C++ Part 14

——- ANIMAL.H ——- 

// This guards against including this header in multiple
// files that make up the program along with #endif
#ifndef ANIMAL_H

// Read the following lines once
#define ANIMAL_H

#include <string>

class Animal {
public:
    Animal();
    Animal(const Animal& orig);
    virtual ~Animal();
    std::string name;
private:

};

#endif /* ANIMAL_H */

——- ANIMAL.CPP ——-

#include "Animal.h"

Animal::Animal() {
}

Animal::Animal(const Animal& orig) {
}

Animal::~Animal() {
}

#include <cstdlib>
#include <iostream>
#include <string>
#include <vector>
#include <ctime>
#include <numeric>
#include <cmath>
#include <sstream>

#include <deque>
#include <iterator>

// ----- PREPROCESSOR DIRECTIVES -----

// Anything that starts with a # is a preprocessor
// directive and they run before the program compiles

// Right click Header Files -> New -> C++ Header File
// and then include it here
#include "Animal.h"

// This is a macro constant that will replace 
// PI with 3.14159 in the code before execution
#define PI 3.14159

// This is a macro function that will do the same with
// a function
#define AREA_CIRCLE(radius) (PI * (std::pow(radius, 2)))

// ----- END PREPROCESSOR DIRECTIVES -----

// ----- TEMPLATE FUNCTIONS -----

// We use templates to create functions or classes
// that can work with many types
// Templates differ from function overloading in that
// instead of having a function that does similar
// things with different objects a template does the
// same thing with different objects

// This says this is a function template that generates
// functions that except 1 parameter
template <typename T>
void Times2(T val){
    std::cout << val << " * 2 = " <<
            val * 2 << "\n";
}

// Receive multiple parameters and return a value
template <typename T>
T Add(T val, T val2){
    return val + val2;
}

// Work with chars and strings
template <typename T>
T Max(T val, T val2){
    return (val < val2) ? val2 : val;
}

// ----- END OF TEMPLATE FUNCTIONS -----

// ----- TEMPLATE CLASSES -----

// Template classes are classes that can work with 
// different data types

// You can define that you may receive parameters
// with different types, but they don't have to
// be different
template <typename T, typename U>
class Person{  
public:
    T height;
    U weight;
    static int numOfPeople;
    Person(T h, U w){
        height = h, weight = w;
        numOfPeople++;
    }   
    void GetData(){
        std::cout << "Height : " <<
            height << 
            " and Weight : " <<
            weight << "\n";
    }
};

// You have to initialize static class members
template<typename T, typename U> int Person<T, U>::numOfPeople;


// ----- END OF TEMPLATE CLASSES -----

int main()
{
    Animal spot = Animal();
    spot.name = "Spot";
    std::cout << "The Animal is named " << 
            spot.name << "\n";

    std::cout << "Circle Area : " <<
            AREA_CIRCLE(5) << "\n";

    // ----- TEMPLATE FUNCTIONS -----
    // The template function can receive ints or floats
    Times2(5);
    Times2(5.3);

    // Multiple parameters and returned value
    std::cout << "5 + 4 = " <<
            Add(5,4) << "\n";
    std::cout << "5.5 + 4.6 = " <<
            Add(5.5,4.6) << "\n";

    // Get biggest value
    std::cout << "Max 4 or 8 = " <<
            Max(4, 8) << "\n";
    std::cout << "Max A or B = " <<
            Max('A', 'B') << "\n";
    std::cout << "Max Dog or Cat = " <<
            Max("Dog", "Cat") << "\n";

    // ----- END OF TEMPLATE FUNCTIONS -----

    // ----- TEMPLATE CLASSES -----

    // When creating the object you must define the 
    // data types used
    Person<double, int> mikeTyson (5.83, 216);
    mikeTyson.GetData();

    // You access static values using the object
    // and not the class
    std::cout << "Number of people : " <<
            mikeTyson.numOfPeople << "\n";

    // ----- END OF TEMPLATE CLASSES -----

    // ----- CONTAINERS -----
    // We have already seen the STL container vector
    // There are many other special ways of storing data

    // ----- DOUBLE ENDED QUEUE -----

    // A double ended queue (Deck) is a dynamic array that can 
    // be expanded or contracted on both ends
    std::deque<int> nums = {1,2,3,4};
    nums.push_front(0);
    nums.push_back(5);
    for(int x: nums)
        std::cout << x << "\n";

    // You can access index values, but they are costly
    // because values aren't stored contigously, but
    // instead use multiple arrays
    std::cout << nums[0] << "\n";

    // ----- END DOUBLE ENDED QUEUE -----

    // ----- ITERATORS -----
    // Iterators are used to point at container
    // memory locations
    std::vector<int> nums2 = {1,2,3,4};

    // Define an iterator as the same type
    std::vector<int>::iterator itr;

    // Refer to the vectors begin and end while
    // incrementing the iterator
    for(itr = nums2.begin(); 
            itr < nums2.end(); 
            itr++){

        // Get value at the pointer
        std::cout << *itr << "\n";
    }

    // You can also increment a set number of spaces
    // Create an iterator and point it at the beginning
    // of the vector
    std::vector<int>::iterator itr2 = nums2.begin();

    // Advance 2 spaces
    advance(itr2, 2);
    std::cout << *itr2 << "\n";

    // Next works like advance, but it returns an 
    // iterator
    auto itr3 = next(itr2, 1);
    std::cout << *itr3 << "\n";

    // Previous moves a set number of indexes and
    // returns an iterator
    auto itr4 = prev(itr2, 1);
    std::cout << *itr4 << "\n";

    // You can also insert at a defined index
    std::vector<int> nums3 = {1,4,5,6};
    std::vector<int> nums4 = {2,3};
    auto itr5 = nums3.begin();
    advance(itr5, 1);
    copy(nums4.begin(), nums4.end(), 
            inserter(nums3, itr5));

    for(int &i: nums3)
        std::cout << i << "\n";

    // ----- END ITERATORS -----

    // ----- END OF CONTAINERS -----

    return 0;
}