block011_write-your-own-function-01.rmd

---
title: "Write your own R functions, part 1"
output:
  html_document:
    toc: true
    toc_depth: 3
---

```{r setup, include = FALSE, cache = FALSE}
knitr::opts_chunk$set(error = TRUE, collapse = TRUE)
```

### What and why?

My goal here is to reveal the __process__ a long-time useR employs for writing functions. I also want to illustrate why the process is the way it is. Merely looking at the finished product, e.g. source code for R packages, can be extremely deceiving. Reality is generally much uglier ... but more interesting!

Why are we covering this now, smack in the middle of data aggregation? Powerful machines like `dplyr`, `purrr`, and the built-in `apply` family of functions, are ready and waiting to apply your purpose-built functions to various bits of your data. If you can express your analytical wishes in a function, these tools will give you great power.

### Load the Gapminder data

As usual, load the Gapminder excerpt.

```{r}
library(gapminder)
str(gapminder)
```

### Max - min

Say you've got a numeric vector, and you want to compute the difference between its max and min. `lifeExp` or `pop` or `gdpPercap` are great examples of a typical input. You can imagine wanting to get this statistic after we slice up the Gapminder data by year, country, continent, or combinations thereof.

### Get something that works

First, develop some working code for interactive use, using a representative input. I'll use Gapminder's life expectancy variable.

R functions that will be useful: `min()`, `max()`, `range()`. __Read their documentation.__

```{r}
## get to know the functions mentioned above
min(gapminder$lifeExp)
max(gapminder$lifeExp)
range(gapminder$lifeExp)

## some natural solutions
max(gapminder$lifeExp) - min(gapminder$lifeExp)
with(gapminder, max(lifeExp) - min(lifeExp))
range(gapminder$lifeExp)[2] - range(gapminder$lifeExp)[1]
with(gapminder, range(lifeExp)[2] - range(lifeExp)[1])
diff(range(gapminder$lifeExp))
```

Internalize this "answer" because our informal testing relies on you noticing departures from this.

#### Skateboard >> perfectly formed rear-view mirror

This image [widely attributed to the Spotify development team](http://blog.fastmonkeys.com/?utm_content=bufferc2d6e&utm_medium=social&utm_source=twitter.com&utm_campaign=buffer) conveys an important point.

![](img/spotify-howtobuildmvp.gif)

Build that skateboard before you build the car or some fancy car part. A limited-but-functioning thing is very useful. It also keeps the spirits high.

This is related to the valuable [Telescope Rule](http://c2.com/cgi/wiki?TelescopeRule):

> It is faster to make a four-inch mirror then a six-inch mirror than to make a six-inch mirror.

### Turn the working interactive code into a function

Add NO new functionality! Just write your very first R function.

```{r}
max_minus_min <- function(x) max(x) - min(x)
max_minus_min(gapminder$lifeExp)
```

Check that you're getting the same answer as you did with your interactive code. Test it eyeball-o-metrically at this point.

### Test your function

#### Test on new inputs

Pick some new artificial inputs where you know (at least approximately) what your function should return.

```{r}
max_minus_min(1:10)
max_minus_min(runif(1000))
```

I know that 10 minus 1 is 9. I know that random uniform [0, 1] variates will be between 0 and 1. Therefore max - min should be less than 1. If I take LOTS of them, max - min should be pretty close to 1.

It is intentional that I tested on integer input as well as floating point. Likewise, I like to use valid-but-random data for this sort of check.

#### Test on real data but *different* real data

Back to the real world now. Two other quantitative variables are lying around: `gdpPercap` and `pop`. Let's have a go.

```{r}
max_minus_min(gapminder$gdpPercap)
max_minus_min(gapminder$pop)
```

Either check these results "by hand" or apply the "does that even make sense?" test.

#### Test on weird stuff

Now we try to break our function. Don't get truly diabolical (yet). Just make the kind of mistakes you can imagine making at 2am when, 3 years from now, you rediscover this useful function you wrote. Give your function inputs it's not expecting.

```{r}
max_minus_min(gapminder) ## hey sometimes things "just work" on data.frames!
max_minus_min(gapminder$country) ## factors are kind of like integer vectors, no?
max_minus_min("eggplants are purple") ## i have no excuse for this one
```

How happy are you with those error messages? You must imagine that some entire __script__ has failed and that you were hoping to just `source()` it without re-reading it. If a colleague or future you encountered these errors, do you run screaming from the room? How hard is it to pinpoint the usage problem?

