I understand the basics of how pointers work, but the following example confuses me.

int *myNum = 10; // Produces an error

char *myChar = "Something"; // Works fine

Why does assigning char work but integer doesn't (Maybe cause char is treated as an array)?

As well what confuses me when directly assigning a pointer variable, does it automatically get an address?

char *myChar = "Something";


char myChar = "Something";
char *charAddr = &myChar;

What would be the difference here, or equals?

  • 3
    char myChar = "Something"; does not work, because "Something" is not a char. – user253751 Mar 14 '16 at 0:43
  • What you're looking for is Array to pointer conversion – hgiesel Mar 14 '16 at 0:48
  • @immibis ITYM "Something" is not implicitly convertible to char. char myChar = 5.5; is legal – M.M Mar 14 '16 at 0:53
  • I think you are simply confusing single quotes and double quotes. int *myNum = 10; is wrong the same way as char *myChar = 'A';. Single quotes surround chars; double quotes surround constant arrays of chars, also known as C string literals. That said, char *myChar = "Something"; is only half right, as others pointed out. Strict compilers will demand that you declare const char *myChar, since you cannot write to elements in the array pointed to by myChar on modern architectures. – Peter - Reinstate Monica Mar 14 '16 at 11:30

is essentially short for:

static const char some_hidden_array[] = {'S', 'o', 'm', 'e', 't', 'h', 'i', 'n', 'g', '\0'};

That is, when you write "Something", the compiler generates an array behind the scenes, and gives you a pointer to the start of that array. Since this is already a pointer to a char, you'll have no problem assigning it to a variable of type "pointer to a char" (written as char*).


is not short for anything similar. It's just the number 10 - it's not a pointer to an array containing the number 10, or anything like that.

Note that a char is a single character, not a string, which is why the string syntax is unusual compared to most other types - a string is several chars, not just one. If you try to use a plain old char, you'll see the same thing:

char *myChar = 'a'; // error

or for any other type:

float *myFloat = 42.1f; // error

In other words, it's not strange that 10 gives an error - if anything, it's strange that "Something" doesn't. (At least, it's strange until you know how string literals work)


It's the same thing (no magic from the compiler is happening). By default, literals like 10 are int values, not int*.

You need to cast:

int *myNum = (int*)10; // Need to cast
char *myChar = "Something"; // No need to cast "..." is already a char*

Note that it's dangerous to reference a pointer to absolute value like this because you will end up with the address 10 in CPU memory.

Regarding your second question, "..." is treated as a contiguous sequence of char in memory similar to array and equivalent to char*.

For a thoughtful understanding of C, pointers and differences between arrays and pointers, you should read this: Expert C Programming: Deep C Secrets by Peter van der Linden.

  • Thank you! As for second question, I meant more like if those 2 equal? Is first example a shorter way of getting the address? Thanks! – J. Doe Mar 14 '16 at 0:00
  • 1
    Remember to select this as your accepted answer if it answered your question. – Kent Kostelac Mar 14 '16 at 0:52
  • 4
    "..." is not a char*. And I wouldn't recommend a C book for learning C++; the idioms are entirely different. – Lightness Races with Monica Mar 14 '16 at 10:56
  • @J.Doe No, the second example simply doesn't work. A string literal is not a char, it's a char[]. Changing that, taking the address of a char[] will give you a pointer to a pointer - in this case, a pointer to a stack variable, so only defined until the scope exits. This is quite important, since string literals are a bit of magic - they appear "local", but don't actually have a scope; the original pointer is valid everywhere, the pointer to a pointer isn't. – Luaan Mar 14 '16 at 11:31

When you do char *myChar = "Something";, you create a read-only string literal somewhere in the memory, which ends in a null character. Now this is something special with the compiler, that it interprets a chunk of 'char' variables stored continuously and ending with a null character as string. So basically you created an array of characters, and when you do *myChar*, it returns the string.

In case of integers or any other data types, it differentiates between int *ptr as a pointer to an integer, and int ptr as an integer. You are getting an error probably because the address you entered may not be valid/available to you.

Also, doing

char myChar = "Something";  //this is an error, since char can hold one character
char *charAddr = &myChar;

Note that myChar and &myChar are the same, since myChar is a pointer!

Edit: Refer here about string literals: Is it possible to modify a string of char in C?

  • Thank you for explanation, so does type *var = something, always create a read-only variable in memory? And as per second question, I more meant like if those 2 are equal (shorter way) :) Thanks! – J. Doe Mar 14 '16 at 0:03
  • @J.Doe Yes. Have a look at this: stackoverflow.com/questions/1011455/… – Sahil Arora Mar 14 '16 at 0:06
  • Thank you, this does help a lot. – J. Doe Mar 14 '16 at 0:20
  • 2
    @J.Doe no, type *var = something does not create a read-only variable. It is only the string literal "Something" which is read-only (and it is not a variable) – M.M Mar 14 '16 at 0:55

Why does assigning char work but integer doesn't (Maybe cause char is treated as an array)?

You are right, "Something" is a string literal and can be treated as char array. After char *myChar = "Something"; the following thing happen: it is allocated length+1 bytes of memory where "Something" will be stored, myChar is pointed to the starting address of this memory. String literals are somewhat special.

Here is a general way of initializing array with constant values:

// valid initializations;
char s2[] = { 'a', 'b', 'c' };
int a[] = { 1, 2, 3 };
char s1[] = "123";

As well what confuses me when directly assigning a pointer variable, does it automatically get an address?


Take a look at 8.5.2 Character arrays of c++ docs


While theoretically the first int *myNum = 10 makes sense—especially if you know there is a useful int at address ten—in general it is rarely useful and potentially quite dangerous.

However, there are certain pointer assignments which are widely used and quite safe:

int *myNum = 0;

On 99.9+% of modern CPU architectures, this is the same as

int *myNum = NULL;

See the definition of NULL in <stddef.h> here.

As a general rule, assignment of pointer variables is best done by setting to the address of something else.

int k, *p = &k;
  • 1
    Thanks! Hmm so basically, int *myNum = 10 // Pointer to an address "10" and not actually an address that contains a variable int with a value of 10? – J. Doe Mar 14 '16 at 0:06
  • 1
    int *myNum = 0; is the same as int *myNum = NULL; on all systems. It makes a null pointer. You're getting mixed up with the fact that null pointer might not be represented by all-bits-zero (which makes no difference to this code) – M.M Mar 14 '16 at 0:57
  • @J.Doe Yes, and your confusion is pretty much exactly why you need to add the explicit cast to make this compile - this is almost always a mistake, rather than the intended behaviour. On a modern desktop/server system, you really don't want to use pointers to manually picked addresses. It was useful in the past, though - for example, for direct access to graphics memory (or any other kind of device, really). With hardware abstraction, there's very few legitimate uses (outside of the rather obvious 0/NULL case, which per C standard always works :)). – Luaan Mar 14 '16 at 11:26

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service, privacy policy and cookie policy

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