I have this code:
char *name[] = { "a1", "b2", "c3", "d4" };
printf("%s\n", *name); //the critical line
Related to critical line:
In this form, the output is simple: a1.
If I replace the critical line with:
printf("%s\n", ++*name);
then the output is 1. I think until now everything is good.
Taking in account that name is a pointer to the first string of characters, respectively "a1", I replace the critical line with:
printf("%s\n", ++name);
in the hope that I'll get "b2" result as output. But I get this error:
../src/test.c:32: error: lvalue required as increment operand.
Question: I can't understand why ++*name is legal - name is a pointer to first string of characters - and ++name isn't. In my opinion, the ++name should move the name to the next string of characters. Can anybody explain me where is the lack in my understing?
When you write ++name, the array name is converted to a pointer to the first element of the array. The result of this conversion is not an lvalue, and it can't be modified with ++ or otherwise. You could instead write name+1, which would print the right thing. When name is an array, there is no way to modify it to refer to anything other than that array[*].
Consider also:
char **p = name; // OK, `name' converts to pointer
++p; // OK, `p' is an lvalue
++(p+1); // not OK, `p+1' is not an lvalue
++((char**)p); // not OK, `(char**)p' is not an lvalue
++*name; // OK, `*name' is an lvalue
Roughly speaking, an "lvalue" is an expression that refers to an object, whereas a "not an lvalue" is an expression that has a value. The difference between an object and a value, is that an object is a place for storing values (well, one value at a time). Values can never be modified, objects sometimes can.
Whenever you have a subexpression which is an lvalue but whose current value is needed, the object is read/loaded/whatever you want to call it. In C++ this is called an "lvalue to rvalue conversion", I can't remember whether it's called anything in C other than "evaluating the subexpression".
[*] you can shadow it with another variable name in an inner scope, that refers to something else. But that's still not modifying the outer name, just temporarily hiding it.
name is an array, so, except when you use it as operand of the sizeof or & operators, it is evaluated as a pointer to the initial member of the array objet and is not an lvalue.
Accordingly, you can't modify name directly, with an operator such as ++ (remember that the postfix increment operator need a modifiable lvalue as operand). Otherwise, you can use a temporary pointer (p in the following example).
#include <stdio.h>
const char *name[] = { "a1", "b2", "c3", "d4" };
const char **p = name;
printf("%s\n", *p); /* Output: a1 */
*++p; /* or *p++ */
printf("%s\n", *p); /* Output: b2 */
While name points to the address of the first element, name is not of type char *, but char *[4]. therefore, sizof(name) == sizeof(char *)*4
Incrementing a pointer always means to add the size of the data it points to. So, after incrementing, it points behind the whole array. Just like if you have
int i, a;
int *p = &i;
p++;
p will now point behind i. It will point to a, if the compiler decided to put a behind i.
Also note that your array only contains 4 pointers, not 4 strings. Like above, it is the compilers choice where those strings actually are. So, the end of the first string is not necessarily next to the beginning of the second string. Especially if you assign other values (string adresses) to name[1] later. Therefore, you may cast name to char **, but should not cast to char *. Incrementing the former will point to the second element (second char* pointer).
First off, make sure you're totally happy and confident with the following fact: An arrays is not a pointer.
Second, what's in a name? The array decays into a pointer to the first element. After decay, the expression name has type char ** (pointer to first element of an array of char*. However, the decayed expression is an rvalue. You cannot modify it! And naturally so, since it makes no sense to modify a pointer that's a pointer to a fixed array.
Therefore, you cannot directly increment the pointer which is the result of decaying name, no more than you can say ++5 or ++foo() (where foo returns a primitive type by value)[whoops, that was a concession meant for C++].
What you can say is this:
char ** np = name;
++np;
printf("%s", *np);
This has the same effect as printing name[1], but now you also have a variable that holds a pointer to the second array element.
Related
I am having a tough time understanding the type and use of the name of the array in C. It might seems a long post but please bear with me.
I understand that the following statement declares a to be of type int [] i.e array of integers.
int a[30];
While a also points the first element of array and things like *(a+2) are valid. Thus, making a look like a pointer to an integer. But actually the types int [] and int* are different; while the former is an array type and later is a pointer to an integer.
Also a variable of type int [] gets converted into a variable of type int* when passing it to functions; as in C arrays are passed by reference (with the exception of the sizeof operator).
