414. Third Maximum Number
Problem Description
The task is to look at a list of integers, nums
, and from that list, identify the third highest distinct number. Distinct numbers are those that are not the same as any others in the list. In other words, if we were to sort all the unique numbers from highest to lowest, we want the number that would be in third place.
However, there's a catch. If it turns out that there aren't enough unique numbers to have a third place, the problem tells us to instead give back the highest number from the original list.
Intuition
The key challenge here is to do this efficiently and with care to ensure that we only consider unique elements from the array. A straightforward idea might be to first remove duplicates and then sort the array but this could be costly in terms of time especially if the array is large.
The solution ingeniously handles this by iterating over the list just once and keeping track of the three highest unique numbers seen so far, which are stored in variables m1
, m2
, and m3
. This mirrors maintaining the first three places in a race where m1
is the gold medal position, m2
is the silver, and m3
is the bronze.
During each iteration, the code checks if the current number is already in one of the medal positions. If it is, it's not distinct and can be ignored. If it’s a new number and bigger than the current gold (m1), then m1 takes the value of this number, and the previous m1 and m2 values move to second and third place respectively. A similar shift happens if the new number is smaller than m1 but bigger than m2 (m2 takes the new value, and m3 takes the old m2), and again for m3.
This way, by the end of the loop, we have the top three distinct values without any unnecessary computations. If m3 is still set to the smallest value it could be (-inf
here is used to symbolize the smallest possible value), then there weren’t enough distinct numbers to have a third place, and so we return m1, the top value.
Learn more about Sorting patterns.
Solution Approach
The implementation of the solution uses a straightforward single-pass algorithm with constant space complexity—that is, it only needs a handful of variables to keep track of the top three numbers, rather than any additional data structures that depend on the size of the input array.
Here's a step-by-step walk-through of the algorithm:
-
Three variables,
m1
,m2
, andm3
, are initialized to hold the top three maximum numbers, but are initially set to negative infinity (-inf
in Python), representing the lowest possible value. Why? Because we're trying to find the maximum, we can safely assume that any number from the input will be higher than-inf
. -
The algorithm iteratively examines each
num
innums
:-
It first checks if
num
is already one of the three maximum values seen so far to avoid duplication. If it is, the algorithm simply continues to the next iteration with thecontinue
statement. -
If
num
is greater than the current maximumm1
, it means a new highest value has been found. Consequently,m1
is updated tonum
, and the previousm1
andm2
are moved down tom2
andm3
, respectively. This is somewhat like shifting the winners of the race down one podium spot to make room for the new champion at the top. -
If
num
is not higher thanm1
but is higher thanm2
, the second place is updated tonum
, and the previousm2
is pushed down tom3
. The gold medalist (m1
) remains unchanged. -
If
num
falls belowm1
andm2
but is higher thanm3
, thenm3
is updated tonum
. There is no effect onm1
orm2
.
-
-
After the loop concludes, the algorithm checks if the bronze position
m3
is still set to-inf
. If it is, it means we never found a third distinct maximum number, so we returnm1
, the highest value found. Ifm3
has been updated with a number from the array, we return it as it represents the third distinct maximum number.
This clever approach allows us to find the answer with a time complexity of O(n) where n is the number of elements in nums
since we're only going over the elements once. There's no additional space needed that scales with the input size, so the space complexity is O(1).
Additionally, the algorithm benefits from short-circuiting; it skips unnecessary comparisons as soon as it has asserted that a number is not a potential candidate for the top three distinct values. This adds a little extra efficiency, as does the fact that there's no need to deal with sorting or dynamically sized data structures.
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Start EvaluatorExample Walkthrough
Let's apply the solution approach to a small example to better understand how it works. Consider the following list of integers:
nums = [5, 2, 2, 4, 1, 5, 6]
We want to use the described algorithm to find the third highest distinct number in this list. As per the problem, if there are not enough unique numbers, we should return the highest number.
-
We initialize three variables
m1
,m2
, andm3
to-inf
, representing the three highest unique numbers we're looking for. -
We start iterating over
nums
:a. First element,
5
: - It is not inm1
,m2
, orm3
(all are-inf
), som1
becomes5
. Now,m1 = 5
,m2 = -inf
,m3 = -inf
.b. Second element,
2
: - Not already present inm1
,m2
, orm3
, and it's less thanm1
, som2
becomes2
. Now,m1 = 5
,m2 = 2
,m3 = -inf
.c. Third and fourth elements, both
2
: - They matchm2
so we continue to the next iteration as these are not distinct numbers.d. Fifth element,
4
: - Not matched withm1
orm2
and is greater thanm2
, som2
gets pushed tom3
andm2
becomes4
. Now,m1 = 5
,m2 = 4
,m3 = 2
.e. Sixth element, again
5
: - Matchesm1
and is skipped as it is not distinct.f. Seventh element,
6
: - Greater thanm1
, som1
gets pushed tom2
,m2
gets pushed tom3
, andm1
becomes6
. Final order ism1 = 6
,m2 = 5
,m3 = 4
. -
After iterating through all elements, we see that
m3
is4
, which is not-inf
, indicating that we found enough distinct numbers. Therefore, our answer ism3
, which is4
.
In summary, for the list [5, 2, 2, 4, 1, 5, 6]
, the algorithm correctly identifies 4
as the third highest distinct number.
Solution Implementation
1from math import inf
2
3class Solution:
4 def thirdMax(self, nums):
5 # Initialize three variables to keep track of the max, second max,
6 # and third max values, initialized as negative infinity
7 max_value = second_max_value = third_max_value = -inf
8
9 for num in nums:
10 # Skip the number if it's equal to any of the three tracked values
11 if num in [max_value, second_max_value, third_max_value]:
12 continue
13
14 # If the number is greater than the current max_value, shift the
15 # values and set this number as the new max_value.
