58

In a function that takes several arguments of the same type, how can we guarantee that the caller doesn't mess up the ordering?

For example

void allocate_things(int num_buffers, int pages_per_buffer, int default_value ...

and later

// uhmm.. lets see which was which uhh..
allocate_things(40,22,80,...
  • 4
    Compiler can help you most of the times. Otherwise, it's your(programmer) responsibilities. – P.P. Aug 8 '16 at 19:05
  • 7
    Isn't this easy in C++ by using specific types? – alk Aug 8 '16 at 19:15
  • 18
    Could you use method chaining? Something like allocate_thing().buffers(40).pages_per_buffer(22).default_value(80) – Mark Plotnick Aug 8 '16 at 19:42
  • 6
    This is a good question. I think the only real solution is to create value-types for each item that needs configuring. Like the <chrono> library uses durations such as std::chrono::seconds to configure time periods. – Galik Aug 8 '16 at 20:01
  • 6
    @gnasher - agreed, that's a dangerous function - that makes it a particularly good example. – Toby Speight Aug 9 '16 at 14:23
69

A typical solution is to put the parameters in a structure, with named fields.

AllocateParams p;
p.num_buffers = 1;
p.pages_per_buffer = 10;
p.default_value = 93;
allocate_things(p);

You don't have to use fields, of course. You can use member functions or whatever you like.

  • 10
    @FrankPuffer: Yes, agreed, but this is not the code review stack exchange. If you have comments about the original author's code, they belong as comments on the question, not on the answers. This code sample is designed to illustrate a particular technique and nothing else. – Dietrich Epp Aug 8 '16 at 19:24
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    @FrankPuffer: I think it's clear that these are just placeholder names. – Dietrich Epp Aug 8 '16 at 19:26
  • 6
    @Galik With this pattern, the programmer would have to be a lot more asleep to get it wrong, since they are required to refer to the fields by name. (until they forget why they did it and think it's clever to pass by braced init-list, ending with the original problem + new pointless filler [edit: nate, we've done it again]) – underscore_d Aug 8 '16 at 19:51
  • 4
    @Galik i.e. allocate_things({ 1, 10, 93 }); – nate Aug 8 '16 at 19:51
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    @FrankPuffer: I think it's clear that this is not supposed to be a real function. Your assertion that the function "does too many things" is basically unfounded—the only information you have for that is the function name, which again, is obviously made up! It might as well be foo(). This kind of tangential commentary is my biggest source of frustration with Stack Overflow. – Dietrich Epp Aug 8 '16 at 20:28
30

If you have a C++11 compiler, you could use user-defined literals in combination with user-defined types. Here is a naive approach:

struct num_buffers_t {
    constexpr num_buffers_t(int n) : n(n) {}  // constexpr constructor requires C++14
    int n;
};

struct pages_per_buffer_t {
    constexpr pages_per_buffer_t(int n) : n(n) {}
    int n;
};

constexpr num_buffers_t operator"" _buffers(unsigned long long int n) {
    return num_buffers_t(n);
}

constexpr pages_per_buffer_t operator"" _pages_per_buffer(unsigned long long int n) {
    return pages_per_buffer_t(n);
}

void allocate_things(num_buffers_t num_buffers, pages_per_buffer_t pages_per_buffer) {
    // do stuff...
}

template <typename S, typename T>
void allocate_things(S, T) = delete; // forbid calling with other types, eg. integer literals

int main() {
    // now we see which is which ...
    allocate_things(40_buffers, 22_pages_per_buffer);

    // the following does not compile (see the 'deleted' function):
    // allocate_things(40, 22);
    // allocate_things(40, 22_pages_per_buffer);
    // allocate_things(22_pages_per_buffer, 40_buffers);
}
  • 4
    ... oh wow . +1; this is very interesting. But I don't know whether I do or don't want to find a scenario where I would need it... ;-) – underscore_d Aug 9 '16 at 13:25
  • 1
    This looks like it can be macro-ified. – rubenvb Aug 9 '16 at 15:38
  • What if 40 were a variable instead of a literal? – Barry Aug 9 '16 at 20:25
  • @Barry I guess if 40 were a variable, it would have a meaningful name. operator"" would not be used. – sergej Aug 9 '16 at 20:34
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    @Joker_vD: User-defined literal suffixes are the other way around. Suffixes that don't start with _ are reserved. (C++11 §17.6.4.3.5; don't have the section for later versions.) – cHao Aug 10 '16 at 6:19
30

Two good answers so far, one more: another approach would be to try leverage the type system wherever possible, and to create strong typedefs. For instance, using boost strong typedef (http://www.boost.org/doc/libs/1_61_0/libs/serialization/doc/strong_typedef.html).

BOOST_STRONG_TYPEDEF(int , num_buffers);
BOOST_STRONG_TYPEDEF(int , num_pages);

void func(num_buffers b, num_pages p);

Calling func with arguments in the wrong order would now be a compile error.

A couple of notes on this. First, boost's strong typedef is rather dated in its approach; you can do much nicer things with variadic CRTP and avoid macros completely. Second, obviously this introduces some overhead as you often have to explicitly convert. So generally you don't want to overuse it. It's really nice for things that come up over and over again in your library. Not so good for things that come up as a one off. So for instance, if you are writing a GPS library, you should have a strong double typedef for distances in metres, a strong int64 typedef for time past epoch in nanoseconds, and so on.

