md5checksum.h

WTL使用MD5加密算法

          H(X,Y,Z) = X xor Y xor Z          I(X,Y,Z) = Y xor (X v not(Z))
   In each bit position F acts as a conditional: if X then Y else Z.
   The function F could have been defined using + instead of v since XY
   and not(X)Z will never have 1's in the same bit position.) It is
   interesting to note that if the bits of X, Y, and Z are independent
   and unbiased, the each bit of F(X,Y,Z) will be independent and   unbiased.
   The functions G, H, and I are similar to the function F, in that they
   act in "bitwise parallel" to produce their output from the bits of X,
   Y, and Z, in such a manner that if the corresponding bits of X, Y,
   and Z are independent and unbiased, then each bit of G(X,Y,Z),
   H(X,Y,Z), and I(X,Y,Z) will be independent and unbiased. Note that
   the function H is the bit-wise "xor" or "parity" function of its   inputs.
   This step uses a 64-element table T[1 ... 64] constructed from the
   sine function. Let T[i] denote the i-th element of the table, which
   is equal to the integer part of 4294967296 times abs(sin(i)), where i
   is in radians. The elements of the table are given in the appendix.
   Do the following:   
   
	 //Process each 16-word block.
     For i = 0 to N/16-1 do     // Copy block i into X.      
		For j = 0 to 15 do
			Set X[j] to M[i*16+j].     
        end //of loop on j

		 // Save A as AA, B as BB, C as CC, and D as DD.
		 AA = A     BB = B
		 CC = C     DD = D     

		 // Round 1.
		 // Let [abcd k s i] denote the operation
		 // a = b + ((a + F(b,c,d) + X[k] + T[i]) <<< s).
		 // Do the following 16 operations.
		 [ABCD  0  7  1]  [DABC  1 12  2]  [CDAB  2 17  3]  [BCDA  3 22  4]
		 [ABCD  4  7  5]  [DABC  5 12  6]  [CDAB  6 17  7]  [BCDA  7 22  8]
		 [ABCD  8  7  9]  [DABC  9 12 10]  [CDAB 10 17 11]  [BCDA 11 22 12]
		 [ABCD 12  7 13]  [DABC 13 12 14]  [CDAB 14 17 15]  [BCDA 15 22 16]

		 // Round 2.      
		 // Let [abcd k s i] denote the operation 
		 // a = b + ((a + G(b,c,d) + X[k] + T[i]) <<< s).
		 // Do the following 16 operations.
		 [ABCD  1  5 17]  [DABC  6  9 18]  [CDAB 11 14 19]  [BCDA  0 20 20]
		 [ABCD  5  5 21]  [DABC 10  9 22]  [CDAB 15 14 23]  [BCDA  4 20 24]
		 [ABCD  9  5 25]  [DABC 14  9 26]  [CDAB  3 14 27]  [BCDA  8 20 28]
		 [ABCD 13  5 29]  [DABC  2  9 30]  [CDAB  7 14 31]  [BCDA 12 20 32]

		 // Round 3.      
		 // Let [abcd k s t] denote the operation
		 // a = b + ((a + H(b,c,d) + X[k] + T[i]) <<< s).
		 // Do the following 16 operations.
		 [ABCD  5  4 33]  [DABC  8 11 34]  [CDAB 11 16 35]  [BCDA 14 23 36]
		 [ABCD  1  4 37]  [DABC  4 11 38]  [CDAB  7 16 39]  [BCDA 10 23 40]
		 [ABCD 13  4 41]  [DABC  0 11 42]  [CDAB  3 16 43]  [BCDA  6 23 44]
		 [ABCD  9  4 45]  [DABC 12 11 46]  [CDAB 15 16 47]  [BCDA  2 23 48]

		 // Round 4. 
		 // Let [abcd k s t] denote the operation
		 // a = b + ((a + I(b,c,d) + X[k] + T[i]) <<< s).
		 // Do the following 16 operations.
		 [ABCD  0  6 49]  [DABC  7 10 50]  [CDAB 14 15 51]  [BCDA  5 21 52]
		 [ABCD 12  6 53]  [DABC  3 10 54]  [CDAB 10 15 55]  [BCDA  1 21 56]
		 [ABCD  8  6 57]  [DABC 15 10 58]  [CDAB  6 15 59]  [BCDA 13 21 60]
		 [ABCD  4  6 61]  [DABC 11 10 62]  [CDAB  2 15 63]  [BCDA  9 21 64]

		 // Then perform the following additions. (That is increment each
		 //   of the four registers by the value it had before this block
		 //   was started.) 
		A = A + AA     B = B + BB     C = C + CC  D = D + DD   

	end // of loop on i

   3.5 Step 5. Output
   The message digest produced as output is A, B, C, D. That is, we
   begin with the low-order byte of A, and end with the high-order byte of D.
   This completes the description of MD5.
   
