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What is the difference between printf() and cout in C++?

1
  • Nowadays (2023) there is a more modern alternative - see my answer below.
    – wohlstad
    Dec 7, 2023 at 6:17

18 Answers 18

522

I'm surprised that everyone in this question claims that std::cout is way better than printf, even if the question just asked for differences. Now, there is a difference - std::cout is C++, and printf is C (however, you can use it in C++, just like almost anything else from C). Now, I'll be honest here; both printf and std::cout have their advantages.

Real differences

Extensibility

std::cout is extensible. I know that people will say that printf is extensible too, but such extension is not mentioned in the C standard (so you would have to use non-standard features - but not even common non-standard feature exists), and such extensions are one letter (so it's easy to conflict with an already-existing format).

Unlike printf, std::cout depends completely on operator overloading, so there is no issue with custom formats - all you do is define a subroutine taking std::ostream as the first argument and your type as second. As such, there are no namespace problems - as long you have a class (which isn't limited to one character), you can have working std::ostream overloading for it.

However, I doubt that many people would want to extend ostream (to be honest, I rarely saw such extensions, even if they are easy to make). However, it's here if you need it.

Syntax

As it could be easily noticed, both printf and std::cout use different syntax. printf uses standard function syntax using pattern string and variable-length argument lists. Actually, printf is a reason why C has them - printf formats are too complex to be usable without them. However, std::cout uses a different API - the operator << API that returns itself.

Generally, that means the C version will be shorter, but in most cases it won't matter. The difference is noticeable when you print many arguments. If you have to write something like Error 2: File not found., assuming error number, and its description is placeholder, the code would look like this. Both examples work identically (well, sort of, std::endl actually flushes the buffer).

printf("Error %d: %s.\n", id, errors[id]);
std::cout << "Error " << id << ": " << errors[id] << "." << std::endl;

While this doesn't appear too crazy (it's just two times longer), things get more crazy when you actually format arguments, instead of just printing them. For example, printing of something like 0x0424 is just crazy. This is caused by std::cout mixing state and actual values. I never saw a language where something like std::setfill would be a type (other than C++, of course). printf clearly separates arguments and actual type. I really would prefer to maintain the printf version of it (even if it looks kind of cryptic) compared to iostream version of it (as it contains too much noise).

printf("0x%04x\n", 0x424);
std::cout << "0x" << std::hex << std::setfill('0') << std::setw(4) << 0x424 << std::endl;

Translation

This is where the real advantage of printf lies. The printf format string is well... a string. That makes it really easy to translate, compared to operator << abuse of iostream. Assuming that the gettext() function translates, and you want to show Error 2: File not found., the code to get translation of the previously shown format string would look like this:

printf(gettext("Error %d: %s.\n"), id, errors[id]);

Now, let's assume that we translate to Fictionish, where the error number is after the description. The translated string would look like %2$s oru %1$d.\n. Now, how to do it in C++? Well, I have no idea. I guess you can make fake iostream which constructs printf that you can pass to gettext, or something, for purposes of translation. Of course, $ is not C standard, but it's so common that it's safe to use in my opinion.

Not having to remember/look-up specific integer type syntax

C has lots of integer types, and so does C++. std::cout handles all types for you, while printf requires specific syntax depending on an integer type (there are non-integer types, but the only non-integer type you will use in practice with printf is const char * (C string, can be obtained using to_c method of std::string)). For instance, to print size_t, you need to use %zu, while int64_t will require using %"PRId64". The tables are available at http://en.cppreference.com/w/cpp/io/c/fprintf and http://en.cppreference.com/w/cpp/types/integer.

You can't print the NUL byte, \0

Because printf uses C strings as opposed to C++ strings, it cannot print NUL byte without specific tricks. In certain cases it's possible to use %c with '\0' as an argument, although that's clearly a hack.

Differences nobody cares about

Performance

Update: It turns out that iostream is so slow that it's usually slower than your hard drive (if you redirect your program to file). Disabling synchronization with stdio may help, if you need to output lots of data. If the performance is a real concern (as opposed to writing several lines to STDOUT), just use printf.

Everyone thinks that they care about performance, but nobody bothers to measure it. My answer is that I/O is bottleneck anyway, no matter if you use printf or iostream. I think that printf could be faster from a quick look into assembly (compiled with clang using the -O3 compiler option). Assuming my error example, printf example does way fewer calls than the cout example. This is int main with printf:

main:                                   @ @main
@ BB#0:
        push    {lr}
        ldr     r0, .LCPI0_0
        ldr     r2, .LCPI0_1
        mov     r1, #2
        bl      printf
        mov     r0, #0
        pop     {lr}
        mov     pc, lr
        .align  2
@ BB#1:

You can easily notice that two strings, and 2 (number) are pushed as printf arguments. That's about it; there is nothing else. For comparison, this is iostream compiled to assembly. No, there is no inlining; every single operator << call means another call with another set of arguments.

