# Puzzle that defies the brute force approach?

I bought a blank DVD to record my favorite TV show. It came with 20 digit stickers. 2 of each of '0'-'9'.
I thought it would be a good idea to numerically label my new DVD collection. I taped the '1' sticker on my first recorded DVD and put the 19 leftover stickers in a drawer.
The next day I bought another blank DVD (receiving 20 new stickers with it) and after recording the show I labeled it '2'.
And then I started wondering: when will the stickers run out and I will no longer be able to label a DVD?
A few lines of Python, no?

Can you provide code that solves this problem with a reasonable run-time?

Edit: The brute force will simply take too long to run. Please improve your algorithm so your code will return the right answer in, say, a minute?

Extra credit: What if the DVDs came with 3 stickers of each digit?

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Is this homework? – Oded Jul 24 '10 at 8:01
Assuming you want to number sequentially, you will be able to number up to 10 DVDs with 2 or 3 stickers per digit (spd), 11 with 4 spd, 20 with 12 stickers per digit, 30 with 13, and so on. Main reason being you'll run out of 1s quite early. – Franci Penov Jul 24 '10 at 8:06
@Franci: Not if you get another set of stickers with every blank DVD... – Jon Skeet Jul 24 '10 at 8:07
@Jon Skeet - that assumes the OP continues to buy blank DVDs for the stickers. The smart move would be to just buy additional stickers, or better yet - get el cheap perm-marker. – Franci Penov Jul 24 '10 at 8:22
Real programmers tape their first DVD a '0' sticker. – kennytm Jul 24 '10 at 8:23

## 6 Answers

Completely new solution. 6 bajillion times faster than first one.

time { python clean.py ; }
0: 0
1: 199990
2: 1999919999999980
3: 19999199999999919999999970
4: 199991999999999199999999919999999960
5: 1999919999999991999999999199999999919999999950
6: 19999199999999919999999991999999999199999999919999999940
7: 199991999999999199999999919999999991999999999199999999919999999930
8: 1999919999999991999999999199999999919999999991999999999199999999919999999920
9: 19999199999999919999999991999999999199999999919999999991999999999199999999919999999918

real    0m0.777s
user    0m0.772s
sys 0m0.004s

code:

cache = {}
def how_many_used(n):
if n in cache:
return cache[n]
result = 0
if int(n) >= 10:
if n[0] == '1':
result += int(n[1:]) + 1
result += how_many_used(str(int(n[1:])))
result += how_many_used(str(int(str(int(n[0])-1) + "9"*(len(n) - 1))))
else:
result += 1 if n >= '1' else 0
if n.endswith("9" * (len(n)-0)) or n.endswith("0" * (len(n)-1)):
cache[n] = result
return result

def how_many_have(i, stickers):
return int(i) * stickers

def end_state(i, stickers):
if i == '':
return 0
return how_many_have(i, stickers) - how_many_used(i)

cache2 = {}
def lowest_state(i, stickers):
if stickers <= 0:
return end_state(i, stickers)
if i in ('', '0'):
return 0
if (i, stickers) in cache2:
return cache2[(i, stickers)]

lowest_candidats = []

tail9 = '9' * (len(i)-1)
if i[0] == '1':
tail = str(int('0'+i[1:]))
lowest_candidats.append(end_state(str(10**(len(i) - 1)), stickers))
lowest_candidats.append(lowest_state(tail, stickers - 1) + end_state(str(10**(len(i) - 1)), stickers))
else:
tail = str(int(i[0])-1) + tail9
series = end_state(tail9, stickers)
if series < 0:
lowest_candidats.append(lowest_state(str(int('0'+i[1:])), stickers) + end_state(i[0] + '0'*(len(i)-1), stickers))
lowest_candidats.append(lowest_state(tail, stickers))
result =  min(lowest_candidats)
cache2[(i, stickers)] = result
return result

def solve(stickers):
i=1
while lowest_state(str(i), stickers) >= 0:
i *= 2

top = i
bottom = 0
center = 0

while top - bottom > 1:
center = (top + bottom) / 2
if lowest_state(str(center), stickers) >= 0:
bottom = center
else:
top = center

if lowest_state(str(top), stickers) >= 0:
return top
else:
return bottom

import sys
sys.setrecursionlimit(sys.getrecursionlimit() * 10)

for i in xrange(10):
print "%d: %d" % (i, solve(i))
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Can you please add a few words about the algorithm? What does "lowest_state" do? I'm also pretty sure there is a way to calculate how_many_used directly, without recursion, but the code is already blazing fast as it is... – Tal Weiss Jul 25 '10 at 18:20
lowest_state returns what was lowest supply of '1' stickers when we buy i DVDs with stickers stickers in each. In fact this number is always 0 or negative (because starting supply is 0, so lowest supply can't be higher) – Tomasz Wysocki Jul 25 '10 at 18:26

This is old solution, completely new 6 bajillion times faster solution is on the bottom.

