It looks like a modification to knapsack would solve it.

Let's say we have N items, maximum knapscak weight is W, and max amount of fragile items is F

let's define our dp table as 3-dimensional array dp[N+1][W+1][F+1]

Now dp[n][w][f] stores maximum value we can get if we fill knapsack with some subset of items from first
n items, having weight of exacly w and having exacly f fragile items.

frop dp[n][w][f] we can move to states:

- dp[n+1][w][f] if we skip n+1 th item
- dp[n+1][w + weight(n+1)][f + isFragile(n+1)] if we take n+1 th item

so pseudocde:

```
dp[N+1][W+1][F+1] // memo table, initially filled with -1
int solve(n,w,f)
{
if(n > N)return 0;
if(dp[n][w][f] != -1) return dp[n][w][f];
dp[n][w][f] = solve(n+1,w,f); //skip item
if(w + weight(n) <= W && f + isFragile(n) <=F)
dp[n][w][f] = max(dp[n][w][f], value(n) + solve(n+1, w + weight(n), f + isFragile(n)));
return dp[n][w][f]
}
print(solve(1,0,0))
```

Getting the actual subset is also not difficult:

```
vector<int> getSolution(n,w,f)
{
int optimalValue = solve(n,w,f);
vector<int>answer; //just some dynamic array / arrayList
while(n <= N)
{
if(solve(n+1,w,f) == optimalValue)n++; //if after skipping item we can still get optimal answer we just skip it
else //otherwise we cant so current item must be taken
{
int new_w = w + weight(n);
int new_f = f + isFragile(n);
answer.push_back(n); //so we just save its index, and update all values
optimalValue -= value(n);
n++;
w = new_w;
f = new_f;
}
}
return answer;
}
```