You can use a generator for an elegant solution. At each iteration, yield twice—once with the original element, and once with the element with the added suffix.
The generator will need to be exhausted; that can be done by tacking on a list call at the end.
def transform(l):
for i, x in enumerate(l, 1):
yield x
yield f'{x}_{i}' # {}_{}'.format(x, i)
You can also re-write this using the yield from syntax for generator delegation:
def transform(l):
for i, x in enumerate(l, 1):
yield from (x, f'{x}_{i}') # (x, {}_{}'.format(x, i))
out_l = list(transform(l))
print(out_l)
['a', 'a_1', 'b', 'b_2', 'c', 'c_3']
If you're on versions older than python-3.6, replace f'{x}_{i}' with '{}_{}'.format(x, i).
Generalising
Consider a general scenario where you have N lists of the form:
l1 = [v11, v12, ...]
l2 = [v21, v22, ...]
l3 = [v31, v32, ...]
...
Which you would like to interleave. These lists are not necessarily derived from each other.
To handle interleaving operations with these N lists, you'll need to iterate over pairs:
def transformN(*args):
for vals in zip(*args):
yield from vals
out_l = transformN(l1, l2, l3, ...)
Sliced list.__setitem__
I'd recommend this from the perspective of performance. First allocate space for an empty list, and then assign list items to their appropriate positions using sliced list assignment. l goes into even indexes, and l' (l modified) goes into odd indexes.
out_l = [None] * (len(l) * 2)
out_l[::2] = l
out_l[1::2] = [f'{x}_{i}' for i, x in enumerate(l, 1)] # [{}_{}'.format(x, i) ...]
print(out_l)
['a', 'a_1', 'b', 'b_2', 'c', 'c_3']
This is consistently the fastest from my timings (below).
Generalising
To handle N lists, iteratively assign to slices.
list_of_lists = [l1, l2, ...]
out_l = [None] * len(list_of_lists[0]) * len(list_of_lists)
for i, l in enumerate(list_of_lists):
out_l[i::2] = l
A functional approach, similar to @chrisz' solution. Construct pairs using zip and then flatten it using itertools.chain.
from itertools import chain
# [{}_{}'.format(x, i) ...]
out_l = list(chain.from_iterable(zip(l, [f'{x}_{i}' for i, x in enumerate(l, 1)])))
print(out_l)
['a', 'a_1', 'b', 'b_2', 'c', 'c_3']
iterools.chain is widely regarded as the pythonic list flattening approach.
Generalising
This is the simplest solution to generalise, and I suspect the most efficient for multiple lists when N is large.
list_of_lists = [l1, l2, ...]
out_l = list(chain.from_iterable(zip(*list_of_lists)))
Performance
Let's take a look at some perf-tests for the simple case of two lists (one list with its suffix). General cases will not be tested since the results widely vary with by data.
Benchmarking code, for reference.
Functions
def cs1(l):
def _cs1(l):
for i, x in enumerate(l, 1):
yield x
yield f'{x}_{i}'
return list(_cs1(l))
def cs2(l):
out_l = [None] * (len(l) * 2)
out_l[::2] = l
out_l[1::2] = [f'{x}_{i}' for i, x in enumerate(l, 1)]
return out_l
def cs3(l):
return list(chain.from_iterable(
zip(l, [f'{x}_{i}' for i, x in enumerate(l, 1)])))
def ajax(l):
return [
i for b in [[a, '{}_{}'.format(a, i)]
for i, a in enumerate(l, start=1)]
for i in b
]
def ajax_cs0(l):
# suggested improvement to ajax solution
return [j for i, a in enumerate(l, 1) for j in [a, '{}_{}'.format(a, i)]]
def chrisz(l):
return [
val
for pair in zip(l, [f'{k}_{j+1}' for j, k in enumerate(l)])
for val in pair
]
