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@@ -285,3 +285,7 @@ void program2(){
```
- `nothrow` is a standard function to prevent a crash if `p` is dereferenced and `length` is 0
+
+---
+
+[01/28 ->](01-28.md)
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+[\<- 01/26](01-26.md)
+
+---
+
+## Pointers and Arrays as Parameters
+
+### Value Parameters that are Pointers
+
+- When a **value parameter is a pointer**, the function **may change the value in the location that the pointer points to**
+- The actual argument in the calling program will still point to the same location, but that location will have a new value
+- Example:
+
+```
+void make_it_3(int *i_ptr){
+ //Precondition: i_ptr is pointing to an integer variable
+ //Postcondition: The integer that i_ptr is pointer at has been changed to 3
+ *i_ptr = 3;
+}
+```
+
+- Parameter `i_ptr` has type `int*`, that is, a pointer to an integer, **and it is a value parameter**
+- The body of the function does not actually change `i_ptr`; it changes only the integer that `i_ptr` points to
+- Example: Assume a program declares a pointer to an integer, allocating memory for the pointer to point to, and calls `make_it_3`:
+
+```
+int *main_ptr;
+main_ptr = new int; //main_ptr is pointing to a newly allocated integer
+make_it_3(main_ptr); //the argument, main_ptr, procides the initial value for the parameter i_ptr
+```
+
+![diagram](01-28_1.png)
+
+- In the body of `make_it_3` function, the assignment statement `*i_ptr = 3` places 3 in the location that `i_ptr` points:
+
+![diagram](01-28_2.png)
+
+- When a function returns, the formal parameter `i_ptr` is freed because it is a local variable allocated on stack memory
+- However, the pointer variable `main_ptr` is still around, and it is still pointing to the same location, but the location has a new value of 3
+
+### Array Parameters
+
+- When a parameter is an array, it is automatically treated as a pointer that points to the first element of the array
+- Example:
+
+```
+void make_it_all_3(double data[], size_t n){
+ //Precondition: data is an array with at least n components
+ //Postcondition: The first n elements of the data have been set to 3
+
+ size_t i;
+ for(i = 0; i < n; ++i){
+ data[i] = 3;
+ }
+}
+```
+
+- If the body of the function changes the components of the array, the changes **do** affect the actual argument
+- Example:
+
+```
+double main_array[10]; //data allocated on stack memory
+make_it_all_3(main_array, 10);
+cout << main_array[5]; //prints 3
+```
+
+- The actual argument of `make_it_all_3` may be a dynamic array:
+
+```
+double *numbers;
+numbers = new double[10]; //data allocated on heap memory
+make_it_all_3(numbers, 10); //set all elements to 3
+```
+
+- You need to remember to delete `numbers` before the end of the above function to avoid a memory leak!
+
+### const Parameters that are Pointers or Arrays
+
+- A parameter that is a pointer may also include the `const` keyword
+- Example:
+
+```
+bool is_3(const int *i_ptr);
+double average(const double data[], size_t n);
+```
+
+- `const` keyword indicates that `i_ptr` is a pointer to a constant integer
+- Implementation of `is_3` may examine `*i_ptr`, but may not change the value of `*i_ptr`
+- `const` keyword indicates that the function cannot change the array entries
+- The functions may examine the item that is pointed to (or the array), but changing the item (or array) is forbidden
+- Example: Is this valid?
+
+```
+bool is_3(const int *i_ptr){
+ //Precondition: i_ptr is pointing to an integer variable
+ //Postcondition: the return value is true if *i_ptr is 3
+
+ return (*i_ptr == 3);
+}
+```
+
+- The above is valid because the value of `*i_ptr` is not being changed, only examined
+
+- Example: Is this valid?
