Related
The following code receives seg fault on line 2:
char *str = "string";
str[0] = 'z'; // could be also written as *str = 'z'
printf("%s\n", str);
While this works perfectly well:
char str[] = "string";
str[0] = 'z';
printf("%s\n", str);
Tested with MSVC and GCC.
See the C FAQ, Question 1.32
Q: What is the difference between these initializations?
char a[] = "string literal";
char *p = "string literal";
My program crashes if I try to assign a new value to p[i].
A: A string literal (the formal term
for a double-quoted string in C
source) can be used in two slightly
different ways:
As the initializer for an array of char, as in the declaration of char a[] , it specifies the initial values
of the characters in that array (and,
if necessary, its size).
Anywhere else, it turns into an unnamed, static array of characters,
and this unnamed array may be stored
in read-only memory, and which
therefore cannot necessarily be
modified. In an expression context,
the array is converted at once to a
pointer, as usual (see section 6), so
the second declaration initializes p
to point to the unnamed array's first
element.
Some compilers have a switch
controlling whether string literals
are writable or not (for compiling old
code), and some may have options to
cause string literals to be formally
treated as arrays of const char (for
better error catching).
Normally, string literals are stored in read-only memory when the program is run. This is to prevent you from accidentally changing a string constant. In your first example, "string" is stored in read-only memory and *str points to the first character. The segfault happens when you try to change the first character to 'z'.
In the second example, the string "string" is copied by the compiler from its read-only home to the str[] array. Then changing the first character is permitted. You can check this by printing the address of each:
printf("%p", str);
Also, printing the size of str in the second example will show you that the compiler has allocated 7 bytes for it:
printf("%d", sizeof(str));
Most of these answers are correct, but just to add a little more clarity...
The "read only memory" that people are referring to is the text segment in ASM terms. It's the same place in memory where the instructions are loaded. This is read-only for obvious reasons like security. When you create a char* initialized to a string, the string data is compiled into the text segment and the program initializes the pointer to point into the text segment. So if you try to change it, kaboom. Segfault.
When written as an array, the compiler places the initialized string data in the data segment instead, which is the same place that your global variables and such live. This memory is mutable, since there are no instructions in the data segment. This time when the compiler initializes the character array (which is still just a char*) it's pointing into the data segment rather than the text segment, which you can safely alter at run-time.
Why do I get a segmentation fault when writing to a string?
C99 N1256 draft
There are two different uses of character string literals:
Initialize char[]:
char c[] = "abc";
This is "more magic", and described at 6.7.8/14 "Initialization":
An array of character type may be initialized by a character string literal, optionally
enclosed in braces. Successive characters of the character string literal (including the
terminating null character if there is room or if the array is of unknown size) initialize the
elements of the array.
So this is just a shortcut for:
char c[] = {'a', 'b', 'c', '\0'};
Like any other regular array, c can be modified.
Everywhere else: it generates an:
unnamed
array of char What is the type of string literals in C and C++?
with static storage
that gives UB if modified
So when you write:
char *c = "abc";
This is similar to:
/* __unnamed is magic because modifying it gives UB. */
static char __unnamed[] = "abc";
char *c = __unnamed;
Note the implicit cast from char[] to char *, which is always legal.
Then if you modify c[0], you also modify __unnamed, which is UB.
This is documented at 6.4.5 "String literals":
5 In translation phase 7, a byte or code of value zero is appended to each multibyte
character sequence that results from a string literal or literals. The multibyte character
sequence is then used to initialize an array of static storage duration and length just
sufficient to contain the sequence. For character string literals, the array elements have
type char, and are initialized with the individual bytes of the multibyte character
sequence [...]
6 It is unspecified whether these arrays are distinct provided their elements have the
appropriate values. If the program attempts to modify such an array, the behavior is
undefined.
6.7.8/32 "Initialization" gives a direct example:
EXAMPLE 8: The declaration
char s[] = "abc", t[3] = "abc";
defines "plain" char array objects s and t whose elements are initialized with character string literals.
This declaration is identical to
char s[] = { 'a', 'b', 'c', '\0' },
t[] = { 'a', 'b', 'c' };
The contents of the arrays are modifiable. On the other hand, the declaration
char *p = "abc";
defines p with type "pointer to char" and initializes it to point to an object with type "array of char" with length 4 whose elements are initialized with a character string literal. If an attempt is made to use p to modify the contents of the array, the behavior is undefined.
