637

I have to format std::string with sprintf and send it into file stream. How can I do this?

4
  • 1
    @Ockonal — For the sake of the community (I couldn't care less about my rep) I suggest you change your selection. The one currently selected, in the first snippet, presents a bug waiting to happen in its use of an arbitrary max length. The second snippet completely ignores your stated desire to use vargs like sprintf. I suggest you select the ONLY answer here that is clean, safe, relies only on C++ standards, tested, and well commented. That it is mine is not relevant. It is objectively true. See stackoverflow.com/questions/2342162/…. Sep 21, 2018 at 21:31
  • @TrevorBoydSmith a std::format was added to C++20 BTW: stackoverflow.com/a/57286312/895245 Awesome! Jul 31, 2019 at 8:24
  • 4
    @CiroSantilli i read an article about C++20 just yesterday and i saw that C++20 copied boost (for the millionth time now) by adding the std::format to the C++20 spec! I was very very happy! Almost every C++ file I have written in the last 9 years has used boost::format. adding official printf style output to streams in C++ will go a long way IMO for all of C++. Jul 31, 2019 at 12:13
  • 5
    @TrevorBoydSmith That is not correct. std::format is using replacement fields ({}) as opposed to the %-style of printf and boost::format. This was initially implemented in the library {fmt} by Victor Zverovich, who also also authored C++20's std::format and has an answer in this very thread.
    – iFreilicht
    Oct 15, 2020 at 10:28

44 Answers 44

595

Modern C++ makes this super simple.

C++20

C++20 introduces std::format, which allows you to do exactly that. It uses replacement fields similar to those in python:

#include <iostream>
#include <format>
 
int main() {
    std::cout << std::format("Hello {}!\n", "world");
}

Code from cppreference.com, CC BY-SA and GFDL

Check out the compiler support page to see if it's available in your standard library implementation.

As of 2023-07-18, partial support is available starting from:

In all other cases, you can resort to the C++11 solution below, or use the {fmt} library, which has the same semantics as std::format.


C++11

With C++11s std::snprintf, this already became a pretty easy and safe task.

#include <memory>
#include <string>
#include <stdexcept>

template<typename ... Args>
std::string string_format( const std::string& format, Args ... args )
{
    int size_s = std::snprintf( nullptr, 0, format.c_str(), args ... ) + 1; // Extra space for '\0'
    if( size_s <= 0 ){ throw std::runtime_error( "Error during formatting." ); }
    auto size = static_cast<size_t>( size_s );
    std::unique_ptr<char[]> buf( new char[ size ] );
    std::snprintf( buf.get(), size, format.c_str(), args ... );
    return std::string( buf.get(), buf.get() + size - 1 ); // We don't want the '\0' inside
}

The code snippet above is licensed under CC0 1.0.

Line by line explanation:

Aim: Write to a char* by using std::snprintf and then convert that to a std::string.

First, we determine the desired length of the char array using a special condition in snprintf. From cppreference.com:

Return value

[...] If the resulting string gets truncated due to buf_size limit, function returns the total number of characters (not including the terminating null-byte) which would have been written, if the limit was not imposed.

This means that the desired size is the number of characters plus one, so that the null-terminator will sit after all other characters and that it can be cut off by the string constructor again. This issue was explained by @alexk7 in the comments.

int size_s = std::snprintf( nullptr, 0, format.c_str(), args ... ) + 1;

snprintf will return a negative number if an error occurred, so we then check whether the formatting worked as desired. Not doing this could lead to silent errors or the allocation of a huge buffer, as pointed out by @ead in the comments.

if( size_s <= 0 ){ throw std::runtime_error( "Error during formatting." ); }

Because we know that size_s can't be negative, we use a static cast to convert it from a signed int to an unsigned size_t. This way, even the most pedantic compiler won't complain about the conversions that would otherwise happen on the next lines.

size_t size = static_cast<size_t>( size_s );

Next, we allocate a new character array and assign it to a std::unique_ptr. This is generally advised, as you won't have to manually delete it again.

Note that this is not a safe way to allocate a unique_ptr with user-defined types as you can not deallocate the memory if the constructor throws an exception!

std::unique_ptr<char[]> buf( new char[ size ] );

In C++14, you could instead use make_unique, which is safe for user-defined types.

auto buf = std::make_unique<char[]>( size );

After that, we can of course just use snprintf for its intended use and write the formatted string to the char[].

std::snprintf( buf.get(), size, format.c_str(), args ... );

Finally, we create and return a new std::string from that, making sure to omit the null-terminator at the end.

return std::string( buf.get(), buf.get() + size - 1 );

You can see an example in action here.


If you also want to use std::string in the argument list, take a look at this gist.


Additional information for Visual Studio users:

As explained in this answer, Microsoft renamed std::snprintf to _snprintf (yes, without std::). MS further set it as deprecated and advises to use _snprintf_s instead, however _snprintf_s won't accept the buffer to be zero or smaller than the formatted output and will not calculate the outputs length if that occurs. So in order to get rid of the deprecation warnings during compilation, you can insert the following line at the top of the file which contains the use of _snprintf:

#pragma warning(disable : 4996)

Final thoughts

A lot of answers to this question were written before the time of C++11 and use fixed buffer lengths or vargs. Unless you're stuck with old versions of C++, I wouldn't recommend using those solutions. Ideally, go the C++20 way.

Because the C++11 solution in this answer uses templates, it can generate quite a bit of code if it is used a lot. However, unless you're developing for an environment with very limited space for binaries, this won't be a problem and is still a vast improvement over the other solutions in both clarity and security.

If space efficiency is super important, these two solution with vargs and vsnprintf can be useful. DO NOT USE any solutions with fixed buffer lengths, that is just asking for trouble.

42
  • 3
    @moooeeeep Multiple reasons. Firstly, the goal here is to return an std::string, not a c-string, so you probably meant return string(&buf[0], size); or something similar. Secondly, if you were to return a c-string like that, it would cause undefined behaviour because the vector that holds the values you point to will be invalidated on return. Thirdly, when I started to learn C++, the standard didn't define in what order elements had to be stored inside an std::vector, so accessing its storage via a pointer was undefined behaviour. Now it'd work, but I see no benefit in doing it that way.
    – iFreilicht
    Apr 25, 2015 at 9:48
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    I really like this solution, however I think the line return string(buf.get(), buf.get() + size); should be return string(buf.get(), buf.get() + size - 1); else you get a string with a null character on the end. I found this to be the case on gcc 4.9. May 21, 2015 at 21:50
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    My compiler complains about this solution (gcc version 5.4.0 20160609 Ubuntu 5.4.0-6ubuntu1~16.04.1): error: format not a string literal and no format arguments [-Werror=format-security]. This makes sense as the format argument to snprintf() is a variable, not a literal, and could result in security issues. More here: stackoverflow.com/q/9707569/143504 and stackoverflow.com/q/9306175/143504.
    – Julien-L
    Jul 20, 2016 at 16:20
  • 4
    Passing a std::string to %s cause a compile error (error: cannot pass object of non-trivial type 'std::__cxx11::basic_string<char>' through variadic function; call will abort at runtime [-Wnon-pod-varargs]) in clang 3.9.1, but in CL 19 it compiles fine and crashes at runtime instead. Any warning flag I can turn on to have that cought at compile time in cl too ?
    – Zitrax
    Feb 1, 2017 at 8:46
  • 3
    The compiler will generate a template specialization for every tuple of parameter types. If this function is used many times with different parameters, then a lot of code will be generated and compiled. (code bloat) Jun 7, 2017 at 14:53
415

You can't do it directly, because you don't have write access to the underlying buffer (until C++11; see Dietrich Epp's comment). You'll have to do it first in a c-string, then copy it into a std::string:

  char buff[100];
  snprintf(buff, sizeof(buff), "%s", "Hello");
  std::string buffAsStdStr = buff;

