# How to find the kth smallest element in the union of two sorted arrays?

This is a homework question. They say it takes `O(logN + logM)` where `N` and `M` are the arrays lengths.

Let's name the arrays `a` and `b`. Obviously we can ignore all `a[i]` and `b[i]` where i > k.
First let's compare `a[k/2]` and `b[k/2]`. Let `b[k/2]` > `a[k/2]`. Therefore we can discard also all `b[i]`, where i > k/2.

Now we have all `a[i]`, where i < k and all `b[i]`, where i < k/2 to find the answer.

What is the next step?

-
Were all these steps included in the assignment, or are the above steps the beginning of your algorithm? – Kendrick Jan 5 '11 at 18:53
The steps above are mine. – Michael Jan 5 '11 at 19:01
Is `O(logN + logM)` only referring to the time it takes to find the kth element? Can preprocessing be done to the union beforehand? – Davidann Jan 5 '11 at 19:16
@David. No preprocessing is expected. – Michael Jan 5 '11 at 19:29
Are duplicates allowed in the arrays? – Davidann Jan 5 '11 at 19:58

You've got it, just keep going! And be careful with the indexes...

To simplify a bit I'll assume that N and M are > k, so the complexity here is O(log k), which is O(log N + log M).

Pseudo-code:

``````i = k/2
j = k - i
step = k/4
while step > 0
if a[i-1] > b[j-1]
i -= step
j += step
else
i += step
j -= step
step /= 2

if a[i-1] > b[j-1]
return a[i-1]
else
return b[j-1]
``````

For the demonstration you can use the loop invariant i + j = k, but I won't do all your homework :)

-
When initializing `j`, did you mean `j = k-i` ? – Davidann Jan 6 '11 at 16:01
This is not a real proof, but the idea behind the algorithm is that we maintain i + j = k, and find such i and j so that a[i-1] < b[j-1] < a[i] (or the other way round). Now since there are i elements in 'a' smaller than b[j-1], and j-1 elements in 'b' smaller than b[j-1], b[j-1] is the i + j-1 + 1 = kth smallest element. To find such i,j the algorithm does a dichotomic search on the arrays. Makes sense? – Jules Olléon Jan 16 '11 at 10:56
How come O(log k) is O(log n + log m) ? – Rajendra Kumar Uppal Feb 19 '12 at 13:36
This doesn't work if all of the values in array 1 come before the values in array 2. – John Kurlak Sep 24 '12 at 0:34
Why did you use k/4 as a step at first? – Maggie Sep 8 '13 at 9:24

I hope I am not answering your homework as it has been over a year since this question was asked. Here is a tail recursive solution that will take log(len(a)+len(b)) time.

Assumption: The inputs are right. i.e. k is in the range [0, len(a)+len(b)]

Base cases:

• If length of one of the arrays is 0, the answer is kth element of the second array.

Reduction steps:

• If mid index of a + mid index of b is less than k
• If mid element of a is greater than mid element of b, we can ignore the first half of b, adjust k.
• else ignore the first half of a, adjust k.
• Else if k is less than sum of mid indices of a and b:
• If mid element of a is greater than mid element of b, we can safely ignore second half of a
• else we can ignore second half of b

Code:

``````def kthlargest(arr1, arr2, k):
if len(arr1) == 0:
return arr2[k]
elif len(arr2) == 0:
return arr1[k]

mida1 = len(arr1)/2
mida2 = len(arr2)/2
if mida1+mida2<k:
if arr1[mida1]>arr2[mida2]:
return kthlargest(arr1, arr2[mida2+1:], k-mida2-1)
else:
return kthlargest(arr1[mida1+1:], arr2, k-mida1-1)
else:
if arr1[mida1]>arr2[mida2]:
return kthlargest(arr1[:mida1], arr2, k)
else:
return kthlargest(arr1, arr2[:mida2], k)
``````

Please note that my solution is creating new copies of smaller arrays in every call, this can be easily eliminated by only passing start and end indices on the original arrays.