main:                                   @ @main
@ BB#0:
        push    {r4, r5, lr}
        ldr     r4, .LCPI0_0
        ldr     r1, .LCPI0_1
        mov     r2, #6
        mov     r3, #0
        mov     r0, r4
        bl      _ZSt16__ostream_insertIcSt11char_traitsIcEERSt13basic_ostreamIT_T0_ES6_PKS3_l
        mov     r0, r4
        mov     r1, #2
        bl      _ZNSolsEi
        ldr     r1, .LCPI0_2
        mov     r2, #2
        mov     r3, #0
        mov     r4, r0
        bl      _ZSt16__ostream_insertIcSt11char_traitsIcEERSt13basic_ostreamIT_T0_ES6_PKS3_l
        ldr     r1, .LCPI0_3
        mov     r0, r4
        mov     r2, #14
        mov     r3, #0
        bl      _ZSt16__ostream_insertIcSt11char_traitsIcEERSt13basic_ostreamIT_T0_ES6_PKS3_l
        ldr     r1, .LCPI0_4
        mov     r0, r4
        mov     r2, #1
        mov     r3, #0
        bl      _ZSt16__ostream_insertIcSt11char_traitsIcEERSt13basic_ostreamIT_T0_ES6_PKS3_l
        ldr     r0, [r4]
        sub     r0, r0, #24
        ldr     r0, [r0]
        add     r0, r0, r4
        ldr     r5, [r0, #240]
        cmp     r5, #0
        beq     .LBB0_5
@ BB#1:                                 @ %_ZSt13__check_facetISt5ctypeIcEERKT_PS3_.exit
        ldrb    r0, [r5, #28]
        cmp     r0, #0
        beq     .LBB0_3
@ BB#2:
        ldrb    r0, [r5, #39]
        b       .LBB0_4
.LBB0_3:
        mov     r0, r5
        bl      _ZNKSt5ctypeIcE13_M_widen_initEv
        ldr     r0, [r5]
        mov     r1, #10
        ldr     r2, [r0, #24]
        mov     r0, r5
        mov     lr, pc
        mov     pc, r2
.LBB0_4:                                @ %_ZNKSt5ctypeIcE5widenEc.exit
        lsl     r0, r0, #24
        asr     r1, r0, #24
        mov     r0, r4
        bl      _ZNSo3putEc
        bl      _ZNSo5flushEv
        mov     r0, #0
        pop     {r4, r5, lr}
        mov     pc, lr
.LBB0_5:
        bl      _ZSt16__throw_bad_castv
        .align  2
@ BB#6:

However, to be honest, this means nothing, as I/O is the bottleneck anyway. I just wanted to show that iostream is not faster because it's "type safe". Most C implementations implement printf formats using computed goto, so the printf is as fast as it can be, even without compiler being aware of printf (not that they aren't - some compilers can optimize printf in certain cases - constant string ending with \n is usually optimized to puts).

Inheritance

I don't know why you would want to inherit ostream, but I don't care. It's possible with FILE too.

class MyFile : public FILE {}

Type safety

True, variable length argument lists have no safety, but that doesn't matter, as popular C compilers can detect problems with printf format string if you enable warnings. In fact, Clang can do that without enabling warnings.

$ cat safety.c

#include <stdio.h>

int main(void) {
    printf("String: %s\n", 42);
    return 0;
}

$ clang safety.c

safety.c:4:28: warning: format specifies type 'char *' but the argument has type 'int' [-Wformat]
    printf("String: %s\n", 42);
                    ~~     ^~
                    %d
1 warning generated.
$ gcc -Wall safety.c
safety.c: In function ‘main’:
safety.c:4:5: warning: format ‘%s’ expects argument of type ‘char *’, but argument 2 has type ‘int’ [-Wformat=]
     printf("String: %s\n", 42);
     ^
16
  • 30
    You say I/O is the bottleneck anyway. Obviously you never tested that assumption. I quote myself: "On the other hand, the iostreams version, at 75.3 MB/s, can't buffer data fast enough to keep up with a hard disk. That's bad, and it's not even doing any real work yet. I don't think I have too high expectations when I say my I/O library should be able to be able to saturate my disk controller."
    – Ben Voigt
    Jan 15, 2014 at 18:15
  • 7
    @BenVoigt: I admit, I try to avoid C++ when possible. I tried using it a lot, but it was more annoying, and less maintainable than other programming language I used. This is yet another reason for me to avoid C++ - this isn't even fast (it's not even iostream - entire C++ library is slow in most implementations, perhaps with exception for std::sort, which is somehow surprisingly fast compared to qsort (2 times), at cost of executable size).
    – 0..
    Jan 15, 2014 at 20:36
  • 3
    No one here has mentioned issues in parallel environment when using cout. May 19, 2014 at 23:35
  • 11
    Your performance argument makes no sense whatsoever. More assembly in your program doesn't mean that program will be slower, because you're not accounting for all the code that makes the printf function, which is a lot of code. In my opinion, it is possible to optimize cout with << operator a lot better than the printf, because compiler can make better sense of variables and formatting.
    – Ignas2526
    Jan 26, 2015 at 12:22
  • 43
    I like a lot of things about this answer, but perhaps my favorite part is "Everyone thinks that they care about performance, but nobody bothers to measure it." Oct 15, 2015 at 17:48
228

From the C++ FAQ:

[15.1] Why should I use <iostream> instead of the traditional <cstdio>?

