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count-of-smaller-numbers-after-self.cpp
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count-of-smaller-numbers-after-self.cpp
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// Time: O(nlogn)
// Space: O(n)
// BST solution. (40ms)
class Solution {
public:
class BSTreeNode {
public:
int val, count;
BSTreeNode *left, *right;
BSTreeNode(int val, int count) {
this->val = val;
this->count = count;
this->left = this->right = nullptr;
}
};
vector<int> countSmaller(vector<int>& nums) {
vector<int> res(nums.size());
BSTreeNode *root = nullptr;
// Insert into BST and get left count.
for (int i = nums.size() - 1; i >= 0; --i) {
BSTreeNode *node = new BSTreeNode(nums[i], 0);
root = insertNode(root, node);
res[i] = query(root, nums[i]);
}
return res;
}
// Insert node into BST.
BSTreeNode* insertNode(BSTreeNode* root, BSTreeNode* node) {
if (root == nullptr) {
return node;
}
BSTreeNode* curr = root;
while (curr) {
// Insert left if smaller.
if (node->val < curr->val) {
++curr->count; // Increase the number of left children.
if (curr->left != nullptr) {
curr = curr->left;
} else {
curr->left = node;
break;
}
} else { // Insert right if larger or equal.
if (curr->right != nullptr) {
curr = curr->right;
} else {
curr->right = node;
break;
}
}
}
return root;
}
// Query the smaller count of the value.
int query(BSTreeNode* root, int val) {
if (root == nullptr) {
return 0;
}
int count = 0;
BSTreeNode* curr = root;
while (curr) {
// Insert left.
if (val < curr->val) {
curr = curr->left;
} else if (val > curr->val) {
count += 1 + curr->count; // Count the number of the smaller nodes.
curr = curr->right;
} else { // Equal.
return count + curr->count;
}
}
return 0;
}
};
// Time: O(nlogn)
// Space: O(n)
// BIT solution. (56ms)
class Solution2 {
public:
vector<int> countSmaller(vector<int>& nums) {
// Get the place (position in the ascending order) of each number.
vector<int> sorted_nums(nums), places(nums.size());
sort(sorted_nums.begin(), sorted_nums.end());
for (int i = 0; i < nums.size(); ++i) {
places[i] =
lower_bound(sorted_nums.begin(), sorted_nums.end(), nums[i]) -
sorted_nums.begin();
}
// Count the smaller elements after the number.
vector<int> bit(nums.size() + 1), ans(nums.size());
for (int i = nums.size() - 1; i >= 0; --i) {
ans[i] = query(bit, places[i]);
add(bit, places[i] + 1, 1);
}
return ans;
}
private:
void add(vector<int>& bit, int i, int val) {
for (; i < bit.size(); i += lower_bit(i)) {
bit[i] += val;
}
}
int query(const vector<int>& bit, int i) {
int sum = 0;
for (; i > 0; i -= lower_bit(i)) {
sum += bit[i];
}
return sum;
}
int lower_bit(int i) {
return i & -i;
}
};
// Time: O(nlogn)
// Space: O(n)
// Divide and Conquer solution. (80ms)
class Solution3 {
public:
vector<int> countSmaller(vector<int>& nums) {
vector<int> counts(nums.size());
vector<pair<int, int>> num_idxs;
for (int i = 0; i < nums.size(); ++i) {
num_idxs.emplace_back(nums[i], i);
}
countAndMergeSort(&num_idxs, 0, num_idxs.size() - 1, &counts);
return counts;
}
void countAndMergeSort(vector<pair<int, int>> *num_idxs, int start, int end, vector<int> *counts) {
if (end - start <= 0) { // The number of range [start, end] of which size is less than 2 doesn't need sort.
return;
}
int mid = start + (end - start) / 2;
countAndMergeSort(num_idxs, start, mid, counts);
countAndMergeSort(num_idxs, mid + 1, end, counts);
int r = mid + 1;
vector<pair<int, int>> tmp;
for (int i = start; i <= mid; ++i) {
// Merge the two sorted arrays into tmp.
while (r <= end && (*num_idxs)[r].first < (*num_idxs)[i].first) {
tmp.emplace_back((*num_idxs)[r++]);
}
tmp.emplace_back((*num_idxs)[i]);
(*counts)[(*num_idxs)[i].second] += r - (mid + 1);
}
// Copy tmp back to num_idxs.
copy(tmp.begin(), tmp.end(), num_idxs->begin() + start);
}
};