In general with FOP ( *functional oriented programming* ) you can put it all in one liner and nest lambdas within one-liners but that is in general bad etiquette, since after 2 nesting function it all becomes quite unreadable.

The best way to approach this kind of issue is to split it up in several stages:

**1: splitting string into **`tuple`

:

```
lst = ['b-3', 'a-2', 'c-4', 'd-2']
res = map( lambda str_x: tuple( str_x.split('-') ) , lst)
```

**2: sorting elements like you wished :**

```
lst = ['b-3', 'a-2', 'c-4', 'd-2']
res = map( lambda str_x: tuple( str_x.split('-') ) , lst)
res = sorted( res, key=lambda x: ( int(x[1]), x[0] ) )
```

Since we split the string into tuple it will return an map object that will be represented as list of tuples. So now the 3rd step is optional:

**3: representing data as you inquired:**

```
lst = ['b-3', 'a-2', 'c-4', 'd-2']
res = map( lambda str_x: tuple( str_x.split('-') ) , lst)
res = sorted( res, key=lambda x: ( int(x[1]), x[0] ) )
res = map( '-'.join, res )
```

Now have in mind that `lambda nesting`

could produce a more one-liner solution and that you can actually embed a non discrete nesting type of lambda like follows:

```
a = ['b-3', 'a-2', 'c-4', 'd-2']
resa = map( lambda x: x.split('-'), a)
resa = map( lambda x: ( int(x[1]),x[0]) , a)
# resa can be written as this, but you must be sure about type you are passing to lambda
resa = map( lambda x: tuple( map( lambda y: int(y) is y.isdigit() else y , x.split('-') ) , a)
```

But as you can see if contents of `list a`

arent anything but 2 string types separated by `'-'`

, `lambda`

function will raise an error and you will have a bad time figuring what the hell is happening.

So in the end, i would like to show you several ways the 3rd step program could be written:

**1:**

```
lst = ['b-3', 'a-2', 'c-4', 'd-2']
res = map( '-'.join,\
sorted(\
map( lambda str_x: tuple( str_x.split('-') ) , lst),\
key=lambda x: ( int(x[1]), x[0] )\
)\
)
```

**2:**

```
lst = ['b-3', 'a-2', 'c-4', 'd-2']
res = map( '-'.join,\
sorted( map( lambda str_x: tuple( str_x.split('-') ) , lst),\
key=lambda x: tuple( reversed( tuple(\
map( lambda y: int(y) if y.isdigit() else y ,x )\
)))\
)\
) # map isn't reversible
```

**3:**

```
res = sorted( lst,\
key=lambda x:\
tuple(reversed(\
tuple( \
map( lambda y: int(y) if y.isdigit() else y , x.split('-') )\
)\
))\
)
```

So you can see how this all can get very complicated and incomprehensible. When reading my own or someone else's code i often love to see this version:

```
res = map( lambda str_x: tuple( str_x.split('-') ) , lst) # splitting string
res = sorted( res, key=lambda x: ( int(x[1]), x[0] ) ) # sorting for each element of splitted string
res = map( '-'.join, res ) # rejoining string
```

That is all from me. Have fun. I've tested all code in `py 3.6`

.

PS. In general, you have 2 ways to approach `lambda functions`

:

```
mult = lambda x: x*2
mu_add= lambda x: mult(x)+x #calling lambda from lambda
```

This way is useful for typical FOP,where you have constant data , and you need to manipulate each element of that data. But if you need to resolve `list,tuple,string,dict`

in `lambda`

these kind of operations aren't very useful, since if any of those `container/wrapper`

types is present the data type of elements inside containers becomes questionable. So we would need to go up a *level of abstraction* and determine how to manipulate data per its type.

```
mult_i = lambda x: x*2 if isinstance(x,int) else 2 # some ternary operator to make our life easier by putting if statement in lambda
```

Now you can use another type of `lambda`

function:

```
int_str = lambda x: ( lambda y: str(y) )(x)*x # a bit of complex, right?
# let me break it down.
#all this could be written as:
str_i = lambda x: str(x)
int_str = lambda x: str_i(x)*x
## we can separate another function inside function with ()
##because they can exclude interpreter to look at it first, then do the multiplication
# ( lambda x: str(x)) with this we've separated it as new definition of function
# ( lambda x: str(x) )(i) we called it and passed it i as argument.
```

Some people call this type of syntax as nested lambdas, i call it indiscreet since you can see all.

And you can use recursive lambda assignment:

```
def rec_lambda( data, *arg_lambda ):
# filtering all parts of lambda functions parsed as arguments
arg_lambda = [ x for x in arg_lambda if type(x).__name__ == 'function' ]
# implementing first function in line
data = arg_lambda[0](data)
if arg_lambda[1:]: # if there are still elements in arg_lambda
return rec_lambda( data, *arg_lambda[1:] ) #call rec_lambda
else: # if arg_lambda is empty or []
return data # returns data
#where you can use it like this
a = rec_lambda( 'a', lambda x: x*2, str.upper, lambda x: (x,x), '-'.join)
>>> 'AA-AA'
```

`key=lambda x: (int((x.split('-') as y)[0]), y[1])`

, which I'm not a fan of.) – chepner Apr 5 '18 at 12:27`y`

might be local to the call to`int`

, not the tuple... ick. – chepner Apr 5 '18 at 12:32`sorted(lst, key= lambda x: x[::-1])`

– Chris_Rands May 22 '18 at 21:31