It seems that auto was a fairly significant feature to be added in C++11 that seems to follow a lot of the newer languages. As with a language like Python, I have not seen any explicit variable declaration (I am not sure if it is possible using Python standards).

Is there a drawback to using auto to declare variables instead of explicitly declaring them?


14 Answers 14


The question is about drawbacks of auto, so this answer highlights some of those. A drawback of using a programming language feature (in this case, a facility associated with a language keyword) does not mean that feature is unacceptable, nor does it mean that feature should be avoided entirely. It means there are disadvantages along with advantages, so a decision to use auto type deduction over alternatives must consider engineering trade-offs.

When used well, auto has several advantages as well - which is not the subject of the question. The drawbacks result from ease of abuse, and from increased potential for code to behave in unintended or unexpected ways.

The main drawback is that, by using auto, you don't necessarily know the type of object being created. There are also occasions where the programmer might expect the compiler to deduce one type, but the compiler adamantly deduces another.

Given a declaration like

auto result = CallSomeFunction(x,y,z);

you don't necessarily have knowledge of what type result is. It might be an int. It might be a pointer. It might be something else. All of those support different operations. You can also dramatically change the code by a minor change like

auto result = CallSomeFunction(a,y,z);

because, depending on what overloads exist for CallSomeFunction() the type of result might be completely different - and subsequent code may therefore behave completely differently than intended. You might suddenly trigger error messages in later code(e.g. subsequently trying to dereference an int, trying to change something which is now const). The more sinister change is where your change sails past the compiler, but subsequent code behaves in different and unknown - possibly buggy - ways. For example (as noted by sashoalm in comments) if the deduced type of a variable changes an integral type to a floating point type - and subsequent code is unexpectedly and silently affected by loss of precision.

Not having explicit knowledge of the type of some variables therefore makes it harder to rigorously justify a claim that the code works as intended. This means more effort to justify claims of "fit for purpose" in high-criticality (e.g. safety-critical or mission-critical) domains.

The other, more common drawback, is the temptation for a programmer to use auto as a blunt instrument to force code to compile, rather than thinking about what the code is doing, and working to get it right.

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    It is interesting to note that if such examples are the drawback of using auto, then most duck-typed language suffer such drawback by design!
    – Leben Asa
    Commented Jan 13, 2016 at 7:45
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    If CallSomeFunction() returns a different type depending on the sequence of its arguments, that's a design defect of CallSomeFunction(), not a problem of auto. If you don't read the documentation of a function you are using prior to using it, that's a defect of the programmer, not a problem of auto. -- But I understand that you're playing devil's advocate here, it's just that Nir Friedman has the much better case.
    – DevSolar
    Commented Jan 13, 2016 at 8:51
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    @DevSolar: Why would T CallSomeFunction(T, int, int) be a design defect? Obviously it "returns a different type depending on the sequence of its arguments."
    – MSalters
    Commented Jan 13, 2016 at 8:59
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    "The main drawback is that, by using auto, you don't necessarily know the type of object being created." Can you elaborate on why this is a problem with auto, and not a problem with subexpression temporaries? Why is auto result = foo(); bad, but foo().bar() not? Commented Jan 13, 2016 at 10:56
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    It seems from comments that "drawback" is being interpreted as a reason that something is unacceptable. A drawback of a language feature is a disadvantage that the developer needs to consider and justify accepting or not - i.e. making engineering trade-offs. I am not making blanket claims about why the feature should or should not be used.
    – Peter
    Commented Jan 13, 2016 at 13:02

This isn't a drawback of auto in a principled way exactly, but in practical terms it seems to be an issue for some. Basically, some people either: a) treat auto as a savior for types and shut their brain off when using it, or b) forget that auto always deduces to value types. This causes people to do things like this:

auto x = my_obj.method_that_returns_reference();

Oops, we just deep copied some object. It's often either a bug or a performance fail. Then, you can swing the other way too:

const auto& stuff = *func_that_returns_unique_ptr();

Now you get a dangling reference. These problems aren't caused by auto at all, so I don't consider them legitimate arguments against it. But it does seem like auto makes these issue more common (from my personal experience), for the reasons I listed at the beginning.

I think given time people will adjust, and understand the division of labor: auto deduces the underlying type, but you still want to think about reference-ness and const-ness. But it's taking a bit of time.