GCC 4.8 x86-64 ELF implementation
Program:
#include <stdio.h>
int main(void) {
char *s = "abc";
printf("%s\n", s);
return 0;
}
Compile and decompile:
gcc -ggdb -std=c99 -c main.c
objdump -Sr main.o
Output contains:
char *s = "abc";
8: 48 c7 45 f8 00 00 00 movq $0x0,-0x8(%rbp)
f: 00
c: R_X86_64_32S .rodata
Conclusion: GCC stores char* it in .rodata section, not in .text.
If we do the same for char[]:
char s[] = "abc";
we obtain:
17: c7 45 f0 61 62 63 00 movl $0x636261,-0x10(%rbp)
so it gets stored in the stack (relative to %rbp).
Note however that the default linker script puts .rodata and .text in the same segment, which has execute but no write permission. This can be observed with:
readelf -l a.out
which contains:
Section to Segment mapping:
Segment Sections...
02 .text .rodata
In the first code, "string" is a string constant, and string constants should never be modified because they are often placed into read only memory. "str" is a pointer being used to modify the constant.
In the second code, "string" is an array initializer, sort of short hand for
char str[7] = { 's', 't', 'r', 'i', 'n', 'g', '\0' };
"str" is an array allocated on the stack and can be modified freely.
Because the type of "whatever" in the context of the 1st example is const char * (even if you assign it to a non-const char*), which means you shouldn't try and write to it.
The compiler has enforced this by putting the string in a read-only part of memory, hence writing to it generates a segfault.
char *str = "string";
The above sets str to point to the literal value "string" which is hard-coded in the program's binary image, which is probably flagged as read-only in memory.
So str[0]= is attempting to write to the read-only code of the application. I would guess this is probably compiler dependent though.
To understand this error or problem you should first know difference b/w the pointer and array
so here firstly i have explain you differences b/w them
string array
char strarray[] = "hello";
In memory array is stored in continuous memory cells, stored as [h][e][l][l][o][\0] =>[] is 1 char byte size memory cell ,and this continuous memory cells can be access by name named strarray here.so here string array strarray itself containing all characters of string initialized to it.in this case here "hello"
so we can easily change its memory content by accessing each character by its index value
`strarray[0]='m'` it access character at index 0 which is 'h'in strarray
and its value changed to 'm' so strarray value changed to "mello";
one point to note here that we can change the content of string array by changing character by character but can not initialized other string directly to it like strarray="new string" is invalid
Pointer
As we all know pointer points to memory location in memory ,
uninitialized pointer points to random memory location so and after initialization points to particular memory location
char *ptr = "hello";
here pointer ptr is initialized to string "hello" which is constant string stored in read only memory (ROM) so "hello" can not be changed as it is stored in ROM
and ptr is stored in stack section and pointing to constant string "hello"
so ptr[0]='m' is invalid since you can not access read only memory
But ptr can be initialised to other string value directly since it is just pointer so it can be point to any memory address of variable of its data type
ptr="new string"; is valid
char *str = "string";
allocates a pointer to a string literal, which the compiler is putting in a non-modifiable part of your executable;
char str[] = "string";
allocates and initializes a local array which is modifiable
The C FAQ that #matli linked to mentions it, but no one else here has yet, so for clarification: if a string literal (double-quoted string in your source) is used anywhere other than to initialize a character array (ie: #Mark's second example, which works correctly), that string is stored by the compiler in a special static string table, which is akin to creating a global static variable (read-only, of course) that is essentially anonymous (has no variable "name"). The read-only part is the important part, and is why the #Mark's first code example segfaults.
The
char *str = "string";
line defines a pointer and points it to a literal string. The literal string is not writable so when you do:
str[0] = 'z';
you get a seg fault. On some platforms, the literal might be in writable memory so you won't see a segfault, but it's invalid code (resulting in undefined behavior) regardless.
The line:
char str[] = "string";
allocates an array of characters and copies the literal string into that array, which is fully writable, so the subsequent update is no problem.
String literals like "string" are probably allocated in your executable's address space as read-only data (give or take your compiler). When you go to touch it, it freaks out that you're in its bathing suit area and lets you know with a seg fault.
