-based
+ extract-and-expand key derivation function. Both HKDF and HMAC were
+ devised by Hugo Krawczyk.
+
+7.1. SHA-Based HMACs
+
+ HMAC is a method for computing a keyed MAC (Message Authentication
+ Code) using a hash function as described in [RFC2104]. It uses a key
+ to mix in with the input text to produce the final hash.
+
+ Sample code is also provided, in Section 8.3 below, to perform HMAC
+ based on any of the SHA algorithms described herein. The sample code
+ found in [RFC2104] was written in terms of a specified text size.
+ Since SHA is defined in terms of an arbitrary number of bits, the
+ sample HMAC code has been written to allow the text input to HMAC to
+ have an arbitrary number of octets and bits. A fixed-length
+ interface is also provided.
+
+7.2. HKDF
+
+ HKDF is a specific Key Derivation Function (KDF), that is, a function
+ of initial keying material from which the KDF derives one or more
+ cryptographically strong secret keys. HKDF, which is described in
+ [RFC5869], is based on HMAC.
+
+ Sample code for HKDF is provided in Section 8.4 below.
+
+8. C Code for SHAs, HMAC, and HKDF
+
+ Below is a demonstration implementation of these secure hash
+ functions in C. Section 8.1 contains the header file sha.h that
+ declares all constants, structures, and functions used by the SHA and
+ HMAC functions. It includes conditionals based on the state of
+ definition of USE_32BIT_ONLY that, if that symbol is defined at
+ compile time, avoids 64-bit operations. It also contains sha-
+ private.h that provides some declarations common to all the SHA
+ functions. Section 8.2 contains the C code for sha1.c, sha224-256.c,
+ sha384-512.c, and usha.c. Section 8.3 contains the C code for the
+ HMAC functions, and Section 8.4 contains the C code for HKDF.
+ Section 8.5 contains a test driver to exercise the code.
+
+ For each of the digest lengths $$$, there is the following set of
+ constants, a structure, and functions:
+
+
+
+
+
+Eastlake & Hansen Informational [Page 17]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+ Constants:
+ SHA$$$HashSize number of octets in the hash
+ SHA$$$HashSizeBits number of bits in the hash
+ SHA$$$_Message_Block_Size
+ number of octets used in the intermediate
+ message blocks
+ Most functions return an enum value that is one of:
+ shaSuccess(0) on success
+ shaNull(1) when presented with a null pointer parameter
+ shaInputTooLong(2) when the input data is too long
+ shaStateError(3) when SHA$$$Input is called after
+ SHA$$$FinalBits or SHA$$$Result
+
+ Structure:
+ typedef SHA$$$Context
+ an opaque structure holding the complete state
+ for producing the hash
+
+ Functions:
+ int SHA$$$Reset(SHA$$$Context *context);
+ Reset the hash context state.
+ int SHA$$$Input(SHA$$$Context *context, const uint8_t *octets,
+ unsigned int bytecount);
+ Incorporate bytecount octets into the hash.
+ int SHA$$$FinalBits(SHA$$$Context *, const uint8_t octet,
+ unsigned int bitcount);
+ Incorporate bitcount bits into the hash. The bits are in
+ the upper portion of the octet. SHA$$$Input() cannot be
+ called after this.
+ int SHA$$$Result(SHA$$$Context *,
+ uint8_t Message_Digest[SHA$$$HashSize]);
+ Do the final calculations on the hash and copy the value
+ into Message_Digest.
+
+ In addition, functions with the prefix USHA are provided that take a
+ SHAversion value (SHA$$$) to select the SHA function suite. They add
+ the following constants, structure, and functions:
+
+ Constants:
+ shaBadParam(4) constant returned by USHA functions when
+ presented with a bad SHAversion (SHA$$$)
+ parameter or other illegal parameter values
+ USAMaxHashSize maximum of the SHA hash sizes
+ SHA$$$ SHAversion enumeration values, used by USHA,
+ HMAC, and HKDF functions to select the SHA
+ function suite
+
+
+
+
+
+Eastlake & Hansen Informational [Page 18]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+ Structure:
+ typedef USHAContext
+ an opaque structure holding the complete state
+ for producing the hash
+
+ Functions:
+ int USHAReset(USHAContext *context, SHAversion whichSha);
+ Reset the hash context state.
+ int USHAInput(USHAContext context*,
+ const uint8_t *bytes, unsigned int bytecount);
+ Incorporate bytecount octets into the hash.
+ int USHAFinalBits(USHAContext *context,
+ const uint8_t bits, unsigned int bitcount);
+ Incorporate bitcount bits into the hash.
+ int USHAResult(USHAContext *context,
+ uint8_t Message_Digest[USHAMaxHashSize]);
+ Do the final calculations on the hash and copy the value
+ into Message_Digest. Octets in Message_Digest beyond
+ USHAHashSize(whichSha) are left untouched.
+ int USHAHashSize(enum SHAversion whichSha);
+ The number of octets in the given hash.
+ int USHAHashSizeBits(enum SHAversion whichSha);
+ The number of bits in the given hash.
+ int USHABlockSize(enum SHAversion whichSha);
+ The internal block size for the given hash.
+ const char *USHAHashName(enum SHAversion whichSha);
+ This function will return the name of the given SHA
+ algorithm as a string.
+
+ The HMAC functions follow the same pattern to allow any length of
+ text input to be used.
+
+ Structure:
+ typedef HMACContext an opaque structure holding the complete state
+ for producing the keyed message digest (MAC)
+
+ Functions:
+ int hmacReset(HMACContext *ctx, enum SHAversion whichSha,
+ const unsigned char *key, int key_len);
+ Reset the MAC context state.
+ int hmacInput(HMACContext *ctx, const unsigned char *text,
+ int text_len);
+ Incorporate text_len octets into the MAC.
+ int hmacFinalBits(HMACContext *ctx, const uint8_t bits,
+ unsigned int bitcount);
+ Incorporate bitcount bits into the MAC.
+ int hmacResult(HMACContext *ctx,
+ uint8_t Message_Digest[USHAMaxHashSize]);
+
+
+
+Eastlake & Hansen Informational [Page 19]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+ Do the final calculations on the MAC and copy the value into
+ Message_Digest. Octets in Message_Digest beyond
+ USHAHashSize(whichSha) are left untouched.
+
+ In addition, a combined interface is provided, similar to that shown
+ in [RFC2104], that allows a fixed-length text input to be used.
+
+ int hmac(SHAversion whichSha,
+ const unsigned char *text, int text_len,
+ const unsigned char *key, int key_len,
+ uint8_t Message_Digest[USHAMaxHashSize]);
+ Calculate the given digest for the given text and key, and
+ return the resulting MAC. Octets in Message_Digest beyond
+ USHAHashSize(whichSha) are left untouched.
+
+ The HKDF functions follow the same pattern to allow any length of
+ text input to be used.
+
+ Structure:
+ typedef HKDFContext an opaque structure holding the complete state
+ for producing the keying material
+ Functions:
+ int hkdfReset(HKDFContext *context, enum SHAversion whichSha,
+ const unsigned char *salt, int salt_len)
+ Reset the key derivation state and initialize it with the
+ salt_len octets of the optional salt.
+ int hkdfInput(HKDFContext *context, const unsigned char *ikm,
+ int ikm_len)
+ Incorporate ikm_len octets into the entropy extractor.
+ int hkdfFinalBits(HKDFContext *context, uint8_t ikm_bits,
+ unsigned int ikm_bit_count)
+ Incorporate ikm_bit_count bits into the entropy extractor.
+ int hkdfResult(HKDFContext *context,
+ uint8_t prk[USHAMaxHashSize],
+ const unsigned char *info, int info_len,
+ uint8_t okm[ ], int okm_len)
+ Finish the HKDF extraction and perform the final HKDF
+ expansion, storing the okm_len octets into output keying
+ material (okm). Optionally store the pseudo-random key
+ (prk) that is generated internally.
+
+ In addition, combined interfaces are provided, similar to that shown
+ in [RFC5869], that allows a fixed-length text input to be used.
+
+ int hkdfExtract(SHAversion whichSha,
+ const unsigned char *salt, int salt_len,
+ const unsigned char *ikm, int ikm_len,
+ uint8_t prk[USHAMaxHashSize])
+
+
+
+Eastlake & Hansen Informational [Page 20]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+ Perform HKDF extraction, combining the salt_len octets of
+ the optional salt with the ikm_len octets of the input
+ keying material (ikm) to form the pseudo-random key prk.
+ The output prk must be large enough to hold the octets
+ appropriate for the given hash type.
+
+ int hkdfExpand(SHAversion whichSha,
+ const uint8_t prk[ ], int prk_len,
+ const unsigned char *info, int info_len,
+ uint8_t okm[ ], int okm_len)
+ Perform HKDF expansion, combining the prk_len octets of the
+ pseudo-random key prk with the info_len octets of info to
+ form the okm_len octets stored in okm.
+
+ int hkdf(SHAversion whichSha,
+ const unsigned char *salt, int salt_len,
+ const unsigned char *ikm, int ikm_len,
+ const unsigned char *info, int info_len,
+ uint8_t okm[ ], int okm_len)
+ This combined interface performs both HKDF extraction and
+ expansion. The variables are the same as in hkdfExtract()
+ and hkdfExpand().
+
+8.1. The Header Files
+
+8.1.1. The .h file
+
+ The following sha.h file, as stated in the comments within the file,
+ assumes that <stdint.h> is available on your system. If it is not,
+ you should change to including <stdint-example.h>, provided in
+ Section 8.1.2, or the like.
+
+/**************************** sha.h ****************************/
+/***************** See RFC 6234 for details. *******************/
+/*
+ Copyright (c) 2011 IETF Trust and the persons identified as
+ authors of the code. All rights reserved.
+
+ Redistribution and use in source and binary forms, with or
+ without modification, are permitted provided that the following
+ conditions are met:
+
+ - Redistributions of source code must retain the above
+ copyright notice, this list of conditions and
+ the following disclaimer.
+
+
+
+
+
+
+Eastlake & Hansen Informational [Page 21]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+ - Redistributions in binary form must reproduce the above
+ copyright notice, this list of conditions and the following
+ disclaimer in the documentation and/or other materials provided
+ with the distribution.
+
+ - Neither the name of Internet Society, IETF or IETF Trust, nor
+ the names of specific contributors, may be used to endorse or
+ promote products derived from this software without specific
+ prior written permission.
+
+ THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND
+ CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES,
+ INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF
+ MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
+ DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR
+ CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
+ SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT
+ NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
+ LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
+ HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
+ CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR
+ OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE,
+ EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
+*/
+#ifndef _SHA_H_
+#define _SHA_H_
+
+/*
+ * Description:
+ * This file implements the Secure Hash Algorithms
+ * as defined in the U.S. National Institute of Standards
+ * and Technology Federal Information Processing Standards
+ * Publication (FIPS PUB) 180-3 published in October 2008
+ * and formerly defined in its predecessors, FIPS PUB 180-1
+ * and FIP PUB 180-2.
+ *
+ * A combined document showing all algorithms is available at
+ * http://csrc.nist.gov/publications/fips/
+ * fips180-3/fips180-3_final.pdf
+ *
+ * The five hashes are defined in these sizes:
+ * SHA-1 20 byte / 160 bit
+ * SHA-224 28 byte / 224 bit
+ * SHA-256 32 byte / 256 bit
+ * SHA-384 48 byte / 384 bit
+ * SHA-512 64 byte / 512 bit
+ *
+
+
+
+
+Eastlake & Hansen Informational [Page 22]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+ * Compilation Note:
+ * These files may be compiled with two options:
+ * USE_32BIT_ONLY - use 32-bit arithmetic only, for systems
+ * without 64-bit integers
+ *
+ * USE_MODIFIED_MACROS - use alternate form of the SHA_Ch()
+ * and SHA_Maj() macros that are equivalent
+ * and potentially faster on many systems
+ *
+ */
+
+#include <stdint.h>
+/*
+ * If you do not have the ISO standard stdint.h header file, then you
+ * must typedef the following:
+ * name meaning
+ * uint64_t unsigned 64-bit integer
+ * uint32_t unsigned 32-bit integer
+ * uint8_t unsigned 8-bit integer (i.e., unsigned char)
+ * int_least16_t integer of >= 16 bits
+ *
+ * See stdint-example.h
+ */
+
+#ifndef _SHA_enum_
+#define _SHA_enum_
+/*
+ * All SHA functions return one of these values.
+ */
+enum {
+ shaSuccess = 0,
+ shaNull, /* Null pointer parameter */
+ shaInputTooLong, /* input data too long */
+ shaStateError, /* called Input after FinalBits or Result */
+ shaBadParam /* passed a bad parameter */
+};
+#endif /* _SHA_enum_ */
+
+/*
+ * These constants hold size information for each of the SHA
+ * hashing operations
+ */
+enum {
+ SHA1_Message_Block_Size = 64, SHA224_Message_Block_Size = 64,
+ SHA256_Message_Block_Size = 64, SHA384_Message_Block_Size = 128,
+ SHA512_Message_Block_Size = 128,
+ USHA_Max_Message_Block_Size = SHA512_Message_Block_Size,
+
+
+
+
+Eastlake & Hansen Informational [Page 23]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+ SHA1HashSize = 20, SHA224HashSize = 28, SHA256HashSize = 32,
+ SHA384HashSize = 48, SHA512HashSize = 64,
+ USHAMaxHashSize = SHA512HashSize,
+
+ SHA1HashSizeBits = 160, SHA224HashSizeBits = 224,
+ SHA256HashSizeBits = 256, SHA384HashSizeBits = 384,
+ SHA512HashSizeBits = 512, USHAMaxHashSizeBits = SHA512HashSizeBits
+};
+
+/*
+ * These constants are used in the USHA (Unified SHA) functions.
+ */
+typedef enum SHAversion {
+ SHA1, SHA224, SHA256, SHA384, SHA512
+} SHAversion;
+
+/*
+ * This structure will hold context information for the SHA-1
+ * hashing operation.
+ */
+typedef struct SHA1Context {
+ uint32_t Intermediate_Hash[SHA1HashSize/4]; /* Message Digest */
+
+ uint32_t Length_High; /* Message length in bits */
+ uint32_t Length_Low; /* Message length in bits */
+
+ int_least16_t Message_Block_Index; /* Message_Block array index */
+ /* 512-bit message blocks */
+ uint8_t Message_Block[SHA1_Message_Block_Size];
+
+ int Computed; /* Is the hash computed? */
+ int Corrupted; /* Cumulative corruption code */
+} SHA1Context;
+
+/*
+ * This structure will hold context information for the SHA-256
+ * hashing operation.
+ */
+typedef struct SHA256Context {
+ uint32_t Intermediate_Hash[SHA256HashSize/4]; /* Message Digest */
+
+ uint32_t Length_High; /* Message length in bits */
+ uint32_t Length_Low; /* Message length in bits */
+
+ int_least16_t Message_Block_Index; /* Message_Block array index */
+ /* 512-bit message blocks */
+ uint8_t Message_Block[SHA256_Message_Block_Size];
+
+
+
+
+Eastlake & Hansen Informational [Page 24]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+ int Computed; /* Is the hash computed? */
+ int Corrupted; /* Cumulative corruption code */
+} SHA256Context;
+
+/*
+ * This structure will hold context information for the SHA-512
+ * hashing operation.
+ */
+typedef struct SHA512Context {
+#ifdef USE_32BIT_ONLY
+ uint32_t Intermediate_Hash[SHA512HashSize/4]; /* Message Digest */
+ uint32_t Length[4]; /* Message length in bits */
+#else /* !USE_32BIT_ONLY */
+ uint64_t Intermediate_Hash[SHA512HashSize/8]; /* Message Digest */
+ uint64_t Length_High, Length_Low; /* Message length in bits */
+#endif /* USE_32BIT_ONLY */
+
+ int_least16_t Message_Block_Index; /* Message_Block array index */
+ /* 1024-bit message blocks */
+ uint8_t Message_Block[SHA512_Message_Block_Size];
+
+ int Computed; /* Is the hash computed?*/
+ int Corrupted; /* Cumulative corruption code */
+} SHA512Context;
+
+/*
+ * This structure will hold context information for the SHA-224
+ * hashing operation. It uses the SHA-256 structure for computation.
+ */
+typedef struct SHA256Context SHA224Context;
+
+/*
+ * This structure will hold context information for the SHA-384
+ * hashing operation. It uses the SHA-512 structure for computation.
+ */
+typedef struct SHA512Context SHA384Context;
+
+/*
+ * This structure holds context information for all SHA
+ * hashing operations.
+ */
+typedef struct USHAContext {
+ int whichSha; /* which SHA is being used */
+ union {
+ SHA1Context sha1Context;
+ SHA224Context sha224Context; SHA256Context sha256Context;
+ SHA384Context sha384Context; SHA512Context sha512Context;
+ } ctx;
+
+
+
+Eastlake & Hansen Informational [Page 25]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+} USHAContext;
+
+/*
+ * This structure will hold context information for the HMAC
+ * keyed-hashing operation.
+ */
+typedef struct HMACContext {
+ int whichSha; /* which SHA is being used */
+ int hashSize; /* hash size of SHA being used */
+ int blockSize; /* block size of SHA being used */
+ USHAContext shaContext; /* SHA context */
+ unsigned char k_opad[USHA_Max_Message_Block_Size];
+ /* outer padding - key XORd with opad */
+ int Computed; /* Is the MAC computed? */
+ int Corrupted; /* Cumulative corruption code */
+
+} HMACContext;
+
+/*
+ * This structure will hold context information for the HKDF
+ * extract-and-expand Key Derivation Functions.
+ */
+typedef struct HKDFContext {
+ int whichSha; /* which SHA is being used */
+ HMACContext hmacContext;
+ int hashSize; /* hash size of SHA being used */
+ unsigned char prk[USHAMaxHashSize];
+ /* pseudo-random key - output of hkdfInput */
+ int Computed; /* Is the key material computed? */
+ int Corrupted; /* Cumulative corruption code */
+} HKDFContext;
+
+/*
+ * Function Prototypes
+ */
+
+/* SHA-1 */
+extern int SHA1Reset(SHA1Context *);
+extern int SHA1Input(SHA1Context *, const uint8_t *bytes,
+ unsigned int bytecount);
+extern int SHA1FinalBits(SHA1Context *, uint8_t bits,
+ unsigned int bit_count);
+extern int SHA1Result(SHA1Context *,
+ uint8_t Message_Digest[SHA1HashSize]);
+
+
+
+
+
+
+
+Eastlake & Hansen Informational [Page 26]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+/* SHA-224 */
+extern int SHA224Reset(SHA224Context *);
+extern int SHA224Input(SHA224Context *, const uint8_t *bytes,
+ unsigned int bytecount);
+extern int SHA224FinalBits(SHA224Context *, uint8_t bits,
+ unsigned int bit_count);
+extern int SHA224Result(SHA224Context *,
+ uint8_t Message_Digest[SHA224HashSize]);
+
+/* SHA-256 */
+extern int SHA256Reset(SHA256Context *);
+extern int SHA256Input(SHA256Context *, const uint8_t *bytes,
+ unsigned int bytecount);
+extern int SHA256FinalBits(SHA256Context *, uint8_t bits,
+ unsigned int bit_count);
+extern int SHA256Result(SHA256Context *,
+ uint8_t Message_Digest[SHA256HashSize]);
+
+/* SHA-384 */
+extern int SHA384Reset(SHA384Context *);
+extern int SHA384Input(SHA384Context *, const uint8_t *bytes,
+ unsigned int bytecount);
+extern int SHA384FinalBits(SHA384Context *, uint8_t bits,
+ unsigned int bit_count);
+extern int SHA384Result(SHA384Context *,
+ uint8_t Message_Digest[SHA384HashSize]);
+
+/* SHA-512 */
+extern int SHA512Reset(SHA512Context *);
+extern int SHA512Input(SHA512Context *, const uint8_t *bytes,
+ unsigned int bytecount);
+extern int SHA512FinalBits(SHA512Context *, uint8_t bits,
+ unsigned int bit_count);
+extern int SHA512Result(SHA512Context *,
+ uint8_t Message_Digest[SHA512HashSize]);
+
+/* Unified SHA functions, chosen by whichSha */
+extern int USHAReset(USHAContext *context, SHAversion whichSha);
+extern int USHAInput(USHAContext *context,
+ const uint8_t *bytes, unsigned int bytecount);
+extern int USHAFinalBits(USHAContext *context,
+ uint8_t bits, unsigned int bit_count);
+extern int USHAResult(USHAContext *context,
+ uint8_t Message_Digest[USHAMaxHashSize]);
+extern int USHABlockSize(enum SHAversion whichSha);
+extern int USHAHashSize(enum SHAversion whichSha);
+extern int USHAHashSizeBits(enum SHAversion whichSha);
+extern const char *USHAHashName(enum SHAversion whichSha);
+
+
+
+Eastlake & Hansen Informational [Page 27]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+/*
+ * HMAC Keyed-Hashing for Message Authentication, RFC 2104,
+ * for all SHAs.
+ * This interface allows a fixed-length text input to be used.
+ */
+extern int hmac(SHAversion whichSha, /* which SHA algorithm to use */
+ const unsigned char *text, /* pointer to data stream */
+ int text_len, /* length of data stream */
+ const unsigned char *key, /* pointer to authentication key */
+ int key_len, /* length of authentication key */
+ uint8_t digest[USHAMaxHashSize]); /* caller digest to fill in */
+
+/*
+ * HMAC Keyed-Hashing for Message Authentication, RFC 2104,
+ * for all SHAs.
+ * This interface allows any length of text input to be used.
+ */
+extern int hmacReset(HMACContext *context, enum SHAversion whichSha,
+ const unsigned char *key, int key_len);
+extern int hmacInput(HMACContext *context, const unsigned char *text,
+ int text_len);
+extern int hmacFinalBits(HMACContext *context, uint8_t bits,
+ unsigned int bit_count);
+extern int hmacResult(HMACContext *context,
+ uint8_t digest[USHAMaxHashSize]);
+
+/*
+ * HKDF HMAC-based Extract-and-Expand Key Derivation Function,
+ * RFC 5869, for all SHAs.
+ */
+extern int hkdf(SHAversion whichSha, const unsigned char *salt,
+ int salt_len, const unsigned char *ikm, int ikm_len,
+ const unsigned char *info, int info_len,
+ uint8_t okm[ ], int okm_len);
+extern int hkdfExtract(SHAversion whichSha, const unsigned char *salt,
+ int salt_len, const unsigned char *ikm,
+ int ikm_len, uint8_t prk[USHAMaxHashSize]);
+extern int hkdfExpand(SHAversion whichSha, const uint8_t prk[ ],
+ int prk_len, const unsigned char *info,
+ int info_len, uint8_t okm[ ], int okm_len);
+
+/*
+ * HKDF HMAC-based Extract-and-Expand Key Derivation Function,
+ * RFC 5869, for all SHAs.
+ * This interface allows any length of text input to be used.
+ */
+extern int hkdfReset(HKDFContext *context, enum SHAversion whichSha,
+ const unsigned char *salt, int salt_len);
+
+
+
+Eastlake & Hansen Informational [Page 28]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+extern int hkdfInput(HKDFContext *context, const unsigned char *ikm,
+ int ikm_len);
+extern int hkdfFinalBits(HKDFContext *context, uint8_t ikm_bits,
+ unsigned int ikm_bit_count);
+extern int hkdfResult(HKDFContext *context,
+ uint8_t prk[USHAMaxHashSize],
+ const unsigned char *info, int info_len,
+ uint8_t okm[USHAMaxHashSize], int okm_len);
+#endif /* _SHA_H_ */
+
+8.1.2. stdint-example.h
+
+If your system does not have <stdint.h>, the following should be
+adequate as a substitute for compiling the other code in this document.
+
+/*********************** stdint-example.h **********************/
+/**** Use this file if your system does not have a stdint.h. ***/
+/***************** See RFC 6234 for details. *******************/
+#ifndef STDINT_H
+#define STDINT_H
+
+typedef unsigned long long uint64_t; /* unsigned 64-bit integer */
+typedef unsigned int uint32_t; /* unsigned 32-bit integer */
+typedef unsigned char uint8_t; /* unsigned 8-bit integer */
+ /* (i.e., unsigned char) */
+typedef int int_least32_t; /* integer of >= 32 bits */
+typedef short int_least16_t; /* integer of >= 16 bits */
+
+#endif /* STDINT_H */
+
+8.1.3. sha-private.h
+
+ The sha-private.h header file contains definitions that should only
+ be needed internally in the other code in this document. These
+ definitions should not be needed in application code calling the code
+ provided in this document.
+
+/************************ sha-private.h ************************/
+/***************** See RFC 6234 for details. *******************/
+#ifndef _SHA_PRIVATE__H
+#define _SHA_PRIVATE__H
+/*
+ * These definitions are defined in FIPS 180-3, section 4.1.
+ * Ch() and Maj() are defined identically in sections 4.1.1,
+ * 4.1.2, and 4.1.3.
+ *
+ * The definitions used in FIPS 180-3 are as follows:
+ */
+
+
+
+Eastlake & Hansen Informational [Page 29]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+#ifndef USE_MODIFIED_MACROS
+#define SHA_Ch(x,y,z) (((x) & (y)) ^ ((~(x)) & (z)))
+#define SHA_Maj(x,y,z) (((x) & (y)) ^ ((x) & (z)) ^ ((y) & (z)))
+#else /* USE_MODIFIED_MACROS */
+/*
+ * The following definitions are equivalent and potentially faster.
+ */
+
+#define SHA_Ch(x, y, z) (((x) & ((y) ^ (z))) ^ (z))
+#define SHA_Maj(x, y, z) (((x) & ((y) | (z))) | ((y) & (z)))
+
+#endif /* USE_MODIFIED_MACROS */
+
+#define SHA_Parity(x, y, z) ((x) ^ (y) ^ (z))
+
+#endif /* _SHA_PRIVATE__H */
+
+8.2. The SHA Code
+
+ This code is primarily intended as expository reference code and
+ could be optimized further. For example, the assignment rotations
+ through the variables a, b, ..., h could be treated as a cycle and
+ the loop unrolled, rather than doing the explicit copying.
+
+ Note that there are alternative representations of the Ch() and Maj()
+ functions controlled by an ifdef.
+
+8.2.1. sha1.c
+
+/**************************** sha1.c ***************************/
+/***************** See RFC 6234 for details. *******************/
+/* Copyright (c) 2011 IETF Trust and the persons identified as */
+/* authors of the code. All rights reserved. */
+/* See sha.h for terms of use and redistribution. */
+
+/*
+ * Description:
+ * This file implements the Secure Hash Algorithm SHA-1
+ * as defined in the U.S. National Institute of Standards
+ * and Technology Federal Information Processing Standards
+ * Publication (FIPS PUB) 180-3 published in October 2008
+ * and formerly defined in its predecessors, FIPS PUB 180-1
+ * and FIP PUB 180-2.
+ *
+ * A combined document showing all algorithms is available at
+ * http://csrc.nist.gov/publications/fips/
+ * fips180-3/fips180-3_final.pdf
+ *
+
+
+
+Eastlake & Hansen Informational [Page 30]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+ * The SHA-1 algorithm produces a 160-bit message digest for a
+ * given data stream that can serve as a means of providing a
+ * "fingerprint" for a message.
+ *
+ * Portability Issues:
+ * SHA-1 is defined in terms of 32-bit "words". This code
+ * uses <stdint.h> (included via "sha.h") to define 32- and
+ * 8-bit unsigned integer types. If your C compiler does
+ * not support 32-bit unsigned integers, this code is not
+ * appropriate.
+ *
+ * Caveats:
+ * SHA-1 is designed to work with messages less than 2^64 bits
+ * long. This implementation uses SHA1Input() to hash the bits
+ * that are a multiple of the size of an 8-bit octet, and then
+ * optionally uses SHA1FinalBits() to hash the final few bits of
+ * the input.
+ */
+
+#include "sha.h"
+#include "sha-private.h"
+
+/*
+ * Define the SHA1 circular left shift macro
+ */
+#define SHA1_ROTL(bits,word) \
+ (((word) << (bits)) | ((word) >> (32-(bits))))
+
+/*
+ * Add "length" to the length.
+ * Set Corrupted when overflow has occurred.
+ */
+static uint32_t addTemp;
+#define SHA1AddLength(context, length) \
+ (addTemp = (context)->Length_Low, \
+ (context)->Corrupted = \
+ (((context)->Length_Low += (length)) < addTemp) && \
+ (++(context)->Length_High == 0) ? shaInputTooLong \
+ : (context)->Corrupted )
+
+/* Local Function Prototypes */
+static void SHA1ProcessMessageBlock(SHA1Context *context);
+static void SHA1Finalize(SHA1Context *context, uint8_t Pad_Byte);
+static void SHA1PadMessage(SHA1Context *context, uint8_t Pad_Byte);
+
+
+
+
+
+
+
+Eastlake & Hansen Informational [Page 31]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+/*
+ * SHA1Reset
+ *
+ * Description:
+ * This function will initialize the SHA1Context in preparation
+ * for computing a new SHA1 message digest.
+ *
+ * Parameters:
+ * context: [in/out]
+ * The context to reset.
+ *
+ * Returns:
+ * sha Error Code.
+ *
+ */
+int SHA1Reset(SHA1Context *context)
+{
+ if (!context) return shaNull;
+
+ context->Length_High = context->Length_Low = 0;
+ context->Message_Block_Index = 0;
+
+ /* Initial Hash Values: FIPS 180-3 section 5.3.1 */
+ context->Intermediate_Hash[0] = 0x67452301;
+ context->Intermediate_Hash[1] = 0xEFCDAB89;
+ context->Intermediate_Hash[2] = 0x98BADCFE;
+ context->Intermediate_Hash[3] = 0x10325476;
+ context->Intermediate_Hash[4] = 0xC3D2E1F0;
+
+ context->Computed = 0;
+ context->Corrupted = shaSuccess;
+
+ return shaSuccess;
+}
+
+/*
+ * SHA1Input
+ *
+ * Description:
+ * This function accepts an array of octets as the next portion
+ * of the message.
+ *
+ * Parameters:
+ * context: [in/out]
+ * The SHA context to update.
+ * message_array[ ]: [in]
+ * An array of octets representing the next portion of
+ * the message.
