You can try to do it using dynamic programming.

Let `dp[k]`

be equal to a list of items, with the sum of size equal to `k`

. Initially `d[0] = []`

and `dp[k] = None`

for `k > 0`

. The size of the list may be bounded by the sum of sizes of all elements, let's call it `S`

.

What the algorithm does is for each `item`

it goes from `i = S`

down to `i = 0`

and it checks if `dp[i] != None`

, which means we know we are able to select items with sum of sizes equal to `i`

. These items are on the list `dp[i]`

. Let's observe that we can add the current `item`

to that list and have a set of items with sum equal to `i + item.size`

. So we assign `dp[i + item.size] = dp[i] + [item]`

. Having processed all items we just have to start at the desired sum of sizes and go both directions to find the closest match.

Code:

```
items = [("ITEM01", 100, 10000), ("ITEM02", 24, 576), \
("ITEM03", 24, 576), ("ITEM04", 51, 2500), ("ITEM05", 155, 25)]
S = sum([item[1] for item in items])
dp = [None for i in xrange(S + 1)]
dp[0] = []
for item in items:
for i in xrange(S, -1, -1):
if dp[i] is not None and i + item[1] <= S:
dp[i + item[1]] = dp[i] + [item]
desired_sum = 150
i = j = desired_sum
while i >= 0 and j <= S:
if dp[i] is not None:
print dp[i]
break
elif dp[j] is not None:
print dp[j]
break
else:
i -= 1
j += 1
```

output:

```
[('ITEM01', 100, 10000), ('ITEM04', 51, 2500)]
```

However the complexity of this solution is `O(n*S)`

where `n`

is the number of items and `S`

is the sum of sizes, so it may be too slow for some purposes. What can be improved in this solution is the `S`

constant. For example you can set `S`

to `2 * desired_sum`

because we have guarantee that we can take a set of items with sum of sizes in `[0, 2 * desired_sum]`

(possibly an empty set with sum `0`

). If you want to take at least one item you can take `S = max(min_item_size, 2 * desired_sum - min_item_size)`

where `min_item_size`

is the minimum of sizes of all items.

**EDIT**:

Oh, you also wanted get maximise value when two combinations are equally close to `desired_size`

. Then you have to alternate the code a bit to keep the best combinations for each sum of sizes.

Namely:

```
if dp[i] is not None and i + item[1] <= S:
```

should be:

```
if dp[i] is not None and i + item[1] <= S and \
(
dp[i + item[1]] is None
or
sum(set_item[2] for set_item in dp[i]) + item[2]
> sum(set_item[2] for set_item in dp[i + item[1]])
):
```

(a bit ugly, but I don't know how to break lines to make it look better)

Of course you can keep these sums to avoid calculating them each time.