2998. Minimum Number of Operations to Make X and Y Equal
Problem Description
You are presented with a task of converting one positive integer (x
) into another (y
) by performing a series of operations. During each operation, you are allowed to:
- Divide
x
by11
ifx
is divisible by11
. - Divide
x
by5
ifx
is divisible by5
. - Decrease the value of
x
by1
. - Increase the value of
x
by1
.
The goal is to determine the minimum number of these operations required to make the two integers equal.
Flowchart Walkthrough
Let's process the problem of Leetcode 2998. Minimum Number of Operations to Make X and Y Equal using the Flowchart. Here's the flow-by-flow analysis:
Is it a graph?
- Yes: The operations that transform X into Y can be thought of as nodes in a graph where each node is a unique state of X or Y, and edges represent transformations.
Is it a tree?
- No: The state transitions do not inherently form a hierarchical tree structure as they could loop or merge (intersecting at common values after transformations).
Is the problem related to directed acyclic graphs (DAGs)?
- No: This problem focuses on performing specific operations to align values, not sorting or managing dependencies like in a DAG.
Is the problem related to shortest paths?
- Yes: We are essentially looking to find the minimal number of transformation operations (path) needed to reach Y from X.
Is the graph weighted?
- No: Each operation can be thought of as having the same 'weight' or cost which is 1—meaning one operation is needed to move from one state to another.
Conclusion: Since we're dealing with an unweighted graph problem focusing on finding a minimum path, the flowchart guides us toward using BFS (Breadth-First Search) to systematically explore all transformations until we find the shortest path from X to Y. This approach ensures optimal operation counts by exploring all possible states level-by-level.
Intuition
When tackling this problem, there is an element of choice at each step, suggesting a recursive solution or dynamic programming approach. The key intuition lies in understanding that larger adjustments can be made when x
is significantly greater than y
. This involves prioritizing dividing by 11 or 5 before resorting to incrementing or decrementing, which are less "efficient" operations since they only change x
by 1.
Recursive Depth-First Search (DFS)
Since we can perform multiple types of operations, we can use recursive depth-first search (DFS) to explore these possibilities. At each step, there are four options, and this is where the problem becomes complex as we need to decide the best option to minimize the number of operations. To optimize the process, we can do the following:
-
If
x
is greater than or equal toy
, the simplest approach is to decrementx
until it equalsy
, with the number of operations beingx - y
. -
If
x
is less thany
, we need to consider:- Dividing
x
by11
if it's a multiple of11
, or gettingx
as close to a multiple of11
as we can, then dividing. - Dividing
x
by5
if it's a multiple of5
, or gettingx
as close to a multiple of5
as we can, then dividing. - Decrementing
x
by1
. - Incrementing
x
by1
.
- Dividing
Caching Intermediate Results
To avoid recalculating the minimum operations for the same values of x
in the recursive process, we can cache the results. This caching mechanism is employed by decorating the recursive function with Python's @cache
decorator, which automatically stores the return values of the function for each unique input.
Recursive Approach
The provided solution function defines a recursive DFS helper function. The recursion acts on the value of x
and computes the minimum operations based on the four available operations. At each recursive call, it calculates the optimal solution through DFS and comparison of the different operation costs, keeping track of the minimum operations needed. The process requires checking for the remainder of x
after division by 5
and 11
to approach the target y
closely, efficiently navigating the choices.
Overall, the recursive DFS with caching is a top-down approach to solve the problem step by step, taking the optimal decision at each state to minimize the total number of operations.
Learn more about Breadth-First Search, Memoization and Dynamic Programming patterns.
Solution Approach
The reference solution provided earlier implements a recursive depth-first search (DFS) approach. Its key elements are:
-
We define a recursive helper function
dfs
which aims to find the minimum number of operations to convertx
toy
. -
The
dfs
function is decorated with the@cache
decorator from Python'sfunctools
module to memoize or cache the results of function calls. This means that results of previous computations are stored, and if the function is called again with the same arguments, it returns the cached result instead of recalculating. -
Inside the
dfs
function, the base case handles the scenario wherey
is greater than or equal tox
. In such a case, since incrementing or decrementing is the only choice, the number of operations is simply the differencey - x
. -
When
x
is greater thany
, the function explores four possible operations:- Directly decrement
x
by 1 until it equalsy
, which costsx - y
operations. - If
x
is divisible by 5, divide it by 5. If it's not, first makex
divisible by 5 (adjusting by the remainder when dividing by 5) and then divide. This takesx % 5 + 1 + dfs(x // 5)
operations, where%
is the modulus operator and//
is the integer division operator. - If
x
is divisible by 11 in a similar fashion, divide it by 11. Otherwise, adjustx
to be divisible by 11 and then divide. It involvesx % 11 + 1 + dfs(x // 11)
operations. - Considering the edge case, sometimes it's quicker to first increment
x
so that it is divisible by 5 or 11 before dividing. This is handled by the two lines:5 - x % 5 + 1 + dfs(x // 5 + 1)
and11 - x % 11 + 1 + dfs(x // 11 + 1)
.
