# High-precision program that calculates 2^n

I'm building a program in C that can get powers of `2`. The user inputs the value of `n`, and the program calculates `2^n`.

Here's the code.

The problem comes when I input `100`

What I am getting:

``````1,267,650,600,228,229,400,000,000,000,000
``````

What I should get

``````1,267,650,600,228,229,401,496,703,205,376
``````

It has to be coded entirely in ANSI C. Any ideas on how to increase the precision? The maximum value of `N` has to be `256` (256 bits, I imagine, which means the maximum output should be `2^256`).

What I'm lacking here is precision, and I don't know how to fix that. Any ideas?

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–  lqs Nov 1 '12 at 2:45
Bignum on C and C++ has got to be one of the most commonly asked questions that have a "difficult" solution. –  Mysticial Nov 1 '12 at 2:48
As @Mysticial makes reference to, you are looking for a `bignum` solution. For info on what this is, look at wikipedia: en.wikipedia.org/wiki/Arbitrary-precision_arithmetic –  lnafziger Nov 1 '12 at 2:54
@Mysticial you are wrong about this being an extremely difficult problem. Implementing arbitrary precision addition is not exactly hardest thing in the world. –  MK. Nov 1 '12 at 2:59
@Kevin That's not cheating, that's intelligent. What's not intelligent is all this nonsense about difficulty and `[long] double` types, which aren't appropriate to this integer problem. –  Jim Balter Nov 1 '12 at 3:16

Here is my quick and dirty implementation of hammar's approach., storing the decimal number as a C string with the digits in reverse order.

Run the code on ideone

``````void doubleDecimal(char * decimal)
{
char buffer[256] = "";
char c;
unsigned char d, carry = 0;
int i = 0;

while (c = decimal[i])
{
d = 2 * (c - '0') + carry;
buffer[i] = (d % 10) + '0';
carry = d / 10;
i++;
}

if (carry > 0)
buffer[i++] = (carry % 10) + '0';

buffer[i] = '\0';
strncpy(decimal, buffer, 256);
}

void reverse(char * str)
{
int i = 0;
int j = strlen(str) - 1;

while (j > i)
{
char tmp = str[i];
str[i] = str[j];
str[j] = tmp;

i++;
j--;
}
}

int main(void)
{
char decimal[256] = "1";
int i;

for (i = 0; i < 100; i++)
doubleDecimal(decimal);

reverse(decimal);
printf("%s", decimal);

return 0;
}
``````

Output:

``````1267650600228229401496703205376
``````
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strncpy is almost always the wrong tool (it is here), and should never ever be suggested to beginners. –  Jim Balter Nov 1 '12 at 3:58
@Jim perhaps you could suggest the correct function for copying one string to another? –  Brian L Nov 1 '12 at 4:01
`strcpy` is fine here ... if you stored more than 256 bytes in buffer you've already got undefined behavior. Generally, if you want safe string copies and you want to use a standard C library routine, snprintf works. Myself, I have my own library that takes care of this deficiency. But `strncpy` is wrong wrong wrong because a) it NUL-fills pointlessly and this can be detectably costly with large arrays and loops and b) it doesn't NUL-terminate the result. –  Jim Balter Nov 1 '12 at 4:06
@Jim thanks, you prompted me to do some research about the behaviour of `strncpy`. You are correct to say that `strcpy` is fine for the range of integers we are dealing with (max 2^256). –  Brian L Nov 1 '12 at 4:22
What happened to "give the man a fish". Was it really so good an idea to do the person's homework for him? –  Cheers and hth. - Alf Nov 2 '12 at 13:01

I think it's easiest if you work in base 10 from the start. This is because while calculating powers of 2 in binary is trivial, the conversion back to base 10 is a lot harder.

If you have an array of base 10 digits1, you only need to implement base 10 addition with carry to be able to multiply by 2 (by adding the number to itself). Do that `n` times in a loop and you have your answer.

If you wish to support higher exponents, you can also look into implementing exponentiation by squaring, but that's harder, since you'll need general multiplication, not just by 2 for that.

1 Tip: It's more convenient if you store the digits in reverse order.

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I'm glad someone gave an intelligent answer. It's amazing how few people can manage to think clearly about problem solving ... they know about bits and can't manage to think past them. –  Jim Balter Nov 1 '12 at 3:25
small endian base 10 numbering, I like it! –  dave Nov 1 '12 at 3:26
@annoying_squid: No, either way the entire work is base conversion. –  R.. Nov 1 '12 at 5:11
By the way, multiplying by 2 at each step is rather inefficient. I would multiply by 536870912 at each step (the largest power of 2 smaller than the largest power of 10 that fits in a 32-bit integer) and work base-1000000000 rather than base-10. –  R.. Nov 1 '12 at 5:13

double is a (probably) 64bit value. You can't store 256 bits of precision in 64 bits. The reason that you are getting a number that is sort of close is because floating point numbers are stored with varying precision -- not all sequential numbers can be represented, but you can represent very large numbers. Pretty useless in this case. What you want is either to use an arbitrary precision library or, since this is probably homework, you are expected to write your own.

