A batch of $$$n$$$ goods ($$$n$$$ — an even number) is brought to the store, $$$i$$$-th of which has weight $$$a_i$$$. Before selling the goods, they must be packed into packages. After packing, the following will be done:

• There will be $$$\frac{n}{2}$$$ packages, each package contains exactly two goods;
• The weight of the package that contains goods with indices $$$i$$$ and $$$j$$$ ($$$1 \le i, j \le n$$$) is $$$a_i + a_j$$$.

With this, the cost of a package of weight $$$x$$$ is always $$$\left \lfloor\frac{x}{k}\right\rfloor$$$ burles (rounded down), where $$$k$$$ — a fixed and given value.

Pack the goods to the packages so that the revenue from their sale is maximized. In other words, make such $$$\frac{n}{2}$$$ pairs of given goods that the sum of the values $$$\left \lfloor\frac{x_i}{k} \right \rfloor$$$, where $$$x_i$$$ is the weight of the package number $$$i$$$ ($$$1 \le i \le \frac{n}{2}$$$), is maximal.

For example, let $$$n = 6, k = 3$$$, weights of goods $$$a = [3, 2, 7, 1, 4, 8]$$$. Let's pack them into the following packages.

• In the first package we will put the third and sixth goods. Its weight will be $$$a_3 + a_6 = 7 + 8 = 15$$$. The cost of the package will be $$$\left \lfloor\frac{15}{3}\right\rfloor = 5$$$ burles.
• In the second package put the first and fifth goods, the weight is $$$a_1 + a_5 = 3 + 4 = 7$$$. The cost of the package is $$$\left \lfloor\frac{7}{3}\right\rfloor = 2$$$ burles.
• In the third package put the second and fourth goods, the weight is $$$a_2 + a_4 = 2 + 1 = 3$$$. The cost of the package is $$$\left \lfloor\frac{3}{3}\right\rfloor = 1$$$ burle.

With this packing, the total cost of all packs would be $$$5 + 2 + 1 = 8$$$ burles.