-
why do you call it `kthlargest()` it returns `(k+1)`-th smallest elements e.g., `1` is the second smallest element in `0,1,2,3` i.e., your function returns `sorted(a+b)[k]`. – J.F. Sebastian Jul 27 '12 at 1:11
I've converted your code to C++. It seems to work – J.F. Sebastian Jul 27 '12 at 3:54
Won't it be kth smallest instead of kth largest? – Neel Feb 21 '13 at 14:34
could you please explain why is it important to compare sum of mid indexes of a and b with k? – Maggie Nov 3 '13 at 11:34
In the reduction steps, it is important to get rid of a number of elements in one of the arrays proportional to its length in order to make the run-time logarithmic. (Here we are getting rid of half). In order to do that, we need to select one array whose one of the halves we can safely ignore. How do we do that? By confidently eliminating the half we know for sure is not going to have the kth element. – lambdapilgrim Nov 4 '13 at 18:51

My attempt for first k numbers, kth number in 2 sorted arrays, and in n sorted arrays:

``````// require() is recognizable by node.js but not by browser;
// for running/debugging in browser, put utils.js and this file in <script> elements,
if (typeof require === "function") require("./utils.js");

// Find K largest numbers in two sorted arrays.
function k_largest(a, b, c, k) {
var sa = a.length;
var sb = b.length;
if (sa + sb < k) return -1;
var i = 0;
var j = sa - 1;
var m = sb - 1;
while (i < k && j >= 0 && m >= 0) {
if (a[j] > b[m]) {
c[i] = a[j];
i++;
j--;
} else {
c[i] = b[m];
i++;
m--;
}
}
debug.log(2, "i: "+ i + ", j: " + j + ", m: " + m);
if (i === k) {
return 0;
} else if (j < 0) {
while (i < k) {
c[i++] = b[m--];
}
} else {
while (i < k) c[i++] = a[j--];
}
return 0;
}

// find k-th largest or smallest number in 2 sorted arrays.
function kth(a, b, kd, dir){
sa = a.length; sb = b.length;
if (kd<1 || sa+sb < kd){
throw "Mission Impossible! I quit!";
}

var k;
//finding the kd_th largest == finding the smallest k_th;
if (dir === 1){ k = kd;
} else if (dir === -1){ k = sa + sb - kd + 1;}
else throw "Direction has to be 1 (smallest) or -1 (largest).";

return find_kth(a, b, k, sa-1, 0, sb-1, 0);
}

// find k-th smallest number in 2 sorted arrays;
function find_kth(c, d, k, cmax, cmin, dmax, dmin){

sc = cmax-cmin+1; sd = dmax-dmin+1; k0 = k; cmin0 = cmin; dmin0 = dmin;
debug.log(2, "=k: " + k +", sc: " + sc + ", cmax: " + cmax +", cmin: " + cmin + ", sd: " + sd +", dmax: " + dmax + ", dmin: " + dmin);

c_comp = k0-sc;
if (c_comp <= 0){
cmax = cmin0 + k0-1;
} else {
dmin = dmin0 + c_comp-1;
k -= c_comp-1;
}

d_comp = k0-sd;
if (d_comp <= 0){
dmax = dmin0 + k0-1;
} else {
cmin = cmin0 + d_comp-1;
k -= d_comp-1;
}
sc = cmax-cmin+1; sd = dmax-dmin+1;

debug.log(2, "#k: " + k +", sc: " + sc + ", cmax: " + cmax +", cmin: " + cmin + ", sd: " + sd +", dmax: " + dmax + ", dmin: " + dmin + ", c_comp: " + c_comp + ", d_comp: " + d_comp);

if (k===1) return (c[cmin]<d[dmin] ? c[cmin] : d[dmin]);
if (k === sc+sd) return (c[cmax]>d[dmax] ? c[cmax] : d[dmax]);

m = Math.floor((cmax+cmin)/2);
n = Math.floor((dmax+dmin)/2);

debug.log(2, "m: " + m + ", n: "+n+", c[m]: "+c[m]+", d[n]: "+d[n]);

if (c[m]<d[n]){
if (m === cmax){ // only 1 element in c;
return d[dmin+k-1];
}

k_next = k-(m-cmin+1);
return find_kth(c, d, k_next, cmax, m+1, dmax, dmin);
} else {
if (n === dmax){
return c[cmin+k-1];
}

k_next = k-(n-dmin+1);
return find_kth(c, d, k_next, cmax, cmin, dmax, n+1);
}
}

function traverse_at(a, ae, h, l, k, at, worker, wp){
var n = ae ? ae.length : 0;
var get_node;
switch (at){
case "k": get_node = function(idx){
var node = {};
var pos = l[idx] + Math.floor(k/n) - 1;
if (pos<l[idx]){ node.pos = l[idx]; }
else if (pos > h[idx]){ node.pos = h[idx];}
else{ node.pos = pos; }

node.idx = idx;
node.val = a[idx][node.pos];
debug.log(6, "pos: "+pos+"\nnode =");
debug.log(6, node);
return node;
};
break;
case "l": get_node = function(idx){
debug.log(6, "a["+idx+"][l["+idx+"]]: "+a[idx][l[idx]]);
return a[idx][l[idx]];
};
break;
case "h": get_node = function(idx){
debug.log(6, "a["+idx+"][h["+idx+"]]: "+a[idx][h[idx]]);
return a[idx][h[idx]];
};
break;
case "s": get_node = function(idx){
debug.log(6, "h["+idx+"]-l["+idx+"]+1: "+(h[idx] - l[idx] + 1));
return h[idx] - l[idx] + 1;
};
break;
default: get_node = function(){
debug.log(1, "!!! Exception: get_node() returns null.");
return null;
};
break;
}

worker.init();

debug.log(6, "--* traverse_at() *--");

var i;
if (!wp){
for (i=0; i<n; i++){
worker.work(get_node(ae[i]));
}
} else {
for (i=0; i<n; i++){
