Using a small priority queue, with one entry per power, is a reasonable way to list the numbers. See following python code.

```
import Queue # in Python 3 say: queue
pmax, vmax = 10, 150
Q=Queue.PriorityQueue(pmax)
p = 2
for e in range(2,pmax):
p *= 2
Q.put((p,2,e))
print 1,1,2
while not Q.empty():
(v, b, e) = Q.get()
if v < vmax:
print v, b, e
b += 1
Q.put((b**e, b, e))
```

With pmax, vmax as in the code above, it produces the following output. For the proposed problem, replace `pmax`

and `vmax`

with `64`

and `2**64`

.

```
1 1 2
4 2 2
8 2 3
9 3 2
16 2 4
16 4 2
25 5 2
27 3 3
32 2 5
36 6 2
49 7 2
64 2 6
64 4 3
64 8 2
81 3 4
81 9 2
100 10 2
121 11 2
125 5 3
128 2 7
144 12 2
```

The complexity of this method is O(vmax^0.5 * log(pmax)). This is because the number of perfect squares is dominant over the number of perfect cubes, fourth powers, etc., and for each square we do O(log(pmax)) work for `get`

and `put`

queue operations. For higher powers, we do O(log(pmax)) work when computing `b**e`

.

When `vmax,pmax =64, 2**64`

, there will be about 2*(2^32 + 2^21 + 2^16 + 2^12 + ...) queue operations, ie about 2^33 queue ops.

*Added note:* This note addresses cf16's comment, “one remark only, I don't think "the number of perfect squares is dominant over the number of perfect cubes, fourth powers, etc." they all are infinite. but yes, if we consider finite set”. It is true that in the overall mathematical scheme of things, the cardinalities are the same. That is, if `P(j)`

is the set of all `j`

'th powers of integers, then the cardinality of `P(j) == P(k)`

for all integers `j,k > 0`

. Elements of any two sets of powers can be put into 1-1 correspondence with each other.

Nevertheless, when computing perfect powers *in ascending order*, no matter how many are computed, finite or not, the work of delivering squares dominates that for any other power. For any given *x*, the density of perfect *k*^{th} powers in the region of *x* declines exponentially as *k* increases. As *x* increases, the density of perfect *k*^{th} powers in the region of *x* is proportional to (*x*^{1/k})/*x*, hence third powers, fourth powers, etc become vanishingly rare compared to squares as *x* increases.

As a concrete example, among perfect powers between 1e8 and 1e9 the number of (2; 3; 4; 5; 6)th powers is about (21622; 535; 77; 24; 10). There are more than 30 times as many squares between 1e8 and 1e9 than there are instances of any higher powers than squares. Here are ratios of the number of perfect squares between two numbers, vs the number of higher perfect powers: 10¹⁰–10¹⁵, r≈301; 10¹⁵–10²⁰, r≈2K; 10²⁰–10²⁵, r≈15K; 10²⁵–10³⁰, r≈100K. In short, as *x* increases, squares dominate more and more when perfect powers are delivered in ascending order.