But I'm not sure why you wouldn't just use a string stream? I'm assuming you have specific reasons to not just do this:

  std::ostringstream stringStream;
  stringStream << "Hello";
  std::string copyOfStr = stringStream.str();
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    The magic cookie in char buf[100]; makes this solution not very robust. But the essential idea is there. Feb 26, 2010 at 14:40
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    John,streams are not slow. The only reason streams seem slow is that by default the iostreams are synchronizing with C FILE output so that intermixed cout and printfs are output correctly. Disabling this link (with a call to cout.sync_with_stdio(false)) causes c++'s streams to outperform stdio, at least as of MSVC10.
    – Jimbo
    Jan 20, 2013 at 21:15
  • 81
    The reason to use formats is to let a localizer rebuild the structure of the sentence for foreign languages, instead of hard coding the grammar of the sentence. Jul 9, 2013 at 14:51
  • 287
    For some reason, other languages use printf-like syntax: Java, Python (the new syntax is still closer to printf than to streams). Only C++ inflicts this verbose abomination on innocent human beings.
    – quant_dev
    Apr 5, 2015 at 0:29
  • 14
    Even better, use asprintf, which allocates a new string with enough space to hold the result. Then copy that to an std::string if you like, and remember to free the original. Also, it's possible to put this in a macro so that any good compiler will help validate the format for you - you don't want to put a double where a %s is expected Jul 10, 2015 at 14:35
252

C++11 solution that uses vsnprintf() internally:

#include <stdarg.h>  // For va_start, etc.

std::string string_format(const std::string fmt, ...) {
    int size = ((int)fmt.size()) * 2 + 50;   // Use a rubric appropriate for your code
    std::string str;
    va_list ap;
    while (1) {     // Maximum two passes on a POSIX system...
        str.resize(size);
        va_start(ap, fmt);
        int n = vsnprintf((char *)str.data(), size, fmt.c_str(), ap);
        va_end(ap);
        if (n > -1 && n < size) {  // Everything worked
            str.resize(n);
            return str;
        }
        if (n > -1)  // Needed size returned
            size = n + 1;   // For null char
        else
            size *= 2;      // Guess at a larger size (OS specific)
    }
    return str;
}

A safer and more efficient (I tested it, and it is faster) approach:

#include <stdarg.h>  // For va_start, etc.
#include <memory>    // For std::unique_ptr

std::string string_format(const std::string fmt_str, ...) {
    int final_n, n = ((int)fmt_str.size()) * 2; /* Reserve two times as much as the length of the fmt_str */
    std::unique_ptr<char[]> formatted;
    va_list ap;
    while(1) {
        formatted.reset(new char[n]); /* Wrap the plain char array into the unique_ptr */
        strcpy(&formatted[0], fmt_str.c_str());
        va_start(ap, fmt_str);
        final_n = vsnprintf(&formatted[0], n, fmt_str.c_str(), ap);
        va_end(ap);
        if (final_n < 0 || final_n >= n)
            n += abs(final_n - n + 1);
        else
            break;
    }
    return std::string(formatted.get());
}

The fmt_str is passed by value to conform with the requirements of va_start.

NOTE: The "safer" and "faster" version doesn't work on some systems. Hence both are still listed. Also, "faster" depends entirely on the preallocation step being correct, otherwise the strcpy renders it slower.

27
  • 3
    slow. why increase size by 1? And when does this funciton return -1? May 18, 2012 at 10:45
  • 28
    You are overwriting str.c_str()? Isn't that dangerous?
    – quantum
    Aug 22, 2012 at 15:12
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    va_start with a reference argument has problems on MSVC. It fails silently and returns pointers to random memory. As a workaround, use std::string fmt instead of std::string &fmt, or write a wrapper object. Aug 27, 2012 at 17:53
  • 6
    I +1'd cause I know this will probably work based on how most std::strings are implemented, however c_str isn't really intended to be a place to modify the underlying string. Its supposed to be read-only.
    – Doug T.
    Sep 25, 2012 at 14:57
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    And to obtain the resulting string length beforehand, see: stackoverflow.com/a/7825892/908336 I don't see the point in increasing size in each iteration, when you can obtain it by the first call of vsnprintf(). May 15, 2013 at 9:12
128

C++20 has std::format which resembles sprintf in terms of API but is fully type-safe, works with user-defined types, and uses Python-like format string syntax. Here's how you can format std::string and write it to a stream:

std::cout << std::format("The answer is {}.", 42);

Alternatively, you could use the {fmt} library to format a string and write it to stdout or a file stream in one go:

fmt::print("The answer is {}.", 42);

As for sprintf or most of the other answers here, unfortunately they use varargs and are inherently unsafe unless you use something like GCC's format attribute which only works with literal format strings. You can see why these functions are unsafe on the following example:

std::string format_str = "%s";
string_format(format_str, format_str[0]);

where string_format is an implementation from the Erik Aronesty's answer. This code compiles, but it will most likely crash when you try to run it:

$ g++ -Wall -Wextra -pedantic test.cc 
$ ./a.out 
Segmentation fault: 11

Disclaimer: I'm the author of {fmt} and C++20 std::format.

5
  • IMHO you miss the include error: 'fmt' has not been declared
    – Sérgio
    Feb 20, 2018 at 4:30
  • 1
    This is just a snippet, not a complete code. Obviously you need to include <fmt/format.h> and put the code in a function.
    – vitaut
    Feb 20, 2018 at 8:20
  • for me is not so obvious , IMHO you should include it in snippet , thanks for the feedback
    – Sérgio
    Feb 20, 2018 at 18:14
  • Building off of Erik Aronesty's answer is a red herring. His first code sample is unsafe and his second is inefficient and clumsy. The clean implementation is clearly indicated by the fact that, if the buf_siz of any of the vprintf family of functions is zero, nothing is written and buffer may be a null pointer, however the return value (number of bytes that would be written not including the null terminator) is still calculated and returned. A production quality answer is here: stackoverflow.com/questions/2342162/… Sep 21, 2018 at 21:16
  • 1
    An fmt like implementation was added to C++20! stackoverflow.com/a/57286312/895245 fmt currently claims support for it. Awesome work! Jul 31, 2019 at 8:25
120

boost::format() provides the functionality you want:

As from the Boost format libraries synopsis:

A format object is constructed from a format-string, and is then given arguments through repeated calls to operator%. Each of those arguments are then converted to strings, who are in turn combined into one string, according to the format-string.

#include <boost/format.hpp>

cout << boost::format("writing %1%,  x=%2% : %3%-th try") % "toto" % 40.23 % 50; 
// prints "writing toto,  x=40.230 : 50-th try"
5
  • 5
    you can prune the libraries you need out of boost as well. Using a suplied tool. Feb 26, 2010 at 16:23
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    Boost Format is not only big, but also very slow. See zverovich.net/2013/09/07/… and boost.org/doc/libs/1_52_0/libs/spirit/doc/html/spirit/karma/…
    – vitaut
    May 20, 2014 at 1:43
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    Including boost anywhere in your project immediately increases significantly compile times. For large projects, it most probably doesn't matter. For small projects, boost is a drag.
    – quant_dev
    Apr 5, 2015 at 0:30
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    @vitaut While it is terribly resource consuming when compared to the alternatives. How often do you format strings? Considering it only takes a few micro seconds and most projects probably only use it a few dozen times, it is not noticeable in a project that doesn't focus heavily on string formatting, right?
    – AturSams
    Aug 17, 2015 at 12:04
  • 2
    Unfortunatelly, boost::format does not work the same way: does not accept the var_args. Some people like to have all code related to a single program looking the same/using the same idioms.
    – xor007
    Oct 26, 2015 at 14:37
26

Tested, Production Quality Answer

This answer handles the general case with standards compliant techniques. The same approach is given as an example on CppReference.com near the bottom of their page. Unlike their example, this code fits the question's requirements and is field tested in robotics and satellite applications. It also has improved commenting. Design quality is discussed further below.

