added variant of median of medians for arrays

2020-10-06 18:34:26 +02:00 · 2020-10-06 18:34:26 +02:00 · c29c08cea7
commit c29c08cea7
parent 9ea381fdba
2 changed files with 103 additions and 5 deletions
--- a/MedianOfMedians.h
+++ b/MedianOfMedians.h
@ -1,6 +1,9 @@
 #pragma once

 // https://en.wikipedia.org/wiki/Median_of_medians
+// https://oneraynyday.github.io/algorithms/2016/06/17/Median-Of-Medians/
+// https://www.geeksforgeeks.org/kth-smallestlargest-element-unsorted-array-set-3-worst-case-linear-time/
+
 int findMedian(std::vector<size_t> values) {
    size_t median;
    size_t size = values.size();
@ -56,4 +59,93 @@ size_t getMedianOfMedians(const std::vector<size_t> values, size_t k) {
        return getMedianOfMedians(L2, k - ((int)L1.size()) - 1);
    }
    return m;
-}
+}
+
+// custom swap function
+void swap(size_t* a, size_t* b)
+{
+    size_t temp = *a;
+    *a = *b;
+    *b = temp;
+}
+
+// A simple function to find median of arr[].  This is called
+// only for an array of size 5 in this program.
+int findMedian(size_t arr[], int n)
+{
+    std::sort(arr, arr + n);  // Sort the array
+    return arr[n / 2];   // Return middle element
+}
+
+// It searches for x in arr[l..r], and partitions the array
+// around x.
+int partition(size_t arr[], int l, int r, int x)
+{
+    // Search for x in arr[l..r] and move it to end
+    int i;
+    for (i = l; i < r; i++)
+        if (arr[i] == x)
+            break;
+    swap(&arr[i], &arr[r]);
+
+    // Standard partition algorithm
+    i = l;
+    for (int j = l; j <= r - 1; j++)
+    {
+        if (arr[j] <= x)
+        {
+            swap(&arr[i], &arr[j]);
+            i++;
+        }
+    }
+    swap(&arr[i], &arr[r]);
+    return i;
+}
+
+// Returns k'th smallest element in arr[l..r] in worst case
+// linear time. ASSUMPTION: ALL ELEMENTS IN ARR[] ARE DISTINCT
+//int getMedianOfMedians(int arr[], int l, int r, int k)
+size_t getMedianOfMedians(size_t* arr, int l, int r, int k)
+{
+    // If k is smaller than number of elements in array
+    if (k > 0 && k <= r - l + 1)
+    {
+        int n = r - l + 1; // Number of elements in arr[l..r]
+
+        // Divide arr[] in groups of size 5, calculate median
+        // of every group and store it in median[] array.
+        // There will be floor((n + 4) / 5) groups;
+        //int median[(n + 4) / 5]; // non VS compliant!
+        size_t* median = new size_t[(n + 4) / 5];
+        int i = 0;
+        for (i = 0; i < n / 5; i++)
+            median[i] = findMedian(arr + l + i * 5, 5);
+        if (i * 5 < n) //For last group with less than 5 elements
+        {
+            median[i] = findMedian(arr + l + i * 5, n % 5);
+            i++;
+        }
+
+        // Find median of all medians using recursive call.
+        // If median[] has only one element, then no need
+        // of recursive call
+        int medOfMed = (i == 1) ? median[i - 1] :
+            getMedianOfMedians(median, 0, i - 1, i / 2);
+
+        // Partition the array around a random element and
+        // get position of pivot element in sorted array
+        int pos = partition(arr, l, r, medOfMed);
+
+        // If position is same as k
+        if (pos - l == k - 1)
+            return arr[pos];
+        if (pos - l > k - 1)  // If position is more, recur for left
+            return getMedianOfMedians(arr, l, pos - 1, k);
+
+        // Else recur for right subarray
+        return getMedianOfMedians(arr, pos + 1, r, k - pos + l - 1);
+    }
+
+    // If k is more than number of elements in array
+    return SIZE_MAX;
+}
--- a/main.cpp
+++ b/main.cpp
@ -69,10 +69,16 @@ int main(int argc, char** argv) {
    std::cout << "randomized select: " << randomizedSelect(numbers, 0, numbers.size() - 1, idxMed) << std::endl;
    Timing::getInstance()->stopRecord("randomized select");

-    // ein weiterer Median - Algorithmus aus der Literatur
-    Timing::getInstance()->startRecord("median of medians");
-    std::cout << "median of medians: " << getMedianOfMedians(numbers, idxMed) << std::endl;
-    Timing::getInstance()->stopRecord("median of medians");
+    // ein weiterer Median - Algorithmus aus der Literatur - implemented with std::vector
+    Timing::getInstance()->startRecord("vector median of medians");
+    std::cout << "vector median of medians: " << getMedianOfMedians(numbers, idxMed) << std::endl;
+    Timing::getInstance()->stopRecord("vector median of medians");
+
+    // ein weiterer Median - Algorithmus aus der Literatur - realized with array
+    std::copy(numbers.begin(), numbers.end(), array);
+    Timing::getInstance()->startRecord("array median of medians");
+    std::cout << "array median of medians: " << getMedianOfMedians(array, 0, numbers.size() - 1, idxMed) << std::endl;
+    Timing::getInstance()->stopRecord("array median of medians");

    // noch ein ein weiterer Median - Algorithmus weil wir so cool sind
    Timing::getInstance()->startRecord("wirth");