+
+
+
+Eastlake & Hansen Informational [Page 32]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+ * length: [in]
+ * The length of the message in message_array.
+ *
+ * Returns:
+ * sha Error Code.
+ *
+ */
+int SHA1Input(SHA1Context *context,
+ const uint8_t *message_array, unsigned length)
+{
+ if (!context) return shaNull;
+ if (!length) return shaSuccess;
+ if (!message_array) return shaNull;
+ if (context->Computed) return context->Corrupted = shaStateError;
+ if (context->Corrupted) return context->Corrupted;
+
+ while (length--) {
+ context->Message_Block[context->Message_Block_Index++] =
+ *message_array;
+
+ if ((SHA1AddLength(context, 8) == shaSuccess) &&
+ (context->Message_Block_Index == SHA1_Message_Block_Size))
+ SHA1ProcessMessageBlock(context);
+
+ message_array++;
+ }
+
+ return context->Corrupted;
+}
+
+/*
+ * SHA1FinalBits
+ *
+ * Description:
+ * This function will add in any final bits of the message.
+ *
+ * Parameters:
+ * context: [in/out]
+ * The SHA context to update.
+ * message_bits: [in]
+ * The final bits of the message, in the upper portion of the
+ * byte. (Use 0b###00000 instead of 0b00000### to input the
+ * three bits ###.)
+ * length: [in]
+ * The number of bits in message_bits, between 1 and 7.
+ *
+ * Returns:
+ * sha Error Code.
+
+
+
+Eastlake & Hansen Informational [Page 33]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+ */
+int SHA1FinalBits(SHA1Context *context, uint8_t message_bits,
+ unsigned int length)
+{
+ static uint8_t masks[8] = {
+ /* 0 0b00000000 */ 0x00, /* 1 0b10000000 */ 0x80,
+ /* 2 0b11000000 */ 0xC0, /* 3 0b11100000 */ 0xE0,
+ /* 4 0b11110000 */ 0xF0, /* 5 0b11111000 */ 0xF8,
+ /* 6 0b11111100 */ 0xFC, /* 7 0b11111110 */ 0xFE
+ };
+
+ static uint8_t markbit[8] = {
+ /* 0 0b10000000 */ 0x80, /* 1 0b01000000 */ 0x40,
+ /* 2 0b00100000 */ 0x20, /* 3 0b00010000 */ 0x10,
+ /* 4 0b00001000 */ 0x08, /* 5 0b00000100 */ 0x04,
+ /* 6 0b00000010 */ 0x02, /* 7 0b00000001 */ 0x01
+ };
+
+ if (!context) return shaNull;
+ if (!length) return shaSuccess;
+ if (context->Corrupted) return context->Corrupted;
+ if (context->Computed) return context->Corrupted = shaStateError;
+ if (length >= 8) return context->Corrupted = shaBadParam;
+
+ SHA1AddLength(context, length);
+ SHA1Finalize(context,
+ (uint8_t) ((message_bits & masks[length]) | markbit[length]));
+
+ return context->Corrupted;
+}
+
+/*
+ * SHA1Result
+ *
+ * Description:
+ * This function will return the 160-bit message digest
+ * into the Message_Digest array provided by the caller.
+ * NOTE:
+ * The first octet of hash is stored in the element with index 0,
+ * the last octet of hash in the element with index 19.
+ *
+ * Parameters:
+ * context: [in/out]
+ * The context to use to calculate the SHA-1 hash.
+ * Message_Digest[ ]: [out]
+ * Where the digest is returned.
+ *
+
+
+
+
+Eastlake & Hansen Informational [Page 34]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+ * Returns:
+ * sha Error Code.
+ *
+ */
+int SHA1Result(SHA1Context *context,
+ uint8_t Message_Digest[SHA1HashSize])
+{
+ int i;
+
+ if (!context) return shaNull;
+ if (!Message_Digest) return shaNull;
+ if (context->Corrupted) return context->Corrupted;
+
+ if (!context->Computed)
+ SHA1Finalize(context, 0x80);
+
+ for (i = 0; i < SHA1HashSize; ++i)
+ Message_Digest[i] = (uint8_t) (context->Intermediate_Hash[i>>2]
+ >> (8 * ( 3 - ( i & 0x03 ) )));
+
+ return shaSuccess;
+}
+
+/*
+ * SHA1ProcessMessageBlock
+ *
+ * Description:
+ * This helper function will process the next 512 bits of the
+ * message stored in the Message_Block array.
+ *
+ * Parameters:
+ * context: [in/out]
+ * The SHA context to update.
+ *
+ * Returns:
+ * Nothing.
+ *
+ * Comments:
+ * Many of the variable names in this code, especially the
+ * single character names, were used because those were the
+ * names used in the Secure Hash Standard.
+ */
+static void SHA1ProcessMessageBlock(SHA1Context *context)
+{
+ /* Constants defined in FIPS 180-3, section 4.2.1 */
+ const uint32_t K[4] = {
+ 0x5A827999, 0x6ED9EBA1, 0x8F1BBCDC, 0xCA62C1D6
+ };
+
+
+
+Eastlake & Hansen Informational [Page 35]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+ int t; /* Loop counter */
+ uint32_t temp; /* Temporary word value */
+ uint32_t W[80]; /* Word sequence */
+ uint32_t A, B, C, D, E; /* Word buffers */
+
+ /*
+ * Initialize the first 16 words in the array W
+ */
+ for (t = 0; t < 16; t++) {
+ W[t] = ((uint32_t)context->Message_Block[t * 4]) << 24;
+ W[t] |= ((uint32_t)context->Message_Block[t * 4 + 1]) << 16;
+ W[t] |= ((uint32_t)context->Message_Block[t * 4 + 2]) << 8;
+ W[t] |= ((uint32_t)context->Message_Block[t * 4 + 3]);
+ }
+
+ for (t = 16; t < 80; t++)
+ W[t] = SHA1_ROTL(1, W[t-3] ^ W[t-8] ^ W[t-14] ^ W[t-16]);
+
+ A = context->Intermediate_Hash[0];
+ B = context->Intermediate_Hash[1];
+ C = context->Intermediate_Hash[2];
+ D = context->Intermediate_Hash[3];
+ E = context->Intermediate_Hash[4];
+
+ for (t = 0; t < 20; t++) {
+ temp = SHA1_ROTL(5,A) + SHA_Ch(B, C, D) + E + W[t] + K[0];
+ E = D;
+ D = C;
+ C = SHA1_ROTL(30,B);
+ B = A;
+ A = temp;
+ }
+
+ for (t = 20; t < 40; t++) {
+ temp = SHA1_ROTL(5,A) + SHA_Parity(B, C, D) + E + W[t] + K[1];
+ E = D;
+ D = C;
+ C = SHA1_ROTL(30,B);
+ B = A;
+ A = temp;
+ }
+
+ for (t = 40; t < 60; t++) {
+ temp = SHA1_ROTL(5,A) + SHA_Maj(B, C, D) + E + W[t] + K[2];
+ E = D;
+ D = C;
+ C = SHA1_ROTL(30,B);
+ B = A;
+
+
+
+Eastlake & Hansen Informational [Page 36]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+ A = temp;
+ }
+
+ for (t = 60; t < 80; t++) {
+ temp = SHA1_ROTL(5,A) + SHA_Parity(B, C, D) + E + W[t] + K[3];
+ E = D;
+ D = C;
+ C = SHA1_ROTL(30,B);
+ B = A;
+ A = temp;
+ }
+
+ context->Intermediate_Hash[0] += A;
+ context->Intermediate_Hash[1] += B;
+ context->Intermediate_Hash[2] += C;
+ context->Intermediate_Hash[3] += D;
+ context->Intermediate_Hash[4] += E;
+ context->Message_Block_Index = 0;
+}
+
+/*
+ * SHA1Finalize
+ *
+ * Description:
+ * This helper function finishes off the digest calculations.
+ *
+ * Parameters:
+ * context: [in/out]
+ * The SHA context to update.
+ * Pad_Byte: [in]
+ * The last byte to add to the message block before the 0-padding
+ * and length. This will contain the last bits of the message
+ * followed by another single bit. If the message was an
+ * exact multiple of 8-bits long, Pad_Byte will be 0x80.
+ *
+ * Returns:
+ * sha Error Code.
+ *
+ */
+static void SHA1Finalize(SHA1Context *context, uint8_t Pad_Byte)
+{
+ int i;
+ SHA1PadMessage(context, Pad_Byte);
+ /* message may be sensitive, clear it out */
+ for (i = 0; i < SHA1_Message_Block_Size; ++i)
+ context->Message_Block[i] = 0;
+ context->Length_High = 0; /* and clear length */
+ context->Length_Low = 0;
+
+
+
+Eastlake & Hansen Informational [Page 37]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+ context->Computed = 1;
+}
+
+/*
+ * SHA1PadMessage
+ *
+ * Description:
+ * According to the standard, the message must be padded to the next
+ * even multiple of 512 bits. The first padding bit must be a '1'.
+ * The last 64 bits represent the length of the original message.
+ * All bits in between should be 0. This helper function will pad
+ * the message according to those rules by filling the Message_Block
+ * array accordingly. When it returns, it can be assumed that the
+ * message digest has been computed.
+ *
+ * Parameters:
+ * context: [in/out]
+ * The context to pad.
+ * Pad_Byte: [in]
+ * The last byte to add to the message block before the 0-padding
+ * and length. This will contain the last bits of the message
+ * followed by another single bit. If the message was an
+ * exact multiple of 8-bits long, Pad_Byte will be 0x80.
+ *
+ * Returns:
+ * Nothing.
+ */
+static void SHA1PadMessage(SHA1Context *context, uint8_t Pad_Byte)
+{
+ /*
+ * Check to see if the current message block is too small to hold
+ * the initial padding bits and length. If so, we will pad the
+ * block, process it, and then continue padding into a second
+ * block.
+ */
+ if (context->Message_Block_Index >= (SHA1_Message_Block_Size - 8)) {
+ context->Message_Block[context->Message_Block_Index++] = Pad_Byte;
+ while (context->Message_Block_Index < SHA1_Message_Block_Size)
+ context->Message_Block[context->Message_Block_Index++] = 0;
+
+ SHA1ProcessMessageBlock(context);
+ } else
+ context->Message_Block[context->Message_Block_Index++] = Pad_Byte;
+
+ while (context->Message_Block_Index < (SHA1_Message_Block_Size - 8))
+ context->Message_Block[context->Message_Block_Index++] = 0;
+
+
+
+
+
+Eastlake & Hansen Informational [Page 38]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+ /*
+ * Store the message length as the last 8 octets
+ */
+ context->Message_Block[56] = (uint8_t) (context->Length_High >> 24);
+ context->Message_Block[57] = (uint8_t) (context->Length_High >> 16);
+ context->Message_Block[58] = (uint8_t) (context->Length_High >> 8);
+ context->Message_Block[59] = (uint8_t) (context->Length_High);
+ context->Message_Block[60] = (uint8_t) (context->Length_Low >> 24);
+ context->Message_Block[61] = (uint8_t) (context->Length_Low >> 16);
+ context->Message_Block[62] = (uint8_t) (context->Length_Low >> 8);
+ context->Message_Block[63] = (uint8_t) (context->Length_Low);
+
+ SHA1ProcessMessageBlock(context);
+}
+
+8.2.2. sha224-256.c
+
+/************************* sha224-256.c ************************/
+/***************** See RFC 6234 for details. *******************/
+/* Copyright (c) 2011 IETF Trust and the persons identified as */
+/* authors of the code. All rights reserved. */
+/* See sha.h for terms of use and redistribution. */
+
+/*
+ * Description:
+ * This file implements the Secure Hash Algorithms SHA-224 and
+ * SHA-256 as defined in the U.S. National Institute of Standards
+ * and Technology Federal Information Processing Standards
+ * Publication (FIPS PUB) 180-3 published in October 2008
+ * and formerly defined in its predecessors, FIPS PUB 180-1
+ * and FIP PUB 180-2.
+ *
+ * A combined document showing all algorithms is available at
+ * http://csrc.nist.gov/publications/fips/
+ * fips180-3/fips180-3_final.pdf
+ *
+ * The SHA-224 and SHA-256 algorithms produce 224-bit and 256-bit
+ * message digests for a given data stream. It should take about
+ * 2**n steps to find a message with the same digest as a given
+ * message and 2**(n/2) to find any two messages with the same
+ * digest, when n is the digest size in bits. Therefore, this
+ * algorithm can serve as a means of providing a
+ * "fingerprint" for a message.
+ *
+ * Portability Issues:
+ * SHA-224 and SHA-256 are defined in terms of 32-bit "words".
+ * This code uses <stdint.h> (included via "sha.h") to define 32-
+ * and 8-bit unsigned integer types. If your C compiler does not
+
+
+
+Eastlake & Hansen Informational [Page 39]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+ * support 32-bit unsigned integers, this code is not
+ * appropriate.
+ *
+ * Caveats:
+ * SHA-224 and SHA-256 are designed to work with messages less
+ * than 2^64 bits long. This implementation uses SHA224/256Input()
+ * to hash the bits that are a multiple of the size of an 8-bit
+ * octet, and then optionally uses SHA224/256FinalBits()
+ * to hash the final few bits of the input.
+ */
+
+#include "sha.h"
+#include "sha-private.h"
+
+/* Define the SHA shift, rotate left, and rotate right macros */
+#define SHA256_SHR(bits,word) ((word) >> (bits))
+#define SHA256_ROTL(bits,word) \
+ (((word) << (bits)) | ((word) >> (32-(bits))))
+#define SHA256_ROTR(bits,word) \
+ (((word) >> (bits)) | ((word) << (32-(bits))))
+
+/* Define the SHA SIGMA and sigma macros */
+#define SHA256_SIGMA0(word) \
+ (SHA256_ROTR( 2,word) ^ SHA256_ROTR(13,word) ^ SHA256_ROTR(22,word))
+#define SHA256_SIGMA1(word) \
+ (SHA256_ROTR( 6,word) ^ SHA256_ROTR(11,word) ^ SHA256_ROTR(25,word))
+#define SHA256_sigma0(word) \
+ (SHA256_ROTR( 7,word) ^ SHA256_ROTR(18,word) ^ SHA256_SHR( 3,word))
+#define SHA256_sigma1(word) \
+ (SHA256_ROTR(17,word) ^ SHA256_ROTR(19,word) ^ SHA256_SHR(10,word))
+
+/*
+ * Add "length" to the length.
+ * Set Corrupted when overflow has occurred.
+ */
+static uint32_t addTemp;
+#define SHA224_256AddLength(context, length) \
+ (addTemp = (context)->Length_Low, (context)->Corrupted = \
+ (((context)->Length_Low += (length)) < addTemp) && \
+ (++(context)->Length_High == 0) ? shaInputTooLong : \
+ (context)->Corrupted )
+
+/* Local Function Prototypes */
+static int SHA224_256Reset(SHA256Context *context, uint32_t *H0);
+static void SHA224_256ProcessMessageBlock(SHA256Context *context);
+static void SHA224_256Finalize(SHA256Context *context,
+ uint8_t Pad_Byte);
+static void SHA224_256PadMessage(SHA256Context *context,
+
+
+
+Eastlake & Hansen Informational [Page 40]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+ uint8_t Pad_Byte);
+static int SHA224_256ResultN(SHA256Context *context,
+ uint8_t Message_Digest[ ], int HashSize);
+
+/* Initial Hash Values: FIPS 180-3 section 5.3.2 */
+static uint32_t SHA224_H0[SHA256HashSize/4] = {
+ 0xC1059ED8, 0x367CD507, 0x3070DD17, 0xF70E5939,
+ 0xFFC00B31, 0x68581511, 0x64F98FA7, 0xBEFA4FA4
+};
+
+/* Initial Hash Values: FIPS 180-3 section 5.3.3 */
+static uint32_t SHA256_H0[SHA256HashSize/4] = {
+ 0x6A09E667, 0xBB67AE85, 0x3C6EF372, 0xA54FF53A,
+ 0x510E527F, 0x9B05688C, 0x1F83D9AB, 0x5BE0CD19
+};
+
+/*
+ * SHA224Reset
+ *
+ * Description:
+ * This function will initialize the SHA224Context in preparation
+ * for computing a new SHA224 message digest.
+ *
+ * Parameters:
+ * context: [in/out]
+ * The context to reset.
+ *
+ * Returns:
+ * sha Error Code.
+ */
+int SHA224Reset(SHA224Context *context)
+{
+ return SHA224_256Reset(context, SHA224_H0);
+}
+
+/*
+ * SHA224Input
+ *
+ * Description:
+ * This function accepts an array of octets as the next portion
+ * of the message.
+ *
+ * Parameters:
+ * context: [in/out]
+ * The SHA context to update.
+ * message_array[ ]: [in]
+ * An array of octets representing the next portion of
+ * the message.
+
+
+
+Eastlake & Hansen Informational [Page 41]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+ * length: [in]
+ * The length of the message in message_array.
+ *
+ * Returns:
+ * sha Error Code.
+ *
+ */
+int SHA224Input(SHA224Context *context, const uint8_t *message_array,
+ unsigned int length)
+{
+ return SHA256Input(context, message_array, length);
+}
+
+/*
+ * SHA224FinalBits
+ *
+ * Description:
+ * This function will add in any final bits of the message.
+ *
+ * Parameters:
+ * context: [in/out]
+ * The SHA context to update.
+ * message_bits: [in]
+ * The final bits of the message, in the upper portion of the
+ * byte. (Use 0b###00000 instead of 0b00000### to input the
+ * three bits ###.)
+ * length: [in]
+ * The number of bits in message_bits, between 1 and 7.
+ *
+ * Returns:
+ * sha Error Code.
+ */
+int SHA224FinalBits(SHA224Context *context,
+ uint8_t message_bits, unsigned int length)
+{
+ return SHA256FinalBits(context, message_bits, length);
+}
+
+/*
+ * SHA224Result
+ *
+ * Description:
+ * This function will return the 224-bit message digest
+ * into the Message_Digest array provided by the caller.
+ * NOTE:
+ * The first octet of hash is stored in the element with index 0,
+ * the last octet of hash in the element with index 27.
+ *
+
+
+
+Eastlake & Hansen Informational [Page 42]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+ * Parameters:
+ * context: [in/out]
+ * The context to use to calculate the SHA hash.
+ * Message_Digest[ ]: [out]
+ * Where the digest is returned.
+ *
+ * Returns:
+ * sha Error Code.
+ */
+int SHA224Result(SHA224Context *context,
+ uint8_t Message_Digest[SHA224HashSize])
+{
+ return SHA224_256ResultN(context, Message_Digest, SHA224HashSize);
+}
+
+/*
+ * SHA256Reset
+ *
+ * Description:
+ * This function will initialize the SHA256Context in preparation
+ * for computing a new SHA256 message digest.
+ *
+ * Parameters:
+ * context: [in/out]
+ * The context to reset.
+ *
+ * Returns:
+ * sha Error Code.
+ */
+int SHA256Reset(SHA256Context *context)
+{
+ return SHA224_256Reset(context, SHA256_H0);
+}
+
+/*
+ * SHA256Input
+ *
+ * Description:
+ * This function accepts an array of octets as the next portion
+ * of the message.
+ *
+ * Parameters:
+ * context: [in/out]
+ * The SHA context to update.
+ * message_array[ ]: [in]
+ * An array of octets representing the next portion of
+ * the message.
+
+
+
+
+Eastlake & Hansen Informational [Page 43]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+ * length: [in]
+ * The length of the message in message_array.
+ *
+ * Returns:
+ * sha Error Code.
+ */
+int SHA256Input(SHA256Context *context, const uint8_t *message_array,
+ unsigned int length)
+{
+ if (!context) return shaNull;
+ if (!length) return shaSuccess;
+ if (!message_array) return shaNull;
+ if (context->Computed) return context->Corrupted = shaStateError;
+ if (context->Corrupted) return context->Corrupted;
+
+ while (length--) {
+ context->Message_Block[context->Message_Block_Index++] =
+ *message_array;
+
+ if ((SHA224_256AddLength(context, 8) == shaSuccess) &&
+ (context->Message_Block_Index == SHA256_Message_Block_Size))
+ SHA224_256ProcessMessageBlock(context);
+
+ message_array++;
+ }
+
+ return context->Corrupted;
+
+}
+
+/*
+ * SHA256FinalBits
+ *
+ * Description:
+ * This function will add in any final bits of the message.
+ *
+ * Parameters:
+ * context: [in/out]
+ * The SHA context to update.
+ * message_bits: [in]
+ * The final bits of the message, in the upper portion of the
+ * byte. (Use 0b###00000 instead of 0b00000### to input the
+ * three bits ###.)
+ * length: [in]
+ * The number of bits in message_bits, between 1 and 7.
+ *
+ * Returns:
+ * sha Error Code.
+
+
+
+Eastlake & Hansen Informational [Page 44]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+ */
+int SHA256FinalBits(SHA256Context *context,
+ uint8_t message_bits, unsigned int length)
+{
+ static uint8_t masks[8] = {
+ /* 0 0b00000000 */ 0x00, /* 1 0b10000000 */ 0x80,
+ /* 2 0b11000000 */ 0xC0, /* 3 0b11100000 */ 0xE0,
+ /* 4 0b11110000 */ 0xF0, /* 5 0b11111000 */ 0xF8,
+ /* 6 0b11111100 */ 0xFC, /* 7 0b11111110 */ 0xFE
+ };
+ static uint8_t markbit[8] = {
+ /* 0 0b10000000 */ 0x80, /* 1 0b01000000 */ 0x40,
+ /* 2 0b00100000 */ 0x20, /* 3 0b00010000 */ 0x10,
+ /* 4 0b00001000 */ 0x08, /* 5 0b00000100 */ 0x04,
+ /* 6 0b00000010 */ 0x02, /* 7 0b00000001 */ 0x01
+ };
+
+ if (!context) return shaNull;
+ if (!length) return shaSuccess;
+ if (context->Corrupted) return context->Corrupted;
+ if (context->Computed) return context->Corrupted = shaStateError;
+ if (length >= 8) return context->Corrupted = shaBadParam;
+
+ SHA224_256AddLength(context, length);
+ SHA224_256Finalize(context, (uint8_t)
+ ((message_bits & masks[length]) | markbit[length]));
+
+ return context->Corrupted;
+}
+
+/*
+ * SHA256Result
+ *
+ * Description:
+ * This function will return the 256-bit message digest
+ * into the Message_Digest array provided by the caller.
+ * NOTE:
+ * The first octet of hash is stored in the element with index 0,
+ * the last octet of hash in the element with index 31.
+ *
+ * Parameters:
+ * context: [in/out]
+ * The context to use to calculate the SHA hash.
+ * Message_Digest[ ]: [out]
+ * Where the digest is returned.
+ *
+ * Returns:
+ * sha Error Code.
+
+
+
+Eastlake & Hansen Informational [Page 45]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+ */
+int SHA256Result(SHA256Context *context,
+ uint8_t Message_Digest[SHA256HashSize])
+{
+ return SHA224_256ResultN(context, Message_Digest, SHA256HashSize);
+}
+
+/*
+ * SHA224_256Reset
+ *
+ * Description:
+ * This helper function will initialize the SHA256Context in
+ * preparation for computing a new SHA-224 or SHA-256 message digest.
+ *
+ * Parameters:
+ * context: [in/out]
+ * The context to reset.
+ * H0[ ]: [in]
+ * The initial hash value array to use.
+ *
+ * Returns:
+ * sha Error Code.
+ */
+static int SHA224_256Reset(SHA256Context *context, uint32_t *H0)
+{
+ if (!context) return shaNull;
+
+ context->Length_High = context->Length_Low = 0;
+ context->Message_Block_Index = 0;
+
+ context->Intermediate_Hash[0] = H0[0];
+ context->Intermediate_Hash[1] = H0[1];
+ context->Intermediate_Hash[2] = H0[2];
+ context->Intermediate_Hash[3] = H0[3];
+ context->Intermediate_Hash[4] = H0[4];
+ context->Intermediate_Hash[5] = H0[5];
+ context->Intermediate_Hash[6] = H0[6];
+ context->Intermediate_Hash[7] = H0[7];
+
+ context->Computed = 0;
+ context->Corrupted = shaSuccess;
+
+ return shaSuccess;
+}
+
+/*
+ * SHA224_256ProcessMessageBlock
+ *
+
+
+
+Eastlake & Hansen Informational [Page 46]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+ * Description:
+ * This helper function will process the next 512 bits of the
+ * message stored in the Message_Block array.
+ *
+ * Parameters:
+ * context: [in/out]
+ * The SHA context to update.
+ *
+ * Returns:
+ * Nothing.
+ *
+ * Comments:
+ * Many of the variable names in this code, especially the
+ * single character names, were used because those were the
+ * names used in the Secure Hash Standard.
+ */
+static void SHA224_256ProcessMessageBlock(SHA256Context *context)
+{
+ /* Constants defined in FIPS 180-3, section 4.2.2 */
+ static const uint32_t K[64] = {
+ 0x428a2f98, 0x71374491, 0xb5c0fbcf, 0xe9b5dba5, 0x3956c25b,
+ 0x59f111f1, 0x923f82a4, 0xab1c5ed5, 0xd807aa98, 0x12835b01,
+ 0x243185be, 0x550c7dc3, 0x72be5d74, 0x80deb1fe, 0x9bdc06a7,
+ 0xc19bf174, 0xe49b69c1, 0xefbe4786, 0x0fc19dc6, 0x240ca1cc,
+ 0x2de92c6f, 0x4a7484aa, 0x5cb0a9dc, 0x76f988da, 0x983e5152,
+ 0xa831c66d, 0xb00327c8, 0xbf597fc7, 0xc6e00bf3, 0xd5a79147,
+ 0x06ca6351, 0x14292967, 0x27b70a85, 0x2e1b2138, 0x4d2c6dfc,
+ 0x53380d13, 0x650a7354, 0x766a0abb, 0x81c2c92e, 0x92722c85,
+ 0xa2bfe8a1, 0xa81a664b, 0xc24b8b70, 0xc76c51a3, 0xd192e819,
+ 0xd6990624, 0xf40e3585, 0x106aa070, 0x19a4c116, 0x1e376c08,
+ 0x2748774c, 0x34b0bcb5, 0x391c0cb3, 0x4ed8aa4a, 0x5b9cca4f,
+ 0x682e6ff3, 0x748f82ee, 0x78a5636f, 0x84c87814, 0x8cc70208,
+ 0x90befffa, 0xa4506ceb, 0xbef9a3f7, 0xc67178f2
+ };
+ int t, t4; /* Loop counter */
+ uint32_t temp1, temp2; /* Temporary word value */
+ uint32_t W[64]; /* Word sequence */
+ uint32_t A, B, C, D, E, F, G, H; /* Word buffers */
+
+ /*
+ * Initialize the first 16 words in the array W
+ */
+ for (t = t4 = 0; t < 16; t++, t4 += 4)
+ W[t] = (((uint32_t)context->Message_Block[t4]) << 24) |
+ (((uint32_t)context->Message_Block[t4 + 1]) << 16) |
+ (((uint32_t)context->Message_Block[t4 + 2]) << 8) |
+ (((uint32_t)context->Message_Block[t4 + 3]));
+
+
+
+
+Eastlake & Hansen Informational [Page 47]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+ for (t = 16; t < 64; t++)
+ W[t] = SHA256_sigma1(W[t-2]) + W[t-7] +
+ SHA256_sigma0(W[t-15]) + W[t-16];
+
+ A = context->Intermediate_Hash[0];
+ B = context->Intermediate_Hash[1];
+ C = context->Intermediate_Hash[2];
+ D = context->Intermediate_Hash[3];
+ E = context->Intermediate_Hash[4];
+ F = context->Intermediate_Hash[5];
+ G = context->Intermediate_Hash[6];
+ H = context->Intermediate_Hash[7];
+
+ for (t = 0; t < 64; t++) {
+ temp1 = H + SHA256_SIGMA1(E) + SHA_Ch(E,F,G) + K[t] + W[t];
+ temp2 = SHA256_SIGMA0(A) + SHA_Maj(A,B,C);
+ H = G;
+ G = F;
+ F = E;
+ E = D + temp1;
+ D = C;
+ C = B;
+ B = A;
+ A = temp1 + temp2;
+ }
+
+ context->Intermediate_Hash[0] += A;
+ context->Intermediate_Hash[1] += B;
+ context->Intermediate_Hash[2] += C;
+ context->Intermediate_Hash[3] += D;
+ context->Intermediate_Hash[4] += E;
+ context->Intermediate_Hash[5] += F;
+ context->Intermediate_Hash[6] += G;
+ context->Intermediate_Hash[7] += H;
+
+ context->Message_Block_Index = 0;
+}
+
+/*
+ * SHA224_256Finalize
+ *
+ * Description:
+ * This helper function finishes off the digest calculations.
+ *
+ * Parameters:
+ * context: [in/out]
+ * The SHA context to update.
+ * Pad_Byte: [in]
+
+
+
+Eastlake & Hansen Informational [Page 48]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+ * The last byte to add to the message block before the 0-padding
+ * and length. This will contain the last bits of the message
+ * followed by another single bit. If the message was an
+ * exact multiple of 8-bits long, Pad_Byte will be 0x80.
+ *
+ * Returns:
+ * sha Error Code.
+ */
+static void SHA224_256Finalize(SHA256Context *context,
+ uint8_t Pad_Byte)
+{
+ int i;
+ SHA224_256PadMessage(context, Pad_Byte);
+ /* message may be sensitive, so clear it out */
+ for (i = 0; i < SHA256_Message_Block_Size; ++i)
+ context->Message_Block[i] = 0;
+ context->Length_High = 0; /* and clear length */
+ context->Length_Low = 0;
+ context->Computed = 1;
+}
+
+/*
+ * SHA224_256PadMessage
+ *
+ * Description:
+ * According to the standard, the message must be padded to the next
+ * even multiple of 512 bits. The first padding bit must be a '1'.
+ * The last 64 bits represent the length of the original message.
+ * All bits in between should be 0. This helper function will pad
+ * the message according to those rules by filling the
+ * Message_Block array accordingly. When it returns, it can be
+ * assumed that the message digest has been computed.
+ *
+ * Parameters:
+ * context: [in/out]
+ * The context to pad.
