1071. Greatest Common Divisor of Strings
Problem Description
The provided problem involves finding the largest string x
that can divide two input strings str1
and str2
. One string divides another if it can be repeated some number of times to obtain the other string. For example, if we have str1 = "abcabc"
and str2 = "abc"
, then str2
divides str1
because we can concatenate str2
with itself twice to get str1
. In other words, str1
is the result of appending str2
to itself multiple times. The challenge is to identify the largest common string that can divide both str1
and str2
in a similar fashion.
To illustrate further, if str1
is "ababab" and str2
is "abab", the string "ab" is the answer since it is the largest string that divides both str1
and str2
.
Intuition
The underlying concept used in the provided solution is based on the mathematical idea of finding the greatest common divisor (GCD), but rather than numbers, we're dealing with strings. The key insight is that if there exists such a common string x
that divides both str1
and str2
, then the concatenation of str1
with str2
(str1 + str2
) should be the same as the concatenation of str2
with str1
(str2 + str1
). If this condition doesn't hold, it implies there is no such common string and the answer is an empty string.
Assuming the condition is true, we can find the length of the largest string x
using the greatest common divisor of the lengths of str1
and str2
. This is because the repeating pattern of string x
must be a factor of both string lengths in order for it to divide both strings completely. Therefore, we find the GCD of the lengths of str1
and str2
and then return the substring of str1
up to that length. This substring is the largest common divider x
.
Learn more about Math patterns.
Solution Approach
The solution provided takes advantage of Python's built-in gcd
function from the [math](/problems/math-basics)
library to calculate the greatest common divisor of the lengths of the two input strings str1
and str2
. This is crucial for the solution, as the gcd
represents the length of the largest string that can divide both strings, if such a string exists.
Here is how the solution unfolds:
-
Check for Compatibility: The first step in the provided solution checks whether the strings are compatible to have a common divisor by concatenating
str1
withstr2
and comparing it tostr2
concatenated withstr1
. This is facilitated by the operationif str1 + str2 != str2 + str1
, which ensures that the pattern of characters in both strings is compatible for them to have a common divisor string. If the check fails, the two strings cannot have a common divisor and the function immediately returns an empty string''
. -
Find Length of the Common Divisor: If the strings pass the compatibility check, the next step is to determine the length of the largest common divisor string. This is where we use the
gcd
function, by callingn = gcd(len(str1), len(str2))
. Thegcd
function takes the lengths ofstr1
andstr2
and returns the greatest common divisor of these two numbers. -
Extract the Common Divisor String: With the length
n
obtained from thegcd
function, the final step is to extract the common divisor string fromstr1
. This is accomplished by the expressionreturn str1[:n]
. The[:n]
slice operation onstr1
returns the substring ofstr1
from the beginning up to then-th
character (exclusive), which is the required largest string that divides bothstr1
andstr2
.
To summarize, the algorithm consists of concatenation for compatibility checking and the greatest common divisor calculation, both of which are simple, efficient operations. The lack of any complex data structures and the use of a mathematical pattern of common division make this solution both elegant and effective. It leverages the fact that if a common divisor string exists, the repeating pattern must align with the gcd of the string lengths.
Ready to land your dream job?
Unlock your dream job with a 2-minute evaluator for a personalized learning plan!
Start EvaluatorExample Walkthrough
Let's use a small example to illustrate the solution approach. Suppose we have two strings str1 = "abab"
and str2 = "ab"
. We need to find the largest string x
that can divide both str1
and str2
.
-
Check for Compatibility: We first check if concatenating
str1
withstr2
is equal tostr2
concatenated withstr1
.str1 + str2 = "abab" + "ab" = "ababab"
str2 + str1 = "ab" + "abab" = "ababab"
Since
str1 + str2
is equal tostr2 + str1
, the two strings are compatible, and therefore, it's possible they have a common divisor string. -
Find Length of the Common Divisor: Next, we find the greatest common divisor of the lengths of
str1
(4) andstr2
(2).gcd(4, 2) = 2
The
gcd
tells us that the length of the largest string that possibly divides bothstr1
andstr2
is 2. -
Extract the Common Divisor String: Since the
gcd
is 2, we take the first 2 characters fromstr1
to form our largest divisor stringx
.str1[:2] = "ab"
So, "ab" is the string we expect to divide both
str1
andstr2
. To verify, we can see that:str1
divided by "ab" is"abab" / "ab" = "ab"
, which is the repetition of "ab" twice.str2
divided by "ab" is"ab" / "ab" = ""
, which is the repetition of "ab" once.
The largest string that can divide both str1
and str2
is "ab", which matches our result from the solution approach. The solution is elegant and efficient, leveraging simple concatenation and the mathematical concept of greatest common divisor to determine the existence and length of a common divisor string.
Solution Implementation
1from math import gcd
2
3class Solution:
4 def gcdOfStrings(self, str1: str, str2: str) -> str:
5 # Check if the concatenation of the two strings in different order results in the same string.
6 # This is required as the strings should be made of the same substrings for them to have a common divisor.
7 if str1 + str2 != str2 + str1:
8 # If they don't form the same string when concatenated in different orders,
9 # there is no common divisor string and hence return an empty string.
10 return ''
11
12 # Find the gcd of the lengths of the two strings.
13 # The gcd of the lengths will give us the maximum length the common divisor string can have.
14 length_gcd = gcd(len(str1), len(str2))
15
16 # Return the substring from 0 to length_gcd from the first string,
17 # which is the greatest common divisor string.
