I was recently reminded of why I think it’s a bad idea to teach beginners C++. It’s a bad idea because it is an objective mess—albeit a beautiful, twisted, tragic, wondrous mess. Despite the current state of the community, this post is not a polemic against modern C++. This post is partly a follow-up on Simon Brand’s article, Initialization in C++ is bonkers, and partly a message to every student who’s wanted to begin their education by gazing into the abyss.

Here are some common remarks I get when students find out they’ll be using C:

“People still use C?”

“C is stupid.”

“Why are we learning C?”

“We should be learning something better like C++.” (cue laugh track)

Many students seem to think learning C is of little relevance (narrator: it’s not) and, more relevant to this post, seem to think that they should instead start with C++. Let’s investigate just one of the reasons this is an absurd suggestion: creating a frickin’ variable. In Simon Brand’s original article, he assumed the reader was already familiar with pre-C++11 initialization oddities. I’ll introduce some of those here and go a bit beyond, too.

Let me preface by pointing out that, although I currently work for Drexel University’s Electrical and Computer Engineering department, the thoughts and opinions in this post—and every post—are my own and not the university’s. The classes I normally assist/instruct are part an engineering curriculum and not computer science, and thus have different needs geared more towards embedded systems and systems programming.

RECORD SCRATCH

u/AlexAlabuzhev on reddit was able to sum up my entire post with a simple gif. (I believe original credit goes to Timur Doumler)

That about sums up this post. I’m not hating on C++, but it’s got a lot of stuff you don’t need early on.

That’s it. Go home. Walk the dog. Do some laundry. Call mom and tell her you love her. Try a new recipe. Nothing to see here, folks. Let’s take a moment to appreciate how much better artists can be at communicating ideas than engineers (read: me) … okay moment’s up!

Oh hey you’re still with me. You’re a real trooper. If I could give you a star, I absolutely would! Chocolate milk for you at lunch! 🍫

We now resume our normal…programming.

Initialization in C

Prologue

First let’s look at initialization in C, since it’s similar to C++ for compatibility reasons. This should go by fairly quick since C is so boring and simple (ahem). Initialization is hammered into anyone new to the language because it acts rather differently in C than in many newer statically typed languages, that will either default to sane values or provide compile time errors if used uninitialized.

int main () { int i ; printf ( "%d" , i ); }

Any C programmer worth anything knows that this initializes i to an indeterminate value (for all intents and purposes, i is uninitialized). Generally, it’s good practice to initialize variables when they are defined, e.g. int i = 0; , and variables must always be initialized before they’re used. No matter how many times we repeat, shout, scream, badger gently remind students about this, there are still those who think it gets initialized to 0 by default.

Great, let’s try something else simple.

int i ; int main () { printf ( "%d" , i ); }

So this is obviously the same, right? We have no idea what value i might have when we print—it could be anything.

Nope.

Because i has static storage duration, it’s initialized to unsigned zero. Why, you ask? Because the standard says so. This has similar behavior for pointer types, which I’m not even going to address in this post.

O-kay, let’s look at structs.

struct A { int i ; }; int main () { struct A a ; printf ( "%d" , a . i ); }

Same deal. a is uninitialized. We can see this if we compile with warnings.

$ gcc -Wuninitalized a.c a.c: In function ‘main’: a.c:9:5: warning: ‘a.i’ is used uninitialized in this function [-Wuninitialized] printf("%d

", a.i);

In C, we can initialize our object a few straight-forward ways. For example: 1) by using a helper function, 2) initializing during definition, or 3) assigning some default global value.

struct A { int i ; } const default_A = { 0 }; void init_A ( struct A * ptr ) { ptr -> i = 0 ; } int main () { /* helper function */ struct A a1 ; init_A ( & a1 ); /* during definition; * Initialize each member, in order. * Any other uninitialized members are implicitly * initialized as if they had static storage duration. */ struct A a2 = { 0 }; /* Error! (Well, technically) Initializer lists are 'non-empty' */ /* struct A a3 = {}; */ /* ...or use designated initializers if C99 or later */ struct A a4 = {. i = 0 }; /* default value */ struct A a5 = default_A ; }

Update—Originally I had struct A a3 = {}; , which I believed implicitly initialized all members. I’ve since been informed that this is not standard C! An initializer list in C must be non-empty (compiling with -pedantic correctly identifies this).