worker.work(get_node(ae[i]), wp);
}
}

return worker.getResult();
}

sumKeeper = function(){
var res = 0;
return {
init     : function(){ res = 0;},
getResult: function(){
debug.log(5, "@@ sumKeeper.getResult: returning: "+res);
return res;
},
work     : function(node){ if (node!==null) res += node;}
};
}();

maxPicker = function(){
var res = null;
return {
init     : function(){ res = null;},
getResult: function(){
debug.log(5, "@@ maxPicker.getResult: returning: "+res);
return res;
},
work     : function(node){
if (res === null){ res = node;}
else if (node!==null && node > res){ res = node;}
}
};
}();

minPicker = function(){
var res = null;
return {
init     : function(){ res = null;},
getResult: function(){
debug.log(5, "@@ minPicker.getResult: returning: ");
debug.log(5, res);
return res;
},
work     : function(node){
if (res === null && node !== null){ res = node;}
else if (node!==null &&
node.val !==undefined &&
node.val < res.val){ res = node; }
else if (node!==null && node < res){ res = node;}
}
};
}();

// find k-th smallest number in n sorted arrays;
// need to consider the case where some of the subarrays are taken out of the selection;
function kth_n(a, ae, k, h, l){
var n = ae.length;
debug.log(2, "------**  kth_n()  **-------");
debug.log(2, "n: " +n+", k: " + k);
debug.log(2, "ae: ["+ae+"],  len: "+ae.length);
debug.log(2, "h: [" + h + "]");
debug.log(2, "l: [" + l + "]");

for (var i=0; i<n; i++){
if (h[ae[i]]-l[ae[i]]+1>k) h[ae[i]]=l[ae[i]]+k-1;
}
debug.log(3, "--after reduction --");
debug.log(3, "h: [" + h + "]");
debug.log(3, "l: [" + l + "]");

if (n === 1)
return a[ae[0]][k-1];
if (k === 1)
return traverse_at(a, ae, h, l, k, "l", minPicker);
if (k === traverse_at(a, ae, h, l, k, "s", sumKeeper))
return traverse_at(a, ae, h, l, k, "h", maxPicker);

var kn = traverse_at(a, ae, h, l, k, "k", minPicker);
debug.log(3, "kn: ");
debug.log(3, kn);

var idx = kn.idx;
debug.log(3, "last: k: "+k+", l["+kn.idx+"]: "+l[idx]);
k -= kn.pos - l[idx] + 1;
l[idx] = kn.pos + 1;
debug.log(3, "next: "+"k: "+k+", l["+kn.idx+"]: "+l[idx]);
if (h[idx]<l[idx]){ // all elements in a[idx] selected;
//remove a[idx] from the arrays.
debug.log(4, "All elements selected in a["+idx+"].");
debug.log(5, "last ae: ["+ae+"]");
ae.splice(ae.indexOf(idx), 1);
h[idx] = l[idx] = "_"; // For display purpose only.
debug.log(5, "next ae: ["+ae+"]");
}

return kth_n(a, ae, k, h, l);
}

function find_kth_in_arrays(a, k){

if (!a || a.length<1 || k<1) throw "Mission Impossible!";

var ae=[], h=[], l=[], n=0, s, ts=0;
for (var i=0; i<a.length; i++){
s = a[i] && a[i].length;
if (s>0){
ae.push(i); h.push(s-1); l.push(0);
ts+=s;
}
}

if (k>ts) throw "Too few elements to choose from!";

return kth_n(a, ae, k, h, l);
}

/////////////////////////////////////////////////////
// tests
// To show everything: use 6.
debug.setLevel(1);

var a = [2, 3, 5, 7, 89, 223, 225, 667];
var b = [323, 555, 655, 673];
//var b = [99];
var c = [];

debug.log(1, "a = (len: " + a.length + ")");
debug.log(1, a);
debug.log(1, "b = (len: " + b.length + ")");
debug.log(1, b);

for (var k=1; k<a.length+b.length+1; k++){
debug.log(1, "================== k: " + k + "=====================");

if (k_largest(a, b, c, k) === 0 ){
debug.log(1, "c = (len: "+c.length+")");
debug.log(1, c);
}

try{
result = kth(a, b, k, -1);
debug.log(1, "===== The " + k + "-th largest number: " + result);
} catch (e) {
debug.log(0, "Error message from kth(): " + e);
}
debug.log("==================================================");
}

debug.log(1, "################# Now for the n sorted arrays ######################");
debug.log(1, "####################################################################");

x = [[1, 3, 5, 7, 9],
[-2, 4, 6, 8, 10, 12],
[8, 20, 33, 212, 310, 311, 623],
[8],
[0, 100, 700],
[300],
[],
null];

debug.log(1, "x = (len: "+x.length+")");
debug.log(1, x);

for (var i=0, num=0; i<x.length; i++){
if (x[i]!== null) num += x[i].length;
}
debug.log(1, "totoal number of elements: "+num);

// to test k in specific ranges:
var start = 0, end = 25;
for (k=start; k<end; k++){
debug.log(1, "=========================== k: " + k + "===========================");

try{
result = find_kth_in_arrays(x, k);
debug.log(1, "====== The " + k + "-th smallest number: " + result);
} catch (e) {
debug.log(1, "Error message from find_kth_in_arrays: " + e);
}
debug.log(1, "=================================================================");
}
debug.log(1, "x = (len: "+x.length+")");
debug.log(1, x);
debug.log(1, "totoal number of elements: "+num);
``````

