题目大意
在平面上给定n个矩形,可以相互覆盖全部或者部分,求出矩形占据的总面积。
题目分析
将矩形按照x方向的进行分割之后,将平面沿着y方向划分一系列单元(不定高度),每个矩形在y方向上占据若干连续的单元;在x方向上,将矩形按照x坐标排序之后,考虑有一个扫描线从左到右扫描,当扫描线进入矩形之后,所有矩形在扫描线上占据的总长度有可能增加,而扫面线离开某个矩形时,所有矩形在扫描线上占据的总长度有可能减少。
在计算面积的时候,将当前扫描点 所有矩形在扫描线上占据的总长度 乘以 当前扫描点到下一扫描点的长度,直到所有矩形均出扫描线。区间操作,考虑使用线段树。
实现(c++)
#define _CRT_SECURE_NO_WARNINGS
#include<stdio.h>
#include<algorithm>
#include<string.h>
#include<vector>
using namespace std;
#define MAX_RECT_NUM 1000
#define MAX_SEG_NUM MAX_RECT_NUM * 2
#define MAX_NODE_NUM 4*MAX_SEG_NUM
#define MAX(a, b) a > b? a :b
#define MIN(a, b) a < b? a :b
//根据矩形的上下边在y方向上划分区间单元(长度不固定),每个矩形占据y方向上的连续的几个单元,形成区间
struct Rect{
double top_left_x;
double top_left_y;
double bottom_right_x;
double bottom_right_y;
int interval_beg; //在y轴上,该矩形所占据区间的起始单元序号
int interval_end; //在y轴上,该矩形所占据区间的结束单元序号(从下向上) inteval_beg 和 interval_end为 闭区间
};
Rect gRects[MAX_RECT_NUM];
vector<double> gPartPoint; //用于离散化的点纵坐标
vector<double> gSegs; //离散化之后的段单元长度
struct Node{
int beg; //在y轴方向离散化之后,节点所代表区间的起始块号
int end; //节点所代表区间的终止块号
double length; //节点所代表区间的长度(y轴方向)
int covered_num; //扫描线被多少个矩形覆盖
};
Node gNodes[MAX_NODE_NUM];
//对矩形进行x坐标从小到大排序,便于进行扫描
bool CmpToSortRect(const Rect& rect1, const Rect& rect2){
if (rect1.top_left_x == rect2.top_left_x)
return rect1.bottom_right_x < rect2.bottom_right_x;
return rect1.top_left_x < rect2.top_left_x;
}
void BuildTree(int beg, int end, int index){
gNodes[index].beg = beg;
gNodes[index].end = end;
gNodes[index].covered_num = 0;
if (beg == end){
gNodes[index].length = gSegs[beg];
return;
}
int left = 2 * index + 1;
int right = 2 * index + 2;
int mid = (beg + end) / 2;
BuildTree(beg, mid, left);
BuildTree(mid + 1, end, right);
//由子节点长度得到父节点代表区间的长度
gNodes[index].length = gNodes[left].length + gNodes[right].length;
}
//向下更新
void PushDown(int index){
if (gNodes[index].covered_num){
int left = 2 * index + 1, right = 2 * index + 2;
gNodes[left].covered_num += gNodes[index].covered_num;
gNodes[right].covered_num += gNodes[index].covered_num;
}
gNodes[index].covered_num = 0;
}
//向上更新
void PushUp(int index){
int left = 2 * index + 1, right = 2 * index + 2;
int min = MIN(gNodes[left].covered_num, gNodes[right].covered_num);
gNodes[index].covered_num = min;
gNodes[left].covered_num -= min;
gNodes[right].covered_num -= min;
}
//当扫描线进入矩形区域时step_in = true, 否则为false
void Update(int beg, int end, int index, bool step_in){
if (gNodes[index].beg >= beg && gNodes[index].end <= end){
if (step_in){
gNodes[index].covered_num++;
}
else{
gNodes[index].covered_num--;
}
return;
}
if (gNodes[index].end < beg || gNodes[index].beg > end){
return;
}
if (beg > end){
return;
}