Increase type safety, reduce errors, allow extensibility, and provide inheritability.

printf() is arguably not broken, and scanf() is perhaps livable despite being error prone, however both are limited with respect to what C++ I/O can do. C++ I/O (using << and >>) is, relative to C (using printf() and scanf()):

  • More type-safe: With <iostream>, the type of object being I/O'd is known statically by the compiler. In contrast, <cstdio> uses "%" fields to figure out the types dynamically.
  • Less error prone: With <iostream>, there are no redundant "%" tokens that have to be consistent with the actual objects being I/O'd. Removing redundancy removes a class of errors.
  • Extensible: The C++ <iostream> mechanism allows new user-defined types to be I/O'd without breaking existing code. Imagine the chaos if everyone was simultaneously adding new incompatible "%" fields to printf() and scanf()?!
  • Inheritable: The C++ <iostream> mechanism is built from real classes such as std::ostream and std::istream. Unlike <cstdio>'s FILE*, these are real classes and hence inheritable. This means you can have other user-defined things that look and act like streams, yet that do whatever strange and wonderful things you want. You automatically get to use the zillions of lines of I/O code written by users you don't even know, and they don't need to know about your "extended stream" class.

On the other hand, printf is significantly faster, which may justify using it in preference to cout in very specific and limited cases. Always profile first. (See, for example, http://programming-designs.com/2009/02/c-speed-test-part-2-printf-vs-cout/)

10
  • 2
    On the other other hand, there's the FastFormat library (fastformat.org), offering type-safety, expressivity and performance at once. (Not that I tried it yet...)
    – xtofl
    May 20, 2010 at 10:07
  • 3
    @Marcelo probably because it's a good summary, with everything cited. The formatting... yeah, that's pretty bad. I should have fixed that myself, but it appears that others (yourself included) took care of it, which, of course, is more constructive than just whining.
    – Mikeage
    May 21, 2010 at 7:59
  • 2
    As of late printf() is also supposed to be extensible. See "printf hooks" at udrepper.livejournal.com/20948.html Nov 25, 2011 at 8:32
  • 4
    @MaximYegorushkin: Standard printf has no such ability. Non-portable library mechanisms are hardly on the same level as fully standardized extensibility of iostreams.
    – Ben Voigt
    Jan 15, 2014 at 18:09
  • 7
    "On the other hand, printf is significantly faster" printf is also cleaner and easier to use, which is why i avoid cout when possible. Nov 11, 2015 at 13:09
56

People often claim that printf is much faster. This is largely a myth. I just tested it, with the following results:

cout with only endl                     1461.310252 ms
cout with only '\n'                      343.080217 ms
printf with only '\n'                     90.295948 ms
cout with string constant and endl      1892.975381 ms
cout with string constant and '\n'       416.123446 ms
printf with string constant and '\n'     472.073070 ms
cout with some stuff and endl           3496.489748 ms
cout with some stuff and '\n'           2638.272046 ms
printf with some stuff and '\n'         2520.318314 ms

Conclusion: if you want only newlines, use printf; otherwise, cout is almost as fast, or even faster. More details can be found on my blog.

To be clear, I'm not trying to say that iostreams are always better than printf; I'm just trying to say that you should make an informed decision based on real data, not a wild guess based on some common, misleading assumption.

Update: Here's the full code I used for testing. Compiled with g++ without any additional options (apart from -lrt for the timing).

#include <stdio.h>
#include <iostream>
#include <ctime>

class TimedSection {
    char const *d_name;
    timespec d_start;
    public:
        TimedSection(char const *name) :
            d_name(name)
        {
            clock_gettime(CLOCK_REALTIME, &d_start);
        }
        ~TimedSection() {
            timespec end;
            clock_gettime(CLOCK_REALTIME, &end);
            double duration = 1e3 * (end.tv_sec - d_start.tv_sec) +
                              1e-6 * (end.tv_nsec - d_start.tv_nsec);
            std::cerr << d_name << '\t' << std::fixed << duration << " ms\n"; 
        }
};

