tvl-depot/data_structures_and_algorithms/optimal-stopping.py

from random import choice
from math import floor

# Applying Chapter 1 from "Algorithms to Live By", which describes optimal
# stopping problems. Technically this simulation is invalid because the
# `candidates` function takes a lower bound and an upper bound, which allows us
# to know the cardinal number of an individual candidates. The "look then leap"
# algorithm is ideal for no-information games - i.e. games when upper and lower
# bounds aren't known. The `look_then_leap/1` function is ignorant of this
# information, so it behaves as if in a no-information game. Strangely enough,
# this algorithm will pick the best candidate 37% of the time.
#
# Chapter 1 describes two algorithms:
# 1. Look-then-leap: ordinal numbers - i.e. no-information games. Look-then-leap
#    finds the best candidate 37% of the time.
# 2. Threshold: cardinal numbers - i.e. where upper and lower bounds are
#    known. The Threshold algorithm finds the best candidate ~55% of the time.
#
# All of this and more can be studied as "optimal stopping theory". This applies
# to finding a spouse, parking a car, picking an apartment in a city, and more.


# candidates :: Int -> Int -> Int -> [Int]
def candidates(lb, ub, ct):
    xs = list(range(lb, ub + 1))
    return [choice(xs) for _ in range(ct)]


# look_then_leap :: [Integer] -> Integer
def look_then_leap(candidates):
    best = candidates[0]
    seen_ct = 1
    ignore_ct = floor(len(candidates) * 0.37)
    for x in candidates[1:]:
        if ignore_ct > 0:
            ignore_ct -= 1
            best = max(best, x)
        else:
            if x > best:
                print('Choosing the {} candidate.'.format(seen_ct))
                return x
        seen_ct += 1
    print('You may have waited too long.')
    return candidates[-1]


candidates = candidates(1, 100, 100)
print(candidates)
print(look_then_leap(candidates))
Add InterviewCake.com examples Adds some of the code I generated while studying for a role transfer at Google using the fantastic resource, InterviewCake.com. This work predates the mono-repo. I should think of ways to DRY up this code and the code in crack_the_coding_interview, but I'm afraid I'm creating unnecessary work for myself that way. 2020-01-15 15:25:33 +01:00			`from random import choice`
			`from math import floor`

			`# Applying Chapter 1 from "Algorithms to Live By", which describes optimal`
			`# stopping problems. Technically this simulation is invalid because the`
			# `candidates` function takes a lower bound and an upper bound, which allows us
			`# to know the cardinal number of an individual candidates. The "look then leap"`
			`# algorithm is ideal for no-information games - i.e. games when upper and lower`
			# bounds aren't known. The `look_then_leap/1` function is ignorant of this
			`# information, so it behaves as if in a no-information game. Strangely enough,`
			`# this algorithm will pick the best candidate 37% of the time.`
			`#`
			`# Chapter 1 describes two algorithms:`
			`# 1. Look-then-leap: ordinal numbers - i.e. no-information games. Look-then-leap`
			`# finds the best candidate 37% of the time.`
			`# 2. Threshold: cardinal numbers - i.e. where upper and lower bounds are`
			`# known. The Threshold algorithm finds the best candidate ~55% of the time.`
			`#`
			`# All of this and more can be studied as "optimal stopping theory". This applies`
			`# to finding a spouse, parking a car, picking an apartment in a city, and more.`


			`# candidates :: Int -> Int -> Int -> [Int]`
			`def candidates(lb, ub, ct):`
			`xs = list(range(lb, ub + 1))`
			`return [choice(xs) for _ in range(ct)]`


			`# look_then_leap :: [Integer] -> Integer`
			`def look_then_leap(candidates):`
			`best = candidates[0]`
			`seen_ct = 1`
			`ignore_ct = floor(len(candidates) * 0.37)`
			`for x in candidates[1:]:`
			`if ignore_ct > 0:`
			`ignore_ct -= 1`
			`best = max(best, x)`
			`else:`
			`if x > best:`
			`print('Choosing the {} candidate.'.format(seen_ct))`
			`return x`
			`seen_ct += 1`
			`print('You may have waited too long.')`
			`return candidates[-1]`


			`candidates = candidates(1, 100, 100)`
			`print(candidates)`
			`print(look_then_leap(candidates))`