16 if num > max_value:
17 third_max_value, second_max_value, max_value = second_max_value, max_value, num
18
19 # Else if the number is greater than the current second_max_value,
20 # shift the second and third max values and set this number as the new second_max_value.
21 elif num > second_max_value:
22 third_max_value, second_max_value = second_max_value, num
23
24 # Else if the number is greater than the current third_max_value, set this
25 # number as the new third_max_value.
26 elif num > third_max_value:
27 third_max_value = num
28
29 # Return third_max_value if it's not negative infinity; otherwise, return max_value.
30 return third_max_value if third_max_value != -inf else max_value
31
1class Solution {
2 public int thirdMax(int[] nums) {
3 // Initialize three variables to hold the first, second, and third maximum values
4 // We use Long.MIN_VALUE to account for the possibility of all elements being negative
5 // or to flag unassigned state since the problem's constraints allow for ints only.
6 long firstMax = Long.MIN_VALUE;
7 long secondMax = Long.MIN_VALUE;
8 long thirdMax = Long.MIN_VALUE;
9
10 // Loop through all the numbers in the array
11 for (int num : nums) {
12 // Continue if the number is already identified as one of the maxima
13 if (num == firstMax || num == secondMax || num == thirdMax) {
14 continue;
15 }
16
17 // Update the maxima if the current number is greater than the first maximum
18 if (num > firstMax) {
19 thirdMax = secondMax; // the old secondMax becomes the new thirdMax
20 secondMax = firstMax; // the old firstMax becomes the new secondMax
21 firstMax = num; // assign the current number to firstMax
22 }
23 // Update the second and third maxima if the current number fits in between
24 else if (num > secondMax) {
25 thirdMax = secondMax; // the old secondMax becomes the new thirdMax
26 secondMax = num; // assign the current number to secondMax
27 }
28 // Update the third maximum if the current number is greater than thirdMax
29 else if (num > thirdMax) {
30 thirdMax = num; // assign the current number to thirdMax
31 }
32 }
33
34 // Return the third max if it's different from the initial value; otherwise, return the first max
35 return (int) (thirdMax != Long.MIN_VALUE ? thirdMax : firstMax);
36 }
37}
38
1class Solution {
2public:
3 int thirdMax(vector<int>& nums) {
4 // Initialize the top three maximum values with the smallest possible long integers.
5 long firstMax = LONG_MIN, secondMax = LONG_MIN, thirdMax = LONG_MIN;
6
7 // Loop through all numbers in the vector.
8 for (int num : nums) {
9 // Skip the iteration if the current number matches any of the top three maxima.
10 if (num == firstMax || num == secondMax || num == thirdMax) continue;
11
12 // If the current number is greater than the first maximum,
13 // shift the top maxima down and update the first maximum.
14 if (num > firstMax) {
15 thirdMax = secondMax;
16 secondMax = firstMax;
17 firstMax = num;
18 // Else if the current number is greater than the second maximum,
19 // shift the second and third maxima down and update the second maximum.
20 } else if (num > secondMax) {
21 thirdMax = secondMax;
22 secondMax = num;
23 // Else if the current number is greater than the third maximum,
24 // update the third maximum.
25 } else if (num > thirdMax) {
26 thirdMax = num;
27 }
28 }
29 // Return the third maximum if it's not LONG_MIN
30 // (which would mean there are at least three distinct numbers).
31 // Otherwise, return the first maximum (the overall maximum number).
32 return (int) (thirdMax != LONG_MIN ? thirdMax : firstMax);
33 }
34};
35
1function thirdMax(nums: number[]): number {
2 // Initialize the top three maximum values with the smallest possible number in JavaScript.
3 let firstMax: number = Number.MIN_SAFE_INTEGER;
4 let secondMax: number = Number.MIN_SAFE_INTEGER;
5 let thirdMax: number = Number.MIN_SAFE_INTEGER;
6
7 // Loop through all numbers in the array.
8 for (let num of nums) {
9 // Skip the iteration if the current number matches any of the top three maxima.
10 if (num === firstMax || num === secondMax || num === thirdMax) continue;
11
12 // If the current number is greater than the first maximum,
13 // shift the top maxima values down and update the first maximum.
14 if (num > firstMax) {
15 thirdMax = secondMax;
16 secondMax = firstMax;
17 firstMax = num;
18 // Else if the current number is greater than the second maximum,
19 // shift the second and third maxima values down and update the second maximum.
20 } else if (num > secondMax) {
21 thirdMax = secondMax;
22 secondMax = num;
23 // Else if the current number is greater than the third maximum,
24 // update the third maximum.
25 } else if (num > thirdMax) {
26 thirdMax = num;
27 }
28 }
29 // Return the third maximum if it's greater than the smallest possible number
30 // (which would mean there are at least three distinct numbers).
31 // Otherwise, return the first maximum (the overall maximum number).
32 return thirdMax > Number.MIN_SAFE_INTEGER ? thirdMax : firstMax;
33}
34
Time and Space Complexity
Time Complexity
The provided code only uses a single for-loop over the length of nums
, and within the for-loop, it performs constant-time checks and assignments. The operations inside the loop include checking if a number is already one of the maxima (m1
, m2
, m3
), and updating these variables accordingly. These operations are O(1) since they take a constant amount of time regardless of the input size. Therefore, the time complexity of the code is directly proportional to the number of elements in the nums
list, which is O(n)
.
Space Complexity
The extra space used by the algorithm is constant: three variables m1
, m2
, m3
to keep track of the three maximum values, and a few temporary variables during value swapping. No additional space that scales with input size is used, so the space complexity is O(1)
.
Learn more about how to find time and space complexity quickly using problem constraints.
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