  • 2
    For integers in particular, scoped enum is a decent choice. – T.C. Aug 8 '16 at 19:47
  • You can go one step further with this approach by using user defined literals to reduce the syntactic overhead of using customs types when making calls. – nate Aug 8 '16 at 19:50
  • 2
    you can get a call that looks like allocate_things(40_buffers,22_pages, 80... and if you don't put the values in the right places, it gives you a compiler error. – nate Aug 8 '16 at 19:57
  • @T.C. Good point, feel free to edit. – Nir Friedman Aug 8 '16 at 21:21
  • @nate good point, feel free to edit. – Nir Friedman Aug 8 '16 at 21:21
9

(Note: post was originally tagged 'C`)

C99 onwards allows an extension to @Dietrich Epp idea: compound literal

struct things {
  int num_buffers;
  int pages_per_buffer;
  int default_value 
};
allocate_things(struct things);

// Use a compound literal
allocate_things((struct things){.default_value=80, .num_buffers=40, .pages_per_buffer=22});

Could even pass the address of the structure.

allocate_things(struct things *);

// Use a compound literal
allocate_things(&((struct things){.default_value=80,.num_buffers=40,.pages_per_buffer=22}));
  • 1
    But this is about C++. Which doesn't import compound literals from C. – underscore_d Aug 8 '16 at 19:39
  • 1
    @underscore_d The post was about C until edited. (The post does still makes sense in a C context - unclear on OP/πάντα ῥεῖ change. - now see it to correlate to title) – chux - Reinstate Monica Aug 8 '16 at 19:40
  • 1
    Yup, just saw that. Fair play as per the original tags. Although the title always disagreed. If only people would tag what they really mean... sigh – underscore_d Aug 8 '16 at 19:40
  • 1
    Don't use a pointer, use a reference. Using a pointer means that the function has to handle the nullptr case, and using a reference requires the object to exist. Also nowadays the general advice is to avoid pointers and use smart pointers instead – Pharap Aug 9 '16 at 0:24
  • 1
    @Pharap Post was originally tagged C and this answer relates to that and so the reference idea of yours has merit with C++. OP's post has since dropped the C tag. – chux - Reinstate Monica Aug 9 '16 at 1:08
7

You can't. That's why it is recommended to have as few function arguments as possible.

In your example you could have separate functions like set_num_buffers(int num_buffers), set_pages_per_buffer(int pages_per_buffer) etc.

You probably have noticed yourself that allocate_things is not a good name because it doesn't express what the function is actually doing. Especially I would not expect it to set a default value.

  • 3
    And to separate responsibilities. – Charles Addis Aug 8 '16 at 19:04
  • 3
    and don't use magic numbers, hard-coding parameters like you do usually leads to more pain than its worth. – Cody Aug 8 '16 at 19:06
  • 2
    this introduces unnecessary (potentially global) state to the system – nate Aug 8 '16 at 19:42
  • 1
    @nate Does a function count as "state"? I must've missed that memo. Or do you mean that having separate functions for properties that might have to interact later means that they need to be stored during the process of setting them up? – underscore_d Aug 8 '16 at 19:43
  • 4
    in order to for set_XXX to affect a future allocate_things call, the arguments must be stored somewhere. – nate Aug 8 '16 at 19:44
7

Just for completeness, you could use named arguments, when your call becomes.

void allocate_things(num_buffers=20, pages_per_buffer=40, default_value=20);
// or equivalently
void allocate_things(pages_per_buffer=40, default_value=20, num_buffers=20);

However, with the current C++ this requires quite a bit of code to be implemented (in the header file declaring allocate_things(), which must also declare appropriate external objects num_buffers etc providing operator= which return a unique suitable object).

---------- working example (for sergej)

#include <iostream>

struct a_t { int x=0; a_t(int i): x(i){} };
struct b_t { int x=0; b_t(int i): x(i){} };
struct c_t { int x=0; c_t(int i): x(i){} };

// implement using all possible permutations of the arguments.
// for many more argumentes better use a varidadic template.
void func(a_t a, b_t b, c_t c)
{ std::cout<<"a="<<a.x<<" b="<<b.x<<" c="<<c.x<<std::endl; }
inline void func(b_t b, c_t c, a_t a) { func(a,b,c); }
inline void func(c_t c, a_t a, b_t b) { func(a,b,c); }
inline void func(a_t a, c_t c, b_t b) { func(a,b,c); }
inline void func(c_t c, b_t b, a_t a) { func(a,b,c); }
inline void func(b_t b, a_t a, c_t c) { func(a,b,c); }

struct make_a { a_t operator=(int i) { return {i}; } } a;
struct make_b { b_t operator=(int i) { return {i}; } } b;
struct make_c { c_t operator=(int i) { return {i}; } } c;

int main()
{
  func(b=2, c=10, a=42);
}
6

Are you really going to try to QA all the combinations of arbitrary integers? And throw in all the checks for negative/zero values etc?

Just create two enum types for minimum, medium and maximum number of buffers, and small medium and large buffer sizes. Then let the compiler do the work and let your QA folks take an afternoon off:

allocate_things(MINIMUM_BUFFER_CONFIGURATION, LARGE_BUFFER_SIZE, 42);

Then you only have to test a limited number of combinations and you'll have 100% coverage. The people working on your code 5 years from now will only need to know what they want to achieve and not have to guess the numbers they might need or which values have actually been tested in the field.

It does make the code slightly harder to extend, but it sounds like the parameters are for low-level performance tuning, so twiddling the values should not be perceived as cheap/trivial/not needing thorough testing. A code review of a change from allocate_something(25, 25, 25);

...to

allocate_something(30, 80, 42);

...will likely get just a shrug/blown off, but a code review of a new enum value EXTRA_LARGE_BUFFERS will likely trigger all the right discussions about memory use, documentation, performance testing etc.

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