+ * Pad_Byte: [in]
+ * The last byte to add to the message block before the 0-padding
+ * and length. This will contain the last bits of the message
+ * followed by another single bit. If the message was an
+ * exact multiple of 8-bits long, Pad_Byte will be 0x80.
+ *
+ * Returns:
+ * Nothing.
+ */
+static void SHA224_256PadMessage(SHA256Context *context,
+ uint8_t Pad_Byte)
+{
+
+
+
+Eastlake & Hansen Informational [Page 49]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+ /*
+ * Check to see if the current message block is too small to hold
+ * the initial padding bits and length. If so, we will pad the
+ * block, process it, and then continue padding into a second
+ * block.
+ */
+ if (context->Message_Block_Index >= (SHA256_Message_Block_Size-8)) {
+ context->Message_Block[context->Message_Block_Index++] = Pad_Byte;
+ while (context->Message_Block_Index < SHA256_Message_Block_Size)
+ context->Message_Block[context->Message_Block_Index++] = 0;
+ SHA224_256ProcessMessageBlock(context);
+ } else
+ context->Message_Block[context->Message_Block_Index++] = Pad_Byte;
+
+ while (context->Message_Block_Index < (SHA256_Message_Block_Size-8))
+ context->Message_Block[context->Message_Block_Index++] = 0;
+
+ /*
+ * Store the message length as the last 8 octets
+ */
+ context->Message_Block[56] = (uint8_t)(context->Length_High >> 24);
+ context->Message_Block[57] = (uint8_t)(context->Length_High >> 16);
+ context->Message_Block[58] = (uint8_t)(context->Length_High >> 8);
+ context->Message_Block[59] = (uint8_t)(context->Length_High);
+ context->Message_Block[60] = (uint8_t)(context->Length_Low >> 24);
+ context->Message_Block[61] = (uint8_t)(context->Length_Low >> 16);
+ context->Message_Block[62] = (uint8_t)(context->Length_Low >> 8);
+ context->Message_Block[63] = (uint8_t)(context->Length_Low);
+
+ SHA224_256ProcessMessageBlock(context);
+}
+
+/*
+ * SHA224_256ResultN
+ *
+ * Description:
+ * This helper function will return the 224-bit or 256-bit message
+ * digest into the Message_Digest array provided by the caller.
+ * NOTE:
+ * The first octet of hash is stored in the element with index 0,
+ * the last octet of hash in the element with index 27/31.
+ *
+ * Parameters:
+ * context: [in/out]
+ * The context to use to calculate the SHA hash.
+ * Message_Digest[ ]: [out]
+ * Where the digest is returned.
+ * HashSize: [in]
+
+
+
+Eastlake & Hansen Informational [Page 50]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+ * The size of the hash, either 28 or 32.
+ *
+ * Returns:
+ * sha Error Code.
+ */
+static int SHA224_256ResultN(SHA256Context *context,
+ uint8_t Message_Digest[ ], int HashSize)
+{
+ int i;
+
+ if (!context) return shaNull;
+ if (!Message_Digest) return shaNull;
+ if (context->Corrupted) return context->Corrupted;
+
+ if (!context->Computed)
+ SHA224_256Finalize(context, 0x80);
+
+ for (i = 0; i < HashSize; ++i)
+ Message_Digest[i] = (uint8_t)
+ (context->Intermediate_Hash[i>>2] >> 8 * ( 3 - ( i & 0x03 ) ));
+
+ return shaSuccess;
+}
+
+8.2.3. sha384-512.c
+
+/************************* sha384-512.c ************************/
+/***************** See RFC 6234 for details. *******************/
+/* Copyright (c) 2011 IETF Trust and the persons identified as */
+/* authors of the code. All rights reserved. */
+/* See sha.h for terms of use and redistribution. */
+
+/*
+ * Description:
+ * This file implements the Secure Hash Algorithms SHA-384 and
+ * SHA-512 as defined in the U.S. National Institute of Standards
+ * and Technology Federal Information Processing Standards
+ * Publication (FIPS PUB) 180-3 published in October 2008
+ * and formerly defined in its predecessors, FIPS PUB 180-1
+ * and FIP PUB 180-2.
+ *
+ * A combined document showing all algorithms is available at
+ * http://csrc.nist.gov/publications/fips/
+ * fips180-3/fips180-3_final.pdf
+ *
+ * The SHA-384 and SHA-512 algorithms produce 384-bit and 512-bit
+ * message digests for a given data stream. It should take about
+ * 2**n steps to find a message with the same digest as a given
+
+
+
+Eastlake & Hansen Informational [Page 51]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+ * message and 2**(n/2) to find any two messages with the same
+ * digest, when n is the digest size in bits. Therefore, this
+ * algorithm can serve as a means of providing a
+ * "fingerprint" for a message.
+ *
+ * Portability Issues:
+ * SHA-384 and SHA-512 are defined in terms of 64-bit "words",
+ * but if USE_32BIT_ONLY is #defined, this code is implemented in
+ * terms of 32-bit "words". This code uses <stdint.h> (included
+ * via "sha.h") to define the 64-, 32- and 8-bit unsigned integer
+ * types. If your C compiler does not support 64-bit unsigned
+ * integers and you do not #define USE_32BIT_ONLY, this code is
+ * not appropriate.
+ *
+ * Caveats:
+ * SHA-384 and SHA-512 are designed to work with messages less
+ * than 2^128 bits long. This implementation uses SHA384/512Input()
+ * to hash the bits that are a multiple of the size of an 8-bit
+ * octet, and then optionally uses SHA384/256FinalBits()
+ * to hash the final few bits of the input.
+ *
+ */
+
+#include "sha.h"
+
+#ifdef USE_32BIT_ONLY
+/*
+ * Define 64-bit arithmetic in terms of 32-bit arithmetic.
+ * Each 64-bit number is represented in a 2-word array.
+ * All macros are defined such that the result is the last parameter.
+ */
+
+/*
+ * Define shift, rotate left, and rotate right functions
+ */
+#define SHA512_SHR(bits, word, ret) ( \
+ /* (((uint64_t)((word))) >> (bits)) */ \
+ (ret)[0] = (((bits) < 32) && ((bits) >= 0)) ? \
+ ((word)[0] >> (bits)) : 0, \
+ (ret)[1] = ((bits) > 32) ? ((word)[0] >> ((bits) - 32)) : \
+ ((bits) == 32) ? (word)[0] : \
+ ((bits) >= 0) ? \
+ (((word)[0] << (32 - (bits))) | \
+ ((word)[1] >> (bits))) : 0 )
+
+#define SHA512_SHL(bits, word, ret) ( \
+ /* (((uint64_t)(word)) << (bits)) */ \
+ (ret)[0] = ((bits) > 32) ? ((word)[1] << ((bits) - 32)) : \
+
+
+
+Eastlake & Hansen Informational [Page 52]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+ ((bits) == 32) ? (word)[1] : \
+ ((bits) >= 0) ? \
+ (((word)[0] << (bits)) | \
+ ((word)[1] >> (32 - (bits)))) : \
+ 0, \
+ (ret)[1] = (((bits) < 32) && ((bits) >= 0)) ? \
+ ((word)[1] << (bits)) : 0 )
+
+/*
+ * Define 64-bit OR
+ */
+#define SHA512_OR(word1, word2, ret) ( \
+ (ret)[0] = (word1)[0] | (word2)[0], \
+ (ret)[1] = (word1)[1] | (word2)[1] )
+
+/*
+ * Define 64-bit XOR
+ */
+#define SHA512_XOR(word1, word2, ret) ( \
+ (ret)[0] = (word1)[0] ^ (word2)[0], \
+ (ret)[1] = (word1)[1] ^ (word2)[1] )
+
+/*
+ * Define 64-bit AND
+ */
+#define SHA512_AND(word1, word2, ret) ( \
+ (ret)[0] = (word1)[0] & (word2)[0], \
+ (ret)[1] = (word1)[1] & (word2)[1] )
+
+/*
+ * Define 64-bit TILDA
+ */
+#define SHA512_TILDA(word, ret) \
+ ( (ret)[0] = ~(word)[0], (ret)[1] = ~(word)[1] )
+
+/*
+ * Define 64-bit ADD
+ */
+#define SHA512_ADD(word1, word2, ret) ( \
+ (ret)[1] = (word1)[1], (ret)[1] += (word2)[1], \
+ (ret)[0] = (word1)[0] + (word2)[0] + ((ret)[1] < (word1)[1]) )
+
+/*
+ * Add the 4word value in word2 to word1.
+ */
+static uint32_t ADDTO4_temp, ADDTO4_temp2;
+#define SHA512_ADDTO4(word1, word2) ( \
+ ADDTO4_temp = (word1)[3], \
+
+
+
+Eastlake & Hansen Informational [Page 53]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+ (word1)[3] += (word2)[3], \
+ ADDTO4_temp2 = (word1)[2], \
+ (word1)[2] += (word2)[2] + ((word1)[3] < ADDTO4_temp), \
+ ADDTO4_temp = (word1)[1], \
+ (word1)[1] += (word2)[1] + ((word1)[2] < ADDTO4_temp2), \
+ (word1)[0] += (word2)[0] + ((word1)[1] < ADDTO4_temp) )
+
+/*
+ * Add the 2word value in word2 to word1.
+ */
+static uint32_t ADDTO2_temp;
+#define SHA512_ADDTO2(word1, word2) ( \
+ ADDTO2_temp = (word1)[1], \
+ (word1)[1] += (word2)[1], \
+ (word1)[0] += (word2)[0] + ((word1)[1] < ADDTO2_temp) )
+
+/*
+ * SHA rotate ((word >> bits) | (word << (64-bits)))
+ */
+static uint32_t ROTR_temp1[2], ROTR_temp2[2];
+#define SHA512_ROTR(bits, word, ret) ( \
+ SHA512_SHR((bits), (word), ROTR_temp1), \
+ SHA512_SHL(64-(bits), (word), ROTR_temp2), \
+ SHA512_OR(ROTR_temp1, ROTR_temp2, (ret)) )
+
+/*
+ * Define the SHA SIGMA and sigma macros
+ *
+ * SHA512_ROTR(28,word) ^ SHA512_ROTR(34,word) ^ SHA512_ROTR(39,word)
+ */
+static uint32_t SIGMA0_temp1[2], SIGMA0_temp2[2],
+ SIGMA0_temp3[2], SIGMA0_temp4[2];
+#define SHA512_SIGMA0(word, ret) ( \
+ SHA512_ROTR(28, (word), SIGMA0_temp1), \
+ SHA512_ROTR(34, (word), SIGMA0_temp2), \
+ SHA512_ROTR(39, (word), SIGMA0_temp3), \
+ SHA512_XOR(SIGMA0_temp2, SIGMA0_temp3, SIGMA0_temp4), \
+ SHA512_XOR(SIGMA0_temp1, SIGMA0_temp4, (ret)) )
+
+/*
+ * SHA512_ROTR(14,word) ^ SHA512_ROTR(18,word) ^ SHA512_ROTR(41,word)
+ */
+static uint32_t SIGMA1_temp1[2], SIGMA1_temp2[2],
+ SIGMA1_temp3[2], SIGMA1_temp4[2];
+#define SHA512_SIGMA1(word, ret) ( \
+ SHA512_ROTR(14, (word), SIGMA1_temp1), \
+ SHA512_ROTR(18, (word), SIGMA1_temp2), \
+ SHA512_ROTR(41, (word), SIGMA1_temp3), \
+
+
+
+Eastlake & Hansen Informational [Page 54]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+ SHA512_XOR(SIGMA1_temp2, SIGMA1_temp3, SIGMA1_temp4), \
+ SHA512_XOR(SIGMA1_temp1, SIGMA1_temp4, (ret)) )
+
+/*
+ * (SHA512_ROTR( 1,word) ^ SHA512_ROTR( 8,word) ^ SHA512_SHR( 7,word))
+ */
+static uint32_t sigma0_temp1[2], sigma0_temp2[2],
+ sigma0_temp3[2], sigma0_temp4[2];
+#define SHA512_sigma0(word, ret) ( \
+ SHA512_ROTR( 1, (word), sigma0_temp1), \
+ SHA512_ROTR( 8, (word), sigma0_temp2), \
+ SHA512_SHR( 7, (word), sigma0_temp3), \
+ SHA512_XOR(sigma0_temp2, sigma0_temp3, sigma0_temp4), \
+ SHA512_XOR(sigma0_temp1, sigma0_temp4, (ret)) )
+
+/*
+ * (SHA512_ROTR(19,word) ^ SHA512_ROTR(61,word) ^ SHA512_SHR( 6,word))
+ */
+static uint32_t sigma1_temp1[2], sigma1_temp2[2],
+ sigma1_temp3[2], sigma1_temp4[2];
+#define SHA512_sigma1(word, ret) ( \
+ SHA512_ROTR(19, (word), sigma1_temp1), \
+ SHA512_ROTR(61, (word), sigma1_temp2), \
+ SHA512_SHR( 6, (word), sigma1_temp3), \
+ SHA512_XOR(sigma1_temp2, sigma1_temp3, sigma1_temp4), \
+ SHA512_XOR(sigma1_temp1, sigma1_temp4, (ret)) )
+
+#ifndef USE_MODIFIED_MACROS
+/*
+ * These definitions are the ones used in FIPS 180-3, section 4.1.3
+ * Ch(x,y,z) ((x & y) ^ (~x & z))
+ */
+static uint32_t Ch_temp1[2], Ch_temp2[2], Ch_temp3[2];
+#define SHA_Ch(x, y, z, ret) ( \
+ SHA512_AND(x, y, Ch_temp1), \
+ SHA512_TILDA(x, Ch_temp2), \
+ SHA512_AND(Ch_temp2, z, Ch_temp3), \
+ SHA512_XOR(Ch_temp1, Ch_temp3, (ret)) )
+
+/*
+ * Maj(x,y,z) (((x)&(y)) ^ ((x)&(z)) ^ ((y)&(z)))
+ */
+static uint32_t Maj_temp1[2], Maj_temp2[2],
+ Maj_temp3[2], Maj_temp4[2];
+#define SHA_Maj(x, y, z, ret) ( \
+ SHA512_AND(x, y, Maj_temp1), \
+ SHA512_AND(x, z, Maj_temp2), \
+ SHA512_AND(y, z, Maj_temp3), \
+
+
+
+Eastlake & Hansen Informational [Page 55]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+ SHA512_XOR(Maj_temp2, Maj_temp3, Maj_temp4), \
+ SHA512_XOR(Maj_temp1, Maj_temp4, (ret)) )
+#else /* !USE_MODIFIED_MACROS */
+/*
+ * These definitions are potentially faster equivalents for the ones
+ * used in FIPS 180-3, section 4.1.3.
+ * ((x & y) ^ (~x & z)) becomes
+ * ((x & (y ^ z)) ^ z)
+ */
+#define SHA_Ch(x, y, z, ret) ( \
+ (ret)[0] = (((x)[0] & ((y)[0] ^ (z)[0])) ^ (z)[0]), \
+ (ret)[1] = (((x)[1] & ((y)[1] ^ (z)[1])) ^ (z)[1]) )
+
+/*
+ * ((x & y) ^ (x & z) ^ (y & z)) becomes
+ * ((x & (y | z)) | (y & z))
+ */
+#define SHA_Maj(x, y, z, ret) ( \
+ ret[0] = (((x)[0] & ((y)[0] | (z)[0])) | ((y)[0] & (z)[0])), \
+ ret[1] = (((x)[1] & ((y)[1] | (z)[1])) | ((y)[1] & (z)[1])) )
+#endif /* USE_MODIFIED_MACROS */
+
+/*
+ * Add "length" to the length.
+ * Set Corrupted when overflow has occurred.
+ */
+static uint32_t addTemp[4] = { 0, 0, 0, 0 };
+#define SHA384_512AddLength(context, length) ( \
+ addTemp[3] = (length), SHA512_ADDTO4((context)->Length, addTemp), \
+ (context)->Corrupted = (((context)->Length[3] < (length)) && \
+ ((context)->Length[2] == 0) && ((context)->Length[1] == 0) && \
+ ((context)->Length[0] == 0)) ? shaInputTooLong : \
+ (context)->Corrupted )
+
+/* Local Function Prototypes */
+static int SHA384_512Reset(SHA512Context *context,
+ uint32_t H0[SHA512HashSize/4]);
+static void SHA384_512ProcessMessageBlock(SHA512Context *context);
+static void SHA384_512Finalize(SHA512Context *context,
+ uint8_t Pad_Byte);
+static void SHA384_512PadMessage(SHA512Context *context,
+ uint8_t Pad_Byte);
+static int SHA384_512ResultN( SHA512Context *context,
+ uint8_t Message_Digest[ ], int HashSize);
+
+/* Initial Hash Values: FIPS 180-3 sections 5.3.4 and 5.3.5 */
+static uint32_t SHA384_H0[SHA512HashSize/4] = {
+ 0xCBBB9D5D, 0xC1059ED8, 0x629A292A, 0x367CD507, 0x9159015A,
+
+
+
+Eastlake & Hansen Informational [Page 56]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+ 0x3070DD17, 0x152FECD8, 0xF70E5939, 0x67332667, 0xFFC00B31,
+ 0x8EB44A87, 0x68581511, 0xDB0C2E0D, 0x64F98FA7, 0x47B5481D,
+ 0xBEFA4FA4
+};
+static uint32_t SHA512_H0[SHA512HashSize/4] = {
+ 0x6A09E667, 0xF3BCC908, 0xBB67AE85, 0x84CAA73B, 0x3C6EF372,
+ 0xFE94F82B, 0xA54FF53A, 0x5F1D36F1, 0x510E527F, 0xADE682D1,
+ 0x9B05688C, 0x2B3E6C1F, 0x1F83D9AB, 0xFB41BD6B, 0x5BE0CD19,
+ 0x137E2179
+};
+
+#else /* !USE_32BIT_ONLY */
+
+#include "sha-private.h"
+
+/* Define the SHA shift, rotate left and rotate right macros */
+#define SHA512_SHR(bits,word) (((uint64_t)(word)) >> (bits))
+#define SHA512_ROTR(bits,word) ((((uint64_t)(word)) >> (bits)) | \
+ (((uint64_t)(word)) << (64-(bits))))
+
+/*
+ * Define the SHA SIGMA and sigma macros
+ *
+ * SHA512_ROTR(28,word) ^ SHA512_ROTR(34,word) ^ SHA512_ROTR(39,word)
+ */
+#define SHA512_SIGMA0(word) \
+ (SHA512_ROTR(28,word) ^ SHA512_ROTR(34,word) ^ SHA512_ROTR(39,word))
+#define SHA512_SIGMA1(word) \
+ (SHA512_ROTR(14,word) ^ SHA512_ROTR(18,word) ^ SHA512_ROTR(41,word))
+#define SHA512_sigma0(word) \
+ (SHA512_ROTR( 1,word) ^ SHA512_ROTR( 8,word) ^ SHA512_SHR( 7,word))
+#define SHA512_sigma1(word) \
+ (SHA512_ROTR(19,word) ^ SHA512_ROTR(61,word) ^ SHA512_SHR( 6,word))
+
+/*
+ * Add "length" to the length.
+ * Set Corrupted when overflow has occurred.
+ */
+static uint64_t addTemp;
+#define SHA384_512AddLength(context, length) \
+ (addTemp = context->Length_Low, context->Corrupted = \
+ ((context->Length_Low += length) < addTemp) && \
+ (++context->Length_High == 0) ? shaInputTooLong : \
+ (context)->Corrupted)
+
+/* Local Function Prototypes */
+static int SHA384_512Reset(SHA512Context *context,
+ uint64_t H0[SHA512HashSize/8]);
+
+
+
+Eastlake & Hansen Informational [Page 57]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+static void SHA384_512ProcessMessageBlock(SHA512Context *context);
+static void SHA384_512Finalize(SHA512Context *context,
+ uint8_t Pad_Byte);
+static void SHA384_512PadMessage(SHA512Context *context,
+ uint8_t Pad_Byte);
+static int SHA384_512ResultN(SHA512Context *context,
+ uint8_t Message_Digest[ ], int HashSize);
+
+/* Initial Hash Values: FIPS 180-3 sections 5.3.4 and 5.3.5 */
+static uint64_t SHA384_H0[ ] = {
+ 0xCBBB9D5DC1059ED8ll, 0x629A292A367CD507ll, 0x9159015A3070DD17ll,
+ 0x152FECD8F70E5939ll, 0x67332667FFC00B31ll, 0x8EB44A8768581511ll,
+ 0xDB0C2E0D64F98FA7ll, 0x47B5481DBEFA4FA4ll
+};
+static uint64_t SHA512_H0[ ] = {
+ 0x6A09E667F3BCC908ll, 0xBB67AE8584CAA73Bll, 0x3C6EF372FE94F82Bll,
+ 0xA54FF53A5F1D36F1ll, 0x510E527FADE682D1ll, 0x9B05688C2B3E6C1Fll,
+ 0x1F83D9ABFB41BD6Bll, 0x5BE0CD19137E2179ll
+};
+
+#endif /* USE_32BIT_ONLY */
+
+/*
+ * SHA384Reset
+ *
+ * Description:
+ * This function will initialize the SHA384Context in preparation
+ * for computing a new SHA384 message digest.
+ *
+ * Parameters:
+ * context: [in/out]
+ * The context to reset.
+ *
+ * Returns:
+ * sha Error Code.
+ *
+ */
+int SHA384Reset(SHA384Context *context)
+{
+ return SHA384_512Reset(context, SHA384_H0);
+}
+
+/*
+ * SHA384Input
+ *
+ * Description:
+ * This function accepts an array of octets as the next portion
+ * of the message.
+
+
+
+Eastlake & Hansen Informational [Page 58]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+ *
+ * Parameters:
+ * context: [in/out]
+ * The SHA context to update.
+ * message_array[ ]: [in]
+ * An array of octets representing the next portion of
+ * the message.
+ * length: [in]
+ * The length of the message in message_array.
+ *
+ * Returns:
+ * sha Error Code.
+ *
+ */
+int SHA384Input(SHA384Context *context,
+ const uint8_t *message_array, unsigned int length)
+{
+ return SHA512Input(context, message_array, length);
+}
+
+/*
+ * SHA384FinalBits
+ *
+ * Description:
+ * This function will add in any final bits of the message.
+ *
+ * Parameters:
+ * context: [in/out]
+ * The SHA context to update.
+ * message_bits: [in]
+ * The final bits of the message, in the upper portion of the
+ * byte. (Use 0b###00000 instead of 0b00000### to input the
+ * three bits ###.)
+ * length: [in]
+ * The number of bits in message_bits, between 1 and 7.
+ *
+ * Returns:
+ * sha Error Code.
+ *
+ */
+int SHA384FinalBits(SHA384Context *context,
+ uint8_t message_bits, unsigned int length)
+{
+ return SHA512FinalBits(context, message_bits, length);
+}
+
+/*
+ * SHA384Result
+
+
+
+Eastlake & Hansen Informational [Page 59]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+ *
+ * Description:
+ * This function will return the 384-bit message digest
+ * into the Message_Digest array provided by the caller.
+ * NOTE:
+ * The first octet of hash is stored in the element with index 0,
+ * the last octet of hash in the element with index 47.
+ *
+ * Parameters:
+ * context: [in/out]
+ * The context to use to calculate the SHA hash.
+ * Message_Digest[ ]: [out]
+ * Where the digest is returned.
+ *
+ * Returns:
+ * sha Error Code.
+ *
+ */
+int SHA384Result(SHA384Context *context,
+ uint8_t Message_Digest[SHA384HashSize])
+{
+ return SHA384_512ResultN(context, Message_Digest, SHA384HashSize);
+}
+
+/*
+ * SHA512Reset
+ *
+ * Description:
+ * This function will initialize the SHA512Context in preparation
+ * for computing a new SHA512 message digest.
+ *
+ * Parameters:
+ * context: [in/out]
+ * The context to reset.
+ *
+ * Returns:
+ * sha Error Code.
+ *
+ */
+int SHA512Reset(SHA512Context *context)
+{
+ return SHA384_512Reset(context, SHA512_H0);
+}
+
+/*
+ * SHA512Input
+ *
+ * Description:
+
+
+
+Eastlake & Hansen Informational [Page 60]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+ * This function accepts an array of octets as the next portion
+ * of the message.
+ *
+ * Parameters:
+ * context: [in/out]
+ * The SHA context to update.
+ * message_array[ ]: [in]
+ * An array of octets representing the next portion of
+ * the message.
+ * length: [in]
+ * The length of the message in message_array.
+ *
+ * Returns:
+ * sha Error Code.
+ *
+ */
+int SHA512Input(SHA512Context *context,
+ const uint8_t *message_array,
+ unsigned int length)
+{
+ if (!context) return shaNull;
+ if (!length) return shaSuccess;
+ if (!message_array) return shaNull;
+ if (context->Computed) return context->Corrupted = shaStateError;
+ if (context->Corrupted) return context->Corrupted;
+
+ while (length--) {
+ context->Message_Block[context->Message_Block_Index++] =
+ *message_array;
+
+ if ((SHA384_512AddLength(context, 8) == shaSuccess) &&
+ (context->Message_Block_Index == SHA512_Message_Block_Size))
+ SHA384_512ProcessMessageBlock(context);
+
+ message_array++;
+ }
+
+ return context->Corrupted;
+}
+
+/*
+ * SHA512FinalBits
+ *
+ * Description:
+ * This function will add in any final bits of the message.
+ *
+ * Parameters:
+ * context: [in/out]
+
+
+
+Eastlake & Hansen Informational [Page 61]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+ * The SHA context to update.
+ * message_bits: [in]
+ * The final bits of the message, in the upper portion of the
+ * byte. (Use 0b###00000 instead of 0b00000### to input the
+ * three bits ###.)
+ * length: [in]
+ * The number of bits in message_bits, between 1 and 7.
+ *
+ * Returns:
+ * sha Error Code.
+ *
+ */
+int SHA512FinalBits(SHA512Context *context,
+ uint8_t message_bits, unsigned int length)
+{
+ static uint8_t masks[8] = {
+ /* 0 0b00000000 */ 0x00, /* 1 0b10000000 */ 0x80,
+ /* 2 0b11000000 */ 0xC0, /* 3 0b11100000 */ 0xE0,
+ /* 4 0b11110000 */ 0xF0, /* 5 0b11111000 */ 0xF8,
+ /* 6 0b11111100 */ 0xFC, /* 7 0b11111110 */ 0xFE
+ };
+ static uint8_t markbit[8] = {
+ /* 0 0b10000000 */ 0x80, /* 1 0b01000000 */ 0x40,
+ /* 2 0b00100000 */ 0x20, /* 3 0b00010000 */ 0x10,
+ /* 4 0b00001000 */ 0x08, /* 5 0b00000100 */ 0x04,
+ /* 6 0b00000010 */ 0x02, /* 7 0b00000001 */ 0x01
+ };
+
+ if (!context) return shaNull;
+ if (!length) return shaSuccess;
+ if (context->Corrupted) return context->Corrupted;
+ if (context->Computed) return context->Corrupted = shaStateError;
+ if (length >= 8) return context->Corrupted = shaBadParam;
+
+ SHA384_512AddLength(context, length);
+ SHA384_512Finalize(context, (uint8_t)
+ ((message_bits & masks[length]) | markbit[length]));
+
+ return context->Corrupted;
+}
+
+/*
+ * SHA512Result
+ *
+ * Description:
+ * This function will return the 512-bit message digest
+ * into the Message_Digest array provided by the caller.
+ * NOTE:
+
+
+
+Eastlake & Hansen Informational [Page 62]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+ * The first octet of hash is stored in the element with index 0,
+ * the last octet of hash in the element with index 63.
+ *
+ * Parameters:
+ * context: [in/out]
+ * The context to use to calculate the SHA hash.
+ * Message_Digest[ ]: [out]
+ * Where the digest is returned.
+ *
+ * Returns:
+ * sha Error Code.
+ *
+ */
+int SHA512Result(SHA512Context *context,
+ uint8_t Message_Digest[SHA512HashSize])
+{
+ return SHA384_512ResultN(context, Message_Digest, SHA512HashSize);
+}
+
+/*
+ * SHA384_512Reset
+ *
+ * Description:
+ * This helper function will initialize the SHA512Context in
+ * preparation for computing a new SHA384 or SHA512 message
+ * digest.
+ *
+ * Parameters:
+ * context: [in/out]
+ * The context to reset.
+ * H0[ ]: [in]
+ * The initial hash value array to use.
+ *
+ * Returns:
+ * sha Error Code.
+ *
+ */
+#ifdef USE_32BIT_ONLY
+static int SHA384_512Reset(SHA512Context *context,
+ uint32_t H0[SHA512HashSize/4])
+#else /* !USE_32BIT_ONLY */
+static int SHA384_512Reset(SHA512Context *context,
+ uint64_t H0[SHA512HashSize/8])
+#endif /* USE_32BIT_ONLY */
+{
+ int i;
+ if (!context) return shaNull;
+
+
+
+
+Eastlake & Hansen Informational [Page 63]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+ context->Message_Block_Index = 0;
+
+#ifdef USE_32BIT_ONLY
+ context->Length[0] = context->Length[1] =
+ context->Length[2] = context->Length[3] = 0;
+
+ for (i = 0; i < SHA512HashSize/4; i++)
+ context->Intermediate_Hash[i] = H0[i];
+#else /* !USE_32BIT_ONLY */
+ context->Length_High = context->Length_Low = 0;
+
+ for (i = 0; i < SHA512HashSize/8; i++)
+ context->Intermediate_Hash[i] = H0[i];
+#endif /* USE_32BIT_ONLY */
+
+ context->Computed = 0;
+ context->Corrupted = shaSuccess;
+
+ return shaSuccess;
+}
+
+/*
+ * SHA384_512ProcessMessageBlock
+ *
+ * Description:
+ * This helper function will process the next 1024 bits of the
+ * message stored in the Message_Block array.
+ *
+ * Parameters:
+ * context: [in/out]
+ * The SHA context to update.
+ *
+ * Returns:
+ * Nothing.
+ *
+ * Comments:
+ * Many of the variable names in this code, especially the
+ * single character names, were used because those were the
+ * names used in the Secure Hash Standard.
