Hey guys i have a quick question about testing my method. Im new to python as of last week but im trying. My assignment was to make a method that takes of list of cards and sorts em in a certain fashion. I know all my checks and and if statements and such work because i tested them in a python shell, but i figured if i put all my code into the shell it would be out of index(correct indentation). So if you guys could help the thing im just not sure about is how to implement my method.

here is my method:

```
def play(list):
for k in list:
a,x,z = 0
#insert into the pile
pile = []
pile = pile + [[list[k]]]
#check if the new card in the pile is compatible to the card 3 to the left
#check in terms if the first char of each card is compatible
if( (((pile[a])[(len(pile[a]))-1])[0] ) == ((((pile[a-3])[(len(pile[a-3]))-1])[0])) ):
#add card to the top of the card 3 to left
pile[a-3] = pile[a-3] + [((pile[a])[(len(pile[a]))-1])]
if (len(pile[a])) == 1:
del pile[a]
else:
del (pile[a])[-1]
#check in terms if the last char of each card is compatible
elif((((pile[a])[(len(pile[a]))-1])[(len((((pile[a])[(len(pile[a]))-1]))))-1]) == (((pile[a-3])[(len(pile[a-3]))-1])[(len((((pile[a-3])[(len(pile[a-3]))-1]))))-1])):
#add card to the top of the card 3 to left
pile[a-3] = pile[a-3] + [((pile[a])[(len(pile[a]))-1])]
if (len(pile[a])) == 1:
del pile[a]
else:
del (pile[a])[-1]
#check if the new card in the pile is compatible to the card to the left
#check in terms if the first char of each card is compatible
elif((((pile[a])[(len(pile[a]))-1])[0] ) == ((((pile[a-1])[(len(pile[a-1]))-1])[0]))):
pile[a-1] = pile[a-1] + [((pile[a])[(len(pile[a]))-1])]
if (len(pile[a])) == 1:
del pile[a]
else:
del (pile[a])[-1]
#check in terms if the last char of each card is compatible
elif( (((pile[a])[(len(pile[a]))-1])[(len((((pile[a])[(len(pile[a]))-1]))))-1]) == (((pile[a-1])[(len(pile[a-1]))-1])[(len((((pile[a-1])[(len(pile[a-1]))-1]))))-1])):
pile[a-1] = pile[a-1] + [((pile[a])[(len(pile[a]))-1])]
if (len(pile[a])) == 1:
del pile[a]
else:
del (pile[a])[-1]
else:
a = a + 1
#now go through and look for additional moves
#(if any match the 1 to the left or 3rd)
while x < (len(pile)):
if((((pile[x])[(len(pile[x]))-1])[0] ) == ((((pile[x-3])[(len(pile[x-3]))-1])[0]))):
pile[x-3] = pile[x-3] + [((pile[x])[(len(pile[x]))-1])]
if (len(pile[x])) == 1:
del (pile[x])[-1]
z = x + 1
while z < (len(pile)):
pile[z-1] = pile[z]
z = z + 1
del pile[(len(pile))-1]
else:
del (pile[x])[-1]
x = x + 1
elif((((pile[x])[(len(pile[x]))-1])[(len((((pile[x])[(len(pile[x]))-1]))))-1]) == (((pile[x-3])[(len(pile[x-3]))-1])[(len((((pile[x-3])[(len(pile[x-3]))-1]))))-1])):
pile[x-3] = pile[x-3] + [((pile[x])[(len(pile[x]))-1])]
if (len(pile[a])) == 1:
del (pile[x])[-1]
z = x + 1
while z < (len(pile)):
pile[z-1] = pile[z]
z = z + 1
else:
del (pile[a])[-1]
x = x + 1
elif((((pile[x])[(len(pile[x]))-1])[0] ) == ((((pile[x-1])[(len(pile[x-1]))-1])[0]))):
pile[x-1] = pile[x-1] + [((pile[x])[(len(pile[x]))-1])]
if (len(pile[x])) == 1:
del (pile[x])[-1]
z = x + 1
while z < (len(pile)):
pile[z-1] = pile[z]
z = z + 1
del pile[(len(pile))-1]
else:
del (pile[x])[-1]
x = x + 1
elif( (((pile[x])[(len(pile[x]))-1])[(len((((pile[x])[(len(pile[x]))-1]))))-1]) == (((pile[x-1])[(len(pile[x-1]))-1])[(len((((pile[x-1])[(len(pile[x-1]))-1]))))-1])):
pile[x-1] = pile[x-1] + [((pile[x])[(len(pile[x]))-1])]
if (len(pile[a])) == 1:
del (pile[x])[-1]
z = x + 1
while z < (len(pile)):
pile[z-1] = pile[z]
z = z + 1
else:
del (pile[x])[-1]
x = x + 1
else:
x = x + 1
#end while loop
#end of for loop
return pile
```