  • Why can you deep-copy an expensive object to begin with? Commented Jan 14, 2016 at 9:04
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    @LaurentLARIZZA: Some classes have copy constructors simply because they are sometimes needed (e.g., instances of std::vector). Being expensive to copy is not a property of a class, but of individual objects. So method_that_returns_reference might refer to an object of a class that has a copy constructor, but which object happens to be quite expensive to copy (and cannot be moved from). Commented Jan 14, 2016 at 9:19
  • @MarcvanLeeuwen: If the object is expensive to copy, and cannot be moved from, why would it be stored in an std::vector? (Because it might, yes, or because you don't control the class, but that's not the point) If it is expensive to copy, (and owns no resource, because it is copyable), why not use COW on the object? Data locality is already killed by the size of the object. Commented Jan 14, 2016 at 10:59
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    @LaurentLARIZZA Not an instance of something stored in a vector being expensive, just a regular e.g. vector<double> is expensive to copy, it's a heap allocation + O(N) work. Moving is a red herring. The first line I showed will copy, not move, unless the reference returned is an rvalue reference. COW is really neither here nor there. The fact is that expensive to copy objects will always exist. Commented Jan 14, 2016 at 15:11
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    @Yakk It can't safely do that, because it could slice. The only safe thing it can do is = delete that overload. Though more generally what you say is a solution. This is a topic I've explored, if you're interested: nirfriedman.com/2016/01/18/…. Commented Aug 12, 2016 at 18:31

Other answers are mentioning drawbacks like "you don't really know what the type of a variable is." I'd say that this is largely related to sloppy naming convention in code. If your interfaces are clearly-named, you shouldn't need to care what the exact type is. Sure, auto result = callSomeFunction(a, b); doesn't tell you much. But auto valid = isValid(xmlFile, schema); tells you enough to use valid without having to care what its exact type is. After all, with just if (callSomeFunction(a, b)), you wouldn't know the type either. The same with any other subexpression temporary objects. So I don't consider this a real drawback of auto.

I'd say its primary drawback is that sometimes, the exact return type is not what you want to work with. In effect, sometimes the actual return type differs from the "logical" return type as an implementation/optimisation detail. Expression templates are a prime example. Let's say we have this:

SomeType operator* (const Matrix &lhs, const Vector &rhs);

Logically, we would expect SomeType to be Vector, and we definitely want to treat it as such in our code. However, it is possible that for optimisation purposes, the algebra library we're using implements expression templates, and the actual return type is this:

MultExpression<Matrix, Vector> operator* (const Matrix &lhs, const Vector &rhs);

Now, the problem is that MultExpression<Matrix, Vector> will in all likelihood store a const Matrix& and const Vector& internally; it expects that it will convert to a Vector before the end of its full-expression. If we have this code, all is well:

extern Matrix a, b, c;
extern Vector v;

void compute()
  Vector res = a * (b * (c * v));
  // do something with res

However, if we had used auto here, we could get in trouble:

void compute()
  auto res = a * (b * (c * v));
  // Oops! Now `res` is referring to temporaries (such as (c * v)) which no longer exist
  • 3
    @NirFriedman You're right it is strong, but I actually feel that auto has very few drawbacks, so I stand by that strength. And other examples of proxies etc. include various "string builders" and similar objects found in DSLs. Commented Jan 13, 2016 at 20:18
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    I've been bitten by expression templates and auto before, specifically with the Eigen library. It's especially tricky because the problem often doesn't show up in debug builds.
    – Dan
    Commented Jan 13, 2016 at 21:38
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    Use of auto can also bite when using the Armadillo matrix library, which makes heavy use of template meta-programming for optimization purposes. Fortunately the developers have added the .eval() function which can be used to avoid the problems with auto
    – mtall
    Commented Jan 14, 2016 at 3:52
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    "If your interfaces are clearly-named, you shouldn't need to care what the exact type is" Your compiler cannot check the correctness of your code by studying the names of variables. This is the entire point of a type system. Blindly bypassing it is silly! Commented Jan 15, 2016 at 10:34
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    @Angew: It isn't a problem for the temporaries because you're usually immediately using them, which without auto generally involves some kind of type check (and splashing auto in everywhere takes that type safety away just as it does everywhere else). It's not a good comparison. Commented Jan 15, 2016 at 10:51

It makes your code a little harder, or tedious, to read. Imagine something like that:

auto output = doSomethingWithData(variables);

Now, to figure out the type of output, you'd have to track down signature of doSomethingWithData function.

