My first little exercise is writing a bubble sort with an extra C++y twist - a bubble sort implementation with the same interface as std::sort, the standard sort. Just as an aide memoire, std::sort looks like this:

std::sort is a generic function that takes a pair of iterators that delimit the sequence to be sorted. There’s an overload, which take a comparison function, should you wish to sort the sequence in the manner of your choosing.

That’s what I want my function to look like on the outside, but what goes on the inside?

Here’s some random dice! We want to sort them so the lowest value is on the left, going up to the largest on the right.

We’ll start by taking the first two dice and comparing them. We want the smaller value on the left.

Here, that’s already the case. There’s nothing to do, so we take the next pair.

These two are in the wrong order, so we swap them and move to the next pair.

This pair is also in the wrong order, so we swap those as well.

We’ve now completed one pass, and we can see the largest value - the six - has moved, been bubbled, the right and is in its proper place. Now we start again from the beginning.

Two is less than four, so we swap.

One is also smaller than four, so we swap this pair too.

We don’t need to compare the last pair, because we know we moved the six to the right place in the first pass. We’ve now completed the second pass, and bubbled the second largest value into its place. We go round again.

This time we only need to compare the first two dice. We swap them, and our sort is complete.

Sorting four dice took three passes. The first pass had three comparisons, the second two, and the third has one comparision. That’s a pretty expensive sort, and you can see how the number of comparisions races away with larger datasets.

Rather than write an extended essay on how I wrote half a dozen lines of sorting code, I thought it might be fun - or at least a little different - to capture what I did, along with my confused looking face, in a short video.

While I was feeling pretty pleased with myself at the end of the video, I did do a little more work on the code afterwards.

but that really doesn’t help at all. It just looks so weird and uncomfortable.

There’s an optimisation we could make to detect if the sequence is sorted before needing all the passes, but it didn’t add to the fun, and it only occurred to me later.

Pretty sure this is the first time I’ve written a bubble sort, although I’m obviously in that demographic that has watched a bubble sort in action many, many times.

In everyday code, where you know the types you’re working with, let’s say you’ve got a std::vector<Something>, then you’re probably just going to call the begin and end member functions, and the iterator’s operator++. And you know, I think that’s absolutely fine. For library code though, when we can’t be as certain or when we don’t want to place unnecessary constraints on people using our code, then these little utility functions are just what we need.

Like the container and iterator utilities above, iter_swap and swap use the magic of template deduction, specialisation, and what-not to do the right thing for the types you’ve called the function with. Let’s say we’ve plugged a vector of vectors into the bubble sort. Using the classic two variable swap, each assignment is going to copy the whole vector, which is probably pretty bad in both time and space. Using iter_swap is, somewhere underneath it all, going to find the std::vector specialisation of std::swap, which is going to call the swap member function on one of those vectors, and that’s going to do it all in am exception-safe heartbeat. Chances are the compiler will inline it all too, so there won’t even be a function call overhead. If we invoke stiX::bubble_sort with a C style array of integers, the magic of std::begin and friends will generate a loop optimise for raw memory access.

This whole endeavour relies on Software Tools in Pascal and Software Tools, both by Brian W Kernighan and PJ Plauger. I love these books and commend them to you. They are both still in print, but new copies are, frankly, just ridiculously expensive. Happily, there are plenty of second-hand copies floating round, or you can borrow them from The Internet Archive using the links above.

For this project I’ve been using JetBrain’s CLion, which I liked enough to buy and renew, because it’s a year already, a license.

The test harness I’m using is Catch. I’ve been aware of Catch pretty much since it was first released, but this project is the first time really getting in and using it. I like it, and it’ll be my first choice in the future.

I recorded the video using OBS, with a cheap noname USB mic and an old, although perfectly servicable, Logitech C525 webcam perched precariously on the top of one of my monitors.

This whole endeavour relies on Software Tools in Pascal and Software Tools, both by Brian W Kernighan and PJ Plauger. I love these books and commend them to you. They are both still in print, but new copies are, frankly, just ridiculously expensive. Happily, there are plenty of second-hand copies floating round, or you can borrow them from The Internet Archive using the links above.

For this project I’ve been using JetBrain’s CLion, which I liked enough to buy and renew, because it’s a year already, a license.

The test harness I’m using is Catch. I’ve been aware of Catch pretty much since it was first released, but this project is the first time really getting in and using it. I like it, and it’ll be my first choice in the future.