In your first example, you're getting a pointer to that const data. In your second example, you're initializing an array of 7 characters with a copy of the const data.
// create a string constant like this - will be read only
char *str_p;
str_p = "String constant";
// create an array of characters like this
char *arr_p;
char arr[] = "String in an array";
arr_p = &arr[0];
// now we try to change a character in the array first, this will work
*arr_p = 'E';
// lets try to change the first character of the string contant
*str_p = 'G'; // this will result in a segmentation fault. Comment it out to work.
/*-----------------------------------------------------------------------------
* String constants can't be modified. A segmentation fault is the result,
* because most operating systems will not allow a write
* operation on read only memory.
*-----------------------------------------------------------------------------*/
//print both strings to see if they have changed
printf("%s\n", str_p); //print the string without a variable
printf("%s\n", arr_p); //print the string, which is in an array.
In the first place, str is a pointer that points at "string". The compiler is allowed to put string literals in places in memory that you cannot write to, but can only read. (This really should have triggered a warning, since you're assigning a const char * to a char *. Did you have warnings disabled, or did you just ignore them?)
In the second place, you're creating an array, which is memory that you've got full access to, and initializing it with "string". You're creating a char[7] (six for the letters, one for the terminating '\0'), and you do whatever you like with it.
Assume the strings are,
char a[] = "string literal copied to stack";
char *p = "string literal referenced by p";
In the first case, the literal is to be copied when 'a' comes into scope. Here 'a' is an array defined on stack. It means the string will be created on the stack and its data is copied from code (text) memory, which is typically read-only (this is implementation specific, a compiler can place this read-only program data in read-writable memory also).
In the second case, p is a pointer defined on stack (local scope) and referring a string literal (program data or text) stored else where. Usually modifying such memory is not good practice nor encouraged.
Section 5.5 Character Pointers and Functions of K&R also discusses about this topic:
There is an important difference between these definitions:
char amessage[] = "now is the time"; /* an array */
char *pmessage = "now is the time"; /* a pointer */
amessage is an array, just big enough to hold the sequence of characters and '\0' that initializes it. Individual characters within the array may be changed but amessage will always refer to the same storage. On the other hand, pmessage is a pointer, initialized to point to a string constant; the pointer may subsequently be modified to point elsewhere, but the result is undefined if you try to modify the string contents.
Constant memory
Since string literals are read-only by design, they are stored in the Constant part of memory. Data stored there is immutable, i.e., cannot be changed. Thus, all string literals defined in C code get a read-only memory address here.
Stack memory
The Stack part of memory is where the addresses of local variables live, e.g., variables defined in functions.
As #matli's answer suggests, there are two ways of working with string these constant strings.
1. Pointer to string literal
When we define a pointer to a string literal, we are creating a pointer variable living in Stack memory. It points to the read-only address where the underlying string literal resides.
#include <stdio.h>
int main(void) {
char *s = "hello";
printf("%p\n", &s); // Prints a read-only address, e.g. 0x7ffc8e224620
return 0;
}
If we try to modify s by inserting
s[0] = 'H';
we get a Segmentation fault (core dumped). We are trying to access memory that we shouldn't access. We are attempting to modify the value of a read-only address, 0x7ffc8e224620.
2. Array of chars
For the sake of the example, suppose the string literal "Hello" stored in constant memory has a read-only memory address identical to the one above, 0x7ffc8e224620.
#include <stdio.h>
int main(void) {
// We create an array from a string literal with address 0x7ffc8e224620.
// C initializes an array variable in the stack, let's give it address
// 0x7ffc7a9a9db2.
// C then copies the read-only value from 0x7ffc8e224620 into
// 0x7ffc7a9a9db2 to give us a local copy we can mutate.
char a[] = "hello";
// We can now mutate the local copy
a[0] = 'H';
printf("%p\n", &a); // Prints the Stack address, e.g. 0x7ffc7a9a9db2
printf("%s\n", a); // Prints "Hello"
return 0;
}
Note: When using pointers to string literals as in 1., best practice is to use the const keyword, like const *s = "hello". This is more readable and the compiler will provide better help when it's violated. It will then throw an error like error: assignment of read-only location ‘*s’ instead of the seg fault. Linters in editors will also likely pick up the error before you manually compile the code.
First is one constant string which can't be modified. Second is an array with initialized value, so it can be modified.
