spoj#RPAR. Raining Parabolas

Raining Parabolas

 

It's raining parabolas!
Nowdays you just can't predict what'll fall on your head tomorrow..
Because we don't care about the nature, it is now striking back:
   it's raining parabolas!
The parabolas that are falling are given in form of quadratic
fuctions: f(x) = ax^2 + bx + c. The ground can be defined as a line
with N blocks, numbered from 0 to N-1, initially having height 0.
At some point, a block can have some positive height, but when it exceeds
10006 ( we don't actually know why, but measurements have shown it is a
weird regularity.. ) it falls back to 0 . When a parabola falls on the ground, 
it interacts with its current configuration ( the parabolas that have
fallen before it ) by summing with them.
Today you somehow came in possesion of some sort of schedule which defines
the order in which the parabolas will fall on the ground. Apart from that, 
you're interested total heights ( sums of heights ) of consecutive blocks
of ground. 
You're given two integers: N and M ( 1 <= N, M <= 100000 ). N specifies
the number of blocks on the floor, and M is the number of queries.
As we already said, we have two types of queries of form:
   0 x0 x1 a b c ( x0 <= x1, 0 <= a, b, c <= 10006 )
      this type of query just tells you that a parabola has
      fallen into the interval [x0, x1], and it function is f(x) = ax^2 + bx + c
   1 x0 x1
      this is the type of query you have to answer - output the sum of heights
      of all the blocks from interval [x0, x1] modulo 10007
All numbers in the input are integers.

Nowdays you just can't predict what'll fall on your head the next day.. Because we don't care about the nature, it is now striking back: it's raining parabolas!

The parabolas that are falling are given in form of quadratic functions: f(x) = ax2 + bx + c. The ground can be defined as a line with N blocks, numbered from 0 to N-1, initially having height 0. At some point, a block can have some positive height, but when it exceeds 10006 ( we don't actually know why, but measurements have shown it is a weird regularity.. ) it falls back to 0. When a parabola falls on some block, it interacts with its current configuration ( the parabolas that have fallen there before it ) by summing with it. More precisely, if we are given an interval [x0, x1] in which the next parabola will fall, and the function of our parabola is f(x) ( defined above ), some block i ( x0  <= i <= x1 ), with height hi, the new height of that block becomes (hi + f(i)) modulo 10007.

Today you somehow came in possesion of some sort of schedule which defines the order in which the parabolas will fall on the ground. Apart from that, you're interested total heights ( sums of heights ) of consecutive blocks of ground. When we want to find the total height of some interval [x0, x1], we're looking for the sum of hi for all i ( x0 <= i <= x1 ) modulo 10007.

Before the first parabola falls, the ground is flat ( all heights are 0 ).

Input

 

The first line of input contains two integers: N and M ( 1 <= N, M <= 100000 ). N specifies the number of blocks on the floor, and M is the number of queries. Each of the next M lines contains a query. As we already said, we have two types of queries of form:

   0 x0 x1 a b c (0 <= x0 <= x< N, 0 <= a, b, c <= 10006, all integers )

      this type of query just tells you that a parabola has

      fallen into the interval [x0, x1], and its function is f(x) = ax2 + bx + c


   1 x0 x( 0 <= x0 <= x1 < N, all integers )

      this is the type of query you have to answer - output the sum of heights

      of all the blocks from interval [x0, x1] modulo 10007

 

Output

For each query of type 1, output a single line containing the sum of all the heights in the given interval modulo 10007.

Example

Input:
10 2
0 0 9 1 0 0
1 0 3
Output:
14 

(the sum of the first 4 squares ( from 0 to 3 ) is 14 )