int main() {
    const int iters = 10000000;
    char const *text = "01234567890123456789";
    {
        TimedSection s("cout with only endl");
        for (int i = 0; i < iters; ++i)
            std::cout << std::endl;
    }
    {
        TimedSection s("cout with only '\\n'");
        for (int i = 0; i < iters; ++i)
            std::cout << '\n';
    }
    {
        TimedSection s("printf with only '\\n'");
        for (int i = 0; i < iters; ++i)
            printf("\n");
    }
    {
        TimedSection s("cout with string constant and endl");
        for (int i = 0; i < iters; ++i)
            std::cout << "01234567890123456789" << std::endl;
    }
    {
        TimedSection s("cout with string constant and '\\n'");
        for (int i = 0; i < iters; ++i)
            std::cout << "01234567890123456789\n";
    }
    {
        TimedSection s("printf with string constant and '\\n'");
        for (int i = 0; i < iters; ++i)
            printf("01234567890123456789\n");
    }
    {
        TimedSection s("cout with some stuff and endl");
        for (int i = 0; i < iters; ++i)
            std::cout << text << "01234567890123456789" << i << std::endl;
    }
    {
        TimedSection s("cout with some stuff and '\\n'");
        for (int i = 0; i < iters; ++i)
            std::cout << text << "01234567890123456789" << i << '\n';
    }
    {
        TimedSection s("printf with some stuff and '\\n'");
        for (int i = 0; i < iters; ++i)
            printf("%s01234567890123456789%i\n", text, i);
    }
}
17
  • 5
    In your scores printf beats cout easily (majority cases). I wonder why you recommend using cout when it comes to perf. Though I agree perf is not too different in realistic cases..
    – mishal153
    May 20, 2010 at 12:07
  • 3
    @mishal153: I'm just trying to say that the performance is not too different, so the commonly-heard advice of "never use cout because it's waaay slow" is plain stupid. Note that cout has the obvious advantage of type-safety, and often readability as well. (Floating-point formatting with iostreams is horrible...)
    – Thomas
    May 20, 2010 at 12:18
  • 47
    The important difference between printf() and std::ostream is that the former outputs all arguments in one single call whereas std::ostream incurs a separate call for each <<. The test only outputs one argument and a new-line, that's why you can't see the difference. Nov 25, 2011 at 8:36
  • 12
    The compiler should be able to inline these calls. Also, printf might make a lot of calls under the covers to helper functions for various formatting specifiers... that, or it's a monstrous monolithic function. And again, because of inlining, it shouldn't make a difference in speed at all.
    – Thomas
    Nov 26, 2011 at 11:05
  • 4
    You timed your terminal. Use sprintf or fprintf and stringstream or fstream.
    – Ben Voigt
    Jan 15, 2014 at 18:10
44

And I quote:

In high level terms, the main differences are type safety (cstdio doesn't have it), performance (most iostreams implementations are slower than the cstdio ones) and extensibility (iostreams allows custom output targets and seamless output of user defined types).

1
  • Especially on unix where with POSIX you never know what size one of the typedefs really has so you need lots of casts or as 99% of the programs you just risk it with %d. Took even a long time before %z came with C99. But for time_t/off_t the quest for the correct format instruction continues.
    – Lothar
    Feb 5, 2015 at 21:40
31

One is a function that prints to stdout. The other is an object that provides several member functions and overloads of operator<< that print to stdout. There are many more differences that I could enumerate, but I'm not sure what you are after.

0
13

For me, the real differences which would make me go for 'cout' rather than 'printf' are:

1) << operator can be overloaded for my classes.

2) Output stream for cout can be easily changed to a file : (: copy paste :)

#include <iostream>
#include <fstream>
using namespace std;

int main ()
{
    cout << "This is sent to prompt" << endl;
    ofstream file;
    file.open ("test.txt");
    streambuf* sbuf = cout.rdbuf();
    cout.rdbuf(file.rdbuf());
    cout << "This is sent to file" << endl;
    cout.rdbuf(sbuf);
    cout << "This is also sent to prompt" << endl;
    return 0;
}

3) I find cout more readable, especially when we have many parameters.

One problem with cout is the formatting options. Formatting the data (precision, justificaton, etc.) in printf is easier.

2
  • 1
    it's nice. How can I know nobody modify global cout this way in some foreign library thread?
    – vp_arth
    Dec 29, 2016 at 17:04
  • 9
    You can easily change printf to a file as well by replacing it with fprintf... Jan 11, 2020 at 8:37
9

Two points not otherwise mentioned here that I find significant:

1) cout carries a lot of baggage if you're not already using the STL. It adds over twice as much code to your object file as printf. This is also true for string, and this is the major reason I tend to use my own string library.

2) cout uses overloaded << operators, which I find unfortunate. This can add confusion if you're also using the << operator for its intended purpose (shift left). I personally don't like to overload operators for purposes tangential to their intended use.

Bottom line: I'll use cout (and string) if I'm already using the STL. Otherwise, I tend to avoid it.

7

I'm not a programmer, but I have been a human factors engineer. I feel a programming language should be easy to learn, understand and use, and this requires that it have a simple and consistent linguistic structure. Although all the languages is symbolic and thus, at its core, arbitrary, there are conventions and following them makes the language easier to learn and use.

There are a vast number of functions in C++ and other languages written as function(parameter), a syntax that was originally used for functional relationships in mathematics in the pre-computer era. printf() follows this syntax and if the writers of C++ wanted to create any logically different method for reading and writing files they could have simply created a different function using a similar syntax.

In Python we of course can print using the also fairly standard object.method syntax, i.e. variablename.print, since variables are objects, but in C++ they are not.

I'm not fond of the cout syntax because the << operator does not follow any rules. It is a method or function, i.e. it takes a parameter and does something to it. However it is written as though it were a mathematical comparison operator. This is a poor approach from a human factors standpoint.

1
  • 2
    << is not a comparison operator. It is the bit shift left operator. It takes two integer arguments (originally). 10 << 1; This shifts the bits of ten 1 time(s) to the left; returning the number 20. But Cpp allows operator overloading and decides to use this operator for stdout. The comparison operators of cpp are less than(<) greater than(>) less than or equal(<=) greater than or equal(>=) equal(==) not equal(!=). It's all just syntax specific to cpp and not directly from Maths. Note that assignment operator is(=). Jan 13, 2023 at 1:36
4

With primitives, it probably doesn't matter entirely which one you use. I say where it gets usefulness is when you want to output complex objects.