+
+```
+double average(const double data[], size_t n){
+ //Library facilities used: cassert, cstdlib
+
+ size_t i; //an array index
+ double sum; //the sum of data[0] through data[n-1]
+
+ assert(n > 0);
+
+ //add up the n numbers and return the average
+ sum = 0;
+
+ for(i = 0; i < n; ++i){
+ sum += data[i];
+ }
+
+ return (sum/n);
+}
+```
+
+- The above is valid because the values in the `data` array are not being changed, only examined
+
+### Reference Parameters that are Pointers
+
+- A **reference parameter that is a pointer** is used when a function:
+ - Changes a pointer parameter so that the pointer points to a new location
+ - The programmer needs the change to affect the actual argument
+
+- Example:
+
+```
+void allocate_doubles(double*& p, size_t& n){
+ //Postcondition: user has been prompted for a size n, and this size has been read
+ //Postcondition: pointer p has been set to point to a new dynamic array containing n doubles
+ //NOTE: If there is insufficient dynamic memory, then bad_alloc is thrown
+
+ cout << "How many doubles should I allocate?" << endl;
+ cout << "Please enter a positive integer: ";
+ cin >> n;
+ p = new double[n];
+}
+```
+
+- `p` is a pointer to a `double` (that is, `double*`) and it is a reference parameter (indicated by the symbol `&`)
+- `p = new double[n]`
+ - Allocates the array of `n` doubles
+ - `p` points to the dynamically allocated memory
+
+- In a program, we can use `allocate_doubles` to allocate an array of double values, with the size of the array determined by interacting with the user
+- Example:
+
+```
+double *numbers;
+size_t array_size;
+allocate_doubles(numbers, array_size);
+```
+
+```
+#include <iostream>
+
+void function_a(int *& a){
+ *a += 5;
+ int *c;
+ a = c;
+}
+
+void function_b(int *a){
+ *a += 5;
+ int *c = new int(7);
+ a = c;
+}
+
+int main(){
+ int *myInt = new int(5);
+ int *myInt2 = new int(5);
+
+ function_a(myInt);
+ std::cout << myInt << std::endl;
+ std::cout << *myInt << std::endl;
+
+ function_b(myInt2);
+ std::cout << myInt2 << std::endl;
+ std::cout << *myInt2 << std::endl;
+
+ return 0;
+}
+
+//OUTPUT:
+0x100202210
+7
+0x100200570
+10
+```
+
+### Overview of Parameter Types
+
+- Value Parameter:
+
+```
+void function(double p);
+```
+
+- Reference Parameter:
+
+```
+void function(double& p);
+```
+
+- const Reference Parameter:
+
+```
+void function(const double& p);
+```
+
+- Value Parameter that is Pointer:
+
+```
+void function(double *p);
+```
+
+- const Value Parameter that is Pointer:
+
+```
+void function(const double* p);
+```
+
+- Reference Parameter that is Pointer:
+
+```
+void function(double*& p);
+```
+
+---
+
+## The Bag Class with Dynamic Arrays
+
+### The Bag Class with Dynamic Arrays
+
+- Pointers enable us to define data structures whose size is determined when a program is actually **running** rather than at **compilation time**
+- Such data structures are called **dynamic data structures**
+- This is in contrast to **static data structures**, which have their size determined when a program is **compiled**
+- A class may be a dynamic data structure, i.e., it may use dynamic memory
+
+### Pointer Member Variables
+
+- The original bag class has a member variable that is a **static array** containing the bag's item
+- Our dynamic bag has a member variable that is a pointer to a **dynamic array**
+- The Static Bag:
+
+```
+class bag{
+ //...
+ private:
+ value_type data[CAPACITY];
+ size_type used;
+};
+```
+
+- The Dynamic Bag:
+
+```
+class bag{
+ //...
+ private:
+ value_type *data;
+ size_type used;
+ size_type capacity;
+};
+```
+
+- The constructor for the dynamic bag will allocate a dynamic array
+- As a program runs, a new, larger dynamic array can be allocated when we need more capacity
+
+```
+class bag{
+ public:
+ //...
+ private:
+ value_type *data; //points to a partially filled dynamic array that stores the acutal items of the bag
+ size_type used; //stores the number of items in the bag
+ size_type capacity; //sores the total size of the dynamic array
+};
+```
+
+### Member Functions Allocate Dynamic Memory As Needed
+
+- When a class uses dynamic memory, **the class's member functions allocate dynamic memory as needed**
+- Example:
+ - The constructor of the dynamic bag allocates the dynamic array that the member variable data points to
+ - **Question**: How big should this array be?
+ - Our plan is to have the constructor allocate a dynamic array whose initial size is determined by a parameter to the constructor
+ - Whenever items are inserted into a bag (through the `insert` member function or the `+=` operator) the bag's capacity may be increased
+
+- Why a programmer needs to be concerned about the initial capacity of a bag?