+ *
+ *
+ */
+static void SHA384_512ProcessMessageBlock(SHA512Context *context)
+{
+#ifdef USE_32BIT_ONLY
+ /* Constants defined in FIPS 180-3, section 4.2.3 */
+ static const uint32_t K[80*2] = {
+ 0x428A2F98, 0xD728AE22, 0x71374491, 0x23EF65CD, 0xB5C0FBCF,
+
+
+
+Eastlake & Hansen Informational [Page 64]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+ 0xEC4D3B2F, 0xE9B5DBA5, 0x8189DBBC, 0x3956C25B, 0xF348B538,
+ 0x59F111F1, 0xB605D019, 0x923F82A4, 0xAF194F9B, 0xAB1C5ED5,
+ 0xDA6D8118, 0xD807AA98, 0xA3030242, 0x12835B01, 0x45706FBE,
+ 0x243185BE, 0x4EE4B28C, 0x550C7DC3, 0xD5FFB4E2, 0x72BE5D74,
+ 0xF27B896F, 0x80DEB1FE, 0x3B1696B1, 0x9BDC06A7, 0x25C71235,
+ 0xC19BF174, 0xCF692694, 0xE49B69C1, 0x9EF14AD2, 0xEFBE4786,
+ 0x384F25E3, 0x0FC19DC6, 0x8B8CD5B5, 0x240CA1CC, 0x77AC9C65,
+ 0x2DE92C6F, 0x592B0275, 0x4A7484AA, 0x6EA6E483, 0x5CB0A9DC,
+ 0xBD41FBD4, 0x76F988DA, 0x831153B5, 0x983E5152, 0xEE66DFAB,
+ 0xA831C66D, 0x2DB43210, 0xB00327C8, 0x98FB213F, 0xBF597FC7,
+ 0xBEEF0EE4, 0xC6E00BF3, 0x3DA88FC2, 0xD5A79147, 0x930AA725,
+ 0x06CA6351, 0xE003826F, 0x14292967, 0x0A0E6E70, 0x27B70A85,
+ 0x46D22FFC, 0x2E1B2138, 0x5C26C926, 0x4D2C6DFC, 0x5AC42AED,
+ 0x53380D13, 0x9D95B3DF, 0x650A7354, 0x8BAF63DE, 0x766A0ABB,
+ 0x3C77B2A8, 0x81C2C92E, 0x47EDAEE6, 0x92722C85, 0x1482353B,
+ 0xA2BFE8A1, 0x4CF10364, 0xA81A664B, 0xBC423001, 0xC24B8B70,
+ 0xD0F89791, 0xC76C51A3, 0x0654BE30, 0xD192E819, 0xD6EF5218,
+ 0xD6990624, 0x5565A910, 0xF40E3585, 0x5771202A, 0x106AA070,
+ 0x32BBD1B8, 0x19A4C116, 0xB8D2D0C8, 0x1E376C08, 0x5141AB53,
+ 0x2748774C, 0xDF8EEB99, 0x34B0BCB5, 0xE19B48A8, 0x391C0CB3,
+ 0xC5C95A63, 0x4ED8AA4A, 0xE3418ACB, 0x5B9CCA4F, 0x7763E373,
+ 0x682E6FF3, 0xD6B2B8A3, 0x748F82EE, 0x5DEFB2FC, 0x78A5636F,
+ 0x43172F60, 0x84C87814, 0xA1F0AB72, 0x8CC70208, 0x1A6439EC,
+ 0x90BEFFFA, 0x23631E28, 0xA4506CEB, 0xDE82BDE9, 0xBEF9A3F7,
+ 0xB2C67915, 0xC67178F2, 0xE372532B, 0xCA273ECE, 0xEA26619C,
+ 0xD186B8C7, 0x21C0C207, 0xEADA7DD6, 0xCDE0EB1E, 0xF57D4F7F,
+ 0xEE6ED178, 0x06F067AA, 0x72176FBA, 0x0A637DC5, 0xA2C898A6,
+ 0x113F9804, 0xBEF90DAE, 0x1B710B35, 0x131C471B, 0x28DB77F5,
+ 0x23047D84, 0x32CAAB7B, 0x40C72493, 0x3C9EBE0A, 0x15C9BEBC,
+ 0x431D67C4, 0x9C100D4C, 0x4CC5D4BE, 0xCB3E42B6, 0x597F299C,
+ 0xFC657E2A, 0x5FCB6FAB, 0x3AD6FAEC, 0x6C44198C, 0x4A475817
+ };
+ int t, t2, t8; /* Loop counter */
+ uint32_t temp1[2], temp2[2], /* Temporary word values */
+ temp3[2], temp4[2], temp5[2];
+ uint32_t W[2*80]; /* Word sequence */
+ uint32_t A[2], B[2], C[2], D[2], /* Word buffers */
+ E[2], F[2], G[2], H[2];
+
+ /* Initialize the first 16 words in the array W */
+ for (t = t2 = t8 = 0; t < 16; t++, t8 += 8) {
+ W[t2++] = ((((uint32_t)context->Message_Block[t8 ])) << 24) |
+ ((((uint32_t)context->Message_Block[t8 + 1])) << 16) |
+ ((((uint32_t)context->Message_Block[t8 + 2])) << 8) |
+ ((((uint32_t)context->Message_Block[t8 + 3])));
+ W[t2++] = ((((uint32_t)context->Message_Block[t8 + 4])) << 24) |
+ ((((uint32_t)context->Message_Block[t8 + 5])) << 16) |
+ ((((uint32_t)context->Message_Block[t8 + 6])) << 8) |
+
+
+
+Eastlake & Hansen Informational [Page 65]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+ ((((uint32_t)context->Message_Block[t8 + 7])));
+ }
+
+ for (t = 16; t < 80; t++, t2 += 2) {
+ /* W[t] = SHA512_sigma1(W[t-2]) + W[t-7] +
+ SHA512_sigma0(W[t-15]) + W[t-16]; */
+ uint32_t *Wt2 = &W[t2-2*2];
+ uint32_t *Wt7 = &W[t2-7*2];
+ uint32_t *Wt15 = &W[t2-15*2];
+ uint32_t *Wt16 = &W[t2-16*2];
+ SHA512_sigma1(Wt2, temp1);
+ SHA512_ADD(temp1, Wt7, temp2);
+ SHA512_sigma0(Wt15, temp1);
+ SHA512_ADD(temp1, Wt16, temp3);
+ SHA512_ADD(temp2, temp3, &W[t2]);
+ }
+
+ A[0] = context->Intermediate_Hash[0];
+ A[1] = context->Intermediate_Hash[1];
+ B[0] = context->Intermediate_Hash[2];
+ B[1] = context->Intermediate_Hash[3];
+ C[0] = context->Intermediate_Hash[4];
+ C[1] = context->Intermediate_Hash[5];
+ D[0] = context->Intermediate_Hash[6];
+ D[1] = context->Intermediate_Hash[7];
+ E[0] = context->Intermediate_Hash[8];
+ E[1] = context->Intermediate_Hash[9];
+ F[0] = context->Intermediate_Hash[10];
+ F[1] = context->Intermediate_Hash[11];
+ G[0] = context->Intermediate_Hash[12];
+ G[1] = context->Intermediate_Hash[13];
+ H[0] = context->Intermediate_Hash[14];
+ H[1] = context->Intermediate_Hash[15];
+
+ for (t = t2 = 0; t < 80; t++, t2 += 2) {
+ /*
+ * temp1 = H + SHA512_SIGMA1(E) + SHA_Ch(E,F,G) + K[t] + W[t];
+ */
+ SHA512_SIGMA1(E,temp1);
+ SHA512_ADD(H, temp1, temp2);
+ SHA_Ch(E,F,G,temp3);
+ SHA512_ADD(temp2, temp3, temp4);
+ SHA512_ADD(&K[t2], &W[t2], temp5);
+ SHA512_ADD(temp4, temp5, temp1);
+ /*
+ * temp2 = SHA512_SIGMA0(A) + SHA_Maj(A,B,C);
+ */
+ SHA512_SIGMA0(A,temp3);
+
+
+
+Eastlake & Hansen Informational [Page 66]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+ SHA_Maj(A,B,C,temp4);
+ SHA512_ADD(temp3, temp4, temp2);
+ H[0] = G[0]; H[1] = G[1];
+ G[0] = F[0]; G[1] = F[1];
+ F[0] = E[0]; F[1] = E[1];
+ SHA512_ADD(D, temp1, E);
+ D[0] = C[0]; D[1] = C[1];
+ C[0] = B[0]; C[1] = B[1];
+ B[0] = A[0]; B[1] = A[1];
+ SHA512_ADD(temp1, temp2, A);
+ }
+
+ SHA512_ADDTO2(&context->Intermediate_Hash[0], A);
+ SHA512_ADDTO2(&context->Intermediate_Hash[2], B);
+ SHA512_ADDTO2(&context->Intermediate_Hash[4], C);
+ SHA512_ADDTO2(&context->Intermediate_Hash[6], D);
+ SHA512_ADDTO2(&context->Intermediate_Hash[8], E);
+ SHA512_ADDTO2(&context->Intermediate_Hash[10], F);
+ SHA512_ADDTO2(&context->Intermediate_Hash[12], G);
+ SHA512_ADDTO2(&context->Intermediate_Hash[14], H);
+
+#else /* !USE_32BIT_ONLY */
+ /* Constants defined in FIPS 180-3, section 4.2.3 */
+ static const uint64_t K[80] = {
+ 0x428A2F98D728AE22ll, 0x7137449123EF65CDll, 0xB5C0FBCFEC4D3B2Fll,
+ 0xE9B5DBA58189DBBCll, 0x3956C25BF348B538ll, 0x59F111F1B605D019ll,
+ 0x923F82A4AF194F9Bll, 0xAB1C5ED5DA6D8118ll, 0xD807AA98A3030242ll,
+ 0x12835B0145706FBEll, 0x243185BE4EE4B28Cll, 0x550C7DC3D5FFB4E2ll,
+ 0x72BE5D74F27B896Fll, 0x80DEB1FE3B1696B1ll, 0x9BDC06A725C71235ll,
+ 0xC19BF174CF692694ll, 0xE49B69C19EF14AD2ll, 0xEFBE4786384F25E3ll,
+ 0x0FC19DC68B8CD5B5ll, 0x240CA1CC77AC9C65ll, 0x2DE92C6F592B0275ll,
+ 0x4A7484AA6EA6E483ll, 0x5CB0A9DCBD41FBD4ll, 0x76F988DA831153B5ll,
+ 0x983E5152EE66DFABll, 0xA831C66D2DB43210ll, 0xB00327C898FB213Fll,
+ 0xBF597FC7BEEF0EE4ll, 0xC6E00BF33DA88FC2ll, 0xD5A79147930AA725ll,
+ 0x06CA6351E003826Fll, 0x142929670A0E6E70ll, 0x27B70A8546D22FFCll,
+ 0x2E1B21385C26C926ll, 0x4D2C6DFC5AC42AEDll, 0x53380D139D95B3DFll,
+ 0x650A73548BAF63DEll, 0x766A0ABB3C77B2A8ll, 0x81C2C92E47EDAEE6ll,
+ 0x92722C851482353Bll, 0xA2BFE8A14CF10364ll, 0xA81A664BBC423001ll,
+ 0xC24B8B70D0F89791ll, 0xC76C51A30654BE30ll, 0xD192E819D6EF5218ll,
+ 0xD69906245565A910ll, 0xF40E35855771202All, 0x106AA07032BBD1B8ll,
+ 0x19A4C116B8D2D0C8ll, 0x1E376C085141AB53ll, 0x2748774CDF8EEB99ll,
+ 0x34B0BCB5E19B48A8ll, 0x391C0CB3C5C95A63ll, 0x4ED8AA4AE3418ACBll,
+ 0x5B9CCA4F7763E373ll, 0x682E6FF3D6B2B8A3ll, 0x748F82EE5DEFB2FCll,
+ 0x78A5636F43172F60ll, 0x84C87814A1F0AB72ll, 0x8CC702081A6439ECll,
+ 0x90BEFFFA23631E28ll, 0xA4506CEBDE82BDE9ll, 0xBEF9A3F7B2C67915ll,
+ 0xC67178F2E372532Bll, 0xCA273ECEEA26619Cll, 0xD186B8C721C0C207ll,
+ 0xEADA7DD6CDE0EB1Ell, 0xF57D4F7FEE6ED178ll, 0x06F067AA72176FBAll,
+ 0x0A637DC5A2C898A6ll, 0x113F9804BEF90DAEll, 0x1B710B35131C471Bll,
+
+
+
+Eastlake & Hansen Informational [Page 67]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+ 0x28DB77F523047D84ll, 0x32CAAB7B40C72493ll, 0x3C9EBE0A15C9BEBCll,
+ 0x431D67C49C100D4Cll, 0x4CC5D4BECB3E42B6ll, 0x597F299CFC657E2All,
+ 0x5FCB6FAB3AD6FAECll, 0x6C44198C4A475817ll
+ };
+ int t, t8; /* Loop counter */
+ uint64_t temp1, temp2; /* Temporary word value */
+ uint64_t W[80]; /* Word sequence */
+ uint64_t A, B, C, D, E, F, G, H; /* Word buffers */
+
+ /*
+ * Initialize the first 16 words in the array W
+ */
+ for (t = t8 = 0; t < 16; t++, t8 += 8)
+ W[t] = ((uint64_t)(context->Message_Block[t8 ]) << 56) |
+ ((uint64_t)(context->Message_Block[t8 + 1]) << 48) |
+ ((uint64_t)(context->Message_Block[t8 + 2]) << 40) |
+ ((uint64_t)(context->Message_Block[t8 + 3]) << 32) |
+ ((uint64_t)(context->Message_Block[t8 + 4]) << 24) |
+ ((uint64_t)(context->Message_Block[t8 + 5]) << 16) |
+ ((uint64_t)(context->Message_Block[t8 + 6]) << 8) |
+ ((uint64_t)(context->Message_Block[t8 + 7]));
+
+ for (t = 16; t < 80; t++)
+ W[t] = SHA512_sigma1(W[t-2]) + W[t-7] +
+ SHA512_sigma0(W[t-15]) + W[t-16];
+ A = context->Intermediate_Hash[0];
+ B = context->Intermediate_Hash[1];
+ C = context->Intermediate_Hash[2];
+ D = context->Intermediate_Hash[3];
+ E = context->Intermediate_Hash[4];
+ F = context->Intermediate_Hash[5];
+ G = context->Intermediate_Hash[6];
+ H = context->Intermediate_Hash[7];
+
+ for (t = 0; t < 80; t++) {
+ temp1 = H + SHA512_SIGMA1(E) + SHA_Ch(E,F,G) + K[t] + W[t];
+ temp2 = SHA512_SIGMA0(A) + SHA_Maj(A,B,C);
+ H = G;
+ G = F;
+ F = E;
+ E = D + temp1;
+ D = C;
+ C = B;
+ B = A;
+ A = temp1 + temp2;
+ }
+
+ context->Intermediate_Hash[0] += A;
+
+
+
+Eastlake & Hansen Informational [Page 68]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+ context->Intermediate_Hash[1] += B;
+ context->Intermediate_Hash[2] += C;
+ context->Intermediate_Hash[3] += D;
+ context->Intermediate_Hash[4] += E;
+ context->Intermediate_Hash[5] += F;
+ context->Intermediate_Hash[6] += G;
+ context->Intermediate_Hash[7] += H;
+#endif /* USE_32BIT_ONLY */
+
+ context->Message_Block_Index = 0;
+}
+
+/*
+ * SHA384_512Finalize
+ *
+ * Description:
+ * This helper function finishes off the digest calculations.
+ *
+ * Parameters:
+ * context: [in/out]
+ * The SHA context to update.
+ * Pad_Byte: [in]
+ * The last byte to add to the message block before the 0-padding
+ * and length. This will contain the last bits of the message
+ * followed by another single bit. If the message was an
+ * exact multiple of 8-bits long, Pad_Byte will be 0x80.
+ *
+ * Returns:
+ * sha Error Code.
+ *
+ */
+static void SHA384_512Finalize(SHA512Context *context,
+ uint8_t Pad_Byte)
+{
+ int_least16_t i;
+ SHA384_512PadMessage(context, Pad_Byte);
+ /* message may be sensitive, clear it out */
+ for (i = 0; i < SHA512_Message_Block_Size; ++i)
+ context->Message_Block[i] = 0;
+#ifdef USE_32BIT_ONLY /* and clear length */
+ context->Length[0] = context->Length[1] = 0;
+ context->Length[2] = context->Length[3] = 0;
+#else /* !USE_32BIT_ONLY */
+ context->Length_High = context->Length_Low = 0;
+#endif /* USE_32BIT_ONLY */
+ context->Computed = 1;
+}
+
+
+
+
+Eastlake & Hansen Informational [Page 69]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+/*
+ * SHA384_512PadMessage
+ *
+ * Description:
+ * According to the standard, the message must be padded to the next
+ * even multiple of 1024 bits. The first padding bit must be a '1'.
+ * The last 128 bits represent the length of the original message.
+ * All bits in between should be 0. This helper function will
+ * pad the message according to those rules by filling the
+ * Message_Block array accordingly. When it returns, it can be
+ * assumed that the message digest has been computed.
+ *
+ * Parameters:
+ * context: [in/out]
+ * The context to pad.
+ * Pad_Byte: [in]
+ * The last byte to add to the message block before the 0-padding
+ * and length. This will contain the last bits of the message
+ * followed by another single bit. If the message was an
+ * exact multiple of 8-bits long, Pad_Byte will be 0x80.
+ *
+ * Returns:
+ * Nothing.
+ *
+ */
+static void SHA384_512PadMessage(SHA512Context *context,
+ uint8_t Pad_Byte)
+{
+ /*
+ * Check to see if the current message block is too small to hold
+ * the initial padding bits and length. If so, we will pad the
+ * block, process it, and then continue padding into a second
+ * block.
+ */
+ if (context->Message_Block_Index >= (SHA512_Message_Block_Size-16)) {
+ context->Message_Block[context->Message_Block_Index++] = Pad_Byte;
+ while (context->Message_Block_Index < SHA512_Message_Block_Size)
+ context->Message_Block[context->Message_Block_Index++] = 0;
+
+ SHA384_512ProcessMessageBlock(context);
+ } else
+ context->Message_Block[context->Message_Block_Index++] = Pad_Byte;
+
+ while (context->Message_Block_Index < (SHA512_Message_Block_Size-16))
+ context->Message_Block[context->Message_Block_Index++] = 0;
+
+ /*
+ * Store the message length as the last 16 octets
+
+
+
+Eastlake & Hansen Informational [Page 70]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+ */
+#ifdef USE_32BIT_ONLY
+ context->Message_Block[112] = (uint8_t)(context->Length[0] >> 24);
+ context->Message_Block[113] = (uint8_t)(context->Length[0] >> 16);
+ context->Message_Block[114] = (uint8_t)(context->Length[0] >> 8);
+ context->Message_Block[115] = (uint8_t)(context->Length[0]);
+ context->Message_Block[116] = (uint8_t)(context->Length[1] >> 24);
+ context->Message_Block[117] = (uint8_t)(context->Length[1] >> 16);
+ context->Message_Block[118] = (uint8_t)(context->Length[1] >> 8);
+ context->Message_Block[119] = (uint8_t)(context->Length[1]);
+
+ context->Message_Block[120] = (uint8_t)(context->Length[2] >> 24);
+ context->Message_Block[121] = (uint8_t)(context->Length[2] >> 16);
+ context->Message_Block[122] = (uint8_t)(context->Length[2] >> 8);
+ context->Message_Block[123] = (uint8_t)(context->Length[2]);
+ context->Message_Block[124] = (uint8_t)(context->Length[3] >> 24);
+ context->Message_Block[125] = (uint8_t)(context->Length[3] >> 16);
+ context->Message_Block[126] = (uint8_t)(context->Length[3] >> 8);
+ context->Message_Block[127] = (uint8_t)(context->Length[3]);
+#else /* !USE_32BIT_ONLY */
+ context->Message_Block[112] = (uint8_t)(context->Length_High >> 56);
+ context->Message_Block[113] = (uint8_t)(context->Length_High >> 48);
+ context->Message_Block[114] = (uint8_t)(context->Length_High >> 40);
+ context->Message_Block[115] = (uint8_t)(context->Length_High >> 32);
+ context->Message_Block[116] = (uint8_t)(context->Length_High >> 24);
+ context->Message_Block[117] = (uint8_t)(context->Length_High >> 16);
+ context->Message_Block[118] = (uint8_t)(context->Length_High >> 8);
+ context->Message_Block[119] = (uint8_t)(context->Length_High);
+
+ context->Message_Block[120] = (uint8_t)(context->Length_Low >> 56);
+ context->Message_Block[121] = (uint8_t)(context->Length_Low >> 48);
+ context->Message_Block[122] = (uint8_t)(context->Length_Low >> 40);
+ context->Message_Block[123] = (uint8_t)(context->Length_Low >> 32);
+ context->Message_Block[124] = (uint8_t)(context->Length_Low >> 24);
+ context->Message_Block[125] = (uint8_t)(context->Length_Low >> 16);
+ context->Message_Block[126] = (uint8_t)(context->Length_Low >> 8);
+ context->Message_Block[127] = (uint8_t)(context->Length_Low);
+#endif /* USE_32BIT_ONLY */
+
+ SHA384_512ProcessMessageBlock(context);
+}
+
+/*
+ * SHA384_512ResultN
+ *
+ * Description:
+ * This helper function will return the 384-bit or 512-bit message
+ * digest into the Message_Digest array provided by the caller.
+
+
+
+Eastlake & Hansen Informational [Page 71]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+ * NOTE:
+ * The first octet of hash is stored in the element with index 0,
+ * the last octet of hash in the element with index 47/63.
+ *
+ * Parameters:
+ * context: [in/out]
+ * The context to use to calculate the SHA hash.
+ * Message_Digest[ ]: [out]
+ * Where the digest is returned.
+ * HashSize: [in]
+ * The size of the hash, either 48 or 64.
+ *
+ * Returns:
+ * sha Error Code.
+ *
+ */
+static int SHA384_512ResultN(SHA512Context *context,
+ uint8_t Message_Digest[ ], int HashSize)
+{
+ int i;
+#ifdef USE_32BIT_ONLY
+ int i2;
+#endif /* USE_32BIT_ONLY */
+
+ if (!context) return shaNull;
+ if (!Message_Digest) return shaNull;
+ if (context->Corrupted) return context->Corrupted;
+
+ if (!context->Computed)
+ SHA384_512Finalize(context, 0x80);
+
+#ifdef USE_32BIT_ONLY
+ for (i = i2 = 0; i < HashSize; ) {
+ Message_Digest[i++]=(uint8_t)(context->Intermediate_Hash[i2]>>24);
+ Message_Digest[i++]=(uint8_t)(context->Intermediate_Hash[i2]>>16);
+ Message_Digest[i++]=(uint8_t)(context->Intermediate_Hash[i2]>>8);
+ Message_Digest[i++]=(uint8_t)(context->Intermediate_Hash[i2++]);
+ Message_Digest[i++]=(uint8_t)(context->Intermediate_Hash[i2]>>24);
+ Message_Digest[i++]=(uint8_t)(context->Intermediate_Hash[i2]>>16);
+ Message_Digest[i++]=(uint8_t)(context->Intermediate_Hash[i2]>>8);
+ Message_Digest[i++]=(uint8_t)(context->Intermediate_Hash[i2++]);
+ }
+#else /* !USE_32BIT_ONLY */
+ for (i = 0; i < HashSize; ++i)
+ Message_Digest[i] = (uint8_t)
+ (context->Intermediate_Hash[i>>3] >> 8 * ( 7 - ( i % 8 ) ));
+#endif /* USE_32BIT_ONLY */
+
+
+
+
+Eastlake & Hansen Informational [Page 72]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+ return shaSuccess;
+}
+
+8.2.4. usha.c
+
+/**************************** usha.c ***************************/
+/***************** See RFC 6234 for details. *******************/
+/* Copyright (c) 2011 IETF Trust and the persons identified as */
+/* authors of the code. All rights reserved. */
+/* See sha.h for terms of use and redistribution. */
+
+/*
+ * Description:
+ * This file implements a unified interface to the SHA algorithms.
+ */
+
+#include "sha.h"
+
+/*
+ * USHAReset
+ *
+ * Description:
+ * This function will initialize the SHA Context in preparation
+ * for computing a new SHA message digest.
+ *
+ * Parameters:
+ * context: [in/out]
+ * The context to reset.
+ * whichSha: [in]
+ * Selects which SHA reset to call
+ *
+ * Returns:
+ * sha Error Code.
+ *
+ */
+int USHAReset(USHAContext *context, enum SHAversion whichSha)
+{
+ if (!context) return shaNull;
+ context->whichSha = whichSha;
+ switch (whichSha) {
+ case SHA1: return SHA1Reset((SHA1Context*)&context->ctx);
+ case SHA224: return SHA224Reset((SHA224Context*)&context->ctx);
+ case SHA256: return SHA256Reset((SHA256Context*)&context->ctx);
+ case SHA384: return SHA384Reset((SHA384Context*)&context->ctx);
+ case SHA512: return SHA512Reset((SHA512Context*)&context->ctx);
+ default: return shaBadParam;
+ }
+}
+
+
+
+Eastlake & Hansen Informational [Page 73]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+/*
+ * USHAInput
+ *
+ * Description:
+ * This function accepts an array of octets as the next portion
+ * of the message.
+ *
+ * Parameters:
+ * context: [in/out]
+ * The SHA context to update.
+ * message_array: [in]
+ * An array of octets representing the next portion of
+ * the message.
+ * length: [in]
+ * The length of the message in message_array.
+ *
+ * Returns:
+ * sha Error Code.
+ *
+ */
+int USHAInput(USHAContext *context,
+ const uint8_t *bytes, unsigned int bytecount)
+{
+ if (!context) return shaNull;
+ switch (context->whichSha) {
+ case SHA1:
+ return SHA1Input((SHA1Context*)&context->ctx, bytes,
+ bytecount);
+ case SHA224:
+ return SHA224Input((SHA224Context*)&context->ctx, bytes,
+ bytecount);
+ case SHA256:
+ return SHA256Input((SHA256Context*)&context->ctx, bytes,
+ bytecount);
+ case SHA384:
+ return SHA384Input((SHA384Context*)&context->ctx, bytes,
+ bytecount);
+ case SHA512:
+ return SHA512Input((SHA512Context*)&context->ctx, bytes,
+ bytecount);
+ default: return shaBadParam;
+ }
+}
+
+
+
+
+
+
+
+
+Eastlake & Hansen Informational [Page 74]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+/*
+ * USHAFinalBits
+ *
+ * Description:
+ * This function will add in any final bits of the message.
+ *
+ * Parameters:
+ * context: [in/out]
+ * The SHA context to update.
+ * message_bits: [in]
+ * The final bits of the message, in the upper portion of the
+ * byte. (Use 0b###00000 instead of 0b00000### to input the
+ * three bits ###.)
+ * length: [in]
+ * The number of bits in message_bits, between 1 and 7.
+ *
+ * Returns:
+ * sha Error Code.
+ */
+int USHAFinalBits(USHAContext *context,
+ uint8_t bits, unsigned int bit_count)
+{
+ if (!context) return shaNull;
+ switch (context->whichSha) {
+ case SHA1:
+ return SHA1FinalBits((SHA1Context*)&context->ctx, bits,
+ bit_count);
+ case SHA224:
+ return SHA224FinalBits((SHA224Context*)&context->ctx, bits,
+ bit_count);
+ case SHA256:
+ return SHA256FinalBits((SHA256Context*)&context->ctx, bits,
+ bit_count);
+ case SHA384:
+ return SHA384FinalBits((SHA384Context*)&context->ctx, bits,
+ bit_count);
+ case SHA512:
+ return SHA512FinalBits((SHA512Context*)&context->ctx, bits,
+ bit_count);
+ default: return shaBadParam;
+ }
+}
+
+
+
+
+
+
+
+
+
+Eastlake & Hansen Informational [Page 75]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+/*
+ * USHAResult
+ *
+ * Description:
+ * This function will return the message digest of the appropriate
+ * bit size, as returned by USHAHashSizeBits(whichSHA) for the
+ * 'whichSHA' value used in the preceeding call to USHAReset,
+ * into the Message_Digest array provided by the caller.
+ *
+ * Parameters:
+ * context: [in/out]
+ * The context to use to calculate the SHA-1 hash.
+ * Message_Digest: [out]
+ * Where the digest is returned.
+ *
+ * Returns:
+ * sha Error Code.
+ *
+ */
+int USHAResult(USHAContext *context,
+ uint8_t Message_Digest[USHAMaxHashSize])
+{
+ if (!context) return shaNull;
+ switch (context->whichSha) {
+ case SHA1:
+ return SHA1Result((SHA1Context*)&context->ctx, Message_Digest);
+ case SHA224:
+ return SHA224Result((SHA224Context*)&context->ctx,
+ Message_Digest);
+ case SHA256:
+ return SHA256Result((SHA256Context*)&context->ctx,
+ Message_Digest);
+ case SHA384:
+ return SHA384Result((SHA384Context*)&context->ctx,
+ Message_Digest);
+ case SHA512:
+ return SHA512Result((SHA512Context*)&context->ctx,
+ Message_Digest);
+ default: return shaBadParam;
+ }
+}
+
+/*
+ * USHABlockSize
+ *
+ * Description:
+ * This function will return the blocksize for the given SHA
+ * algorithm.
+
+
+
+Eastlake & Hansen Informational [Page 76]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+ *
+ * Parameters:
+ * whichSha:
+ * which SHA algorithm to query
+ *
+ * Returns:
+ * block size
+ *
+ */
+int USHABlockSize(enum SHAversion whichSha)
+{
+ switch (whichSha) {
+ case SHA1: return SHA1_Message_Block_Size;
+ case SHA224: return SHA224_Message_Block_Size;
+ case SHA256: return SHA256_Message_Block_Size;
+ case SHA384: return SHA384_Message_Block_Size;
+ default:
+ case SHA512: return SHA512_Message_Block_Size;
+ }
+}
+
+/*
+ * USHAHashSize
+ *
+ * Description:
+ * This function will return the hashsize for the given SHA
+ * algorithm.
