Each program in chapter one was progressively a little more complex than the one before. This is not the case in Chapter Two, where the various programs form more of a loose map of the territory. Here we have a program that replaces many characters with a single character, while over there we have a program that might produce many lines of output for a single line of input, and so on.

This chapter is, without directly saying so, pretty explicitly about the Unix philosophy. While Unix systems (or at least Unix-ish systems) are basically the substrate of most modern computing (yes, even if you’re a Windows, Android, or iOS user) in 1981, when Software Tools in Pascal was published, there were “800 systems [already] in use outside [Bell Labs]”. Kernighan and Pike have to take time to describe what’s now commonplace - combining small programs with pipelines, text as common currency, indeed the whole idea of software tools and of the programmer as tool user.

When I first read Software Tools in Pascal, I’d just started my first substantial job on a Unix system (in fact four Unix systems, all slightly different) and I was only passingly familiar with a handleful of command line tools. The idea that these small programs not only did simple things, but could be combined like some kind of giant tokusatsu robot to do very powerful things was really quite startling. It certainly changed, and continues to influence, how I think about programming and I have no doubt I’m a better programmer for that. I’m not sure I’ll ever touch the heights achieved by my friend Thomas in his masterful He Sells Shell Scripts To Intersect Sets, in which he combines standard Unix tools to do full on computer science, but I’m nearer than I otherwise would be.

Next up, files!

After the relative calm of echo, it all kicks off (or, if you prefer, all comes together) in translit, the finale of Chapter Two. As its name suggests translit transliterates certain characters on their way through. “We would like”, say Kernighan and Plauger, “to have a program translit so that we can write”

“and have all occurrences of x in the standard input be replaced by y on the standard output.”

Ah, so this is why we took that detour into command line arguments. Given what we’ve been through to get here, though, this task is pretty trivial. But hold on, they’re just getting started.

“Multiple translations are also handy:”

“would change all lower case x, y and z to the corresponding upper case letter.”

Ok, that’s slightly more involved but not particularly tricky.

“It would be nice”, they continue breezily, “to have a shorthand for alphabets, so”

“would translate all lower case letters to upper case.”

All right, this still isn’t too difficult. We can deal with the arguments easily enough, and then the transliteration is routine

We don’t even need to write a function - we do all it all in line with a simple lambda. This seems a touch anticlimactic. But Kernighan and Plauger haven’t finished. Not by a long shot. “There are times when we would like to translate a whole class of characters into just one character, and even to squash runs of that translation into just one instance …​ We can specify this squashing operation by giving a second argument that is shorter than the first …​ we could also take [the case when the second argument is not given] as a request to delete all occurrences of characters in the first string …​” Easy there fellows “…​ One final capability is worth adding: sometimes we would like to be able to translate and compress all but a set of characters. For instance”

“would replace strings of non-letters with a dash. And”

“would delete all but lower case letters.”

Wait, wait, wait.

When I write my C++ versions of the programs in Software Tools, I don’t translate from the Pascal. Of course, I do read the code along with the commentary, and then write a series of unit tests to capture the behaviour. Leaving aside argument expansion, for translit I finished up with five distinct sets of tests -

Obviously the two squashing cases and the two deletions cases are pretty similar, but that still leaves, as far as I was concerned, with three distinct operations. Kernighan and Plauger implement them in one loop

As you read this section of the book, you see the program grow a little bit at a time from an initial half a dozen lines to the code above, along with all the preamble to handle the command line arguments, the inner works of xindex and all the rest of it. This piece of code isn’t difficult at all, because you know it inside out. Coming to it cold, it’s pretty daunting. There are two different flags, nested loops, an if-ladder nested within another if, and assignment through out parameters. It’s compact and dense and not entirely straightforward.

Partly because I was starting from a different place, partly because I wanted to keep the std::transform model I’d adopted for the preceding filters, and partly because I wanted to try and hoist as many of the conditions up and away from the main body of the code, I finished up with rather different

The argument expansion populates the replace and with strings. It’s also set selectionMode based on the presence of the leading ^ character. Not shown here are the implementations of the in_range and out_of_range functions, which determine whether a particular character is within or not within a given string. The variable matcher then is a function pointer, and I implement the normal or negated search by pointing it to the appropriate function.

The if-ladder then determines which mode translit has been invoked in - deletion, squashing, or simple replacement. In the Pascal implementation, this if-ladder is at the heart of the read loop, traversed for every character. I’ve hoisted it right up and out - we decide here, then never have to worry about it again.

The three modes are then implemented in three separate functions. This turned out pretty well. Two of the cases - replacing and removing - can be implemented using functions provided by the standard library. Replacement uses std::transform, as shown above, while removing uses the catchily named std::remove_copy_if.

std::remove_copy_if copies the elements in the range, except those elements for which predicate returns true. In this case, the predicate is a little lambda wrapped around the matcher function pointer which we set up earlier.