Segmentation fault is caused when you try to access the memory which is inaccessible.
char *str is a pointer to a string that is nonmodifiable(the reason for getting segfault).
whereas char str[] is an array and can be modifiable..
The following code receives seg fault on line 2:
char *str = "string";
str[0] = 'z'; // could be also written as *str = 'z'
printf("%s\n", str);
While this works perfectly well:
char str[] = "string";
str[0] = 'z';
printf("%s\n", str);
Tested with MSVC and GCC.
See the C FAQ, Question 1.32
Q: What is the difference between these initializations?
char a[] = "string literal";
char *p = "string literal";
My program crashes if I try to assign a new value to p[i].
A: A string literal (the formal term
for a double-quoted string in C
source) can be used in two slightly
different ways:
As the initializer for an array of char, as in the declaration of char a[] , it specifies the initial values
of the characters in that array (and,
if necessary, its size).
Anywhere else, it turns into an unnamed, static array of characters,
and this unnamed array may be stored
in read-only memory, and which
therefore cannot necessarily be
modified. In an expression context,
the array is converted at once to a
pointer, as usual (see section 6), so
the second declaration initializes p
to point to the unnamed array's first
element.
Some compilers have a switch
controlling whether string literals
are writable or not (for compiling old
code), and some may have options to
cause string literals to be formally
treated as arrays of const char (for
better error catching).
Normally, string literals are stored in read-only memory when the program is run. This is to prevent you from accidentally changing a string constant. In your first example, "string" is stored in read-only memory and *str points to the first character. The segfault happens when you try to change the first character to 'z'.
In the second example, the string "string" is copied by the compiler from its read-only home to the str[] array. Then changing the first character is permitted. You can check this by printing the address of each:
printf("%p", str);
Also, printing the size of str in the second example will show you that the compiler has allocated 7 bytes for it:
printf("%d", sizeof(str));
Most of these answers are correct, but just to add a little more clarity...
The "read only memory" that people are referring to is the text segment in ASM terms. It's the same place in memory where the instructions are loaded. This is read-only for obvious reasons like security. When you create a char* initialized to a string, the string data is compiled into the text segment and the program initializes the pointer to point into the text segment. So if you try to change it, kaboom. Segfault.
When written as an array, the compiler places the initialized string data in the data segment instead, which is the same place that your global variables and such live. This memory is mutable, since there are no instructions in the data segment. This time when the compiler initializes the character array (which is still just a char*) it's pointing into the data segment rather than the text segment, which you can safely alter at run-time.
Why do I get a segmentation fault when writing to a string?
C99 N1256 draft
There are two different uses of character string literals:
Initialize char[]:
char c[] = "abc";
This is "more magic", and described at 6.7.8/14 "Initialization":
An array of character type may be initialized by a character string literal, optionally
enclosed in braces. Successive characters of the character string literal (including the
terminating null character if there is room or if the array is of unknown size) initialize the
elements of the array.
So this is just a shortcut for:
char c[] = {'a', 'b', 'c', '\0'};
Like any other regular array, c can be modified.
Everywhere else: it generates an:
unnamed
array of char What is the type of string literals in C and C++?
with static storage
that gives UB if modified
So when you write:
char *c = "abc";
This is similar to:
/* __unnamed is magic because modifying it gives UB. */
static char __unnamed[] = "abc";
char *c = __unnamed;
Note the implicit cast from char[] to char *, which is always legal.
Then if you modify c[0], you also modify __unnamed, which is UB.
This is documented at 6.4.5 "String literals":
5 In translation phase 7, a byte or code of value zero is appended to each multibyte
character sequence that results from a string literal or literals. The multibyte character
sequence is then used to initialize an array of static storage duration and length just
sufficient to contain the sequence. For character string literals, the array elements have
type char, and are initialized with the individual bytes of the multibyte character
sequence [...]
6 It is unspecified whether these arrays are distinct provided their elements have the
appropriate values. If the program attempts to modify such an array, the behavior is
undefined.
6.7.8/32 "Initialization" gives a direct example:
EXAMPLE 8: The declaration
char s[] = "abc", t[3] = "abc";
defines "plain" char array objects s and t whose elements are initialized with character string literals.