Here comes the point which makes me dangle. Have a look at the following piece of code:
int main()
{
int (*p)[3];
int a[3] = { 5, 4, 6 };
p = &a;
printf("a:%d\t&a:%d\n",a,&a);
printf("%d",*(*p + 2));
}
OUTPUT:
a:2686720 &a:2686720
6
So, how does the above code work? I have two questions:
a and &a have the same values. Why?
What exactly does int (*p)[3]; do? It declares a pointer to an array, I know this. But how is a pointer to an array different from the pointer to the first element of the array and name of the array?
Can anyone clarify things up? I am having a hell of a lot of confusions.
I know that I should use %p as a placeholder instead of using %d for printing the value of pointer variables. As using the integer placeholder might print truncated addresses. But I just want to keep things simple.
Other answers already explained the issue. I am trying to explain it with some diagram. Hope this will help.
When you declare an array
int a[3] = {5, 4, 6}
the memory arrangement looks like
Now answering your question:
a and &a have the same values.How?
As you already know that a is of array type and array name a becomes a pointer to first element of array a (after decay),i.e it points to the address 0x100. Note that 0x100 also is the starting address of the memory block (array a). And you should know that, in general, the address of the first byte is said to be the address of the variable. That is, if a variable is of 100 bytes, then its address is equal to the address of its first byte.
&a is address of the entire memory block, i.e it is an address of array a. See the diagram:
Now you can understand why a and &a both have same address value although both are of different type.
What exactly it does int (*p)[3]; Declares a pointer to an array,i know this.But,how a pointer to an array is different from the pointer to the first element of the array and name of the array?
See the above figure, it is explained clearly how pointer to an array is different from the pointer to an array element.
When you assign &a to p, then p points to the entire array having starting address 0x100.
NOTE: Regarding to the line
... as in C arrays are passed by references (with exception of sizeof function).
In C, arguments are passed by value. No pass by reference in C. When an ordinary variable is passed to a function, its value is copied; any changes to corresponding parameter do not affect the variable.
Arrays are also passed by value, but difference is that the array name decays to pointer to first element and this pointer assigned to the parameter (here, pointer value is copied) of the function; the array itself isn't copied.
In contrast to ordinary variable, an array used as an argument is not protected against any change, since no copy is made of the array itself, instead copy of pointer to first element is made.
You should also note that sizeof is not a function and array name does not act as an argument in this case. sizeof is an operator and array name serves as an operand. Same holds true when array name is an operand of the unary & operator.
a and &a have the same values.How?
They have the same value but different types. Array objects have no padding between elements (before or after) so the address of the array and the address of the first element of the array are the same.
That is:
(void *) a == (void *) &a
What exactly it does int (*p)[3]; Declares a pointer to an array,i know this.But,how a pointer to an array is different from the pointer to the first element of the array and name of the array?
These are two different pointer types. Take for example, pointer arithmetic:
a + 1 /* address of the second element of the array */
&a + 1 /* address one past the last element of the array */
EDIT: due to popular demand I added below some information about conversion of arrays.
With three exceptions, in an expression an object of type array of T is converted to a value of type pointer to T pointing to the first element of the array. The exceptions are if the object is the operand of sizeof or & unary operator or if the object is a string literal initializing an array.
For example this statement:
printf("a:%d\t&a:%d\n", a, &a);
is actually equivalent to:
printf("a:%d\t&a:%d\n", &a[0], &a);
Also please note that d conversion specifier can only be use to print a signed integer; to print a pointer value you have to use p specifier (and the argument must be void *). So to do things correctly use:
printf("a:%p\t&a:%p\n", (void *) a, (void *) &a);
respectively:
printf("a:%p\t&a:%p\n", (void *) &a[0], (void *) &a);
a corresponds to the pointer pointing at 0th element of the array. Whereas,the same is the case with &a.It just gives the starting address of the array.
As,a --> pointer pointing to starting element of array a[],it does not know about other element's location..
&a --->address location for storing array a[] which stores first element location,but knows every element's location.
Similarly,other elements location will be (a+2),(a+4) and so upto the end of the array.
Hence,you got such result.
int (*p)[3] is a pointer to the array. had it been int *p[3],it would been meant entirely different. It'd have meant an array of pointers which would have been totally different from this context.
