codeforces#P1427C. The Hard Work of Paparazzi

The Hard Work of Paparazzi

Description

You are a paparazzi working in Manhattan.

Manhattan has $r$ south-to-north streets, denoted by numbers $1, 2,\ldots, r$ in order from west to east, and $r$ west-to-east streets, denoted by numbers $1,2,\ldots,r$ in order from south to north. Each of the $r$ south-to-north streets intersects each of the $r$ west-to-east streets; the intersection between the $x$-th south-to-north street and the $y$-th west-to-east street is denoted by $(x, y)$. In order to move from the intersection $(x,y)$ to the intersection $(x', y')$ you need $|x-x'|+|y-y'|$ minutes.

You know about the presence of $n$ celebrities in the city and you want to take photos of as many of them as possible. More precisely, for each $i=1,\dots, n$, you know that the $i$-th celebrity will be at the intersection $(x_i, y_i)$ in exactly $t_i$ minutes from now (and he will stay there for a very short time, so you may take a photo of him only if at the $t_i$-th minute from now you are at the intersection $(x_i, y_i)$). You are very good at your job, so you are able to take photos instantaneously. You know that $t_i < t_{i+1}$ for any $i=1,2,\ldots, n-1$.

Currently you are at your office, which is located at the intersection $(1, 1)$. If you plan your working day optimally, what is the maximum number of celebrities you can take a photo of?

The first line of the input contains two positive integers $r, n$ ($1\le r\le 500$, $1\le n\le 100,000$) – the number of south-to-north/west-to-east streets and the number of celebrities.

Then $n$ lines follow, each describing the appearance of a celebrity. The $i$-th of these lines contains $3$ positive integers $t_i, x_i, y_i$ ($1\le t_i\le 1,000,000$, $1\le x_i, y_i\le r$)  — denoting that the $i$-th celebrity will appear at the intersection $(x_i, y_i)$ in $t_i$ minutes from now.

It is guaranteed that $t_i<t_{i+1}$ for any $i=1,2,\ldots, n-1$.

Print a single integer, the maximum number of celebrities you can take a photo of.

Input

The first line of the input contains two positive integers $r, n$ ($1\le r\le 500$, $1\le n\le 100,000$) – the number of south-to-north/west-to-east streets and the number of celebrities.

Then $n$ lines follow, each describing the appearance of a celebrity. The $i$-th of these lines contains $3$ positive integers $t_i, x_i, y_i$ ($1\le t_i\le 1,000,000$, $1\le x_i, y_i\le r$)  — denoting that the $i$-th celebrity will appear at the intersection $(x_i, y_i)$ in $t_i$ minutes from now.

It is guaranteed that $t_i<t_{i+1}$ for any $i=1,2,\ldots, n-1$.

Output

Print a single integer, the maximum number of celebrities you can take a photo of.

Samples

10 1
11 6 8
0
6 9
1 2 6
7 5 1
8 5 5
10 3 1
12 4 4
13 6 2
17 6 6
20 1 4
21 5 4
4
10 4
1 2 1
5 10 9
13 8 8
15 9 9
1
500 10
69 477 122
73 186 235
341 101 145
372 77 497
390 117 440
494 471 37
522 300 498
682 149 379
821 486 359
855 157 386
3

Note

Explanation of the first testcase: There is only one celebrity in the city, and he will be at intersection $(6,8)$ exactly $11$ minutes after the beginning of the working day. Since you are initially at $(1,1)$ and you need $|1-6|+|1-8|=5+7=12$ minutes to reach $(6,8)$ you cannot take a photo of the celebrity. Thus you cannot get any photo and the answer is $0$.

Explanation of the second testcase: One way to take $4$ photos (which is the maximum possible) is to take photos of celebrities with indexes $3, 5, 7, 9$ (see the image for a visualization of the strategy):

  • To move from the office at $(1,1)$ to the intersection $(5,5)$ you need $|1-5|+|1-5|=4+4=8$ minutes, so you arrive at minute $8$ and you are just in time to take a photo of celebrity $3$.
  • Then, just after you have taken a photo of celebrity $3$, you move toward the intersection $(4,4)$. You need $|5-4|+|5-4|=1+1=2$ minutes to go there, so you arrive at minute $8+2=10$ and you wait until minute $12$, when celebrity $5$ appears.
  • Then, just after you have taken a photo of celebrity $5$, you go to the intersection $(6,6)$. You need $|4-6|+|4-6|=2+2=4$ minutes to go there, so you arrive at minute $12+4=16$ and you wait until minute $17$, when celebrity $7$ appears.
  • Then, just after you have taken a photo of celebrity $7$, you go to the intersection $(5,4)$. You need $|6-5|+|6-4|=1+2=3$ minutes to go there, so you arrive at minute $17+3=20$ and you wait until minute $21$ to take a photo of celebrity $9$.

Explanation of the third testcase: The only way to take $1$ photo (which is the maximum possible) is to take a photo of the celebrity with index $1$ (since $|2-1|+|1-1|=1$, you can be at intersection $(2,1)$ after exactly one minute, hence you are just in time to take a photo of celebrity $1$).

Explanation of the fourth testcase: One way to take $3$ photos (which is the maximum possible) is to take photos of celebrities with indexes $3, 8, 10$:

  • To move from the office at $(1,1)$ to the intersection $(101,145)$ you need $|1-101|+|1-145|=100+144=244$ minutes, so you can manage to be there when the celebrity $3$ appears (at minute $341$).
  • Then, just after you have taken a photo of celebrity $3$, you move toward the intersection $(149,379)$. You need $|101-149|+|145-379|=282$ minutes to go there, so you arrive at minute $341+282=623$ and you wait until minute $682$, when celebrity $8$ appears.
  • Then, just after you have taken a photo of celebrity $8$, you go to the intersection $(157,386)$. You need $|149-157|+|379-386|=8+7=15$ minutes to go there, so you arrive at minute $682+15=697$ and you wait until minute $855$ to take a photo of celebrity $10$.