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Merge pull request #309 from YooSeonjae/master

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Scheduling to Minimize Lateness ( Greedy Algorithm )
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Christian Bender 2018-07-16 23:55:48 +02:00 committed by GitHub
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211
ClosestPair/ClosestPair.java Normal file
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import java.io.*;
import java.util.*;
public class ClosestPair {
static int count = 0;// array length
static int secondCount = 0;// array length
static Location array[] = new Location[10000];
static Location point1 = null; // Minimum point coordinate
static Location point2 = null; // Minimum point coordinate
static double minNum = Double.MAX_VALUE;// Minimum point length
private static class Location { // Location class
double x = 0, y = 0;
public Location(double x, double y) { //Save x, y coordinates
this.x = x;
this.y = y;
}
}
public static int xPartition(Location[] a, int first, int last) { // x-axis Quick Sorting
Location pivot = a[last]; // pivot
int pIndex = last;
int i = first - 1;
Location temp; // Temporarily store the value for position transformation
for (int j = first; j <= last - 1; j++) {
if (a[j].x <= pivot.x) { // Less than or less than pivot
i++;
temp = a[i]; // array[i] <-> array[j]
a[i] = a[j];
a[j] = temp;
}
}
i++;
temp = a[i];// array[pivot] <-> array[i]
a[i] = a[pIndex];
a[pIndex] = temp;
return i;// pivot index
}
public static int yPartition(Location[] a, int first, int last) { //y-axis Quick Sorting
Location pivot = a[last]; // pivot
int pIndex = last;
int i = first - 1;
Location temp; // Temporarily store the value for position transformation
for (int j = first; j <= last - 1; j++) {
if (a[j].y <= pivot.y) { // Less than or less than pivot
i++;
temp = a[i]; // array[i] <-> array[j]
a[i] = a[j];
a[j] = temp;
}
}
i++;
temp = a[i];// array[pivot] <-> array[i]
a[i] = a[pIndex];
a[pIndex] = temp;
return i;// pivot index
}
public static void xQuickSort(Location[] a, int first, int last) { //x-axis Quick Sorting
if (first < last) {
int q = xPartition(a, first, last); // pivot
xQuickSort(a, first, q - 1); // Left
xQuickSort(a, q + 1, last); // Right
}
}
public static void yQuickSort(Location[] a, int first, int last) { //y-axis Quick Sorting
if (first < last) {
int q = yPartition(a, first, last); // pivot
yQuickSort(a, first, q - 1); // Left
yQuickSort(a, q + 1, last); // Right
}
}
public static double closestPair(Location[] a, int indexNum, int first, int last) {// closestPair
Location divideArray[] = new Location[indexNum]; // array stored before divide
System.arraycopy(a, 0, divideArray, 0, indexNum); // Copy from previous array
int totalNum = indexNum; // number of coordinates in the divideArray array
int divideX = indexNum / 2; // Intermediate value for divide
Location leftArray[] = new Location[divideX]; //divide - left array
Location rightArray[] = new Location[totalNum - divideX]; //divide - right array
if (indexNum <= 3) { // If the number of coordinates is 3 or less
return bruteForce(divideArray);
}
System.arraycopy(divideArray, 0, leftArray, 0, divideX); //divide - left array
System.arraycopy(divideArray, divideX, rightArray, 0, totalNum - divideX); //divide - right array
double minLeftArea = 0; //Minimum length of left array
double minRightArea = 0; //Minimum length of right array
double minValue = 0; //Minimum lengt
minLeftArea = closestPair(leftArray, divideX, 0, divideX - 1); // recursive closestPair
minRightArea = closestPair(rightArray, totalNum - divideX, divideX, totalNum - divideX - 1);
minValue = Math.min(minLeftArea, minRightArea);// window size (= minimum length)
// Create window
for (int i = 0; i < totalNum; i++) { // Set the size for creating a window and creating a new array for the coordinates in the window
double xGap = Math.abs(divideArray[divideX].x - divideArray[i].x);
if (xGap < minValue) {
secondCount++; // size of the array
} else {
if (divideArray[i].x > divideArray[divideX].x) {
break;
}
}
}
Location firstWindow[] = new Location[secondCount]; // new array for coordinates in window
int k = 0;
for (int i = 0; i < totalNum; i++) {
double xGap = Math.abs(divideArray[divideX].x - divideArray[i].x);
if (xGap < minValue) { // if it's inside a window
firstWindow[k] = divideArray[i]; // put in an array
k++;
} else {
if (divideArray[i].x > divideArray[divideX].x) {
break;
}
}
}
yQuickSort(firstWindow, 0, secondCount - 1);// Sort by y coordinates
/ * Coordinates in Window * /
double length = 0;
for (int i = 0; i < secondCount - 1; i++) { // size comparison within window
for (int j = (i + 1); j < secondCount; j++) {
double xGap = Math.abs(firstWindow[i].x - firstWindow[j].x);
double yGap = Math.abs(firstWindow[i].y - firstWindow[j].y);
if (yGap < minValue) {
length = (double) Math.sqrt(Math.pow(xGap, 2) + Math.pow(yGap, 2));
if (length < minValue) { // If the measured distance is less than the current minimum distance
minValue = length;// Change minimum distance to current distance
if (length < minNum) { // Conditional statement for registering final coordinate
minNum = length;
point1 = firstWindow[i];
point2 = firstWindow[j];
}
}
}
else
break;
}
}
secondCount = 0;
return minValue;
}
public static double bruteForce(Location[] array) { // When the number of coordinates is less than 3
double minValue = Double.MAX_VALUE; // minimum distance
double length = 0;
double xGap = 0, yGap = 0; // Difference between x, y coordinates
if (array.length == 2) { // When there are two coordinates
xGap = (array[0].x - array[1].x); // Difference between x coordinates
yGap = (array[0].y - array[1].y); // Difference between y coordinates
length = (double) Math.sqrt(Math.pow(xGap, 2) + Math.pow(yGap, 2)); // distance between coordinates
if (length < minNum) { // Conditional statement for registering final coordinate
minNum = length;
point1 = array[0];
point2 = array[1];
}
return length;
} else if (array.length == 3) { // When there are 3 coordinates
for (int i = 0; i < array.length - 1; i++) {
for (int j = (i + 1); j < array.length; j++) {
xGap = (array[i].x - array[j].x); // Difference between x coordinates
yGap = (array[i].y - array[j].y); // Difference between y coordinates
length = (double) Math.sqrt(Math.pow(xGap, 2) + Math.pow(yGap, 2)); // distance between coordinates
if (length < minValue) { // If the measured distance is less than the current minimum distance
minValue = length; // Change minimum distance to current distance
if (length < minNum) { // Conditional statement for registering final coordinate
minNum = length;
point1 = array[i];
point2 = array[j];
}
}
}
}
return minValue;
}
return minValue;
}
public static void main(String[] args) throws IOException {
// TODO Auto-generated method stub
StringTokenizer token;
BufferedReader in = new BufferedReader(new FileReader("closest_data.txt"));
//Input data consists of one x-coordinate and one y-coordinate
String ch;
System.out.println("Input data");
while ((ch = in.readLine()) != null) {
token = new StringTokenizer(ch, " ");
array[count] = new Location(Double.parseDouble(token.nextToken()), Double.parseDouble(token.nextToken())); // put in an array
count++; // the number of coordinates actually in the array
System.out.println("x: "+array[count - 1].x + ", y: " + array[count - 1].y);
}
xQuickSort(array, 0, count - 1); // Sorting by x value
double result; // minimum distance
result = closestPair(array, count, 0, count - 1); // ClosestPair start
System.out.println("Output Data");// minimum distance coordinates and distance output
System.out.println("(" + point1.x + ", " + point1.y + ")");
System.out.println("(" + point2.x + ", " + point2.y + ")");
System.out.println("Minimum Distance : " + result);
}
}