- Directly decrement
-
The recursive calls are made, and the minimum number of operations calculated from each recursion is determined using the
min
function. -
The optimal minimum number of operations from the current state is returned from each recursive call until we get back to the original call from the
minimumOperationsToMakeEqual
method.
In terms of algorithm design, the solution leverages recursion with memoization—an optimization technique to avoid redundant computations and improve performance, widely applied in dynamic programming. The cache allows the algorithms to keep track of and reuse previous results, minimizing the search space and eliminating the need to recompute the cost of operations for the same values of x
.
The data structure used implicitly is the call stack through recursion and the dictionary used by the @cache
decorator to store computation results.
This approach dynamically computes the solutions to sub-problems and efficiently finds the minimum number of operations required to make x
and y
equal.
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Start EvaluatorExample Walkthrough
Let's walk through the recursive depth-first search (DFS) approach with an example where x = 50
and y = 8
.
- The goal is to minimize the number of operations to transform
x
to equaly
. - We call the
dfs
function withx = 50
.
Since x
is greater than y
, we have four paths to explore. Let's look at these paths:
-
Path 1: Decrementing
x
by1
untilx
equalsy
. This would take50 - 8 = 42
operations. -
Path 2: Since
x
is divisible by5
, we could dividex
by5
. However, 50 divided by5
is10
, which is still greater thany
. So, we would perform one division and then recurse:1 + dfs(10)
: One division operation plus whatever the recursive call returns for10
.
-
Path 3:
x
is not divisible by11
but we want to divide by11
. So, we could adjustx
to be closer to a multiple of11
and then divide:- Since
50 % 11
is6
, we need to decrementx
by6
first to make it exactly divisible by11
, then dividex
by11
, which leaves us with50 / 11 = 4
, leavingx
at4
. - The recursive call would then be
6 + 1 + dfs(4)
: Six decrement operations, one division operation, plus whatever the recursive call returns for4
.
- Since
-
Path 4: In some cases, it would be better to first increment
x
to make it divisible by5
or11
. Since 50 is already divisible by5
, this doesn't apply, but for11
, we could consider incrementingx
by5
to make it55
, then dividing by11
to get5
. But in this example, sincex = 50
is already divisible by5
, this doesn't offer any benefit, so we wouldn't consider this option.
Now, we need to recursively invoke dfs
for the cases where x
is greater than y
. Let's detail the recursion for dfs(10)
from Path 2:
- We repeat the process for
x = 10
andy = 8
. - Optimal sub-path: As
10
is greater than8
, we can decrement twice to reach8
. So,dfs(10)
would return10 - 8 = 2
.
Substituting back into Path 2, we get 1 + 2 = 3
operations to go from 50
to 8
via dividing by 5
and decrementing twice.
After evaluating these options and paths, we can determine the minimum number of steps. In our case, the minimum operations can be found in Path 2 with 3
steps: one division by 5
and two decrements.
The cached results prevent redundant computations. If another call to dfs(10)
occurs, the previously stored result (2
) is used instead of recalculating.
This example demonstrates how the DFS with caching efficiently computes the minimum number of steps. It explores different operations and leverages past results to avoid unnecessary work, thereby finding the optimal solution.
Solution Implementation
1from functools import lru_cache # Import lru_cache for memoization
2
3class Solution:
4 def minimumOperationsToMakeEqual(self, x: int, y: int) -> int:
5 # This function uses dynamic programming to calculate the minimum number
6 # of operations to make x equal to y using allowed operations.
7 @lru_cache(maxsize=None) # Memoize results of the dfs function
8 def dfs(current_value: int) -> int:
9 # Base case: if the current value is greater than or equal to y,
10 # the operation needed is the difference between them.
11 if current_value >= y:
12 return current_value - y
13
14 # Initialize the minimum operations to the difference (subtracting operations).
15 minimum_operations = current_value - y
16
17 # Operation: multiply by 5 and add 1 to the answer, then call dfs recursively.
18 operations_to_five_multiple = current_value % 5
19 minimum_operations = min(minimum_operations, operations_to_five_multiple + 1 + dfs(current_value // 5))
20
21 # Operation: get to the next multiple of 5, add 1 to the answer, and call dfs recursively.
22 operations_to_next_five_multiple = 5 - current_value % 5
23 minimum_operations = min(minimum_operations, operations_to_next_five_multiple + 1 + dfs(current_value // 5 + 1))
24
25 # Operation: multiply by 11 and add 1 to the answer, then call dfs recursively.
