How many distinct numbers are from 1.5 x 10^{45} to 3.4 x 10^{38} (IEE754 single precision floats)?

Assuming that you are talking about the range in IEEE singleprecision float (the 1.5 x 10^45 is the smallest positive value it can represent that it can represent and 3.4 x 10^38 is the biggest positive value) we would have the following possible layouts for the 4 bytes this number would occupy:
Which should give us 2139095037 numbers inbetween the two. 


This isn't really programming. bc says (for whole integers):



I think you mean integer numbers. And also you mean between 3.4*10^38 and 1.5*10^45 because 1.5*10^45 is larger than the other one. Anyway the answer is the same as with smaller numbers. I'll assume you want to exclude these two numbers so : How many numbers are there between 2 and 10? The answer is 1021=7. Indeed 3,4,5,6,7,8,9 are 7 numbers. So the "formula" is :



I'm trying to guess what your question really is about. 1.4E45 is approximately the smallest number (sometimes known as epsilon) that can be represented in an IEEE 754 single. The largest number is approximately 3.4E38. A single is on a computer stored in a 32 bit value and one bit used for the sign. This leaves 31 bits to represent the numbers from epsilon to the maximum value. If we assume that all possible 31 bit numbers result in a valid single then the answer to your question is 2^31 or 2,147,483,648. As it has been pointed out this assumption is not correct as some values are Not a Number or NaN. You can read more about floating point numbers on Wikipedia 


Of course, this can be done programmaticaly, for any two float numbers in general. A "lexicographic index" is the ordered index of a float number, available among other things because IEEE 754 was designed in such a way to make it easy to produce. The basic rule is, for any two floats, if So calculating the number of IEEE 754 numbers between is a matter of subtracting the lexicographic indexes of the two numbers:
And of course, usage in this case:
In this case, the result is 