Solution:

time { python solution.py; }
0: 0
1: 199990
2: 1999919999999980
3: 19999199999999919999999970
4: 199991999999999199999999919999999960
5: 1999919999999991999999999199999999919999999950
6: 19999199999999919999999991999999999199999999919999999940
7: 199991999999999199999999919999999991999999999199999999919999999930
8: 1999919999999991999999999199999999919999999991999999999199999999919999999920
9: 19999199999999919999999991999999999199999999919999999991999999999199999999919999999918

real    1m53.493s
user    1m53.183s
sys 0m0.036s

Code:

OPTIMIZE_1 = True # we assum that '1' will run out first (It's easy to prove anyway)

if OPTIMIZE_1:
NUMBERS = [1]
else:
NUMBERS = range(10)

def how_many_have(dight, n, stickers):
return stickers * n

cache = {}
def how_many_used(dight, n):
if (dight, n) in cache:
return cache[(dight,n)]
result = 0
if dight == "0":
if OPTIMIZE_1:
return 0
else:
assert(False)
#TODO
else:
if int(n) >= 10:
if n[0] == dight:
result += int(n[1:]) + 1
result += how_many_used(dight, str(int(n[1:])))
result += how_many_used(dight, str(int(str(int(n[0])-1) + "9"*(len(n) - 1))))
else:
result += 1 if n >= dight else 0
if n.endswith("9" * (len(n)-4)): # '4' constant was pick out based on preformence tests
cache[(dight, n)] = result
return result

def best_jump(i, stickers_left):
no_of_dights = len(str(i))
return max(1, min(
stickers_left / no_of_dights,
10 ** no_of_dights - i - 1,
))

def solve(stickers):
i = 0
stickers_left = 0
while stickers_left >= 0:
i += best_jump(i, stickers_left)

stickers_left = min(map(
lambda x: how_many_have(x, i, stickers) - how_many_used(str(x), str(i)),
NUMBERS
))
return i - 1

for stickers in range(10):
print '%d: %d' % (stickers, solve(stickers))

Prove that '1' will run out first:

def(number, position):
""" when number[position] is const, this function is injection """
if number[position] > "1":
return (position, number[:position]+"1"+number[position+1:])
else:
return (position, str(int(number[:position])-1)+"1"+number[position+1:])
-
And a beautiful pattern emerges +1! Very cool! Playing with it now. Can someone please explain the resulting pattern? Here is the logic, as I understand it: if you are at dvd # I (I being an N digit number), and you have S stickers in your leftovers stash, you can fast forward without checking the next S / N numbers (assuming there are that many N digit numbers left). This is the meaning of min( stickers_left / no_of_dights, 10 ** (no_of_dights + 1) - i - 1) – Tal Weiss Jul 24 '10 at 13:57
Less than 1 second to run on a very old desktop (for the requested 2 sticker version)! Less than 5 seconds to solve the 3 sticker version... – Tal Weiss Jul 24 '10 at 14:14
I'm happy to see that you are satisfied with this solution. – Tomasz Wysocki Jul 24 '10 at 14:20
There was bug in solution. It should be: min( stickers_left / no_of_dights, 10 ** no_of_dights - i - 1) I have fixed it (the results hasn't changed). – Tomasz Wysocki Jul 24 '10 at 14:30
The resulting pattern emerges once you understand that 1 runs out first. If you prefer, the problem can be stated like this: For which number n does the sum of 1 digits in [1-n] become greater than 2*n? @Tomasz: Absolutely awesome solution, by the way. – Michael Foukarakis Jul 24 '10 at 14:47

Here is proof that a solution exists:

Assuming you ever get to 21 digit numbers, you will start losing a sticker with every DVD you purchase and label ((+20) + (-21)).
It doesn't matter how many stickers you have accumulated until this point. From here on it is all downhill for your sticker stash and you will eventually run out.

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To those upvoting this post: This is by the OP himself. OP: Please put this information into your original post. – Noon Silk Jul 24 '10 at 12:16
@silky: Answering your own question is useful and encouraged, since it adds to the community knowledge base. – Daenyth Jul 24 '10 at 14:34
@Daenyth: sigh. I wish I didn't have to explain this, but: 1) I don't disagree, 2) The op new this information at the time of posting the question. – Noon Silk Jul 24 '10 at 15:09
@silky: I did know this info at the time of posting but felt it was part of the answer, sort of like a spoiler for the movie plot or a hint for a puzzle. It is not information needed to solve the question. I wouldn't have wanted other such posts to give hints as part of the question.... That said, if people disagree I will move it to the question. – Tal Weiss Jul 24 '10 at 18:13

here's a quick and dirty python script:

#!/bin/env python

disc = 0
stickers = {
0: 0, 1: 0,
2: 0, 3: 0,
4: 0, 5: 0,
6: 0, 7: 0,
8: 0, 9: 0 }

def buyDisc():
global disc
disc += 1
for k in stickers.keys():
stickers[k] += 1

def labelDisc():
lbl = str(disc)
for c in lbl:
if(stickers[int(c)] <= 0): return False;
stickers[int(c)] -= 1;
return True

while True:
buyDisc()
if not labelDisc(): break

print("No stickers left after " + str(disc) + " discs.")
print("Remaining stickers: " + str(stickers))

i don't know if it yields the correct result though. if you find logical errors, please comment

result with debug output:

Bought disc 199991. Labels:
Remaining stickers: {0: 111102, 1: 0, 2: 99992, 3: 99992, 4: 99992, 5: 99997, 6: 99992, 7: 99992, 8: 99992, 9: 100024}
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MPAA will send their goons to your house before you buy even half that number. :-) – Franci Penov Jul 24 '10 at 8:37
Seems to work correctly, but you are adding only 1 sticker of each 0-9 every round. Adding 2 would answer the original question, but not likely to stop any time soon... – Jari Jul 24 '10 at 8:38
@ jari, hm, yeah. you are right, missed that … – knittl Jul 24 '10 at 8:40
@jari: adding +2 in every round lets the number of stickers grow and grow and grow. no end in sight (only after integer overflow :D) – knittl Jul 24 '10 at 8:45
Guys, read the question label: brute force not likely to work for ya... – Tal Weiss Jul 24 '10 at 8:58

The results for any base N and number of stickers per digit per DVD "S" are:

N\S ]      1 |        2 |          3 |         4 |    5 |        S?
===================================================================
2 ]      2 |       14 |         62 |       254 | 1022 |   4^S - 2
----+--------+----------+------------+-----------+------+----------
3 ]     12 |      363 |       9840 |    265719 |     (27^S - 3)/2
----+--------+----------+------------+-----------+-----------------
4 ]     28 |     7672 |    1965558 | 503184885 |
----+--------+----------+------------+-----------+
5 ]    181 |   571865 | 1787099985 |
----+--------+----------+------------+
6 ]    426 | 19968756 |
----+--------+----------+
7 ]   3930 | (≥ 2^31) |
----+--------+----------+
8 ]   8184 |
----+--------+
9 ] 102780 |
----+--------+
10 ] 199990 |
----+--------+

I can't see any patterns.

Alternatively, if the sticker starts from 0 instead of 1,

N\S ]       1 |        2 |          3 |         4 |    5 |          S?
======================================================================
2 ]       4 |       20 |         84 |       340 | 1364 | (4^S-1)*4/3
----+---------+----------+------------+-----------+------+------------
3 ]      12 |      363 |       9840 |    265719 |       (27^S - 3)/2
----+---------+----------+------------+-----------+-------------------
4 ]      84 |     7764 |    1965652 | 503184980 |
----+---------+----------+------------+-----------+
5 ]     182 |   571875 | 1787100182 |
----+---------+----------+------------+
6 ]    1728 | 19970496 |
----+---------+----------+
7 ]    3931 | (≥ 2^31) |
----+---------+----------+
8 ]   49152 |
----+---------+
9 ]  102789 |
----+---------+
10 ] 1600000 |
----+---------+

Let's assume that it's the “1” sticker running out first — which is indeed the case for most other computed info.

Suppose we are in base N and there will be S new stickers per digit per DVD.

At DVD #X, there will be totally X×S “1” stickers, used or not.

The number of “1” stickers used is just the number of “1” in the digits from 1 to X in base N expansion.

Thus we just need to find the cross-over point of X×S and the total “1” digit count.

there does not seem to be a closed for all these sequences, so a loop proportional X iterations is necessary. The digits can be extracted in log X time, so in principle the algorithm can finish in O(X log X) time.

This is no better than the other algorithm but at least a lot computations can be removed. A sample C code:

#include <stdio.h>

static inline int ones_in_digit(int X, int N) {
int res = 0;
while (X) {
if (X % N == 1)
++ res;
X /= N;
}
return res;
}

int main() {
int N, S, X;

printf("Base N?   ");
scanf("%d", &N);
printf("Stickers? ");
scanf("%d", &S);

int count_of_1 = 0;
X = 0;
do {
++ X;
count_of_1 += S - ones_in_digit(X, N);
if (X % 10000000 == 0)
printf("%d -> %d\n", X/10000000, count_of_1);
} while (count_of_1 >= 0);
printf("%d\n", X-1);
return 0;
}
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4^S and 27^S and …. maybe it's (S^S)^S? – knittl Jul 24 '10 at 10:40
@knittl: Won't work for N>3 though. – kennytm Jul 24 '10 at 10:44

Here's some thoughts on the upper bound demonstrated by @Tal Weiss:

The first 21-digit number is 10^20, at which point we will have at most 20 * 10^20 stickers. Each subsequent DVD will then cost us at least 1 net sticker, so we will definitely have run out by 10^20 + 20 * 10^20, which equals 21 * 10^20. This is therefore an upper bound on the solution. (Not a particularly tight upper bound by any means! But one that's easy to establish).

Generalising the above result to base b:

• each DVD comes with 2b stickers
• the first DVD that costs us 1 net sticker is number b ^ (2b), at which point we will have at most 2b . b ^ (2b) stickers
• so we will definitely run out by b ^ (2b) + 2b . [b ^ (2b)], which equals (2b + 1)[b ^ (2b)]

So for example if we work in base 3, this calculation gives an upper bound of 5103; in base 4, it is 589824. These are numbers it is going to be far easier to brute-force / mathematically solve with.

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