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Copy path850. Rectangle Area II.go
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850. Rectangle Area II.go
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package leetcode
import (
"sort"
)
func rectangleArea(rectangles [][]int) int {
sat, res := SegmentAreaTree{}, 0
posXMap, posX, posYMap, posY, lines := discretization850(rectangles)
tmp := make([]int, len(posYMap))
for i := 0; i < len(tmp)-1; i++ {
tmp[i] = posY[i+1] - posY[i]
}
sat.Init(tmp, func(i, j int) int {
return i + j
})
for i := 0; i < len(posY)-1; i++ {
tmp[i] = posY[i+1] - posY[i]
}
for i := 0; i < len(posX)-1; i++ {
for _, v := range lines[posXMap[posX[i]]] {
sat.Update(posYMap[v.start], posYMap[v.end], v.state)
}
res += ((posX[i+1] - posX[i]) * sat.Query(0, len(posY)-1)) % 1000000007
}
return res % 1000000007
}
func discretization850(positions [][]int) (map[int]int, []int, map[int]int, []int, map[int][]LineItem) {
tmpXMap, tmpYMap, posXArray, posXMap, posYArray, posYMap, lines := map[int]int{}, map[int]int{}, []int{}, map[int]int{}, []int{}, map[int]int{}, map[int][]LineItem{}
for _, pos := range positions {
tmpXMap[pos[0]]++
tmpXMap[pos[2]]++
}
for k := range tmpXMap {
posXArray = append(posXArray, k)
}
sort.Ints(posXArray)
for i, pos := range posXArray {
posXMap[pos] = i
}
for _, pos := range positions {
tmpYMap[pos[1]]++
tmpYMap[pos[3]]++
tmp1 := lines[posXMap[pos[0]]]
tmp1 = append(tmp1, LineItem{start: pos[1], end: pos[3], state: 1})
lines[posXMap[pos[0]]] = tmp1
tmp2 := lines[posXMap[pos[2]]]
tmp2 = append(tmp2, LineItem{start: pos[1], end: pos[3], state: -1})
lines[posXMap[pos[2]]] = tmp2
}
for k := range tmpYMap {
posYArray = append(posYArray, k)
}
sort.Ints(posYArray)
for i, pos := range posYArray {
posYMap[pos] = i
}
return posXMap, posXArray, posYMap, posYArray, lines
}
// LineItem define
type LineItem struct { // 垂直于 x 轴的线段
start, end, state int // state = 1 代表进入,-1 代表离开
}
// SegmentItem define
type SegmentItem struct {
count int
val int
}
// SegmentAreaTree define
type SegmentAreaTree struct {
data []int
tree []SegmentItem
left, right int
merge func(i, j int) int
}
// Init define
func (sat *SegmentAreaTree) Init(nums []int, oper func(i, j int) int) {
sat.merge = oper
data, tree := make([]int, len(nums)), make([]SegmentItem, 4*len(nums))
for i := 0; i < len(nums); i++ {
data[i] = nums[i]
}
sat.data, sat.tree = data, tree
if len(nums) > 0 {
sat.buildSegmentTree(0, 0, len(nums)-1)
}
}
// 在 treeIndex 的位置创建 [left....right] 区间的线段树
func (sat *SegmentAreaTree) buildSegmentTree(treeIndex, left, right int) {
if left == right-1 {
sat.tree[treeIndex] = SegmentItem{count: 0, val: sat.data[left]}
return
}
midTreeIndex, leftTreeIndex, rightTreeIndex := left+(right-left)>>1, sat.leftChild(treeIndex), sat.rightChild(treeIndex)
sat.buildSegmentTree(leftTreeIndex, left, midTreeIndex)
sat.buildSegmentTree(rightTreeIndex, midTreeIndex, right)
sat.pushUp(treeIndex, leftTreeIndex, rightTreeIndex)
}
func (sat *SegmentAreaTree) pushUp(treeIndex, leftTreeIndex, rightTreeIndex int) {