That’s pretty much it for C, and it’s enough to cause many tricksy bugs to manifest in many student projects. It’s certainly enough to cause a minor headache deciding how to simply default everything to 0 .

Initialization in C++

Act 1: Our Hero’s Journey Begins

If you’re eager to learn all the terrors wonders of C++, you should first learn how to initialize your variables. All the same behaviors apply for C++ as in C for the previous code, with some caveats in the rules for those behaviors. C++-specific lingo will be italicized to emphasize when I’m not just arbitrarily naming things and to emphasize how many more…features…C++ has compared to C. Let’s start off with an easy one:

struct A { int i ; }; int main () { A a ; std :: cout << a . i << std :: endl ; }

C++ has almost the same behavior as C here. In C, this just creates an object of type A whose value could be anything. In C++, a is default initialized, meaning its default constructor is used to construct it. Because A is so trivial, it has an implicitly-defined default constructor which does nothing in this case. The implicitly-defined default constructor “has exactly the same effect” as:

struct A { A (){} int i ; }

To check that we’re getting an uninitialized value, we can opt for a compile-time warning. As of this post, I’ve found that g++ 8.2.1 provides good warnings, while clang++ 7.0.1 does not for this case (with -Wuninitialized ). Note that optimizations are turned on to catch some extra examples where variables would be uninitialized.

$ g++ -Wuninitalized -O2 a.cpp a.cpp: In function ‘int main()’: a.cpp:9:20: warning: ‘a.A::i’ is used uninitialized in this function [-Wuninitialized] std::cout << a.i << std::endl;

So in essence, this is as we’d expect coming from C. So how do we initialize A::i ?

Act 2: Our Hero Stumbles

Well, we could at least use the same ways as we did in C, right? C++ is a superset of C, after all, right? (ahem)

struct A { int i ; }; int main () { A a = {. i = 0 }; std :: cout << a . i << std :: endl ; }

$ g++ -Wuninitialized -O2 -pedantic-errors a.cpp a.cpp: In function ‘int main()’: a.cpp:9:12: error: C++ designated initializers only available with -std=c++2a or -std=gnu++2a [-Wpedantic] A a = {.i = 0};

Well there goes the neighborhood. Apparently designated initializers aren’t supported in C++ until C++20. That is, the C++ standards targeted for 2020. Yes, C++ is getting a feature 21 years after C. Note that I’ve added -pedantic-errors to remove support for non-standard gcc extensions.

What about this?

struct A { int i ; }; int main () { A a = { 0 }; std :: cout << a . i << std :: endl ; }

$ g++ -Wuninitialized -O2 -pedantic-errors a.cpp $

Well at least that works. We can also do A a = {}; and it will have the same effect of zero-initializing a.i . That’s because A is an aggregate type. What’s an aggregate type?

In pre-C++11 world: an aggregate type is (essentially) either a simple C-style array, or a struct that looks like a simple C struct. No access specifiers, no base classes, no user-declared constructors, no virtual functions. An aggregate type gets aggregate initialized. What’s aggregate initialization?

Each member of the aggregate is initialized by each element of the braced list in order. Each member without a corresponding element braced list will get value initialized.

Great, what does that mean? If the member is another class type with a user-provided constructor, it’ll be called. If the member is a class type without a user-provided constructor, like A , it’ll be recursively value-initialized. If the member is a built-in like our int i , then it’s zero-initialized.

HooOOooOOrraay! We finally achieved a sort-of-default value of zero! Whew.

In post-C++11 world: …we’ll get to that later.

Does that seem hard to remember and confusing? Note there’s a different set of rules for each version of C++. It is. It’s frickin’ confusing and no one likes it. These rules are mostly in place so things act like you’d expect them to when you go to initialize something with nothing. In practice, it’s best to explicitly initialize. I’m not picking on aggregate initialization in its own right. I’m picking on having to partake in a goose-chase through the standard to find out precisely what happens during initialization.

