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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
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55 Answers 55

Use of const keyword in pointers context :

The difference between following declarations :

 A)   const char* pChar  // pointer to a CONSTANT char  
 B)   char* const pChar  // CONSTANT pointer to a char  
 C)   const char* const pChar  // Both

So with A :

const char* pChar = 'M';
*pChar = 'S'; // error : you can't modify value pointed by pChar

and with B :

char OneChar = 'M';
char AnotherChar = 'S';
char* const pChar = &OneChar;
pChar = &AnotherChar; // error : you can't modify address of pChar
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My teachers spent so much time teaching us that pointers are scary little goobers that can cause lots of problems if not used correctly, that they never bothered to show us how powerful they can really be.

For example, the concept of pointer arithmetic was foreign to me until I had already been using C++ for several years:

Examples:

  • c[0] is equivalent to *c
  • c[1] is equivalent to *(c + 1)
  • Loop iteration: for(char* c = str; *c != '\0'; c++)
  • and so on...

Rather than making students afraid to use pointers, teach them how to use them appropriately.

EDIT: As brought to my attention by a comment I just read on a different answer, I think there is also some value in discussing the subtle differences between pointers and arrays (and how to put the two together to facilitate some pretty complex structures), as well as how to properly use the const keyword with respect to pointer declarations.

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Personally, as a teacher, I think teachers should teach BOTH. students need both to understand the power of pointers, but they also need to respect them. Beginners SHOULD be a little afraid of pointers, but not so afraid that they never use them and then actually understand them... –  Brian Postow Aug 10 '09 at 15:16
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@Brian: I can't disagree more. Fear keeps students from learning new things. They'll get the respect for pointers after fixing their first few memory leaks, segfaults and out-of-bounds errors, but they'll never get that far otherwise. –  Paul Biggar Aug 10 '09 at 16:53
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They really should learn to use helper tools (i.e. anything other than the compiler).

1) Valgrind is an excellent tool. It's phenomenally easy to use and it tracks down memory leaks and memory corruption perfectly.

It'll help them understand C's memory model: what it is, what you can do, and what you shouldn't do.

2) GDB + Emacs with gdb-many-windows. Or any other integrated debugger, really.

It'll help those that are to lazy to step through the code with pencil and paper.


Not really restricted to C; here's what I think they should learn:

1) How to properly write code: How to write unmaintainable code. Reading that, I found at least three crimes I was guilty of.

Seriously, we write code for other programmers. Thus, it's more important for us to write clearly than it is to write smartly.

You say your students aren't actually programmers (they're engineers). So, they shouldn't be doing tricky things, they should focus on clear coding.

2) STFW. When I started programming (I started in Pascal, than moved to C), I did it by reading books. I spent countless hours trying to figure out how to do stuff.

Later on, I found that everything I had had to figure out had already been done by many others, and at least one of them had posted it online.

Your students are engineers; they don't have as much time to devote to programming. So, the little time they have, they should spend reading other people's code and, maybe, brushing up on idioms.


All in all, C's a pretty easy language to learn. They'll have a lot more trouble writing anything longer than a few lines than they'll have learning independent notions.

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When I had to use C as part of a larger project in school it was the ability to use gdb properly (i.e. at all) that ended up predicting who would finish their project and who would not. Yeah if things get crazy and you have tons of pointer and memory related bugs gdb will show weird information but even knowing that can point people in the right direction.

Also reminding them that C isn't C++, Java, C#, etc. is a good idea. This comes up most frequently when you see someone treating a char* like a string in C++.

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unsigned vs signed.

Bit shift operators

Bit masking

Bit setting

integer sizes (8-bit, 16-bit, 32-bit)

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+1 for bitshifting - also, bitmasking. –  Meredith L. Patterson Aug 10 '09 at 14:40
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Object orientation:

struct Class {
    size_t size;
    void * (* ctor) (void * self, va_list * app); // constructor method
    void * (* dtor) (void * self);                // destructor method
    void (* draw) (const void * self);            // draw method
};

(Code source)

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+1 for noting that you can do OO without explicit support for it in your language. –  Jon Aug 10 '09 at 14:50
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C++ does all this work for you so you can focus on actually coding, not doing it by hand. I know they are different languages, but C++ is superior in almost any way. You can do this (the answer) in C++ cleanly, and let the compiler take care of the details. So, why not learn C++ and use it rather than do a poor imitation of it. The only two reasons I can think of for not using C++ over C are compiler options (embedded systems) and existing code base. –  GManNickG Aug 10 '09 at 15:04
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The OP notes that the students are mainly studying electronics and signal processing. So compiler options are very likely the reason for learning to do things like this in C. –  John D. Aug 10 '09 at 15:20
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Meh, comments are used for commenting. –  GManNickG Aug 10 '09 at 15:20
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Not suitable for beginners! –  Norman Ramsey Aug 10 '09 at 17:24
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Portability -- rarely taught or mentioned in school, but comes up a lot in the real world.

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The (dangerous) side effects of macros.

