# Help me finish the last part of my app? It solves any Countdown Numbers game on Channel 4 by brute forcing every possibly equation

For those not familiar with the game. You're given 8 numbers and you have to reach the target by using +, -, / and *.

So if the target is 254 and your game numbers are 2, 50, 5, 2, 1, you would answer the question correctly by saying 5 * 50 = 250. Then 2+2 is four. Add that on aswell to get 254.

Some videos of the game are here:

Basically I brute force the game using by generating all perms of all sizes for the numbers and all perms of the symbols and use a basic inflix calculator to calculate the solution.

However it contains a flaw because all the solutions are solved as following: ((((1+1)*2)*3)*4). It doesn't permutate the brackets and it's causing my a headache.

Therefore I cannot solve every equation. For example, given

A target of 16 and the numbers 1,1,1,1,1,1,1,1 it fails when it should do (1+1+1+1)*(1+1+1+1)=16.

I'd love it in someone could help finish this...in any language.

This is what I've written so far:

`````` #!/usr/bin/env perl

use strict;
use warnings;

use Algorithm::Permute;

# GAME PARAMETERS TO FILL IN
my \$target = 751;
my @numbers = ( '2', '4', '7', '9', '1', '6', '50', '25' );

my \$num_numbers = scalar(@numbers);

my @symbols = ();

foreach my \$n (@numbers) {
push(@symbols, ('+', '-', '/', '*'));
}

my \$num_symbols = scalar(@symbols);

print "Symbol table: " . join(", ", @symbols);

my \$lst = [];
my \$symb_lst = [];

my \$perms = '';
my @perm = ();

my \$symb_perms = '';
my @symb_perm;

my \$print_mark = 0;
my \$progress = 0;
my \$total_perms = 0;

my @closest_numbers;
my @closest_symb;
my \$distance = 999999;

sub calculate {
my @oprms = @{ \$_[0] };
my @ooperators = @{ \$_[1] };

my @prms = @oprms;
my @operators = @ooperators;

#print "PERMS: " . join(", ", @prms) . ", OPERATORS: " . join(", ", @operators);

my \$total = pop(@prms);

foreach my \$operator (@operators) {
my \$x = pop(@prms);

if (\$operator eq '+') {
\$total += \$x;
}
if (\$operator eq '-') {
\$total -= \$x;
}
if (\$operator eq '*') {
\$total *= \$x;
}
if (\$operator eq '/') {
\$total /= \$x;
}
}
#print "Total: \$total\n";

if (\$total == \$target) {
#print "ABLE TO ACCURATELY SOLVE WITH THIS ALGORITHM:\n";
#print "PERMS: " . join(", ", @oprms) . ", OPERATORS: " . join(", ", @ooperators) . ", TOTAL=\$total\n";
sum_print(\@oprms, \@ooperators, \$total, 0);
exit(0);
}

my \$own_distance = (\$target - \$total);
if (\$own_distance < 0) {
\$own_distance *= -1;
}

if (\$own_distance < \$distance) {
#print "found a new solution - only \$own_distance from target \$target\n";
#print "PERMS: " . join(", ", @oprms) . ", OPERATORS: " . join(", ", @ooperators) . ", TOTAL=\$total\n";
sum_print(\@oprms, \@ooperators, \$total, \$own_distance);
@closest_numbers = @oprms;
@closest_symb = @ooperators;
\$distance = \$own_distance;
}

\$progress++;
if ((\$progress % \$print_mark) == 0) {
print "Tested \$progress permutations. " . ((\$progress / \$total_perms) * 100) . "%\n";
}
}

sub factorial {
my \$f = shift;
\$f == 0 ? 1 : \$f*factorial(\$f-1);
}

sub sum_print {
my @prms = @{ \$_[0] };
my @operators = @{ \$_[1] };
my \$total = \$_[2];
my \$distance = \$_[3];
my \$tmp = '';

my \$op_len = scalar(@operators);

print "BEST SOLUTION SO FAR: ";
for (my \$x = 0; \$x < \$op_len; \$x++) {
print "(";
}

\$tmp = pop(@prms);
print "\$tmp";

foreach my \$operator (@operators) {
\$tmp = pop(@prms);
print " \$operator \$tmp)";
}

if (\$distance == 0) {
print " = \$total\n";
}
else {
print " = \$total (distance from target \$target is \$distance)\n";
}
}

# look for straight match
foreach my \$number (@numbers) {
if (\$number == \$target) {
print "matched!\n";
}
}

for (my \$x = 1; \$x < ((\$num_numbers*2)-1); \$x++) {
\$total_perms += factorial(\$x);
}

print "Total number of permutations: \$total_perms\n";
\$print_mark = \$total_perms / 100;
if (\$print_mark == 0) {
\$print_mark = \$total_perms;
}

for (my \$num_size=2; \$num_size <= \$num_numbers; \$num_size++) {
\$lst = \@numbers;
\$perms = new Algorithm::Permute(\$lst, \$num_size);

print "Perms of size: \$num_size.\n";

# print matching symb permutations
\$symb_lst = \@symbols;
\$symb_perms = new Algorithm::Permute(\$symb_lst, \$num_size-1);

while (@perm = \$perms->next) {
while (@symb_perm = \$symb_perms->next) {
calculate(\@perm, \@symb_perm);
}

\$symb_perms = new Algorithm::Permute(\$symb_lst, \$num_size-1);
}
}

print "exhausted solutions";
print "CLOSEST I CAN GET: \$distance\n";
sum_print(\@closest_numbers, \@closest_symb, \$target-\$distance, \$distance);
exit(0);
``````