The complete code with debug utils can be found at: https://github.com/brainclone/teasers/tree/master/kth

-

Here's my code based on Jules Olleon's solution:

``````int getNth(vector<int>& v1, vector<int>& v2, int n)
{
int step = n / 4;

int i1 = n / 2;
int i2 = n - i1;

while(!(v2[i2] >= v1[i1 - 1] && v1[i1] > v2[i2 - 1]))
{
if (v1[i1 - 1] >= v2[i2 - 1])
{
i1 -= step;
i2 += step;
}
else
{
i1 += step;
i2 -= step;
}

step /= 2;
if (!step) step = 1;
}

if (v1[i1 - 1] >= v2[i2 - 1])
return v1[i1 - 1];
else
return v2[i2 - 1];
}

int main()
{
int a1[] = {1,2,3,4,5,6,7,8,9};
int a2[] = {4,6,8,10,12};

//int a1[] = {1,2,3,4,5,6,7,8,9};
//int a2[] = {4,6,8,10,12};

//int a1[] = {1,7,9,10,30};
//int a2[] = {3,5,8,11};
vector<int> v1(a1, a1+9);
vector<int> v2(a2, a2+5);

cout << getNth(v1, v2, 5);
return 0;
}
``````
-
This will not work for some cases. For example, int a2[] = {1,2,3,4, 5}; int a1[] = {5,6,8,10,12}; getNth( a1, a2, 7 ). The index of the array will go out of boundary. – Jay Apr 20 '11 at 3:35