and this is like what my teacher gave me, like the test cases:

```
import unittest
import solitaire
class Test(unittest.TestCase):
def test1(self):
actual = solitaire.play(['AC','2C','3C','4C','5C','6C','7C','8C','9C','TC','JC','QC','KC',
'AD','2D','3D','4D','5D','6D','7D','8D','9D','TD','JD','QD','KD',
'AH','2H','3H','4H','5H','6H','7H','8H','9H','TH','JH','QH','KH',
'AS','2S','3S','4S','5S','6S','7S','8S','9S','TS','JS','QS','KS'] )
expected = [['AS','2S','3S','4S','5S','6S','7S','8S','9S','TS','JS','QS','KS','KH','QH','JH','TH','9H','8H','7H','6H','5H','4H','3H','2H','AH','AD','2D','3D','4D','5D','6D','7D','8D','9D','TD','JD','QD','KD','KC','QC','JC','TC','9C','8C','7C','6C','5C','4C','3C','2C','AC']]
self.assertEqual ( len(expected), len(actual), 'Incorrect result' )
self.assertListEqual( expected, actual, 'Incorrect result' )
pass
def test2(self):
actual = solitaire.play(['QS','5D','4S','8D','8H','3C','3H','5C','9H','6S','QD','2S','2C',
'KS','QC','7C','JC','4H','3D','5S','6C','KD','JS','9C','TS','2D',
'4D','AS','AC','7H','TC','AH','KH','6D','4C','8C','TD','AD','8S',
'3S','JH','KC','QH','TH','6H','7S','5H','2H','9S','7D','JD','9D'] )
expected = [['8D','8H','3H','3C','JC','7C','QC','QD','4D','4S','6S','KS','KD','5D','5C','2C','2S','QS'],
['9C','4C','4H','9H'],
['6D','2D','3D'],
['JS','TS','TC','6C','AC','AS','5S'],
['KH','AH','7H'],
['8C'],
['AD','TD'],
['3S','8S'],
['6H','TH','JH'],
['KC'],
['2H','QH'],
['9D','JD','7D','7S'],
['5H'],
['9S']]
self.assertEqual ( len(expected), len(actual), 'Incorrect result' )
self.assertListEqual( expected, actual, 'Incorrect result' )
pass
def test3(self):
actual = solitaire.play(['5S','9H','QH','2H','8H','6H','3S','3H','AS','5H','JH','3C','KH',
'4H','6S','8S','8D','2D','JD','AH','KC','TD','TC','3D','6D','2C',
'AD','QS','9C','7C','6C','QD','JS','7H','7S','7D','KD','TS','5D',
'KS','9S','9D','4C','5C','8C','QC','JC','TH','4S','4D','2S','AC'] )
expected = [['4D','5D','5C','8C','QC','JC','4C','4S','TS','AS','AH','4H','5H','7H','7S','JS','QS','QD','AD','6D','3D','TD','JD','2D','8D','8S','6S','KS','KD','7D','9D','9C','7C','6C','2C','TC','3C','KC','KH','JH','9H','QH','2H','8H','6H','3H','3S','5S'],
['9S'],
['TH'],
['2S'],
['AC']]
self.assertEqual ( len(expected), len(actual), 'Incorrect result' )
self.assertListEqual( expected, actual, 'Incorrect result' )
pass
def test4(self):
actual = solitaire.play(['7C','9S','QC','4H','9D','3S','AD','9C','8H','AC','2D','9H','AH',
'5D','6C','QD','3H','TC','QS','2S','8D','7D','QH','6H','4C','3C',
'JS','JD','7H','TS','4S','TD','5H','KD','8C','KS','JC','6D','2H',
'5C','3D','KH','8S','JH','TH','KC','2C','5S','AS','4D','7S','6S'] )
expected = [['3S','9S','9D','AD','AC','7C'],