#### I will scare you now

Here are some great examples STAT545 students devised during class where the function __should break but it does not.__

```{r}
max_minus_min(gapminder[c('lifeExp', 'gdpPercap', 'pop')])
max_minus_min(c(TRUE, TRUE, FALSE, TRUE, TRUE))
```

In both cases, R's eagerness to make sense of our requests is unfortunately successful. In the first case, a data.frame containing just the quantitative variables is eventually coerced into numeric vector. We can compute max minus min, even though it makes absolutely no sense at all. In the second case, a logical vector is converted to zeroes and ones, which might merit an error or at least a warning.

### Check the validity of arguments

For functions that will be used again -- which is not all of them! -- it is good to check the validity of arguments. This implements a rule from [the Unix philosophy](http://www.faqs.org/docs/artu/ch01s06.html):

> Rule of Repair: When you must fail, fail noisily and as soon as possible.

#### stopifnot

`stopifnot()` is the entry level solution. I use it here to make sure the input `x` is a numeric vector.

```{r}
mmm <- function(x) {
  stopifnot(is.numeric(x))
  max(x) - min(x)
}
mmm(gapminder)
mmm(gapminder$country)
mmm("eggplants are purple")
mmm(gapminder[c('lifeExp', 'gdpPercap', 'pop')])
mmm(c(TRUE, TRUE, FALSE, TRUE, TRUE))
```

And we see that it catches all of the self-inflicted damage we would like to avoid.

#### if then stop

`stopifnot()` doesn't provide a very good error message. The next approach is very widely used. Put your validity check inside an `if()` statement and call `stop()` yourself, with a custom error message, in the body.

```{r}
mmm2 <- function(x) {
  if(!is.numeric(x)) {
    stop('I am so sorry, but this function only works for numeric input!\n',
         'You have provided an object of class: ', class(x)[1])
  }
  max(x) - min(x)
}
mmm2(gapminder)
```

In addition to a gratuitous apology, the error raised also contains two more pieces of helpful info:

  * *Which* function threw the error.
  * Hints on how to fix things: expected class of input vs actual class.

If it is easy to do so, I highly recommend this template: "you gave me THIS, but I need THAT".

#### Sidebar: non-programming uses for assertions

Another good use of this pattern is to leave checks behind in data analytical scripts. Consider our repetitive use of Gapminder in this course. Every time we load it, we inspect it, hoping to see the usual stuff. If we were loading from file (vs. a stable data package), we might want to formalize our expectations about the number of rows and columns, the names and flavors of the variables, etc. This would alert us if the data suddenly changed, which can be a useful wake-up call in scripts that you re-run *ad nauseum* on auto-pilot or non-interactively.

### Wrap-up and what's next?

Here's the function we've written so far:

```{r}
mmm2
```

What we've accomplished:

  * we've written our first function
  * we are checking the validity of its input, argument `x`
  * we've done a good amount of informal testing
  
Where to next? In [part 2](block011_write-your-own-function-02.html), we generalize this function to take differences in other quantiles and learn how to set default values for arguments.

### Resources

Packages for runtime assertions (the last 3 seem to be under more active development than `assertthat`):

  * `assertthat` on [CRAN](https://cran.r-project.org/web/packages/asserthat/index.html) and [GitHub](https://github.com/hadley/assertthat) *the Hadleyverse option*
  * `ensurer` on [CRAN](https://cran.r-project.org/web/packages/ensurer/index.html) and [GitHub](https://github.com/smbache/ensurer) *general purpose, pipe-friendly*
  * `assertr` on [CRAN](https://cran.r-project.org/web/packages/assertr/index.html) and [GitHub](https://github.com/tonyfischetti/assertr) *explicitly data pipeline oriented*
  * `assertive` on [CRAN](https://cran.r-project.org/web/packages/assertive/index.html) and [Bitbucket](https://bitbucket.org/richierocks/assertive) *rich set of built-in functions*

Hadley Wickham's book [Advanced R](http://adv-r.had.co.nz)

  * Section on [defensive programming](http://adv-r.had.co.nz/Exceptions-Debugging.html#defensive-programming)