This declaration is identical to
char s[] = { 'a', 'b', 'c', '\0' },
t[] = { 'a', 'b', 'c' };
The contents of the arrays are modifiable. On the other hand, the declaration
char *p = "abc";
defines p with type "pointer to char" and initializes it to point to an object with type "array of char" with length 4 whose elements are initialized with a character string literal. If an attempt is made to use p to modify the contents of the array, the behavior is undefined.
GCC 4.8 x86-64 ELF implementation
Program:
#include <stdio.h>
int main(void) {
char *s = "abc";
printf("%s\n", s);
return 0;
}
Compile and decompile:
gcc -ggdb -std=c99 -c main.c
objdump -Sr main.o
Output contains:
char *s = "abc";
8: 48 c7 45 f8 00 00 00 movq $0x0,-0x8(%rbp)
f: 00
c: R_X86_64_32S .rodata
Conclusion: GCC stores char* it in .rodata section, not in .text.
If we do the same for char[]:
char s[] = "abc";
we obtain:
17: c7 45 f0 61 62 63 00 movl $0x636261,-0x10(%rbp)
so it gets stored in the stack (relative to %rbp).
Note however that the default linker script puts .rodata and .text in the same segment, which has execute but no write permission. This can be observed with:
readelf -l a.out
which contains:
Section to Segment mapping:
Segment Sections...
02 .text .rodata
In the first code, "string" is a string constant, and string constants should never be modified because they are often placed into read only memory. "str" is a pointer being used to modify the constant.
In the second code, "string" is an array initializer, sort of short hand for
char str[7] = { 's', 't', 'r', 'i', 'n', 'g', '\0' };
"str" is an array allocated on the stack and can be modified freely.
Because the type of "whatever" in the context of the 1st example is const char * (even if you assign it to a non-const char*), which means you shouldn't try and write to it.
The compiler has enforced this by putting the string in a read-only part of memory, hence writing to it generates a segfault.
char *str = "string";
The above sets str to point to the literal value "string" which is hard-coded in the program's binary image, which is probably flagged as read-only in memory.
So str[0]= is attempting to write to the read-only code of the application. I would guess this is probably compiler dependent though.
To understand this error or problem you should first know difference b/w the pointer and array
so here firstly i have explain you differences b/w them
string array
char strarray[] = "hello";
In memory array is stored in continuous memory cells, stored as [h][e][l][l][o][\0] =>[] is 1 char byte size memory cell ,and this continuous memory cells can be access by name named strarray here.so here string array strarray itself containing all characters of string initialized to it.in this case here "hello"
so we can easily change its memory content by accessing each character by its index value
`strarray[0]='m'` it access character at index 0 which is 'h'in strarray
and its value changed to 'm' so strarray value changed to "mello";
one point to note here that we can change the content of string array by changing character by character but can not initialized other string directly to it like strarray="new string" is invalid
Pointer
As we all know pointer points to memory location in memory ,
uninitialized pointer points to random memory location so and after initialization points to particular memory location
char *ptr = "hello";
here pointer ptr is initialized to string "hello" which is constant string stored in read only memory (ROM) so "hello" can not be changed as it is stored in ROM
and ptr is stored in stack section and pointing to constant string "hello"
so ptr[0]='m' is invalid since you can not access read only memory
But ptr can be initialised to other string value directly since it is just pointer so it can be point to any memory address of variable of its data type
ptr="new string"; is valid
char *str = "string";
allocates a pointer to a string literal, which the compiler is putting in a non-modifiable part of your executable;
char str[] = "string";
allocates and initializes a local array which is modifiable
The C FAQ that #matli linked to mentions it, but no one else here has yet, so for clarification: if a string literal (double-quoted string in your source) is used anywhere other than to initialize a character array (ie: #Mark's second example, which works correctly), that string is stored by the compiler in a special static string table, which is akin to creating a global static variable (read-only, of course) that is essentially anonymous (has no variable "name"). The read-only part is the important part, and is why the #Mark's first code example segfaults.
The
char *str = "string";
line defines a pointer and points it to a literal string. The literal string is not writable so when you do:
str[0] = 'z';
you get a seg fault. On some platforms, the literal might be in writable memory so you won't see a segfault, but it's invalid code (resulting in undefined behavior) regardless.
The line:
char str[] = "string";
allocates an array of characters and copies the literal string into that array, which is fully writable, so the subsequent update is no problem.