Act 3: Our Hero Journeys Into the Cave

Let’s use the C++ way to initialize A , with constructors! (triumphant music) We can give A ’s member, i , an initial value in a user-provided default constructor:

struct A { A () : i ( 0 ) {} int i ; };

This initializes i in a member initializer list. A smellier way would be to set the value inside the constructor body:

struct A { A () { i = 0 ; } int i ; };

Because the constructor body can pretty much do anything, it’s better to separate initialization into the member initializer list (technically a part of the constructor body).

In C++11 or later, we can use default member initializers (seriously, just use these when you can). struct A { int i = 0 ; // default member initializer, available in C++11 and later };

O-kay, now the default constructor ensures that i is set to 0 when any A is default initialized. Finally, if we wanted to allow users of A to set i ’s initial value, we could create another constructor just for that, or alternatively mush them together using default arguments:

struct A { A ( int i = 0 ) : i ( i ) {} int i ; }; int main () { A a1 ; A a2 ( 1 ); std :: cout << a1 . i << " " << a2 . i << std :: endl ; }

$ g++ -pedantic-errors -Wuninitialized -O2 a.cpp $ ./a.out 0 1

Note: We can’t write A a(); to call the default constructor because it gets parsed as: a declaration of a function, named a , that takes no arguments and returns an A object. Why? Because someone somewhere a long time ago wanted to allow function declarations in compound statement blocks, and now we’re stuck with it.

Great! That’s it. Mission accomplished. Roll credits. You are now ready your adventures into C++ primed with your handy-dandy C++ survival guide with instructions on initializing variables. Turn around and be on your way!

Act 4: Our Hero Continues Into the Blackness

We could stop there. But, if we want to use the modern features of modern C++, we have to delve further. In fact the version of g++ I’ve been using (8.2.1) uses gnu++1y by default, which equivalent to C++14 with some extra GNU extensions. Even more, this version of g++ also fully supports C++17. “Does that matter?” you might ask. Put on your fishing waders and wade with me yonder.

All versions following, and including, C++11, have this new-fangled way to initialize objects, called list initialization. Did anyone else feel a chill up their spine just now? This is also referred to as uniform initialization. There are some good reasons to use this syntax, covered here and here. One amusing quote from the FAQ:

C++11 uniform initialization is not perfectly uniform, but it’s very nearly so.

List initialization uses braces ( {thing1, thing2, ...} , called a braced-init-list) and looks like this:

1 2 3 4 5 6 7 8 9 10 #include <iostream> struct A { int i ; }; int main () { A a1 ; // default initialization -- as before A a2 {}; // direct-list-initialization with empty list A a3 = {}; // copy-list-initialization with empty list std :: cout << a1 . i << " " << a2 . i << " " << a3 . i << std :: endl ; }

$ g++ -std=c++11 -pedantic-errors -Wuninitialized -O2 a.cpp a.cpp: In function ‘int main()’: a.cpp:9:26: warning: ‘a1.A::i’ is used uninitialized in this function [-Wuninitialized] std::cout << a1.i << " " << a2.i << " " << a3.i « std::endl;

Whoa, whoa, whoa. Did you catch that? Only a1.i is uninitialized. Clearly, list initialization works differently than just calling a constructor.

A a{}; produces the same behavior as A a = {}; . In both, a is initialized with an empty braced-init-list. Also, A a = {}; isn’t called aggregate initialization anymore—now it’s copy-list-initialization (sigh). We already said that A a; creates an object with indeterminate value and calls the default constructor.

The following happens in lines 7/8 (remember, this is post-C++11):

List initialization of A , causes 2. aggregate initialization because A is an aggregate type. Because the list is empty, all members are initialized by empty lists. int i{} leads to value initialization which initializes i to 0.

What if the list isn’t empty?

int main () { A a1 { 0 }; A a2 {{}}; A a3 { a1 }; std :: cout << a1 . i << " " << a2 . i << " " << a3 . i << std :: endl ; }

$ g++ -std=c++11 -pedantic-errors -Wuninitialized -O2 a.cpp $

a1.i is initialized with 0 , a2.i is initialized with an empty list, and a3 is copy constructed from a1 . You know what a copy constructor is, right? Then you also know about move constructors and rvalue references and forwarding references and pr-values and x-values and gl-val…okay nevermind.