#include <string>
#include <cstdarg>
#include <vector>

// requires at least C++11
const std::string vformat(const char * const zcFormat, ...) {

    // initialize use of the variable argument array
    va_list vaArgs;
    va_start(vaArgs, zcFormat);

    // reliably acquire the size
    // from a copy of the variable argument array
    // and a functionally reliable call to mock the formatting
    va_list vaArgsCopy;
    va_copy(vaArgsCopy, vaArgs);
    const int iLen = std::vsnprintf(NULL, 0, zcFormat, vaArgsCopy);
    va_end(vaArgsCopy);

    // return a formatted string without risking memory mismanagement
    // and without assuming any compiler or platform specific behavior
    std::vector<char> zc(iLen + 1);
    std::vsnprintf(zc.data(), zc.size(), zcFormat, vaArgs);
    va_end(vaArgs);
    return std::string(zc.data(), iLen); }

#include <ctime>
#include <iostream>
#include <iomanip>

// demonstration of use
int main() {

    std::time_t t = std::time(nullptr);
    std::cerr
        << std::put_time(std::localtime(& t), "%D %T")
        << " [debug]: "
        << vformat("Int 1 is %d, Int 2 is %d, Int 3 is %d", 11, 22, 33)
        << std::endl;
    return 0; }

Predictable Linear Efficiency

Two passes are necessities for a secure, reliable, and predictable reusable function per the question specifications. Presumptions about the distribution of sizes of vargs in a reusable function is bad programming style and should be avoided. In this case, arbitrarily large variable length representations of vargs is a key factor in choice of algorithm.

Retrying upon overflow is exponentially inefficient, which is another reason discussed when the C++11 standards committee discussed the above proposal to provide a dry run when the write buffer is null.

In the above production ready implementation, the first run is such a dry run to determine allocation size. No allocation occurs. Parsing of printf directives and the reading of vargs has been made extremely efficient over decades. Reusable code should be predictable, even if a small inefficiency for trivial cases must be sacrificed.

Security and Reliability

Andrew Koenig said to a small group of us after his lecture at a Cambridge event, "User functions shouldn't rely on the exploitation of a failure for unexceptional functionality." As usual, his wisdom has been shown true in the record since. Fixed and closed security bug issues often indicate retry hacks in the description of the hole exploited prior to the fix.

This is mentioned in the formal standards revision proposal for the null buffer feature in Alternative to sprintf, C9X Revision Proposal, ISO IEC Document WG14 N645/X3J11 96-008. An arbitrarily long string inserted per print directive, "%s," within the constraints of dynamic memory availability, is not an exception, and should not be exploited to produce, "Unexceptional functionality."

Consider the proposal along side the example code given at the bottom of the C++Reference.org page linked to in the first paragraph of this answer.

Also, the testing of failure cases is rarely as robust of success cases.

Portability

All major O.S. vendors provide compilers that fully support std::vsnprintf as part of the c++11 standards. Hosts running products of vendors that no longer maintain distributions should be furnished with g++ or clang++ for many reasons.

Stack Use

Stack use in the 1st call to std::vsnprintf will be less than or equal to that of the 2nd, and and it will be freed before the 2nd call begins. If the first call exceeds stack availability, then std::fprintf would fail too.

5
  • Brief and robust. It could fail on HP-UX, IRIX, Tru64 which have have non-conforming vsnprintf-s. EDIT: also, considering how two-passes might impact performances, esp. for most common, small strings formatting, have you considered a guess for the initial pass, that might be sufficiently large? Dec 22, 2018 at 15:46
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    FWIW, the guessing I was referring to uses a stack-allocated buffer where the first run occurs. If it fits it saves the cost of a second run and the dynamic allocation that occurs there. Presumably, small strings are more frequently used than large strings. In my crude benchmark that strategy (almost) halves the running time for small strings and is within a few percents (fixed overhead maybe?) of the strategy above. Would you please elaborate on the C++11 design that employs a dry run, etc.? I would like to read about it. Dec 23, 2018 at 14:06
  • @Engineerist, your questions have been addressed in the body of the answer, above and below the code. The sub topics can be made easier to read that way. Dec 23, 2018 at 23:34
  • 2
    So why do you use a std::vector<char> instead of a std::string ? Oct 8, 2020 at 20:41
  • 2
    Those brackets are the real crime here Apr 15, 2023 at 22:28
20

I wrote my own using vsnprintf so it returns string instead of having to create my own buffer.

#include <string>
#include <cstdarg>

//missing string printf
//this is safe and convenient but not exactly efficient
inline std::string format(const char* fmt, ...){
    int size = 512;
    char* buffer = 0;
    buffer = new char[size];
    va_list vl;
    va_start(vl, fmt);
    int nsize = vsnprintf(buffer, size, fmt, vl);
    if(size<=nsize){ //fail delete buffer and try again
        delete[] buffer;
        buffer = 0;
        buffer = new char[nsize+1]; //+1 for /0
        nsize = vsnprintf(buffer, size, fmt, vl);
    }
    std::string ret(buffer);
    va_end(vl);
    delete[] buffer;
    return ret;
}

So you can use it like

std::string mystr = format("%s %d %10.5f", "omg", 1, 10.5);
4
  • This does a full extra copy of the data, it's possible to use vsnprintf directly into the string. Mar 12, 2013 at 16:47
  • 1
    Use the code in stackoverflow.com/a/7825892/908336 to obtain the resulting string length beforehand. And you can use smart pointers for an exception-safe code: std::unique_ptr<char[]> buffer (new char[size]); May 15, 2013 at 9:19
  • 2
    I'm not sure this is correct in the fallback case; I think you need to do a va_copy of vl for the second vsnprintf() to see the arguments correctly. For an example see: github.com/haberman/upb/blob/… Nov 2, 2013 at 18:25
  • You cannot reuse vl without calling va_end() and va_start() again. Add a va_end() after both vsnprintf's and and add a va_start before the second one. Oct 28, 2022 at 22:40
20

In order to format std::string in a 'sprintf' manner, call snprintf (arguments nullptr and 0) to get length of buffer needed. Write your function using C++11 variadic template like this:

#include <cstdio>
#include <string>
#include <cassert>

template< typename... Args >
std::string string_sprintf( const char* format, Args... args ) {
  int length = std::snprintf( nullptr, 0, format, args... );
  assert( length >= 0 );

  char* buf = new char[length + 1];
  std::snprintf( buf, length + 1, format, args... );

  std::string str( buf );
  delete[] buf;
  return str;
}

Compile with C++11 support, for example in GCC: g++ -std=c++11

Usage:

  std::cout << string_sprintf("%g, %g\n", 1.23, 0.001);
8
  • std::snprintf is not available in VC++12 (Visual Studio 2013). Replace it with _snprintf instead. Apr 12, 2016 at 6:31
  • why you do not use char buf[length + 1]; instead of char* buf = new char[length + 1]; ?
    – Behrouz.M
    May 19, 2016 at 6:49
  • 1
    The difference between using char[] and char* with new, is that in the former case buf would be allocated on stack. It is OK for small buffers, but since we cannot guarantee size of resulting string, it is slightly better to use new. For example on my machine string_sprintf("value: %020000000d",5) , print outrageous number of leading zeros before number 5, core dumps when using array on stack, but works OK when using dynamically allocated array new char[length + 1] May 19, 2016 at 13:52
  • very clever idea to get the actual buff size needed for formatted output
    – Eddie Deng
    Sep 3, 2016 at 13:11
  • 1
    @user2622016: Thanks for the solution! Please note that std::move is superfluous. Jun 18, 2019 at 15:45
20

C++20 std::format

It has arrived! The feature is described at: http://www.open-std.org/jtc1/sc22/wg21/docs/papers/2019/p0645r9.html and uses a Python-like .format() syntax.

I expect that the usage will be like:

#include <format>
#include <string>

int main() {
    std::string message = std::format("The answer is {}.", 42);
}

GCC 9.1.0 with g++-9 -std=c++2a still doesn't support it.