That leaves squashing. The implementation is similar to that of entab. When entab encounters a space in the input, it switches into entabbing mode until it encounters a non-space or hits a tab stop. When squashing when we encounter one of our from range, we flip into squash mode until we see a character that isn’t in the range. There’s a bit of house keeping to do then, but it’s straightforward enough.

Chapter 2 of Software Tools in Pascal is entitled Filters, and thus far it’s been absolutely focused on processing streams of text. We’ve substituted tabs for spaces, messed around with printer pre-processing, compressed and expanded text files. Where on earth could we be going next? I’m going to bet you wouldn’t expect something that’s very decidedly not a filter in any shape or form.

Weird huh?

In many ways, this is a little chill-out program - a light palate cleanser ahead of the big meaty one coming up next. It also allows Kernighan and Plauger to go off for a page on Pascal’s, or at least standard Pascal’s, weaknesses as a proper programming language. They don’t put it in quite those terms, but they bemoan its lack of provision for command line argument handling and, more seriously, the weaknesses of its type system, particularly its lack of dedicated string type. They work around the string type problem by using a fixed length array with an end-of-string sentinel, and “pay the price of wasted storage”. They are rather more coy on how they solved the command line argument problem, other than to say they’ve defined a primitive

which can grab the i^th command line argument. echo then is a few lines to demonstrate getarg and their string type.

This is one of the few places where Software Tools in Pascal differs in any significant way from Software Tools. As far as I’m aware neither FORTRAN nor PL/1 had command line argument handling or a string type either, but the corresponding place in chapter 2 of Software Tools instead presents a trivial text encryption program. That program also uses a getarg primitive of exactly the same sort, but it goes entirely unremarked.

C++ provides ready access to command line arguments and (setting aside the char* legacy) offers a serviceable string type, and so echo offers little challenge.

In spite of having “Do The Simplest Thing That Could Possibly Work” taped to the side of my monitor (and I really do try to hold true to it), I chose to set that aside and indulge in a little standard library style nonsense.

You’re probably familiar with the general shape of join - handle the initial value in the sequence, then loop through rest, prefixing them with the separator. The declaration and return type follow the general form of standard library. It is worth just taking a moment to consider just how much is going in

I’m not sufficiently down in the details to be sure if there are four or five (or some other number) of separate operations occurring here. It’s something along the lines of

After many years, many years of waiting, the standard library is finally catching up with the fact that most of the time the sequence we’re operating over is already neatly wrapped up in a container. Having to spell out mycontainer.begin() and mycontainer.end() is a bit redundant and it would be nice if we could just lob the whole shebang over in one go. In preparation of C++ 20 then, I put together a range version of join. (I’m being overly flippant. This is the absolute least of what’s coming in ranges, which looks to be an important and exciting addition to the library.)

This is, I believe, the more-or-less canonical form of a range adapter function. Jonathan Boccara discusses why passing the range with a forwarding reference, InputRange&&, is the preferred form in Algorithms on Ranges. It’s a subtle business, and I’m happy to pass the heavy thinking off to some one else.

Having presented a simple text compression utility, Kernighan and Plauger’s next program is, unsurprisingly, the companion program to reinflate the compressed text. Expansion is easier than compression - processing a sequence of characters with interleaved occasional encoded runs - and so the code should be straightforward. “Our first impulse is thus to write :”

They counsel caution though.

They mention possible mitigations - adding a shim over getc or modifying getc itself to be safe in the face of ENDFILE, having the program stop immediately on hitting an error state - but discard them. Their preference is explicit error checking and reasonable recovery.

This strikes me as an application of Postel’s Robustness Principle. The Robustness Principle, also called Postel’s Law, is given in RFC 760 as

RFC 760 describes TCP and so is world changing in all kinds of ways, but it’s arguable that if not for Jon Postel’s call to generosity in implementation then TCP would have foundered, certainly that take-up would have been significantly slower than it was. This isn’t to say we should apply the Robustness Principle at all times and in every case - it certainly isn’t a Law in that sense - but in the smaller context of a little text expansion utility, it’s certainly worth considering.

I’m not sure when the Robustness Principle was first named as such (possibly not until RFC 1122 in 1989), but as a point of pedantry Kernighan and Plauger certainly didn’t know that name when they wrote this chapter. RFC 760 was written in 1980, and I don’t believe it was projected back through time to 1976, when Software Tools was published. Still, good advice is good advice no matter when it was said or who said it.

Bearing that in mind, the tests I used to write this program included a number of malformed inputs.

In terms of lines of code, my implementation is rather longer than Kernighan and Plauger’s Pascal version. Our respective versions have the same three states, but they’re not as obvious in the Pascal. While working on this code, I thought I had found two error states that K&P had missed. I was wrong, they had them both covered, but it took quite a close reading of the code for me to realise.

Consider the code above and below with the following inputs - the first two well-formed, the second two not so much.