The polynomials in the numerator and denominator can be factorised by inspection: \[\begin{aligned} x^2+x-20 &= \left(x-4\right)\,\left(x+5\right)\\[0.25cm] x^2+4\,x-5 &= \left(x-1\right)\,\left(x+5\right)\end{aligned}\] So: \[\begin{aligned} \frac{x^2+x-20}{x^2+4\,x-5} &= \frac{\left(x-4\right)\,\left(x+5\right)}{\left(x-1\right)\,\left(x+5\right)}\\[0.25cm] &= {{x-4}\over{x-1}}\end{aligned}\] Because the leading coefficient of the denominator in the previous expression is equal to \(1\), we have indeed obtained the normal form.

\(\phantom{abc}\)

Of course, instead of factorisation, we could have found the greatest common divisor of the numerator and denominator, and then divided both the numerator and denominator by this:

\[\begin{aligned} \mathrm{gcd}(x^2+x-20,x^2+4\,x-5) &= \mathrm{gcd}(x^2+4\,x-5,-3\,x-15)\\[0.1cm] {\small \blue{\text{because }x^2+x-20}} &\;{\small \blue{= (x^2+4\,x-5) -3\,x-15}}\\[0.4cm] &= \mathrm{gcd}(-3\,x-15,0)\\[0.1cm] {\small \blue{\text{because }x^2+4\,x-5}} &\;{\small \blue{= -{{x-1}\over{3}}\cdot (-3\,x-15) + 0}}\\[0.4cm] &= x+5\\[0.1cm] {\small \blue{\text{gcd (with leading coefficient 1)}}}& {\small \blue{\text{ read off from the previous result}}}\end{aligned}\] From \[\frac{x^2+x-20}{x+5}=x-4\quad\text{and}\quad \frac{x^2+4\,x-5}{x+5}=x-1\] follows that \[\frac{x^2+x-20}{x^2+4\,x-5}={{x-4}\over{x-1}}\]