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Tools are important, so I'd recommend to at least mention something about

  • Makefiles and how the build process works
  • gdb
  • lint
  • the usefulness of compiler warnings

Concerning C, I think it's important to stress that the programmer should know what "undefined behaviour" really means, i.e. to know that there could be a future problem even if it seems to work with the current compiler/platform combination.

Edit: I forgot: teach them how to search and ask proper questions on SO!

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Use a consistent and readable coding style.

(This should help you in reviewing their code as well.)

Related: Don't prematurely optimize. Profile first to see where the bottleneck is.

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Know that when you increment a pointer, the new address depends upon the size of the data pointed to by that pointer... (IE, what's the difference between a char* being incremented and an unsigned long*)...

Knowing exactly what a segmentation fault really is first of all, and also how to deal with them.

Knowing how to use GDB is great. Knowing how to use valgrind is great.

Develop a C programming style... For example, I tend to write fairly object oriented code when I write large C programs (usually, all the functions in a particular .C file accept some (1) particular struct* and operate on it... I tend to have foo* foo_create() and foo_destroy(foo*) ctor's and dtors...)...

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Understanding the linker. Anyone using C should understand why "static int x;" at file scope does not create a global variable. The exercise of writing a simple program where every function is in its own translation unit and compiling each separately is not done often enough in the early stages of learning C.

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Always active warnings. With GCC, use at least -Wall -Wextra -Wstrict-prototypes -Wwrite-strings.

I/O is difficult. scanf() is evil. gets() should never be used.

When you print something which isn't '\n'-terminated, you have to flush stdout if you want to print it immediatly, e.g.

printf("Type something: ");
fflush(stdout);
getchar();

Use const pointers whenever possible. E.g. void foo(const char* p);.

Use size_t for storing sizes.

Litteral strings generally can't be modified, so make them const. E.g. const char* p = "whatever";.

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Why not include -Werror ? Else there is a temptation to neglect the warnings. –  Andrew Y Aug 10 '09 at 18:07
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  • Trashed memory can trigger all sorts of weird bugs.
  • Debuggers can lie to you.
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It would be helpful to say how debuggers can lie to you. For example, they initialize memory to zero, and change thread ordering (hiding race conditions in some cases). –  Paul Biggar Aug 10 '09 at 15:13
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I think that the overall idea seems really good. These are some extra stuff.

  1. A debugger is a good friend.
  2. Check the boundaries.
  3. Make sure that the pointer is actually pointing to something before it is used.
  4. Memory management.
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Hope this wasn't posted before (just read through very quickly), but I think what is very important when you have to work with C, is to know about the machine representation of data. For example: IEEE 754 floating point numbers, big vs little endian, alignment of structs (here: Windows vs Linux)... To practice this, it is very useful to make some bit-puzzles (solving some problems without using a any functionality then printf to print the result, a limited number of variables and some logical operators). Also it is often useful to have a basic knowledge about how a linker works, how the whole compiling process works etc.. But especially understanding the linker (without that, it is so hard to find some kind of errors...)

The book which helped me most to improve my C and C++ skills was: http://www.amazon.com/Computer-Systems-Programmers-Randal-Bryant/dp/013034074X

I think that a deep knowledge about computer architecture makes the difference between a good and a bad C programmer (or at least it is a significant factor).

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Teach them unit testing.

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How about general best practices?

  • Always assume that someone else has already written your code and that it is both freely available on the internet and better written and tested than anything you'll produce before your deadline.
  • Return early / Avoid else clauses
  • Initialize all variables
  • One page per function as a guideline (i.e. Use smaller pieces of code together)
  • When to use switch, if-else if, or a hash table
  • Avoid global variables
  • Always check your inputs and your outputs (I don't trust my own code.)
  • Most functions should return a status

    [ To others: feel free to edit this and add to the list ]

Regarding checking inputs:

I once wrote a big program in a hurry and I wrote all kinds of Guard Clauses, input checks, into my functions. When I ran the program for the first time, the errors from those clauses streamed by so fast I couldn't even read them, but the program did not crash and could be shut down cleanly. It was then a simple matter of going through the list and fixing bugs which went surprisingly fast.

Think of Guard Clauses as run-time compiler warnings and errors.

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I don't think you should be teaching tools. That should be left to Java teachers. They are useful and widely used but have nothing to do with C. A debugger is as much as they should hope to get access to. Many times all you get is printf and/or a blinking LED.

Teach them pointers but teach them well, telling them that they are an integer variable representing a position in memory(in most courses they also have some training in assembly even if it is for some imaginary machine so they should be able to understand that) and not an asterisk prefixed variable that somehow points to something and that sometimes becomes an array(C is not Java). Teach them that C arrays are just pointer + index.

Have them write programs that will overflow and segfault for sure and after that, make sure they understand why it happened.

The standard library is also C, have them use it and have their programs die painfully in your private tests because of having used gets() and strcpy() or double-freed something.

Force them to deal with variables of different type, endianness(Your tests could run in a different arch), float to int conversion. Make them use masks and bitwise operators.

i.e. teach them C.

What I got instead was some batch processing in C that could as well have been done in GW-BASIC.