Here is the example output:

``````[15:53: /mnt/mydocuments/git_working_dir/countdown_solver\$] perl countdown_solver.pl
Symbol table: +, -, /, *, +, -, /, *, +, -, /, *, +, -, /, *, +, -, /, *, +, -, /, *, +, -, /, *, +, -, /, *Total number of permutations: 93928268313
Perms of size: 2.
BEST SOLUTION SO FAR: (2 + 4) = 6 (distance from target 751 is 745)
BEST SOLUTION SO FAR: (2 * 4) = 8 (distance from target 751 is 743)
BEST SOLUTION SO FAR: (4 + 7) = 11 (distance from target 751 is 740)
BEST SOLUTION SO FAR: (4 * 7) = 28 (distance from target 751 is 723)
BEST SOLUTION SO FAR: (4 * 9) = 36 (distance from target 751 is 715)
BEST SOLUTION SO FAR: (7 * 9) = 63 (distance from target 751 is 688)
BEST SOLUTION SO FAR: (4 * 50) = 200 (distance from target 751 is 551)
BEST SOLUTION SO FAR: (7 * 50) = 350 (distance from target 751 is 401)
BEST SOLUTION SO FAR: (9 * 50) = 450 (distance from target 751 is 301)
Perms of size: 3.
BEST SOLUTION SO FAR: ((4 + 7) * 50) = 550 (distance from target 751 is 201)
BEST SOLUTION SO FAR: ((2 * 7) * 50) = 700 (distance from target 751 is 51)
BEST SOLUTION SO FAR: ((7 + 9) * 50) = 800 (distance from target 751 is 49)
BEST SOLUTION SO FAR: ((9 + 6) * 50) = 750 (distance from target 751 is 1)
Perms of size: 4.
BEST SOLUTION SO FAR: (((9 + 6) * 50) + 1) = 751
``````
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You don't want permutations; you need to create every possible binary tree with the given numbers as leaves and then assign operators to the nodes until you find an answer. –  jwodder May 9 '11 at 15:16
Forget brackets, use reverse Polish notation: 2 3 + 4 2 - * –  Dallaylaen May 9 '11 at 15:52
Seems to me that you could work backwards from the target. Subtract game number integers from and divide other integers into the target until you have a list of factors that match your game numbers. –  Gilbert Le Blanc May 9 '11 at 15:56

Here is Java applet (source) and Javascript version.

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The suggestion to use reverse polish notation is excellent.

If you have N=5 numbers, the template is

``````{num} {num} {ops} {num} {ops} {num} {ops} {num} {ops}
``````

There can be zero to N ops in any spot, although the total number will be N-1. You just have to try different placements of numbers and ops.

The `(((1+1)+1)+1)*(((1+1)+1)+1)=16` solution will be found when you try

``````1 1 + 1 + 1 + 1 1 + 1 + 1 + *
``````

Update: Maybe not so good, since finding the above could take 433,701,273,600 tries. The number was obtained using the following:

``````use strict;
use warnings;

{
my %cache = ( 0 => 1 );
sub fact { my (\$n) = @_; \$cache{\$n} ||= fact(\$n-1) * \$n }
}

{
my %cache;
sub C {
my (\$n,\$r) = @_;
return \$cache{"\$n,\$r"} ||= do {
my \$i = \$n;
my \$j = \$n-\$r;
my \$c = 1;
\$c *= \$i--/\$j-- while \$j;
\$c
};
}
}

my @nums = (1,1,1,1,1,1,1,1);

my \$Nn = 0+@nums;  # Number of numbers.
my \$No = \$Nn-1;    # Number of operators.

my \$max_tries = do {
my \$num_orderings = fact(\$Nn);
{
my %counts;
++\$counts{\$_} for @nums;
\$num_orderings /= fact(\$_) for values(%counts);
}

my \$op_orderings = 4 ** \$No;

my \$op_placements = 1;
\$op_placements *= C(\$No, \$_) for 1..\$No-1;

\$num_orderings * \$op_orderings * \$op_placements
};

printf "At most %.f tries needed\n", \$max_tries;
``````
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