Pointer to an array will automatically take care of all the other
elements in the array.In this case,your's is (p);
Whereas,the pointer to the first element of the array,i.e., a will
only know about first element of the array.You'll have to manually
give pointer arithmetic directions to access next elements.See,in this
case---we can get second element from a by adding 2 to a,i.e.
a+2,third element by adding 4 to a,i.e., a+4 and so on. // mind the
difference of two as it is an integer array!
In answer to question 1, this is simply an aspect of the C language as designed, unlike most other modern languages C/C++ allows direct manipulation of addresses in memory and has built in facilities to 'understand' that. There are many articles online that explain this better than I could in this small space. Here is one and I am sure there are many others: http://www.cprogramming.com/tutorial/c/lesson8.html
From C99 Standard n1124 6.3.2.1 p3
Except when it is the operand of the sizeof operator or the unary &
operator, or is a string literal used to initialize an array, an
expression that has type ‘‘array of type’’ is converted to an
expression with type ‘‘pointer to type’’ that points to the initial
element of the array object and is not an lvalue. If the array object
has register storage class, the behavior is undefined.
a and &a have the same value because a long time ago you were required to use the address operator & on arrays to get the array's address, but it is no longer necessary. The name of the array (a in this case) these days just represents the memory address of the array itself, which is also what you get from &a. It's a shorthand that the compiler handles for you.
For example,
I declared variable like this,
char szBuffer[12] = {"Hello"};
char szData[12] = {"Cheese"};
szBuffer = szData;
is error, since szBuffer can't be l-value.
szBuffer has its own address, for example, 0x0012345678, and szBuffer's value is also its address, 0x0012345678.
So I think "array name can't be l-value" means that an array's address and its value have to be equal.
Am I right?
If I'm right, why do they have to be equal?
array name can't be l-value
It means an array can not be used as l-value or left hand side of the assignment operator (not to be confused with initialization). An l-value must be modifiable. You can modify the contents of array but not the array itself.
In C you can not assign to arrays. Though you can intialize them.
You should use strcpy(szBuffer, szData) or memcpy(szBuffer, szData, 12).
Also there is no need of {} in the initialization from string literal.
If you insist on using operator =, you need to put your string in a struct because struct object copy is allowed in C.
ex:
struct string {
char name[12];
};
struct string szBuffer = {"Hello"};
struct string szData = {"Cheese"};
szBuffer = szData;
No, it won't mean such a thing.
Array's address isn't value of array in general.
Arrays in expression except for operands of sizeof and unary & operator are automatically converted to pointers to first arguments of that array.
Therefore, the converted pointer is not an l-value and you cannot assign there.
array name can't be l-value means that array names cannot be used on the left side of an =.
To be more clearer, you need a modifiable l-value on the left side of a =
Arrays are modifiable l-value when they are used with indices like arr[i].
But array name themselves are not, and hence cannot be used on the left side of a =
An L-value is something that can appear on the left hand side of an assignment. Examples: Scalar variables, array elements, pointer dereferences. An array name is not an L-value in C. Instead, you can do one of two things: (1) a pointer assignment, if you just need a pointer to the array, or (2) an array copy, if you really need to copy the array itself.
I am having a tough time understanding the type and use of the name of the array in C. It might seems a long post but please bear with me.
I understand that the following statement declares a to be of type int [] i.e array of integers.
int a[30];
While a also points the first element of array and things like *(a+2) are valid. Thus, making a look like a pointer to an integer. But actually the types int [] and int* are different; while the former is an array type and later is a pointer to an integer.
Also a variable of type int [] gets converted into a variable of type int* when passing it to functions; as in C arrays are passed by reference (with the exception of the sizeof operator).
Here comes the point which makes me dangle. Have a look at the following piece of code:
int main()
{
int (*p)[3];
int a[3] = { 5, 4, 6 };
p = &a;
printf("a:%d\t&a:%d\n",a,&a);
printf("%d",*(*p + 2));
}
OUTPUT:
a:2686720 &a:2686720
6
So, how does the above code work? I have two questions:
a and &a have the same values. Why?
What exactly does int (*p)[3]; do? It declares a pointer to an array, I know this. But how is a pointer to an array different from the pointer to the first element of the array and name of the array?
Can anyone clarify things up? I am having a hell of a lot of confusions.