The existing fmt library implements it for before it gets official support: https://github.com/fmtlib/fmt as previously mentioned at: std::string formatting like sprintf Install on Ubuntu 22.04:

sudo apt install libfmt-dev

Modify source to replace:

  • <format> with <fmt/core.h>
  • std::format to fmt::format

main.cpp

#include <string>
#include <iostream>

#include <fmt/core.h>

int main() {
    std::string message = fmt::format("The answer is {}.", 42);
    std::cout << message << std::endl;
}

and compile and run with:

g++ -std=c++11 -o main.out main.cpp -lfmt
./main.out

Output:

The answer is 42.

The API will add a new std::format header:

The proposed formatting API is defined in the new header <format> and should have no impact on existing code.

Hexadecimal format {:x}

C++ cout hex values?

Leading zeroes {:03}

Print leading zeros with C++ output operator?

Alignment left {:<}, right {:>}, center {:^}

C++ alignment when printing cout <<

Floating point precision {:.2}

Show sign on positive numbers {:+}

How to print positive numbers with a prefix + in C++

Show booleans as true and false: {:}

Converting bool to text in C++

0
17

If you only want a printf-like syntax (without calling printf yourself), have a look at Boost Format.

1
15

[edit: 20/05/25] better still...:
In header:

// `say` prints the values
// `says` returns a string instead of printing
// `sayss` appends the values to it's first argument instead of printing
// `sayerr` prints the values and returns `false` (useful for return statement fail-report)<br/>

void PRINTSTRING(const std::string &s); //cater for GUI, terminal, whatever..
template<typename...P> void say(P...p) { std::string r{}; std::stringstream ss(""); (ss<<...<<p); r=ss.str(); PRINTSTRING(r); }
template<typename...P> std::string says(P...p) { std::string r{}; std::stringstream ss(""); (ss<<...<<p); r=ss.str(); return r; }
template<typename...P> void sayss(std::string &s, P...p) { std::string r{}; std::stringstream ss(""); (ss<<...<<p); r=ss.str();  s+=r; } //APPENDS! to s!
template<typename...P> bool sayerr(P...p) { std::string r{}; std::stringstream ss("ERROR: "); (ss<<...<<p); r=ss.str(); PRINTSTRING(r); return false; }

The PRINTSTRING(r)-function is to cater for GUI or terminal or any special output needs using #ifdef _some_flag_, the default is:

void PRINTSTRING(const std::string &s) { std::cout << s << std::flush; }

[edit '17/8/31] Adding a variadic templated version 'vtspf(..)':

template<typename T> const std::string type_to_string(const T &v)
{
    std::ostringstream ss;
    ss << v;
    return ss.str();
};

template<typename T> const T string_to_type(const std::string &str)
{
    std::istringstream ss(str);
    T ret;
    ss >> ret;
    return ret;
};

template<typename...P> void vtspf_priv(std::string &s) {}

template<typename H, typename...P> void vtspf_priv(std::string &s, H h, P...p)
{
    s+=type_to_string(h);
    vtspf_priv(s, p...);
}

template<typename...P> std::string temp_vtspf(P...p)
{
    std::string s("");
    vtspf_priv(s, p...);
    return s;
}

which is effectively a comma-delimited version (instead) of the sometimes hindering <<-operators, used like this:

char chSpace=' ';
double pi=3.1415;
std::string sWorld="World", str_var;
str_var = vtspf("Hello", ',', chSpace, sWorld, ", pi=", pi);


[edit] Adapted to make use of the technique in Erik Aronesty's answer (above):

#include <string>
#include <cstdarg>
#include <cstdio>

//=============================================================================
void spf(std::string &s, const std::string fmt, ...)
{
    int n, size=100;
    bool b=false;
    va_list marker;

    while (!b)
    {
        s.resize(size);
        va_start(marker, fmt);
        n = vsnprintf((char*)s.c_str(), size, fmt.c_str(), marker);
        va_end(marker);
        if ((n>0) && ((b=(n<size))==true)) s.resize(n); else size*=2;
    }
}

//=============================================================================
void spfa(std::string &s, const std::string fmt, ...)
{
    std::string ss;
    int n, size=100;
    bool b=false;
    va_list marker;

    while (!b)
    {
        ss.resize(size);
        va_start(marker, fmt);
        n = vsnprintf((char*)ss.c_str(), size, fmt.c_str(), marker);
        va_end(marker);
        if ((n>0) && ((b=(n<size))==true)) ss.resize(n); else size*=2;
    }
    s += ss;
}

[previous answer]
A very late answer, but for those who, like me, do like the 'sprintf'-way: I've written and are using the following functions. If you like it, you can expand the %-options to more closely fit the sprintf ones; the ones in there currently are sufficient for my needs. You use stringf() and stringfappend() same as you would sprintf. Just remember that the parameters for ... must be POD types.

//=============================================================================
void DoFormatting(std::string& sF, const char* sformat, va_list marker)
{
    char *s, ch=0;
    int n, i=0, m;
    long l;
    double d;
    std::string sf = sformat;
    std::stringstream ss;

    m = sf.length();
    while (i<m)
    {
        ch = sf.at(i);
        if (ch == '%')
        {
            i++;
            if (i<m)
            {
                ch = sf.at(i);
                switch(ch)
                {
                    case 's': { s = va_arg(marker, char*);  ss << s;         } break;
                    case 'c': { n = va_arg(marker, int);    ss << (char)n;   } break;
                    case 'd': { n = va_arg(marker, int);    ss << (int)n;    } break;
                    case 'l': { l = va_arg(marker, long);   ss << (long)l;   } break;
                    case 'f': { d = va_arg(marker, double); ss << (float)d;  } break;
                    case 'e': { d = va_arg(marker, double); ss << (double)d; } break;
                    case 'X':
                    case 'x':
                        {
                            if (++i<m)
                            {
                                ss << std::hex << std::setiosflags (std::ios_base::showbase);
                                if (ch == 'X') ss << std::setiosflags (std::ios_base::uppercase);
                                char ch2 = sf.at(i);
                                if (ch2 == 'c') { n = va_arg(marker, int);  ss << std::hex << (char)n; }
                                else if (ch2 == 'd') { n = va_arg(marker, int); ss << std::hex << (int)n; }
                                else if (ch2 == 'l') { l = va_arg(marker, long);    ss << std::hex << (long)l; }
                                else ss << '%' << ch << ch2;
                                ss << std::resetiosflags (std::ios_base::showbase | std::ios_base::uppercase) << std::dec;
                            }
                        } break;
                    case '%': { ss << '%'; } break;
                    default:
                    {
                        ss << "%" << ch;
                        //i = m; //get out of loop
                    }
                }
            }
        }
        else ss << ch;
        i++;
    }
    va_end(marker);
    sF = ss.str();
}

//=============================================================================
void stringf(string& stgt,const char *sformat, ... )
{
    va_list marker;
    va_start(marker, sformat);
    DoFormatting(stgt, sformat, marker);
}

//=============================================================================
void stringfappend(string& stgt,const char *sformat, ... )
{
    string sF = "";
    va_list marker;
    va_start(marker, sformat);
    DoFormatting(sF, sformat, marker);
    stgt += sF;
}
4
  • @MooingDuck: Changed function parameter as per Dan's comment to Aronesty's answer. I use only Linux/gcc, and with fmt as reference it works fine. (But I suppose people will want to play with toys, so ...) If there are any other supposed 'bugs' could you please elaborate?
    – slashmais
    Mar 12, 2013 at 13:21
  • I misunderstood how part of his code worked and thought it was doing to many resizes. Reexamining shows that I was mistaken. Your code is correct. Mar 12, 2013 at 16:45
  • Building off of Erik Aronesty's answer is a red herring. His first code sample is unsafe and his second is inefficient and clumsy. The clean implementation is clearly indicated by the fact that, if the buf_siz of any of the vprintf family of functions is zero, nothing is written and buffer may be a null pointer, however the return value (number of bytes that would be written not including the null terminator) is still calculated and returned. A production quality answer is here: stackoverflow.com/questions/2342162/… Sep 21, 2018 at 21:19
  • what about %g ?
    – asad_nitp
    Nov 23, 2020 at 9:22
14
template<typename... Args>
std::string string_format(const char* fmt, Args... args)
{
    size_t size = snprintf(nullptr, 0, fmt, args...);
    std::string buf;
    buf.reserve(size + 1);
    buf.resize(size);
    snprintf(&buf[0], size + 1, fmt, args...);
    return buf;
}