newCount, newValue := sat.merge(sat.tree[leftTreeIndex].count, sat.tree[rightTreeIndex].count), 0
if sat.tree[leftTreeIndex].count > 0 && sat.tree[rightTreeIndex].count > 0 {
newValue = sat.merge(sat.tree[leftTreeIndex].val, sat.tree[rightTreeIndex].val)
} else if sat.tree[leftTreeIndex].count > 0 && sat.tree[rightTreeIndex].count == 0 {
newValue = sat.tree[leftTreeIndex].val
} else if sat.tree[leftTreeIndex].count == 0 && sat.tree[rightTreeIndex].count > 0 {
newValue = sat.tree[rightTreeIndex].val
}
sat.tree[treeIndex] = SegmentItem{count: newCount, val: newValue}
}
func (sat *SegmentAreaTree) leftChild(index int) int {
return 2*index + 1
}
func (sat *SegmentAreaTree) rightChild(index int) int {
return 2*index + 2
}
// 查询 [left....right] 区间内的值
// Query define
func (sat *SegmentAreaTree) Query(left, right int) int {
if len(sat.data) > 0 {
return sat.queryInTree(0, 0, len(sat.data)-1, left, right)
}
return 0
}
func (sat *SegmentAreaTree) queryInTree(treeIndex, left, right, queryLeft, queryRight int) int {
midTreeIndex, leftTreeIndex, rightTreeIndex := left+(right-left)>>1, sat.leftChild(treeIndex), sat.rightChild(treeIndex)
if left > queryRight || right < queryLeft { // segment completely outside range
return 0 // represents a null node
}
if queryLeft <= left && queryRight >= right { // segment completely inside range
if sat.tree[treeIndex].count > 0 {
return sat.tree[treeIndex].val
}
return 0
}
if queryLeft > midTreeIndex {
return sat.queryInTree(rightTreeIndex, midTreeIndex, right, queryLeft, queryRight)
} else if queryRight <= midTreeIndex {
return sat.queryInTree(leftTreeIndex, left, midTreeIndex, queryLeft, queryRight)
}
// merge query results
return sat.merge(sat.queryInTree(leftTreeIndex, left, midTreeIndex, queryLeft, midTreeIndex),
sat.queryInTree(rightTreeIndex, midTreeIndex, right, midTreeIndex, queryRight))
}
// Update define
func (sat *SegmentAreaTree) Update(updateLeft, updateRight, val int) {
if len(sat.data) > 0 {
sat.updateInTree(0, 0, len(sat.data)-1, updateLeft, updateRight, val)
}
}
func (sat *SegmentAreaTree) updateInTree(treeIndex, left, right, updateLeft, updateRight, val int) {
midTreeIndex, leftTreeIndex, rightTreeIndex := left+(right-left)>>1, sat.leftChild(treeIndex), sat.rightChild(treeIndex)
if left > right || left >= updateRight || right <= updateLeft { // 由于叶子节点的区间不在是 left == right 所以这里判断需要增加等号的判断
return // out of range. escape.
}
if updateLeft <= left && right <= updateRight { // segment is fully within update range
if left == right-1 {
sat.tree[treeIndex].count = sat.merge(sat.tree[treeIndex].count, val)
}
if left != right-1 { // update lazy[] for children
sat.updateInTree(leftTreeIndex, left, midTreeIndex, updateLeft, updateRight, val)
sat.updateInTree(rightTreeIndex, midTreeIndex, right, updateLeft, updateRight, val)
sat.pushUp(treeIndex, leftTreeIndex, rightTreeIndex)
}
return
}
sat.updateInTree(leftTreeIndex, left, midTreeIndex, updateLeft, updateRight, val)
sat.updateInTree(rightTreeIndex, midTreeIndex, right, updateLeft, updateRight, val)
// merge updates
sat.pushUp(treeIndex, leftTreeIndex, rightTreeIndex)
}