Monocarp is planning on opening a chemistry lab. During the first month, he's going to distribute solutions of a certain acid.

First, he will sign some contracts with a local chemistry factory. Each contract provides Monocarp with an unlimited supply of some solution of the same acid. The factory provides $$$n$$$ contract options, numbered from $$$1$$$ to $$$n$$$. The $$$i$$$-th solution has a concentration of $$$x_i\%$$$, the contract costs $$$w_i$$$ burles, and Monocarp will be able to sell it for $$$c_i$$$ burles per liter.

Monocarp is expecting $$$k$$$ customers during the first month. Each customer will buy a liter of a $$$y\%$$$-solution, where $$$y$$$ is a real number chosen uniformly at random from $$$0$$$ to $$$100$$$ independently for each customer. More formally, the probability of number $$$y$$$ being less than or equal to some $$$t$$$ is $$$P(y \le t) = \frac{t}{100}$$$.

Monocarp can mix the solution that he signed the contracts with the factory for, at any ratio. More formally, if he has contracts for $$$m$$$ solutions with concentrations $$$x_1, x_2, \dots, x_m$$$, then, for these solutions, he picks their volumes $$$a_1, a_2, \dots, a_m$$$ so that $$$\sum \limits_{i=1}^{m} a_i = 1$$$ (exactly $$$1$$$ since each customer wants exactly one liter of a certain solution).

The concentration of the resulting solution is $$$\sum \limits_{i=1}^{m} x_i \cdot a_i$$$. The price of the resulting solution is $$$\sum \limits_{i=1}^{m} c_i \cdot a_i$$$.

If Monocarp can obtain a solution of concentration $$$y\%$$$, then he will do it while maximizing its price (the cost for the customer). Otherwise, the customer leaves without buying anything, and the price is considered equal to $$$0$$$.

Monocarp wants to sign some contracts with a factory (possibly, none or all of them) so that the expected profit is maximized — the expected total price of the sold solutions for all $$$k$$$ customers minus the total cost of signing the contracts from the factory.

Print the maximum expected profit Monocarp can achieve.