  • 42
    Not always. auto it = vec.begin(); is a lot easier to read than std::vector<std::wstring>::iterator it = vec.begin(); for example. Commented Jan 13, 2016 at 4:03
  • 4
    Agreed. It depends on the use case. I could have been a more precise about that.
    – Skam
    Commented Jan 13, 2016 at 4:09
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    "Track down the function signature", if that isn'tisn't a mouse hover or a key press away ("follow symbol"/" go to declaration"/whatever it is called), you need to either configure your editor more or switch to an IDE which can do this without configuration... Your point is still valid, though.
    – hyde
    Commented Jan 13, 2016 at 20:33
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    I noticed that not in an IDE but in small peepholes of diffs when reviewing checkins! With auto they are harder to read for that reason.
    – JDługosz
    Commented Jan 14, 2016 at 5:31
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    If the author of doSomethingWithData whould have cared to call his method crossProductOf(variables), the returned type would have been irrelevant.
    – xtofl
    Commented Jan 20, 2016 at 9:55

One of the drawbacks is that sometimes you can't declare const_iterator with auto. You will get ordinary (non const) iterator in this example of code taken from this question:

map<string,int> usa;
//...init usa
auto city_it = usa.find("New York");
  • 3
    Well, you get an iterator in any case since your map is non-const. if you want to convert it to a const_iterator, either specify the variable type explicitly as usual, or extract a method so that your map is const in the context of your find. (I'd prefer the latter. SRP.) Commented Jan 14, 2016 at 11:47
  • auto city_it = static_cast<const auto&>(map).find("New York") ? or, with C++17, auto city_if = std::as_const(map).find("New York").
    – Dev Null
    Commented Oct 28, 2017 at 5:57

Like this developer, I hate auto. Or rather, I hate how people misuse auto.

I'm of the (strong) opinion that auto is for helping you write generic code, not for reducing typing.
C++ is a language whose goal is to let you write robust code, not to minimize development time.
This is fairly obvious from many features of C++, but unfortunately a few of the newer ones like auto that reduce typing mislead people into thinking they should start being lazy with typing.

In pre-auto days, people used typedefs, which was great because typedef allowed the designer of the library to help you figure out what the return type should be, so that their library works as expected. When you use auto, you take away that control from the class's designer and instead ask the compiler to figure out what the type should be, which removes one of the most powerful C++ tools from the toolbox and risks breaking their code.

Generally, if you use auto, it should be because your code works for any reasonable type, not because you're just too lazy to write down the type that it should work with. If you use auto as a tool to help laziness, then what happens is that you eventually start introducing subtle bugs in your program, usually caused by implicit conversions that did not happen because you used auto.

Unfortunately, these bugs are difficult to illustrate in a short example here because their brevity makes them less convincing than the actual examples that come up in a user project -- however, they occur easily in template-heavy code that expect certain implicit conversions to take place.

If you want an example, there is one here. A little note, though: before being tempted to jump and criticize the code: keep in mind that many well-known and mature libraries have been developed around such implicit conversions, and they are there because they solve problems that can be difficult if not impossible to solve otherwise. Try to figure out a better solution before criticizing them.

  • 3
    which was great because typedef allowed the designer of the library to help you figure out what the return type should be, so that their library works as expected. When you use auto, you take away that control from the class's designer and instead ask the compiler to figure out what the type should be Not really a good reason IMO. Up-to-date IDE's, Visual Studio 2015 for example, allow you to check the type of the variable by hovering over auto. This is *exactly* the same as the typedef one. Commented Jan 14, 2016 at 15:22
  • @JameyD: You're missing several crucial points there: (1) Your IDE argument only works if the type is concrete, not templated. IDEs cannot possibly tell you the correct type in the case of dependent types, e.g. typename std::iterator_traits<It>::value_type. (2) The entire point was that the inferred type need not be "exactly the same" as the correct type intended by the previous designer of the code; by using auto, you're taking away the designer's ability to specify the correct type.
    – user541686
    Commented Jan 14, 2016 at 15:36
  • You are basically talking about proxies, which one of the answers already mentions. Expression templates and vector<bool> nonsense aren't everyday code for most people. In most situations, you don't want implicit conversions, and auto helps with that. Herb Sutter talks about the advantages of auto extensively in one of his blog posts, and it's not mostly about keystrokes, and it's also not just for generic code. Also, the first link you provided, the blog post is simply terrible advice (which is why he's criticized vociferously in his comments section). Commented Jan 14, 2016 at 18:15
  • @NirFriedman: "...vector<bool> nonsense"... pardon? How do you think bitset is implemented? Or do you consider bit containers to be nonsense altogether?!
    – user541686
    Commented Jan 15, 2016 at 1:18
  • 1
    @NirFriedman: Nothing about vector<bool> is news to me. What I'm trying to tell you and that you're blatantly refusing to understand is that for the purposes of this question bitset is no different from vector<bool> -- both of them use proxies, because the proxies were deemed to be useful, and the fact that proxies are useful is a reality you need to accept instead of living in denial of. Can you please stop turning this into a debate about whether you think proxies are useful? That's not the subject of debate, and also, your opinion on them is just your opinion, not some kind of fact.
    – user541686
    Commented Jan 15, 2016 at 4:24

