UVALive - 4108 SKYLINE[线段树]

时间:2022-03-05 09:38:45
UVALive - 4108
Time Limit: 3000MS     64bit IO Format: %lld & %llu

Submit Status UVALive - 4108 SKYLINE[线段树]uDebug

Description

UVALive - 4108 SKYLINE[线段树]

The skyline of Singapore as viewed from the Marina Promenade (shown on the left) is one of the iconic scenes of Singapore. Country X would also like to create an iconic skyline, and it has put up a call for proposals. Each submitted proposal is a description of a proposed skyline and one of the metrics that country X will use to evaluate a proposed skyline is the amount of overlap in the proposed sky-line.

UVALive - 4108 SKYLINE[线段树]<tex2html_verbatim_mark>

As the assistant to the chair of the skyline evaluation committee, you have been tasked with determining the amount of overlap in each proposal. Each proposal is a sequence of buildings, UVALive - 4108 SKYLINE[线段树]b1b2,..., bnUVALive - 4108 SKYLINE[线段树] <tex2html_verbatim_mark>, where a building is specified by its left and right endpoint and its height. The buildings are specified in back to front order, in other words a building which appears later in the sequence appears in front of a building which appears earlier in the sequence.

The skyline formed by the first k <tex2html_verbatim_mark>buildings is the union of the rectangles of the first k <tex2html_verbatim_mark>buildings (see Figure 4). The overlap of a building, bi <tex2html_verbatim_mark>, is defined as the total horizontal length of the parts of bi <tex2html_verbatim_mark>, whose height is greater than or equal to the skyline behind it. This is equivalent to the total horizontal length of parts of the skyline behind bi<tex2html_verbatim_mark>which has a height that is less than or equal to hi <tex2html_verbatim_mark>, where hi <tex2html_verbatim_mark>is the height of building bi <tex2html_verbatim_mark>. You may assume that initially the skyline has height zero everywhere.

Input

The input consists of a line containing the number c <tex2html_verbatim_mark>of datasets, followed by c <tex2html_verbatim_mark>datasets, followed by a line containing the number ` 0'.

The first line of each dataset consists of a single positive integer, n <tex2html_verbatim_mark>(0 < n < 100000) <tex2html_verbatim_mark>, which is the number of buildings in the proposal. The following n<tex2html_verbatim_mark>lines of each dataset each contains a description of a single building. The i <tex2html_verbatim_mark>-th line is a description of building bi <tex2html_verbatim_mark>. Each building bi <tex2html_verbatim_mark>is described by three positive integers, separated by spaces, namely, li <tex2html_verbatim_mark>, ri <tex2html_verbatim_mark>and hi <tex2html_verbatim_mark>, where li <tex2html_verbatim_mark>and rj <tex2html_verbatim_mark>(0 < li < riUVALive - 4108 SKYLINE[线段树]100000) <tex2html_verbatim_mark>represents the left and right end point of the building and hi represents the height of the building.

UVALive - 4108 SKYLINE[线段树]<tex2html_verbatim_mark>

Output

The output consists of one line for each dataset. The c <tex2html_verbatim_mark>-th line contains one single integer, representing the amount of overlap in the proposal for dataset c<tex2html_verbatim_mark>. You may assume that the amount of overlap for each dataset is at most 2000000.

Note: In this test case, the overlap of building b1 <tex2html_verbatim_mark>, b2 <tex2html_verbatim_mark>and b3 <tex2html_verbatim_mark>are 6, 4 and 4 respectively. Figure 4 shows how to compute the overlap of building b3 <tex2html_verbatim_mark>. The grey area represents the skyline formed by b1 <tex2html_verbatim_mark>and b2 <tex2html_verbatim_mark>and the black rectangle represents b3 <tex2html_verbatim_mark>. As shown in the figure, the length of the skyline covered by b3 <tex2html_verbatim_mark>is from position 3 to position 5 and from position 11 to position 13, therefore the overlap of b3 <tex2html_verbatim_mark>is 4.

Sample Input

1
3
5 11 3
1 10 1
3 13 2
0

Sample Output

14

题意:在线区间[l,r]查询h是最大值的长度,并更新


很明显区间max

但怎么找这个长度overlap呢?

如果当前区间满足ql<=l&&r<=qr&&h>=t[o].mx 那么就可以被完全覆盖

用lazy维护区间完全覆盖中的最大值,h<t[o].lazy时就不用继续找了(因为h不可能覆盖这个区间了),有点像个剪枝

否则必须继续找,下传lazy(无需清空自己的标记,剪枝嘛),合并mx

lazy和mx还有点小细节,比如paint没有用lazy更新mx,其实这不影响,因为先if(h<t[o].lazy) return;了

注意点是区间[i,i+1]

#include <iostream>
#include <cstdio>
#include <algorithm>
#include <cstring>
#define m (l+r)/2
#define lson o<<1,l,m
#define rson o<<1|1,m+1,r
#define lc o<<1
#define rc o<<1|1
using namespace std;
typedef long long ll;
const int N=1e5+;
inline int read(){
char c=getchar();int x=,f=;
while(c<''||c>''){if(c=='-')f=-;c=getchar();}
while(c>=''&&c<=''){x=x*+c-'';c=getchar();}
return x*f;
}
int T,n,ql,qr,h;
struct node{
int mx,lazy;//totally cover
}t[N<<];
inline void pushDown(int o){
if(t[o].lazy>t[lc].lazy) t[lc].lazy=t[o].lazy;
if(t[o].lazy>t[rc].lazy) t[rc].lazy=t[o].lazy;
}
int lap=;
inline void update(int o,int l,int r,int ql,int qr,int h){
if(h<t[o].lazy) return;
if(ql<=l&&r<=qr&&h>=t[o].mx){
t[o].mx=t[o].lazy=h;
lap+=r-l+;
}else{
pushDown(o);
if(ql<=m) update(lson,ql,qr,h);
if(m<qr) update(rson,ql,qr,h);
t[o].mx=max(t[lc].mx,t[rc].mx);
}
} int main(){
T=read();
while(T--){
n=read();
int ans=;
memset(t,,sizeof(t));
for(int i=;i<=n;i++){
ql=read();qr=read()-;h=read();
lap=;
update(,,1e5,ql,qr,h);
//printf("lap %d\n",lap);
ans+=lap;
}
printf("%d\n",ans);
}
}