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📜  矩阵中对到达目标的最小可能修改

📅  最后修改于: 2021-06-26 11:06:01             🧑  作者: Mango

给定大小为N x M的矩阵,该矩阵由整数1、2、34组成
每个值代表该单元格可能发生的移动:

1 -> move left
2 -> move right
3 -> move up
4 -> move down.

任务是找到矩阵中所需的最小可能变化,以使存在从(0,0)(N-1,M-1)的路径。
例子:

先决条件:
1. Djikstra的算法
2.0-1 BFS

方法1

  • 让我们将2D矩阵的每个像元视为加权图的一个节点,每个节点最多可以有四个连接的节点(可能是四个方向)。每个边的权重为:
    • 如果节点U的运动方向指向V,则weight(U,V)= 0,否则
    • 重量(U,V)= 1
  • 现在,这基本上简化为可以使用Djikstra算法计算的最短路径问题

下面是上述方法的实现:

C++
// CPP program to find minimum possible
// changes required in the matrix
#include 
using namespace std;
 
// Function to find next possible node
int nextNode(int x, int y, int dir, int N, int M)
{
    if (dir == 1)
        y--;
    else if (dir == 2)
        y++;
    else if (dir == 3)
        x--;
    else
        x++;
 
    // If node is out of matrix
    if (!(x >= 0 && x < N && y >= 0 && y < M))
        return -1;
    else
        return (x * N + y);
}
 
// Prints shortest paths from src
// to all other vertices
int dijkstra(vector >* adj,
             int src, int dest, int N, int M)
{
    // Create a set to store vertices
    // that are bein preprocessed
    set > setds;
 
    // Create a vector for distances
    // and initialize all distances
    // as infinite (large value)
    vector dist(N * M, INT_MAX);
 
    // Insert source itself in Set
    // and initialize its distance as 0
    setds.insert(make_pair(0, src));
    dist[src] = 0;
 
    /* Looping till all shortest
        distance are finalized
        then setds will become empty */
    while (!setds.empty()) {
        // The first vertex in Set
        // is the minimum distance
        // vertex, extract it from set.
        pair tmp = *(setds.begin());
        setds.erase(setds.begin());
 
        // vertex label is stored in second
        // of pair (it has to be done this
        // way to keep the vertices sorted
        // distance (distance must be
        // first item in pair)
        int u = tmp.second;
 
        // 'i' is used to get all adjacent
        // vertices of a vertex
        vector >::iterator i;
        for (i = adj[u].begin();
             i != adj[u].end(); ++i) {
            // Get vertex label and weight
            // of current adjacent of u.
            int v = (*i).first;
            int weight = (*i).second;
 
            // If there is shorter path from u to v
            if (dist[v] > dist[u] + weight) {
                // If distance of v is not
                // INF then it must be
                // in our set, so removing it
                // and inserting again with
                // updated less distance.
                // Note : We extract only
                // those vertices from Set
                // for which distance is
                // finalized. So for them,
                // we would never reach here
                if (dist[v] != INT_MAX)
                    setds.erase(setds.find(
                        { dist[v], v }));
 
                // Updating distance of v
                dist[v] = dist[u] + weight;
                setds.insert(make_pair(dist[v], v));
            }
        }
    }
 
    // Return the distance
    return dist[dest];
}
 
// Function to find minimum possible
// changes required in the matrix
int MinModifications(vector >& mat)
{
    int N = mat.size(), M = mat[0].size();
 
    // Converting given matrix to a graph
    vector > adj[N * M];
 
    for (int i = 0; i < N; i++) {
        for (int j = 0; j < M; j++) {
            // Each cell is a node,
            // with label i*N + j
            for (int dir = 1; dir <= 4; dir++) {
                // Label of node if we
                // move in direction dir
                int nextNodeLabel
                    = nextNode(i, j, dir, N, M);
 
                // If invalid(out of matrix)
                if (nextNodeLabel == -1)
                    continue;
 
