# How many time do I need to add 2 to get the value equivalent to 2 raised to 1000

I am trying to solve Project Euler Prob 16. I am planning to take two dimensional array to store the calculate and store the results. To calculate 2 raised to 3, I need to add 2, 4 times To calculate 2 raised to 4, I need to add 2, 8 times Similarly, how many times will I need to add 2 to the result to get 2 raised to 1000? Which data structure will be best suited for this (preferably in C++)? And what would be a good algorithm to solve this in C++?

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Thank you Nicolas78 –  pl56 Jan 3 '12 at 21:32
Exact duplicate of this question. –  Alexey Frunze Jan 3 '12 at 21:35
`nx2 = 2^m`, so, `n = (2^m)/2`. To get, 2^1000, you need to add 2 for 2^999 times. This answers your first question. Am I missing something? –  Bhaskar Jan 3 '12 at 21:37
You are going about this the wrong way. In order to get n (any even number) you always needs to add together 2 n/2 times; to get 2^n you need to add 2 together 2^(n-1) times. This tells you nothing. Can I give you the hint that you don't need to calculate the total to answer the question? –  DJClayworth Jan 3 '12 at 21:40
@BhaskarUpadhyayula: Thanks. Yes that is what I wanted. Thats a partial answer. I am also looking to store the numbers. Would anyone know which datastructure should I use (preferably c++) ? –  pl56 Jan 3 '12 at 21:43

A solution to exactly the same kind of problem has been previously shown here. The number of decimal digits in 21000 is `ceil((1000 + 1) * log10(2)) = 302`. One more character will be needed for the string terminator, `'\0'`. `* log10(2) = * 0.3` can be approximated with `/ 3 = * 0.3(3)`.

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This worked. One more question, can you please explain how does the AddNumber functions works. I tried stepping through the AddNumber function especially the foll code: ' if (ddigit > '9') { ddigit -= 10; carry = 1; carry = 0; }' and all I could see is that values were doubling like 8 was becoming 6 (without the carry). I would really be nice to understand this awesome function so that I can reuse it later. –  pl56 Jan 4 '12 at 20:33
It works the same way as you'd do it with pencil and paper. It adds digits of the two numbers going from the least significant to the most significant digits, propagating the carry and stopping when '\0' (string terminator) is encountered (there're two checks for it). The only difference is that it actually manipulates with C's characters, not digits, which is why '0' (numeric value of character '0') is subtracted in one place. Nothing fancy, just school arithmetic. –  Alexey Frunze Jan 4 '12 at 20:43
See a video, if you missed the concept. –  Alexey Frunze Jan 4 '12 at 21:17
Oh, I got that, thanks. However, the pointers were kind of obscuring the real value on the debugger inside the function. The only difference from the actual addition is that your code is adding from MSB to LSB. Also, you are just copying over the value in a temp variable to double it. So if it was something like 3 raised to 2010, then you would have to copy the values in 2 different variables and then perform the addn. If you had changed the *dst++ and *src++ to *dst-- and *src-- and then changed the addition accordingly, then you would not have to reverse the entire char array in the end. –  pl56 Jan 5 '12 at 20:57
@SameerShah: you got it wrong. The addition proceeds from LSB to MSB. How would you propagate carries if it was done the other way around??? The reversing is done because we customarily write and print numbers from the most significant digits to the least significant digits. The adding function was implemented in a way to support arbitrarily long numbers and have a simple interface. If you don't like it for whatever reason, change it. Transform it to a "doubler" instead of "adder", if you want to. It's up to you. –  Alexey Frunze Jan 5 '12 at 21:11