I've just ACed this problem.

I don't know what exactly your "dp solution" is, but apparently this problem lies in the category of knapsack (still a DP problem). And according to the problem description, it's generally a 0/1 knapsack problem. Therefore an equation like below is enough for the problem, where `opt[i]`

denotes the maximum value that can be achieved for a backpack whose total volume is i.

```
opt[i] = max(opt[i], opt[i - items[j].vol] + items[j].value)
```

What makes this problem special is that each main item could have 0, 1, or 2 items attached to it. Say we have a main item `M`

, and its two attachments `A1`

and `A2`

. Instead of considering `M, A1, A2`

separately, we can imagine that there are 4 items bundled by them:

`B1`

, which is indeed `M`

itself. Therefore `B1.volume = M.volume`

and `B1.value = M.volume * M.c`

.
`B2`

, is bundled by `M`

and `A1`

. `B1.volume = M.volume + A1.volume`

and `B1.value = M.volume * M.c + A1.volume * A1.c`

`B3`

, is similar to `B2`

, but replace `A1`

with `A2`

.
`B4`

consists of `M, A1,`

and `A2`

. `B4.volume = M.volume + A1.volume + A2.volume`

and `B4.value = M.volume * M.c + A1.volume * A1.c + A2.volume * A2.c`

By doing the operations above, we can translate all items into bundles and we can perform 0/1 knapsack using these bundles.

Last but not least, note that for bundles generated by a same `M`

, ONLY ONE of `B1, B2, B3,`

and `B4`

can be chosen. This may require a little bit of hacks, but shouldn't be complicated. :)