Please include an example with the explanation.
Dereferencing a pointer means getting the value that is stored in the memory location pointed by the pointer. The operator * is used to do this, and is called the dereferencing operator.
Why we use dereferencing pointer? It can be used to access or manipulate the data stored at the memory location, which is pointed by the pointer. Any operation applied to the dereferenced pointer will directly affect the value of the variable that it points to.
To go to an address before performing the operation. For example, in C programming, a dereferenced variable is a pointer to the variable, not the variable itself.
In computer programming, a dereference operator, also known as an indirection operator, operates on a pointer variable. It returns the location value, or l-value in memory pointed to by the variable's value.
It's usually good enough - unless you're programming assembly - to envisage a pointer containing a numeric memory address, with 1 referring to the second byte in the process's memory, 2 the third, 3 the fourth and so on....
When you want to access the data/value in the memory that the pointer points to - the contents of the address with that numerical index - then you dereference the pointer.
Different computer languages have different notations to tell the compiler or interpreter that you're now interested in the pointed-to object's (current) value - I focus below on C and C++.
Consider in C, given a pointer such as p
below...
const char* p = "abc";
...four bytes with the numerical values used to encode the letters 'a', 'b', 'c', and a 0 byte to denote the end of the textual data, are stored somewhere in memory and the numerical address of that data is stored in p
. This way C encodes text in memory is known as ASCIIZ.
For example, if the string literal happened to be at address 0x1000 and p
a 32-bit pointer at 0x2000, the memory content would be:
Memory Address (hex) Variable name Contents 1000 'a' == 97 (ASCII) 1001 'b' == 98 1002 'c' == 99 1003 0 ... 2000-2003 p 1000 hex
Note that there is no variable name/identifier for address 0x1000, but we can indirectly refer to the string literal using a pointer storing its address: p
.
To refer to the characters p
points to, we dereference p
using one of these notations (again, for C):
assert(*p == 'a'); // The first character at address p will be 'a' assert(p[1] == 'b'); // p[1] actually dereferences a pointer created by adding // p and 1 times the size of the things to which p points: // In this case they're char which are 1 byte in C... assert(*(p + 1) == 'b'); // Another notation for p[1]
You can also move pointers through the pointed-to data, dereferencing them as you go:
++p; // Increment p so it's now 0x1001 assert(*p == 'b'); // p == 0x1001 which is where the 'b' is...
If you have some data that can be written to, then you can do things like this:
int x = 2; int* p_x = &x; // Put the address of the x variable into the pointer p_x *p_x = 4; // Change the memory at the address in p_x to be 4 assert(x == 4); // Check x is now 4
Above, you must have known at compile time that you would need a variable called x
, and the code asks the compiler to arrange where it should be stored, ensuring the address will be available via &x
.
In C, if you have a variable that is a pointer to a structure with data members, you can access those members using the ->
dereferencing operator:
typedef struct X { int i_; double d_; } X; X x; X* p = &x; p->d_ = 3.14159; // Dereference and access data member x.d_ (*p).d_ *= -1; // Another equivalent notation for accessing x.d_
To use a pointer, a computer program also needs some insight into the type of data that is being pointed at - if that data type needs more than one byte to represent, then the pointer normally points to the lowest-numbered byte in the data.
So, looking at a slightly more complex example:
double sizes[] = { 10.3, 13.4, 11.2, 19.4 }; double* p = sizes; assert(p[0] == 10.3); // Knows to look at all the bytes in the first double value assert(p[1] == 13.4); // Actually looks at bytes from address p + 1 * sizeof(double) // (sizeof(double) is almost always eight bytes) ++p; // Advance p by sizeof(double) assert(*p == 13.4); // The double at memory beginning at address p has value 13.4 *(p + 2) = 29.8; // Change sizes[3] from 19.4 to 29.8 // Note earlier ++p and + 2 here => sizes[3]
Sometimes you don't know how much memory you'll need until your program is running and sees what data is thrown at it... then you can dynamically allocate memory using malloc
. It is common practice to store the address in a pointer...
int* p = (int*)malloc(sizeof(int)); // Get some memory somewhere... *p = 10; // Dereference the pointer to the memory, then write a value in fn(*p); // Call a function, passing it the value at address p (*p) += 3; // Change the value, adding 3 to it free(p); // Release the memory back to the heap allocation library
In C++, memory allocation is normally done with the new
operator, and deallocation with delete
:
int* p = new int(10); // Memory for one int with initial value 10 delete p; p = new int[10]; // Memory for ten ints with unspecified initial value delete[] p; p = new int[10](); // Memory for ten ints that are value initialised (to 0) delete[] p;
See also C++ smart pointers below.