+ *
+ * Parameters:
+ * whichSha:
+ * which SHA algorithm to query
+ *
+ * Returns:
+ * hash size
+ *
+ */
+int USHAHashSize(enum SHAversion whichSha)
+{
+ switch (whichSha) {
+ case SHA1: return SHA1HashSize;
+ case SHA224: return SHA224HashSize;
+ case SHA256: return SHA256HashSize;
+ case SHA384: return SHA384HashSize;
+ default:
+ case SHA512: return SHA512HashSize;
+ }
+}
+
+
+
+
+Eastlake & Hansen Informational [Page 77]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+/*
+ * USHAHashSizeBits
+ *
+ * Description:
+ * This function will return the hashsize for the given SHA
+ * algorithm, expressed in bits.
+ *
+ * Parameters:
+ * whichSha:
+ * which SHA algorithm to query
+ *
+ * Returns:
+ * hash size in bits
+ *
+ */
+int USHAHashSizeBits(enum SHAversion whichSha)
+{
+ switch (whichSha) {
+ case SHA1: return SHA1HashSizeBits;
+ case SHA224: return SHA224HashSizeBits;
+ case SHA256: return SHA256HashSizeBits;
+ case SHA384: return SHA384HashSizeBits;
+ default:
+ case SHA512: return SHA512HashSizeBits;
+ }
+}
+
+/*
+ * USHAHashName
+ *
+ * Description:
+ * This function will return the name of the given SHA algorithm
+ * as a string.
+ *
+ * Parameters:
+ * whichSha:
+ * which SHA algorithm to query
+ *
+ * Returns:
+ * character string with the name in it
+ *
+ */
+const char *USHAHashName(enum SHAversion whichSha)
+{
+ switch (whichSha) {
+ case SHA1: return "SHA1";
+ case SHA224: return "SHA224";
+ case SHA256: return "SHA256";
+
+
+
+Eastlake & Hansen Informational [Page 78]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+ case SHA384: return "SHA384";
+ default:
+ case SHA512: return "SHA512";
+ }
+}
+
+8.3. The HMAC Code
+
+/**************************** hmac.c ***************************/
+/***************** See RFC 6234 for details. *******************/
+/* Copyright (c) 2011 IETF Trust and the persons identified as */
+/* authors of the code. All rights reserved. */
+/* See sha.h for terms of use and redistribution. */
+
+/*
+ * Description:
+ * This file implements the HMAC algorithm (Keyed-Hashing for
+ * Message Authentication, [RFC 2104]), expressed in terms of
+ * the various SHA algorithms.
+ */
+
+#include "sha.h"
+
+/*
+ * hmac
+ *
+ * Description:
+ * This function will compute an HMAC message digest.
+ *
+ * Parameters:
+ * whichSha: [in]
+ * One of SHA1, SHA224, SHA256, SHA384, SHA512
+ * message_array[ ]: [in]
+ * An array of octets representing the message.
+ * Note: in RFC 2104, this parameter is known
+ * as 'text'.
+ * length: [in]
+ * The length of the message in message_array.
+ * key[ ]: [in]
+ * The secret shared key.
+ * key_len: [in]
+ * The length of the secret shared key.
+ * digest[ ]: [out]
+ * Where the digest is to be returned.
+ * NOTE: The length of the digest is determined by
+ * the value of whichSha.
+ *
+
+
+
+
+Eastlake & Hansen Informational [Page 79]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+ * Returns:
+ * sha Error Code.
+ *
+ */
+
+int hmac(SHAversion whichSha,
+ const unsigned char *message_array, int length,
+ const unsigned char *key, int key_len,
+ uint8_t digest[USHAMaxHashSize])
+{
+ HMACContext context;
+ return hmacReset(&context, whichSha, key, key_len) ||
+ hmacInput(&context, message_array, length) ||
+ hmacResult(&context, digest);
+}
+
+/*
+ * hmacReset
+ *
+ * Description:
+ * This function will initialize the hmacContext in preparation
+ * for computing a new HMAC message digest.
+ *
+ * Parameters:
+ * context: [in/out]
+ * The context to reset.
+ * whichSha: [in]
+ * One of SHA1, SHA224, SHA256, SHA384, SHA512
+ * key[ ]: [in]
+ * The secret shared key.
+ * key_len: [in]
+ * The length of the secret shared key.
+ *
+ * Returns:
+ * sha Error Code.
+ *
+ */
+int hmacReset(HMACContext *context, enum SHAversion whichSha,
+ const unsigned char *key, int key_len)
+{
+ int i, blocksize, hashsize, ret;
+
+ /* inner padding - key XORd with ipad */
+ unsigned char k_ipad[USHA_Max_Message_Block_Size];
+
+ /* temporary buffer when keylen > blocksize */
+ unsigned char tempkey[USHAMaxHashSize];
+
+
+
+
+Eastlake & Hansen Informational [Page 80]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+ if (!context) return shaNull;
+ context->Computed = 0;
+ context->Corrupted = shaSuccess;
+
+ blocksize = context->blockSize = USHABlockSize(whichSha);
+ hashsize = context->hashSize = USHAHashSize(whichSha);
+ context->whichSha = whichSha;
+
+ /*
+ * If key is longer than the hash blocksize,
+ * reset it to key = HASH(key).
+ */
+ if (key_len > blocksize) {
+ USHAContext tcontext;
+ int err = USHAReset(&tcontext, whichSha) ||
+ USHAInput(&tcontext, key, key_len) ||
+ USHAResult(&tcontext, tempkey);
+ if (err != shaSuccess) return err;
+
+ key = tempkey;
+ key_len = hashsize;
+ }
+
+ /*
+ * The HMAC transform looks like:
+ *
+ * SHA(K XOR opad, SHA(K XOR ipad, text))
+ *
+ * where K is an n byte key, 0-padded to a total of blocksize bytes,
+ * ipad is the byte 0x36 repeated blocksize times,
+ * opad is the byte 0x5c repeated blocksize times,
+ * and text is the data being protected.
+ */
+
+ /* store key into the pads, XOR'd with ipad and opad values */
+ for (i = 0; i < key_len; i++) {
+ k_ipad[i] = key[i] ^ 0x36;
+ context->k_opad[i] = key[i] ^ 0x5c;
+ }
+ /* remaining pad bytes are '\0' XOR'd with ipad and opad values */
+ for ( ; i < blocksize; i++) {
+ k_ipad[i] = 0x36;
+ context->k_opad[i] = 0x5c;
+ }
+
+ /* perform inner hash */
+ /* init context for 1st pass */
+ ret = USHAReset(&context->shaContext, whichSha) ||
+
+
+
+Eastlake & Hansen Informational [Page 81]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+ /* and start with inner pad */
+ USHAInput(&context->shaContext, k_ipad, blocksize);
+ return context->Corrupted = ret;
+}
+
+/*
+ * hmacInput
+ *
+ * Description:
+ * This function accepts an array of octets as the next portion
+ * of the message. It may be called multiple times.
+ *
+ * Parameters:
+ * context: [in/out]
+ * The HMAC context to update.
+ * text[ ]: [in]
+ * An array of octets representing the next portion of
+ * the message.
+ * text_len: [in]
+ * The length of the message in text.
+ *
+ * Returns:
+ * sha Error Code.
+ *
+ */
+int hmacInput(HMACContext *context, const unsigned char *text,
+ int text_len)
+{
+ if (!context) return shaNull;
+ if (context->Corrupted) return context->Corrupted;
+ if (context->Computed) return context->Corrupted = shaStateError;
+ /* then text of datagram */
+ return context->Corrupted =
+ USHAInput(&context->shaContext, text, text_len);
+}
+
+/*
+ * hmacFinalBits
+ *
+ * Description:
+ * This function will add in any final bits of the message.
+ *
+ * Parameters:
+ * context: [in/out]
+ * The HMAC context to update.
+ * message_bits: [in]
+ * The final bits of the message, in the upper portion of the
+ * byte. (Use 0b###00000 instead of 0b00000### to input the
+
+
+
+Eastlake & Hansen Informational [Page 82]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+ * three bits ###.)
+ * length: [in]
+ * The number of bits in message_bits, between 1 and 7.
+ *
+ * Returns:
+ * sha Error Code.
+ */
+int hmacFinalBits(HMACContext *context,
+ uint8_t bits, unsigned int bit_count)
+{
+ if (!context) return shaNull;
+ if (context->Corrupted) return context->Corrupted;
+ if (context->Computed) return context->Corrupted = shaStateError;
+ /* then final bits of datagram */
+ return context->Corrupted =
+ USHAFinalBits(&context->shaContext, bits, bit_count);
+}
+
+/*
+ * hmacResult
+ *
+ * Description:
+ * This function will return the N-byte message digest into the
+ * Message_Digest array provided by the caller.
+ *
+ * Parameters:
+ * context: [in/out]
+ * The context to use to calculate the HMAC hash.
+ * digest[ ]: [out]
+ * Where the digest is returned.
+ * NOTE 2: The length of the hash is determined by the value of
+ * whichSha that was passed to hmacReset().
+ *
+ * Returns:
+ * sha Error Code.
+ *
+ */
+int hmacResult(HMACContext *context, uint8_t *digest)
+{
+ int ret;
+ if (!context) return shaNull;
+ if (context->Corrupted) return context->Corrupted;
+ if (context->Computed) return context->Corrupted = shaStateError;
+
+ /* finish up 1st pass */
+ /* (Use digest here as a temporary buffer.) */
+ ret =
+ USHAResult(&context->shaContext, digest) ||
+
+
+
+Eastlake & Hansen Informational [Page 83]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+ /* perform outer SHA */
+ /* init context for 2nd pass */
+ USHAReset(&context->shaContext, context->whichSha) ||
+
+ /* start with outer pad */
+ USHAInput(&context->shaContext, context->k_opad,
+ context->blockSize) ||
+
+ /* then results of 1st hash */
+ USHAInput(&context->shaContext, digest, context->hashSize) ||
+ /* finish up 2nd pass */
+ USHAResult(&context->shaContext, digest);
+
+ context->Computed = 1;
+ return context->Corrupted = ret;
+}
+
+8.4. The HKDF Code
+
+/**************************** hkdf.c ***************************/
+/***************** See RFC 6234 for details. *******************/
+/* Copyright (c) 2011 IETF Trust and the persons identified as */
+/* authors of the code. All rights reserved. */
+/* See sha.h for terms of use and redistribution. */
+
+/*
+ * Description:
+ * This file implements the HKDF algorithm (HMAC-based
+ * Extract-and-Expand Key Derivation Function, RFC 5869),
+ * expressed in terms of the various SHA algorithms.
+ */
+
+#include "sha.h"
+#include <string.h>
+#include <stdlib.h>
+
+/*
+ * hkdf
+ *
+ * Description:
+ * This function will generate keying material using HKDF.
+ *
+ * Parameters:
+ * whichSha: [in]
+ * One of SHA1, SHA224, SHA256, SHA384, SHA512
+ * salt[ ]: [in]
+ * The optional salt value (a non-secret random value);
+ * if not provided (salt == NULL), it is set internally
+
+
+
+Eastlake & Hansen Informational [Page 84]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+ * to a string of HashLen(whichSha) zeros.
+ * salt_len: [in]
+ * The length of the salt value. (Ignored if salt == NULL.)
+ * ikm[ ]: [in]
+ * Input keying material.
+ * ikm_len: [in]
+ * The length of the input keying material.
+ * info[ ]: [in]
+ * The optional context and application specific information.
+ * If info == NULL or a zero-length string, it is ignored.
+ * info_len: [in]
+ * The length of the optional context and application specific
+ * information. (Ignored if info == NULL.)
+ * okm[ ]: [out]
+ * Where the HKDF is to be stored.
+ * okm_len: [in]
+ * The length of the buffer to hold okm.
+ * okm_len must be <= 255 * USHABlockSize(whichSha)
+ *
+ * Notes:
+ * Calls hkdfExtract() and hkdfExpand().
+ *
+ * Returns:
+ * sha Error Code.
+ *
+ */
+int hkdf(SHAversion whichSha,
+ const unsigned char *salt, int salt_len,
+ const unsigned char *ikm, int ikm_len,
+ const unsigned char *info, int info_len,
+ uint8_t okm[ ], int okm_len)
+{
+ uint8_t prk[USHAMaxHashSize];
+ return hkdfExtract(whichSha, salt, salt_len, ikm, ikm_len, prk) ||
+ hkdfExpand(whichSha, prk, USHAHashSize(whichSha), info,
+ info_len, okm, okm_len);
+}
+
+/*
+ * hkdfExtract
+ *
+ * Description:
+ * This function will perform HKDF extraction.
+ *
+ * Parameters:
+ * whichSha: [in]
+ * One of SHA1, SHA224, SHA256, SHA384, SHA512
+ * salt[ ]: [in]
+
+
+
+Eastlake & Hansen Informational [Page 85]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+ * The optional salt value (a non-secret random value);
+ * if not provided (salt == NULL), it is set internally
+ * to a string of HashLen(whichSha) zeros.
+ * salt_len: [in]
+ * The length of the salt value. (Ignored if salt == NULL.)
+ * ikm[ ]: [in]
+ * Input keying material.
+ * ikm_len: [in]
+ * The length of the input keying material.
+ * prk[ ]: [out]
+ * Array where the HKDF extraction is to be stored.
+ * Must be larger than USHAHashSize(whichSha);
+ *
+ * Returns:
+ * sha Error Code.
+ *
+ */
+int hkdfExtract(SHAversion whichSha,
+ const unsigned char *salt, int salt_len,
+ const unsigned char *ikm, int ikm_len,
+ uint8_t prk[USHAMaxHashSize])
+{
+ unsigned char nullSalt[USHAMaxHashSize];
+ if (salt == 0) {
+ salt = nullSalt;
+ salt_len = USHAHashSize(whichSha);
+ memset(nullSalt, '\0', salt_len);
+ } else if (salt_len < 0) {
+ return shaBadParam;
+ }
+ return hmac(whichSha, ikm, ikm_len, salt, salt_len, prk);
+}
+
+/*
+ * hkdfExpand
+ *
+ * Description:
+ * This function will perform HKDF expansion.
+ *
+ * Parameters:
+ * whichSha: [in]
+ * One of SHA1, SHA224, SHA256, SHA384, SHA512
+ * prk[ ]: [in]
+ * The pseudo-random key to be expanded; either obtained
+ * directly from a cryptographically strong, uniformly
+ * distributed pseudo-random number generator, or as the
+ * output from hkdfExtract().
+ * prk_len: [in]
+
+
+
+Eastlake & Hansen Informational [Page 86]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+ * The length of the pseudo-random key in prk;
+ * should at least be equal to USHAHashSize(whichSHA).
+ * info[ ]: [in]
+ * The optional context and application specific information.
+ * If info == NULL or a zero-length string, it is ignored.
+ * info_len: [in]
+ * The length of the optional context and application specific
+ * information. (Ignored if info == NULL.)
+ * okm[ ]: [out]
+ * Where the HKDF is to be stored.
+ * okm_len: [in]
+ * The length of the buffer to hold okm.
+ * okm_len must be <= 255 * USHABlockSize(whichSha)
+ *
+ * Returns:
+ * sha Error Code.
+ *
+ */
+int hkdfExpand(SHAversion whichSha, const uint8_t prk[ ], int prk_len,
+ const unsigned char *info, int info_len,
+ uint8_t okm[ ], int okm_len)
+{
+ int hash_len, N;
+ unsigned char T[USHAMaxHashSize];
+ int Tlen, where, i;
+
+ if (info == 0) {
+ info = (const unsigned char *)"";
+ info_len = 0;
+ } else if (info_len < 0) {
+ return shaBadParam;
+ }
+ if (okm_len <= 0) return shaBadParam;
+ if (!okm) return shaBadParam;
+
+ hash_len = USHAHashSize(whichSha);
+ if (prk_len < hash_len) return shaBadParam;
+ N = okm_len / hash_len;
+ if ((okm_len % hash_len) != 0) N++;
+ if (N > 255) return shaBadParam;
+
+ Tlen = 0;
+ where = 0;
+ for (i = 1; i <= N; i++) {
+ HMACContext context;
+ unsigned char c = i;
+ int ret = hmacReset(&context, whichSha, prk, prk_len) ||
+ hmacInput(&context, T, Tlen) ||
+
+
+
+Eastlake & Hansen Informational [Page 87]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+ hmacInput(&context, info, info_len) ||
+ hmacInput(&context, &c, 1) ||
+ hmacResult(&context, T);
+ if (ret != shaSuccess) return ret;
+ memcpy(okm + where, T,
+ (i != N) ? hash_len : (okm_len - where));
+ where += hash_len;
+ Tlen = hash_len;
+ }
+ return shaSuccess;
+}
+
+/*
+ * hkdfReset
+ *
+ * Description:
+ * This function will initialize the hkdfContext in preparation
+ * for key derivation using the modular HKDF interface for
+ * arbitrary length inputs.
+ *
+ * Parameters:
+ * context: [in/out]
+ * The context to reset.
+ * whichSha: [in]
+ * One of SHA1, SHA224, SHA256, SHA384, SHA512
+ * salt[ ]: [in]
+ * The optional salt value (a non-secret random value);
+ * if not provided (salt == NULL), it is set internally
+ * to a string of HashLen(whichSha) zeros.
+ * salt_len: [in]
+ * The length of the salt value. (Ignored if salt == NULL.)
+ *
+ * Returns:
+ * sha Error Code.
+ *
+ */
+int hkdfReset(HKDFContext *context, enum SHAversion whichSha,
+ const unsigned char *salt, int salt_len)
+{
+ unsigned char nullSalt[USHAMaxHashSize];
+ if (!context) return shaNull;
+
+ context->whichSha = whichSha;
+ context->hashSize = USHAHashSize(whichSha);
+ if (salt == 0) {
+ salt = nullSalt;
+ salt_len = context->hashSize;
+ memset(nullSalt, '\0', salt_len);
+
+
+
+Eastlake & Hansen Informational [Page 88]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+ }
+
+ return hmacReset(&context->hmacContext, whichSha, salt, salt_len);
+}
+
+/*
+ * hkdfInput
+ *
+ * Description:
+ * This function accepts an array of octets as the next portion
+ * of the input keying material. It may be called multiple times.
+ *
+ * Parameters:
+ * context: [in/out]
+ * The HKDF context to update.
+ * ikm[ ]: [in]
+ * An array of octets representing the next portion of
+ * the input keying material.
+ * ikm_len: [in]
+ * The length of ikm.
+ *
+ * Returns:
+ * sha Error Code.
+ *
+ */
+int hkdfInput(HKDFContext *context, const unsigned char *ikm,
+ int ikm_len)
+{
+ if (!context) return shaNull;
+ if (context->Corrupted) return context->Corrupted;
+ if (context->Computed) return context->Corrupted = shaStateError;
+ return hmacInput(&context->hmacContext, ikm, ikm_len);
+}
+
+/*
+ * hkdfFinalBits
+ *
+ * Description:
+ * This function will add in any final bits of the
+ * input keying material.
+ *
+ * Parameters:
+ * context: [in/out]
+ * The HKDF context to update
+ * ikm_bits: [in]
+ * The final bits of the input keying material, in the upper
+ * portion of the byte. (Use 0b###00000 instead of 0b00000###
+ * to input the three bits ###.)
+
+
+
+Eastlake & Hansen Informational [Page 89]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+ * ikm_bit_count: [in]
+ * The number of bits in message_bits, between 1 and 7.
+ *
+ * Returns:
+ * sha Error Code.
+ */
+int hkdfFinalBits(HKDFContext *context, uint8_t ikm_bits,
+ unsigned int ikm_bit_count)
+{
+ if (!context) return shaNull;
+ if (context->Corrupted) return context->Corrupted;
+ if (context->Computed) return context->Corrupted = shaStateError;
+ return hmacFinalBits(&context->hmacContext, ikm_bits, ikm_bit_count);
+}
+
+/*
+ * hkdfResult
+ *
+ * Description:
+ * This function will finish the HKDF extraction and perform the
+ * final HKDF expansion.
+ *
+ * Parameters:
+ * context: [in/out]
+ * The HKDF context to use to calculate the HKDF hash.
+ * prk[ ]: [out]
+ * An optional location to store the HKDF extraction.
+ * Either NULL, or pointer to a buffer that must be
+ * larger than USHAHashSize(whichSha);
+ * info[ ]: [in]
+ * The optional context and application specific information.
+ * If info == NULL or a zero-length string, it is ignored.
+ * info_len: [in]
+ * The length of the optional context and application specific
+ * information. (Ignored if info == NULL.)
+ * okm[ ]: [out]
+ * Where the HKDF is to be stored.
+ * okm_len: [in]
+ * The length of the buffer to hold okm.
+ * okm_len must be <= 255 * USHABlockSize(whichSha)
+ *
+ * Returns:
+ * sha Error Code.
+ *
+ */
+int hkdfResult(HKDFContext *context,
+ uint8_t prk[USHAMaxHashSize],
+ const unsigned char *info, int info_len,
+
+
+
+Eastlake & Hansen Informational [Page 90]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+ uint8_t okm[ ], int okm_len)
+{
+ uint8_t prkbuf[USHAMaxHashSize];
+ int ret;
+
+ if (!context) return shaNull;
+ if (context->Corrupted) return context->Corrupted;
+ if (context->Computed) return context->Corrupted = shaStateError;
+ if (!okm) return context->Corrupted = shaBadParam;
+ if (!prk) prk = prkbuf;
+
+ ret = hmacResult(&context->hmacContext, prk) ||
+ hkdfExpand(context->whichSha, prk, context->hashSize, info,
+ info_len, okm, okm_len);
+ context->Computed = 1;
+ return context->Corrupted = ret;
+}
+
+8.5. The Test Driver
+
+ The following code is a main program test driver to exercise the code
+ in sha1.c, sha224-256.c, sha384-512.c, hmac.c, and hkdf.c. The test
+ driver can also be used as a standalone program for generating the
+ hashes. Note that the tests assume that character values are as in
+ [US-ASCII] and a run time check warns if the code appears to have
+ been compiled with some other character system.
+
+ See also [SHAVS].
+
+/************************** shatest.c **************************/
+/***************** See RFC 6234 for details. *******************/
+/* Copyright (c) 2011 IETF Trust and the persons identified as */
+/* authors of the code. All rights reserved. */
+/* See sha.h for terms of use and redistribution. */
+
+/*
+ * Description:
+ * This file will exercise the SHA code performing
+ * the three tests documented in FIPS PUB 180-3
+ * (http://csrc.nist.gov/publications/fips/
+ * fips180-2/fips180-2withchangenotice.pdf)
+ * one that calls SHAInput with an exact multiple of 512 bits
+ * the seven tests documented for each algorithm in
+ * "The Secure Hash Algorithm Validation System (SHAVS)"
+ * (http://csrc.nist.gov/cryptval/shs/SHAVS.pdf),
+ * three of which are bit-level tests
+ *
+
+
+
+
+Eastlake & Hansen Informational [Page 91]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+ * These tests have subsequently been moved to pages linked from
+ * http://csrc.nist.gov/groups/ST/toolkit/examples.html
+ *
+ * This file will exercise the HMAC SHA1 code performing
+ * the seven tests documented in RFCs [RFC 2202] and [RFC 4231].
+ *
+ * This file will exercise the HKDF code performing
+ * the seven tests documented in RFC 4869.
+ *
+ * To run the tests and just see PASSED/FAILED, use the -p option.
+ *
+ * Other options exercise:
+ * hashing an arbitrary string
+ * hashing a file's contents
+ * a few error test checks
+ * printing the results in raw format
+ *
+ * Portability Issues:
+ * None.