                // If direction is same as mat[i][j]
                if (dir == mat[i][j])
                    adj[i * N + j].push_back(
                        { nextNodeLabel, 0 });
                else
                    adj[i * N + j].push_back(
                        { nextNodeLabel, 1 });
            }
        }
    }
 
    // Applying djikstra's algorithm
    return dijkstra(adj, 0,
                    (N - 1) * N + M - 1, N, M);
}
 
// Driver code
int main()
{
    vector > mat = { { 2, 2, 1 },
                                 { 4, 2, 3 },
                                 { 4, 3, 2 } };
 
    // Function call
    cout << MinModifications(mat);
 
    return 0;
}


C++
// CPP program to find minimum
// possible changes required
// in the matrix
#include 
using namespace std;
 
// Function to find next possible node
int nextNode(int x, int y, int dir,
             int N, int M)
{
    if (dir == 1)
        y--;
    else if (dir == 2)
        y++;
    else if (dir == 3)
        x--;
    else
        x++;
 
    // If node is out of matrix
    if (!(x >= 0 && x < N && y >= 0 && y < M))
        return -1;
    else
        return (x * N + y);
}
 
// Prints shortest distance
// from given source to
// every other vertex
int zeroOneBFS(vector >* adj,
               int src, int dest, int N, int M)
{
    // Initialize distances
    // from given source
    int dist[N * M];
    for (int i = 0; i < N * M; i++)
        dist[i] = INT_MAX;
 
    // Double ended queue to do BFS.
    deque Q;
    dist[src] = 0;
    Q.push_back(src);
 
    while (!Q.empty()) {
        int v = Q.front();
        Q.pop_front();
 
        for (auto i : adj[v]) {
            // Checking for the optimal distance
            if (dist[i.first] > dist[v]
                                    + i.second) {
                dist[i.first] = dist[v]
                                + i.second;
 
                // Put 0 weight edges to front
                // and 1 weight edges to back
                // so that vertices are processed
                // in increasing order of weights.
                if (i.second == 0)
                    Q.push_front(i.first);
                else
                    Q.push_back(i.first);
            }
        }
    }
 
    // Shortest distance to
    // reach destination
    return dist[dest];
}
 
// Function to find minimum possible
// changes required in the matrix
int MinModifications(vector >& mat)
{
    int N = mat.size(), M = mat[0].size();
 
    // Converting given matrix to a graph
    vector > adj[N * M];
 
    for (int i = 0; i < N; i++) {
        for (int j = 0; j < M; j++) {
            // Each cell is a node
            // with label i*N + j
            for (int dir = 1; dir <= 4; dir++) {
                // Label of node if we
                // move in direction dir
                int nextNodeLabel = nextNode(i, j,
                                             dir, N, M);
 
                // If invalid(out of matrix)
                if (nextNodeLabel == -1)
                    continue;
 
                // If direction is same as mat[i][j]
                if (dir == mat[i][j])
                    adj[i * N + j].push_back(
                        { nextNodeLabel, 0 });
                else
                    adj[i * N + j].push_back(
                        { nextNodeLabel, 1 });
            }
        }
    }
 
    // Applying djikstra's algorithm
    return zeroOneBFS(adj, 0,
                      (N - 1) * N + M - 1, N, M);
}
 
// Driver code
int main()
{
    vector > mat = { { 2, 2, 1 },
                                 { 4, 2, 3 },
                                 { 4, 3, 2 } };
 
    // Function call
    cout << MinModifications(mat);
 
    return 0;
}


Python3
# Python program to find minimum
# possible changes required
# in the matrix
from collections import deque
 
# Function to find next possible node
def nextNode(x, y, dir, N, M):
    if (dir == 1):
        y -= 1
    elif (dir == 2):
        y += 1
    elif (dir == 3):
        x -= 1
    else:
        x += 1
 
    # If node is out of matrix
    if (not (x >= 0 and x < N and y >= 0 and y < M)):
        return -1
    else:
        return (x * N + y)
 