For example, if you have a class,

#include <iostream>
#include <cstdlib>

using namespace std;

class Something
{
public:
        Something(int x, int y, int z) : a(x), b(y), c(z) { }
        int a;
        int b;
        int c;

        friend ostream& operator<<(ostream&, const Something&);
};

ostream& operator<<(ostream& o, const Something& s)
{
        o << s.a << ", " << s.b << ", " << s.c;
        return o;
}

int main(void)
{
        Something s(3, 2, 1);

        // output with printf
        printf("%i, %i, %i\n", s.a, s.b, s.c);

        // output with cout
        cout << s << endl;

        return 0;
}

Now the above might not seem all that great, but let's suppose you have to output this in multiple places in your code. Not only that, let's say you add a field "int d." With cout, you only have to change it in once place. However, with printf, you'd have to change it in possibly a lot of places and not only that, you have to remind yourself which ones to output.

With that said, with cout, you can reduce a lot of times spent with maintenance of your code and not only that if you re-use the object "Something" in a new application, you don't really have to worry about output.

2
  • Also, to add about the performance thing, I'd say that you shouldn't output anything at all if your application is made for performance. Any sort of output to std is rather expensive and slow. I say you should avoid it and only output when it is absolutely necessary to do so.
    – Daniel
    May 20, 2010 at 18:04
  • keep in mind that your class might have private members you cannot access so easily from the outside. With the output operator, you have exactly one location that needs to be friend to your class, and now you can output it anywhere, even in code you didn't know about.
    – hochl
    Aug 4, 2017 at 14:02
4

I'd like to point out that if you want to play with threads in C++, if you use cout you can get some interesting results.

Consider this code:

#include <string>
#include <iostream>
#include <thread>

using namespace std;

void task(int taskNum, string msg) {
    for (int i = 0; i < 5; ++i) {
        cout << "#" << taskNum << ": " << msg << endl;
    }
}

int main() {
    thread t1(task, 1, "AAA");
    thread t2(task, 2, "BBB");
    t1.join();
    t2.join();
    return 0;
}

// g++ ./thread.cpp -o thread.out -ansi -pedantic -pthread -std=c++0x

Now, the output comes all shuffled. It can yield different results too, try executing several times:

##12::  ABABAB

##12::  ABABAB

##12::  ABABAB

##12::  ABABAB

##12::  ABABAB

You can use printf to get it right, or you can use mutex.

#1: AAA
#2: BBB
#1: AAA
#2: BBB
#1: AAA
#2: BBB
#1: AAA
#2: BBB
#1: AAA
#2: BBB

Have fun!

4
  • 2
    wtf threads don't make output go nuts. I just reproduced and found both xyz and ABC in the output. There was not mangling b/w ABC as ABABAB. Jan 18, 2016 at 13:10
  • 4
    I don't know how cout works with threads, but I know for sure that the code you are showing isn't the one that you used to get those outputs. Your code passes the string "ABC" for thread 1 and "xyz" for thread 2, but your output shows AAA and BBB. Please fix it, because right now it's confusing. Feb 8, 2016 at 21:28
  • 1
    cout make things interleave because as the other answers pointed out, cout will not run as a single call, but will run in a chain of calls, so they will eventually interleave. But differently from what @Apollo mentioned, it won't ever interleave A and B since msg will print in a single call. But it can print something like #2: AAABBB. Jun 24, 2022 at 14:41
  • 1
    It's no longer relevant. The secret is in the compile command : -std=c++0x. Using a c++ standard that is not 10 year old and this issue will disappear.
    – Welgriv
    Jun 29, 2023 at 8:15
4

API

printf uses a replacement-based API with placeholders starting with % replaced with formatted arguments:

printf("The answer is %d.\n", answer);

cout or, more generally, ostreams use a concatenation-based API with parts of a formatted message interleaved with arguments:

std::cout << "The answer is " << answer << ".\n";

A replacement-based API with proper synchronization provides atomicity, e.g. when writing from multiple threads different messages written with printf won't interleave while parts of the messages written with cout may interleave. For this reason C++20 introduced std::osyncstream which is a clunky way of achieving atomicity.

With operator overloading formatting can quickly become cumbersome, e.g.

std::cout << std::setprecision(2) << std::fixed << 1.23456 << "\n";

vs

printf("%.2f\n", 1.23456);

Matthew Wilson, the author of FastFormat, called this "chevron hell".

Extensibility

cout supports formatting of user-defined types through overloading of operator<<. There is no standard way to do the same with printf, although there is a glibc extension which is rarely used in practice.

Safety

printf uses varargs which are inherently unsafe unless you use something like GCC's format attribute which only works with literal format strings. It is a user's responsibility to correctly pass type information via format specifiers. Any mismatch results in an undefined behavior and is a common source of vulnerabilities.

cout/ostreams are type-safe and the user doesn't need to manually handle type information.

Buffering

cout adds another layer of buffering and synchronizes with the underlying C streams by default. This brings significant performance overhead. It is possible to disable this synchronization at the cost of worse interoperability with C and potentially other languages.

