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I'm currently confused as to the behaviour of the DES algorithm provided by the GNU Crypto package. Here's a link to the algorithm in question: GNU Crypto DES algorithm

Originally I was merely wanting to extract the state of the key(s) at certain points, i.e. after PC-1, PC-2, the sub keys, etc. However, this plan's not going too well as the 56bit key expected after PC-1, appears to be 48 bits, going by the pc1m variable (working on the assumption that representation of the key (pc1m's value) when converted from decimal to binary is sound). As such I tried to figure out this piece of code:

for (i = 0; i < 56; i++) { l = PC1[i]; pc1m |= ((kb[l >>> 3] & (0x80 >>> (l & 7))) != 0) ? (1L << (55 - i)) : 0; }

However, my understanding of the bitwise operations is ropey, and although I have a vague understanding of how it's evaluating, I can't see the overall logic to it and how it works (or, rather why it appears to not actually work -- although the algorithm does encrypt and decrypt successfully going by the official test vectors). Where can I get the 56 bit permutation after PC-1?

It is also unclear to me what the code does after " // Encryption key first. ", as the pc1m variable is unchanged, and pcr appears to just copy the value after all that.

On the brightside, it appears clear, that "cooking" the keys creates the subkeys for the Feistel rounds.

As an aside, any other non-copyrighted Java implementations you can reference would be of interest to me, however, I would quite like to work with this implementation.

Any help would be much, much appreciated! Thanks.

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1 Answer 1

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The code snippet indeed is reading 56 bits from kb and rearranging them into pc1m (assuming the initial value of pc1m is 0).

// For each of the 56 bits
for (i = 0; i < 56; i++)
{
    L = PC1[i];                 // Get i-th bit index
    L_byte = L >>> 3;           // Get the byte where that bit is stored
    L_mask = 0x80 >>> (L & 7);  // Get the bit mask
    if (kb[L_byte] & L_mask] != 0)
    {
        // The PC1[i]-th bit of kb is set
        // so set bit at position 55-i (i=0 => MSB) in pc1m
        pc1m |= (1L << (55-i));
    }
}

so the value of kb after the 56-bit permutation described in PC1 will be available in pc1m as a single long integer.

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Thanks for the answer! I find your code much easier to understand also. However, the long integer found in pc1m, when converted from decimal to binary, is 48 bits long, rather than 56 bits. I think I must be missing something? Thanks again for your time. –  Cryptified by Cryptography Jan 27 '11 at 20:51
    
It depends on the value of kb and of PC1; for example if kb array is all zeros then I'd bet that the value of pc1m will be also 0, if kb is instead all 0xFF then pc1m will be more or less 72057594037927935 ;-). –  6502 Jan 27 '11 at 21:01
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