String literals like "string" are probably allocated in your executable's address space as read-only data (give or take your compiler). When you go to touch it, it freaks out that you're in its bathing suit area and lets you know with a seg fault.
In your first example, you're getting a pointer to that const data. In your second example, you're initializing an array of 7 characters with a copy of the const data.
// create a string constant like this - will be read only
char *str_p;
str_p = "String constant";
// create an array of characters like this
char *arr_p;
char arr[] = "String in an array";
arr_p = &arr[0];
// now we try to change a character in the array first, this will work
*arr_p = 'E';
// lets try to change the first character of the string contant
*str_p = 'G'; // this will result in a segmentation fault. Comment it out to work.
/*-----------------------------------------------------------------------------
* String constants can't be modified. A segmentation fault is the result,
* because most operating systems will not allow a write
* operation on read only memory.
*-----------------------------------------------------------------------------*/
//print both strings to see if they have changed
printf("%s\n", str_p); //print the string without a variable
printf("%s\n", arr_p); //print the string, which is in an array.
In the first place, str is a pointer that points at "string". The compiler is allowed to put string literals in places in memory that you cannot write to, but can only read. (This really should have triggered a warning, since you're assigning a const char * to a char *. Did you have warnings disabled, or did you just ignore them?)
In the second place, you're creating an array, which is memory that you've got full access to, and initializing it with "string". You're creating a char[7] (six for the letters, one for the terminating '\0'), and you do whatever you like with it.
Assume the strings are,
char a[] = "string literal copied to stack";
char *p = "string literal referenced by p";
In the first case, the literal is to be copied when 'a' comes into scope. Here 'a' is an array defined on stack. It means the string will be created on the stack and its data is copied from code (text) memory, which is typically read-only (this is implementation specific, a compiler can place this read-only program data in read-writable memory also).
In the second case, p is a pointer defined on stack (local scope) and referring a string literal (program data or text) stored else where. Usually modifying such memory is not good practice nor encouraged.
Section 5.5 Character Pointers and Functions of K&R also discusses about this topic:
There is an important difference between these definitions:
char amessage[] = "now is the time"; /* an array */
char *pmessage = "now is the time"; /* a pointer */
amessage is an array, just big enough to hold the sequence of characters and '\0' that initializes it. Individual characters within the array may be changed but amessage will always refer to the same storage. On the other hand, pmessage is a pointer, initialized to point to a string constant; the pointer may subsequently be modified to point elsewhere, but the result is undefined if you try to modify the string contents.
Constant memory
Since string literals are read-only by design, they are stored in the Constant part of memory. Data stored there is immutable, i.e., cannot be changed. Thus, all string literals defined in C code get a read-only memory address here.
Stack memory
The Stack part of memory is where the addresses of local variables live, e.g., variables defined in functions.
As #matli's answer suggests, there are two ways of working with string these constant strings.
1. Pointer to string literal
When we define a pointer to a string literal, we are creating a pointer variable living in Stack memory. It points to the read-only address where the underlying string literal resides.
#include <stdio.h>
int main(void) {
char *s = "hello";
printf("%p\n", &s); // Prints a read-only address, e.g. 0x7ffc8e224620
return 0;
}
If we try to modify s by inserting
s[0] = 'H';
we get a Segmentation fault (core dumped). We are trying to access memory that we shouldn't access. We are attempting to modify the value of a read-only address, 0x7ffc8e224620.
2. Array of chars
For the sake of the example, suppose the string literal "Hello" stored in constant memory has a read-only memory address identical to the one above, 0x7ffc8e224620.
#include <stdio.h>
int main(void) {
// We create an array from a string literal with address 0x7ffc8e224620.
// C initializes an array variable in the stack, let's give it address
// 0x7ffc7a9a9db2.
// C then copies the read-only value from 0x7ffc8e224620 into
// 0x7ffc7a9a9db2 to give us a local copy we can mutate.
char a[] = "hello";
// We can now mutate the local copy
a[0] = 'H';
printf("%p\n", &a); // Prints the Stack address, e.g. 0x7ffc7a9a9db2
printf("%s\n", a); // Prints "Hello"
return 0;
}
Note: When using pointers to string literals as in 1., best practice is to use the const keyword, like const *s = "hello". This is more readable and the compiler will provide better help when it's violated. It will then throw an error like error: assignment of read-only location ‘*s’ instead of the seg fault. Linters in editors will also likely pick up the error before you manually compile the code.