# Prints shortest distance
# from given source to
# every other vertex
def zeroOneBFS(adj, src, dest, N, M):
   
    # Initialize distances
    # from given source
    dist = [10**8] *(N * M)
 
    # Double ended queue to do BFS.
    Q = deque()
    dist[src] = 0
    Q.append(src)
 
    while (len(Q) > 0):
        v = Q.popleft()
 
        for i in adj[v]:
           
            # print(i)
            # Checking for the optimal distance
            if (dist[i[0]] > dist[v] + i[1]):
                dist[i[0]] = dist[v] + i[1]
                 
                # Put 0 weight edges to front
                # and 1 weight edges to back
                # so that vertices are processed
                # in increasing order of weights.
                if (i[1] == 0):
                    Q.appendleft(i[0])
                else:
                    Q.append(i[0])
 
    # Shortest distance to
    # reach destination
    return dist[dest]
 
# Function to find minimum possible
# changes required in the matrix
def MinModifications(mat):
    N, M = len(mat), len(mat[0])
 
    # Converting given matrix to a graph
    adj = [[] for i in range(N * M)]
 
    for i in range(N):
        for j in range(M):
           
            # Each cell is a node
            # with label i*N + j
            for dir in range(1, 5):
               
                # Label of node if we
                # move in direction dir
                nextNodeLabel = nextNode(i, j, dir, N, M)
 
                # If invalid(out of matrix)
                if (nextNodeLabel == -1):
                    continue
 
                # If direction is same as mat[i][j]
                if (dir == mat[i][j]):
                    adj[i * N + j].append([nextNodeLabel, 0])
                else:
                    adj[i * N + j].append([nextNodeLabel, 1])
 
    # Applying djikstra's algorithm
    return zeroOneBFS(adj, 0, (N - 1) * N + M - 1, N, M)
 
# Driver code
if __name__ == '__main__':
    mat = [ [ 2, 2, 1 ],
             [ 4, 2, 3 ],
             [ 4, 3, 2 ] ]
 
    # Function call
    print (MinModifications(mat))
 
# This code is contributed by mohit kumar 29.


输出:
2

时间复杂度: O(N * M * log(N * M))
方法二
在这里,边缘权重为0,仅1,即0-1图。使用0-1 BFS可以找到此类图中的最短路径。
下面是上述方法的实现:

C++

// CPP program to find minimum
// possible changes required
// in the matrix
#include 
using namespace std;
 
// Function to find next possible node
int nextNode(int x, int y, int dir,
             int N, int M)
{
    if (dir == 1)
        y--;
    else if (dir == 2)
        y++;
    else if (dir == 3)
        x--;
    else
        x++;
 
    // If node is out of matrix
    if (!(x >= 0 && x < N && y >= 0 && y < M))
        return -1;
    else
        return (x * N + y);
}
 
// Prints shortest distance
// from given source to
// every other vertex
int zeroOneBFS(vector >* adj,
               int src, int dest, int N, int M)
{
    // Initialize distances
    // from given source
    int dist[N * M];
    for (int i = 0; i < N * M; i++)
        dist[i] = INT_MAX;
 
    // Double ended queue to do BFS.
    deque Q;
    dist[src] = 0;
    Q.push_back(src);
 
    while (!Q.empty()) {
        int v = Q.front();
        Q.pop_front();
 
        for (auto i : adj[v]) {
            // Checking for the optimal distance
            if (dist[i.first] > dist[v]
                                    + i.second) {
                dist[i.first] = dist[v]
                                + i.second;
 
                // Put 0 weight edges to front
                // and 1 weight edges to back
                // so that vertices are processed
                // in increasing order of weights.
                if (i.second == 0)
                    Q.push_front(i.first);
                else
                    Q.push_back(i.first);
            }
        }
    }
 
