# Understanding assumptions about machine word size in analyzing computer algorithms

I am reading the book Introduction to Algorithms by Thomas H. Cormen, Charles E. Leiserson, Ronald L. Rivest, Clifford Stein.. In the second chapter under "Analyzing Algorithms" it is mentioned that :

We also assume a limit on the size of each word of data. For example , when working with inputs of size n , we typically assume that integers are represented by c lg n bits for some constant c>=1 . We require c>=1 so that each word can hold the value of n , enabling us to index the individual input elements , and we restrict c to be a constant so that the word size doesn't grow arbitrarily .( If the word size could grow arbitrarily , we could store huge amounts of data in one word and operate on it all in constant time - clearly an unrealistic scenario.)

My questions are why this assumption that each integer should be represented by c lg n bits and also how c>=1 being the case allows us to index the individual input elements ?

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I had exact same problem! – Eugene Aug 26 '12 at 22:14

first, by `lg` they apparently mean log base 2, so `lg n` is the number of bits in `n`.

then what they are saying is that if they have an algorithm that takes a list of numbers (i am being more specific in my example to help make it easier to understand) like `1,2,3,...n` then they assume that:

• a "word" in memory is big enough to hold any of those numbers.

• a "word" in memory is not big enough to hold all the numbers (in one single word, packed in somehow).

• when calculating the number of "steps" in an algorithm, an operation on one "word" takes one step.

the reason they are doing this is to keep the analysis realistic (you can only store numbers up to some size in "native" types; after that you need to switch to arbitrary precision libraries) without choosing a particular example (like 32 bit integers) that might be inappropriate in some cases, or become outdated.

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You need at least lg n bits to represent integers of size n, so that's a lower bound on the number of bits needed to store inputs of size n. Setting the constant c >= 1 makes it a lower bound. If the constant multiplier were less than 1, you wouldn't have enough bits to store n.

This is a simplifying step in the RAM model. It allows you to treat each individual input value as though it were accessible in a single slot (or "word") of memory, instead of worrying about complications that might arise otherwise. (Loading, storing, and copying values of different word sizes would take differing amounts of time if we used a model that allowed varying word lengths.) This is what's meant by "enabling us to index the individual input elements." Each input element of the problem is assumed to be accessible at a single address, or index (meaning it fits in one word of memory), simplifying the model.

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"You need at least lg n bits to represent integers of size n, so that's a lower bound on the number of bits needed to store inputs of size n." . Do you mean we need that many bits to store all the inputs or individual inputs ? – Geek Jul 21 '12 at 14:16
@BilltheLizard: the "size" of an integer is rather ambiguous :) – larsmans Jul 21 '12 at 14:17
@larsmans but why are they making such an assumption we can have inputs like 123456, 2, 3456789, 234 . So here n=4 . can lg 4 bits hold 123456 ? – Geek Jul 21 '12 at 14:20
@larsmans I see . I was confused by the "inputs of size n" and interpreted it like a input sequence of size n – Geek Jul 21 '12 at 14:23
@Geek: wait a minute, I totally misread the quote. n actually is the size of the input. Cormen et al. are postulating that the size of integers is a function of the input size. You need large word sizes to handle large problems, but the word size must be capped somehow. – larsmans Jul 21 '12 at 14:27