Unfortunately, the definition of an aggregate has changed in every version since C++11, although there is functionally no difference between C++17 and C++20 aggregates, so far. Depending on which version of the C++ standard is used, something may or may not be an aggregate. The trend is to be more permissive of what is considered an aggregate. For example, public base classes are allowed in aggregates as of C++17, which in turn complicates the rules of aggregate initialization. Everything is great!

How are you feeling? Do you need some water? Are your fists clenching? Maybe take a break, go outside.

Act 5: Sanity’s Requiem

What happens if A isn’t an aggregate?

Quick recap, an aggregate is:

an array, or

a struct/class/union with no private/protected members no user-(provided/declared) constructors no virtual functions no default member initializers (in C++11, doesn’t matter for later) no base classes (public bases allowed in C++17) no inherited constructors ( using Base::Base; , in C++17)



So not-an-aggregate could be:

1 2 3 4 5 6 7 8 9 #include <iostream> struct A { A (){}; int i ; }; int main () { A a {}; std :: cout << a . i << std :: endl ; }

$ g++ -std=c++11 -pedantic-errors -Wuninitialized -O2 a.cpp a.cpp: In function ‘int main()’: a.cpp:8:20: warning: ‘a.A::i’ is used uninitialized in this function [-Wuninitialized] std::cout << a.i << std::endl;

Here, A has a user-provided constructor so list initialization works differently.

The following happens on line 7:

List initialization of A , causes 2. Non-aggregate with an empty braced-init-list causes value initialization, go to 3. A user-provided constructor was found, so the default constructor called which does nothing in this case. a.i is uninitialized.

What’s a user-provided constructor anyway? struct A { A () = default ; }; The above is not a user-provided constructor. It’s as if no constructor was declared at all and A is an aggregate. struct A { A (); }; A :: A () = default ; The above is a user-provided constructor. It’s as if we wrote A(){} in the body and A is not an aggregate. Guess what, in C++20, the wording has changed to require aggregates to have no user-declared constructors 😊. What does that mean in practice? I’m not sure! Let’s carry on.

What about the following:

#include <iostream> class A { int i ; friend int main (); }; int main () { A a {}; std :: cout << a . i << std :: endl ; }

A is a class, not a struct, so i is private, and we had to set main as a friend function. That makes A not an aggregate. It’s just a normal class type. That means a.i will be uninitialized, right?

$ g++ -std=c++11 -pedantic-errors -Wuninitialized -O2 a.cpp $

Dangit. And just when we thought we were getting the hang of this. Turns out a.i will be initialized to 0 , even though it doesn’t invoke aggregate initialization:

List initialization of A , causes 2. Non-aggregate, class type with a default constructor, and an empty braced-init-list causes value initialization, go to 3. No user-provided constructor found, so zero-initialize the object, go to 4. Invoke default-initialization if the implicitly-defined default constructor is non-trivial (it is in this case so nothing is done).

What if we try aggregate initialization:

#include <iostream> class A { int i ; friend int main (); }; int main () { A a = { 1 }; std :: cout << a . i << std :: endl ; }

$ g++ -std=c++11 -pedantic-errors -Wuninitialized -O2 a.cpp a.cpp: In function ‘int main()’: a.cpp:7:13: error: could not convert ‘{1}’ from ‘<brace-enclosed initializer list>’ to ‘A’ A a = {1};

A is not an aggregate, so the following happens:

List initialization of A , causes 2. Search for a matching constructor No way to convert a 1 to an A , compilation fails

Update—bonus tricksy example:

#include <iostream> struct A { A ( int i ) : i ( i ) {} A () = default ; int i ; }; int main () { A a {}; std :: cout << a . i << std :: endl ; }

There are no private variables like in our previous example, but there is a user-provided constructor like in our previous-previous example—thus A is not an aggregate. The user-provided constructor precludes zero-initialization, right?

$ g++ -std=c++11 -pedantic-errors -Wuninitialized -O2 a.cpp $

Nope! Breaking it down:

List initialization of A , causes 2. Non-aggregate, class type with a default constructor, and an empty braced-init-list causes value initialization, go to 3. No user-provided default constructor found (my lie by omission above), so zero-initialize the object, go to 4. Invoke default-initialization if the implicitly-defined default constructor is non-trivial (it is in this case so nothing is done).