First is one constant string which can't be modified. Second is an array with initialized value, so it can be modified.
Segmentation fault is caused when you try to access the memory which is inaccessible.
char *str is a pointer to a string that is nonmodifiable(the reason for getting segfault).
whereas char str[] is an array and can be modifiable..
From C in a Nutshell:
In most cases, the compiler implicitly converts an expression
with an array type, such as the name of an array, into a pointer to
the array’s first element.
The array expression is not converted into a pointer only in the
following cases:
• When the array is the operand of the sizeof operator
• When the array is the operand of the address operator &
• When a string literal is used to initialize an array of char ,
wchar_t , char16_t , or char32_t
Could you explain what the last bullet means with some positive and
negative examples? I don't find an example in the book for the last
bullet.
Also why is an array of characters, not other element types?
char *ptr = "Hello OP!!";
ptr is an pointer to first char of the string literal stored in the RODATA segment. When you dereference it you can only read but not write values as string literals are constant char arrays.
char arr[] = "Hello OP!! How are you my friend?";
In this case:
Is allocated space for the arr array of the length of size literal including the trailing zero.
String literal is copied into the space allocated for the arr array
In this case arr is used as place in the memory where the string literal is copied.
You can read and write as the arr elements are read & write
And now answering the question
sizeof of an array is the size in bytes if all array elements. If the array was converted to pointer - the size would be the size of the pointer which is obviously wrong in this case
Array is only the continuous space in the memory accommodating all its elements. So the address of the array is always the address of this memory location
Third case i have explained above
you can see the code
https://godbolt.org/g/xVL5cR
** Note to TIM ** String literals are not converted to anything. String literal is only stored as a char (wchar_t ....) array with NUL (NOT NULL) teriminator at the end, in the RO memory.
Why is an array of characters, not other element types?
Its becouse string literals have static storage duration, and thus exist in memory for the life of the program.
Attempting to modify a string literal(with pointer to literal) results in undefined behavior: they may be stored in read-only storage (such as .rodata) or combined with other string literals.
Any of other constants arent stored like this, so this is why only array of characters (literals).
Could you explain what the last bullet means with some positive and
negative examples? I don't find an example in the book for the last
bullet.
String literal initialization looks like this:
char ptr[] = "Hello world!"; // This is char[]
char ptr[] = L"Hello world!"; // This is wchar_t[]
char ptr[] = u8"Hello world!"; // This is char[]
char ptr[] = u"Hello world!"; // This is char16_t[]
char ptr[] = U"Hello world!"; // This is char32_t[]
The string literal is copied from static storage duration to automatic storage duration and its possible to modify him.
While
char ptr[] = {'H','e','l','l',o',' ','w','o','r','l','d','\0'};
wont be string literal and wont have static duration storage.
The following C program is not supposed to work by my understanding of pointers but it does.
#include<stdio.h>
main() {
char *p;
p = "abcdefghijk";
printf("%s", p);
}
Outputs:
abcdefghijk
The char pointer variable p is pointing to something random as I have not assigned any address to it like p = &i; where i is some char array.
That means if I try to write anything to the memory address held by the pointer p it should give me segmentation fault since it is some random address not assigned to my program by the OS.
But the program compiles and runs successfully. What is happening?
In this expression statement
p="abcdefghijk";
the pointer p is assigned with the address of the first character of the string literal "abcdefghijk" that the compiler stores as a zero-terminated character array in the static memory area.
Thus in this statement there are two things that happen. At first the compiler creates an unnamed character array with the static storage duration to hold the string literal. Then the address of the first character of the array is assigned to the pointer. You can imagine it the following way
char unnamed[] = { 'a', 'b', 'c', 'd', 'e', 'f', 'g', 'h', 'i', 'j', 'k', '\0' };
p = unnamed;
or
p = &unnamed[0];
Take into account that though string literals in C have types of non-constant character arrays opposite to C++ where they have types of constant character arrays nevertheless you may not change string literals. Any attempt to change a string literal results in undefined behavior.
So this code snippet is invalid
char *p = "abcdefghijk";
p[0] = 'A';
But you could create your own character array initializing it with the string literal and in this case you can change the array. For example
char s[] = "abcdefghijk";
char *p = s;
p[0] = 'A';
From the C Standard (6.4.5 String literals)
7 It is unspecified whether these arrays are distinct provided their
elements have the appropriate values. If the program attempts to
modify such an array, the behavior is undefined.