I realised I had three functions that all looked pretty similar.

The loop itself, reading each entry in the archive before we decide what to do with it, isn’t that complex but it’s not entirely trivial and that archive_in.peek() is a little bit clever-clogsy. We’ve written it three times already and with two operations yet to go, we could end up doing it twice more. Let’s go the other way, do the loop once and just drop the interesting part of each operation into the middle.

Often in C++, you have the choice of doing something at compile time or at runtime. read_archive could have been written, almost identically, as a template function. Here, I made the runtime choice using std::function. For this application it doesn’t make any kind of noticeable difference - I’m trading an almost unmeasurably slower application against, perhaps, a triflingly longer build time.^[1]

The archive program’s update command replaces named members and adds new files onto the end of an existing archive. Kernighan and Plauger treat creating an archive and updating an archive as the same operation. Creation for them is an update where there’s nothing to replace. They also implement updating in place. If you’re updating, say, the second file in an archive, the new version will be also be the second file in the archive.

For me, creation and updating are not the same. Updating is an operation on an archive that already exists. It doesn’t seem ok to create one if it isn’t there. The order of files within the archive doesn’t seem important either. As a user, we can’t say give me the first and third file in the archive, we can only refer to the contents by name. To update an archive, we can remove any existing versions from the archive, then add the new versions to the end of archive. And hey, there’s code to that already.

This piece of code is at a slightly higher level than that previously shown, so it’s got a bit of the file manipulation detail.

Beautiful. Really pleased with this.

That just left the extract operation. I started with a test

Just as I did with create, I’m not letting extract_files interact directly with the file system. Instead, I’m passing in a function that’ll do whatever needs to be done file-wise and hands back a stream. For the tests, I’m not going to let it go anywhere near a real filesystem.

Test in place, a quick cut/paste/edit of the print operation

Boom - tests pass. Just need to hook up to the real file creation function, and job done right?

and …​ oh

Ok, so instead of auto& out = …​ it should be auto out = …​.

and …​ oh, again

Damned with a cannot bind non-const lvalue reference of type ‘std::basic_ofstream<char>&’ to an rvalue of type ‘std::basic_ofstream<char>’ if I do, damned with a use of deleted function ‘std::basic_ostream<_CharT, _Traits>::basic_ostream(const std::basic_ostream<_CharT, _Traits>&) if I don’t. This time the error has come while compiling the tests. It took me a little while to work this out. extract_files is a template function, and I’m instantiating it with two functions that have similar but ever so slightly different signatures.

One returns a stream, the other a stream reference. The rules for auto type deduction are the same as for template type deduction, which basically means the reference gets tossed away. If I force a reference, auto& out …​ it can’t bind to the object returned by file_creator. If we leave it as auto out …​, it’ll try to copy the ostream reference returned by test_mock, which fails because ostream is an abstract class and so can’t be copied.

What we need here is for out to take on the actual return type of the function parameter, and to do that we just change the rules!

Now we’ll pick up the actual return type of the function, and everything clicks into place.

Printing and extracting are almost the same. The extract implementation is just a light edit of print. That can’t stand - it’s a big fat duplication that can be factored away.

Six weeks (crikey) of start-stop (mainly stop) work from when I started, archive is done, and so is chapter three. Blimey.

My first encounter with a file archiving program was in the summer of 1989 during which I had the use of a friend’s Amstrad CPC 6128. In between writing programs to calculate 4 colour Mandelbrot Sets (I’d set them running in the morning when I went out to work, returning several hours later to see what I’d find), I spent the time poking around his collection of floppy disks. Some of those disks had ARC files on them, and when I discovered those files had files inside them, it just blew my mind. Writing a file archiver of my own, albeit with a strong steer, is really quite satisfying.

Source code for this program, indeed the whole project, is available in the stiX GitHub repository. archive is the sixth program of Chapter 3.

This whole endeavour relies on Software Tools in Pascal and Software Tools, both by Brian W Kernighan and PJ Plauger. I love these books and commend them to you. They’re both still in print, but new copies are, frankly, just ridiculously expensive. Happily, there are plenty of second-hand copies floating round, or you can borrow them from The Internet Archive using the links above.

For this project I’ve been using JetBrain’s CLion, which I liked enough to buy and renew a license.

The test harness I’m using is Catch. I’ve been aware of Catch pretty much since it was first released, but this project is the first time really getting in and using it. I like it, and it’ll be my first choice in the future.