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The homework tag is obsolete, please stop using it. –  lnafziger Nov 1 '12 at 2:52
How about using arrays? The problem is implementing them properly. –  Icekilla Nov 1 '12 at 2:55
@Icekilla yes, you can do it with arrays. That would be "rolling your own" bigint library. –  MK. Nov 1 '12 at 2:57
@MK.Oh c'mon. Eavery schoolkid learned how to add by hand. All that's called for here is repeatedly doubling a number ... do it with a char array of ASCII digits. –  Jim Balter Nov 1 '12 at 3:22
@JimBalter that's exactly what bigint library does. –  MK. Nov 1 '12 at 3:25

A typical `double`, using 64-bit IEEE 754, has about 51 bits precision, IIRC.

Most probably the point of supporting exponents up to 256 is to exceed that precision, and also the precision of a `long double` or `long long`, so that you have to do things yourself.

As a homework exercise, then,

• Store decimal digit values in an array + a digit count
• Implement doubling of the value in such array + count
-

A few things you'll want to think about to solve this:

1. You are only dealing with integers so you should use an integer representation (you will need to roll your own because you can't use long long which is "only" 64 bits long).
2. Powers of 2 you say -how convenient - computers store numbers using powers of 2 (you'll only need to use shift operations and bit fiddling .... no multiplications will be needed).
3. How can you convert a base 2 number to a base 10 number for display purposes (think of division and outputting one number at a time (think about what a hardware divisor does in order to get the bit manipulations correct).
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4. Probably the best way to store the bits would be in a character array.... –  lnafziger Nov 1 '12 at 3:04
care to elaborate? How do you magically convert binary to decimal? –  MK. Nov 1 '12 at 3:28
magically converting from binary to decimal isn't so difficult (okay we might have to implement some arithmetic operators for our type); it's a first year university assignment. –  dave Nov 1 '12 at 3:30
dave, you're completely missing the point. To convert to decimal requires division and mod 10 of your multiword binary number ... a binary number that is itself pointless because it only holds a single 1 bit. Yes it's not magic, but the conversion is the whole problem. –  Jim Balter Nov 1 '12 at 3:33
@JimBalter: how am I missing the point, have a look at step 3 - think about hardware division. It can be done. I wasn't trying to solve the problem for him just giving him a way to get the solution (it's better than using double, but not as good as hammar's). –  dave Nov 1 '12 at 3:42

You can't the store 256 bits of precision in 64 bits. Reason that you are getting a number to close is because floating point numbers are stored with varying precision. To all sequential numbers can be represented, but you can represent very large numbers. Pretty useless in this case.

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That's not an answer. –  Jim Balter Nov 1 '12 at 3:27
``````#include <conio.h>
#include <stdio.h>
#include <stdlib.h>
#include <string.h>

//constants
#define MAX_DIGITS 1000

//big integer number struct
struct bigint {
char Digits[MAX_DIGITS];
};

//assign a value
void assign(struct bigint* Number,int Value) {
if (Value!=1) {
printf("Can not assign value other than 1\n");
exit(0);
}
memset(Number,0,sizeof(bigint));
Number->Digits[0] = Value;
}

//multiply the big integer number with value
void multiply(struct bigint* Number,int Value) {
int Digit,New_Digit;
int Carry = 0;

for (int Index=0; Index<MAX_DIGITS; Index++) {
Digit     = Number->Digits[Index];
New_Digit = Digit*Value%10;
if (New_Digit+Carry<10) {
New_Digit = New_Digit+Carry;
Carry     = Digit*Value/10;
}
else {
New_Digit = (New_Digit+Carry)%10;
Carry     = (Digit*Value/10)+1;
}

//set the new digit
Number->Digits[Index] = New_Digit;
}//for loop
}

//print out the value of big integer type
void print(struct bigint* Number) {
int Index = MAX_DIGITS-1;
while (Number->Digits[Index]==0 && Index>=0)
Index--;

//the big integer value is zero
if (Index==-1) {
printf("0");
return;
}

while (Index>=0) {
printf("%u",Number->Digits[Index]);
Index--;
}
}

//main programme entry point
int main(int Argc,char** Args) {
int Power = 100;
struct bigint Number;

//assign the initial value
assign(&Number,1);

//do the multiplication
for (int Index=0; Index<Power; Index++)
multiply(&Number,2);

//print result
print(&Number);
getch();
}

//END-OF-FILE
``````
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