Here's a C++ iterative version of @lambdapilgrim's solution (see the explanation of the algorithm there):

``````#include <cassert>
#include <iterator>

template<class RandomAccessIterator, class Compare>
typename std::iterator_traits<RandomAccessIterator>::value_type
nsmallest_iter(RandomAccessIterator firsta, RandomAccessIterator lasta,
RandomAccessIterator firstb, RandomAccessIterator lastb,
size_t n,
Compare less) {
assert(issorted(firsta, lasta, less) && issorted(firstb, lastb, less));
for ( ; ; ) {
assert(n < static_cast<size_t>((lasta - firsta) + (lastb - firstb)));
if (firsta == lasta) return *(firstb + n);
if (firstb == lastb) return *(firsta + n);

size_t mida = (lasta - firsta) / 2;
size_t midb = (lastb - firstb) / 2;
if ((mida + midb) < n) {
if (less(*(firstb + midb), *(firsta + mida))) {
firstb += (midb + 1);
n -= (midb + 1);
}
else {
firsta += (mida + 1);
n -= (mida + 1);
}
}
else {
if (less(*(firstb + midb), *(firsta + mida)))
lasta = (firsta + mida);
else
lastb = (firstb + midb);
}
}
}
``````

It works for all `0 <= n < (size(a) + size(b))` indexes and has `O(log(size(a)) + log(size(b)))` complexity.

### Example

``````#include <functional> // greater<>
#include <iostream>

#define SIZE(a) (sizeof(a) / sizeof(*a))

int main() {
int a[] = {5,4,3};
int b[] = {2,1,0};
int k = 1; // find minimum value, the 1st smallest value in a,b

int i = k - 1; // convert to zero-based indexing
int v = nsmallest_iter(a, a + SIZE(a), b, b + SIZE(b),
SIZE(a)+SIZE(b)-1-i, std::greater<int>());
std::cout << v << std::endl; // -> 0
return v;
}
``````
-

Many people answered this "kth smallest element from two sorted array" question, but usually with only general ideas, not a clear working code or boundary conditions analysis.

Here I'd like to elaborate it carefully with the way I went though to help some novices to understand, with my correct working Java code. A1 and A2 are two sorted ascending array, with size1 and size2 as length respectively. We need to find the k-th smallest element from the union of that two array. Here we reasonably assume that (k > 0 && k <= size1 + size2), which implies that A1 and A2 can't be both empty.

First, let's approach this question with a slow O(k) algorithm. The method is to compare the first element of both array, A1[0] and A2[0]. Take the smaller one, say A1[0] away into our pocket. Then compare A1[1] with A2[0], and so on. Repeat this action until our pocket reached k elements. Very important: In the first step, we can only commit to A1[0] in our pocket. We can NOT include or exclude A2[0]!!!