26 operations_to_eleven_multiple = current_value % 11
27 minimum_operations = min(minimum_operations, operations_to_eleven_multiple + 1 + dfs(current_value // 11))
28
29 # Operation: get to the next multiple of 11, add 1 to the answer, and call dfs recursively.
30 operations_to_next_eleven_multiple = 11 - current_value % 11
31 minimum_operations = min(minimum_operations, operations_to_next_eleven_multiple + 1 + dfs(current_value // 11 + 1))
32
33 return minimum_operations
34
35 # Start the recursive process from the initial value x.
36 return dfs(x)
37
1import java.util.Map;
2import java.util.HashMap;
3
4public class Solution {
5 // Store the computed values to avoid redundant calculations
6 private Map<Integer, Integer> computedValues = new HashMap<>();
7
8 // This variable holds the target value 'y' that we want 'x' to equal after operations
9 private int targetValue;
10
11 // Calculate the minimum number of operations required to make 'x' equal to 'y'
12 public int minimumOperationsToMakeEqual(int x, int y) {
13 this.targetValue = y;
14 return findMinimumOperations(x);
15 }
16
17 // A recursive method to compute the minimum number of operations using dynamic programming (memoization)
18 private int findMinimumOperations(int currentValue) {
19 // Base case: if currentValue is already greater than or equal to targetValue, return the difference
20 if (targetValue >= currentValue) {
21 return targetValue - currentValue;
22 }
23
24 // Check if the result has been computed before to avoid redundant calculations
25 if (computedValues.containsKey(currentValue)) {
26 return computedValues.get(currentValue);
27 }
28
29 // Operations involve increments or decrements by a fixed step, or division by 5 or 11
30 // Initialize 'ans' to some maximum value: typically, the difference between current and target value
31 int ans = currentValue - targetValue;
32
33 // Operation set when 'currentValue' is divisible by 5
34 int addStepsWhenDivBy5 = currentValue % 5 + 1;
35 int operationsWhenDivBy5 = addStepsWhenDivBy5 + findMinimumOperations(currentValue / 5);
36
37 // Operation set when 'currentValue' is not divisible by 5 (Move toward divisibility)
38 int addStepsToNextDivBy5 = 5 - currentValue % 5 + 1;
39 int operationsToNextDivBy5 = addStepsToNextDivBy5 + findMinimumOperations(currentValue / 5 + 1);
40
41 // Operation set when 'currentValue' is divisible by 11
42 int addStepsWhenDivBy11 = currentValue % 11 + 1;
43 int operationsWhenDivBy11 = addStepsWhenDivBy11 + findMinimumOperations(currentValue / 11);
44
45 // Operation set when 'currentValue' is not divisible by 11 (Move toward divisibility)
46 int addStepsToNextDivBy11 = 11 - currentValue % 11 + 1;
47 int operationsToNextDivBy11 = addStepsToNextDivBy11 + findMinimumOperations(currentValue / 11 + 1);
48
49 // Finding the minimum of all operation sets
50 ans = Math.min(ans, Math.min(operationsWhenDivBy5, Math.min(operationsToNextDivBy5,
51 Math.min(operationsWhenDivBy11, operationsToNextDivBy11))));
52
53 // Store the result in the map to avoid redundant future calculations
54 computedValues.put(currentValue, ans);
55
56 return ans;
57 }
58}
59
1#include <unordered_map>
2#include <functional>
3#include <algorithm>
4
5class Solution {
6public:
7 int minimumOperationsToMakeEqual(int x, int y) {
8 // Using an unordered_map to memoize the results of subproblems.
9 std::unordered_map<int, int> memo;
10
11 // Defining the recursive function using std::function.
12 std::function<int(int)> dfs = [&](int current) {
13 // Base case: if current value is greater or equal to y,
14 // return the difference (the number of operations needed to decrease x to y).
15 if (current <= y) {
16 return y - current;
17 }
18
19 // If the result for this value of current has already been computed,
20 // return it to avoid redundant calculations.
21 if (memo.count(current)) {
22 return memo[current];
23 }
24
25 // Recursive case: Calculate the operations needed if we do a divide by 5 or 11
26 // and potentially add or subtract to get to a multiple of 5 or 11, respectively.
27 int a = current % 5 + 1 + dfs(current / 5);
28 int b = 5 - current % 5 + 1 + dfs(current / 5 + 1);
29 int c = current % 11 + 1 + dfs(current / 11);
30 int d = 11 - current % 11 + 1 + dfs(current / 11 + 1);
31
32 // The result for current is the minimum of subtracting y from current,
33 // or the computed values from the four scenarios (a, b, c, and d).
34 // We save the minimum result in our memoization map to use later.
35 memo[current] = std::min({current - y, a, b, c, d});
36
37 // Return the computed minimum for the current value.
