The main thing is to go through all the possible values. Don't try to break when you find the first answer just start with a best answer of zero then try all combinations and keep updating best. The secondary thing is to try to reduce the set of "all combinations".

One thing you can do is limit your inner loop to values less than or equal to a (since a*b == b*a). This puts the larger value of your equation always in a and substantially reduces the number of values you have to test.

```
for a in range.to_a.reverse do
for b in (100..a).to_a.reverse do
```

The next thing you can do is break out of the inner loop whenever the product is less than the current best value.

```
c = a*b
next if c < best
```

Next, if you're going to go through them all anyway there's no benefit to going through them in reverse. By starting at the top of the range it takes a while before you find a palindromic number and as a result it takes a while to reduce your search set. If you start at the bottom you begin to increase the lower bound quickly.

```
for a in range.to_a do
for b in (100..a).to_a do
```

My tests show that either way you try some 405K pairs however. So how about thinking of the problem a different way. What is the largest possible product of two 3 digit numbers? 999 * 999 = 998001 and the smallest is 100*100 = 10000. How about we take the idea you had of breaking on the first answer but apply it to a different range, that being 998001 to 10000 (or 999*999 to 100*100).

```
for c in (10000...998001).to_a.reverse do
```

We get to a palindrome after only 202 tests... the problem is it isn't a product of two 3-digit numbers. So now we have to check whether the palindrome we've found is a product of 2 3-digit numbers. As soon as we find a value in the range that is a palindrome and a product of two 3-digit numbers we're done. My tests show we find the highest palindrome that meets the requirement after less than 93K tests. But since we have the overhead of checking that all palindromes to that point were products of two 3-digit numbers it may not be more efficient than the previous solution.

So lets go back to the original improvement.

```
for a in range.to_a.reverse do
for b in (100..a).to_a.reverse do
```

We're looping rows then columns and trying to be efficient by detecting a point where we can go to the next row because any additional trys on the current row could not possibly be better than our current best. What if, instead of going down the rows, we go across the diagonals?

Since the products get smaller diagonal by diagonal you can stop as soon as you find a palindome number. This is a really efficient solution but with a more complex implementation. It turns out this method finds the highest palindrome after slightly more than 2200 trys.