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In September, I will give my first lectures on C to students in engineering school (usually I teach math and signal processing, but I have also done a lot of practical work in C, without giving the lectures). Computer science is not their main topic (they are more studying electronics and signal processing), but they need to have a good background in programming (some of them will maybe become software developers)

This year will be their 2nd year of learning C (they are supposed to know what a pointer is and how to use it, but of course, this notion is not yet assimilated)

In addition to the classical stuff (data structures, classical algorithms, ...), I will probably focus some of my lectures on: - design the algorithm (and write it in pseudo-code) before coding it in C (think before coding) - make your code readable (comments, variable names, ...) and - pointers, pointers, pointers ! (what is it, how and when to use it, memory allocation, etc...)

According to your experience, what are the most important notions in C that your teachers never taught you ? On which particular point should I focus ?

For example, should I introduce them to some tools (lint, ...) ?

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16  
should be community wiki –  Samuel Carrijo Aug 10 '09 at 14:30

55 Answers 55

  • Non-procedural programming techniques including OOP patterns in C.
  • Advanced C preprocessor techniques
  • Debugging with something other than printf().
  • Complier and linker features, including building shared/dynamic objects.
  • Unit testing and mock objects, TDD in general.
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Never believe the compiler. It is usually right that there is a problem, but except for the most trivial of errors, it's almost always wrong about what the problem is, and where it is.

NOTE: I didn't say ignore the compiler. I said don't BELIEVE it. It knows there is a problem, but it is frequently wrong about what exactly it is. Taking the compiler output at face value is a recipe for frustration and wasted time. Especially for complex errors.

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4  
Nonsense. The compiler is your friend. Listen to what it says. –  Kristof Provost Aug 10 '09 at 14:40
2  
I'm with Kristof. I've wasted so much time in the past trying to fix errors when a carefull reading of the compiler output was what was really needed! –  Jackson Aug 10 '09 at 15:04
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The trick is learning how to interpret the compiler errors. It's usually wrong about what the error is, but it's CONSISTENT, so when it says the error is X on line Y, you can predict that it's really error Z on line Y-a... –  Brian Postow Aug 10 '09 at 15:14

An array is a pointer The differences between the * (dereferencing) and & (addressof) operators and when to use both

And emphasize that the best (and really only) real place for C these days is in embedded systems and real-time apps where resources are scarce and run-time is a factor.

I didn't really appreciate C as a language until I took my embedded microprocessors systems class and we implemented the hardware via a reading through the programmer's guide in the manual for the Motorolla Dragonball board. Consequently, if it's at all possible (which may be hard, as you'll need to get cheap hardware) try to have them work on projects similar (implementing UART and interrupt vector tables, etc)...

Because although stuff like string processing, sorting, etc are toy classical school problems, they really aren't as useful anymore, and frustrate students who know there are easier ways. It's much more rewarding to & a byte with a bit-mask and watch an LED light up.

Oh, and I never learned about how to use stuff like gcc in school, or what was actually going on with makefiles. Pragmatic Programmers say that's a good thing to know.

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1  
An array is most definitely not a pointer; an array identifier will implicitly be converted to a pointer value in most contexts, but arrays and pointers are different animals entirely. –  John Bode Aug 10 '09 at 17:18

Wrap all macro parameters in parentheses.

If a macro is a statement that is more complicated than an assignment or function call, wrap it thusly:

#define M(A) do { ... (A) ... } while (0)
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I used C89 in embedded programming and debugging the hardware was nightmarish. We had a few coding conventions that saved our sanities:

  1. All functions return a unique error code.
  2. All return values are auto variables passed by reference.

E.g.:

#define NOERR 0
#define VariableLookupNULL 1024
#define VariableLookupNOTFOUND 1025
... separate #define for each error
#define EvaluateExpressionNULL 1055
#define EvaluateExpressionUNKNOWNOP 1056


int EvaluateExpression( char *expression, int* result )
{
    ASSERT(result != 0);
    if (expression==0)
    	return EvaluateExpressionNULL;

    *result = 0;
    while (*expression != 0)
    {
    	switch (*expression)
    	{
    		case ' ':
    		case '\t':
    			break;	// ignore whitespace

    		case 'a':
    		... other variables
    		{
    			int var = 0;
    			int lookupResult = VariableLookup(*expression, &var);
    			if (lookupResult != NOERR)
    				return lookupResult;

    			*result += var;
    			break;
    		}

    		... check operators, et al.

    		default:
    			return EvaluateExpressionUNKNOWNOP;
    	}

    	++expression;
    }

    return NOERR;
}

ASSERT was a debug macro that would abort the runtime.