Formatting state

In printf formatting is controlled via a format string and decoupled from the stream itself. In cout/ostreams the formatting state is stored in the stream which may negatively affect performance and cause unexpected results. Quoting N4412: Shortcomings of iostreams:

Formatting parameters (such as uppercase/lowercase and radix) are specified by setting flags, which mostly persist for an arbitrary number of subsequent low-level formatting operations, until explicitly changed. This approach inhibits compile-time checks and compile-time choice of formatting, and potentially establishes state shared between threads (which requires synchronization for access).

Locales

printf uses the global C locale.

cout uses the C++ locale associated with the stream.

Both printf and cout use locales by default.

Performance

cout is often slower than printf for reasons mentioned above: extra buffering and synchronization (can be disabled) and stateful API.

Language

printf is a part of the C standard library and can be used in C and C++. cout is a part of the C++ standard library and can only be used in C++.


You can have the best of both worlds by using C++23 std::print. It provides a replacement-based API with positional arguments. It is extensible, type-safe, doesn't introduce extra buffering and makes localized formatting an opt-in.

Disclaimer: I'm the author of C++23 std::print.

2
cout<< "Hello";
printf("%s", "Hello"); 

Both are used to print values. They have completely different syntax. C++ has both, C only has printf.

10
  • 20
    ... what? did you mixup something?
    – xtofl
    May 20, 2010 at 10:08
  • 1
    Fixed the issue. -1 because it required fixing and the answer leaves a lot to be desired.
    – Yacoby
    May 20, 2010 at 10:36
  • 3
    The function names had been reversed: cout was used with the printf syntax, and printf was used with the cout syntax. Shouldn't have even been accepted! May 20, 2010 at 11:12
  • 2
    and the main disadvantage of cout is that it uses operator<< which is verbose and ugly and arguably operator abuse. :)
    – jalf
    May 20, 2010 at 12:24
  • 10
    Although this is certainty not the best answer, I don't understand how scatman is being punished for his answer only because it was picked as the best answer. xbit has a way worse answer IMO but has -1 vote. I'm not saying xbit should be down voted any more, but I don't see it being fair to down vote scatman for the OP's mistake anymore than it has to be...
    – Jesse
    Sep 4, 2010 at 20:35
2

Of course you can write "something" a bit better to keep maintenance:

#include <iostream>
#include <cstdlib>

using namespace std;

class Something
{
    public:
        Something(int x, int y, int z) : a(x), b(y), c(z) { }
        int a;
        int b;
        int c;

        friend ostream& operator<<(ostream&, const Something&);

        void print() const { printf("%i, %i, %i\n", a, b, c); }
};

ostream& operator<<(ostream& o, const Something& s)
{
    o << s.a << ", " << s.b << ", " << s.c;
    return o;
}

int main(void)
{
    Something s(3, 2, 1);

    // Output with printf
    s.print(); // Simple as well, isn't it?

    // Output with cout
    cout << s << endl;

    return 0;
}

And a bit extended test of cout vs. printf, added a test of 'double', if anyone wants to do more testing (Visual Studio 2008, release version of the executable):

#include <stdio.h>
#include <iostream>
#include <ctime>

class TimedSection {
    char const *d_name;
    //timespec d_start;
    clock_t d_start;

    public:
        TimedSection(char const *name) :
            d_name(name)
        {
            //clock_gettime(CLOCK_REALTIME, &d_start);
            d_start = clock();
        }
        ~TimedSection() {
            clock_t end;
            //clock_gettime(CLOCK_REALTIME, &end);
            end = clock();
            double duration = /*1e3 * (end.tv_sec - d_start.tv_sec) +
                              1e-6 * (end.tv_nsec - d_start.tv_nsec);
                              */
                              (double) (end - d_start) / CLOCKS_PER_SEC;

            std::cerr << d_name << '\t' << std::fixed << duration * 1000.0 << " ms\n";
        }
};


int main() {
    const int iters = 1000000;
    char const *text = "01234567890123456789";
    {
        TimedSection s("cout with only endl");
        for (int i = 0; i < iters; ++i)
            std::cout << std::endl;
    }
    {
        TimedSection s("cout with only '\\n'");
        for (int i = 0; i < iters; ++i)
            std::cout << '\n';
    }
    {
        TimedSection s("printf with only '\\n'");
        for (int i = 0; i < iters; ++i)
            printf("\n");
    }
    {
        TimedSection s("cout with string constant and endl");
        for (int i = 0; i < iters; ++i)
            std::cout << "01234567890123456789" << std::endl;
    }
    {
        TimedSection s("cout with string constant and '\\n'");
        for (int i = 0; i < iters; ++i)
            std::cout << "01234567890123456789\n";
    }
    {
        TimedSection s("printf with string constant and '\\n'");
        for (int i = 0; i < iters; ++i)
            printf("01234567890123456789\n");
    }
    {
        TimedSection s("cout with some stuff and endl");
        for (int i = 0; i < iters; ++i)
            std::cout << text << "01234567890123456789" << i << std::endl;
    }
    {
        TimedSection s("cout with some stuff and '\\n'");
        for (int i = 0; i < iters; ++i)
            std::cout << text << "01234567890123456789" << i << '\n';
    }
    {
        TimedSection s("printf with some stuff and '\\n'");
        for (int i = 0; i < iters; ++i)
            printf("%s01234567890123456789%i\n", text, i);
    }
    {
        TimedSection s("cout with formatted double (width & precision once)");
        std::cout << std::fixed << std::scientific << std::right << std::showpoint;
        std::cout.width(8);
        for (int i = 0; i < iters; ++i)
            std::cout << text << 8.315 << i << '\n';
    }
    {
        TimedSection s("cout with formatted double (width & precision on each call)");
        std::cout << std::fixed << std::scientific << std::right << std::showpoint;

        for (int i = 0; i < iters; ++i)
            { std::cout.width(8);
              std::cout.precision(3);
              std::cout << text << 8.315 << i << '\n';
            }
    }
    {
        TimedSection s("printf with formatted double");
        for (int i = 0; i < iters; ++i)
            printf("%8.3f%i\n", 8.315, i);
    }
}