   Summary
   The MD5 message-digest algorithm is simple to implement, and provides
   a "fingerprint" or message digest of a message of arbitrary length.
   It is conjectured that the difficulty of coming up with two messages
   having the same message digest is on the order of 2^64 operations,
   and that the difficulty of coming up with any message having a given
   message digest is on the order of 2^128 operations. The MD5 algorithm
   has been carefully scrutinized for weaknesses. It is, however, a
   relatively new algorithm and further security analysis is of course
   justified, as is the case with any new proposal of this sort.


   5. Differences Between MD4 and MD5
   The following are the differences between MD4 and MD5:
       1.   A fourth round has been added.
       2.   Each step now has a unique additive constant.
       3.   The function g in round 2 was changed from (XY v XZ v YZ) to
       (XZ v Y not(Z)) to make g less symmetric.
       4.   Each step now adds in the result of the previous step.  This
       promotes a faster "avalanche effect".
       5.   The order in which input words are accessed in rounds 2 and
       3 is changed, to make these patterns less like each other.
       6.   The shift amounts in each round have been approximately
       optimized, to yield a faster "avalanche effect." The shifts in
       different rounds are distinct.

   References
   [1] Rivest, R., "The MD4 Message Digest Algorithm", RFC 1320, MIT and
       RSA Data Security, Inc., April 1992.
   [2] Rivest, R., "The MD4 message digest algorithm", in A.J.  Menezes
       and S.A. Vanstone, editors, Advances in Cryptology - CRYPTO '90
       Proceedings, pages 303-311, Springer-Verlag, 1991.
   [3] CCITT Recommendation X.509 (1988), "The Directory -
       Authentication Framework."APPENDIX A - Reference Implementation


   The level of security discussed in this memo is considered to be
   sufficient for implementing very high security hybrid digital-
   signature schemes based on MD5 and a public-key cryptosystem.
   Author's Address
   Ronald L. Rivest   Massachusetts Institute of Technology
   Laboratory for Computer Science   NE43-324   545 Technology Square
   Cambridge, MA  02139-1986   Phone: (617) 253-5880
   EMail: rivest@theory.lcs.mit.edu

*****************************************************************************************/
#include <atlmisc.h>
class CMD5Checksum  
{
public:
	//interface functions for the RSA MD5 calculation
	static CString GetMD5(BYTE* pBuf, UINT nLength);
//	static CString GetMD5(CFile& File);
//	static CString GetMD5(const CString& strFilePath);

protected:
	//constructor/destructor
	CMD5Checksum();
	virtual ~CMD5Checksum() {};

	//RSA MD5 implementation
	void Transform(BYTE Block[64]);
	void Update(BYTE* Input, ULONG nInputLen);
	CString Final();
	inline DWORD RotateLeft(DWORD x, int n);
	inline void FF( DWORD& A, DWORD B, DWORD C, DWORD D, DWORD X, DWORD S, DWORD T);
	inline void GG( DWORD& A, DWORD B, DWORD C, DWORD D, DWORD X, DWORD S, DWORD T);
	inline void HH( DWORD& A, DWORD B, DWORD C, DWORD D, DWORD X, DWORD S, DWORD T);
	inline void II( DWORD& A, DWORD B, DWORD C, DWORD D, DWORD X, DWORD S, DWORD T);

	//utility functions
	void DWordToByte(BYTE* Output, DWORD* Input, UINT nLength);
	void ByteToDWord(DWORD* Output, BYTE* Input, UINT nLength);

private:
	BYTE  m_lpszBuffer[64];		//input buffer
	ULONG m_nCount[2];			//number of bits, modulo 2^64 (lsb first)
	ULONG m_lMD5[4];			//MD5 checksum
};

#endif // !defined(AFX_MD5CHECKSUM_H__2BC7928E_4C15_11D3_B2EE_A4A60E20D2C3__INCLUDED_)