auto does not have drawbacks per se, and I advocate to (hand-wavily) use it everywhere in new code. It allows your code to consistently type-check, and consistently avoid silent slicing. (If B derives from A and a function returning A suddenly returns B, then auto behaves as expected to store its return value)

Although, pre-C++11 legacy code may rely on implicit conversions induced by the use of explicitly-typed variables. Changing an explicitly-typed variable to auto might change code behaviour, so you'd better be cautious.

  • Downvoting is fair, but could you please comment on why? Commented Jan 17, 2016 at 18:02
  • 1
    I didn't downvote you, but auto does have drawbacks per se (or at least - many think it does). Consider the example given in the second question in this panel discussion with Sutter, Alexandrescu and Meyers: If you have auto x = foo(); if (x) { bar(); } else { baz(); } and foo() returns bool - what happens if foo() changes to return an enum (three options instead of two)? The auto code will continue to work, but produce unexpected results.
    – einpoklum
    Commented Mar 27, 2017 at 21:49
  • @einpoklum: And does using bool instead of auto change anything in case of an unscoped enum? I may be wrong (can't check here), but I think the only difference is that conversion to bool happens at variable declaration instead of at evaluation of the condition in the if. If the enum is scoped, then conversion to bool shall not happen without an explicit notice. Commented Mar 30, 2017 at 7:08

Keyword auto simply deduce the type from the return value. Therefore, it is not equivalent with a Python object, e.g.

# Python
a = 10       # OK
a = "10"     # OK
a = ClassA() # OK

// C++
auto a;      // Unable to deduce variable a
auto a = 10; // OK
a = "10";    // Value of const char* can't be assigned to int
a = ClassA{} // Value of ClassA can't be assigned to int
a = 10.0;    // OK, implicit casting warning

Since auto is deduced during compilation, it won't have any drawback at runtime whatsoever.

  • 1
    yes, it basically does what type() in python does. It deduces the type, it doesn't create a new variable of that type.
    – lciamp
    Commented Jan 13, 2016 at 5:50
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    @lciamp Actually, that would be decltype. auto is for variable assignment specifically.
    – Cubic
    Commented Jan 13, 2016 at 12:26

What no one mentioned here so far, but for itself is worth an answer if you asked me.

Since (even if everyone should be aware that C != C++) code written in C can easily be designed to provide a base for C++ code and therefore be designed without too much effort to be C++ compatible, this could be a requirement for design.

I know about some rules where some well defined constructs from C are invalid for C++ and vice versa. But this would simply result in broken executables and the known UB-clause applies which most times is noticed by strange loopings resulting in crashes or whatever (or even may stay undetected, but that doesn't matter here).

But auto is the first time1 this changes!

Imagine you used auto as storage-class specifier before and transfer the code. It would not even necessarily (depending on the way it was used) "break"; it actually could silently change the behaviour of the program.

That's something one should keep in mind.

1At least the first time I'm aware of.

  • 1
    You'd get a compiler error anyway when trying to compile. Commented Jan 13, 2016 at 9:41
  • @JameyD: What would do so? why should 2 valid code situations with diferent meaning resutl ever in error?
    – dhein
    Commented Jan 13, 2016 at 9:45
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    If you're relying on "no type implies int" in C, you deserve all the bad stuff that you'll get from this. And if you're not relying on it, using auto as a storage class specifier alongside a type will give you a nice compilation error in C++ (which is a Good Thing in this case). Commented Jan 13, 2016 at 10:30
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    @Angew well thats the case I'm refering to, yeah. I'm not doing this. But it is something that should at least be kept in mind.
    – dhein
    Commented Jan 13, 2016 at 11:10

As I described in this answer auto can sometimes result in funky situations you didn't intend. You have to explictly say auto& to have a reference type while doing just auto can create a pointer type. This can result in confusion by omitting the specifier all together, resulting in a copy of the reference instead of an actual reference.