The result is:

cout with only endl    6453.000000 ms
cout with only '\n'    125.000000 ms
printf with only '\n'    156.000000 ms
cout with string constant and endl    6937.000000 ms
cout with string constant and '\n'    1391.000000 ms
printf with string constant and '\n'    3391.000000 ms
cout with some stuff and endl    9672.000000 ms
cout with some stuff and '\n'    7296.000000 ms
printf with some stuff and '\n'    12235.000000 ms
cout with formatted double (width & precision once)    7906.000000 ms
cout with formatted double (width & precision on each call)    9141.000000 ms
printf with formatted double    3312.000000 ms
4
  • Wow, why is endl so much less efficient than '\n'? May 19, 2014 at 23:38
  • 1
    I believe it's because endl flushes the buffer, and \n does not, although I'm not sure this is definitively the reason why.
    – Caleb Xu
    Mar 5, 2015 at 2:18
  • This is not an asnwer to the question, it's more like an answer to Daniel's and Thomas's. Feb 8, 2016 at 21:35
  • @CalebXu, nope, you're right; that's the only reason why. If you look at the definition for std::endl template <class _Elem, class _Traits> basic_ostream<_Elem, _Traits> &__CLRCALL_OR_CDECL endl(basic_ostream<_Elem, _Traits> &_Ostr) { // insert newline and flush stream _Ostr.put(_Ostr.widen('\n')); _Ostr.flush(); return _Ostr; } it literally inserts a newline and flushes the stream.
    – avighnac
    May 11, 2022 at 18:49
2

Update 2023:

The idiomatic way to print to the console from c++23 is supposed to be with std::print, which uses {} placeholders in the format string syntax (see below):

#include <print>

int main()
{
    std::print("{}, {} !", "Hello", "world");
}

However as of now, the compilers support for it is very poor.

Meanwhile we can use the {fmt} library for a similar API.
Note that the c++ standard is actually based (mostly) on a subset of {fmt}.
See more about it here: What are the differences between libfmt and std::format?.
For more info about the format string syntax see here: {fmt} Format String Syntax.

Working example:

#include <fmt/core.h>

int main()
{
    fmt::print("{}, {} !", "Hello", "world");
}

Live demo - Godbolt

1

I would like say that extensibility lack of printf is not entirely true:
In C, it is true. But in C, there are no real classes.
In C++, it is possible to overload cast operator, so, overloading a char* operator and using printf like this:

Foo bar;
...;
printf("%s",bar);

can be possible, if Foo overload the good operator. Or if you made a good method. In short, printf is as extensible as cout for me.

Technical argument I can see for C++ streams (in general... not only cout.) are:

  • Typesafety. (And, by the way, if I want to print a single '\n' I use putchar('\n')... I will not use a nuke-bomb to kill an insect.).

  • Simpler to learn. (no "complicated" parameters to learn, just to use << and >> operators)

  • Work natively with std::string (for printf there is std::string::c_str(), but for scanf?)

For printf I see:

  • Easier, or at least shorter (in term of characters written) complex formatting. Far more readable, for me (matter of taste I guess).

  • Better control of what the function made (Return how many characters where written and there is the %n formatter: "Nothing printed. The argument must be a pointer to a signed int, where the number of characters written so far is stored." (from printf - C++ Reference)

  • Better debugging possibilities. For same reason as last argument.

My personal preferences go to printf (and scanf) functions, mainly because I love short lines, and because I don't think type problems on printing text are really hard to avoid. The only thing I deplore with C-style functions is that std::string is not supported. We have to go through a char* before giving it to printf (with the std::string::c_str() if we want to read, but how to write?)

2
  • 3
    The compiler has no type information for varargs functions, so it won't convert the actual parameter (except default argument promotions, such as standard integral promotions). See 5.2.2p7. A user-defined conversion to char* won't be used.
    – Ben Voigt
    Jul 31, 2012 at 2:42
  • 1
    Even if this worked, it wouldn't be an example of sprintf extensibility, just a clever hack to give sprintf what it expects, and it ignores some serious issues such as where the char* lives and for how long, and the dangers of user-defined implicit casts. Jun 7, 2015 at 3:40
1

More differences: "printf" returns an integer value (equal to the number of characters printed) and "cout" does not return anything

And.

cout << "y = " << 7; is not atomic.

printf("%s = %d", "y", 7); is atomic.

cout performs typechecking, printf doesn't.