Using C99 snprintf and C++11

2
  • Of all the answers, this one is has the two things you want: Using C++ type safety (no va_list) and it writes directly into the std::string without a temporary buffer. I posted a Gist with a header library that does exactly this, but I'll only add it to this answer because it's essentially the same idea (except it also supports std::wstring). gist.github.com/dwcullop/aabb2007ba0dcd8c7e80a761545e6ca3 Aug 13, 2021 at 17:57
  • It also correctly allocates a null terminator but ensures that the '\0' is NOT included in the size, creating a result that works properly with both code that is size-aware and code that expects null termination. This is a subtle but important detail that many other answers have overlooked. Aug 13, 2021 at 18:04
11

This is how google does it: StringPrintf (BSD License)
and facebook does it in a quite similar fashion: StringPrintf (Apache License)
Both provide with a convenient StringAppendF too.

0
11

My two cents on this very popular question.

To quote the manpage of printf-like functions:

Upon successful return, these functions return the number of characters printed (excluding the null byte used to end output to strings).

The functions snprintf() and vsnprintf() do not write more than size bytes (including the terminating null byte ('\0')). If the output was truncated due to this limit then the return value is the number of characters (excluding the terminating null byte) which would have been written to the final string if enough space had been available. Thus, a return value of size or more means that the output was truncated.

In other words, a sane C++11 implementation should be the following:

#include <string>
#include <cstdio>

template <typename... Ts>
std::string fmt (const std::string &fmt, Ts... vs)
{
    char b;
    size_t required = std::snprintf(&b, 0, fmt.c_str(), vs...) + 1;
        // See comments: the +1 is necessary, while the first parameter
        //               can also be set to nullptr

    char bytes[required];
    std::snprintf(bytes, required, fmt.c_str(), vs...);

    return std::string(bytes);
}

It works quite well :)

Variadic templates are supported only in C++11. The answer from pixelpoint show a similar technique using older programming styles.

It's weird that C++ does not have such a thing out of the box. They recently added to_string(), which in my opinion is a great step forward. I'm wondering if they will add a .format operator to the std::string eventually...

Edit

As alexk7 pointed out, A +1 is needed on the return value of std::snprintf, since we need to have space for the \0 byte. Intuitively, on most architectures missing the +1 will cause the required integer to be partially overwritten with a 0. This will happen after the evaluation of required as actual parameter for std::snprintf, so the effect should not be visible.

This problem could however change, for instance with compiler optimization: what if the compiler decides to use a register for the required variable? This is the kind of errors which sometimes result in security issues.

7
  • 1
    snprintf always appends a terminating null-byte but returns the number of characters without it. Doesn't this code always skip the last character?
    – alexk7
    Jan 4, 2015 at 19:12
  • @alexk7, Nice catch! I'm updating the answer. The code does not skip the last character, but writes beyond the end of the bytes buffer, probably over the required integer (which fortunately at that point is already evaluated).
    – Dacav
    Jan 5, 2015 at 7:12
  • 1
    Just a small hint: With a buffer size of 0, you can pass a nullptr as the buffer argument, eliminating the char b; line in your code. (Source)
    – iFreilicht
    Mar 20, 2015 at 15:26
  • @iFreilicht, fix'd. Also +1
    – Dacav
    Mar 22, 2015 at 12:32
  • 2
    Using "char bytes[required]" will allocated on stack instead of heap, it can be dangerous on large format strings. Consider using use a new instead. Yann
    – Yannuth
    Mar 16, 2016 at 20:30
6

If you are on a system that has asprintf(3), you can easily wrap it:

#include <iostream>
#include <cstdarg>
#include <cstdio>

std::string format(const char *fmt, ...) __attribute__ ((format (printf, 1, 2)));

std::string format(const char *fmt, ...)
{
    std::string result;

    va_list ap;
    va_start(ap, fmt);

    char *tmp = 0;
    int res = vasprintf(&tmp, fmt, ap);
    va_end(ap);

    if (res != -1) {
        result = tmp;
        free(tmp);
    } else {
        // The vasprintf call failed, either do nothing and
        // fall through (will return empty string) or
        // throw an exception, if your code uses those
    }

    return result;
}

int main(int argc, char *argv[]) {
    std::string username = "you";
    std::cout << format("Hello %s! %d", username.c_str(), 123) << std::endl;
    return 0;
}
4
  • 2
    I would add this line as a declaration before format, as it tells gcc to check the types of the arguments and give a decent warning with -Wall: std::string format(const char *fmt, ...) __attribute__ ((format (printf, 1, 2))); Jul 11, 2015 at 12:48
  • 2
    I've just added a call to va_end . "if va_end is not called before a function that calls va_start or va_copy returns, the behavior is undefined. " - docs Jul 11, 2015 at 12:51
  • 1
    You should check the return result of vasprintf as the pointer value is undefined upon failure. So, possibly include <new> and add: if (size == -1) { throw std::bad_alloc(); }
    – Goblinhack
    Aug 27, 2017 at 23:47
  • Good point, I've modified the answer accordingly, I've decided to just put a comment there instead of doing the throw std::bad_alloc();, since I'm not using C++ exceptions in my codebase, and for people who do, they can easily add it based on the source comment and your comment here. Aug 28, 2017 at 8:52
5

Based on the answer provided by Erik Aronesty:

std::string string_format(const std::string &fmt, ...) {
    std::vector<char> str(100,'\0');
    va_list ap;
    while (1) {
        va_start(ap, fmt);
        auto n = vsnprintf(str.data(), str.size(), fmt.c_str(), ap);
        va_end(ap);
        if ((n > -1) && (size_t(n) < str.size())) {
            return str.data();
        }
        if (n > -1)
            str.resize( n + 1 );
        else
            str.resize( str.size() * 2);
    }
    return str.data();
}

This avoids the need to cast away const from the result of .c_str() which was in the original answer.

3
  • 1
    Building off of Erik Aronesty's answer is a red herring. His first code sample is unsafe and his second, with the loop is inefficient and clumsy. The clean implementation is clearly indicated by the fact that, if the buf_siz of any of the vprintf family of functions is zero, nothing is written and buffer may be a null pointer, however the return value (number of bytes that would be written not including the null terminator) is still calculated and returned. A production quality answer is here: stackoverflow.com/questions/2342162/… Sep 21, 2018 at 21:18
  • Erik Aronesty's answer has been edited since mine was added. I wanted to highlight the option of using vector<char> to store strings as they are built. I use this technique often when calling C functions from C++ code. It is interesting that the question now has 34 answers.
    – ChetS
    Oct 5, 2018 at 17:30
  • The cppreference.com example on the vfprintf page was added later. I believe the best answer is the currently accepted answer, using string streams instead of a printf variant is the C++ way of things. However my answer did add value when it was provided; It was incrementally better than other answers at the time. Now the standard has string_view, parameter packs and Variadic template a new answer could include those features. As for my answer, although it may no longer be deserving of additional up-votes, it does not deserve to be deleted or down-voted, so I'm leaving it as it.
    – ChetS
    Oct 11, 2018 at 17:50
5
inline void format(string& a_string, const char* fmt, ...)
{
    va_list vl;
    va_start(vl, fmt);
    int size = _vscprintf( fmt, vl );
    a_string.resize( ++size );
    vsnprintf_s((char*)a_string.data(), size, _TRUNCATE, fmt, vl);
    va_end(vl);
}
1
  • 2
    +1 for the smart idea, but it's not very clear what _vscprintf is. I think you should elaborate on this answer.
    – Dacav
    Oct 4, 2014 at 21:24
3

string doesn't have what you need, but std::stringstream does. Use a stringstream to create the string and then extract the string. Here is a comprehensive list on the things you can do. For example:

cout.setprecision(10); //stringstream is a stream like cout

will give you 10 decimal places of precision when printing a double or float.