+- Can't we just start with a small initial capacity and insert items one after another? The `insert` function will take care of increasing the capacity as needed
+ - Yes, this approach works correctly
+ - However, if there are many items, then many of the activations of `insert` would need to increase the capacity, and this could be inefficient
+ - Each time the capacity is increased, new memory is allocated, the items are copied into the new memory, and the old memory is released
+ - **To avoid this repeated allocation of memory**, a programmer can request a large initial capacity
+
+- The new bag's constructor:
+
+```
+bag(size_type initial_capacity = DEFAULT_CAPACITY);
+//Postcondition: The bag is empty with a capacity given by the parameter
+//Postcondition: The insert function will work efficiently (without allocating new memory) until this capacity is reached
+```
+
+- Example:
+ - When the bag is declared, the programmer can specify a capacity of 1000:
+ - `bag kilosack(1000);`
+ - 1000 items can be efficiently added to kilosack
+ - After the initial capacity is reached, the `insert` function continues to work **correctly**, but it might be **slowed down by memory allocations**
+
+- Notice that the parameter of the constructor has a **default argument**, `DEFAULT_CAPACITY`, which will be a constant in our class definition
+- **The single constructor actually serves two purposes:**
+ - It **can be used with an argument** to construct a bag with a specific capacity, or
+ - It **can be used as a default constructor** (with no argument list)
+
+- Example:
+
+```
+bag ordinary; //the initial capacity is DEFAULT_CAPACITY
+bag super(9000); //the initial capacity is 9000
+```
+
+- Example:
+
+```
+bag sixpack(6); //the constructor creates a bag with an initial capacity of 6
+
+sixpack.insert(10);
+sixpack.insert(20);
+sixpack.insert(30);
+```
+
+- After these declarations, the bag's private member variable look like this:
+
+![diagram](01-28_3.png)
+
+- While the bag is in use, a programmer can make an explicit adjustment to the bag's capacity via a member function called `reserve`:
+
+```
+void reserve(size_type new_capacity);
+//Postcondition: The bag's current capacity is changed to the new_capacity (but not less than the number of items already in the bag)
+//Postcondition: The insert function will work efficiently (without allocating new memory) until the new capacity is reached
+```
+
+- By using the `reserve` member function, the bag's efficiency is improved
+- The constructor, `reserve`, `insert`, `operator +=`, and `operator +` member functions can allocate new dynamic memory
+
+### Provide Documentation About Possible Dynamic Memory Failure
+
+- There are two extra factors that play an important role whenever a class uses dynamic memory:
+ - The first factor is the **value semantics** (i.e., the assignment operator and the copy constructor)
+ - The second factor is a requirement for a special member function called a **destructor**
+
+```
+class bag{
+ public:
+ //...
+ private:
+ value_type *data;
+ size_type used;
+ size_type capacity;
+}
+```
+
+- What is the value semantics for this class?
+
+### Value Semantics
+
+- Example: Suppose we set up a bag called `x` with an initial capacity of 5, containing the integers 10, 20, and 30 - then we assign `x` to bag `y` through `y=x`
+
+![diagram](01-28_4.png)
+
+- What is the problem?
+
+- When we assign `y = x`, we want `y` to have its own dynamic array, completely separate from `x`'s dynamic array
+
+![diagram](01-28_5.png)
+
+- **We must provide our own assignment operator** rather than relying on the automatic assignment operator
+- **We can do this by overloading the assignment operator** for the bag class
+
+```
+void bag::operator = (const bag& source);
+//Postcondition: The bag that activated this function has the same items and capacity as source
+```
+
+- When you overload the assignment operator, **C++ requires it to be a member function**
+- In an assignment statement `y=x`, in fact we have `y.operator = (x)` thereby bag `y` is activating the function, and the bag `x` is the argument for the parameter named `source`
+- The second part of the value semantics is the **copy constructor**, which is activated **when a new object is initialized as a copy of an existing object**
+- Unless you indicate otherwise, `y` is initialized using the automatic copy constructor, which merely copies the member variables from `x` to `y`
+- If you want to avoid the simple copying of member variables, then **you must provide a copy constructor with the prototype:**
+
+```
+bag::bag(const bag& source);
+//Postcondition: The bag that is being constructed has been initialized with the same items and capacity as source
+```
+
+- Note: The parameter of the copy constructor is usually a const reference parameter (C++ also permits an ordinary reference parameter, **but does not allow a value parameter**)
+
+### The Destructor
+
+- The **destructor** of a class is **a member function that is automatically acitvated when an object becomes inaccessible**
+- **The primary purpose of the destructor is to return an object's dynamic memory to the heap when the object is no longer in use**
+- The destructor has three unique features
+ 1. The name of the destructor is always the tilde character (`~`) followed by the class name
+ 2. The destructor has no parameters and no return value
+ - Example: `~bag();`
+ 3. Programmers who **use** a class should not need to know about the destructor
+ - Programs rarely activate the destructor explicitly
+ - The activation is usually **automatic** whenever an object becomes inaccessible
+
+Several common situations cause **automatic destructor activation**:
+
+1. When **a local variable is an object with a destructor**, the destructor is **automatically activated when the function returns**
+- Example:
+
+```
+void example1(){
+ bag sample1;
+ ...
+}
+```
+
+- When the function `example1` returns, the destructor `sample1.~bag()` is automatically activated
+
+2. Suppose **a function has a value parameter that is an object**
+
+```
+void example2(bag sample2);
+//Does some calculation using a bag
+```
+
+- When the function `example2` returns, the destructor `sample2.~bag()` is automatically activated
+- Note: If `sample2` was a reference parameter, then the destructor would no be activated because a reference parameter is actually an object in the calling program, **and that object is still accessible**
+
+3. Suppose that **a dynamic variable is an object**
+
+```
+bag *b_ptr;
+b_ptr = new bag;
+...
+delete b_ptr;
+```
+
+- When `delete b_ptr` is executed, the destructor for `*b_ptr` is automatically activated
+- The destructor ensures that the dynamic array used by `*b_ptr` is released
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