One last example for good measure:

#include <iostream> struct A { A (){} int i ; }; struct B : public A { int j ; }; int main () { B b = {}; std :: cout << b . i << " " << b . j << std :: endl ; }

$ g++ -std=c++11 -pedantic-errors -Wuninitialized -O2 a.cpp a.cpp: In function ‘int main()’: a.cpp:11:25: warning: ‘b.B::<anonymous>.A::i’ is used uninitialized in this function [-Wuninitialized] std::cout << b.i << " " << b.j << std::endl;

b.j is initialized but b.i is uninitialized. What’s happening in this example? I’m not sure! 🤷 All of b ’s bases and members should be getting zero-initialized here. I’ve asked about this on Stack Overflow, and as of publishing this post haven’t received a sufficient answer other than a possible compiler bug. there is some consensus that this is a compiler bug. These rules are subtle and complicated for everyone. For comparison, clang’s static analyzer (not the normal compiler warnings) does not warn about uninitialized values. Go figure.

… (blankly stares at you) (stare turns to polite smile) alright let’s dive deeper!

Act 6: The Abyss

C++11 introduced something called a std::initializer_list . It has its own type, which is obviously std::initializer_list<T> . You can create one with a braced-init-list. Oh by the way, a braced-init-list, used in list initialization, that has no type. Make sure you don’t confuse an initializer_list with list initialization or braced-init-lists! And they are sorta related to member initializer lists and default member initializers, in that they help initialize non-static data members, but are also quite different. They are related but different! Easy, right?

1 2 3 4 5 6 7 8 9 10 11 12 struct A { template < typename T > A ( std :: initializer_list < T > ) {} int i ; }; int main () { A a1 { 0 }; A a2 { 1 , 2 , 3 }; A a3 { "hey" , "thanks" , "for" , "reading!" }; std :: cout << a1 . i << a2 . i << a3 . i << std :: endl ; }

$ g++ -std=c++17 -pedantic-errors -Wuninitialized -O2 a.cpp a.cpp: In function ‘int main()’: a.cpp:12:21: warning: ‘a1.A::i’ is used uninitialized in this function [-Wuninitialized] std::cout << a1.i << a2.i << a3.i << std::endl; ^ a.cpp:12:29: warning: ‘a2.A::i’ is used uninitialized in this function [-Wuninitialized] std::cout << a1.i << a2.i << a3.i << std::endl; ^ a.cpp:12:37: warning: ‘a3.A::i’ is used uninitialized in this function [-Wuninitialized] std::cout << a1.i << a2.i << a3.i << std::endl;

O—kay. A has one templated constructor that takes a std::initializer_list<T> . The user-provided constructor is called each time, which does nothing, so i remains uninitialized. The type of T is deduced depending the elements in the list, and a new constructor is instantiated depending on the type.

So in line 8, {0} is deduced as a std::initializer_list<int> with one element, 0 .

is deduced as a with one element, . In line 9, {1, 2, 3} is deduced as a std::initializer_list<int> with three elements.

is deduced as a with three elements. In line 10, the braced-init-list is deduced as a std::initializer_list<const char*> with 4 elements.

Note: A a{} will produce an error because a type cannot be deduced. We would have to write A a{std::initializer_list<int>{}} , for example. Or, we could exactly specify the constructor as in A(std::initializer_list<int>){} .

std::initializer_list acts kinda like a typical STL container, but it only has three member functions: size , begin , and end . begin and end return iterators you can dereference, increment, and compare normally. This is useful when you want to initialize an object with varying length lists:

#include <vector> #include <string> int main () { std :: vector < int > v_1_int { 5 }; std :: vector < int > v_5_ints ( 5 ); std :: vector < std :: string > v_strs = { "neato!" , "blammo!" , "whammo!" , "egh" }; }

std::vector<T> has a constructor that takes a std::initializer_list<T> , so we can easily initialize vectors as shown above.