1
  • 8
    which still doesn't give you anything near the control printf gives you... but is nice. Aug 27, 2014 at 15:16
3

I usually use this:

std::string myformat(const char *const fmt, ...)
{
        char *buffer = NULL;
        va_list ap;

        va_start(ap, fmt);
        (void)vasprintf(&buffer, fmt, ap);
        va_end(ap);

        std::string result = buffer;
        free(buffer);

        return result;
}

Disadvantage: not all systems support vasprint

1
  • vasprintf is nice - however you need to check the return code. On -1 buffer will have an undefined value. Need: if (size == -1) { throw std::bad_alloc(); }
    – Goblinhack
    Aug 27, 2017 at 23:49
2

You could try this:

string str;
str.resize( _MAX_PATH );

sprintf( &str[0], "%s %s", "hello", "world" );
// optionals
// sprintf_s( &str[0], str.length(), "%s %s", "hello", "world" ); // Microsoft
// #include <stdio.h>
// snprintf( &str[0], str.length(), "%s %s", "hello", "world" ); // c++11

str.resize( strlen( str.data() ) + 1 );
0
2

This is the code I use to do this in my program... It's nothing fancy, but it does the trick... Note, you will have to adjust your size as applicable. MAX_BUFFER for me is 1024.

std::string Format ( const char *fmt, ... )
{
    char textString[MAX_BUFFER*5] = {'\0'};

    // -- Empty the buffer properly to ensure no leaks.
    memset(textString, '\0', sizeof(textString));

    va_list args;
    va_start ( args, fmt );
    vsnprintf ( textString, MAX_BUFFER*5, fmt, args );
    va_end ( args );
    std::string retStr = textString;
    return retStr;
}
2
  • 4
    The initialization of textString already sets the whole buffer to zero. No need to memset... Mar 3, 2012 at 15:46
  • This does a full extra copy of the data, it's possible to use vsnprintf directly into the string. Mar 12, 2013 at 16:48
2

Took the idea from Dacav and pixelpoint's answer. I played around a bit and got this:

#include <cstdarg>
#include <cstdio>
#include <string>

std::string format(const char* fmt, ...)
{
    va_list vl;

    va_start(vl, fmt);
    int size = vsnprintf(0, 0, fmt, vl) + sizeof('\0');
    va_end(vl);

    char buffer[size];

    va_start(vl, fmt);
    size = vsnprintf(buffer, size, fmt, vl);
    va_end(vl);

    return std::string(buffer, size);
}

With sane programming practice I believe the code should be enough, however I'm still open to more secure alternatives that are still simple enough and would not require C++11.


And here's another version that makes use of an initial buffer to prevent second call to vsnprintf() when initial buffer is already enough.

std::string format(const char* fmt, ...)
{

    va_list vl;
    int size;

    enum { INITIAL_BUFFER_SIZE = 512 };

    {
        char buffer[INITIAL_BUFFER_SIZE];

        va_start(vl, fmt);
        size = vsnprintf(buffer, INITIAL_BUFFER_SIZE, fmt, vl);
        va_end(vl);

        if (size < INITIAL_BUFFER_SIZE)
            return std::string(buffer, size);
    }

    size += sizeof('\0');

    char buffer[size];

    va_start(vl, fmt);
    size = vsnprintf(buffer, size, fmt, vl);
    va_end(vl);

    return std::string(buffer, size);
}

(It turns out that this version is just similar to Piti Ongmongkolkul's answer, only that it doesn't use new and delete[], and also specifies a size when creating std::string.

The idea here of not using new and delete[] is to imply usage of the stack over the heap since it doesn't need to call allocation and deallocation functions, however if not properly used, it could be dangerous to buffer overflows in some (perhaps old, or perhaps just vulnerable) systems. If this is a concern, I highly suggest using new and delete[] instead. Note that the only concern here is about the allocations as vsnprintf() is already called with limits, so specifying a limit based on the size allocated on the second buffer would also prevent those.)

2

Below slightly modified version of @iFreilicht answer, updated to C++14 (usage of make_unique function instead of raw declaration) and added support for std::string arguments (based on Kenny Kerr article)

#include <iostream>
#include <memory>
#include <string>
#include <cstdio>

template <typename T>
T process_arg(T value) noexcept
{
    return value;
}

template <typename T>
T const * process_arg(std::basic_string<T> const & value) noexcept
{
    return value.c_str();
}

template<typename ... Args>
std::string string_format(const std::string& format, Args const & ... args)
{
    const auto fmt = format.c_str();
    const size_t size = std::snprintf(nullptr, 0, fmt, process_arg(args) ...) + 1;
    auto buf = std::make_unique<char[]>(size);
    std::snprintf(buf.get(), size, fmt, process_arg(args) ...);
    auto res = std::string(buf.get(), buf.get() + size - 1);
    return res;
}

int main()
{
    int i = 3;
    float f = 5.f;
    char* s0 = "hello";
    std::string s1 = "world";
    std::cout << string_format("i=%d, f=%f, s=%s %s", i, f, s0, s1) << "\n";
}

Output:

i = 3, f = 5.000000, s = hello world

Feel free to merge this answer with the original one if desired.

2

UPDATE 1: added fmt::format tests

I've took my own investigation around methods has introduced here and gain diametrically opposite results versus mentioned here.

I have used 4 functions over 4 methods:

  • variadic function + vsnprintf + std::unique_ptr
  • variadic function + vsnprintf + std::string
  • variadic template function + std::ostringstream + std::tuple + utility::for_each
  • fmt::format function from fmt library

For the test backend the googletest has used.

#include <string>
#include <cstdarg>
#include <cstdlib>
#include <memory>
#include <algorithm>

#include <fmt/format.h>

inline std::string string_format(size_t string_reserve, const std::string fmt_str, ...)
{
    size_t str_len = (std::max)(fmt_str.size(), string_reserve);

    // plain buffer is a bit faster here than std::string::reserve
    std::unique_ptr<char[]> formatted;

    va_list ap;
    va_start(ap, fmt_str);

    while (true) {
        formatted.reset(new char[str_len]);

        const int final_n = vsnprintf(&formatted[0], str_len, fmt_str.c_str(), ap);

        if (final_n < 0 || final_n >= int(str_len))
            str_len += (std::abs)(final_n - int(str_len) + 1);
        else
            break;
    }

    va_end(ap);

    return std::string(formatted.get());
}

inline std::string string_format2(size_t string_reserve, const std::string fmt_str, ...)
{
    size_t str_len = (std::max)(fmt_str.size(), string_reserve);
    std::string str;

    va_list ap;
    va_start(ap, fmt_str);

    while (true) {
        str.resize(str_len);

        const int final_n = vsnprintf(const_cast<char *>(str.data()), str_len, fmt_str.c_str(), ap);

        if (final_n < 0 || final_n >= int(str_len))
            str_len += (std::abs)(final_n - int(str_len) + 1);
        else {
            str.resize(final_n); // do not forget to shrink the size!
            break;
        }
    }

    va_end(ap);

    return str;
}

template <typename... Args>
inline std::string string_format3(size_t string_reserve, Args... args)
{
    std::ostringstream ss;
    if (string_reserve) {
        ss.rdbuf()->str().reserve(string_reserve);
    }
    std::tuple<Args...> t{ args... };
    utility::for_each(t, [&ss](auto & v)
    {
        ss << v;
    });
    return ss.str();
}

