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From Computer System: A Programmer's Perspective http://csapp.cs.cmu.edu

Practice Problem 2.51

We saw in Problem 2.46 that the Patriot missile software approximated 0.1 as x =

0.00011001100110011001100(binary). 

Suppose instead that they had used IEEE round-to-even mode to determine an approximation x′ to 0.1 with 23 bits to the right of the binary point.

A. What is the binary representation of x′?

from the solution at the back of book, 
Looking at the nonterminating sequence for 1/10, we can see that the 2 bits to the right of the rounding position are 1, and so a better approximation to 1/10 would be obtained by incrementing x to get x′ = 0.00011001100110011001101, which is larger than 0.1.

B. What is the approximate decimal value of x′ − 0.1?

The solution says it's

We can see that x′ − 0.1 has binary representation: 0.0000000000000000000000000[1100]
Comparing this to the binary representation of 1 , we can see that it is 2^−22 × 0.1 , which is around 2.38 x 10^-8

My question for (B) is that how do we get

x' - 0.1 == 0.0 0000 0000 0000 0000 0000 0000[1100] ?

my calculation gives me 0.000 0000 0000 0000 0000 0000 0100 (about twice what the solution says)

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1 Answer 1

Using Julia

A.

julia> bits(0.1f0)
"00111101110011001100110011001101"

B. We can't compute the difference exactly (as there is no native decimal type), but you can print the decimal exactly, and subtract manually

julia> @printf "%.40f" 0.1f0
0.1000000014901161193847656250000000000000

So the difference is 0.0000000014901161193847656250000000000000 = 1.490116119384765625e-9

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