What you need is called the **Lambert W function** and evaluate it for *p*.

The Lambert W function solves the following equation:

*p = xe*^{x}

Taking the logarithm on both sides gives us:

*ln(p) = ln(x*e*^{x})

Logarithmic laws for a product gives us the sum of the logarithms:

*ln(p) = ln(x) + ln(e*^{x})

Applying the definition of the natural logarithm gives your formula:

*ln(p) = ln(x) + x*

Thus, you **need to evaluate** *W(p)* to get your *x*.

## Approximation

**According to Wikipedia**:

## Implementation

You can find an implementation in the **GNU Scientific Library**:

```
gsl_sf_lambert_W0(p);
```

Or in Python from an **ActiveState recipe** which uses Newton's method as described by Wikipedia.

```
# http://en.wikipedia.org/wiki/Lambert_W_function
# FB - 201105297
import math
eps = 0.00000001 # max error allowed
def w0(x): # Lambert W function using Newton's method
w = x
while True:
ew = math.exp(w)
wNew = w - (w * ew - x) / (w * ew + ew)
if abs(w - wNew) <= eps: break
w = wNew
return w
# Usage
print w0(p)
```