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Besides the obvious pointer stuff, I found nobody talking about commas when I was learning C.

a= 1, b= 2 ;

Sure you use it inside of for (;;) {} statements, but nobody ever understood why, and I've never seen anybody else use it outside of for statements.

But C treats commas differently from semi-colons. for example:

"if ( a ) b= a, c= a ;"

is the same as

"if ( a ) { b= a ; c= a ; }"

and different than

"if ( a ) b= a ; c= a ;

Now, I'm not saying that the first form with commas is better, because its going to trip up programmers that don't know better, and its going to be hard to see if you use very small fonts, but there are times where you might run across this kind of code and its good to know what the language actually does.

Also, I found that if I have a lot of initialization at the top of a function,

a= 1,

b= 2,

i1= 0,

i2= 0,

i3= 0,

i4= 0,

dtmp= 0.0,

p= strtmp ;

Having all these assignments be seperated by a comma, makes them one statement, and lets me "step" in the debugger past all of them in one step, instead of eight ( or more ).

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My lecturers would occasionally talk about performance, but never made mention of the cost of branching compared with other operations, it wasn't until later when I studied microprocessors that I understood this. So many times we make unnecessary branches when the same problem can be solved with a bit of bitwise manipulation, finding the position of a letter in the alphabet for instance:

if (islower(letter)) {
   pos = letter - 'a' + 1;
} else if (isupper(letter)) {
   pos = letter - 'A' + 1;
}

vs:

pos = letter & 31;

of course, ascii was designed with this sort of thing in mind, so it's not as if showing us this would've been teaching us 'bad style' or some sort of 'magical hacks'... I now find myself using bitwise tricks every day to avoid branching.

-- my 2c worth

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While not tied directly to C I would like to have learned about the technique of using ASSERTs to catch errors early (e.g. long before some bizarre error caused by overwriting of memory). Instead I independently discovered it some years later. This technique has catched many, many bugs (including some very subtle ones) that would otherwise have gone unnoticed.

In general an assert is added whereever some assumption can be made about a value in the program, e.g. it is never negative or zero or it is larger than some other variable.

E.g.:

assert(pInt)

if it is assumed pInt will point to reasonable data. Will fire for a null pointer. Often used for pointers passed to functions.

Or

assert(pInt < pMax)

where pMax points just past the end of an integer array that pInt is operating on.

Or

assert(yMass > 57.90)

(where yMass is the mass of single charged y-ion for a peptide)

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  • No one ever taught me how to lay out a project. In a language like C, there are often header files, code files, libraries for static & dynamic linking, etc. What goes in the header, and what goes in the code file? Should these all just be stuck into a single directory, or should they be grouped in some way?
  • If they'll be using Visual Studio, it's to avoid ever learning how to use the compiler, and what the difference is between compiling and linking.
  • Teach them how to use a build tool like make, and also why.
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I wish my professors had taught us how to use the debugger. Instead I fumbled through instrumenting my code with printf's trying to figure out problems. Discovering gdb was like turning on a lightbulb. Being able to debug a crash using a core dump was especially helpful since a lot of newb C programming errors usually arise from bad pointer logic.

Nowadays unit testing would probably be a good practice to teach.

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  • Using debuggers and other analysis tools (such as Valgrind etc.)
  • Optimization tricks, like Duff's device.

I'm very glad to say I was taught almost everything else that has been mentioned here (including unit testing and OOP patterns in C, really!).

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#pragma directive, can be used to issue additional details to a processor. I worked on TI processors with C language, and this helped me a lot for defining the memory segments.

Also '__FILE__' & '__LINE__' predefined macros are very useful while debugging/logs, but I never knew this. These kind of thing should be told to students.

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One thing I'd like to see taught by more programming professors is a little about source control. A day on any VCS: why you use it, some simple operations, version numbering, etc.

There are far too many graduates that find source control a foreign concept...it doesn't matter that they're EE's or CS majors, if they're writing code, they should know a little about version control systems.