I know that I should use %p as a placeholder instead of using %d for printing the value of pointer variables. As using the integer placeholder might print truncated addresses. But I just want to keep things simple.
Other answers already explained the issue. I am trying to explain it with some diagram. Hope this will help.
When you declare an array
int a[3] = {5, 4, 6}
the memory arrangement looks like
Now answering your question:
a and &a have the same values.How?
As you already know that a is of array type and array name a becomes a pointer to first element of array a (after decay),i.e it points to the address 0x100. Note that 0x100 also is the starting address of the memory block (array a). And you should know that, in general, the address of the first byte is said to be the address of the variable. That is, if a variable is of 100 bytes, then its address is equal to the address of its first byte.
&a is address of the entire memory block, i.e it is an address of array a. See the diagram:
Now you can understand why a and &a both have same address value although both are of different type.
What exactly it does int (*p)[3]; Declares a pointer to an array,i know this.But,how a pointer to an array is different from the pointer to the first element of the array and name of the array?
See the above figure, it is explained clearly how pointer to an array is different from the pointer to an array element.
When you assign &a to p, then p points to the entire array having starting address 0x100.
NOTE: Regarding to the line
... as in C arrays are passed by references (with exception of sizeof function).
In C, arguments are passed by value. No pass by reference in C. When an ordinary variable is passed to a function, its value is copied; any changes to corresponding parameter do not affect the variable.
Arrays are also passed by value, but difference is that the array name decays to pointer to first element and this pointer assigned to the parameter (here, pointer value is copied) of the function; the array itself isn't copied.
In contrast to ordinary variable, an array used as an argument is not protected against any change, since no copy is made of the array itself, instead copy of pointer to first element is made.
You should also note that sizeof is not a function and array name does not act as an argument in this case. sizeof is an operator and array name serves as an operand. Same holds true when array name is an operand of the unary & operator.
a and &a have the same values.How?
They have the same value but different types. Array objects have no padding between elements (before or after) so the address of the array and the address of the first element of the array are the same.
That is:
(void *) a == (void *) &a
What exactly it does int (*p)[3]; Declares a pointer to an array,i know this.But,how a pointer to an array is different from the pointer to the first element of the array and name of the array?
These are two different pointer types. Take for example, pointer arithmetic:
a + 1 /* address of the second element of the array */
&a + 1 /* address one past the last element of the array */
EDIT: due to popular demand I added below some information about conversion of arrays.
With three exceptions, in an expression an object of type array of T is converted to a value of type pointer to T pointing to the first element of the array. The exceptions are if the object is the operand of sizeof or & unary operator or if the object is a string literal initializing an array.
For example this statement:
printf("a:%d\t&a:%d\n", a, &a);
is actually equivalent to:
printf("a:%d\t&a:%d\n", &a[0], &a);
Also please note that d conversion specifier can only be use to print a signed integer; to print a pointer value you have to use p specifier (and the argument must be void *). So to do things correctly use:
printf("a:%p\t&a:%p\n", (void *) a, (void *) &a);
respectively:
printf("a:%p\t&a:%p\n", (void *) &a[0], (void *) &a);
a corresponds to the pointer pointing at 0th element of the array. Whereas,the same is the case with &a.It just gives the starting address of the array.
As,a --> pointer pointing to starting element of array a[],it does not know about other element's location..
&a --->address location for storing array a[] which stores first element location,but knows every element's location.
Similarly,other elements location will be (a+2),(a+4) and so upto the end of the array.
Hence,you got such result.
int (*p)[3] is a pointer to the array. had it been int *p[3],it would been meant entirely different. It'd have meant an array of pointers which would have been totally different from this context.
Pointer to an array will automatically take care of all the other
elements in the array.In this case,your's is (p);
Whereas,the pointer to the first element of the array,i.e., a will
only know about first element of the array.You'll have to manually
give pointer arithmetic directions to access next elements.See,in this
case---we can get second element from a by adding 2 to a,i.e.
a+2,third element by adding 4 to a,i.e., a+4 and so on. // mind the
difference of two as it is an integer array!
