I’m in a gap, hopefully a brief one, between gigs at the moment. The work I’ve been doing for the past few months, improving the accessibility of a Windows desktop application for people with visual impairments, has been pretty interesting - I’ll certainly never work on a user interface in the same way again - and it was a good team to be a part of.

As I look forward to the next few months and whatever work comes along, there’s also the JezUK 2019/20 Winter Tour to think about. My thoughts naturally turned not to whatever the hell I was going to talk about, but my bloody speaker biography.

Speaker bios are, I’ve always found, ridiculously hard to write. I’ve long loathed the X started programming Y years ago template, and I’m instantly suspicious of anyone who describes themself as an expert (curiously, even if I know this to be true). In recent years, I’ve toyed with off-track things like Jez Higgins was 2017 Player of the Season for Kings Heath Hockey Club Mens IIIs and Jez is …​ so dedicated to the pursuit of software craftsmanship he once cycled to the conference from Birmingham. Both these things are true, and I like the way they have the kind of minor success anyone could achieve, but they really only work in a context where people already have an idea of who I am.

As the job wound down, I took advantage of our Slack channel to crowdsource (groupsource maybe, there were only six of us) my speaker bio with my colleagues. We came up with

which I’m pretty pleased with. I was also given a more corporate version

We finished the job on Friday. It’s only Wednesday and I miss my team already.

Software Tools shows its age properly for the first time here. Back in 1981 this was a genuine problem, and even 10 or more years later it was entirely possible send a printer into spasms if you weren’t careful. These days of course, printers behave perfectly all the time and never give anyone any bother at all.

While printing might be a solved problem, the question of tabs or spaces in source code remains an eternal problem. The motivation might have changed, but the tool remains relevant.

This final program in Software Tools' first chapter also turns the complexity screw another notch or two. I’m not going to reproduce the whole of the code, but here’s the core of the now familiar read/process/output loop

We’ve got all the small parts Kernighan and Plauger have built up over the previous four programs - reading and outputing characters, counting characters, special processing on new lines. The new element is that repeat/until loop, which converts each tab by outputting the requisite number of spaces.

In my C++ programs, I’ve avoided direct output in the body of the code. I’ve used functions that return a value, or written out through iterators. Here, after reading a character I might need to write one or more characters in response. Or, put in a more C++y way, we need to convert a sequence of characters into a sequence of strings. Rummaging once again in the algorithm header leads us to std::transform, which applies a given function to a sequence and stores the result in another sequence. In other languages you might know this as map or apply. JavaScript’s Array.prototype.map, for example, returns a new array filled with the results of calling the provided function on each element of the calling array. The start of the my C++ implementation is then

The …​ something …​ could be a function, a lambda, or a function object. Because the transformation I’m doing here needs a little bit of state - the action performed depends not just on the current character but also where we are in the line - I used a little function object.

The implementation is straightforward, and not hugely dissimilar to the Pascal original.

After counting characters and then lines, Kernighan and Plauger take us next to counting words.

You can see the little path Kernighan and Plauger are on quite clearly now. Start with a simple loop, then extend that loop with a simple counter. Next add a simple conditional, and now extend that conditional into a little state machine. Each little step has added something extra, changing the functionality of each program to provide a new and useful result.

My path has to been to look through the list of functions provided in the algorithm header and pick the one that does what’s needed for this task.

Kernighan and Plauger have a straightforward, although entirely reasonably, definition of a word - the maximal sequence of characters not containing a blank, a tab, or a newline. The additional complexity of Kernighan and Plauger’s wordcount over linecount is to keep track of whitespace delimiters between the words. They are, in effect, splitting up the sequence of characters into a sequence of words.

Previously, I blythely said that C++'s istream and ostream provide a number of different iterators. To get down and deal with the raw character stream we use istreambuf_iterator<char>. For formatted input, that is anything that needs a bit of work to process those raw characters in some way, we want some sort of istream_iterator.

Gathering characters up into whitespace delimited words qualifies as a bit of processing work. It’s the kind of thing people do all the time, and consequently is precisely what the istream_iterator<std::string> provides.

I rather loosely described std::distance(InputIt first, InputIt last) as counting the hops between first and last. More formally, it returns the number of iterator increments needed to go from first and last. Incrementing an istream_iterator<std::string> returns the next word, so plugging that into std::distance counts the number of words in the input.

So once you can count characters, you might also want to count the number of lines in some input. Instead of counting every character on our input, I just count the number of newline characters I see.

It’s at this point that Software Tools in Pascal does rather show its age. In their discussion of the code, Kernighan and Plauger say

There follows a paragraph or two about the implementation of their getc and putc primitives, and how they might be implemented on systems which have fixed length records, differing character sets, disk formats, or whatever. The point of these two functions is to insulate their code from the vagaries of the underlying system. Even if the implementations of getc and putc are trivial on a particular system, it is still worth doing.

This kind of insulation is part of what the standard library provides for us. I’ve built this code on three different operating systems, each with a three different file system, using four different compilers, and it’s all just worked. Kernighan and Plauger were not so blessed, and had to build their own low-level library as they went.

Of course our library doesn’t just have low-level stuff. It has mid-level stuff too, like the std::copy and std::distance functions I used previously, and like the std::count I’m using today.