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[\<- 01/19](01-19.md)
---
# Container Classes Implementations
## The Bag Class
### The value_type must have a default constructor
- The `value_type` is used as the component type of an array in the private member variable:
```
class bag{
//...
private:
value_type data[CAPACITY]; // An array to store items
//...
};
```
- If the `value_type` is a class with constructors (rather than one of the C++ built-in types), then the compiler must initialize each component of the data array using the item's **default constructor**
- This is why our bag documentation includes the statement that "the `value_type` type must be "a class with a default constructor..."
- When an array has a component type that is a class, **the compiler uses the default constructor** to initialize the array components
### The Invariant of a Class
- We need to state **how the member variables of the bag class are used** to represent a bag of items
- There are two rules for our bag implementation
- The number of items in the bag is stored in the member variable `used`
- for an empty bag, we do not care what is stored in any of `data` for a non-empty bag, the items in the bag are stored in `data[0]` through `data[used-1]`, and we don't care what is stored in the rest of the data
- The rules that dictate how the member variables of a class represent a value (such as a bag of items) are called the **invariant** of the class
- With the exception of the constructors, **each function depends on the invariant being valid when the function is called**
- And each function, including the constructors, has a responsibility of ensuring that the invariant is valid when the function finishes
- The **invariant of a class** is a condition that is **an implicit part of every function's postcondition**
- The invariant **is not usually written as an explicit part of the preconditions and postconditions** because the programmer who uses the class does not need to know about these conditions
- The invariant is a critical part of the implementation of a class, but it has no effect on the way the class is used
### The Bag Class Implementation - The Value Semantics
- Our documentation indicates that **assignments and the copy constructor may be used with a bag**
- Our plan is to use the **automatic assignment operator** and the **automatic copy constructor**, each of which simply copies the member variables from one bag to another
- This is fine because **the copying process will copy both the data array and the member variable** `used`
- Ecample: If a programmer has two bags `x` and `y`, then the statement `y=x` will invoke the automatic assignment operator to copy all of `x.data` to `y.data`, and to copy `x.used` to `y.used`
- Our only "work" for the value semantics is confirming that the automatic operations are correct
### Header File for the Bag Class
```
#ifndef SCU_coen79_BAG1_H
#define SCU_coen79_BAG1_H
#include <cstdlib> //provides size_t
namespace scu_coen79_3{
class bag{
public:
//TYPEDEFS and MEMBER CONSTANTS
typedef int value_type;
typedef std::size_t size_type;
static const size_type CAPACITY = 30;
//CONSTRUCTOR
bag() {used = 0;};
//MODIFICATION MEMBER FUNCTIONS
size_type erase(const value_type& target);
bool erase_one(const value_type& target);
void insert(const value_type& entry);
void operator +=(const bag& addend);
//CONSTANT MEMBER FUNCTIONS
size_type size() const {return used;};
size_type count(const value_type& target) const;
private:
value_type data[CAPACITY]; //The array to store items
size_type used; //How much of array is used
};
//NONMEMBER FUNCTIONS for the bag class
bag operator +(const bag& b1, const bag& b2);
}
#endif
```
### The Bag Class Implementation - The Count Member Function
- To count **the number of occurrences of a particular item** in a bag, we step through the used portion of the partially filled array
- Remember that we are using locations `data[0]` through `data[used-1]`, so the correct loop is:
```
bag::size_type bag::count(const value_type& target) const{
size_type answer;
size_type i;
answer = 0;
for(i = 0; i < used, ++i){
if(target == data[i]) ++answer;
}
return answer;
}
```
### The Bag Class Implementation - Needing to use the Full Type Name
- When we implement the `count` function, we must take care to write the return type:
```
bag::size_type bag::count(const value_type& target) const;
```
- We have used the completely specified type `bag::size_type` rather than just `size_type`
- Because many compiler do not recognize that you are implementing a bag member functino until after seeing `bag::count`
- In the implementation, after `bag::count`, we may use simpler names such as `size_type` and `value_type`
- However, before `bag::count`, we should use the full type name `bag::size_type`
### The Bag Class Implementation - The Insert member function
- The `insert` function checks that there is room to insert a new item
- The next available location is `data[used]`
- Example: If `used=3`, then `data[0]`, `data[1]`, and `data[2]` are already occupied, and the next location is `data[3]`
```
void bag::insert(const value_type& entry){
//Library facilities used: cassert
assert(size() < CAPACITY);
data[used] = entry;
++used;
}
```
- Note: within a member function we can refer to the static member constant `CAPACITY` with no extra notation
### The Bag Class Implementation - The Erase_One member function
- How the `erase_one` function removes an item name `target` from a bag?