+ *
+ */
+
+#include <stdint.h>
+#include <stdio.h>
+#include <stdlib.h>
+#include <string.h>
+#include <ctype.h>
+#include <unistd.h> /* defines getopt() and optarg */
+#include "sha.h"
+
+static int scasecmp(const char *s1, const char *s2);
+
+/*
+ * Define patterns for testing
+ */
+#define TEST1 "abc"
+#define TEST2_1 \
+ "abcdbcdecdefdefgefghfghighijhijkijkljklmklmnlmnomnopnopq"
+#define TEST2_2a \
+ "abcdefghbcdefghicdefghijdefghijkefghijklfghijklmghijklmn"
+#define TEST2_2b \
+ "hijklmnoijklmnopjklmnopqklmnopqrlmnopqrsmnopqrstnopqrstu"
+#define TEST2_2 TEST2_2a TEST2_2b
+#define TEST3 "a" /* times 1000000 */
+#define TEST4a "01234567012345670123456701234567"
+#define TEST4b "01234567012345670123456701234567"
+ /* an exact multiple of 512 bits */
+#define TEST4 TEST4a TEST4b /* times 10 */
+
+
+
+Eastlake & Hansen Informational [Page 92]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+#define TEST7_1 \
+ "\x49\xb2\xae\xc2\x59\x4b\xbe\x3a\x3b\x11\x75\x42\xd9\x4a\xc8"
+#define TEST8_1 \
+ "\x9a\x7d\xfd\xf1\xec\xea\xd0\x6e\xd6\x46\xaa\x55\xfe\x75\x71\x46"
+#define TEST9_1 \
+ "\x65\xf9\x32\x99\x5b\xa4\xce\x2c\xb1\xb4\xa2\xe7\x1a\xe7\x02\x20" \
+ "\xaa\xce\xc8\x96\x2d\xd4\x49\x9c\xbd\x7c\x88\x7a\x94\xea\xaa\x10" \
+ "\x1e\xa5\xaa\xbc\x52\x9b\x4e\x7e\x43\x66\x5a\x5a\xf2\xcd\x03\xfe" \
+ "\x67\x8e\xa6\xa5\x00\x5b\xba\x3b\x08\x22\x04\xc2\x8b\x91\x09\xf4" \
+ "\x69\xda\xc9\x2a\xaa\xb3\xaa\x7c\x11\xa1\xb3\x2a"
+#define TEST10_1 \
+ "\xf7\x8f\x92\x14\x1b\xcd\x17\x0a\xe8\x9b\x4f\xba\x15\xa1\xd5\x9f" \
+ "\x3f\xd8\x4d\x22\x3c\x92\x51\xbd\xac\xbb\xae\x61\xd0\x5e\xd1\x15" \
+ "\xa0\x6a\x7c\xe1\x17\xb7\xbe\xea\xd2\x44\x21\xde\xd9\xc3\x25\x92" \
+ "\xbd\x57\xed\xea\xe3\x9c\x39\xfa\x1f\xe8\x94\x6a\x84\xd0\xcf\x1f" \
+ "\x7b\xee\xad\x17\x13\xe2\xe0\x95\x98\x97\x34\x7f\x67\xc8\x0b\x04" \
+ "\x00\xc2\x09\x81\x5d\x6b\x10\xa6\x83\x83\x6f\xd5\x56\x2a\x56\xca" \
+ "\xb1\xa2\x8e\x81\xb6\x57\x66\x54\x63\x1c\xf1\x65\x66\xb8\x6e\x3b" \
+ "\x33\xa1\x08\xb0\x53\x07\xc0\x0a\xff\x14\xa7\x68\xed\x73\x50\x60" \
+ "\x6a\x0f\x85\xe6\xa9\x1d\x39\x6f\x5b\x5c\xbe\x57\x7f\x9b\x38\x80" \
+ "\x7c\x7d\x52\x3d\x6d\x79\x2f\x6e\xbc\x24\xa4\xec\xf2\xb3\xa4\x27" \
+ "\xcd\xbb\xfb"
+#define TEST7_224 \
+ "\xf0\x70\x06\xf2\x5a\x0b\xea\x68\xcd\x76\xa2\x95\x87\xc2\x8d"
+#define TEST8_224 \
+ "\x18\x80\x40\x05\xdd\x4f\xbd\x15\x56\x29\x9d\x6f\x9d\x93\xdf\x62"
+#define TEST9_224 \
+ "\xa2\xbe\x6e\x46\x32\x81\x09\x02\x94\xd9\xce\x94\x82\x65\x69\x42" \
+ "\x3a\x3a\x30\x5e\xd5\xe2\x11\x6c\xd4\xa4\xc9\x87\xfc\x06\x57\x00" \
+ "\x64\x91\xb1\x49\xcc\xd4\xb5\x11\x30\xac\x62\xb1\x9d\xc2\x48\xc7" \
+ "\x44\x54\x3d\x20\xcd\x39\x52\xdc\xed\x1f\x06\xcc\x3b\x18\xb9\x1f" \
+ "\x3f\x55\x63\x3e\xcc\x30\x85\xf4\x90\x70\x60\xd2"
+#define TEST10_224 \
+ "\x55\xb2\x10\x07\x9c\x61\xb5\x3a\xdd\x52\x06\x22\xd1\xac\x97\xd5" \
+ "\xcd\xbe\x8c\xb3\x3a\xa0\xae\x34\x45\x17\xbe\xe4\xd7\xba\x09\xab" \
+ "\xc8\x53\x3c\x52\x50\x88\x7a\x43\xbe\xbb\xac\x90\x6c\x2e\x18\x37" \
+ "\xf2\x6b\x36\xa5\x9a\xe3\xbe\x78\x14\xd5\x06\x89\x6b\x71\x8b\x2a" \
+ "\x38\x3e\xcd\xac\x16\xb9\x61\x25\x55\x3f\x41\x6f\xf3\x2c\x66\x74" \
+ "\xc7\x45\x99\xa9\x00\x53\x86\xd9\xce\x11\x12\x24\x5f\x48\xee\x47" \
+ "\x0d\x39\x6c\x1e\xd6\x3b\x92\x67\x0c\xa5\x6e\xc8\x4d\xee\xa8\x14" \
+ "\xb6\x13\x5e\xca\x54\x39\x2b\xde\xdb\x94\x89\xbc\x9b\x87\x5a\x8b" \
+ "\xaf\x0d\xc1\xae\x78\x57\x36\x91\x4a\xb7\xda\xa2\x64\xbc\x07\x9d" \
+ "\x26\x9f\x2c\x0d\x7e\xdd\xd8\x10\xa4\x26\x14\x5a\x07\x76\xf6\x7c" \
+ "\x87\x82\x73"
+#define TEST7_256 \
+ "\xbe\x27\x46\xc6\xdb\x52\x76\x5f\xdb\x2f\x88\x70\x0f\x9a\x73"
+#define TEST8_256 \
+ "\xe3\xd7\x25\x70\xdc\xdd\x78\x7c\xe3\x88\x7a\xb2\xcd\x68\x46\x52"
+
+
+
+Eastlake & Hansen Informational [Page 93]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+#define TEST9_256 \
+ "\x3e\x74\x03\x71\xc8\x10\xc2\xb9\x9f\xc0\x4e\x80\x49\x07\xef\x7c" \
+ "\xf2\x6b\xe2\x8b\x57\xcb\x58\xa3\xe2\xf3\xc0\x07\x16\x6e\x49\xc1" \
+ "\x2e\x9b\xa3\x4c\x01\x04\x06\x91\x29\xea\x76\x15\x64\x25\x45\x70" \
+ "\x3a\x2b\xd9\x01\xe1\x6e\xb0\xe0\x5d\xeb\xa0\x14\xeb\xff\x64\x06" \
+ "\xa0\x7d\x54\x36\x4e\xff\x74\x2d\xa7\x79\xb0\xb3"
+#define TEST10_256 \
+ "\x83\x26\x75\x4e\x22\x77\x37\x2f\x4f\xc1\x2b\x20\x52\x7a\xfe\xf0" \
+ "\x4d\x8a\x05\x69\x71\xb1\x1a\xd5\x71\x23\xa7\xc1\x37\x76\x00\x00" \
+ "\xd7\xbe\xf6\xf3\xc1\xf7\xa9\x08\x3a\xa3\x9d\x81\x0d\xb3\x10\x77" \
+ "\x7d\xab\x8b\x1e\x7f\x02\xb8\x4a\x26\xc7\x73\x32\x5f\x8b\x23\x74" \
+ "\xde\x7a\x4b\x5a\x58\xcb\x5c\x5c\xf3\x5b\xce\xe6\xfb\x94\x6e\x5b" \
+ "\xd6\x94\xfa\x59\x3a\x8b\xeb\x3f\x9d\x65\x92\xec\xed\xaa\x66\xca" \
+ "\x82\xa2\x9d\x0c\x51\xbc\xf9\x33\x62\x30\xe5\xd7\x84\xe4\xc0\xa4" \
+ "\x3f\x8d\x79\xa3\x0a\x16\x5c\xba\xbe\x45\x2b\x77\x4b\x9c\x71\x09" \
+ "\xa9\x7d\x13\x8f\x12\x92\x28\x96\x6f\x6c\x0a\xdc\x10\x6a\xad\x5a" \
+ "\x9f\xdd\x30\x82\x57\x69\xb2\xc6\x71\xaf\x67\x59\xdf\x28\xeb\x39" \
+ "\x3d\x54\xd6"
+#define TEST7_384 \
+ "\x8b\xc5\x00\xc7\x7c\xee\xd9\x87\x9d\xa9\x89\x10\x7c\xe0\xaa"
+#define TEST8_384 \
+ "\xa4\x1c\x49\x77\x79\xc0\x37\x5f\xf1\x0a\x7f\x4e\x08\x59\x17\x39"
+#define TEST9_384 \
+ "\x68\xf5\x01\x79\x2d\xea\x97\x96\x76\x70\x22\xd9\x3d\xa7\x16\x79" \
+ "\x30\x99\x20\xfa\x10\x12\xae\xa3\x57\xb2\xb1\x33\x1d\x40\xa1\xd0" \
+ "\x3c\x41\xc2\x40\xb3\xc9\xa7\x5b\x48\x92\xf4\xc0\x72\x4b\x68\xc8" \
+ "\x75\x32\x1a\xb8\xcf\xe5\x02\x3b\xd3\x75\xbc\x0f\x94\xbd\x89\xfe" \
+ "\x04\xf2\x97\x10\x5d\x7b\x82\xff\xc0\x02\x1a\xeb\x1c\xcb\x67\x4f" \
+ "\x52\x44\xea\x34\x97\xde\x26\xa4\x19\x1c\x5f\x62\xe5\xe9\xa2\xd8" \
+ "\x08\x2f\x05\x51\xf4\xa5\x30\x68\x26\xe9\x1c\xc0\x06\xce\x1b\xf6" \
+ "\x0f\xf7\x19\xd4\x2f\xa5\x21\xc8\x71\xcd\x23\x94\xd9\x6e\xf4\x46" \
+ "\x8f\x21\x96\x6b\x41\xf2\xba\x80\xc2\x6e\x83\xa9"
+#define TEST10_384 \
+ "\x39\x96\x69\xe2\x8f\x6b\x9c\x6d\xbc\xbb\x69\x12\xec\x10\xff\xcf" \
+ "\x74\x79\x03\x49\xb7\xdc\x8f\xbe\x4a\x8e\x7b\x3b\x56\x21\xdb\x0f" \
+ "\x3e\x7d\xc8\x7f\x82\x32\x64\xbb\xe4\x0d\x18\x11\xc9\xea\x20\x61" \
+ "\xe1\xc8\x4a\xd1\x0a\x23\xfa\xc1\x72\x7e\x72\x02\xfc\x3f\x50\x42" \
+ "\xe6\xbf\x58\xcb\xa8\xa2\x74\x6e\x1f\x64\xf9\xb9\xea\x35\x2c\x71" \
+ "\x15\x07\x05\x3c\xf4\xe5\x33\x9d\x52\x86\x5f\x25\xcc\x22\xb5\xe8" \
+ "\x77\x84\xa1\x2f\xc9\x61\xd6\x6c\xb6\xe8\x95\x73\x19\x9a\x2c\xe6" \
+ "\x56\x5c\xbd\xf1\x3d\xca\x40\x38\x32\xcf\xcb\x0e\x8b\x72\x11\xe8" \
+ "\x3a\xf3\x2a\x11\xac\x17\x92\x9f\xf1\xc0\x73\xa5\x1c\xc0\x27\xaa" \
+ "\xed\xef\xf8\x5a\xad\x7c\x2b\x7c\x5a\x80\x3e\x24\x04\xd9\x6d\x2a" \
+ "\x77\x35\x7b\xda\x1a\x6d\xae\xed\x17\x15\x1c\xb9\xbc\x51\x25\xa4" \
+ "\x22\xe9\x41\xde\x0c\xa0\xfc\x50\x11\xc2\x3e\xcf\xfe\xfd\xd0\x96" \
+ "\x76\x71\x1c\xf3\xdb\x0a\x34\x40\x72\x0e\x16\x15\xc1\xf2\x2f\xbc" \
+ "\x3c\x72\x1d\xe5\x21\xe1\xb9\x9b\xa1\xbd\x55\x77\x40\x86\x42\x14" \
+ "\x7e\xd0\x96"
+
+
+
+Eastlake & Hansen Informational [Page 94]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+#define TEST7_512 \
+ "\x08\xec\xb5\x2e\xba\xe1\xf7\x42\x2d\xb6\x2b\xcd\x54\x26\x70"
+#define TEST8_512 \
+ "\x8d\x4e\x3c\x0e\x38\x89\x19\x14\x91\x81\x6e\x9d\x98\xbf\xf0\xa0"
+#define TEST9_512 \
+ "\x3a\xdd\xec\x85\x59\x32\x16\xd1\x61\x9a\xa0\x2d\x97\x56\x97\x0b" \
+ "\xfc\x70\xac\xe2\x74\x4f\x7c\x6b\x27\x88\x15\x10\x28\xf7\xb6\xa2" \
+ "\x55\x0f\xd7\x4a\x7e\x6e\x69\xc2\xc9\xb4\x5f\xc4\x54\x96\x6d\xc3" \
+ "\x1d\x2e\x10\xda\x1f\x95\xce\x02\xbe\xb4\xbf\x87\x65\x57\x4c\xbd" \
+ "\x6e\x83\x37\xef\x42\x0a\xdc\x98\xc1\x5c\xb6\xd5\xe4\xa0\x24\x1b" \
+ "\xa0\x04\x6d\x25\x0e\x51\x02\x31\xca\xc2\x04\x6c\x99\x16\x06\xab" \
+ "\x4e\xe4\x14\x5b\xee\x2f\xf4\xbb\x12\x3a\xab\x49\x8d\x9d\x44\x79" \
+ "\x4f\x99\xcc\xad\x89\xa9\xa1\x62\x12\x59\xed\xa7\x0a\x5b\x6d\xd4" \
+ "\xbd\xd8\x77\x78\xc9\x04\x3b\x93\x84\xf5\x49\x06"
+#define TEST10_512 \
+ "\xa5\x5f\x20\xc4\x11\xaa\xd1\x32\x80\x7a\x50\x2d\x65\x82\x4e\x31" \
+ "\xa2\x30\x54\x32\xaa\x3d\x06\xd3\xe2\x82\xa8\xd8\x4e\x0d\xe1\xde" \
+ "\x69\x74\xbf\x49\x54\x69\xfc\x7f\x33\x8f\x80\x54\xd5\x8c\x26\xc4" \
+ "\x93\x60\xc3\xe8\x7a\xf5\x65\x23\xac\xf6\xd8\x9d\x03\xe5\x6f\xf2" \
+ "\xf8\x68\x00\x2b\xc3\xe4\x31\xed\xc4\x4d\xf2\xf0\x22\x3d\x4b\xb3" \
+ "\xb2\x43\x58\x6e\x1a\x7d\x92\x49\x36\x69\x4f\xcb\xba\xf8\x8d\x95" \
+ "\x19\xe4\xeb\x50\xa6\x44\xf8\xe4\xf9\x5e\xb0\xea\x95\xbc\x44\x65" \
+ "\xc8\x82\x1a\xac\xd2\xfe\x15\xab\x49\x81\x16\x4b\xbb\x6d\xc3\x2f" \
+ "\x96\x90\x87\xa1\x45\xb0\xd9\xcc\x9c\x67\xc2\x2b\x76\x32\x99\x41" \
+ "\x9c\xc4\x12\x8b\xe9\xa0\x77\xb3\xac\xe6\x34\x06\x4e\x6d\x99\x28" \
+ "\x35\x13\xdc\x06\xe7\x51\x5d\x0d\x73\x13\x2e\x9a\x0d\xc6\xd3\xb1" \
+ "\xf8\xb2\x46\xf1\xa9\x8a\x3f\xc7\x29\x41\xb1\xe3\xbb\x20\x98\xe8" \
+ "\xbf\x16\xf2\x68\xd6\x4f\x0b\x0f\x47\x07\xfe\x1e\xa1\xa1\x79\x1b" \
+ "\xa2\xf3\xc0\xc7\x58\xe5\xf5\x51\x86\x3a\x96\xc9\x49\xad\x47\xd7" \
+ "\xfb\x40\xd2"
+#define SHA1_SEED "\xd0\x56\x9c\xb3\x66\x5a\x8a\x43\xeb\x6e\xa2\x3d" \
+ "\x75\xa3\xc4\xd2\x05\x4a\x0d\x7d"
+#define SHA224_SEED "\xd0\x56\x9c\xb3\x66\x5a\x8a\x43\xeb\x6e\xa2" \
+ "\x3d\x75\xa3\xc4\xd2\x05\x4a\x0d\x7d\x66\xa9\xca\x99\xc9\xce\xb0" \
+ "\x27"
+#define SHA256_SEED "\xf4\x1e\xce\x26\x13\xe4\x57\x39\x15\x69\x6b" \
+ "\x5a\xdc\xd5\x1c\xa3\x28\xbe\x3b\xf5\x66\xa9\xca\x99\xc9\xce\xb0" \
+ "\x27\x9c\x1c\xb0\xa7"
+#define SHA384_SEED "\x82\x40\xbc\x51\xe4\xec\x7e\xf7\x6d\x18\xe3" \
+ "\x52\x04\xa1\x9f\x51\xa5\x21\x3a\x73\xa8\x1d\x6f\x94\x46\x80\xd3" \
+ "\x07\x59\x48\xb7\xe4\x63\x80\x4e\xa3\xd2\x6e\x13\xea\x82\x0d\x65" \
+ "\xa4\x84\xbe\x74\x53"
+#define SHA512_SEED "\x47\x3f\xf1\xb9\xb3\xff\xdf\xa1\x26\x69\x9a" \
+ "\xc7\xef\x9e\x8e\x78\x77\x73\x09\x58\x24\xc6\x42\x55\x7c\x13\x99" \
+ "\xd9\x8e\x42\x20\x44\x8d\xc3\x5b\x99\xbf\xdd\x44\x77\x95\x43\x92" \
+ "\x4c\x1c\xe9\x3b\xc5\x94\x15\x38\x89\x5d\xb9\x88\x26\x1b\x00\x77" \
+ "\x4b\x12\x27\x20\x39"
+
+
+
+
+Eastlake & Hansen Informational [Page 95]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+#define TESTCOUNT 10
+#define HASHCOUNT 5
+#define RANDOMCOUNT 4
+#define HMACTESTCOUNT 7
+#define HKDFTESTCOUNT 7
+
+#define PRINTNONE 0
+#define PRINTTEXT 1
+#define PRINTRAW 2
+#define PRINTHEX 3
+#define PRINTBASE64 4
+
+#define PRINTPASSFAIL 1
+#define PRINTFAIL 2
+
+#define length(x) (sizeof(x)-1)
+
+/* Test arrays for hashes. */
+struct hash {
+ const char *name;
+ SHAversion whichSha;
+ int hashsize;
+ struct {
+ const char *testarray;
+ int length;
+ long repeatcount;
+ int extrabits;
+ int numberExtrabits;
+ const char *resultarray;
+ } tests[TESTCOUNT];
+ const char *randomtest;
+ const char *randomresults[RANDOMCOUNT];
+} hashes[HASHCOUNT] = {
+ { "SHA1", SHA1, SHA1HashSize,
+ {
+ /* 1 */ { TEST1, length(TEST1), 1, 0, 0,
+ "A9993E364706816ABA3E25717850C26C9CD0D89D" },
+ /* 2 */ { TEST2_1, length(TEST2_1), 1, 0, 0,
+ "84983E441C3BD26EBAAE4AA1F95129E5E54670F1" },
+ /* 3 */ { TEST3, length(TEST3), 1000000, 0, 0,
+ "34AA973CD4C4DAA4F61EEB2BDBAD27316534016F" },
+ /* 4 */ { TEST4, length(TEST4), 10, 0, 0,
+ "DEA356A2CDDD90C7A7ECEDC5EBB563934F460452" },
+ /* 5 */ { "", 0, 0, 0x98, 5,
+ "29826B003B906E660EFF4027CE98AF3531AC75BA" },
+ /* 6 */ { "\x5e", 1, 1, 0, 0,
+ "5E6F80A34A9798CAFC6A5DB96CC57BA4C4DB59C2" },
+ /* 7 */ { TEST7_1, length(TEST7_1), 1, 0x80, 3,
+
+
+
+Eastlake & Hansen Informational [Page 96]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+ "6239781E03729919C01955B3FFA8ACB60B988340" },
+ /* 8 */ { TEST8_1, length(TEST8_1), 1, 0, 0,
+ "82ABFF6605DBE1C17DEF12A394FA22A82B544A35" },
+ /* 9 */ { TEST9_1, length(TEST9_1), 1, 0xE0, 3,
+ "8C5B2A5DDAE5A97FC7F9D85661C672ADBF7933D4" },
+ /* 10 */ { TEST10_1, length(TEST10_1), 1, 0, 0,
+ "CB0082C8F197D260991BA6A460E76E202BAD27B3" }
+ }, SHA1_SEED, { "E216836819477C7F78E0D843FE4FF1B6D6C14CD4",
+ "A2DBC7A5B1C6C0A8BCB7AAA41252A6A7D0690DBC",
+ "DB1F9050BB863DFEF4CE37186044E2EEB17EE013",
+ "127FDEDF43D372A51D5747C48FBFFE38EF6CDF7B"
+ } },
+ { "SHA224", SHA224, SHA224HashSize,
+ {
+ /* 1 */ { TEST1, length(TEST1), 1, 0, 0,
+ "23097D223405D8228642A477BDA255B32AADBCE4BDA0B3F7E36C9DA7" },
+ /* 2 */ { TEST2_1, length(TEST2_1), 1, 0, 0,
+ "75388B16512776CC5DBA5DA1FD890150B0C6455CB4F58B1952522525" },
+ /* 3 */ { TEST3, length(TEST3), 1000000, 0, 0,
+ "20794655980C91D8BBB4C1EA97618A4BF03F42581948B2EE4EE7AD67" },
+ /* 4 */ { TEST4, length(TEST4), 10, 0, 0,
+ "567F69F168CD7844E65259CE658FE7AADFA25216E68ECA0EB7AB8262" },
+ /* 5 */ { "", 0, 0, 0x68, 5,
+ "E3B048552C3C387BCAB37F6EB06BB79B96A4AEE5FF27F51531A9551C" },
+ /* 6 */ { "\x07", 1, 1, 0, 0,
+ "00ECD5F138422B8AD74C9799FD826C531BAD2FCABC7450BEE2AA8C2A" },
+ /* 7 */ { TEST7_224, length(TEST7_224), 1, 0xA0, 3,
+ "1B01DB6CB4A9E43DED1516BEB3DB0B87B6D1EA43187462C608137150" },
+ /* 8 */ { TEST8_224, length(TEST8_224), 1, 0, 0,
+ "DF90D78AA78821C99B40BA4C966921ACCD8FFB1E98AC388E56191DB1" },
+ /* 9 */ { TEST9_224, length(TEST9_224), 1, 0xE0, 3,
+ "54BEA6EAB8195A2EB0A7906A4B4A876666300EEFBD1F3B8474F9CD57" },
+ /* 10 */ { TEST10_224, length(TEST10_224), 1, 0, 0,
+ "0B31894EC8937AD9B91BDFBCBA294D9ADEFAA18E09305E9F20D5C3A4" }
+ }, SHA224_SEED, { "100966A5B4FDE0B42E2A6C5953D4D7F41BA7CF79FD"
+ "2DF431416734BE", "1DCA396B0C417715DEFAAE9641E10A2E99D55A"
+ "BCB8A00061EB3BE8BD", "1864E627BDB2319973CD5ED7D68DA71D8B"
+ "F0F983D8D9AB32C34ADB34", "A2406481FC1BCAF24DD08E6752E844"
+ "709563FB916227FED598EB621F"
+ } },
+ { "SHA256", SHA256, SHA256HashSize,
+ {
+ /* 1 */ { TEST1, length(TEST1), 1, 0, 0, "BA7816BF8F01CFEA4141"
+ "40DE5DAE2223B00361A396177A9CB410FF61F20015AD" },
+ /* 2 */ { TEST2_1, length(TEST2_1), 1, 0, 0, "248D6A61D20638B8"
+ "E5C026930C3E6039A33CE45964FF2167F6ECEDD419DB06C1" },
+ /* 3 */ { TEST3, length(TEST3), 1000000, 0, 0, "CDC76E5C9914FB92"
+ "81A1C7E284D73E67F1809A48A497200E046D39CCC7112CD0" },
+
+
+
+Eastlake & Hansen Informational [Page 97]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+ /* 4 */ { TEST4, length(TEST4), 10, 0, 0, "594847328451BDFA"
+ "85056225462CC1D867D877FB388DF0CE35F25AB5562BFBB5" },
+ /* 5 */ { "", 0, 0, 0x68, 5, "D6D3E02A31A84A8CAA9718ED6C2057BE"
+ "09DB45E7823EB5079CE7A573A3760F95" },
+ /* 6 */ { "\x19", 1, 1, 0, 0, "68AA2E2EE5DFF96E3355E6C7EE373E3D"
+ "6A4E17F75F9518D843709C0C9BC3E3D4" },
+ /* 7 */ { TEST7_256, length(TEST7_256), 1, 0x60, 3, "77EC1DC8"
+ "9C821FF2A1279089FA091B35B8CD960BCAF7DE01C6A7680756BEB972" },
+ /* 8 */ { TEST8_256, length(TEST8_256), 1, 0, 0, "175EE69B02BA"
+ "9B58E2B0A5FD13819CEA573F3940A94F825128CF4209BEABB4E8" },
+ /* 9 */ { TEST9_256, length(TEST9_256), 1, 0xA0, 3, "3E9AD646"
+ "8BBBAD2AC3C2CDC292E018BA5FD70B960CF1679777FCE708FDB066E9" },
+ /* 10 */ { TEST10_256, length(TEST10_256), 1, 0, 0, "97DBCA7D"
+ "F46D62C8A422C941DD7E835B8AD3361763F7E9B2D95F4F0DA6E1CCBC" },
+ }, SHA256_SEED, { "83D28614D49C3ADC1D6FC05DB5F48037C056F8D2A4CE44"
+ "EC6457DEA5DD797CD1", "99DBE3127EF2E93DD9322D6A07909EB33B6399"
+ "5E529B3F954B8581621BB74D39", "8D4BE295BB64661CA3C7EFD129A2F7"
+ "25B33072DBDDE32385B9A87B9AF88EA76F", "40AF5D3F9716B040DF9408"
+ "E31536B70FF906EC51B00447CA97D7DD97C12411F4"
+ } },
+ { "SHA384", SHA384, SHA384HashSize,
+ {
+ /* 1 */ { TEST1, length(TEST1), 1, 0, 0,
+ "CB00753F45A35E8BB5A03D699AC65007272C32AB0EDED163"
+ "1A8B605A43FF5BED8086072BA1E7CC2358BAECA134C825A7" },
+ /* 2 */ { TEST2_2, length(TEST2_2), 1, 0, 0,
+ "09330C33F71147E83D192FC782CD1B4753111B173B3B05D2"
+ "2FA08086E3B0F712FCC7C71A557E2DB966C3E9FA91746039" },
+ /* 3 */ { TEST3, length(TEST3), 1000000, 0, 0,
+ "9D0E1809716474CB086E834E310A4A1CED149E9C00F24852"
+ "7972CEC5704C2A5B07B8B3DC38ECC4EBAE97DDD87F3D8985" },
+ /* 4 */ { TEST4, length(TEST4), 10, 0, 0,
+ "2FC64A4F500DDB6828F6A3430B8DD72A368EB7F3A8322A70"
+ "BC84275B9C0B3AB00D27A5CC3C2D224AA6B61A0D79FB4596" },
+ /* 5 */ { "", 0, 0, 0x10, 5,
+ "8D17BE79E32B6718E07D8A603EB84BA0478F7FCFD1BB9399"
+ "5F7D1149E09143AC1FFCFC56820E469F3878D957A15A3FE4" },
+ /* 6 */ { "\xb9", 1, 1, 0, 0,
+ "BC8089A19007C0B14195F4ECC74094FEC64F01F90929282C"
+ "2FB392881578208AD466828B1C6C283D2722CF0AD1AB6938" },
+ /* 7 */ { TEST7_384, length(TEST7_384), 1, 0xA0, 3,
+ "D8C43B38E12E7C42A7C9B810299FD6A770BEF30920F17532"
+ "A898DE62C7A07E4293449C0B5FA70109F0783211CFC4BCE3" },
+ /* 8 */ { TEST8_384, length(TEST8_384), 1, 0, 0,
+ "C9A68443A005812256B8EC76B00516F0DBB74FAB26D66591"
+ "3F194B6FFB0E91EA9967566B58109CBC675CC208E4C823F7" },
+ /* 9 */ { TEST9_384, length(TEST9_384), 1, 0xE0, 3,
+ "5860E8DE91C21578BB4174D227898A98E0B45C4C760F0095"
+
+
+
+Eastlake & Hansen Informational [Page 98]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+ "49495614DAEDC0775D92D11D9F8CE9B064EEAC8DAFC3A297" },
+ /* 10 */ { TEST10_384, length(TEST10_384), 1, 0, 0,
+ "4F440DB1E6EDD2899FA335F09515AA025EE177A79F4B4AAF"
+ "38E42B5C4DE660F5DE8FB2A5B2FBD2A3CBFFD20CFF1288C0" }
+ }, SHA384_SEED, { "CE44D7D63AE0C91482998CF662A51EC80BF6FC68661A3C"
+ "57F87566112BD635A743EA904DEB7D7A42AC808CABE697F38F", "F9C6D2"
+ "61881FEE41ACD39E67AA8D0BAD507C7363EB67E2B81F45759F9C0FD7B503"
+ "DF1A0B9E80BDE7BC333D75B804197D", "D96512D8C9F4A7A4967A366C01"
+ "C6FD97384225B58343A88264847C18E4EF8AB7AEE4765FFBC3E30BD485D3"
+ "638A01418F", "0CA76BD0813AF1509E170907A96005938BC985628290B2"
+ "5FEF73CF6FAD68DDBA0AC8920C94E0541607B0915A7B4457F7"
+ } },
+ { "SHA512", SHA512, SHA512HashSize,
+ {
+ /* 1 */ { TEST1, length(TEST1), 1, 0, 0,
+ "DDAF35A193617ABACC417349AE20413112E6FA4E89A97EA2"
+ "0A9EEEE64B55D39A2192992A274FC1A836BA3C23A3FEEBBD"
+ "454D4423643CE80E2A9AC94FA54CA49F" },
+ /* 2 */ { TEST2_2, length(TEST2_2), 1, 0, 0,
+ "8E959B75DAE313DA8CF4F72814FC143F8F7779C6EB9F7FA1"
+ "7299AEADB6889018501D289E4900F7E4331B99DEC4B5433A"
+ "C7D329EEB6DD26545E96E55B874BE909" },
+ /* 3 */ { TEST3, length(TEST3), 1000000, 0, 0,
+ "E718483D0CE769644E2E42C7BC15B4638E1F98B13B204428"
+ "5632A803AFA973EBDE0FF244877EA60A4CB0432CE577C31B"
+ "EB009C5C2C49AA2E4EADB217AD8CC09B" },
+ /* 4 */ { TEST4, length(TEST4), 10, 0, 0,
+ "89D05BA632C699C31231DED4FFC127D5A894DAD412C0E024"
+ "DB872D1ABD2BA8141A0F85072A9BE1E2AA04CF33C765CB51"
+ "0813A39CD5A84C4ACAA64D3F3FB7BAE9" },
+ /* 5 */ { "", 0, 0, 0xB0, 5,
+ "D4EE29A9E90985446B913CF1D1376C836F4BE2C1CF3CADA0"
+ "720A6BF4857D886A7ECB3C4E4C0FA8C7F95214E41DC1B0D2"
+ "1B22A84CC03BF8CE4845F34DD5BDBAD4" },
+ /* 6 */ { "\xD0", 1, 1, 0, 0,
+ "9992202938E882E73E20F6B69E68A0A7149090423D93C81B"
+ "AB3F21678D4ACEEEE50E4E8CAFADA4C85A54EA8306826C4A"
+ "D6E74CECE9631BFA8A549B4AB3FBBA15" },
+ /* 7 */ { TEST7_512, length(TEST7_512), 1, 0x80, 3,
+ "ED8DC78E8B01B69750053DBB7A0A9EDA0FB9E9D292B1ED71"
+ "5E80A7FE290A4E16664FD913E85854400C5AF05E6DAD316B"
+ "7359B43E64F8BEC3C1F237119986BBB6" },
+ /* 8 */ { TEST8_512, length(TEST8_512), 1, 0, 0,
+ "CB0B67A4B8712CD73C9AABC0B199E9269B20844AFB75ACBD"
+ "D1C153C9828924C3DDEDAAFE669C5FDD0BC66F630F677398"
+ "8213EB1B16F517AD0DE4B2F0C95C90F8" },
+ /* 9 */ { TEST9_512, length(TEST9_512), 1, 0x80, 3,
+ "32BA76FC30EAA0208AEB50FFB5AF1864FDBF17902A4DC0A6"
+
+
+
+Eastlake & Hansen Informational [Page 99]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+ "82C61FCEA6D92B783267B21080301837F59DE79C6B337DB2"
+ "526F8A0A510E5E53CAFED4355FE7C2F1" },
+ /* 10 */ { TEST10_512, length(TEST10_512), 1, 0, 0,
+ "C665BEFB36DA189D78822D10528CBF3B12B3EEF726039909"
+ "C1A16A270D48719377966B957A878E720584779A62825C18"
+ "DA26415E49A7176A894E7510FD1451F5" }
+ }, SHA512_SEED, { "2FBB1E7E00F746BA514FBC8C421F36792EC0E11FF5EFC3"
+ "78E1AB0C079AA5F0F66A1E3EDBAEB4F9984BE14437123038A452004A5576"
+ "8C1FD8EED49E4A21BEDCD0", "25CBE5A4F2C7B1D7EF07011705D50C62C5"
+ "000594243EAFD1241FC9F3D22B58184AE2FEE38E171CF8129E29459C9BC2"
+ "EF461AF5708887315F15419D8D17FE7949", "5B8B1F2687555CE2D7182B"
+ "92E5C3F6C36547DA1C13DBB9EA4F73EA4CBBAF89411527906D35B1B06C1B"
+ "6A8007D05EC66DF0A406066829EAB618BDE3976515AAFC", "46E36B007D"
+ "19876CDB0B29AD074FE3C08CDD174D42169D6ABE5A1414B6E79707DF5877"
+ "6A98091CF431854147BB6D3C66D43BFBC108FD715BDE6AA127C2B0E79F"
+ }
+ }
+};
+
+/* Test arrays for HMAC. */
+struct hmachash {
+ const char *keyarray[5];
+ int keylength[5];
+ const char *dataarray[5];
+ int datalength[5];
+ const char *resultarray[5];
+ int resultlength[5];
+} hmachashes[HMACTESTCOUNT] = {
+ { /* 1 */ {
+ "\x0b\x0b\x0b\x0b\x0b\x0b\x0b\x0b\x0b\x0b\x0b\x0b\x0b\x0b\x0b"
+ "\x0b\x0b\x0b\x0b\x0b"
+ }, { 20 }, {
+ "\x48\x69\x20\x54\x68\x65\x72\x65" /* "Hi There" */
+ }, { 8 }, {
+ /* HMAC-SHA-1 */
+ "B617318655057264E28BC0B6FB378C8EF146BE00",
+ /* HMAC-SHA-224 */
+ "896FB1128ABBDF196832107CD49DF33F47B4B1169912BA4F53684B22",
+ /* HMAC-SHA-256 */
+ "B0344C61D8DB38535CA8AFCEAF0BF12B881DC200C9833DA726E9376C2E32"
+ "CFF7",
+ /* HMAC-SHA-384 */
+ "AFD03944D84895626B0825F4AB46907F15F9DADBE4101EC682AA034C7CEB"
+ "C59CFAEA9EA9076EDE7F4AF152E8B2FA9CB6",
+ /* HMAC-SHA-512 */
+ "87AA7CDEA5EF619D4FF0B4241A1D6CB02379F4E2CE4EC2787AD0B30545E1"
+ "7CDEDAA833B7D6B8A702038B274EAEA3F4E4BE9D914EEB61F1702E696C20"
+ "3A126854"
+
+
+