Often a pointer may be the only indication of where some data or buffer exists in memory. If ongoing use of that data/buffer is needed, or the ability to call free()
or delete
to avoid leaking the memory, then the programmer must operate on a copy of the pointer...
const char* p = asprintf("name: %s", name); // Common but non-Standard printf-on-heap // Replace non-printable characters with underscores.... for (const char* q = p; *q; ++q) if (!isprint(*q)) *q = '_'; printf("%s\n", p); // Only q was modified free(p);
...or carefully orchestrate reversal of any changes...
const size_t n = ...; p += n; ... p -= n; // Restore earlier value... free(p);
In C++, it's best practice to use smart pointer objects to store and manage the pointers, automatically deallocating them when the smart pointers' destructors run. Since C++11 the Standard Library provides two, unique_ptr
for when there's a single owner for an allocated object...
{ std::unique_ptr<T> p{new T(42, "meaning")}; call_a_function(p); // The function above might throw, so delete here is unreliable, but... } // p's destructor's guaranteed to run "here", calling delete
...and shared_ptr
for share ownership (using reference counting)...
{ auto p = std::make_shared<T>(3.14, "pi"); number_storage1.may_add(p); // Might copy p into its container number_storage2.may_add(p); // Might copy p into its container } // p's destructor will only delete the T if neither may_add copied it
In C, NULL
and 0
- and additionally in C++ nullptr
- can be used to indicate that a pointer doesn't currently hold the memory address of a variable, and shouldn't be dereferenced or used in pointer arithmetic. For example:
const char* p_filename = NULL; // Or "= 0", or "= nullptr" in C++ int c; while ((c = getopt(argc, argv, "f:")) != -1) switch (c) { case f: p_filename = optarg; break; } if (p_filename) // Only NULL converts to false ... // Only get here if -f flag specified
In C and C++, just as inbuilt numeric types don't necessarily default to 0
, nor bools
to false
, pointers are not always set to NULL
. All these are set to 0/false/NULL when they're static
variables or (C++ only) direct or indirect member variables of static objects or their bases, or undergo zero initialisation (e.g. new T();
and new T(x, y, z);
perform zero-initialisation on T's members including pointers, whereas new T;
does not).
Further, when you assign 0
, NULL
and nullptr
to a pointer the bits in the pointer are not necessarily all reset: the pointer may not contain "0" at the hardware level, or refer to address 0 in your virtual address space. The compiler is allowed to store something else there if it has reason to, but whatever it does - if you come along and compare the pointer to 0
, NULL
, nullptr
or another pointer that was assigned any of those, the comparison must work as expected. So, below the source code at the compiler level, "NULL" is potentially a bit "magical" in the C and C++ languages...
More strictly, initialised pointers store a bit-pattern identifying either NULL
or a (often virtual) memory address.
The simple case is where this is a numeric offset into the process's entire virtual address space; in more complex cases the pointer may be relative to some specific memory area, which the CPU may select based on CPU "segment" registers or some manner of segment id encoded in the bit-pattern, and/or looking in different places depending on the machine code instructions using the address.
For example, an int*
properly initialised to point to an int
variable might - after casting to a float*
- access memory in "GPU" memory quite distinct from the memory where the int
variable is, then once cast to and used as a function pointer it might point into further distinct memory holding machine opcodes for the program (with the numeric value of the int*
effectively a random, invalid pointer within these other memory regions).
3GL programming languages like C and C++ tend to hide this complexity, such that:
If the compiler gives you a pointer to a variable or function, you can dereference it freely (as long as the variable's not destructed/deallocated meanwhile) and it's the compiler's problem whether e.g. a particular CPU segment register needs to be restored beforehand, or a distinct machine code instruction used
If you get a pointer to an element in an array, you can use pointer arithmetic to move anywhere else in the array, or even to form an address one-past-the-end of the array that's legal to compare with other pointers to elements in the array (or that have similarly been moved by pointer arithmetic to the same one-past-the-end value); again in C and C++, it's up to the compiler to ensure this "just works"
Specific OS functions, e.g. shared memory mapping, may give you pointers, and they'll "just work" within the range of addresses that makes sense for them
Attempts to move legal pointers beyond these boundaries, or to cast arbitrary numbers to pointers, or use pointers cast to unrelated types, typically have undefined behaviour, so should be avoided in higher level libraries and applications, but code for OSes, device drivers, etc. may need to rely on behaviour left undefined by the C or C++ Standard, that is nevertheless well defined by their specific implementation or hardware.
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