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ClosestPair/closest_data.txt Normal file
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2 3
2 16
3 9
6 3
7 7
9 12
10 11
15 2
15 19
16 11
17 13
19 4

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MinimizingLateness/MinimizingLateness.java Normal file
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import java.io.*;
import java.util.*;
public class MinimizingLateness {
private static class Schedule { // Schedule class
int t = 0; // Time required for the operation to be performed
int d = 0; // Time the job should be completed
int s = 0; // Start time of the task
int f = 0; // End time of the operation
public Schedule(int t, int d) {
this.t = t;
this.d = d;
}
}
public static void main(String[] args) throws IOException {
// TODO Auto-generated method stub
StringTokenizer token;
String ch;
BufferedReader in = new BufferedReader(new FileReader("input.txt"));
int indexCount; // size of array index
ch = in.readLine();
indexCount = Integer.parseInt(ch); // The first line specifies the size of the operation (= the size of the array)
System.out.println("Input Data : ");
System.out.println(indexCount); // number of operations
Schedule array[] = new Schedule[indexCount]; // Create an array to hold the operation
int i = 0;
while ((ch = in.readLine()) != null) {
token = new StringTokenizer(ch, " ");
// Include the time required for the operation to be performed in the array and the time it should be completed.
array[i] = new Schedule(Integer.parseInt(token.nextToken()), Integer.parseInt(token.nextToken()));
i++; // 다음 인덱스
System.out.println(array[i - 1].t + " " + array[i - 1].d);
}
int tryTime = 0; // Total time worked
int lateness = 0; // Lateness
for (int j = 0; j < indexCount - 1; j++) {
array[j].s = tryTime; // Start time of the task
array[j].f = tryTime + array[j].t; // Time finished
tryTime = tryTime + array[j].t; // Add total work time
// Lateness
lateness = lateness + Math.max(0, tryTime - array[j].d);
}
System.out.println();
System.out.println("Output Data : ");
System.out.println(lateness);
}
}

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MinimizingLateness/data06_lateness.txt Normal file
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6
3 6
2 8
1 9
4 9
3 14
2 15