1. We find the index of `target` in the bag's array, and store this index in a local variable named `index`
2. Take the final item in the bag and copy it to `data[index]`
- The final item is copied onto the item that we are removing
- The reason for this copying is so that all the bag's items stay together at the front of the partially filled array, with no holes
3. Reduce the value of `used` by one - in effect reducing the used part of the array by one
- The value of `used` is reduced by one to indicate that one item has been removed
```
bool bag::erase_one(const value_type& target){
size_type index;
index = 0;
while((index < used) && (data[index] != target)){
++index;
}
if(index == used) return false;
--used;
data[index] = data[used];
return true;
}
```
- C++ uses **short-circuit evaluation** to evaluate boolean expressions
- In short-circuit evaluation: A boolean expression is evaluated from left to right, **and the evaluation stops as soon as there is enough information to determine the value of the expression**
### The Bag Class Implementation - The operator +=
- The implementation is as follows:
```
void bag::operator +=(const bag& addend){
//...
for(i = 0; i < number of items to copy; ++i){
data[used] = addend.data[i];
++used;
}
}
```
- To avoid an explicit loop **we can used the copy functino from the <algorithm> Standard Library**
### An Object can be an Argument to its Own Member Function
- **Pitfall:** The same variable is sometimes used on both sides of an assignment or other operator
- Example:
```
bag b;
b.insert(5);
b.insert(2);
b += b;
```
- In the `+=` statement, the bag `b` is activating the `+=` operator, but this smae bag `b` is the actual argument to the operator
- This is a situatino that must be carefully tested
- **Example of the danger:** Consider the **incorrect** implementation of +=
```
void bag::operator +=(const bag& addend){
size_type i;
assert(size() + addend.size() <= CAPACITY);
for(i = 0; i < addend.used; ++i){
data[used] = addend.data[i];
++used;
}
}
```
- If we activate `b+=b` then the private member variable used is the same variable as `addend.used`
- Each iteration of the loop adds 1 to `used`, and hence `addend.used` is also increasing, and the loop never ends
- What is the solution?
### The Copy Function from the C++ Standard Library
- The Standard Library contains a **copy function** for easy copying of items from one location to another
- The function is part of the `std` namespace in the `<algorithm<` facility:
```
copy(<beginning location>, <ending location>, <destination>);
```
- It continues beyond the beginning location, copying more and more items to the next spot of the destination, until we are about to copy the ending location - **The ending location is not copied**
- This implementation uses the `copy` functino from the `<algorithm>` Standard Library
```
void bag::operator +=(const bag& addend){
assert(size() + addend.size() <= CAPACITY);
copy(addend.data, addend.data + addend.used, data+used);
used += addend.used;
}
```
### The Bag Class Implementation - The Operator +
- The `operator+` is **an ordinary function** rather than a member function
- The function must take two bags, add them together into a third bag, and return this **third bag**
```
bag operator +(const bag& b1, const bag& b2){
bag answer;
assert(b1.size() + b2.size() <= bag::CAPACITY);
answer += b1;
answer += b2;
return answer;
}
```
- Does this function need to be a friend function of the bag class?
- No, we are not using any private members
### The Bag Class Implementation - The Erase member function
- The `erase` function **removes all copies of target** from the bag and returns the number of copies removed
```
bag::size_type bag::erase(const value_type& target){
size_type index = 0;
size_type many_removed = 0;
while(index < used){
if(data[index] == target){
--used;
data[index] = data[used];
++many_removed;
}
else ++index;
}
return many_removed;
}
```
### Document Class Invariant in the Implementation File
- The best place to document the class's invariant is at the top of the implementation file
- In particular, do not write the invariant in the header file, **because a programmer who uses the class does not need to know about how the invariant dictates the use of private fields**
- But the programmer who implements the class does need to know about the invariant
### The Bag Class - Analysis
- We'll use the number of items in a bag as the input size for the time analysis
- To count the operations, we'll count the number of statements executed by the function, although we won't need an exact count since our answer will use *big-O* notation
- All of the work in `count()` happens in this loop:
```
for(i = 0; i < used; ++i){
if(target == data[i]) ++answer;
}
```
- The body of the loop will be executed exactly `n` times
- The time expression is always O(n)
### Time Analysis for the Bag Functions
|Operation |Time Analysis |
|-------------------|------------------------------------------------|
|Default constructor|O(1) (consant time) |
|count |O(n) (n is the size of the bag) |
|erase_one |O(n) (linear time) |
|erase |O(n) (linear time) |
|+= another bag |O(n) (n is the size of the other bag) |
|b1 + b2 |O(n1 + n2) (n1 and n2 are the sizes of the bags)|
|insert |O(1) (constant time) |
|size |O(1) (constant time) |
- `erase_one` sometimes requires fewer than `n * (number of statements in the loop)`; however, this does not change the fact that the function is O(n)
- In the worst case, the loop does execute a full `n` iterations, therefore the correct time analysis is no better than O(n)
- Several of the other bag functions do not contain any loops at all, and do not call any functions with loops
- Example, when an item is added to a bag, the new item is always placed at the end of the array
- This class would be good to use if you need to do a lot of insertion, and not as many removals
---
# Summary
- A **container class** is a class where each object contains a collection of items
- Examples: Bags and sequences classes
- `typedef` statement makes it easy to alter the data type of the underlying items
- The simplest implementations of container classes use a **partially filled array**, which requires each object to have at least two member variables:
- The array
- A variable to keep track of how much of the array is being used
- At the top of the implementation file: When you design a class, always make an explicit statement of the rules (**invariant of the class**) that dictate how the member variables are used
---
[01/26 ->](01-26.md)
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