# Why the 14 most significant bits of 17612864 is 67?

At the bottom of Page 264 of CLRS, the authors say after obtaining r0 = 17612864, the 14 most significant bits of r0 yield the hash value h(k) = 67. I do not understand why it gives 67 since 67 in binary is 1000011 which is 7 bits.

EDIT In the textbook: As an example, suppose we have k = 123456, p = 14, m = 2^14 = 16384, and w = 32. Adapting Knuth's suggestion, we choose A to be the fraction of the form s/2^32 that is closest to (\sqrt(5) - 1) / 2, so that A = 2654435769/2^32. then k*s = 327706022297664 = (76300 * 2^32) + 17612864, and so r1 = 76300 and r0 = 17612864. The 14 most significant bits of r0 yield the value h(k)=67.

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I do not know how possible it would be, but including here a bit more of the context instead of just the page number on the book might help to find someone that can answer your question. –  David Bejar Nov 2 '12 at 2:35
Look at the figure 11.4 (at the top of the page 264), w is 32, you extract p (14) bits from the left (most significant) of a 32-bit number. –  Esailija Nov 2 '12 at 2:51
Thank you! Now I can understand this figure. –  zxia31 Nov 2 '12 at 3:00

17612864 = 0x010CC040 =

0000 0001 0000 1100 1100 0000 0100 0000


Most significant 14 bits of that is

0000 0001 0000 11


Which is 0x43, which is 67

Also:

int32 input = 17612864;
int32 output = input >> (32-14); //67

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I did not take the machine word size into account. Indeed, the authors mention before that suppose the word size of the machine is w bits and that k fits into a single word. I did not fully understand its meaning. –  zxia31 Nov 2 '12 at 2:54