In answer to question 1, this is simply an aspect of the C language as designed, unlike most other modern languages C/C++ allows direct manipulation of addresses in memory and has built in facilities to 'understand' that. There are many articles online that explain this better than I could in this small space. Here is one and I am sure there are many others: http://www.cprogramming.com/tutorial/c/lesson8.html
From C99 Standard n1124 6.3.2.1 p3
Except when it is the operand of the sizeof operator or the unary &
operator, or is a string literal used to initialize an array, an
expression that has type ‘‘array of type’’ is converted to an
expression with type ‘‘pointer to type’’ that points to the initial
element of the array object and is not an lvalue. If the array object
has register storage class, the behavior is undefined.
a and &a have the same value because a long time ago you were required to use the address operator & on arrays to get the array's address, but it is no longer necessary. The name of the array (a in this case) these days just represents the memory address of the array itself, which is also what you get from &a. It's a shorthand that the compiler handles for you.
I am just trying to understand the pointers concept in C and came across this error.
I got the "lvalue required as increment operand" error for the following code. Please help me understand what is wrong.
#include<stdio.h>
int main()
{
char *s[] = {"black", "white", "pink", "violet"};
++s; //error at this line
printf("%s\n", *s);
char **ptr[] = {s+3, s+2, s+1, s}, ***p;
p = ptr;
++p;
printf("%s", **p+1);
return 0;
}
s is an array of pointers to char. Array names are non-modifiable l-value. ++s is modifying s which can't be modified.
Array Names vs Pointer Variables:
As we have seen, when we declare an array, a contiguous block of memory is allocated for the cells of the array and a pointer cell (of the appropriate type) is also allocated and initialized to point to the first cell of the array. This pointer cell is given the name of the array. When memory is allocated for the array cells, the starting address is fixed, i.e. it cannot be changed during program execution. Therefore, the value of the pointer cell should not be changed. To ensure that this pointer is not changed, in C, array names may not be used as variables on the left of an assignment statement, i.e. they may not be used as an Lvalue. Instead, if necessary, separate pointer variables of the appropriate type may be declared and used as Lvalues.
Suggested reading: Is array name a pointer in C?
The problem is that in expressions an array name is converted to an rvalue of pointer to the first element of the array. That is a temporary object of type in your case char ** is created. You may not increment a temporary object. The situation is similar to what occur in the following code snippet
int x = 10;
++( x + 5 );
The compiler will issue a similar error message.
For example in your code snippet you may not write
char **ptr[] = { ++(s+3), s+2, s+1, s};
The compiler will issue the same error. In fact when you write ++s then it is equivalent to ++( s + 0 ) that is you deal not with the original array but with some temporary pointer that is rvalue`
I am having a tough time understanding the type and use of the name of the array in C. It might seems a long post but please bear with me.
I understand that the following statement declares a to be of type int [] i.e array of integers.
int a[30];
While a also points the first element of array and things like *(a+2) are valid. Thus, making a look like a pointer to an integer. But actually the types int [] and int* are different; while the former is an array type and later is a pointer to an integer.
Also a variable of type int [] gets converted into a variable of type int* when passing it to functions; as in C arrays are passed by reference (with the exception of the sizeof operator).
Here comes the point which makes me dangle. Have a look at the following piece of code:
int main()
{
int (*p)[3];
int a[3] = { 5, 4, 6 };
p = &a;
printf("a:%d\t&a:%d\n",a,&a);
printf("%d",*(*p + 2));
}
OUTPUT:
a:2686720 &a:2686720
6
So, how does the above code work? I have two questions:
a and &a have the same values. Why?
What exactly does int (*p)[3]; do? It declares a pointer to an array, I know this. But how is a pointer to an array different from the pointer to the first element of the array and name of the array?
Can anyone clarify things up? I am having a hell of a lot of confusions.
I know that I should use %p as a placeholder instead of using %d for printing the value of pointer variables. As using the integer placeholder might print truncated addresses. But I just want to keep things simple.
Other answers already explained the issue. I am trying to explain it with some diagram. Hope this will help.
When you declare an array
int a[3] = {5, 4, 6}
the memory arrangement looks like
Now answering your question:
a and &a have the same values.How?
As you already know that a is of array type and array name a becomes a pointer to first element of array a (after decay),i.e it points to the address 0x100. Note that 0x100 also is the starting address of the memory block (array a). And you should know that, in general, the address of the first byte is said to be the address of the variable. That is, if a variable is of 100 bytes, then its address is equal to the address of its first byte.
