This is the hard version of this problem. The only difference between the easy and hard versions is the constraints on $$$k$$$ and $$$m$$$. In this version of the problem, you need to output the answer by modulo $$$10^9+7$$$.

You are given a sequence $$$a$$$ of length $$$n$$$ consisting of integers from $$$1$$$ to $$$n$$$. The sequence may contain duplicates (i.e. some elements can be equal).

Find the number of tuples of $$$m$$$ elements such that the maximum number in the tuple differs from the minimum by no more than $$$k$$$. Formally, you need to find the number of tuples of $$$m$$$ indices $$$i_1 < i_2 < \ldots < i_m$$$, such that

$$$$$$\max(a_{i_1}, a_{i_2}, \ldots, a_{i_m}) - \min(a_{i_1}, a_{i_2}, \ldots, a_{i_m}) \le k.$$$$$$

For example, if $$$n=4$$$, $$$m=3$$$, $$$k=2$$$, $$$a=[1,2,4,3]$$$, then there are two such triples ($$$i=1, j=2, z=4$$$ and $$$i=2, j=3, z=4$$$). If $$$n=4$$$, $$$m=2$$$, $$$k=1$$$, $$$a=[1,1,1,1]$$$, then all six possible pairs are suitable.

As the result can be very large, you should print the value modulo $$$10^9 + 7$$$ (the remainder when divided by $$$10^9 + 7$$$).