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alien-dictionary.cpp
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alien-dictionary.cpp
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// Time: O(n)
// Space: O(|V|+|E|) = O(26 + 26^2) = O(1)
// BFS solution.
class Solution {
public:
string alienOrder(vector<string>& words) {
unordered_set<char> nodes;
unordered_map<char, unordered_set<char>> in_degree, out_degree;
queue<char> zero_in_degree_queue;
for (const auto& word : words) {
for (const auto& c : word) {
nodes.emplace(c);
}
}
for (int i = 1; i < words.size(); ++i) {
if (words[i - 1].length() > words[i].length() &&
words[i - 1].substr(0, words[i].length()) == words[i]) {
return "";
}
findEdges(words[i - 1], words[i], &in_degree, &out_degree);
}
for (const auto& node : nodes) {
if (in_degree.find(node) == in_degree.end()) {
zero_in_degree_queue.emplace(node);
}
}
// BFS
string result;
while (!zero_in_degree_queue.empty()) {
const auto& precedence = zero_in_degree_queue.front();
zero_in_degree_queue.pop();
result.push_back(precedence);
if (out_degree.find(precedence) != out_degree.end()) {
for (const auto& c : out_degree[precedence]) {
in_degree[c].erase(precedence);
if (in_degree[c].empty()) {
zero_in_degree_queue.emplace(c);
}
}
out_degree.erase(precedence);
}
}
if (!out_degree.empty()) {
return "";
}
return result;
}
private:
// Construct the graph.
void findEdges(const string &word1, const string &word2,
unordered_map<char, unordered_set<char>> *in_degree,
unordered_map<char, unordered_set<char>> *out_degree) {
const int len = min(word1.length(), word2.length());
for (int i = 0; i < len; ++i) {
if (word1[i] != word2[i]) {
(*in_degree)[word2[i]].emplace(word1[i]);
(*out_degree)[word1[i]].emplace(word2[i]);
break;
}
}
}
};
// DFS solution.
class Solution2 {
public:
string alienOrder(vector<string>& words) {
// Find ancestors of each node by DFS.
unordered_set<char> nodes;
unordered_map<char, vector<char>> ancestors;
for (int i = 0; i < words.size(); ++i) {
for (const auto& c : words[i]) {
nodes.emplace(c);
}
if (i > 0) {
findEdges(words[i - 1], words[i], &ancestors);
}
}
// Output topological order by DFS.
string result;
unordered_map<char, char> visited;
for (const auto& node : nodes) {
if (topSortDFS(node, node, &ancestors, &visited, &result)) {
return "";
}
}
return result;
}
private:
// Construct the graph.
void findEdges(const string &word1, const string &word2,
unordered_map<char, vector<char>> *ancestors) {
const int len = min(word1.length(), word2.length());
for (int i = 0; i < len; ++i) {
if (word1[i] != word2[i]) {
(*ancestors)[word2[i]].emplace_back(word1[i]);
break;
}
}
}
// Topological sort, return whether there is a cycle.
bool topSortDFS(const char& root,
const char& node,
unordered_map<char, vector<char>> *ancestors,
unordered_map<char, char> *visited,
string *result) {
if (visited->emplace(make_pair(node, root)).second) {
for (auto& ancestor: (*ancestors)[node]) {
if (topSortDFS(root, ancestor, ancestors, visited, result)) {
return true;
}
}
result->push_back(node);
} else if ((*visited)[node] == root) {
// Visited from the same root in the DFS path.
// So it is cyclic.
return true;
}
return false;
}
};
// DFS with adjacency matrix solution.
class Solution3 {
public:
string alienOrder(vector<string>& words) {
string result;
vector<vector<bool>> graph(26, vector<bool>(26));
findDependency(words, &graph);
findOrder(&graph, &result);
return result;
}
private:
void findEdges(const string &word1, const string &word2, vector<vector<bool>> *graph) {
const int len = min(word1.length(), word2.length());
for (int i = 0; i < len; ++i) {
if (word1[i] != word2[i]) {
(*graph)[word1[i] - 'a'][word2[i] - 'a'] = true;
break;
}
}
}
// Construct the graph.
void findDependency(const vector<string>& words, vector<vector<bool>> *graph) {
for (const auto& c : words[0]) {
(*graph)[c - 'a'][c - 'a'] = true;
}
for (int i = 1; i < words.size(); ++i) {
for (const auto& c : words[i]) {
(*graph)[c - 'a'] [c - 'a'] = true;
}
findEdges(words[i - 1], words[i], graph);
}
}
// Topological sort, return whether there is a cycle.
bool topSortDFS(string *result, vector<bool> *visited,
vector<vector<bool>> *graph, const int root) {
if ((*visited)[root]) {
result->clear();
return true;
}
(*visited)[root] = true;
for (int i = 0; i < 26; ++i) {
if (i != root && (*graph)[root][i]) {
if (topSortDFS(result, visited, graph, i)) {
return true;
}
}
}
(*graph)[root][root] = false;
result->push_back(root + 'a');
return false;
}
void findOrder(vector<vector<bool>> *graph, string *result) {
for (int i = 0; i < 26; ++i) {
// Find a root node.
bool root_node = (*graph)[i][i];
if ((*graph)[i][i]) {
for (int j = 0; j < 26; ++j) {
if (j != i && (*graph)[j][i]) {
root_node = false;
break;
}
}
}
if (root_node) {
string reversed_order = "";
vector<bool> visited(26, false);
if (topSortDFS(&reversed_order, &visited, graph, i)) {
result->clear();
return;
} else {
result->append(reversed_order);
}
}
}
// If there is any unvisited node, return "".
for (int i = 0; i < 26; ++i) {
if ((*graph)[i][i]) {
result->clear();
return;
}
}
// The order should be reversed.
reverse(result->begin(), result->end());
}
};