Improving on my previous answer, here is a version that works to test any number of entries, up to a maximum number.
UPDATE: (Optimization added; see comments below)
For example, if the desired value is 15
, and the list is (1, 17, 20)
, the best choice is 1+1+1+1+1+1+1+1+1+1+1+1+1+1+1
, so you would have to allow $max_loops
, below, to be at least 15
in order to find this match - even though there are only 3 values in the list! It's worse for (1, 133, 138)
where the desired value is, say, 130
. In that case, you need 130 recursions! You can see that this is could be an optimization nightmare. But, the below algorithm works and is fairly well optimized.
<?php
echo "<html><head><title>Test Array Sums</title></head><body>";
$testarray = array(1, 3, 6);
$target_value = 10;
$current_closest_sum = 0;
$current_closest_difference = 0;
$first_time_in_loop = TRUE;
$max_loops = 10;
$current_loop = 0;
$best_set = array();
$current_set = array();
$sums_already_evaluated = array();
function nestedLoop($current_test = 0)
{
global $testarray, $target_value, $current_closest_sum, $current_closest_difference, $first_time_in_loop, $max_loops, $current_loop, $best_set, $current_set, $sums_already_evaluated;
++$current_loop;
foreach ($testarray AS $entry)
{
$current_set_temp = $current_set;
$current_set[] = $entry;
if ($first_time_in_loop)
{
$first_time_in_loop = FALSE;
$current_closest_sum = $entry + $current_test;
$current_closest_difference = abs($target_value - $current_closest_sum);
$best_set[] = $entry;
}
$test_sum = $entry + $current_test;
if (in_array($test_sum, $sums_already_evaluated))
{
// no need to test a sum that has already been tested
$current_set = $current_set_temp;
continue;
}
$sums_already_evaluated[] = $test_sum;
if ($test_sum > $target_value && $current_closest_sum > $target_value && $test_sum >= $current_closest_sum)
{
// No need to evaluate a sum that is certainly worse even by itself
$current_set = $current_set_temp;
continue;
}
$set_best = FALSE;
if (abs($test_sum - $target_value) < $current_closest_difference)
{
if ($test_sum - $target_value >= 0)
{
// Definitely the best so far
$set_best = TRUE;
}
else if ($current_closest_sum - $target_value < 0)
{
// The sum isn't big enough, but neither was the previous best option
// and at least this is closer
$set_best = TRUE;
}
}
else
{
if ($current_closest_sum - $target_value < 0 && $test_sum - $target_value >= 0)
{
// $test_value is farther away from the target than the previous best option,
// but at least it's bigger than the target value (the previous best option wasn't)
$set_best = TRUE;
}
}
if ($set_best)
{
$current_closest_sum = $test_sum;
$current_closest_difference = abs($current_closest_sum - $target_value);
$best_set = $current_set;
}
if ($current_loop < $max_loops)
{
if ($test_sum - $target_value < 0)
{
nestedLoop($test_sum);
}
}
$current_set = $current_set_temp;
}
--$current_loop;
}
// make array unique
$testarray = array_unique($testarray);
rsort($testarray, SORT_NUMERIC);
// Enter the recursion
nestedLoop();
echo "Best set: ";
foreach ($best_set AS $best_set_entry)
{
echo $best_set_entry . " ";
}
echo "<br />";
echo "</body></html>";
?>
UPDATE: I have added two small optimizations that seem to help greatly, and avoid the memory overload or hash-table lookup. They are:
(1) Track all previously evaluated sums, and do not evaluate them again.
(2) If a sum is (by itself) already worse than a previous test, skip any further tests with that sum.
I think, with these two optimizations, the algorithm may work quite well for realistic use in your situation.
PREVIOUS COMMENTS BELOW, NOW SOMEWHAT IRRELEVANT
My previous comments, below, are somewhat moot because the above two optimizations do seem to work quite well. But I include the comments anyways.
Unfortunately, as noted, the above loop is HIGHLY non-optimized. It would have to be optimized in order to work in a realistic situation, by avoiding duplicate tests (and other optimizations). However, it demonstrates an algorithm that works.
Note that this is a complex area mathematically. Various optimizations might help in one scenario, but not another. Therefore, to make the above algorithm work efficiently, you would need to discuss realistic usage scenarios - Will there be a limit on the largest length in the list of parts? What is the range of lengths? And other, more subtle features of the parts list & desired goal, though subtle, are likely to make a big difference in how to go about optimizing the algorithm.
This is a case where the "theoretical" problem isn't sufficient to yield a desired solution, since optimization is so critically important. Therefore, it's not particularly useful to make optimization suggestions.
Leonard's optimization, for example, (avoiding duplicates by saving all combinations previously tested) works well for a small-ish set, but the memory usage would explode for larger sets (as he noted). It's not a simple problem.
(code edited ~2 hours later to handle possible missed combination due to limiting the recursion to a certain number of recursions - by sorting the array from high to low, initially)