&a is address of the entire memory block, i.e it is an address of array a. See the diagram:
Now you can understand why a and &a both have same address value although both are of different type.
What exactly it does int (*p)[3]; Declares a pointer to an array,i know this.But,how a pointer to an array is different from the pointer to the first element of the array and name of the array?
See the above figure, it is explained clearly how pointer to an array is different from the pointer to an array element.
When you assign &a to p, then p points to the entire array having starting address 0x100.
NOTE: Regarding to the line
... as in C arrays are passed by references (with exception of sizeof function).
In C, arguments are passed by value. No pass by reference in C. When an ordinary variable is passed to a function, its value is copied; any changes to corresponding parameter do not affect the variable.
Arrays are also passed by value, but difference is that the array name decays to pointer to first element and this pointer assigned to the parameter (here, pointer value is copied) of the function; the array itself isn't copied.
In contrast to ordinary variable, an array used as an argument is not protected against any change, since no copy is made of the array itself, instead copy of pointer to first element is made.
You should also note that sizeof is not a function and array name does not act as an argument in this case. sizeof is an operator and array name serves as an operand. Same holds true when array name is an operand of the unary & operator.
a and &a have the same values.How?
They have the same value but different types. Array objects have no padding between elements (before or after) so the address of the array and the address of the first element of the array are the same.
That is:
(void *) a == (void *) &a
What exactly it does int (*p)[3]; Declares a pointer to an array,i know this.But,how a pointer to an array is different from the pointer to the first element of the array and name of the array?
These are two different pointer types. Take for example, pointer arithmetic:
a + 1 /* address of the second element of the array */
&a + 1 /* address one past the last element of the array */
EDIT: due to popular demand I added below some information about conversion of arrays.
With three exceptions, in an expression an object of type array of T is converted to a value of type pointer to T pointing to the first element of the array. The exceptions are if the object is the operand of sizeof or & unary operator or if the object is a string literal initializing an array.
For example this statement:
printf("a:%d\t&a:%d\n", a, &a);
is actually equivalent to:
printf("a:%d\t&a:%d\n", &a[0], &a);
Also please note that d conversion specifier can only be use to print a signed integer; to print a pointer value you have to use p specifier (and the argument must be void *). So to do things correctly use:
printf("a:%p\t&a:%p\n", (void *) a, (void *) &a);
respectively:
printf("a:%p\t&a:%p\n", (void *) &a[0], (void *) &a);
a corresponds to the pointer pointing at 0th element of the array. Whereas,the same is the case with &a.It just gives the starting address of the array.
As,a --> pointer pointing to starting element of array a[],it does not know about other element's location..
&a --->address location for storing array a[] which stores first element location,but knows every element's location.
Similarly,other elements location will be (a+2),(a+4) and so upto the end of the array.
Hence,you got such result.
int (*p)[3] is a pointer to the array. had it been int *p[3],it would been meant entirely different. It'd have meant an array of pointers which would have been totally different from this context.
Pointer to an array will automatically take care of all the other
elements in the array.In this case,your's is (p);
Whereas,the pointer to the first element of the array,i.e., a will
only know about first element of the array.You'll have to manually
give pointer arithmetic directions to access next elements.See,in this
case---we can get second element from a by adding 2 to a,i.e.
a+2,third element by adding 4 to a,i.e., a+4 and so on. // mind the
difference of two as it is an integer array!
In answer to question 1, this is simply an aspect of the C language as designed, unlike most other modern languages C/C++ allows direct manipulation of addresses in memory and has built in facilities to 'understand' that. There are many articles online that explain this better than I could in this small space. Here is one and I am sure there are many others: http://www.cprogramming.com/tutorial/c/lesson8.html
From C99 Standard n1124 6.3.2.1 p3
Except when it is the operand of the sizeof operator or the unary &
operator, or is a string literal used to initialize an array, an
expression that has type ‘‘array of type’’ is converted to an
expression with type ‘‘pointer to type’’ that points to the initial
element of the array object and is not an lvalue. If the array object
has register storage class, the behavior is undefined.
a and &a have the same value because a long time ago you were required to use the address operator & on arrays to get the array's address, but it is no longer necessary. The name of the array (a in this case) these days just represents the memory address of the array itself, which is also what you get from &a. It's a shorthand that the compiler handles for you.