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keyword: volatile

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Seriously? How often has that come up for you doing basic stuff in C? –  Jon Aug 10 '09 at 14:44
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The one time I've needed it the compiler had a bug and ignored it! On the 16bit ISA bus on the PC you read a word by reading the same byte address twice. Which the compiler optimizes out, on the Zortech C++ compiler even if you add volatile. –  Martin Beckett Aug 10 '09 at 14:51
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For hardware-type programmers, volatile is very much needed. There are all kinds of hardware interfaces that demand that you access them in a very specific way. –  Robert Aug 10 '09 at 17:10
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  1. Check the boundaries
  2. Check the boundaries,

    and of course,

  3. Check the boundaries.

And if you forgot one of these rules, use Valgrind. This applies to arrays, strings, and pointers, but it's really very easy to forget about what you're really doing when doing allocations and memory aritmethics.

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  • Where the language ends and the implementation begins: e.g., stdio.h is part of the standard library, conio.h is not, stuff like that;
  • The difference between undefined and implementation-defined behavior, and why things like x=x++ are undefined;
  • Just because it compiles doesn't mean it's right;
  • The difference between precedence and order of evaluation, and why a * b + c doesn't guarantee that a will be evaluated before b or c;
  • "It works on my machine" does not trump behavior specified by the language standard: e.g., just because void main() or x = x++ is giving you the results you expect for a specific platform and compiler doesn't mean it's okay to use;
  • Pretend you never heard of gets();
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The debugger is your friend. C is an easy language to mess up and the best way to understand your mistakes is often to see them under a debugger.

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It would be beneficial if the students were at some point exposed to tools that can help them write cleaner, better code. The tools may not all be relevant to them at this stage, but knowing what is available helps.

One should also stress the use of different (!) compilers with strict compiler warning flags and attending to each and every warning message.

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Given their background, perhaps a good focus on C for embedded systems, including:

  • Static analysis tools (e.g. PC-Lint)
  • MISRA-C.
  • Exposure to multiple processors (e.g. PIC, STM32) and compilers
  • How to debug.
  • Real-time issues, including interrupts, debouncing signals, simple scheduling/RTOS.
  • Software design.

And very significantly: version control software. I work in industry and use it religiously, yet I'm astounded that it was never mentioned in the course of my degree!

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There are too many to name them all. Some of them are C specific; some of them are general best-practices kinds of things.

  • Learn to use the tools available
    • Revision control system. Every time it works, check it in.
    • Diff tools: diff, rdiff, meld, kdiff3, etc. Especially in conjunction with the RCS.
    • Compiler options. -Wextra -Wall __attribute__((aligned(8))), how to pack structs.
    • make: Produce debug and production versions
    • debugger: How to get and interpret a stack trace. How to set breakpoints. How to step through/over code.
    • Editor: Compile within the editor. Open multiple windows, M-x tags-query-replace (are my emacs roots showing?) etc.
    • cscope, kscope, [ce]tags, or other source browsing tools
  • Program defensively. assert(foo != NULL) in -DDEBUG; scrub user inputs.
  • Halt and Catch Fire when an error is detected. Debugging is easier when you core dump 2 lines after you detect the problem.
  • Maintain a 0-warning compile with -Wextra and -Wall enabled.
  • Don't put everything into 1 huge honking .c file.
  • Test. Test. And test some more. And check those tests in alongside your source. Because the instructor might come back and change the requirements after it's been turned in once.
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Go over the whole programming life cycle, including what happens to your code after you're done with it.

  • Pre-planning stages, and a bit on how to look for an existing project/existing code you can use to reduce the amount of original code
  • A small (Basic) overview of licenses and how that external code affects what licenses you can and can't use (and other considerations that go into licensing)
  • Concurrent version control, and versioning. I'd do SVN/Git, but to each his own. You will save them SO MUCH time if you introduce it to them now rather than learning on the job.
  • Show them what avenues there are for open-sourcing code (Google Code, Github, etc.) and when/how to tell if it's appropriate or not.

None of this is C-specific, but I add it because I personally just went through the 'C for Electrical Engineers' at my university, and this is all stuff I had to find out on my own.

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An important notion in C that I did not learn from my teachers is:

Operator * does not mean "pointer to" (on the left-hand side). It is instead the dereference operator - exactly as it is on the right-hand side (yes, I know it is disturbing to some).

Thus:

int *pInt

means that when pInt is dereferenced you get an int. Thus pInt is a pointer to int. Or put differently: *pInt is an int - dereferenced pInt is an int; pInt must then be a pointer to int (otherwise we would not get an int when it is dereferenced).

This means it is not necessary to learn more complicated declarations by heart:

const char *pChar

*pChar is of type const char. Thus pChar is a pointer to const char.


char *const pChar

*const pChar is of type char. Thus const pChar is a pointer to char (pChar itself is constant).


const char *const pChar

*const pChar is of type const char. Thus const pChar is a pointer to const char (pChar itself is constant).

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Indent Style. All teachers were saying that code must be indented but noone really gave directions on how to indent. I remember all students' code was really a mess.

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