Below O(k) code gives you one element before the correct answer. Here I use it to show my idea, and analysis boundary condition. I have correct code after this one:

``````private E kthSmallestSlowWithFault(int k) {
int size1 = A1.length, size2 = A2.length;

int index1 = 0, index2 = 0;
// base case, k == 1
if (k == 1) {
if (size1 == 0) {
return A2[index2];
} else if (size2 == 0) {
return A1[index1];
} else if (A1[index1].compareTo(A2[index2]) < 0) {
return A1[index1];
} else {
return A2[index2];
}
}

/* in the next loop, we always assume there is one next element to compare with, so we can
* commit to the smaller one. What if the last element is the kth one?
*/
if (k == size1 + size2) {
if (size1 == 0) {
return A2[size2 - 1];
} else if (size2 == 0) {
return A1[size1 - 1];
} else if (A1[size1 - 1].compareTo(A2[size2 - 1]) > 0) {
return A1[size1 - 1];
} else {
return A2[size2 - 1];
}
}

/*
* only when k > 1, below loop will execute. In each loop, we commit to one element, till we
* reach (index1 + index2 == k - 1) case. But the answer is not correct, always one element
* ahead, because we didn't merge base case function into this loop yet.
*/
int lastElementFromArray = 0;
while (index1 + index2 < k - 1) {
if (A1[index1].compareTo(A2[index2]) < 0) {
index1++;
lastElementFromArray = 1;
// commit to one element from array A1, but that element is at (index1 - 1)!!!
} else {
index2++;
lastElementFromArray = 2;
}
}
if (lastElementFromArray == 1) {
return A1[index1 - 1];
} else {
return A2[index2 - 1];
}
}
``````

The most powerful idea is that in each loop, we always use the base case approach. After committed to the current smallest element, we get one step closer to the target: the k-th smallest element. Never jump into the middle and make yourself confused and lost!

By observing the above code base case k == 1, k == size1+size2, and combine with that A1 and A2 can't both be empty. We can turn the logic into below more concise style.

Here is a slow but correct working code:

``````private E kthSmallestSlow(int k) {
// System.out.println("this is an O(k) speed algorithm, very concise");
int size1 = A1.length, size2 = A2.length;

int index1 = 0, index2 = 0;
while (index1 + index2 < k - 1) {
if (size1 > index1 && (size2 <= index2 || A1[index1].compareTo(A2[index2]) < 0)) {
index1++; // here we commit to original index1 element, not the increment one!!!
} else {
index2++;
}
}
// below is the (index1 + index2 == k - 1) base case
// also eliminate the risk of referring to an element outside of index boundary
if (size1 > index1 && (size2 <= index2 || A1[index1].compareTo(A2[index2]) < 0)) {
return A1[index1];
} else {
return A2[index2];
}
}
``````

Now we can try a faster algorithm runs at O(log k). Similarly, compare A1[k/2] with A2[k/2], if A1[k/2] is smaller, then all the elements from A1[0] to A1[k/2] should be in our pocket. The idea is not just commit to one element in each loop, the first step contains k/2 elements. Again, we can NOT include or exclude A2[0] to A2[k/2] anyway. So in the first step, we can't go more than k/2 elements. For the second step, we can't go more than k/4 elements...

After each step, we get much closer to k-th element. At the same time each step get smaller and smaller, until we reach (step == 1), which is (k-1 == index1+index2). Then we can refer to the simple and powerful base case again.

Here is the working correct code:

``````private E kthSmallestFast(int k) {
// System.out.println("this is an O(log k) speed algorithm with meaningful variables name");
int size1 = A1.length, size2 = A2.length;

int index1 = 0, index2 = 0, step = 0;
while (index1 + index2 < k - 1) {
step = (k - index1 - index2) / 2;
int step1 = index1 + step;
int step2 = index2 + step;
if (size1 > step1 - 1
&& (size2 <= step2 - 1 || A1[step1 - 1].compareTo(A2[step2 - 1]) < 0)) {
index1 = step1; // commit to element at index = step1 - 1
} else {
index2 = step2;
}
}
// the base case of (index1 + index2 == k - 1)
if (size1 > index1 && (size2 <= index2 || A1[index1].compareTo(A2[index2]) < 0)) {
return A1[index1];
} else {
return A2[index2];
}
}
``````

Some people may worry what if (index1+index2) jump over k-1? Could we miss the base case (k-1 == index1+index2)? That's impossible. You can add up 0.5+0.25+0.125..., and you will never go beyond 1.

