It is not clear what you are asking, but I will try to guess.

We first solve the equation `z^z = a`

for a real number `z`

. Let `u`

and `v`

be `z`

rounded down and up, respectively. Among the three candidates `(u,u)`

, `(v,u)`

, `(u,v)`

we choose the largest one that does not exceed `a`

.

Example: Consder the case `a = 2000`

. We solve `z^z = 2000`

by numerical methods (see below) to get an approximate solution `z = 4.8278228255818725`

. We round down an up to obtain `u = 4`

and `v = 5`

. We now have three candidates, `4^4 = 256`

, `4^5 = 1023`

and `5^4 = 625`

. They are all smaller than `2000`

, so we take the one that gives the largest answer, which is `x = 4`

, `y = 5`

.

Here is Python code. The function `solve_approx`

does what you want. It works well for `a >= 3`

. I am sure you can cope with the cases `a = 1`

and `a = 2`

by yourself.

```
import math
def solve(a):
""""Solve the equation x^x = a using Newton's method"""
x = math.log(a) / math.log(math.log(a)) # Initial estimate
while abs (x ** x - a) > 0.1:
x = x - (x ** x - a) / (x ** x * (1 + math.log(x)))
return x
def solve_approx(a):
""""Find two integer numbers x and y such that x^y is smaller than
a but as close to it as possible, and try to make x and y as equal
as possible."""
# First we solve exactly to find z such that z^z = a
z = solve(a)
# We round z up and down
u = math.floor(z)
v = math.ceil(z)
# We now have three possible candidates to choose from:
# u ** zdwon, v ** u, u ** v
candidates = [(u, u), (v, u), (u, v)]
# We filter out those that are too big:
candidates = [(x,y) for (x,y) in candidates if x ** y <= a]
# And we select the one that gives the largest result
candidates.sort(key=(lambda key: key[0] ** key[1]))
return candidates[-1]
```

Here is a little demo:

```
>>> solve_approx(5)
solve_approx(5)
(2, 2)
>>> solve_approx(100)
solve_approx(100)
(3, 4)
>>> solve_approx(200)
solve_approx(200)
(3, 4)
>>> solve_approx(1000)
solve_approx(1000)
(5, 4)
>>> solve_approx(1000000)
solve_approx(1000000)
(7, 7)
```