The for_each implementation is taken from here: iterate over tuple

#include <type_traits>
#include <tuple>

namespace utility {

    template <std::size_t I = 0, typename FuncT, typename... Tp>
    inline typename std::enable_if<I == sizeof...(Tp), void>::type
        for_each(std::tuple<Tp...> &, const FuncT &)
    {
    }

    template<std::size_t I = 0, typename FuncT, typename... Tp>
    inline typename std::enable_if<I < sizeof...(Tp), void>::type
        for_each(std::tuple<Tp...> & t, const FuncT & f)
    {
        f(std::get<I>(t));
        for_each<I + 1, FuncT, Tp...>(t, f);
    }

}

The tests:

TEST(ExternalFuncs, test_string_format_on_unique_ptr_0)
{
    for (size_t i = 0; i < 1000000; i++) {
        const std::string v = string_format(0, "%s+%u\n", "test test test", 12345);
        UTILITY_SUPPRESS_OPTIMIZATION_ON_VAR(v);
    }
}

TEST(ExternalFuncs, test_string_format_on_unique_ptr_256)
{
    for (size_t i = 0; i < 1000000; i++) {
        const std::string v = string_format(256, "%s+%u\n", "test test test", 12345);
        UTILITY_SUPPRESS_OPTIMIZATION_ON_VAR(v);
    }
}

TEST(ExternalFuncs, test_string_format_on_std_string_0)
{
    for (size_t i = 0; i < 1000000; i++) {
        const std::string v = string_format2(0, "%s+%u\n", "test test test", 12345);
        UTILITY_SUPPRESS_OPTIMIZATION_ON_VAR(v);
    }
}

TEST(ExternalFuncs, test_string_format_on_std_string_256)
{
    for (size_t i = 0; i < 1000000; i++) {
        const std::string v = string_format2(256, "%s+%u\n", "test test test", 12345);
        UTILITY_SUPPRESS_OPTIMIZATION_ON_VAR(v);
    }
}

TEST(ExternalFuncs, test_string_format_on_string_stream_on_variadic_tuple_0)
{
    for (size_t i = 0; i < 1000000; i++) {
        const std::string v = string_format3(0, "test test test", "+", 12345, "\n");
        UTILITY_SUPPRESS_OPTIMIZATION_ON_VAR(v);
    }
}

TEST(ExternalFuncs, test_string_format_on_string_stream_on_variadic_tuple_256)
{
    for (size_t i = 0; i < 1000000; i++) {
        const std::string v = string_format3(256, "test test test", "+", 12345, "\n");
        UTILITY_SUPPRESS_OPTIMIZATION_ON_VAR(v);
    }
}

TEST(ExternalFuncs, test_string_format_on_string_stream_inline_0)
{
    for (size_t i = 0; i < 1000000; i++) {
        std::ostringstream ss;
        ss << "test test test" << "+" << 12345 << "\n";
        const std::string v = ss.str();
        UTILITY_SUPPRESS_OPTIMIZATION_ON_VAR(v);
    }
}

TEST(ExternalFuncs, test_string_format_on_string_stream_inline_256)
{
    for (size_t i = 0; i < 1000000; i++) {
        std::ostringstream ss;
        ss.rdbuf()->str().reserve(256);
        ss << "test test test" << "+" << 12345 << "\n";
        const std::string v = ss.str();
        UTILITY_SUPPRESS_OPTIMIZATION_ON_VAR(v);
    }
}

TEST(ExternalFuncs, test_fmt_format_positional)
{
    for (size_t i = 0; i < 1000000; i++) {
        const std::string v = fmt::format("{0:s}+{1:d}\n", "test test test", 12345);
        UTILITY_SUPPRESS_OPTIMIZATION_ON_VAR(v);
    }
}

TEST(ExternalFuncs, test_fmt_format_named)
{
    for (size_t i = 0; i < 1000000; i++) {
        const std::string v = fmt::format("{first:s}+{second:d}\n", fmt::arg("first", "test test test"), fmt::arg("second", 12345));
        UTILITY_SUPPRESS_OPTIMIZATION_ON_VAR(v);
    }
}

The UTILITY_SUPPRESS_OPTIMIZATION_ON_VAR.

unsued.hpp:

#define UTILITY_SUPPRESS_OPTIMIZATION_ON_VAR(var)   ::utility::unused_param(&var)

namespace utility {

    extern const volatile void * volatile g_unused_param_storage_ptr;

    extern void
#ifdef __GNUC__
    __attribute__((optimize("O0")))
#endif
        unused_param(const volatile void * p);

}

unused.cpp:

namespace utility {

    const volatile void * volatile g_unused_param_storage_ptr = nullptr;

    void
#ifdef __GNUC__
    __attribute__((optimize("O0")))
#endif
        unused_param(const volatile void * p)
    {
        g_unused_param_storage_ptr = p;
    }

}

RESULTS:

[ RUN      ] ExternalFuncs.test_string_format_on_unique_ptr_0
[       OK ] ExternalFuncs.test_string_format_on_unique_ptr_0 (556 ms)
[ RUN      ] ExternalFuncs.test_string_format_on_unique_ptr_256
[       OK ] ExternalFuncs.test_string_format_on_unique_ptr_256 (331 ms)
[ RUN      ] ExternalFuncs.test_string_format_on_std_string_0
[       OK ] ExternalFuncs.test_string_format_on_std_string_0 (457 ms)
[ RUN      ] ExternalFuncs.test_string_format_on_std_string_256
[       OK ] ExternalFuncs.test_string_format_on_std_string_256 (279 ms)
[ RUN      ] ExternalFuncs.test_string_format_on_string_stream_on_variadic_tuple_0
[       OK ] ExternalFuncs.test_string_format_on_string_stream_on_variadic_tuple_0 (1214 ms)
[ RUN      ] ExternalFuncs.test_string_format_on_string_stream_on_variadic_tuple_256
[       OK ] ExternalFuncs.test_string_format_on_string_stream_on_variadic_tuple_256 (1325 ms)
[ RUN      ] ExternalFuncs.test_string_format_on_string_stream_inline_0
[       OK ] ExternalFuncs.test_string_format_on_string_stream_inline_0 (1208 ms)
[ RUN      ] ExternalFuncs.test_string_format_on_string_stream_inline_256
[       OK ] ExternalFuncs.test_string_format_on_string_stream_inline_256 (1302 ms)
[ RUN      ] ExternalFuncs.test_fmt_format_positional
[       OK ] ExternalFuncs.test_fmt_format_positional (288 ms)
[ RUN      ] ExternalFuncs.test_fmt_format_named
[       OK ] ExternalFuncs.test_fmt_format_named (392 ms)

As you can see implementation through the vsnprintf+std::string is equal to fmt::format, but faster than through the vsnprintf+std::unique_ptr, which is faster than through the std::ostringstream.

The tests compiled in Visual Studio 2015 Update 3 and run at Windows 7 x64 / Intel Core i7-4820K CPU @ 3.70GHz / 16GB.

2

All the answers so far here seems to have one or more of these problems: (1) it may not work on VC++ (2) it requires additional dependencies like boost or fmt (3) its too complicated custom implementation and probably not tested well.

Below code addresses all of above issues.