Of course, it is very easy to turn the above code into recursive algorithm:

``````private E kthSmallestFastRecur(int k, int index1, int index2, int size1, int size2) {
// System.out.println("this is an O(log k) speed algorithm with meaningful variables name");

// the base case of (index1 + index2 == k - 1)
if (index1 + index2 == k - 1) {
if (size1 > index1 && (size2 <= index2 || A1[index1].compareTo(A2[index2]) < 0)) {
return A1[index1];
} else {
return A2[index2];
}
}

int step = (k - index1 - index2) / 2;
int step1 = index1 + step;
int step2 = index2 + step;
if (size1 > step1 - 1 && (size2 <= step2 - 1 || A1[step1 - 1].compareTo(A2[step2 - 1]) < 0)) {
index1 = step1;
} else {
index2 = step2;
}
return kthSmallestFastRecur(k, index1, index2, size1, size2);
}
``````

Hope the above analysis and Java code could help you to understand. But never copy my code as your homework! Cheers ;)

-
Thank you so much for your great explanations and answer, +1 :) – Hengameh Aug 1 at 11:23
In first code, shouldn't be `else if (A1[size1 - 1].compareTo(A2[size2 - 1]) < 0)` instead of `else if (A1[size1 - 1].compareTo(A2[size2 - 1]) > 0)` ? (In kthSmallestSlowWithFault code) – Hengameh Aug 1 at 12:47

Here is my implementation in C, you can refer to @Jules Olléon 's explains for the algorithm: the idea behind the algorithm is that we maintain i + j = k, and find such i and j so that a[i-1] < b[j-1] < a[i] (or the other way round). Now since there are i elements in 'a' smaller than b[j-1], and j-1 elements in 'b' smaller than b[j-1], b[j-1] is the i + j-1 + 1 = kth smallest element. To find such i,j the algorithm does a dichotomic search on the arrays.

``````int find_k(int A[], int m, int B[], int n, int k) {
if (m <= 0 )return B[k-1];
else if (n <= 0) return A[k-1];
int i =  ( m/double (m + n))  * (k-1);
if (i < m-1 && i<k-1) ++i;
int j = k - 1 - i;

int Ai_1 = (i > 0) ? A[i-1] : INT_MIN, Ai = (i<m)?A[i]:INT_MAX;
int Bj_1 = (j > 0) ? B[j-1] : INT_MIN, Bj = (j<n)?B[j]:INT_MAX;
if (Ai >= Bj_1 && Ai <= Bj) {
return Ai;
} else if (Bj >= Ai_1 && Bj <= Ai) {
return Bj;
}
if (Ai < Bj_1) { // the answer can't be within A[0,...,i]
return find_k(A+i+1, m-i-1, B, n, j);
} else { // the answer can't be within A[0,...,i]
return find_k(A, m, B+j+1, n-j-1, i);
}
}
``````
-

Here's my solution. The C++ code prints the kth smallest value as well as the number of iterations to get the kth smallest value using a loop, which in my opinion is in the order of log(k). The code however requires k to be smaller than the length of the first array which is a limitation.

``````#include <iostream>
#include <vector>
#include<math.h>
using namespace std;

template<typename comparable>
comparable kthSmallest(vector<comparable> & a, vector<comparable> & b, int k){

int idx1; // Index in the first array a
int idx2; // Index in the second array b
comparable maxVal, minValPlus;
float iter = k;
int numIterations = 0;

if(k > a.size()){ // Checks if k is larger than the size of first array
cout << " k is larger than the first array" << endl;
return -1;
}
else{ // If all conditions are satisfied, initialize the indexes
idx1 = k - 1;
idx2 = -1;
}

for ( ; ; ){
numIterations ++;
if(idx2 == -1 || b[idx2] <= a[idx1] ){
maxVal = a[idx1];
minValPlus = b[idx2 + 1];
idx1 = idx1 - ceil(iter/2); // Binary search
idx2 = k - idx1 - 2; // Ensures sum of indices  = k - 2
}
else{
maxVal = b[idx2];
minValPlus = a[idx1 + 1];
idx2 = idx2 - ceil(iter/2); // Binary search
idx1 = k - idx2 - 2; // Ensures sum of indices  = k - 2
}
if(minValPlus >= maxVal){ // Check if kth smallest value has been found
cout << "The number of iterations to find the " << k << "(th) smallest value is    " << numIterations << endl;
return maxVal;

}
else
iter/=2; // Reduce search space of binary search
}
}

int main(){
//Test Cases
vector<int> a = {2, 4, 9, 15, 22, 34, 45, 55, 62, 67, 78, 85};
vector<int> b = {1, 3, 6, 8, 11, 13, 15, 20, 56, 67, 89};
// Input k < a.size()
int kthSmallestVal;
for (int k = 1; k <= a.size() ; k++){
kthSmallestVal = kthSmallest<int>( a ,b ,k );
cout << k <<" (th) smallest Value is " << kthSmallestVal << endl << endl << endl;
}
}
``````
-