['QD','8D','7D','2D','5D','5H','8H','4H','9H','9C','QC'],
['AH'],
['TC','6C'],
['6H','3H'],
['JD','JS','2S','QS'],
['QH'],
['5C','JC','8C','3C','4C'],
['7H'],
['6D','TD','KD','KS','4S','TS'],
['2H'],
['3D'],
['TH','KH'],
['AS','5S','8S'],
['JH'],
['2C','KC'],
['4D'],
['6S','7S']]
self.assertEqual ( len(expected), len(actual), 'Incorrect result' )
self.assertListEqual( expected, actual, 'Incorrect result' )
pass
def test5(self):
actual = solitaire.play(['6C','AC','7C','7D','KC','6S','9H','5C','JS','3S','TS','9D','JH',
'QD','2D','8H','QS','8D','8C','2S','TC','9C','9S','5H','4D','3C',
'JD','QC','AS','3H','TD','7H','KS','KH','AD','TH','KD','4C','2C',
'QH','3D','5D','7S','4S','6D','2H','AH','JC','8S','4H','5S','6H'] )
expected = [['JC','QC','2C','2H','QH','AH','4H','6H','6D','3D','5D','JD','TD','TH','7H','7S','4S','4C','TC','3C','3H','5H','KH','KS','KD','8D','4D','AD','AS','9S','9C','KC','5C','8C','8H','9H','JH','JS','TS','3S','6S','QS','2S','2D','QD','9D','7D','7C','AC','6C'],
['5S','8S']]
self.assertEqual ( len(expected), len(actual), 'Incorrect result' )
self.assertListEqual( expected, actual, 'Incorrect result' )
pass
def test6(self):
actual = solitaire.play(['8S','7C','AS','5H','7H','9D','8C','8H','3H','TC','AH','KH','JH',
'JC','AD','9C','AC','QS','6H','KC','KS','5C','TS','3C','9H','7D',
'3S','4D','TD','QD','5D','9S','3D','6S','6D','8D','JS','2S','4C',
'4S','5S','6C','2D','4H','7S','2H','KD','TH','JD','QH','QC','2C'] )
expected = [['5S','7S','JS','2S','4S','4C','4H','TH','QH','QC','6C','9C','AC','KC','KS','QS','3S','3C','5C','5D','QD','7D','4D','TD','TS','9S','6S','6D','3D','8D','2D','2H','KH','6H','9H','9D','AD','AS','AH','3H','5H','JH','JC','8C','TC','7C','7H','8H','8S'],
['JD','KD'],
['2C']]
self.assertEqual ( len(expected), len(actual), 'Incorrect result' )
self.assertListEqual( expected, actual, 'Incorrect result' )
pass
if __name__ == "__main__":
#import sys;sys.argv = ['', 'Test.testName']
unittest.main()
```

Because i just learned python idk that much but im just not sure how i would use that test 'class' i guess it's called.

Any idea's?

Thanks a bunch!

`unittest`

is that it will tell you whether you got it right or not. You just have to save your`play`

function in a file called`solitaire.py`

(because the test program is trying to`import solitaire`

, so you have to match that name), then just run the tester script. (If it's called, say,`solitairetest.py`

, then type`python solitairetest.py`

at a shell.) It'll give you a nice printout of which tests you passed, and, if you failed any, what went wrong. – abarnert Nov 9 '12 at 4:14`python solitairetest.py`

in a python shell? – erp Nov 9 '12 at 6:38