+Eastlake & Hansen Informational [Page 100]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+ }, { SHA1HashSize, SHA224HashSize, SHA256HashSize,
+ SHA384HashSize, SHA512HashSize }
+ },
+ { /* 2 */ {
+ "\x4a\x65\x66\x65" /* "Jefe" */
+ }, { 4 }, {
+ "\x77\x68\x61\x74\x20\x64\x6f\x20\x79\x61\x20\x77\x61\x6e\x74"
+ "\x20\x66\x6f\x72\x20\x6e\x6f\x74\x68\x69\x6e\x67\x3f"
+ /* "what do ya want for nothing?" */
+ }, { 28 }, {
+ /* HMAC-SHA-1 */
+ "EFFCDF6AE5EB2FA2D27416D5F184DF9C259A7C79",
+ /* HMAC-SHA-224 */
+ "A30E01098BC6DBBF45690F3A7E9E6D0F8BBEA2A39E6148008FD05E44",
+ /* HMAC-SHA-256 */
+ "5BDCC146BF60754E6A042426089575C75A003F089D2739839DEC58B964EC"
+ "3843",
+ /* HMAC-SHA-384 */
+ "AF45D2E376484031617F78D2B58A6B1B9C7EF464F5A01B47E42EC3736322"
+ "445E8E2240CA5E69E2C78B3239ECFAB21649",
+ /* HMAC-SHA-512 */
+ "164B7A7BFCF819E2E395FBE73B56E0A387BD64222E831FD610270CD7EA25"
+ "05549758BF75C05A994A6D034F65F8F0E6FDCAEAB1A34D4A6B4B636E070A"
+ "38BCE737"
+ }, { SHA1HashSize, SHA224HashSize, SHA256HashSize,
+ SHA384HashSize, SHA512HashSize }
+ },
+ { /* 3 */
+ {
+ "\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa"
+ "\xaa\xaa\xaa\xaa\xaa"
+ }, { 20 }, {
+ "\xdd\xdd\xdd\xdd\xdd\xdd\xdd\xdd\xdd\xdd\xdd\xdd\xdd\xdd\xdd"
+ "\xdd\xdd\xdd\xdd\xdd\xdd\xdd\xdd\xdd\xdd\xdd\xdd\xdd\xdd\xdd"
+ "\xdd\xdd\xdd\xdd\xdd\xdd\xdd\xdd\xdd\xdd\xdd\xdd\xdd\xdd\xdd"
+ "\xdd\xdd\xdd\xdd\xdd"
+ }, { 50 }, {
+ /* HMAC-SHA-1 */
+ "125D7342B9AC11CD91A39AF48AA17B4F63F175D3",
+ /* HMAC-SHA-224 */
+ "7FB3CB3588C6C1F6FFA9694D7D6AD2649365B0C1F65D69D1EC8333EA",
+ /* HMAC-SHA-256 */
+ "773EA91E36800E46854DB8EBD09181A72959098B3EF8C122D9635514CED5"
+ "65FE",
+ /* HMAC-SHA-384 */
+ "88062608D3E6AD8A0AA2ACE014C8A86F0AA635D947AC9FEBE83EF4E55966"
+ "144B2A5AB39DC13814B94E3AB6E101A34F27",
+ /* HMAC-SHA-512 */
+
+
+
+Eastlake & Hansen Informational [Page 101]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+ "FA73B0089D56A284EFB0F0756C890BE9B1B5DBDD8EE81A3655F83E33B227"
+ "9D39BF3E848279A722C806B485A47E67C807B946A337BEE8942674278859"
+ "E13292FB"
+ }, { SHA1HashSize, SHA224HashSize, SHA256HashSize,
+ SHA384HashSize, SHA512HashSize }
+ },
+ { /* 4 */ {
+ "\x01\x02\x03\x04\x05\x06\x07\x08\x09\x0a\x0b\x0c\x0d\x0e\x0f"
+ "\x10\x11\x12\x13\x14\x15\x16\x17\x18\x19"
+ }, { 25 }, {
+ "\xcd\xcd\xcd\xcd\xcd\xcd\xcd\xcd\xcd\xcd\xcd\xcd\xcd\xcd\xcd"
+ "\xcd\xcd\xcd\xcd\xcd\xcd\xcd\xcd\xcd\xcd\xcd\xcd\xcd\xcd\xcd"
+ "\xcd\xcd\xcd\xcd\xcd\xcd\xcd\xcd\xcd\xcd\xcd\xcd\xcd\xcd\xcd"
+ "\xcd\xcd\xcd\xcd\xcd"
+ }, { 50 }, {
+ /* HMAC-SHA-1 */
+ "4C9007F4026250C6BC8414F9BF50C86C2D7235DA",
+ /* HMAC-SHA-224 */
+ "6C11506874013CAC6A2ABC1BB382627CEC6A90D86EFC012DE7AFEC5A",
+ /* HMAC-SHA-256 */
+ "82558A389A443C0EA4CC819899F2083A85F0FAA3E578F8077A2E3FF46729"
+ "665B",
+ /* HMAC-SHA-384 */
+ "3E8A69B7783C25851933AB6290AF6CA77A9981480850009CC5577C6E1F57"
+ "3B4E6801DD23C4A7D679CCF8A386C674CFFB",
+ /* HMAC-SHA-512 */
+ "B0BA465637458C6990E5A8C5F61D4AF7E576D97FF94B872DE76F8050361E"
+ "E3DBA91CA5C11AA25EB4D679275CC5788063A5F19741120C4F2DE2ADEBEB"
+ "10A298DD"
+ }, { SHA1HashSize, SHA224HashSize, SHA256HashSize,
+ SHA384HashSize, SHA512HashSize }
+ },
+ { /* 5 */ {
+ "\x0c\x0c\x0c\x0c\x0c\x0c\x0c\x0c\x0c\x0c\x0c\x0c\x0c\x0c\x0c"
+ "\x0c\x0c\x0c\x0c\x0c"
+ }, { 20 }, {
+ "Test With Truncation"
+ }, { 20 }, {
+ /* HMAC-SHA-1 */
+ "4C1A03424B55E07FE7F27BE1",
+ /* HMAC-SHA-224 */
+ "0E2AEA68A90C8D37C988BCDB9FCA6FA8",
+ /* HMAC-SHA-256 */
+ "A3B6167473100EE06E0C796C2955552B",
+ /* HMAC-SHA-384 */
+ "3ABF34C3503B2A23A46EFC619BAEF897",
+ /* HMAC-SHA-512 */
+ "415FAD6271580A531D4179BC891D87A6"
+
+
+
+Eastlake & Hansen Informational [Page 102]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+ }, { 12, 16, 16, 16, 16 }
+ },
+ { /* 6 */ {
+ "\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa"
+ "\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa"
+ "\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa"
+ "\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa"
+ "\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa"
+ "\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa"
+ "\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa"
+ "\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa"
+ "\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa"
+ }, { 80, 131 }, {
+ "Test Using Larger Than Block-Size Key - Hash Key First"
+ }, { 54 }, {
+ /* HMAC-SHA-1 */
+ "AA4AE5E15272D00E95705637CE8A3B55ED402112",
+ /* HMAC-SHA-224 */
+ "95E9A0DB962095ADAEBE9B2D6F0DBCE2D499F112F2D2B7273FA6870E",
+ /* HMAC-SHA-256 */
+ "60E431591EE0B67F0D8A26AACBF5B77F8E0BC6213728C5140546040F0EE3"
+ "7F54",
+ /* HMAC-SHA-384 */
+ "4ECE084485813E9088D2C63A041BC5B44F9EF1012A2B588F3CD11F05033A"
+ "C4C60C2EF6AB4030FE8296248DF163F44952",
+ /* HMAC-SHA-512 */
+ "80B24263C7C1A3EBB71493C1DD7BE8B49B46D1F41B4AEEC1121B013783F8"
+ "F3526B56D037E05F2598BD0FD2215D6A1E5295E64F73F63F0AEC8B915A98"
+ "5D786598"
+ }, { SHA1HashSize, SHA224HashSize, SHA256HashSize,
+ SHA384HashSize, SHA512HashSize }
+ },
+ { /* 7 */ {
+ "\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa"
+ "\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa"
+ "\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa"
+ "\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa"
+ "\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa"
+ "\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa"
+ "\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa"
+ "\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa"
+ "\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa\xaa"
+ }, { 80, 131 }, {
+ "Test Using Larger Than Block-Size Key and "
+ "Larger Than One Block-Size Data",
+ "\x54\x68\x69\x73\x20\x69\x73\x20\x61\x20\x74\x65\x73\x74\x20"
+ "\x75\x73\x69\x6e\x67\x20\x61\x20\x6c\x61\x72\x67\x65\x72\x20"
+ "\x74\x68\x61\x6e\x20\x62\x6c\x6f\x63\x6b\x2d\x73\x69\x7a\x65"
+
+
+
+Eastlake & Hansen Informational [Page 103]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+ "\x20\x6b\x65\x79\x20\x61\x6e\x64\x20\x61\x20\x6c\x61\x72\x67"
+ "\x65\x72\x20\x74\x68\x61\x6e\x20\x62\x6c\x6f\x63\x6b\x2d\x73"
+ "\x69\x7a\x65\x20\x64\x61\x74\x61\x2e\x20\x54\x68\x65\x20\x6b"
+ "\x65\x79\x20\x6e\x65\x65\x64\x73\x20\x74\x6f\x20\x62\x65\x20"
+ "\x68\x61\x73\x68\x65\x64\x20\x62\x65\x66\x6f\x72\x65\x20\x62"
+ "\x65\x69\x6e\x67\x20\x75\x73\x65\x64\x20\x62\x79\x20\x74\x68"
+ "\x65\x20\x48\x4d\x41\x43\x20\x61\x6c\x67\x6f\x72\x69\x74\x68"
+ "\x6d\x2e"
+ /* "This is a test using a larger than block-size key and a "
+ "larger than block-size data. The key needs to be hashed "
+ "before being used by the HMAC algorithm." */
+ }, { 73, 152 }, {
+ /* HMAC-SHA-1 */
+ "E8E99D0F45237D786D6BBAA7965C7808BBFF1A91",
+ /* HMAC-SHA-224 */
+ "3A854166AC5D9F023F54D517D0B39DBD946770DB9C2B95C9F6F565D1",
+ /* HMAC-SHA-256 */
+ "9B09FFA71B942FCB27635FBCD5B0E944BFDC63644F0713938A7F51535C3A"
+ "35E2",
+ /* HMAC-SHA-384 */
+ "6617178E941F020D351E2F254E8FD32C602420FEB0B8FB9ADCCEBB82461E"
+ "99C5A678CC31E799176D3860E6110C46523E",
+ /* HMAC-SHA-512 */
+ "E37B6A775DC87DBAA4DFA9F96E5E3FFDDEBD71F8867289865DF5A32D20CD"
+ "C944B6022CAC3C4982B10D5EEB55C3E4DE15134676FB6DE0446065C97440"
+ "FA8C6A58"
+ }, { SHA1HashSize, SHA224HashSize, SHA256HashSize,
+ SHA384HashSize, SHA512HashSize }
+ }
+};
+
+/* Test arrays for HKDF. */
+struct hkdfhash {
+ SHAversion whichSha;
+ int ikmlength;
+ const char *ikmarray;
+ int saltlength;
+ const char *saltarray;
+ int infolength;
+ const char *infoarray;
+ int prklength;
+ const char *prkarray;
+ int okmlength;
+ const char *okmarray;
+} hkdfhashes[HKDFTESTCOUNT] = {
+ { /* RFC 5869 A.1. Test Case 1 */
+ SHA256,
+ 22, "\x0b\x0b\x0b\x0b\x0b\x0b\x0b\x0b\x0b\x0b\x0b\x0b\x0b\x0b"
+
+
+
+Eastlake & Hansen Informational [Page 104]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+ "\x0b\x0b\x0b\x0b\x0b\x0b\x0b\x0b",
+ 13, "\x00\x01\x02\x03\x04\x05\x06\x07\x08\x09\x0a\x0b\x0c",
+ 10, "\xf0\xf1\xf2\xf3\xf4\xf5\xf6\xf7\xf8\xf9",
+ 32, "077709362C2E32DF0DDC3F0DC47BBA6390B6C73BB50F9C3122EC844A"
+ "D7C2B3E5",
+ 42, "3CB25F25FAACD57A90434F64D0362F2A2D2D0A90CF1A5A4C5DB02D56"
+ "ECC4C5BF34007208D5B887185865"
+ },
+ { /* RFC 5869 A.2. Test Case 2 */
+ SHA256,
+ 80, "\x00\x01\x02\x03\x04\x05\x06\x07\x08\x09\x0a\x0b\x0c\x0d"
+ "\x0e\x0f\x10\x11\x12\x13\x14\x15\x16\x17\x18\x19\x1a\x1b"
+ "\x1c\x1d\x1e\x1f\x20\x21\x22\x23\x24\x25\x26\x27\x28\x29"
+ "\x2a\x2b\x2c\x2d\x2e\x2f\x30\x31\x32\x33\x34\x35\x36\x37"
+ "\x38\x39\x3a\x3b\x3c\x3d\x3e\x3f\x40\x41\x42\x43\x44\x45"
+ "\x46\x47\x48\x49\x4a\x4b\x4c\x4d\x4e\x4f",
+ 80, "\x60\x61\x62\x63\x64\x65\x66\x67\x68\x69\x6a\x6b\x6c\x6d"
+ "\x6e\x6f\x70\x71\x72\x73\x74\x75\x76\x77\x78\x79\x7a\x7b"
+ "\x7c\x7d\x7e\x7f\x80\x81\x82\x83\x84\x85\x86\x87\x88\x89"
+ "\x8a\x8b\x8c\x8d\x8e\x8f\x90\x91\x92\x93\x94\x95\x96\x97"
+ "\x98\x99\x9a\x9b\x9c\x9d\x9e\x9f\xa0\xa1\xa2\xa3\xa4\xa5"
+ "\xa6\xa7\xa8\xa9\xaa\xab\xac\xad\xae\xaf",
+ 80, "\xb0\xb1\xb2\xb3\xb4\xb5\xb6\xb7\xb8\xb9\xba\xbb\xbc\xbd"
+ "\xbe\xbf\xc0\xc1\xc2\xc3\xc4\xc5\xc6\xc7\xc8\xc9\xca\xcb"
+ "\xcc\xcd\xce\xcf\xd0\xd1\xd2\xd3\xd4\xd5\xd6\xd7\xd8\xd9"
+ "\xda\xdb\xdc\xdd\xde\xdf\xe0\xe1\xe2\xe3\xe4\xe5\xe6\xe7"
+ "\xe8\xe9\xea\xeb\xec\xed\xee\xef\xf0\xf1\xf2\xf3\xf4\xf5"
+ "\xf6\xf7\xf8\xf9\xfa\xfb\xfc\xfd\xfe\xff",
+ 32, "06A6B88C5853361A06104C9CEB35B45C"
+ "EF760014904671014A193F40C15FC244",
+ 82, "B11E398DC80327A1C8E7F78C596A4934"
+ "4F012EDA2D4EFAD8A050CC4C19AFA97C"
+ "59045A99CAC7827271CB41C65E590E09"
+ "DA3275600C2F09B8367793A9ACA3DB71"
+ "CC30C58179EC3E87C14C01D5C1F3434F"
+ "1D87"
+ },
+ { /* RFC 5869 A.3. Test Case 3 */
+ SHA256,
+ 22, "\x0b\x0b\x0b\x0b\x0b\x0b\x0b\x0b\x0b\x0b\x0b\x0b\x0b\x0b"
+ "\x0b\x0b\x0b\x0b\x0b\x0b\x0b\x0b",
+ 0, "",
+ 0, "",
+ 32, "19EF24A32C717B167F33A91D6F648BDF"
+ "96596776AFDB6377AC434C1C293CCB04",
+ 42, "8DA4E775A563C18F715F802A063C5A31"
+ "B8A11F5C5EE1879EC3454E5F3C738D2D"
+ "9D201395FAA4B61A96C8"
+
+
+
+Eastlake & Hansen Informational [Page 105]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+ },
+ { /* RFC 5869 A.4. Test Case 4 */
+ SHA1,
+ 11, "\x0b\x0b\x0b\x0b\x0b\x0b\x0b\x0b\x0b\x0b\x0b",
+ 13, "\x00\x01\x02\x03\x04\x05\x06\x07\x08\x09\x0a\x0b\x0c",
+ 10, "\xf0\xf1\xf2\xf3\xf4\xf5\xf6\xf7\xf8\xf9",
+ 20, "9B6C18C432A7BF8F0E71C8EB88F4B30BAA2BA243",
+ 42, "085A01EA1B10F36933068B56EFA5AD81"
+ "A4F14B822F5B091568A9CDD4F155FDA2"
+ "C22E422478D305F3F896"
+ },
+ { /* RFC 5869 A.5. Test Case 5 */
+ SHA1,
+ 80, "\x00\x01\x02\x03\x04\x05\x06\x07\x08\x09\x0a\x0b\x0c\x0d"
+ "\x0e\x0f\x10\x11\x12\x13\x14\x15\x16\x17\x18\x19\x1a\x1b"
+ "\x1c\x1d\x1e\x1f\x20\x21\x22\x23\x24\x25\x26\x27\x28\x29"
+ "\x2a\x2b\x2c\x2d\x2e\x2f\x30\x31\x32\x33\x34\x35\x36\x37"
+ "\x38\x39\x3a\x3b\x3c\x3d\x3e\x3f\x40\x41\x42\x43\x44\x45"
+ "\x46\x47\x48\x49\x4a\x4b\x4c\x4d\x4e\x4f",
+ 80, "\x60\x61\x62\x63\x64\x65\x66\x67\x68\x69\x6A\x6B\x6C\x6D"
+ "\x6E\x6F\x70\x71\x72\x73\x74\x75\x76\x77\x78\x79\x7A\x7B"
+ "\x7C\x7D\x7E\x7F\x80\x81\x82\x83\x84\x85\x86\x87\x88\x89"
+ "\x8A\x8B\x8C\x8D\x8E\x8F\x90\x91\x92\x93\x94\x95\x96\x97"
+ "\x98\x99\x9A\x9B\x9C\x9D\x9E\x9F\xA0\xA1\xA2\xA3\xA4\xA5"
+ "\xA6\xA7\xA8\xA9\xAA\xAB\xAC\xAD\xAE\xAF",
+ 80, "\xB0\xB1\xB2\xB3\xB4\xB5\xB6\xB7\xB8\xB9\xBA\xBB\xBC\xBD"
+ "\xBE\xBF\xC0\xC1\xC2\xC3\xC4\xC5\xC6\xC7\xC8\xC9\xCA\xCB"
+ "\xCC\xCD\xCE\xCF\xD0\xD1\xD2\xD3\xD4\xD5\xD6\xD7\xD8\xD9"
+ "\xDA\xDB\xDC\xDD\xDE\xDF\xE0\xE1\xE2\xE3\xE4\xE5\xE6\xE7"
+ "\xE8\xE9\xEA\xEB\xEC\xED\xEE\xEF\xF0\xF1\xF2\xF3\xF4\xF5"
+ "\xF6\xF7\xF8\xF9\xFA\xFB\xFC\xFD\xFE\xFF",
+ 20, "8ADAE09A2A307059478D309B26C4115A224CFAF6",
+ 82, "0BD770A74D1160F7C9F12CD5912A06EB"
+ "FF6ADCAE899D92191FE4305673BA2FFE"
+ "8FA3F1A4E5AD79F3F334B3B202B2173C"
+ "486EA37CE3D397ED034C7F9DFEB15C5E"
+ "927336D0441F4C4300E2CFF0D0900B52"
+ "D3B4"
+ },
+ { /* RFC 5869 A.6. Test Case 6 */
+ SHA1,
+ 22, "\x0b\x0b\x0b\x0b\x0b\x0b\x0b\x0b\x0b\x0b\x0b\x0b\x0b\x0b"
+ "\x0b\x0b\x0b\x0b\x0b\x0b\x0b\x0b",
+ 0, "",
+ 0, "",
+ 20, "DA8C8A73C7FA77288EC6F5E7C297786AA0D32D01",
+ 42, "0AC1AF7002B3D761D1E55298DA9D0506"
+ "B9AE52057220A306E07B6B87E8DF21D0"
+
+
+
+Eastlake & Hansen Informational [Page 106]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+ "EA00033DE03984D34918"
+ },
+ { /* RFC 5869 A.7. Test Case 7. */
+ SHA1,
+ 22, "\x0c\x0c\x0c\x0c\x0c\x0c\x0c\x0c\x0c\x0c\x0c\x0c\x0c\x0c"
+ "\x0c\x0c\x0c\x0c\x0c\x0c\x0c\x0c",
+ 0, 0,
+ 0, "",
+ 20, "2ADCCADA18779E7C2077AD2EB19D3F3E731385DD",
+ 42, "2C91117204D745F3500D636A62F64F0A"
+ "B3BAE548AA53D423B0D1F27EBBA6F5E5"
+ "673A081D70CCE7ACFC48"
+ }
+};
+
+/*
+ * Check the hash value against the expected string, expressed in hex
+ */
+static const char hexdigits[ ] = "0123456789ABCDEF";
+int checkmatch(const unsigned char *hashvalue,
+ const char *hexstr, int hashsize)
+{
+ int i;
+ for (i = 0; i < hashsize; ++i) {
+ if (*hexstr++ != hexdigits[(hashvalue[i] >> 4) & 0xF])
+ return 0;
+ if (*hexstr++ != hexdigits[hashvalue[i] & 0xF]) return 0;
+ }
+ return 1;
+}
+
+/*
+ * Print the string, converting non-printable characters to "."
+ */
+void printstr(const char *str, int len)
+{
+ for ( ; len-- > 0; str++)
+ putchar(isprint((unsigned char)*str) ? *str : '.');
+}
+
+/*
+ * Print the string, converting all characters to hex "## ".
+ */
+void printxstr(const char *str, int len)
+{
+ char *sep = "";
+ for ( ; len-- > 0; str++) {
+ printf("%s%c%c", sep, hexdigits[(*str >> 4) & 0xF],
+
+
+
+Eastlake & Hansen Informational [Page 107]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+ hexdigits[*str & 0xF]);
+ sep = " ";
+ }
+}
+
+/*
+ * Print a usage message.
+ */
+void usage(const char *argv0)
+{
+ fprintf(stderr,
+ "Usage:\n"
+ "Common options: [-h hash] [-w|-x|-6] [-H]\n"
+ "Hash a string:\n"
+ "\t%s [-S expectedresult] -s hashstr [-k key] "
+ "[-i info -L okm-len]\n"
+ "Hash a file:\n"
+ "\t%s [-S expectedresult] -f file [-k key] "
+ "[-i info -L okm-len]\n"
+ "Hash a file, ignoring whitespace:\n"
+ "\t%s [-S expectedresult] -F file [-k key] "
+ "[-i info -L okm-len]\n"
+ "Additional bits to add in: [-B bitcount -b bits]\n"
+ "(If -k,-i&-L are used, run HKDF-SHA###.\n"
+ " If -k is used, but not -i&-L, run HMAC-SHA###.\n"
+ " Otherwise, run SHA###.)\n"
+ "Standard tests:\n"
+ "\t%s [-m | -d] [-l loopcount] [-t test#] [-e]\n"
+ "\t\t[-r randomseed] [-R randomloop-count] "
+ "[-p] [-P|-X]\n"
+ "-h\thash to test: "
+ "0|SHA1, 1|SHA224, 2|SHA256, 3|SHA384, 4|SHA512\n"
+ "-m\tperform hmac standard tests\n"
+ "-k\tkey for hmac test\n"
+ "-d\tperform hkdf standard tests\n"
+ "-t\ttest case to run, 1-10\n"
+ "-l\thow many times to run the test\n"
+ "-e\ttest error returns\n"
+ "-p\tdo not print results\n"
+ "-P\tdo not print PASSED/FAILED\n"
+ "-X\tprint FAILED, but not PASSED\n"
+ "-r\tseed for random test\n"
+ "-R\thow many times to run random test\n"
+ "-s\tstring to hash\n"
+ "-S\texpected result of hashed string, in hex\n"
+ "-w\toutput hash in raw format\n"
+ "-x\toutput hash in hex format\n"
+ "-6\toutput hash in base64 format\n"
+
+
+
+Eastlake & Hansen Informational [Page 108]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+ "-B\t# extra bits to add in after string or file input\n"
+ "-b\textra bits to add (high order bits of #, 0# or 0x#)\n"
+ "-H\tinput hashstr or randomseed is in hex\n"
+ , argv0, argv0, argv0, argv0);
+ exit(1);
+}
+
+/*
+ * Print the results and PASS/FAIL.
+ */
+void printResult(uint8_t *Message_Digest, int hashsize,
+ const char *hashname, const char *testtype, const char *testname,
+ const char *resultarray, int printResults, int printPassFail)
+{
+ int i, k;
+ if (printResults == PRINTTEXT) {
+ printf("\nhashsize=%d\n", hashsize);
+ putchar('\t');
+ for (i = 0; i < hashsize; ++i) {
+ putchar(hexdigits[(Message_Digest[i] >> 4) & 0xF]);
+ putchar(hexdigits[Message_Digest[i] & 0xF]);
+ putchar(' ');
+ }
+ putchar('\n');
+ } else if (printResults == PRINTRAW) {
+ fwrite(Message_Digest, 1, hashsize, stdout);
+ } else if (printResults == PRINTHEX) {
+ for (i = 0; i < hashsize; ++i) {
+ putchar(hexdigits[(Message_Digest[i] >> 4) & 0xF]);
+ putchar(hexdigits[Message_Digest[i] & 0xF]);
+ }
+ putchar('\n');
+ } else if (printResults == PRINTBASE64) {
+ unsigned char b;
+ char *sm = "ABCDEFGHIJKLMNOPQRSTUVWXYZabcdefghijklmnopqrstuvwxyz"
+ "0123456789+/";
+ for (i = 0; i < hashsize; i += 3) {
+ putchar(sm[Message_Digest[i] >> 2]);
+ b = (Message_Digest[i] & 0x03) << 4;
+ if (i+1 < hashsize) b |= Message_Digest[i+1] >> 4;
+ putchar(sm[b]);
+ if (i+1 < hashsize) {
+ b = (Message_Digest[i+1] & 0x0f) << 2;
+ if (i+2 < hashsize) b |= Message_Digest[i+2] >> 6;
+ putchar(sm[b]);
+ } else putchar('=');
+ if (i+2 < hashsize) putchar(sm[Message_Digest[i+2] & 0x3f]);
+ else putchar('=');
+
+
+
+Eastlake & Hansen Informational [Page 109]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+ }
+ putchar('\n');
+ }
+
+ if (printResults && resultarray) {
+ printf(" Should match:\n\t");
+ for (i = 0, k = 0; i < hashsize; i++, k += 2) {
+ putchar(resultarray[k]);
+ putchar(resultarray[k+1]);
+ putchar(' ');
+ }
+ putchar('\n');
+ }
+
+ if (printPassFail && resultarray) {
+ int ret = checkmatch(Message_Digest, resultarray, hashsize);
+ if ((printPassFail == PRINTPASSFAIL) || !ret)
+ printf("%s %s %s: %s\n", hashname, testtype, testname,
+ ret ? "PASSED" : "FAILED");
+ }
+}
+
+/*
+ * Exercise a hash series of functions. The input is the testarray,
+ * repeated repeatcount times, followed by the extrabits. If the
+ * result is known, it is in resultarray in uppercase hex.
+ */
+int hash(int testno, int loopno, int hashno,
+ const char *testarray, int length, long repeatcount,
+ int numberExtrabits, int extrabits, const unsigned char *keyarray,
+ int keylen, const unsigned char *info, int infolen, int okmlen,
+ const char *resultarray, int hashsize, int printResults,
+ int printPassFail)
+{
+ USHAContext sha;
+ HMACContext hmac;
+ HKDFContext hkdf;
+ int err, i;
+ uint8_t Message_Digest_Buf[USHAMaxHashSize];
+ uint8_t *Message_Digest = Message_Digest_Buf;
+ char buf[20];
+
+ if (printResults == PRINTTEXT) {
+ printf("\nTest %d: Iteration %d, Repeat %ld\n\t'", testno+1,
+ loopno, repeatcount);
+ printstr(testarray, length);
+ printf("'\n\t'");
+ printxstr(testarray, length);
+
+
+
+Eastlake & Hansen Informational [Page 110]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+ printf("'\n");
+ printf(" Length=%d bytes (%d bits), ", length, length * 8);
+ printf("ExtraBits %d: %2.2x\n", numberExtrabits, extrabits);
+ }
+
+ if (info) Message_Digest = malloc(okmlen);
+ memset(&sha, '\343', sizeof(sha)); /* force bad data into struct */
+ memset(&hmac, '\343', sizeof(hmac));
+ memset(&hkdf, '\343', sizeof(hkdf));
+
+ err = info ? hkdfReset(&hkdf, hashes[hashno].whichSha,
+ keyarray, keylen) :
+ keyarray ? hmacReset(&hmac, hashes[hashno].whichSha,
+ keyarray, keylen) :
+ USHAReset(&sha, hashes[hashno].whichSha);
+ if (err != shaSuccess) {
+ fprintf(stderr, "hash(): %sReset Error %d.\n",
+ info ? "hkdf" : keyarray ? "hmac" : "sha", err);
+ return err;
+ }
+
+ for (i = 0; i < repeatcount; ++i) {
+ err = info ? hkdfInput(&hkdf, (const uint8_t *)testarray, length) :
+ keyarray ? hmacInput(&hmac, (const uint8_t *) testarray,
+ length) :
+ USHAInput(&sha, (const uint8_t *) testarray,
+ length);
+ if (err != shaSuccess) {
+ fprintf(stderr, "hash(): %sInput Error %d.\n",
+ info ? "hkdf" : keyarray ? "hmac" : "sha", err);
+ return err;
+ }
+ }
+
+ if (numberExtrabits > 0) {
+ err = info ? hkdfFinalBits(&hkdf, extrabits, numberExtrabits) :
+ keyarray ? hmacFinalBits(&hmac, (uint8_t) extrabits,
+ numberExtrabits) :
+ USHAFinalBits(&sha, (uint8_t) extrabits,
+ numberExtrabits);
+ if (err != shaSuccess) {
+ fprintf(stderr, "hash(): %sFinalBits Error %d.\n",
+ info ? "hkdf" : keyarray ? "hmac" : "sha", err);
+ return err;
+ }
+ }
+
+ err = info ? hkdfResult(&hkdf, 0, info, infolen,
+
+
+
+Eastlake & Hansen Informational [Page 111]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+ Message_Digest, okmlen) :
+ keyarray ? hmacResult(&hmac, Message_Digest) :
+ USHAResult(&sha, Message_Digest);
+ if (err != shaSuccess) {
+ fprintf(stderr, "hash(): %s Result Error %d, could not compute "
+ "message digest.\n",
+ info ? "hkdf" : keyarray ? "hmac" : "sha", err);
+ return err;
+ }
+
+ sprintf(buf, "%d", testno+1);
+ printResult(Message_Digest, info ? okmlen : hashsize,
+ hashes[hashno].name, info ? "hkdf standard test" :
+ keyarray ? "hmac standard test" : "sha standard test", buf,
+ resultarray, printResults, printPassFail);
+
+ return err;
+}
+
+/*
+ * Exercise an HKDF series. The input is the testarray,
+ * repeated repeatcount times, followed by the extrabits. If the
+ * result is known, it is in resultarray in uppercase hex.