  • 2
    That's not funky. That's what auto does, never inferring a reference nor const type. For an auto reference, you'd better use auto&&. (a universal reference) If the type is not cheap to copy or owns a resource, then the type should not be copyable to begin with. Commented Jan 14, 2016 at 9:01

One reason that I can think of is that you lose the opportunity to coerce the class that is returned. If your function or method returned a long 64 bit, and you only wanted a 32 unsigned int, then you lose the opportunity to control that.

  • 1
    There's static_cast, and IIRC for example Meyers' Effective Modern C++ even recommends using it to specify type for auto-typed variable.
    – hyde
    Commented Jan 13, 2016 at 20:23

I think auto is good when used in a localized context, where the reader easily & obviously can deduct its type, or well documented with a comment of its type or a name that infer the actual type. Those who don't understand how it works might take it in the wrong ways, like using it instead of template or similar. Here are some good and bad use cases in my opinion.

void test (const int & a)
    // b is not const
    // b is not a reference

    auto b = a;

    // b type is decided by the compiler based on value of a
    // a is int

Good Uses


std::vector<boost::tuple<ClassWithLongName1,std::vector<ClassWithLongName2>,int> v();


std::vector<boost::tuple<ClassWithLongName1,std::vector<ClassWithLongName2>,int>::iterator it = v.begin();

// VS

auto vi = v.begin();

Function Pointers

int test (ClassWithLongName1 a, ClassWithLongName2 b, int c)


int (*fp)(ClassWithLongName1, ClassWithLongName2, int) = test;

// VS

auto *f = test;

Bad Uses

Data Flow

auto input = "";


auto output = test(input);

Function Signature

auto test (auto a, auto b, auto c)

Trivial Cases

for(auto i = 0; i < 100; i++)
  • 2
    When you want an int, you have to type one more char if you go for auto. That's unacceptable
    – Rerito
    Commented Jan 20, 2016 at 10:46
  • @Rerito yes, it's an int as easily seen here & typing int is shorter. That's why it's a trivial case.
    – Khaled.K
    Commented Jan 20, 2016 at 10:54
  • Why would you not use "using X = ClassWithLongName1"?
    – user997112
    Commented Sep 25, 2020 at 22:46
  • @user997112 you can totally use that, but it also force you to create an alias everywhere you use it & remember it every-time you need it, your comment is more suitable on the question than here.. for my answer, the OP question is about the uses of auto
    – Khaled.K
    Commented Sep 28, 2020 at 11:20
  • @Khaled.K I meant a lot of people argue 'auto' avoids long class names, but 'using' allows this too, without obfuscating and losing control.
    – user997112
    Commented Sep 28, 2020 at 23:14

I'm surprised nobody has mentioned this, but suppose you are calculating the factorial of something:

#include <iostream>
using namespace std;

int main() {
    auto n = 40;
    auto factorial = 1;

    for(int i = 1; i <=n; ++i)
        factorial *= i;

    cout << "Factorial of " << n << " = " << factorial <<endl;   
    cout << "Size of factorial: " << sizeof(factorial) << endl; 
    return 0;

This code will output this:

Factorial of 40 = 0
Size of factorial: 4

That was definetly not the expected result. That happened because auto deduced the type of the variable factorial as int because it was assigned to 1.


Another irritating example:

for (auto i = 0; i < s.size(); ++i)

generates a warning (comparison between signed and unsigned integer expressions [-Wsign-compare]), because i is a signed int. To avoid this you need to write e.g.

for (auto i = 0U; i < s.size(); ++i)

or perhaps better:

for (auto i = 0ULL; i < s.size(); ++i)
  • 1
    Yes I find this one irritating too. But the hole in the language is somewhere else. For this code to be truly portable, assuming size returns size_t, you'd have to be able to have a size_t literal like 0z. But you can declare a UDL to do this. (size_t operator""_z(...)) Commented Jan 24, 2017 at 8:09
  • 1
    Purely theoretical objections: unsigned is quite likely not to be nearly large enough to hold all values of std::size_t on mainstream architectures, so in the unlikely event that someone had a container with an absurdly gigantic number of elements, using unsigned could cause an infinite loop over the lower range of indices. While this is unlikely to be an issue, std::size_t should be used to get clean code that properly signals intent. I'm not sure even unsigned long long is strictly guaranteed to suffice, although in practice it presumably must be the same. Commented Jun 6, 2017 at 11:55
  • @underscore_d: yes, fair point - unsigned long long is guaranteed to be at least 64 bits, but in theory size_t could be bigger than this, I suppose. Of course if you have > 2^64 elements in your container then you may have bigger problems to worry about... ;-)
    – Paul R
    Commented Jun 6, 2017 at 12:08

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