Note: v_1_int is a vector created from its constructor taking a std::initializer_list<int> init with one element, 5 .

v_5_ints is a vector created from its constructor taking a size_t count , which initializes a vector of count ( 5 ) elements and value-initializes them (all set to 0 in this case).

Okie–dokie, one last example:

1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 #include <iostream> struct A { A ( std :: initializer_list < int > l ) : i ( 2 ) {} A ( int i = 1 ) : i ( i ) {} int i ; }; int main () { A a1 ; A a2 {}; A a3 ( 3 ); A a4 = { 5 }; A a5 { 4 , 3 , 2 }; std :: cout << a1 . i << " " << a2 . i << " " << a3 . i << " " << a4 . i << " " << a5 . i << std :: endl ; }

At first glance, this isn’t too complicated. We have two constructors, one that takes a std::initializer_list<int> and another with default arguments taking an int . Before you look below at the output, try to figure out what will be the value for each i .

Thought about it…? Let’s see what we get.

$ g++ -std=c++11 -pedantic-errors -Wuninitialized -O2 a.cpp $ ./a.out 1 1 3 2 2

a1 should have been easy. This is simple default initialization, which chooses the default constructor using its default arguments. a2 uses list initialization with an empty list. Because A has a default constructor (with default arguments), value initialization occurs which just calls that constructor. If A didn’t have that constructor, then the constructor on line 3 would be called with an empty list. a3 uses parenthesis, not a braced-init-list, so the overload resolution matches 3 with the constructor taking an int . a4 uses list initialization, which overload resolution will more favorably match with a constructor taking a std::initializer_list . a5 obviously can’t match against a single int , so the same constructor as a4 is used.

Epilogue

Hopefully you’ve realized this post is (mostly) tongue-in-cheek and hopefully a bit informative, too. Many of the peculiarities described in this post can be ignored and the language will act as you’d expect if you remember to initialize your variables before use and initialize your data members during construction. Knowing all of the corner cases of C++ is not necessary to write competent code, and you will otherwise learn common pitfalls and idioms along the way. To be clear, list initialization is a good thing™. If you write a default constructor, it gets called and you’re expected to initialize everything there. Otherwise, everything gets zero-initialized and then default member initializers kick in regardless. Uninitialized behavior needs to stay around because somewhere, out in the ether, there is probably code that depends on variables being uninitialized.

The point I’ve hopefully gotten across is that C++ is a big, crusty language (for many historical reasons). This entire post was a rabbit hole on initialization rules. Just initializing variables. And we didn’t even cover all of it. This post briefly covers 5 types of initialization. Simon mentions in his original post that he found 18 types of initialization.

C++ is not a language I’d want to teach beginners. At no point in this post was there room for systems programming concepts, discourse on programming paradigms, computational-oriented problem solving methodologies, or fundamental algorithms. If you are interested in C++ then feel free to take a class specifically on C++, but know that the class will probably be specifically on learning C++. If you are interested in using C with classes or C with namespaces, then you can at least learn about the this implementation and identifier collisions in C beforehand.

C is a great, focused, fast, widely-supported, and widely-used language for solving problems across a variety of domains. And it doesn’t have at least 18 types of initialization.

Update—I had completely forgotten that I commented on this exact topic a month ago. The power of the subconscious on full display.

I don’t have a comments thingamabob (yet?). In lieu, here is the community’s discussion/critique at:

A response to the most common critique: Yes, you could be taught the sane ways to initialize variables and never see the abyss. I added in a to-be-clear in the Epilogue and in case I was not clear before. Personally, I rarely use templates, but I still use C++. That’s not the point. For early programmers, one could completely ignore the STL and just use the standard C library and ignore references and ignore exceptions and ignore inheritance. Now we’re approaching C with classes, except it isn’t C and you still don’t understand pointers and memory allocation or the stack and heap or virtual memory or volatile ports better than before. And now whenever I actually need C, I have to context switch back to a different language that I could have just learned anyway from the start. If you’re going to use C++, use C++. And if you want to use C++ without all the C++-ness, then just learn C 🙂. And goodness gracious, blistering barnacles, to reiterate from the first paragraph, I don’t have beef with C++. We should be able to acknowledge the warts on our loved ones and still love them ❤️.