Pay attention to this part of the quote
It is unspecified whether these arrays are distinct provided their
elements have the appropriate values.
It means that for example if you will write
char *p = "abcdefghijk";
char *q = "abcdefghijk";
then it is not necessary that this expression yields true (integer value 1)
p == q
and the result depends on compiler options whether the same string literals are stored as one array or as distinct arrays.
In C a string literal like "abcdefghijk" is actually stored as an (read-only) array of characters. The assignment makes p point to the first character of that array.
I note that you mention p = &i where i would be an array. That is in most cases wrong. Arrays naturally decays to pointers to their first element. I.e. doing p = i would be equal to p = &i[0].
While both &i and &i[0] would result in the same address, it is semantically very different. Lets take an example:
char array[10];
With the above definition doing &array[0] (or just plain array as explained just above) you get a pointer to char, i.e. char *. When doing &array you get a pointer to an array of ten characters, i.e. char (*)[10]. The two types are very different.
"abcdefghijk" is a string constant, and p="abcdefghijk"; will give to p adress of this string.
So it's normal that printf("%s",p); display this string without error.
p="abcdefghijk";
You are creating a string literal in code segment and assigning the address of first character of the literal to the pointer, and as the pointer is not constant you can assign it again with different addresses.
The string literal "abcdefghijk" is compiled by putting the characters in a block in the program's datatext segment. Then your assignment of it to the pointer assigns the address of its location in the data segment to the pointer.
Can someone explain why this works with the pointer:
char * str1;
str1 = "Hello1";
str1 = "new string";
// but not this
char str2 [] = "hello";
str2 = "four";
// or this
char str3 [];
str3 = "hello";
str3 = "hello";
Why it works with pointers:
When you say char * str1 in C, you are allocating a pointer in the memory. When you write str1 = "Hello";, you are creating a string literal in memory and making the pointer point to it. When you create another string literal "new string" and assign it to str1, all you are doing is changing where the pointer points.
Why it doesn't work with arrays:
When you say char str2 [] = "Hello", you are creating a string literal and putting it in the array during its definition. It is ok to not give a size, as the array calculates it and appends a '\0' to it. You cannot reassign anything to that array without resizing it. That is why str2 = "four" will not work.
In case of str3, it is the same case. You haven't defined the size of the array in the definition, so it calculated its size to be 0. You cannot assign anything new without resizing the array.
An array and a pointer are different things, that's why.
You can assign to a pointer, but you can't assign to an array. A special exception is made for initialization of char arrays with string literals.
char a[] = "Hello"; //initialize a char array with string literal. Special case, OK
char* p = "Hello"; //initializa a pointer with an array(which gets converted to pointer)
p = "My"; //assign pointer to point to another value. OK
a = "My"; //error, arrays cannot be assigned to. Use `strcpy`
String literals (such as "Hello") have type char[N] where N is number of characters (including the terminating '\0'). An array can be converted to a pointer to its first element, but arrays and pointers are not the same thing, whatever some bad books or teachers may say.
Put simply, because an array is not a first-class object in C/C++. The only way to assign to an array is to use str(n)cpy or memcpy.
While an array collapses into a pointer when passed to a function, it is not possible to assign to an array, except at compile-time as initialisation.
The case with pointers
It works because when you are assigning like str1="Hello" , You are actually creating a string literal named hello allocating it somewhere in the memory , and assigning the address of first character of the literal to the pointer , and as the pointer is not constant you can assign it again with different addresses. And one more important point to note is that the string literal created are in read only memory.
The case with character array
You can assign it a string literal while initialisation as that is supported by the language . And dont confuse assignment with initialisation. While assignment , since its an character array you have to change value character by character ,You are trying to address the first address of the string literal to the first character of the array ( the name of the array return the address of first element of the array).And this clearly is not right as the first element is not pointer , it cant store address.
It is simply because, when you write this code:
char str2 [] = "hello";
or even:
int arr[] = {1,2,4,4,5};
it creates str2 or arr as a constant pointer. That's why you can not reassign any other values to these pointers while in later case you are creating a normal pointer and you can assign anything to it.