Check this code.

``````import math
def findkthsmallest():

A=[1,5,10,22,30,35,75,125,150,175,200]
B=[15,16,20,22,25,30,100,155,160,170]
lM=0
lN=0
hM=len(A)-1
hN=len(B)-1
k=17

while True:
if k==1:
return min(A[lM],B[lN])

cM=hM-lM+1
cN=hN-lN+1
tmp = cM/float(cM+cN)
iM=int(math.ceil(tmp*k))
iN=k-iM
iM=lM+iM-1
iN=lN+iN-1
if A[iM] >= B[iN]:
if iN == hN or A[iM] < B[iN+1]:
return A[iM]
else:
k = k - (iN-lN+1)
lN=iN+1
hM=iM-1
if B[iN] >= A[iM]:
if iM == hM or B[iN] < A[iM+1]:
return B[iN]
else:
k = k - (iM-lM+1)
lM=iM+1
hN=iN-1
if hM < lM:
return B[lN+k-1]
if hN < lN:
return A[lM+k-1]

if __name__ == '__main__':
print findkthsmallest();
``````
-

The first pseudo code provided above, does not work for many values. For example, here are two arrays. int[] a = { 1, 5, 6, 8, 9, 11, 15, 17, 19 }; int[] b = { 4, 7, 8, 13, 15, 18, 20, 24, 26 };

It did not work for k=3 and k=9 in it. I have another solution. It is given below.

``````private static void traverse(int pt, int len) {
int temp = 0;

if (len == 1) {
int val = 0;
while (k - (pt + 1) - 1 > -1 && M[pt] < N[k - (pt + 1) - 1]) {

if (val == 0)
val = M[pt] < N[k - (pt + 1) - 1] ? N[k - (pt + 1) - 1]
: M[pt];
else {
int t = M[pt] < N[k - (pt + 1) - 1] ? N[k - (pt + 1) - 1]
: M[pt];
val = val < t ? val : t;

}

++pt;
}

if (val == 0)
val = M[pt] < N[k - (pt + 1) - 1] ? N[k - (pt + 1) - 1] : M[pt];

System.out.println(val);
return;
}

temp = len / 2;

if (M[pt + temp - 1] < N[k - (pt + temp) - 1]) {
traverse(pt + temp, temp);

} else {
traverse(pt, temp);
}

}
``````

But... it is also not working for k=5. There is this even/odd catch of k which is not letting it to be simple.

-

Below C# code to Find the k-th Smallest Element in the Union of Two Sorted Arrays. Time Complexity : O(logk)

``````public int findKthElement(int k, int[] array1, int start1, int end1, int[] array2, int start2, int end2)
{
// if (k>m+n) exception
if (k == 0)
{
return Math.Min(array1[start1], array2[start2]);
}
if (start1 == end1)
{
return array2[k];
}
if (start2 == end2)
{
return array1[k];
}
int mid = k / 2;
int sub1 = Math.Min(mid, end1 - start1);
int sub2 = Math.Min(mid, end2 - start2);
if (array1[start1 + sub1] < array2[start2 + sub2])
{
return findKthElement(k - mid, array1, start1 + sub1, end1, array2, start2, end2);
}
else
{
return findKthElement(k - mid, array1, start1, end1, array2, start2 + sub2, end2);
}
}
``````
-
Why you put code on stackoverflow with so many bugs??? – sammy333 Nov 29 '14 at 15:29
there is no bug, i have tested my code before i posted to SO – Piyush Patel Dec 4 '14 at 17:58