18 return str1[:length_gcd]
19
1class Solution {
2 // Function to find the greatest common divisor of lengths of two strings.
3 // This GCD can be used to find the longest substring that can construct
4 // the given strings by repeated concatenation.
5 public String gcdOfStrings(String str1, String str2) {
6 // Check if the two strings can be constructed from a common substring
7 // Only if str1+str2 equals str2+str1, they have a common divisor string
8 if (!(str1 + str2).equals(str2 + str1)) {
9 return ""; // If not, return an empty string as there is no common divisor
10 }
11 // Calculate the GCD of lengths of the two strings
12 int len = gcd(str1.length(), str2.length());
13 // The substring from the beginning of str1 with length 'len' is the gcd string
14 return str1.substring(0, len);
15 }
16
17 // Helper function to calculate the greatest common divisor (GCD) of two integers
18 // It uses the Euclidean algorithm to find the GCD
19 private int gcd(int a, int b) {
20 // Base case: if b is 0, then a is the GCD (as GCD(a, 0) = a)
21 // Recursive step: GCD(a, b) = GCD(b, a mod b)
22 return b == 0 ? a : gcd(b, a % b);
23 }
24}
25
1#include <algorithm> // include algorithm header for std::gcd
2
3class Solution {
4public:
5 // Function to find the greatest common divisor of strings str1 and str2
6 string gcdOfStrings(string str1, string str2) {
7 // check if concatenating the strings in both orders gives the same result
8 // this is required because two strings can only be multiples of each other
9 // if this condition is true
10 if (str1 + str2 != str2 + str1) {
11 return ""; // if they are not equivalent, return an empty string
12 }
13
14 // calculate the greatest common divisor (GCD) of the sizes of the two strings
15 // std::gcd is available in C++17 and later. For C++14 and earlier, use a custom gcd function
16 int gcdValue = std::gcd(str1.size(), str2.size());
17
18 // return the common divisor string which is the substring from start of str1 to its GCD length
19 return str1.substr(0, gcdValue);
20 }
21};
22
1// Function to calculate the greatest common divisor (GCD) of two numbers
2// Uses Euclidean algorithm
3function gcd(a: number, b: number): number {
4 while (b !== 0) {
5 let t = b;
6 b = a % b;
7 a = t;
8 }
9 return a;
10}
11
12// Function to find the greatest common divisor of strings str1 and str2
13function gcdOfStrings(str1: string, str2: string): string {
14 // Check if concatenating the strings in both orders gives the same result
15 // This is required because two strings can only be multiples of each other
16 // if this condition is true
17 if (str1 + str2 !== str2 + str1) {
18 return ""; // If they are not equivalent, return an empty string
19 }
20
21 // Calculate the greatest common divisor (GCD) of the lengths of the two strings
22 const gcdValue = gcd(str1.length, str2.length);
23
24 // Return the common divisor string which is the substring from start of str1 to its GCD length
25 return str1.substring(0, gcdValue);
26}
27
Time and Space Complexity
The code contains the gcdOfStrings
method that finds the greatest common divisor (GCD) of lengths of two strings str1
and str2
to determine the largest string that can be repeatedly used to construct str1
and str2
.
Time Complexity:
The time complexity of this function mainly depends on two operations: the string concatenation operation (str1 + str2
and str2 + str1
) and the greatest common divisor computation (gcd(len(str1), len(str2))
).
-
String Concatenation: If
str1
is of lengthn
andstr2
of lengthm
, the concatenation will takeO(n + m)
time as each character from both strings need to be combined once. -
Checking String Equality: Comparing the concatenated strings takes
O(n + m)
time. If the strings differ, the method returns early. -
Greatest Common Divisor: The
gcd
function typically employs Euclid's algorithm, which has a time complexity ofO(log(min(n, m)))
wheren
andm
are the lengths of the strings.
Therefore, the overall time complexity combines these operations resulting in O(n + m + log(min(n, m)))
. However, the dominating factor for large values of n
and m
will tend to be the concatenation and comparison, so we can approximate the time complexity as O(n + m)
.
Space Complexity:
The space complexity of the gcdOfStrings
function can be analyzed as follows:
-
Temporary Strings: The creation of concatenated strings
str1 + str2
andstr2 + str1
requires additional space ofO(n + m)
. -
GCD Computation: The
gcd
function itself may use constant space,O(1)
, if the Euclidean algorithm is implemented in an iterative manner.
As such, no additional space that grows with the input size is required except for the string concatenation. Hence, the space complexity is O(n + m)
.
Learn more about how to find time and space complexity quickly using problem constraints.
What's the relationship between a tree and a graph?
Recommended Readings
Math for Technical Interviews How much math do I need to know for technical interviews The short answer is about high school level math Computer science is often associated with math and some universities even place their computer science department under the math faculty However the reality is that you
LeetCode Patterns Your Personal Dijkstra's Algorithm to Landing Your Dream Job The goal of AlgoMonster is to help you get a job in the shortest amount of time possible in a data driven way We compiled datasets of tech interview problems and broke them down by patterns This way we
Recursion Recursion is one of the most important concepts in computer science Simply speaking recursion is the process of a function calling itself Using a real life analogy imagine a scenario where you invite your friends to lunch https algomonster s3 us east 2 amazonaws com recursion jpg You first
Want a Structured Path to Master System Design Too? Don’t Miss This!