Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

I'm having a hard time grasping data types in C. I'm going through a C book and one of the challenges asks what the maximum and minimum number a short can store.

Using sizeof(short); I can see that a short consumes 2 bytes. That means it's 16 bits, which means two numbers since it takes 8 bits to store the binary representation of a number. For example, 9 would be 00111001 which fills up one bit. So would it not be 0 to 99 for unsigned, and -9 to 9 signed?

I know I'm wrong, but I'm not sure why. It says here the maximum is (-)32,767 for signed, and 65,535 for unsigned.

short int, 2 Bytes, 16 Bits, -32,768 -> +32,767 Range (16kb)

share|improve this question
16-bit means that you have 16 switches that you can turn on and off. The total number of different on-off patterns is 2^16, which is 65536 different states. –  nhahtdh Jul 29 '12 at 17:30
Just out of curiosity, what are the allowed ranges by the standard? –  Antimony Jul 29 '12 at 17:35
@Antimony see the link in Richard J. Ross III's answer: {SHRT_MAX} Maximum value of type short. Minimum Acceptable Value: +32 767 –  Kay Jul 29 '12 at 17:40
remember even though 65536 = 2^16, as per limits.h max limit is 65535 because 65536 is considered as an overflow –  ocluser Jul 31 '12 at 4:24
add comment

5 Answers

up vote 5 down vote accepted

Think in decimal for a second. If you have only 2 digits for a number, that means you can store from 00 to 99 in them. If you have 4 digits, that range becomes 0000 to 9999.

A binary number is similar to decimal, except the digits can be only 0 and 1, instead of 0, 1, 2, 3, ..., 9.

If you have a number like this:


This is:

0*128 + 1*64 + 0*32 + 1*16 + 1*8 + 1*4 + 0*2 + 1*1 = 93

So as you can see, you can store bigger values than 9 in one byte. In an unsigned 8-bit number, you can actually store values from 00000000 to 11111111, which is 255 in decimal.

In a 2-byte number, this range becomes from 00000000 00000000 to 11111111 11111111 which happens to be 65535.

Your statement "it takes 8 bits to store the binary representation of a number" is like saying "it takes 8 digits to store the decimal representation of a number", which is not correct. For example the number 12345678901234567890 has more than 8 digits. In the same way, you cannot fit all numbers in 8 bits, but only 256 of them. That's why you get 2-byte (short), 4-byte (int) and 8-byte (long long) numbers. In truth, if you need even higher range of numbers, you would need to use a library.

As long as negative numbers are concerned, in a 2's-complement computer, they are just a convention to use the higher half of the range as negative values. This means the numbers that have a 1 on the left side are considered negative.

Nevertheless, these numbers are congruent modulo 256 (modulo 2^n if n bits) to their positive value as the number really suggests. For example the number 11111111 is 255 if unsigned, and -1 if signed which are congruent modulo 256.

share|improve this answer
Ok! Thank you. I got it. I have to think in "base-2" numbers instead of base-10. Makes sense now. My understand was way off! –  Mohamad Jul 29 '12 at 17:48
@Mohamad, exactly. It's fairly similar to base-10. Whenever you get confused, you can use this analogy to understand better ;) –  Shahbaz Jul 29 '12 at 17:59
add comment

The reference you read is correct. At least, for the usual C implementations where short is 16 bits - that's not actually fixed in the standard.

16 bits can hold 2^16 possible bit patterns, that's 65536 possibilities. Signed shorts are -32768 to 32767, unsigned shorts are 0 to 65535.

share|improve this answer
But it takes 8 bits to store a number, right? The 16 bits can store 2 numbers? I'm missing something here! –  Mohamad Jul 29 '12 at 17:32
@Mohamad one bit is enough to store a number in range [0;1]. Two bits can store 4 numbers. And so on … –  Kay Jul 29 '12 at 17:33
@Mohamad: No. 8 bits only stores numbers in the range 0-255. 16 bits stores numbers in the range 0-25535. 32-bit (usually int) can store somewhere in the 4 billions. You get the idea. It's all powers of two. –  Linuxios Jul 29 '12 at 17:34
add comment

This is defined in <limits.h>, and is SHRT_MIN & SHRT_MAX.

share|improve this answer
The OP clearly has problems with understanding binary numbers. How is this going to help him understand? –  Shahbaz Jul 29 '12 at 17:57
@Shahbaz: It's not going to make him understand, but it does give him some simple decimal numbers. <limits.h> can also be a very valuable tool when writing portable programs, and who knows if that was the question at the heart of the issue? This question has just the right balance of theory and practicality in it's answers. –  Linuxios Jul 29 '12 at 18:18
add comment

Others have posted pretty good solutions for you, but I don't think they have followed your thinking and explained where you were wrong. I will try.

I can see that a short consumes 2 bytes. That means it's 16 bits,

Up to this point you are correct (though short is not guaranteed to be 2 bytes long like int is not guaranteed to be 4 — the only guaranteed size by standard (if I remember correctly) is char which should always be 1 byte wide).

which means two numbers since it takes 8 bits to store the binary representation of a number.

From here you started to drift a bit. It doesn't really take 8 bits to store a number. Depending on a number, it may take 16, 32 64 or even more bits to store it. Dividing your 16 bits into 2 is wrong. If not a CPU implementation specifics, we could have had, for example, 2 bit numbers. In that case, those two bits could store values like:

00 - 0 in decimal
01 - 1 in decimal
10 - 2 in decimal
11 - 3 in decimal

To store 4, we need 3 bits. And so the value would "not fit" causing an overflow. Same applies to 16-bit number. For example, say we have unsigned "255" in decimal stored in 16-bits, the binary representation would be 0000000011111111. When you add 1 to that number, it becomes 0000000100000000 (256 in decimal). So if you had only 8 bits, it would overflow and become 0 because the most significant bit would have been discarded.

Now, the maximum unsigned number you can in 16 bits memory is — 1111111111111111, which is 65535 in decimal. In other words, for unsigned numbers - set all bits to 1 and that will yield you the maximum possible value.

For signed numbers, however, the most significant bit represents a sign — 0 for positive and 1 for negative. For negative, the maximum value is 1000000000000000, which is -32678 in base 10. The rules for signed binary representation are well described here.

Hope it helps!

share|improve this answer
thanks for that awesome explanation. I can't choose between you and Shahbaz, although props for following my line of thought! –  Mohamad Jul 30 '12 at 14:03
You are welcome! I was puzzled by these things myself :) Everything is in base 10 :-D –  user405725 Jul 30 '12 at 14:56
add comment

The formula to find the range of any unsigned binary represented number:

2 ^ (sizeof(type)*8)
share|improve this answer
Or to make it C code: 1 << (sizeof(type)*8) –  Kay Jul 29 '12 at 17:35
@Kay: How does that work? –  Linuxios Jul 29 '12 at 17:35
<< is the shift left operator. If you shift a 1 bit n bits left, you get 2 to the power of n. ^ means bitwise xor in C. –  Kay Jul 29 '12 at 17:38
@Kay: Thanks. I didn't know a power of two could be just a left shift. Comment +1? –  Linuxios Jul 29 '12 at 18:16
add comment

Your Answer


By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.