The trick is to store additional information that will allow you to reconstruct the choices made at each step, while filling-up the dynamic programming table. Sometimes, the table itself contains such information. For instance, in the 0/1 knapsack problem, here's how you can find out the items used to reach the optimal solution (notice that only the table is needed):

```
# 0/1 knapsack. O(nC) time, O(nC) space,
# also returns the index of the items to pick
# V: values, W: weights, C: capacity
def integral_knapsack_items(V, W, C):
table = integral_knapsack_table(V, W, C)
i, j, items = len(W), C, []
while i != 0 and j != 0:
if table[i][j] != table[i-1][j]:
items.append(i-1)
i, j = i-1, j-W[i-1]
else:
i -= 1
return (table[-1][-1], items)
def integral_knapsack_table(V, W, C):
m, n = len(W)+1, C+1
table = [[0] * n for x in xrange(m)]
for i in xrange(1, m):
for j in xrange(1, n):
if W[i-1] > j:
table[i][j] = table[i-1][j]
else:
table[i][j] = max(table[i-1][j],
V[i-1] + table[i-1][j-W[i-1]])
return table
```

In the above code, you call integral_knapsack_items() with V (an array of values), W (an array of corresponding weights) and C (the capacity of the knapsack), and the procedure returns a tuple with the maximum value obtained while filling the knapsack, and the indexes of the items used to reach that value.