    // Shortest distance to
    // reach destination
    return dist[dest];
}
 
// Function to find minimum possible
// changes required in the matrix
int MinModifications(vector >& mat)
{
    int N = mat.size(), M = mat[0].size();
 
    // Converting given matrix to a graph
    vector > adj[N * M];
 
    for (int i = 0; i < N; i++) {
        for (int j = 0; j < M; j++) {
            // Each cell is a node
            // with label i*N + j
            for (int dir = 1; dir <= 4; dir++) {
                // Label of node if we
                // move in direction dir
                int nextNodeLabel = nextNode(i, j,
                                             dir, N, M);
 
                // If invalid(out of matrix)
                if (nextNodeLabel == -1)
                    continue;
 
                // If direction is same as mat[i][j]
                if (dir == mat[i][j])
                    adj[i * N + j].push_back(
                        { nextNodeLabel, 0 });
                else
                    adj[i * N + j].push_back(
                        { nextNodeLabel, 1 });
            }
        }
    }
 
    // Applying djikstra's algorithm
    return zeroOneBFS(adj, 0,
                      (N - 1) * N + M - 1, N, M);
}
 
// Driver code
int main()
{
    vector > mat = { { 2, 2, 1 },
                                 { 4, 2, 3 },
                                 { 4, 3, 2 } };
 
    // Function call
    cout << MinModifications(mat);
 
    return 0;
}

Python3

# Python program to find minimum
# possible changes required
# in the matrix
from collections import deque
 
# Function to find next possible node
def nextNode(x, y, dir, N, M):
    if (dir == 1):
        y -= 1
    elif (dir == 2):
        y += 1
    elif (dir == 3):
        x -= 1
    else:
        x += 1
 
    # If node is out of matrix
    if (not (x >= 0 and x < N and y >= 0 and y < M)):
        return -1
    else:
        return (x * N + y)
 
# Prints shortest distance
# from given source to
# every other vertex
def zeroOneBFS(adj, src, dest, N, M):
   
    # Initialize distances
    # from given source
    dist = [10**8] *(N * M)
 
    # Double ended queue to do BFS.
    Q = deque()
    dist[src] = 0
    Q.append(src)
 
    while (len(Q) > 0):
        v = Q.popleft()
 
        for i in adj[v]:
           
            # print(i)
            # Checking for the optimal distance
            if (dist[i[0]] > dist[v] + i[1]):
                dist[i[0]] = dist[v] + i[1]
                 
                # Put 0 weight edges to front
                # and 1 weight edges to back
                # so that vertices are processed
                # in increasing order of weights.
                if (i[1] == 0):
                    Q.appendleft(i[0])
                else:
                    Q.append(i[0])
 
    # Shortest distance to
    # reach destination
    return dist[dest]
 
# Function to find minimum possible
# changes required in the matrix
def MinModifications(mat):
    N, M = len(mat), len(mat[0])
 
    # Converting given matrix to a graph
    adj = [[] for i in range(N * M)]
 
    for i in range(N):
        for j in range(M):
           
            # Each cell is a node
            # with label i*N + j
            for dir in range(1, 5):
               
                # Label of node if we
                # move in direction dir
                nextNodeLabel = nextNode(i, j, dir, N, M)
 
                # If invalid(out of matrix)
                if (nextNodeLabel == -1):
                    continue
 
                # If direction is same as mat[i][j]
                if (dir == mat[i][j]):
                    adj[i * N + j].append([nextNodeLabel, 0])
                else:
                    adj[i * N + j].append([nextNodeLabel, 1])
 
    # Applying djikstra's algorithm
    return zeroOneBFS(adj, 0, (N - 1) * N + M - 1, N, M)
 
# Driver code
if __name__ == '__main__':
    mat = [ [ 2, 2, 1 ],
             [ 4, 2, 3 ],
             [ 4, 3, 2 ] ]
 
    # Function call
    print (MinModifications(mat))
 
# This code is contributed by mohit kumar 29.
输出:
2

时间复杂度: O(N * M)

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