+ */
+int hashHkdf(int testno, int loopno, int hashno,
+ int printResults, int printPassFail)
+{
+ int err;
+ unsigned char prk[USHAMaxHashSize+1];
+ uint8_t okm[255 * USHAMaxHashSize+1];
+ char buf[20];
+
+ if (printResults == PRINTTEXT) {
+ printf("\nTest %d: Iteration %d\n\tSALT\t'", testno+1, loopno);
+ printxstr(hkdfhashes[testno].saltarray,
+ hkdfhashes[testno].saltlength);
+ printf("'\n\tIKM\t'");
+ printxstr(hkdfhashes[testno].ikmarray,
+ hkdfhashes[testno].ikmlength);
+ printf("'\n\tINFO\t'");
+ printxstr(hkdfhashes[testno].infoarray,
+ hkdfhashes[testno].infolength);
+ printf("'\n");
+ printf(" L=%d bytes\n", hkdfhashes[testno].okmlength);
+ }
+
+ /* Run hkdf() against the test vectors */
+ err = hkdf(hkdfhashes[testno].whichSha,
+
+
+
+Eastlake & Hansen Informational [Page 112]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+ (const uint8_t *) hkdfhashes[testno].saltarray,
+ hkdfhashes[testno].saltlength,
+ (const uint8_t *) hkdfhashes[testno].ikmarray,
+ hkdfhashes[testno].ikmlength,
+ (const uint8_t *) hkdfhashes[testno].infoarray,
+ hkdfhashes[testno].infolength, okm,
+ hkdfhashes[testno].okmlength);
+ if (err != shaSuccess) {
+ fprintf(stderr, "hashHkdf(): hkdf Error %d.\n", err);
+ return err;
+ }
+ sprintf(buf, "hkdf %d", testno+1);
+ printResult(okm, hkdfhashes[testno].okmlength,
+ USHAHashName(hkdfhashes[testno].whichSha), "hkdf standard test",
+ buf, hkdfhashes[testno].okmarray, printResults, printPassFail);
+
+ /* Now run hkdfExtract() by itself against the test vectors */
+ /* to verify the intermediate results. */
+ err = hkdfExtract(hkdfhashes[testno].whichSha,
+ (const uint8_t *) hkdfhashes[testno].saltarray,
+ hkdfhashes[testno].saltlength,
+ (const uint8_t *) hkdfhashes[testno].ikmarray,
+ hkdfhashes[testno].ikmlength, prk);
+ if (err != shaSuccess) {
+ fprintf(stderr, "hashHkdf(): hkdfExtract Error %d.\n", err);
+ return err;
+ }
+ sprintf(buf, "hkdfExtract %d", testno+1);
+ printResult(prk, USHAHashSize(hkdfhashes[testno].whichSha),
+ USHAHashName(hkdfhashes[testno].whichSha), "hkdf standard test",
+ buf, hkdfhashes[testno].prkarray, printResults, printPassFail);
+
+ /* Now run hkdfExpand() by itself against the test vectors */
+ /* using the intermediate results from hkdfExtract. */
+ err = hkdfExpand(hkdfhashes[testno].whichSha, prk,
+ USHAHashSize(hkdfhashes[testno].whichSha),
+ (const uint8_t *)hkdfhashes[testno].infoarray,
+ hkdfhashes[testno].infolength, okm, hkdfhashes[testno].okmlength);
+ if (err != shaSuccess) {
+ fprintf(stderr, "hashHkdf(): hkdfExpand Error %d.\n", err);
+ return err;
+ }
+ sprintf(buf, "hkdfExpand %d", testno+1);
+ printResult(okm, hkdfhashes[testno].okmlength,
+ USHAHashName(hkdfhashes[testno].whichSha), "hkdf standard test",
+ buf, hkdfhashes[testno].okmarray, printResults, printPassFail);
+
+ return err;
+
+
+
+Eastlake & Hansen Informational [Page 113]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+}
+
+/*
+ * Exercise a hash series of functions. The input is a filename.
+ * If the result is known, it is in resultarray in uppercase hex.
+ */
+int hashfile(int hashno, const char *hashfilename, int bits,
+ int bitcount, int skipSpaces, const unsigned char *keyarray,
+ int keylen, const unsigned char *info, int infolen, int okmlen,
+ const char *resultarray, int hashsize,
+ int printResults, int printPassFail)
+{
+ USHAContext sha;
+ HMACContext hmac;
+ HKDFContext hkdf;
+ int err, nread, c;
+ unsigned char buf[4096];
+ uint8_t Message_Digest_Buf[USHAMaxHashSize];
+ uint8_t *Message_Digest = Message_Digest_Buf;
+ unsigned char cc;
+ FILE *hashfp = (strcmp(hashfilename, "-") == 0) ? stdin :
+ fopen(hashfilename, "r");
+
+ if (!hashfp) {
+ fprintf(stderr, "cannot open file '%s'\n", hashfilename);
+ return shaStateError;
+ }
+
+ if (info) Message_Digest = malloc(okmlen);
+ memset(&sha, '\343', sizeof(sha)); /* force bad data into struct */
+ memset(&hmac, '\343', sizeof(hmac));
+ memset(&hkdf, '\343', sizeof(hkdf));
+ err = info ? hkdfReset(&hkdf, hashes[hashno].whichSha,
+ keyarray, keylen) :
+ keyarray ? hmacReset(&hmac, hashes[hashno].whichSha,
+ keyarray, keylen) :
+ USHAReset(&sha, hashes[hashno].whichSha);
+ if (err != shaSuccess) {
+ fprintf(stderr, "hashfile(): %sReset Error %d.\n",
+ info ? "hkdf" : keyarray ? "hmac" : "sha", err);
+ return err;
+ }
+
+ if (skipSpaces)
+ while ((c = getc(hashfp)) != EOF) {
+ if (!isspace(c)) {
+ cc = (unsigned char)c;
+ err = info ? hkdfInput(&hkdf, &cc, 1) :
+
+
+
+Eastlake & Hansen Informational [Page 114]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+ keyarray ? hmacInput(&hmac, &cc, 1) :
+ USHAInput(&sha, &cc, 1);
+ if (err != shaSuccess) {
+ fprintf(stderr, "hashfile(): %sInput Error %d.\n",
+ info ? "hkdf" : keyarray ? "hmac" : "sha", err);
+ if (hashfp != stdin) fclose(hashfp);
+ return err;
+ }
+ }
+ }
+ else
+ while ((nread = fread(buf, 1, sizeof(buf), hashfp)) > 0) {
+ err = info ? hkdfInput(&hkdf, buf, nread) :
+ keyarray ? hmacInput(&hmac, buf, nread) :
+ USHAInput(&sha, buf, nread);
+ if (err != shaSuccess) {
+ fprintf(stderr, "hashfile(): %s Error %d.\n",
+ info ? "hkdf" : keyarray ? "hmacInput" :
+ "shaInput", err);
+ if (hashfp != stdin) fclose(hashfp);
+ return err;
+ }
+ }
+
+ if (bitcount > 0)
+ err = info ? hkdfFinalBits(&hkdf, bits, bitcount) :
+ keyarray ? hmacFinalBits(&hmac, bits, bitcount) :
+ USHAFinalBits(&sha, bits, bitcount);
+ if (err != shaSuccess) {
+ fprintf(stderr, "hashfile(): %s Error %d.\n",
+ info ? "hkdf" : keyarray ? "hmacFinalBits" :
+ "shaFinalBits", err);
+ if (hashfp != stdin) fclose(hashfp);
+ return err;
+ }
+
+ err = info ? hkdfResult(&hkdf, 0, info, infolen,
+ Message_Digest, okmlen) :
+ keyarray ? hmacResult(&hmac, Message_Digest) :
+ USHAResult(&sha, Message_Digest);
+ if (err != shaSuccess) {
+ fprintf(stderr, "hashfile(): %s Error %d.\n",
+ info ? "hkdf" : keyarray ? "hmacResult" :
+ "shaResult", err);
+ if (hashfp != stdin) fclose(hashfp);
+ return err;
+ }
+
+
+
+
+Eastlake & Hansen Informational [Page 115]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+ printResult(Message_Digest, info ? okmlen : hashsize,
+ hashes[hashno].name, "file", hashfilename, resultarray,
+ printResults, printPassFail);
+
+ if (hashfp != stdin) fclose(hashfp);
+ if (info) free(Message_Digest);
+ return err;
+}
+
+/*
+ * Exercise a hash series of functions through multiple permutations.
+ * The input is an initial seed. That seed is replicated 3 times.
+ * For 1000 rounds, the previous three results are used as the input.
+ * This result is then checked, and used to seed the next cycle.
+ * If the result is known, it is in resultarrays in uppercase hex.
+ */
+void randomtest(int hashno, const char *seed, int hashsize,
+ const char **resultarrays, int randomcount,
+ int printResults, int printPassFail)
+{
+ int i, j; char buf[20];
+ unsigned char SEED[USHAMaxHashSize], MD[1003][USHAMaxHashSize];
+
+ /* INPUT: Seed - A random seed n bits long */
+ memcpy(SEED, seed, hashsize);
+ if (printResults == PRINTTEXT) {
+ printf("%s random test seed= '", hashes[hashno].name);
+ printxstr(seed, hashsize);
+ printf("'\n");
+ }
+
+ for (j = 0; j < randomcount; j++) {
+ /* MD0 = MD1 = MD2 = Seed; */
+ memcpy(MD[0], SEED, hashsize);
+ memcpy(MD[1], SEED, hashsize);
+ memcpy(MD[2], SEED, hashsize);
+ for (i=3; i<1003; i++) {
+ /* Mi = MDi-3 || MDi-2 || MDi-1; */
+ USHAContext Mi;
+ memset(&Mi, '\343', sizeof(Mi)); /* force bad data into struct */
+ USHAReset(&Mi, hashes[hashno].whichSha);
+ USHAInput(&Mi, MD[i-3], hashsize);
+ USHAInput(&Mi, MD[i-2], hashsize);
+ USHAInput(&Mi, MD[i-1], hashsize);
+ /* MDi = SHA(Mi); */
+ USHAResult(&Mi, MD[i]);
+ }
+
+
+
+
+Eastlake & Hansen Informational [Page 116]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+ /* MDj = Seed = MDi; */
+ memcpy(SEED, MD[i-1], hashsize);
+
+ /* OUTPUT: MDj */
+ sprintf(buf, "%d", j);
+ printResult(SEED, hashsize, hashes[hashno].name, "random test",
+ buf, resultarrays ? resultarrays[j] : 0, printResults,
+ (j < RANDOMCOUNT) ? printPassFail : 0);
+ }
+}
+
+/*
+ * Look up a hash name.
+ */
+int findhash(const char *argv0, const char *opt)
+{
+ int i;
+ const char *names[HASHCOUNT][2] = {
+ { "0", "sha1" }, { "1", "sha224" }, { "2", "sha256" },
+ { "3", "sha384" }, { "4", "sha512" }
+ };
+ for (i = 0; i < HASHCOUNT; i++)
+ if ((strcmp(opt, names[i][0]) == 0) ||
+ (scasecmp(opt, names[i][1]) == 0))
+ return i;
+
+ fprintf(stderr, "%s: Unknown hash name: '%s'\n", argv0, opt);
+ usage(argv0);
+ return 0;
+}
+
+/*
+ * Run some tests that should invoke errors.
+ */
+void testErrors(int hashnolow, int hashnohigh, int printResults,
+ int printPassFail)
+{
+ USHAContext usha;
+ uint8_t Message_Digest[USHAMaxHashSize];
+ int hashno, err;
+
+ for (hashno = hashnolow; hashno <= hashnohigh; hashno++) {
+ memset(&usha, '\343', sizeof(usha)); /* force bad data */
+ USHAReset(&usha, hashno);
+ USHAResult(&usha, Message_Digest);
+ err = USHAInput(&usha, (const unsigned char *)"foo", 3);
+ if (printResults == PRINTTEXT)
+ printf ("\nError %d. Should be %d.\n", err, shaStateError);
+
+
+
+Eastlake & Hansen Informational [Page 117]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+ if ((printPassFail == PRINTPASSFAIL) ||
+ ((printPassFail == PRINTFAIL) && (err != shaStateError)))
+ printf("%s se: %s\n", hashes[hashno].name,
+ (err == shaStateError) ? "PASSED" : "FAILED");
+
+ err = USHAFinalBits(&usha, 0x80, 3);
+ if (printResults == PRINTTEXT)
+ printf ("\nError %d. Should be %d.\n", err, shaStateError);
+ if ((printPassFail == PRINTPASSFAIL) ||
+ ((printPassFail == PRINTFAIL) && (err != shaStateError)))
+ printf("%s se: %s\n", hashes[hashno].name,
+ (err == shaStateError) ? "PASSED" : "FAILED");
+
+ err = USHAReset(0, hashes[hashno].whichSha);
+ if (printResults == PRINTTEXT)
+ printf("\nError %d. Should be %d.\n", err, shaNull);
+ if ((printPassFail == PRINTPASSFAIL) ||
+ ((printPassFail == PRINTFAIL) && (err != shaNull)))
+ printf("%s usha null: %s\n", hashes[hashno].name,
+ (err == shaNull) ? "PASSED" : "FAILED");
+
+ switch (hashno) {
+ case SHA1: err = SHA1Reset(0); break;
+ case SHA224: err = SHA224Reset(0); break;
+ case SHA256: err = SHA256Reset(0); break;
+ case SHA384: err = SHA384Reset(0); break;
+ case SHA512: err = SHA512Reset(0); break;
+ }
+ if (printResults == PRINTTEXT)
+ printf("\nError %d. Should be %d.\n", err, shaNull);
+ if ((printPassFail == PRINTPASSFAIL) ||
+ ((printPassFail == PRINTFAIL) && (err != shaNull)))
+ printf("%s sha null: %s\n", hashes[hashno].name,
+ (err == shaNull) ? "PASSED" : "FAILED");
+ }
+}
+
+/* replace a hex string in place with its value */
+int unhexStr(char *hexstr)
+{
+ char *o = hexstr;
+ int len = 0, nibble1 = 0, nibble2 = 0;
+ if (!hexstr) return 0;
+ for ( ; *hexstr; hexstr++) {
+ if (isalpha((int)(unsigned char)(*hexstr))) {
+ nibble1 = tolower((int)(unsigned char)(*hexstr)) - 'a' + 10;
+ } else if (isdigit((int)(unsigned char)(*hexstr))) {
+ nibble1 = *hexstr - '0';
+
+
+
+Eastlake & Hansen Informational [Page 118]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+ } else {
+ printf("\nError: bad hex character '%c'\n", *hexstr);
+ }
+ if (!*++hexstr) break;
+ if (isalpha((int)(unsigned char)(*hexstr))) {
+ nibble2 = tolower((int)(unsigned char)(*hexstr)) - 'a' + 10;
+ } else if (isdigit((int)(unsigned char)(*hexstr))) {
+ nibble2 = *hexstr - '0';
+ } else {
+ printf("\nError: bad hex character '%c'\n", *hexstr);
+ }
+ *o++ = (char)((nibble1 << 4) | nibble2);
+ len++;
+ }
+ return len;
+}
+
+int main(int argc, char **argv)
+{
+ int i, err;
+ int loopno, loopnohigh = 1;
+ int hashno, hashnolow = 0, hashnohigh = HASHCOUNT - 1;
+ int testno, testnolow = 0, testnohigh;
+ int ntestnohigh = 0;
+ int printResults = PRINTTEXT;
+ int printPassFail = 1;
+ int checkErrors = 0;
+ char *hashstr = 0;
+ int hashlen = 0;
+ const char *resultstr = 0;
+ char *randomseedstr = 0;
+ int runHmacTests = 0;
+ int runHkdfTests = 0;
+ char *hmacKey = 0;
+ int hmaclen = 0;
+ char *info = 0;
+ int infolen = 0, okmlen = 0;
+ int randomcount = RANDOMCOUNT;
+ const char *hashfilename = 0;
+ const char *hashFilename = 0;
+ int extrabits = 0, numberExtrabits = 0;
+ int strIsHex = 0;
+
+ if ('A' != 0x41) {
+ fprintf(stderr, "%s: these tests require ASCII\n", argv[0]);
+ }
+
+ while ((i = getopt(argc, argv,
+
+
+
+Eastlake & Hansen Informational [Page 119]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+ "6b:B:def:F:h:i:Hk:l:L:mpPr:R:s:S:t:wxX")) != -1)
+ switch (i) {
+ case 'b': extrabits = strtol(optarg, 0, 0); break;
+ case 'B': numberExtrabits = atoi(optarg); break;
+ case 'd': runHkdfTests = 1; break;
+ case 'e': checkErrors = 1; break;
+ case 'f': hashfilename = optarg; break;
+ case 'F': hashFilename = optarg; break;
+ case 'h': hashnolow = hashnohigh = findhash(argv[0], optarg);
+ break;
+ case 'H': strIsHex = 1; break;
+ case 'i': info = optarg; infolen = strlen(optarg); break;
+ case 'k': hmacKey = optarg; hmaclen = strlen(optarg); break;
+ case 'l': loopnohigh = atoi(optarg); break;
+ case 'L': okmlen = strtol(optarg, 0, 0); break;
+ case 'm': runHmacTests = 1; break;
+ case 'P': printPassFail = 0; break;
+ case 'p': printResults = PRINTNONE; break;
+ case 'R': randomcount = atoi(optarg); break;
+ case 'r': randomseedstr = optarg; break;
+ case 's': hashstr = optarg; hashlen = strlen(hashstr); break;
+ case 'S': resultstr = optarg; break;
+ case 't': testnolow = ntestnohigh = atoi(optarg) - 1; break;
+ case 'w': printResults = PRINTRAW; break;
+ case 'x': printResults = PRINTHEX; break;
+ case 'X': printPassFail = 2; break;
+ case '6': printResults = PRINTBASE64; break;
+ default: usage(argv[0]);
+ }
+
+ if (strIsHex) {
+ hashlen = unhexStr(hashstr);
+ unhexStr(randomseedstr);
+ hmaclen = unhexStr(hmacKey);
+ infolen = unhexStr(info);
+ }
+ testnohigh = (ntestnohigh != 0) ? ntestnohigh:
+ runHmacTests ? (HMACTESTCOUNT-1) :
+ runHkdfTests ? (HKDFTESTCOUNT-1) :
+ (TESTCOUNT-1);
+ if ((testnolow < 0) ||
+ (testnohigh >= (runHmacTests ? HMACTESTCOUNT : TESTCOUNT)) ||
+ (hashnolow < 0) || (hashnohigh >= HASHCOUNT) ||
+ (hashstr && (testnolow == testnohigh)) ||
+ (randomcount < 0) ||
+ (resultstr && (!hashstr && !hashfilename && !hashFilename)) ||
+ ((runHmacTests || hmacKey) && randomseedstr) ||
+ (hashfilename && hashFilename) ||
+
+
+
+Eastlake & Hansen Informational [Page 120]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+ (info && ((infolen <= 0) || (okmlen <= 0))) ||
+ (info && !hmacKey))
+ usage(argv[0]);
+
+ /*
+ * Perform SHA/HMAC tests
+ */
+ for (hashno = hashnolow; hashno <= hashnohigh; ++hashno) {
+ if (printResults == PRINTTEXT)
+ printf("Hash %s\n", hashes[hashno].name);
+ err = shaSuccess;
+
+ for (loopno = 1; (loopno <= loopnohigh) && (err == shaSuccess);
+ ++loopno) {
+ if (hashstr)
+ err = hash(0, loopno, hashno, hashstr, hashlen, 1,
+ numberExtrabits, extrabits, (const unsigned char *)hmacKey,
+ hmaclen, (const uint8_t *) info, infolen, okmlen, resultstr,
+ hashes[hashno].hashsize, printResults, printPassFail);
+
+ else if (randomseedstr)
+ randomtest(hashno, randomseedstr, hashes[hashno].hashsize, 0,
+ randomcount, printResults, printPassFail);
+
+ else if (hashfilename)
+ err = hashfile(hashno, hashfilename, extrabits,
+ numberExtrabits, 0,
+ (const unsigned char *)hmacKey, hmaclen,
+ (const uint8_t *) info, infolen, okmlen,
+ resultstr, hashes[hashno].hashsize,
+ printResults, printPassFail);
+
+ else if (hashFilename)
+ err = hashfile(hashno, hashFilename, extrabits,
+ numberExtrabits, 1,
+ (const unsigned char *)hmacKey, hmaclen,
+ (const uint8_t *) info, infolen, okmlen,
+ resultstr, hashes[hashno].hashsize,
+ printResults, printPassFail);
+
+ else /* standard tests */ {
+ for (testno = testnolow;
+ (testno <= testnohigh) && (err == shaSuccess); ++testno) {
+ if (runHmacTests) {
+ err = hash(testno, loopno, hashno,
+ hmachashes[testno].dataarray[hashno] ?
+ hmachashes[testno].dataarray[hashno] :
+ hmachashes[testno].dataarray[1] ?
+
+
+
+Eastlake & Hansen Informational [Page 121]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+ hmachashes[testno].dataarray[1] :
+ hmachashes[testno].dataarray[0],
+ hmachashes[testno].datalength[hashno] ?
+ hmachashes[testno].datalength[hashno] :
+ hmachashes[testno].datalength[1] ?
+ hmachashes[testno].datalength[1] :
+ hmachashes[testno].datalength[0],
+ 1, 0, 0,
+ (const unsigned char *)(
+ hmachashes[testno].keyarray[hashno] ?
+ hmachashes[testno].keyarray[hashno] :
+ hmachashes[testno].keyarray[1] ?
+ hmachashes[testno].keyarray[1] :
+ hmachashes[testno].keyarray[0]),
+ hmachashes[testno].keylength[hashno] ?
+ hmachashes[testno].keylength[hashno] :
+ hmachashes[testno].keylength[1] ?
+ hmachashes[testno].keylength[1] :
+ hmachashes[testno].keylength[0],
+ 0, 0, 0,
+ hmachashes[testno].resultarray[hashno],
+ hmachashes[testno].resultlength[hashno],
+ printResults, printPassFail);
+ } else if (runHkdfTests) {
+ err = hashHkdf(testno, loopno, hashno,
+ printResults, printPassFail);
+ } else { /* sha tests */
+ err = hash(testno, loopno, hashno,
+ hashes[hashno].tests[testno].testarray,
+ hashes[hashno].tests[testno].length,
+ hashes[hashno].tests[testno].repeatcount,
+ hashes[hashno].tests[testno].numberExtrabits,
+ hashes[hashno].tests[testno].extrabits,
+ 0, 0, 0, 0, 0,
+ hashes[hashno].tests[testno].resultarray,
+ hashes[hashno].hashsize,
+ printResults, printPassFail);
+ }
+ }
+ if (!runHmacTests && !runHkdfTests) {
+ randomtest(hashno, hashes[hashno].randomtest,
+ hashes[hashno].hashsize, hashes[hashno].randomresults,
+ RANDOMCOUNT, printResults, printPassFail);
+ }
+ }
+ }
+ }
+
+
+
+
+Eastlake & Hansen Informational [Page 122]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+ /* Test some error returns */
+ if (checkErrors) {
+ testErrors(hashnolow, hashnohigh, printResults, printPassFail);
+ }
+
+ return 0;
+}
+
+/*
+ * Compare two strings, case independently.
+ * Equivalent to strcasecmp() found on some systems.
+ */
+int scasecmp(const char *s1, const char *s2)
+{
+ for (;;) {
+ char u1 = tolower((int)(unsigned char)(*s1++));
+ char u2 = tolower((int)(unsigned char)(*s2++));
+ if (u1 != u2)
+ return u1 - u2;
+ if (u1 == '\0')
+ return 0;
+ }
+}
+
+9. Security Considerations
+
+ This document is intended to provide convenient open source access by
+ the Internet community to the United States of America Federal
+ Information Processing Standard Secure Hash Algorithms (SHAs) [FIPS
+ 180-2], HMACs based thereon, and HKDF. No independent assertion of
+ the security of these functions by the authors for any particular use
+ is intended.
+
+ See [RFC6194] for a discussion of SHA-1 Security Considerations.
+
+10. Acknowledgements
+
+ Thanks for the corrections to [RFC4634] that were provided by Alfred
+ Hoenes and Jan Andres and to Alfred's comments on the document
+ hereof.
+
+ Also to the following in alphabetic order, whose comments lead to
+ improvements in the document: James Carlson, Russ Housley, Tero
+ Kivinen, Juergen Quittek, and Sean Turner.
+
+
+
+
+
+
+
+Eastlake & Hansen Informational [Page 123]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+11. References
+
+11.1. Normative References
+
+ [RFC2104] Krawczyk, H., Bellare, M., and R. Canetti, "HMAC: Keyed-
+ Hashing for Message Authentication", RFC 2104, February
+ 1997.
+
+ [RFC5869] Krawczyk, H. and P. Eronen, "HMAC-based Extract-and-Expand
+ Key Derivation Function (HKDF)", RFC 5869, May 2010.
+
+ [SHS] "Secure Hash Standard", United States of American,
+ National Institute of Science and Technology, Federal
+ Information Processing Standard (FIPS) 180-3,
+ http://csrc.nist.gov/publications/fips/fips180-3/
+ fips180-3_final.pdf.
+
+ [US-ASCII] ANSI, "USA Standard Code for Information Interchange",
+ X3.4, American National Standards Institute: New York,
+ 1968.
+
+11.2. Informative References
+
+ [RFC3174] Eastlake 3rd, D. and P. Jones, "US Secure Hash Algorithm 1
+ (SHA1)", RFC 3174, September 2001.
+
+ [RFC3874] Housley, R., "A 224-bit One-way Hash Function:
+ SHA-224", RFC 3874, September 2004.
+
+ [RFC4055] Schaad, J., Kaliski, B., and R. Housley, "Additional
+ Algorithms and Identifiers for RSA Cryptography for use in
+ the Internet X.509 Public Key Infrastructure Certificate
+ and Certificate Revocation List (CRL) Profile", RFC 4055,
+ June 2005.
+
+ [RFC4086] Eastlake 3rd, D., Schiller, J., and S. Crocker,
+ "Randomness Requirements for Security", BCP 106, RFC 4086,
+ June 2005.
+
+ [RFC4634] Eastlake 3rd, D. and T. Hansen, "US Secure Hash Algorithms
+ (SHA and HMAC-SHA)", RFC 4634, July 2006.
+
+ [RFC6194] Polk, T., Chen, L., Turner, S., and P. Hoffman, "Security
+ Considerations for the SHA-0 and SHA-1 Message-Digest
+ Algorithms", RFC 6194, March 2011.
+
+
+
+
+
+
+Eastlake & Hansen Informational [Page 124]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+ [SHAVS] "The Secure Hash Algorithm Validation System (SHAVS)",
+ http://csrc.nist.gov/groups/STM/cavp/documents/shs/
+ SHAVS.pdf, July 2004.
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+Eastlake & Hansen Informational [Page 125]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+Appendix: Changes from RFC 4634
+
+ The following changes were made to RFC 4634 to produce this document:
+
+ 1. Add code for HKDF and brief text about HKDF with pointer to
+ [RFC5869].
+
+ 2. Fix numerous errata filed against [RFC4634] as included below.
+ Note that in no case did the old code return an incorrect hash
+ value.
+
+ 2.a. Correct some of the error return values which has erroneously
+ been "shaNull" to the correct "shaInputTooLong" error.
+
+ 2.b. Update comments and variable names within the code for
+ consistency and clarity and other editorial changes.
+
+ 2.c. The previous code for SHA-384 and SHA-512 would stop after
+ 2^93 bytes (2^96 bits). The fixed code handles up to 2^125
+ bytes (2^128 bits).
+
+ 2.d. Add additional error checking including a run time check in
+ the test driver to detect attempts to run the test driver
+ after compilation using some other character set instead of
+ [US-ASCII].
+
+ 3. Update boilerplate, remove special license in [RFC4634] as new
+ boilerplate mandates simplified BSD license.
+
+ 4. Replace MIT version of getopt with new code to satisfy IETF
+ incoming and outgoing license restrictions.
+
+ 5. Add references to [RFC6194].
+
+ 6. Other assorted editorial improvements.
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+Eastlake & Hansen Informational [Page 126]
+
+RFC 6234 SHAs, HMAC-SHAs, and HKDF May 2011
+
+
+Author's Address
+
+ Donald Eastlake
+ Huawei
+ 155 Beaver Street
+ Milford, MA 01757 USA
+
+ Telephone: +1-508-333-2270
+ EMail: d3e3e3@gmail.com
+
+
+ Tony Hansen
+ AT&T Laboratories
+ 200 Laurel Ave.
+ Middletown, NJ 07748 USA
+
+ Telephone: +1-732-420-8934
+ EMail: tony+shs@maillennium.att.com
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+Eastlake & Hansen Informational [Page 127]
+