You can use `uniroot`

to find roots of *any* 1D equations within a given range. However, getting multiple roots seems like a very hard problem in general (e.g. see the relevant chapter of *Numerical Recipes* for some background: chapter 9 at http://apps.nrbook.com/c/index.html ). Which root is found when there are multiple roots is hard to predict. *If* you know enough about the problem to subdivide the space into subregions with zero or one roots, or if you're willing to divide it into lots of regions and hope that you found all the roots, you can do it. Otherwise I look forward to other peoples' solutions ...

In this particular case, as shown by @liuminzhao's solution, there's (at most? exactly?) one solution between `n*pi`

and `(n+1)*pi`

```
y = function(x) x-1/tan(x)
curve(y,xlim=c(-10,10),n=501,ylim=c(-5,5))
abline(v=(-3:3)*pi,col="gray")
abline(h=0,col=2)
```

This is a bit of a hack, but it will find roots of your equation (provided they are not too close to a multiple of pi: you can reduce `eps`

if you like ...). However, if you want to solve a *different* multi-root transcendental equation you might need another (specialized) strategy ...

```
f <- function(n,eps=1e-6) uniroot(y,c(n*pi+eps,(n+1)*pi-eps))$root
sapply(0:3,f)
## [1] 0.8603337 3.4256204 6.4372755 9.5293334
```