#P1540E. Tasty Dishes
Tasty Dishes
No submission language available for this problem.
Description
Note that the memory limit is unusual.
There are $n$ chefs numbered $1, 2, \ldots, n$ that must prepare dishes for a king. Chef $i$ has skill $i$ and initially has a dish of tastiness $a_i$ where $|a_i| \leq i$. Each chef has a list of other chefs that he is allowed to copy from. To stop chefs from learning bad habits, the king makes sure that chef $i$ can only copy from chefs of larger skill.
There are a sequence of days that pass during which the chefs can work on their dish. During each day, there are two stages during which a chef can change the tastiness of their dish.
- At the beginning of each day, each chef can choose to work (or not work) on their own dish, thereby multiplying the tastiness of their dish of their skill ($a_i := i \cdot a_i$) (or doing nothing).
- After all chefs (who wanted) worked on their own dishes, each start observing the other chefs. In particular, for each chef $j$ on chef $i$'s list, chef $i$ can choose to copy (or not copy) $j$'s dish, thereby adding the tastiness of the $j$'s dish to $i$'s dish ($a_i := a_i + a_j$) (or doing nothing). It can be assumed that all copying occurs simultaneously. Namely, if chef $i$ chooses to copy from chef $j$ he will copy the tastiness of chef $j$'s dish at the end of stage $1$.
All chefs work to maximize the tastiness of their own dish in order to please the king.
Finally, you are given $q$ queries. Each query is one of two types.
- $1$ $k$ $l$ $r$ — find the sum of tastiness $a_l, a_{l+1}, \ldots, a_{r}$ after the $k$-th day. Because this value can be large, find it modulo $10^9 + 7$.
- $2$ $i$ $x$ — the king adds $x$ tastiness to the $i$-th chef's dish before the $1$-st day begins ($a_i := a_i + x$). Note that, because the king wants to see tastier dishes, he only adds positive tastiness ($x > 0$).
Note that queries of type $1$ are independent of each all other queries. Specifically, each query of type $1$ is a scenario and does not change the initial tastiness $a_i$ of any dish for future queries. Note that queries of type $2$ are cumulative and only change the initial tastiness $a_i$ of a dish. See notes for an example of queries.
The first line contains a single integer $n$ ($1 \le n \le 300$) — the number of chefs.
The second line contains $n$ integers $a_1, a_2, \ldots, a_n$ ($-i \le a_i \le i$).
The next $n$ lines each begin with a integer $c_i$ ($0 \le c_i < n$), denoting the number of chefs the $i$-th chef can copy from. This number is followed by $c_i$ distinct integers $d$ ($i < d \le n$), signifying that chef $i$ is allowed to copy from chef $d$ during stage $2$ of each day.
The next line contains a single integer $q$ ($1 \le q \le 2 \cdot 10^5$) — the number of queries.
Each of the next $q$ lines contains a query of one of two types:
- $1$ $k$ $l$ $r$ ($1 \le l \le r \le n$; $1 \le k \le 1000$);
- $2$ $i$ $x$ ($1 \le i \le n$; $1 \le x \le 1000$).
It is guaranteed that there is at least one query of the first type.
For each query of the first type, print a single integer — the answer to the query.
Input
The first line contains a single integer $n$ ($1 \le n \le 300$) — the number of chefs.
The second line contains $n$ integers $a_1, a_2, \ldots, a_n$ ($-i \le a_i \le i$).
The next $n$ lines each begin with a integer $c_i$ ($0 \le c_i < n$), denoting the number of chefs the $i$-th chef can copy from. This number is followed by $c_i$ distinct integers $d$ ($i < d \le n$), signifying that chef $i$ is allowed to copy from chef $d$ during stage $2$ of each day.
The next line contains a single integer $q$ ($1 \le q \le 2 \cdot 10^5$) — the number of queries.
Each of the next $q$ lines contains a query of one of two types:
- $1$ $k$ $l$ $r$ ($1 \le l \le r \le n$; $1 \le k \le 1000$);
- $2$ $i$ $x$ ($1 \le i \le n$; $1 \le x \le 1000$).
It is guaranteed that there is at least one query of the first type.
Output
For each query of the first type, print a single integer — the answer to the query.
Samples
5
1 0 -2 -2 4
4 2 3 4 5
1 3
1 4
1 5
0
7
1 1 1 5
2 4 3
1 1 1 5
2 3 2
1 2 2 4
2 5 1
1 981 4 5
57
71
316
278497818
Note
Below is the set of chefs that each chef is allowed to copy from:
- $1$: $\{2, 3, 4, 5\}$
- $2$: $\{3\}$
- $3$: $\{4\}$
- $4$: $\{5\}$
- $5$: $\emptyset$ (no other chefs)
Following is a description of the sample.
For the first query of type $1$, the initial tastiness values are $[1, 0, -2, -2, 4]$.
The final result of the first day is shown below:
- $[1, 0, -2, -2, 20]$ (chef $5$ works on his dish).
- $[21, 0, -2, 18, 20]$ (chef $1$ and chef $4$ copy from chef $5$).
So, the answer for the $1$-st query is $21 + 0 - 2 + 18 + 20 = 57$.
For the $5$-th query ($3$-rd of type $1$). The initial tastiness values are now $[1, 0, 0, 1, 4]$.
Day 1
- $[1, 0, 0, 4, 20]$ (chefs $4$ and $5$ work on their dishes).
- $[25,0, 4, 24, 20]$ (chef $1$ copies from chefs $4$ and $5$, chef $3$ copies from chef $4$, chef $4$ copies from chef $5$).
Day 2
- $[25, 0, 12, 96, 100]$ (all chefs but chef $2$ work on their dish).
- $[233, 12, 108, 196, 100]$ (chef $1$ copies from chefs $3$, $4$ and $5$, chef $2$ from $3$, chef $3$ from $4$, chef $4$ from chef $5$).
So, the answer for the $5$-th query is $12+108+196=316$.
It can be shown that, in each step we described, all chefs moved optimally.