There are two sorted arrays nums1 and nums2 of size m and n respectively.
Find the median of the two sorted arrays. The overall run time complexity should be O(log (m+n)).
Example 1:
nums1 = [1, 3]
nums2 = [2]
The median is 2.0
Example 2:
nums1 = [1, 2]
nums2 = [3, 4]
The median is (2 + 3)/2 = 2.5
O(log (m+n)) means half of the sequence is ruled out on each loop. So obviously we need binary search.
To do it on two sorted arrays, we need a formula to guide division.
Let nums3
be the sorted array combining all the items in
nums1
and nums2
.
If nums2[j-1] <= nums1[i] <= nums2[j]
, then we know
nums1[i]
is at num3[i+j]
. Same goes
nums1[i-1] <= nums2[j] <= nums1[i]
.
Let k
be ⌊(m+n-1)/2⌋
. We need to find
nums3[k]
(and also nums3[k+1]
if m+n is even).
Let i + j = k
, if we find
nums2[j-1] <= nums1[i] <= nums2[j]
or
nums1[i-1] <= nums2[j] <= nums1[i]
, then we got
k
.
Otherwise, if nums1[i] <= nums2[j]
then we know
nums1[i] < nums2[j-1]
(because we did not find
k
).
There are i
items before nums1[i]
, and
j-1
items brefor nums2[j-1]
, which means
nums1[0...i]
are before nums3[i+j-1]
. So we
now know nums1[0...i] < nums3[k]
. They can be safely
discarded.
We Also have nums1[i] < nums2[j]
, which means
nums2[j...n)
are after nums3[i+j]
. So
nums2[j...n) > nums3[k]
.
Same goes nums1[i-1] <= nums2[j] <= nums1[i]
.
/**
* @param {number[]} nums1
* @param {number[]} nums2
* @return {number}
*/
let findMedianSortedArrays = function (nums1, nums2) {
const mid = ((nums1.length + nums2.length - 1) / 2) | 0;
if ((nums1.length + nums2.length) % 2 === 0) {
return (_find(nums1, nums2, mid) + _find(nums1, nums2, mid + 1)) / 2;
}
return _find(nums1, nums2, mid);
};
function _find(nums1, nums2, k) {
if (nums1.length > nums2.length) {
// So that the `i` below is always smalller than k,
// which makes `j` always non-negative
[nums1, nums2] = [nums2, nums1];
}
let s1 = 0;
let s2 = 0;
let e1 = nums1.length;
let e2 = nums2.length;
while (s1 < e1 || s2 < e2) {
const i = s1 + (((e1 - s1) / 2) | 0);
const j = k - i;
const ni = i >= e1 ? Infinity : nums1[i];
const nj = j >= e2 ? Infinity : nums2[j];
const ni_1 = i <= 0 ? -Infinity : nums1[i - 1];
const nj_1 = j <= 0 ? -Infinity : nums2[j - 1];
if (nj_1 <= ni && ni <= nj) {
return ni;
}
if (ni_1 <= nj && nj <= ni) {
return nj;
}
if (ni <= nj) {
s1 = i + 1;
e2 = j;
} else {
s2 = j + 1;
e1 = i;
}
}
}
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☆: .。. o(≧▽≦)o .。.:☆☆: .。. o(≧▽≦)o .。.:☆