int left = 2 * index + 1, right = 2 * index + 2;
int mid = (gNodes[index].beg + gNodes[index].end) / 2;
//向下递归时,先pushdown 向下更新
PushDown(index);
Update(beg, MIN(mid, end), left, step_in);
Update(MAX(mid + 1, beg), end, right, step_in);
//递归返回进行 向上更新
PushUp(index);
}
//查询,查询当前情况下,扫描线占据的矩形y方向长度
double Query(int index){
if (gNodes[index].covered_num > 0){
return gNodes[index].length;
}
if (gNodes[index].beg == gNodes[index].end){
return 0;
}
int left = 2 * index + 1, right = 2 * index + 2;
return Query(left) + Query(right);
}
bool DoubleEqual(double d1, double d2){
if (abs(d1 - d2) < 1e-7){
return true;
}
return false;
}
int main(){
int n, cas = 1;
while (true){
scanf("%d", &n);
if (n == 0){
break;
}
gPartPoint.clear();
for (int i = 0; i < n; i++){
scanf("%lf %lf %lf %lf", &gRects[i].top_left_x, &gRects[i].top_left_y, &gRects[i].bottom_right_x, &gRects[i].bottom_right_y);
gPartPoint.push_back(gRects[i].top_left_y); //得到y方向上的各个离散的分界点
gPartPoint.push_back(gRects[i].bottom_right_y);
}
//对分界点进行排序,去重
sort(gPartPoint.begin(), gPartPoint.end());
vector<double>::iterator it = unique(gPartPoint.begin(), gPartPoint.end());
gPartPoint.erase(it, gPartPoint.end());
//根据分界点,得到离散化之后的区间长度
gSegs.clear();
gSegs.reserve(gPartPoint.size());
for (int i = 0; i < gPartPoint.size() - 1; i++){
double len = gPartPoint[i + 1] - gPartPoint[i];
gSegs.push_back(len);
}
//得到每个矩形在y方向上占据的离散化之后的区间的 beg和end(闭区间)
for (int i = 0; i < n; i++){
vector<double>::iterator it = find(gPartPoint.begin(), gPartPoint.end(), gRects[i].top_left_y);
gRects[i].interval_beg = it - gPartPoint.begin();
it = find(gPartPoint.begin(), gPartPoint.end(), gRects[i].bottom_right_y);
gRects[i].interval_end = it - gPartPoint.begin() - 1;
}
BuildTree(0, gSegs.size() - 1, 0);
//将x方向的各个分割点进行排序,去重
gPartPoint.clear();
for (int i = 0; i < n; i++){
gPartPoint.push_back(gRects[i].top_left_x);
gPartPoint.push_back(gRects[i].bottom_right_x);
}
sort(gPartPoint.begin(), gPartPoint.end());
it = unique(gPartPoint.begin(), gPartPoint.end());
gPartPoint.erase(it, gPartPoint.end());
int seg_num = gSegs.size();
double sum_area = 0;
double height = 0;
int beg, end;
for (int i = 0; i < gPartPoint.size() - 1; i++){
for (int r = 0; r < n; r++){
if (DoubleEqual(gRects[r].top_left_x, gPartPoint[i])){ //扫描线进入矩形
Update(gRects[r].interval_beg, gRects[r].interval_end, 0, true);
}
if (DoubleEqual(gRects[r].bottom_right_x, gPartPoint[i])){//扫描线离开矩形
Update(gRects[r].interval_beg, gRects[r].interval_end, 0, false);
}
}
height = Query(0);
sum_area += height*(gPartPoint[i + 1] - gPartPoint[i]);
}
printf("Test case #%d
", cas ++);
printf("Total explored area: %.2lf
", sum_area);
}
return 0;
}