You got a job as a marketer in a pet shop, and your current task is to boost sales of cat food. One of the strategies is to sell cans of food in packs with discounts.
Suppose you decided to sell packs with $$$a$$$ cans in a pack with a discount and some customer wants to buy $$$x$$$ cans of cat food. Then he follows a greedy strategy:
$$$\left\lfloor \frac{x}{a} \right\rfloor$$$ is $$$x$$$ divided by $$$a$$$ rounded down, $$$x \bmod a$$$ is the remainer of $$$x$$$ divided by $$$a$$$.
But customers are greedy in general, so if the customer wants to buy $$$(x \bmod a)$$$ cans one by one and it happens that $$$(x \bmod a) \ge \frac{a}{2}$$$ he decides to buy the whole pack of $$$a$$$ cans (instead of buying $$$(x \bmod a)$$$ cans). It makes you, as a marketer, happy since the customer bought more than he wanted initially.
You know that each of the customers that come to your shop can buy any number of cans from $$$l$$$ to $$$r$$$ inclusive. Can you choose such size of pack $$$a$$$ that each customer buys more cans than they wanted initially?
The first line contains a single integer $$$t$$$ ($$$1 \le t \le 1000$$$) — the number of test cases.
The first and only line of each test case contains two integers $$$l$$$ and $$$r$$$ ($$$1 \le l \le r \le 10^9$$$) — the range of the number of cans customers can buy.
For each test case, print YES if you can choose such size of pack $$$a$$$ that each customer buys more cans than they wanted initially. Otherwise, print NO.
You can print each character in any case.
3 3 4 1 2 120 150
YES NO YES
In the first test case, you can take, for example, $$$a = 5$$$ as the size of the pack. Then if a customer wants to buy $$$3$$$ cans, he'll buy $$$5$$$ instead ($$$3 \bmod 5 = 3$$$, $$$\frac{5}{2} = 2.5$$$). The one who wants $$$4$$$ cans will also buy $$$5$$$ cans.
In the second test case, there is no way to choose $$$a$$$.
In the third test case, you can take, for example, $$$a = 80$$$.
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