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Hygienic names in C macros:

#define SOME_MACRO(_x) do {     \
  int *x = (_x);                \
  ...                           \
} while(0)

Defining x this way inside a macro is dangerous, because (_x) may also expand to x, ending up with:

do {
  int *x = x;
  ...
} while(0)

which might not get any warning from your compiler, but actually initialize your x pointer with garbage (rather than the shadowed x from the outer scope).

Its important to use names that you know are unique to that macro. The C preprocessor has no mechanism to automate this, so you just have to choose ugly names for your macro-defined variables, or just avoid them for these purposes.

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The compiler is not always right. Particularly when developing for embedded systems.

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How to load tape into tape player - I am not joking, I have learned C on ZX Spectrum and every compilation required loading a compiler from a tape.

Those were times :D

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good portable coding concepts, programming models ( e.g. ILP32 v LP64), and expose them to different C compilers and toolchains (not all the world uses GCC)

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The concepts of order of execution and sequence points are pretty useful, and not much discussed.

Knowing that x=x++; invokes undefined behavior is useful. Knowing why it oes can be much more educational.

Given your audience, some discussion of "volatile" might be useful, as well as other concepts in interfacing with hardware. How to handle write-only registers, that sort of thing.

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Initialise pointers, that would otherwise be undefined, to a value that will make the program crash immediately when dereferenced (instead of overwriting of memory in some arbitrary location).

This will work as intended on most 32 bit system:

int *pInt = (int *)0xDEADBEEF

I am not sure what would be a good value on a 64 bit system.

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That a pointer is nothing but a datatype for storing addresses, just as an int is a datatype for storing integers. When I assimilated this, everything about pointers and pointer-arithmetic just fell into place.

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Simple debug tool, printf(). If you don't have any debug tools!!

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Simulate objects with structures and function pointers

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Integer promotions rules; representation of NULL pointers; alignment; sequence points; some kind of interesting optimisations the compiler is allowed to do; what is unspecified, undefined, and implementation defined -- and what it means. Good practices are also important, and its a shame some professional coding guidelines contains some really hugely stupid things. For example: do if (foo) free(foo); instead of free(foo); when foo can be NULL while the correct advice would precisely be the opposite: do free(foo) and never if (foo) free(foo); I'm also officially sick of shitty multi-threaded code so please either tell your students how to correctly write multi-threaded programs (by giving them a subset of known and provably safe techniques and forbidding them to use anything else or to invent something themselves) or warn them its just too complicated for them. Also tell them that buffer overflows are not acceptable in any context -- and neither are stack overflows ;)

Some things are not C specific at all but please also remind them what pre/post conditions are, loop invariants, complexity... Also some fundamental metrics used in serious industries are far too rarely known (for example cyclomatic complexity is absolutely crucial, yet up to now the only people I've met knowing about it have worked on safety critical software or have learned about cyclomatic complexity ultimately from people working on safety critical software)

Back to C: take a close look at the C99 standard: you will find tons of interesting subtilities rarely known by even otherwise good programmers. The worst is that when they take something for granting for a long time (and because of poor education this can even be things that are never been true or have not been true anymore for decades) and then have to face reality when their incorrect code introduce real life bugs and security holes, they shout on compilers and, instead of saying they are sorry for their incompetence, write long stupid rants insisting on why the behavior they falsely thought being used is the only one that make sense. Exemple: overflowing arithmetic on signed integers is often believed as being two's complement (at least if the computer is), when it is indeed not mandated and even false with GCC.

Before I forget: tell them to always compile with at least -Wall -Wextra -Werror (I tend to add -Wuninitialized -Winit-self -Wswitch-enum -Wstrict-aliasing -Wundef -Wshadow -Wpointer-arith -Wbad-function-cast -Wcast-qual -Wcast-align -Wwrite-strings -Wstrict-prototypes -Wmissing-prototypes -Wmissing-declarations -Wold-style-definition -Wredundant-decls)

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Alone semicolon is a NOP operation:

if(cond0) { /*...*/ }
else if(cond1) ;  //is correct and does nothing 
else { /*...*/}

Comma operator:

a = (++i, k);  //eq: ++i; a = k;
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if(constant=variable)
{
work();
}
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