Yes, yes, I know... I am kind of an oddball for programming in Ada. When the matter comes out in conversations I am usually asked to defend this choice of mine. For future reference (and maybe to help others knowing this nice language) I decided to write few articles about what I like in Ada.

History and other stuff

Before diving in the details, let me spend a couple of words about the language. Many never heard about Ada and many of those who did have some prejudices about it.

The language Ada is named after Ada Lovelace daughter of Lord Byron (yes, that Byron) and considered the first programmer in history.

Incidentally, did you notice that I write "Ada" and not "ADA"? This is because it is a name of a person, not an acronym. Use "ADA" on an forum/newsgroup and you will be corrected in no time...

Ada was developed in the '80s following an idea of the Department of Defence. (I am not replicating here the interesting history that is available elsewhere.) Since then it was updated every approximately ten years giving rise to several releases, informally known with the year number (Ada 83, Ada 95, Ada 2005 and Ada 2012, next release will probably be Ada 2020). Ada is a language very alive and modern, with several feature not easily found elsewhere: contracts, type invariants, formal checking, private packages, distributed programming, native multitasking and so on...

Ada is quite flexible: it is used to write million-line code in avionics, but also to control small devices like the STM32. See, for example, this segway implemented with a Lego mindstorm controlled by a multitasking code (with a 16 bit processor and 64K of RAM!) presented at FOSDEM.

Why do you love Ada?

A simple answer? Reduced debugging time: my personal experience is that an Ada code will require maybe 1/10 of debugging time if compared with a C code of similar complexity. The reason is that Ada compiler is much "stricter" than C, so that when the program compiles, it has an internal coherence that prevents the existence of many silly bugs (and most bugs are just silly!) that would have survived in a C code (functions with no return, a missing break / case in a switch , dangling pointers, buffer overflows...). The remaining bugs are easily caught by the many bug traps (I love this term) that the compiler adds to your code. Programming in Ada is like doing pair programming, but with the compiler playing the role of the observer.

Please note that I am not claiming that by using Ada your code will be automagically readable, maintainable and bug free. You can write bad code in Ada, you just need to make an effort... :-)

Seriously, it is often said that the quality of the code depends mainly from the skill of the programmer, rather than from the type of tools. Nevertheless, using the right tool will help you to achieve the same result with less effort.

OK, OK, I understand... But can you make me an example?

Sure, I am here for this. Maybe the simplest characteristic of Ada that helps you in writing robust software is the type system, especially its strong typing nature. Let me explain with an example: if in C you write



typedef int serial_number ; typedef int port ;

you can assign with no problem a variable of type port to a variable of type serial_port since both are integers; but if you do in Ada



type Serial_Number is new Integer ; type Port is new Integer ;

you cannot assign a variable of type Port to a variable of type Serial_Number although both "under the hood" are implemented as integers. This is because they actually represents two different things despite being implemented in the same way at the lowest level. Well, it makes sense, doesn't it? Why should you want to use a TCP port as a serial number? Most probably, if you try to do such a thing, there is an error somewhere.

What if you actually need to use a port as a serial number? No problem, you can convert it with Serial := Serial_Number(Client_Port); . Note that this conversion has no cost since both are integers; it is just a way to tell to the compiler "Listen, this is not an error, I know what I want, please bear with me and assign this value." Note the use of "camel case with underscores" for names that are not keywords. This style is quite common in modern Ada code. It is not mandatory, of course, but personally, I find it quite readable. Please also note that Ada is case-insensitive, so that you could write, e.g., serial_number . Oh, yes, and the use of ":=" for assignment.

Actually, the code above is not the best choice. How do you know that an Integer will be large enough to keep a serial number or a port? Well, on current Intel processor (whit 32-bit integers), that is quite reasonable, but what if you have a small micro-controller with 16 bit integers? Well, maybe the best thing is to let the compiler to decide by writing



type Serial_Number is range 0 .. 999_999 ; type Port is range 0 .. 2 ** 16 - 1 ;

Note the use of '_' as separator in numbers. A simple thing, but really convenient...

Note how we do not say to the compiler which low-level implementation to use, but which characteristics we need and let the compiler to decide how to handle them. On a microcontroller with 16-bit int s maybe Serial_Number will be implemented as a long int , while Port will be an unsigned int . But who really cares? Let the compiler take care of this boring stuff...