38 return memo[current];
39 };
40
41 // Start the depth-first search from value x.
42 return dfs(x);
43 }
44};
45
1// Define a type for the frequency map to hold calculated operations for certain values.
2type FrequencyMap = Map<number, number>;
3
4// Global frequency map to store the number of operations needed for given values.
5const frequencyMap: FrequencyMap = new Map();
6
7// The depth-first search function to find the minimum number of operations
8// to make x equal to y.
9function dfs(x: number): number {
10 // Base case: if x is already greater or equal to y, return the difference.
11 if (y >= x) {
12 return y - x;
13 }
14 // If the number of operations for x is already calculated, return it.
15 if (frequencyMap.has(x)) {
16 return frequencyMap.get(x)!;
17 }
18
19 // Calculate the number of operations if we decrease x by x modulo 5.
20 const decreaseByMod5 = (x % 5) + 1 + dfs((x / 5) | 0);
21 // Calculate the number of operations if we increase x to be divisible by 5.
22 const increaseToNextMultipleOf5 = 5 - (x % 5) + 1 + dfs(((x / 5) | 0) + 1);
23 // Calculate the number of operations if we decrease x by x modulo 11.
24 const decreaseByMod11 = (x % 11) + 1 + dfs((x / 11) | 0);
25 // Calculate the number of operations if we increase x to be divisible by 11.
26 const increaseToNextMultipleOf11 = 11 - (x % 11) + 1 + dfs(((x / 11) | 0) + 1);
27
28 // Determine the minimum number of operations from all possibilities.
29 const minOperations = Math.min(
30 x - y,
31 decreaseByMod5,
32 increaseToNextMultipleOf5,
33 decreaseByMod11,
34 increaseToNextMultipleOf11
35 );
36
37 // Store the computed number of operations in the map for memoization.
38 frequencyMap.set(x, minOperations);
39 return minOperations;
40}
41
42// The main function to initiate the process of making x equal to y
43// using the minimum number of operations.
44function minimumOperationsToMakeEqual(x: number, y: number): number {
45 return dfs(x);
46}
47
Time and Space Complexity
The given Python code defines a function minimumOperationsToMakeEqual
that calculates the minimum number of operations needed to make x
equal to y
. The dfs
(depth-first search) function is a helper function that uses memoization via the @cache
decorator to store previously computed results and avoid redundant computations.
Time Complexity
The time complexity of the code is influenced by:
- The number of different states that need to be computed, which correspond to different values of
x
during the recursion. - The number of recursive calls made at each step.
Here, the number of unique states can be determined by the range of possible values from x
to y
and the different operations applied to x
. The operations include:
- Subtracting
x
byy
(base case). - Dividing by 5 and adjusting (two cases: adding a step if
x
is not a multiple of 5 and adjusting the result accordingly). - Dividing by 11 and adjusting (similar to dividing by 5, with two cases).
Despite having multiple recursive calls per function call, the use of memoization ensures that each unique state of x
is calculated only once. Given that x
can only be halved a logarithmic number of times before reaching y
, the time complexity would be O(log(x - y))
for each possible division operation (dividing by 5 or 11). Additionally, the constant operations within each recursive call don't add to the asymptotic complexity.
Hence, the overall time complexity of the function is O(log(x - y))
.
Space Complexity
The space complexity of the code involves the following considerations:
- The space used by the memoization cache.
- The space used by the recursion call stack.
The memoization cache will store results for each unique value of x
encountered during the recursive calls. Since x
can decrease by a factor of 5 or 11 at each step or by one of the smaller steps (from the %
operations), the space used by the memoization cache would also be related to the logarithm of the difference x - y
.
The call stack depth is also bound by the number of recursive calls before x
reaches y
, again related to the logarithm of the difference between x
and y
.
Therefore, the space complexity of the function is O(log(x - y))
accounting for both the memoization cache and the call stack depth.
Learn more about how to find time and space complexity quickly using problem constraints.
Which of the following problems can be solved with backtracking (select multiple)
Recommended Readings
https algomonster s3 us east 2 amazonaws com cover_photos bfs svg Breadth First Search on Trees Hopefully by this time you've drunk enough DFS Kool Aid to understand its immense power and seen enough visualization to create a call stack in your mind Now let me introduce the companion spell
Memoization Prereq Backtracking problems backtracking Memoization is a fancy word for a simple concept so is the case for a lot of things we learn in school It means saving the previous function call result in a dictionary and reading from it when we do the exact same call again
What is Dynamic Programming Prerequisite DFS problems dfs_intro Backtracking problems backtracking Memoization problems memoization_intro Pruning problems backtracking_pruning Dynamic programming is an algorithmic optimization technique that breaks down a complicated problem into smaller overlapping sub problems in a recursive manner and uses solutions to the sub problems to construct a solution
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