There's no iostream equivalent of "% d"

5
  • 3
    cout doesn't return anything because it's an object, not a function. operator<< does return something (normally its left operand, but a false value if there's an error). And in what sense is the printf call "atomic"? Dec 27, 2012 at 16:44
  • 10
    It is like an atomic bomb. printf("%s\n",7); Mar 14, 2013 at 2:25
  • @artlessnoise wait why segmentation fault? %s is ? Jan 18, 2016 at 13:14
  • 2
    That is the point of the 'atomic bomb' statement. A printf %s argument must have a valid pointer to a null terminated string. The memory range '7' (a pointer) is not usually valid; a segmentation fault could be lucky. On some systems, '7' might print a lot of garbage to a console and you would have to look at it for a day before the program stops. In other words, this is a bad thing about printf. Static analysis tools can catch many of these issues. Jan 18, 2016 at 14:36
  • 1
    While technically printf doesn't do typechecking, I've never ever used a compiler that didn't warn me about type errors with printf... Jan 11, 2020 at 8:43
1

TL;DR: Always do your own research, in regard of generated machine code size, performance, readability and coding time before trusting random comments online, including this one.

I'm no expert. I just happened to overhear two co-workers talking about how we should avoid using C++ in embedded systems because of performance issues. Well, interesting enough, I did a benchmark based on a real project task.

In said task, we had to write some config to RAM. Something like:

coffee=hot
sugar=none
milk=breast
mac=AA:BB:CC:DD:EE:FF

Here's my benchmark programs (Yes, I know OP asked about printf(), not fprintf(). Try to capture the essence and by the way, OP's link points to fprintf() anyway.)

C program:

char coffee[10], sugar[10], milk[10];
unsigned char mac[6];

/* Initialize those things here. */

FILE * f = fopen("a.txt", "wt");

fprintf(f, "coffee=%s\nsugar=%s\nmilk=%s\nmac=%02X:%02X:%02X:%02X:%02X:%02X\n", coffee, sugar, milk, mac[0], mac[1],mac[2],mac[3],mac[4],mac[5]);

fclose(f);

C++ program:

//Everything else is identical except:

std::ofstream f("a.txt", std::ios::out);

f << "coffee=" << coffee << "\n";
f << "sugar=" << sugar << "\n";
f << "milk=" << milk << "\n";
f << "mac=" << (int)mac[0] << ":"
    << (int)mac[1] << ":"
    << (int)mac[2] << ":"
    << (int)mac[3] << ":"
    << (int)mac[4] << ":"
    << (int)mac[5] << endl;
f.close();

I did my best to polish them before I looped them both 100,000 times. Here are the results:

C program:

real    0m 8.01s
user    0m 2.37s
sys     0m 5.58s

C++ program:

real    0m 6.07s
user    0m 3.18s
sys     0m 2.84s

Object file size:

C   - 2,092 bytes
C++ - 3,272 bytes

Conclusion: On my very specific platform, with a very specific processor, running a very specific version of Linux kernel, to run a program which is compiled with a very specific version of GCC, in order to accomplish a very specific task, I would say the C++ approach is more suitable because it runs significantly faster and provide much better readability. On the other hand, C offers small footprint, in my opinion, means nearly nothing because program size is not of our concern.

Remeber, YMMV.

4
  • 3
    I disagree that C++ is more readable in this example, because your example packs multiple lines into a single printf call. That is naturally less readable than the way you did the C++ code, and is rarely done in C because its hard to read and hard to maintain. A fair comparison would spread out the C into separate printfs, one for reach line.
    – Alcamtar
    Apr 24, 2018 at 6:24
  • 1
    @maharvey67 It's true what you said. However, the example I provided in C was in consideration of performance. The packed-in-one call to fprintf was two seconds slower than the C++ equivalence already. If I were to make the C code readable then it might be even slower. Disclaimer: This was one year ago and I remember I tried my best to polish both C and C++ code. I had no proof of separated calls to fprintf would be faster than one single call, but the reason I did it this way probably indicates that it wasn't.
    – Wesley
    Apr 25, 2018 at 2:39
  • I would say the C++ approach is more suitable because it runs significantly faster and provide much better readability I wouldn't. The C++ version took 3.18 seconds of user time while the C version took only 2.37 seconds of user time. That means the C binary was much more efficient in doing its user-space work, and the entirety of the performance difference is due to the system time being much lower for the C++ version. Since you neglected to specify how the IO was actually being performed by the compiled binaries, there's no way to tell why the C++ binary used less system time. Jun 8, 2021 at 22:59
  • It could be something mundane as the C++ output being buffered differently. It could be because of locking in the C calls. How about benchmarking sprintf() and then write() using 'O_DIRECT'? Jun 8, 2021 at 23:00
-5

printf is a function whereas cout is a variable.

3
  • 10
    I did a roll-back because, although the answer itself may be wrong, it is still a genuine answer. If you (correctly) think the answer is wrong, you have two options: 1) add a comment or 2) add a new answer (or do both). Don't change someone's answer to such that it says something completely different from what was intended by the author.
    – Mark
    Jul 15, 2014 at 16:27
  • 1
    printf is a function, but printf() is a function call =)
    – vp_arth
    Dec 29, 2016 at 17:15
  • 1
    cout is an object, not a variable.
    – Lin
    Mar 22, 2020 at 16:36

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