I'm aware that what I'm about to suggest is not ideal, but I think this is as close as I can get for my contribution. This is a fun problem to solve, even if it isn't the most traditional application of reduce.
The key issue seems to be keeping track of the distance from point to point without overwriting the points themselves- adding another 'dimension' to each point gives you a field with which you can track the running distance.
iterable = ((1,2,0), (3,4,0), (1,8,0))
# originally ((1,2), (3,4), (1,8))
from math import sqrt
def func(tup1, tup2):
'''function to pass to reduce'''
# extract coordinates
x0 = tup1
x1 = tup2
y0 = tup1
y1 = tup2
dist = tup1 # retrieve running total for distance
dx = x1 - x0 # find change in x
dy = y1 - y0 # find change in y
# add new distance to running total
dist += sqrt(dx**2 + dy**2)
# return 2nd point with the updated distance
return tup2[:-1] + (dist,) # e.g. (3, 4, 2.828)
# returns 7.3005630797457695
This way, the intermediate tuple of tuples (i.e., after one 'reduction') becomes:
((3, 4, 2.8284271247461903), (1,8,0))