Abstract Class Fibonacci
Mr. M's demo and code on Abstract Classes
/*
* Creator: Nighthawk Coding Society
* Mini Lab Name: Fibonacci sequence, featuring a Stream Algorithm
*
*/
import java.util.ArrayList;
import java.util.HashMap;
import java.util.stream.Stream;
/* Objective will require changing to abstract class with one or more abstract methods below */
abstract class Fibo {
String name; // name or title of method
int size; // nth sequence
int hashID; // counter for hashIDs in hash map
ArrayList<Long> list; // captures current Fibonacci sequence
HashMap<Integer, Object> hash; // captures each sequence leading to final result
/*
Zero parameter constructor uses Telescoping technique to allow setting of the required value nth
@param: none
*/
public Fibo() {
this(30); // telescope to avoid code duplication, using default as 20
}
/*
Construct the nth fibonacci number
@param: nth number, the value is constrained to 92 because of overflow in a long
*/
public Fibo(int nth) {
this.size = nth;
this.list = new ArrayList<>();
this.hashID = 0;
this.hash = new HashMap<>();
//initialize fibonacci and time mvc
this.init();
}
/*
This Method should be "abstract"
Leave method as protected, as it is only authorized to extender of the class
Make new class that extends and defines init()
Inside references within this class would change from this to super
Repeat process using for, while, recursion
*/
protected abstract void init();
/*
Number is added to fibonacci sequence, current state of "list" is added to hash for hashID "num"
*/
public void setData(long num) {
list.add(num);
hash.put(this.hashID++, list.clone());
}
/*
Custom Getter to return last element in fibonacci sequence
*/
public long getNth() {
return list.get(this.size - 1);
}
/*
Custom Getter to return last fibonacci sequence in HashMap
*/
public Object getNthSeq(int i) {
return hash.get(i);
}
/*
Console/Terminal supported print method
*/
public void print() {
System.out.println("Init method = " + this.name);
System.out.println("fibonacci Number " + this.size + " = " + this.getNth());
System.out.println("fibonacci List = " + this.list);
System.out.println("fibonacci Hashmap = " + this.hash);
for (int i=0 ; i<this.size; i++ ) {
System.out.println("fibonacci Sequence " + (i+1) + " = " + this.getNthSeq(i));
}
}
}
public class FiboFor extends Fibo {
public FiboFor() {
super();
}
public FiboFor(int nth) {
super(nth);
}
@Override
protected void init() {
super.name = "For Extends";
long limit = this.size;
// for loops are likely the most common iteration structure, all the looping facts are in one line
for (long[] f = new long[]{0, 1}; limit-- > 0; f = new long[]{f[1], f[0] + f[1]})
this.setData(f[0]);
}
/*
Tester class method. If this becomes abstract you will not be able to test it directly ...
Change this method to call "main" class of each of the extended classes
*/
static public void main(String[] args) {
FiboFor fib = new FiboFor();
fib.print();
}
}
FiboFor.main(null);
public class FiboStream extends Fibo {
public FiboStream() {
super();
}
public FiboStream(int nth) {
super(nth);
}
@Override
protected void init() {
super.name = "Stream Extends";
Stream.iterate(new long[]{0, 1}, f -> new long[]{f[1], f[0] + f[1]})
.limit(super.size)
.forEach(f -> super.setData(f[0]) );
}
/*
Tester class method. If this becomes abstract you will not be able to test it directly ...
Change this method to call "main" class of each of the extended classes
*/
static public void main(String[] args) {
FiboStream fib = new FiboStream();
fib.print();
}
}
FiboStream.main(null);