This would put `NULL`

s into `inverses`

for the singular matrices:

```
inverses[[count]] <- tryCatch(solve(x), error=function(e) NULL)
```

If the first expression in a call to `tryCatch`

raises an error, it executes and returns the value of the function supplied to its `error`

argument. The function supplied to the `error`

arg has to take the error itself as an argument (here I call it `e`

), but you don't have to do anything with it.

You could then drop the `NULL`

entries with `inverses[! is.null(inverses)]`

.

Alternatively, you could use the lower level `try`

. The choice is really a matter of taste.

```
count <- 0
repeat {
if (count == 100) break
count <- count + 1
x <- matrix(sample(0:2, 4, replace = T), 2, 2)
x.inv <- try(solve(x), silent=TRUE)
if ('try-error' %in% class(x.inv)) next
else inverses[[count]] <- x.inv
}
```

If your expression generates an error, `try`

returns an object with class `try-error`

. It will print the message to screen if `silent=FALSE`

. In this case, if `x.inv`

has class `try-error`

, we call `next`

to stop the execution of the current iteration and move to the next one, otherwise we add `x.inv`

to `inverses`

.

## Edit:

You could avoid using the `repeat`

loop with `replicate`

and `lapply`

.

```
matrices <- replicate(100, matrix(sample(0:2, 4, replace=T), 2, 2), simplify=FALSE)
inverses <- lapply(matrices, function(mat) if (det(mat) != 0) solve(mat))
```

It's interesting to note that the second argument to `replicate`

is treated as an `expression`

, meaning it gets executed afresh for each replicate. This means you can use `replicate`

to make a `list`

of any number of random objects that are generated from the same expression.