What if you need Serial_Number to have a specific size, say 24 bits (because, for example, you need to write it in a packet)? Just write



type Serial_Number is range 0 .. 999_999 with Size => 24 ;

I do not want to dig deeper in the Ada type system, but I cannot resist telling you about two types that are not commonly found elsewhere. If you write type Volt is delta 0.125 range 0.0 .. 255.0; the variables of type Volt will hold a fixed point real ranging in the interval 0 V..255 V with step 0.125 V. Fixed point numbers are usually implemented as integers and are used, for example, in some DSP applications running on small processors without floating point maths. Another uncommon type is the decimal fixed point type defined with something like type Money is delta 0.01 digits 15; . I'll let you discover about them. See also the corresponding Reference Manual page.

An example: cleaning user input

Let us make a toy (but not so-toy) example of exploitation of the strict typing of Ada.

Someone could object that there are other ways to handle the problem considered here. Yes, I know, but I just need a simple example to show what you can do with strict typing. I am not claiming that is the only (or best) solution (although, I think it is quite good).

It is well known that in any application using user input care must be taken in using the user input since it could open security holes. The following xkcd comic is a classic

Of course, we can pay all the attention we want to not use user input before sanitizing it, but if the application is very large and everything is a String (or char* ), something can slip in the cracks... Type strictness can help us here. We just need to define a new type Dirty_String and have all the user input function return a Dirty_String rather than a string (this is easier to check). The only way to transform a Dirty_String in a normal String will be via a special Sanitize function.

Let's dig into details. We will define the following package specs



package Dirty_Strings is type Dirty_String ( <> ) is private ; function Sanitize ( X : Dirty_String ) return String ; function Taint ( X : String ) return Dirty_String ; private type Dirty_String is new String ; function Taint ( X : String ) return Dirty_String is ( Dirty_String ( X )); end Dirty_Strings ;

In Ada a package is divided into two parts: its specs that specifies the "resources" exported by the package and its body with the actual implementation. The specs are further divided into a public part (visible to the rest of the code) and an optional private part.

This package define a type Dirty_String . In the public part (before the private ) the type is defined as private , that is, none of your business. Moreover, the package exports two function that can be used to convert from Dirty_String to normal String and vice-versa.

However, in the private part we see that a Dirty_String is just... a String . Putting its definition in the private part prevents short-cut conversions from Dirty_String to String and forces the programmer to go through the function Sanitize that, we guess, will do stuff like quoting special characters. Instead, the conversion of a normal String to a Dirty_String is just a type conversion since there is no need to change it. This allows us to define it as a expression function (see also the RM) that, most probably, will be "inlined" by the compiler.

Run-time constraints

Let me conclude with a feature of Ada 2012 that I find quit cute (and useful). Few years ago, I wrote a small package to write Matlab files from Ada. One day I discovered that the package was writing files that could not be read from Matlab. The reason was that the names of the variables in the Matlab file were not valid Matlab names. After correcting the bug, I decided to add a new bug trap to the code. I defined the type to be used for variable names as



type Matlab_Name is new String with Dynamic_Predicate => ( for all I in Matlab_Name ' Range => Is_Alphanumeric ( Matlab_Name ( I )) or Matlab_Name ( I ) = '_' ) and Is_Letter ( Matlab_Name ( Matlab_Name ' First ));

If you have a bit of programming experience, you should be able to understand the code above, even if you do not know Ada. As you can see Matlab_Name is a String (but you cannot mix it with other strings, e.g., a filename!), but it also must satisfy a Dynamic_Predicate (a condition that is checked at run-time, if you ask the compiler to do so). The condition can be split in two, the first part



( for all I in Matlab_Name ' Range => Is_Alphanumeric ( Matlab_Name ( I )) or Matlab_Name ( I ) = '_' )

requires that every character in the name must be a letter, a digit or an underscore, while the second part



Is_Letter ( Matlab_Name ( Matlab_Name ' First ));

requires that the first character must be a letter. If checks are enabled and at some time your code generates a bad name, an exception will be raised precisely in the point were the bug happened. (This pinpointing of bugs helps a lot in debugging...)