So I am work on Project Euler 145 which says:

Some positive integers n have the property that the sum

`[ n + reverse(n) ]`

consists entirely of odd (decimal) digits. For instance,`36 + 63 = 99`

and`409 + 904 = 1313`

. We will call such numbers reversible; so 36, 63, 409, and 904 are reversible. Leading zeroes are not allowed in either n or reverse(n).There are 120 reversible numbers below one-thousand.

How many reversible numbers are there below one-billion (10**9)?

I am trying the following code (and instead of using 10^9 I am using 10 to check if the result (which should be zero) is happening:

```
def check(x):
y = int(str(x)[::-1]) #x backwards
#add the rev number to the original number (convert them to a list)
xy = list(str(x+y))
#a list of even digits.
evens = ['0', '2', '4', '6', '8']
#check if the number has any digits using intersection method.
intersect = set(xy).intersection(set(evens))
if not intersect:
#if there was no intersection the digits must be all odd.
return True
return False
def firstCheck(x):
if (int(str(x)[:1])+(x%10))%2 == 0:
#See if first number and last number of x make an even number.
return False
return True
def solve():
L = range(1, 10) #Make a list of 10
for x in L:
if firstCheck(x) == False:
#This quickly gets rid of some elements, not all, but some.
L.remove(x)
for x in L:
if check(x) == False:
#This should get rid of all the elements.
L.remove(x)
#what is remaining should be the number of "reversible" numbers.
#So return the length of the list.
return len(L)
print solve()
```

It works in two parts: In the method `solve`

there is a `firstCheck`

and `check`

the first check is to eliminate some numbers quickly (so when I make a 10^9 size list I can free some RAM). The second check is the one that gets rid of all the numbers supposedly that are not "reversible numbers". In the first check I just see if the first and last digit make an even number, and eliminate that number. In the check method I reverse the number, add the two numbers together and make them into a list, then check if it intersects a list of evens, if it does eliminate it from the list. The resulting list should be the number of elements that are "reversible" numbers so I take the list and return its length. For `range(1,10)`

I get 2 as the result (as opposed to the desired zero). And the numbers it doesn't eliminate [4,8] and I can't seem to find out why.

countinginstead of managing lists, that's also faster. 2. This approach is slow and doesn't scale well, by analysing the conditions you can get a solution that returns the answer instantaneously even for bounds like 10^20.