#include <string>
#include <cstdarg>
#include <memory>

std::string stringf(const char* format, ...)
{
    va_list args;
    va_start(args, format);
    #ifndef _MSC_VER
        
        //GCC generates warning for valid use of snprintf to get
        //size of result string. We suppress warning with below macro.
        #ifdef __GNUC__
        #pragma GCC diagnostic push
        #pragma GCC diagnostic ignored "-Wformat-nonliteral"
        #endif
        
        size_t size = std::snprintf(nullptr, 0, format, args) + 1; // Extra space for '\0'

        #ifdef __GNUC__
        # pragma GCC diagnostic pop
        #endif
        
        std::unique_ptr<char[]> buf(new char[ size ] ); 
        std::vsnprintf(buf.get(), size, format, args);
        return std::string(buf.get(), buf.get() + size - 1 ); // We don't want the '\0' inside
    #else
        int size = _vscprintf(format, args);
        std::string result(size, 0);
        vsnprintf_s((char*)result.data(), size + 1, _TRUNCATE, format, args);
        return result;
    #endif
    va_end(args);
}    

int main() {
    float f = 3.f;
    int i = 5;
    std::string s = "hello!";
    auto rs = stringf("i=%d, f=%f, s=%s", i, f, s.c_str());
    printf("%s", rs.c_str());
    return 0;
}

Notes:

  1. Separate VC++ code branch is necessary because VC++ has decided to deprecate snprintf which will generate compiler warnings for other highly voted answers above. As I always run in "warnings as errors" mode, its no go for me.
  2. The function accepts char * instead of std::string. This because most of the time this function would be called with literal string which is indeed char *, not std::string. In case you do have std::string as format parameter, then just call .c_str().
  3. Name of the function is stringf instead of things like string_format to keepup with printf, scanf etc.
  4. It doesn't address safety issue (i.e. bad parameters can potentially cause seg fault instead of exception). If you need this then you are better off with boost or fmt libraries. My preference here would be fmt because it is just one header and source file to drop in the project while having less weird formatting syntax than boost. However both are non-compatible with printf format strings so below is still useful in that case.
  5. The stringf code passes through GCC strict mode compilation. This requires extra #pragma macros to suppress false positives in GCC warnings.

Above code was tested on,

2
  • Superb lonely answer. Always view StackOverflow pages from the bottom up!
    – Dino Dini
    Feb 10, 2023 at 22:58
  • std::string result(size, 0); vsnprintf_s((char*)result.data(), size+1, _TRUNCATE, format, args); prevents an extra null character being added to the resulting string if _MSC_VER
    – Dino Dini
    Feb 11, 2023 at 15:02
2

(This runs fine on VC++ VS2019, VS2022)

C++17 solution (this will work for both std::string & for std::wstring):

It is not efficient to allocate a buffer, format into it & after copy it into the another string. It is possible to create std::string in the size of the formatted string & format directly into that string buffer:

#include <string>
#include <stdexcept>
#include <cwchar>
#include <cstdio>
#include <type_traits>

template<typename T, typename ... Args>
std::basic_string<T> string_format(T const* const format, Args ... args)
{
    int size_signed{ 0 };

    // 1) Determine size with error handling:    
    if constexpr (std::is_same_v<T, char>) { // C++17
        size_signed = std::snprintf(nullptr, 0, format, args ...);
    }
    else {
        size_signed = std::swprintf(nullptr, 0, format, args ...);
    }  
    if (size_signed <= 0) {
        throw std::runtime_error("error during formatting.");
    }
    const auto size = static_cast<size_t>(size_signed);

    // 2) Prepare formatted string:
    std::basic_string<T> formatted(size, T{});
    if constexpr (std::is_same_v<T, char>) { // C++17
        std::snprintf(formatted.data(), size + 1, format, args ...); // +1 for the '\0' (it will not be part of formatted).
    }
    else {
        std::swprintf(formatted.data(), size + 1, format, args ...); // +1 for the '\0' (it will not be part of formatted).
    }

    return formatted; // Named Return Value Optimization (NRVO), avoids an unnecessary copy. 
}

In addition: Often, the format parameter is a char[] / wchar_t[] & it is not efficient to create a std::string object. Pass char* or wchar_t* & if you already have a std::string object, you still can use it as your_string.c_str(). Example:

int main()
{
    int i{ 0 };

    // The format parameter is a char[] / wchar_t[]:

    const std::string title1 = string_format("story[%d].", ++i); // => "story[1]"

    const std::wstring title2 = string_format(L"story[%d].", ++i); // => L"story[2]"

    // If you already have a std::string object:

    const std::string format1{ "story[%d]." };
    const std::string title3 = string_format(format1.c_str(), ++i); // => "story[3]"

    const std::wstring format2{ L"story[%d]." };
    const std::wstring title4 = string_format(format2.c_str(), ++i); // => L"story[4]"  
}
2
  • why you write "T const* const format", no "const T* const format"? Sep 2, 2022 at 22:57
  • @Barracudach The rule: "const applies to the thing left of it. If there is nothing on the left then it applies to the thing right of it.".
    – Amit
    Sep 3, 2022 at 6:34
1

Poco Foundation library has a very convenient format function, which supports std::string in both the format string and the values:

1

You can format C++ output in cout using iomanip header file. Make sure that you include iomanip header file before you use any of the helper functions like setprecision, setfill etc.

Here is a code snippet I have used in the past to print the average waiting time in the vector, which I have "accumulated".

#include<iomanip>
#include<iostream>
#include<vector>
#include<numeric>

...

cout<< "Average waiting times for tasks is " << setprecision(4) << accumulate(all(waitingTimes), 0)/double(waitingTimes.size()) ;
cout << " and " << Q.size() << " tasks remaining" << endl;

Here is a brief description of how we can format C++ streams. http://www.cprogramming.com/tutorial/iomanip.html

1

There can be problems, if the buffer is not large enough to print the string. You must determine the length of the formatted string before printing a formatted message in there. I make own helper to this (tested on Windows and Linux GCC), and you can try use it.

String.cpp: http://pastebin.com/DnfvzyKP
String.h: http://pastebin.com/7U6iCUMa

String.cpp:

#include <cstdio>
#include <cstdarg>
#include <cstring>
#include <string>

using ::std::string;

#pragma warning(disable : 4996)

#ifndef va_copy
#ifdef _MSC_VER
#define va_copy(dst, src) dst=src
#elif !(__cplusplus >= 201103L || defined(__GXX_EXPERIMENTAL_CXX0X__))
#define va_copy(dst, src) memcpy((void*)dst, (void*)src, sizeof(*src))
#endif
#endif

///
/// \breif Format message
/// \param dst String to store formatted message
/// \param format Format of message
/// \param ap Variable argument list
///
void toString(string &dst, const char *format, va_list ap) throw() {
  int length;
  va_list apStrLen;
  va_copy(apStrLen, ap);
  length = vsnprintf(NULL, 0, format, apStrLen);
  va_end(apStrLen);
  if (length > 0) {
    dst.resize(length);
    vsnprintf((char *)dst.data(), dst.size() + 1, format, ap);
  } else {
    dst = "Format error! format: ";
    dst.append(format);
  }
}

///
/// \breif Format message
/// \param dst String to store formatted message
/// \param format Format of message
/// \param ... Variable argument list
///
void toString(string &dst, const char *format, ...) throw() {
  va_list ap;
  va_start(ap, format);
  toString(dst, format, ap);
  va_end(ap);
}

///
/// \breif Format message
/// \param format Format of message
/// \param ... Variable argument list
///
string toString(const char *format, ...) throw() {
  string dst;
  va_list ap;
  va_start(ap, format);
  toString(dst, format, ap);
  va_end(ap);
  return dst;
}

///
/// \breif Format message
/// \param format Format of message
/// \param ap Variable argument list
///
string toString(const char *format, va_list ap) throw() {
  string dst;
  toString(dst, format, ap);
  return dst;
}


int main() {
  int a = 32;
  const char * str = "This works!";

  string test(toString("\nSome testing: a = %d, %s\n", a, str));
  printf(test.c_str());

  a = 0x7fffffff;
  test = toString("\nMore testing: a = %d, %s\n", a, "This works too..");
  printf(test.c_str());

  a = 0x80000000;
  toString(test, "\nMore testing: a = %d, %s\n", a, "This way is cheaper");
  printf(test.c_str());

  return 0;
}

String.h:

#pragma once
#include <cstdarg>
#include <string>

using ::std::string;

///
/// \breif Format message
/// \param dst String to store formatted message
/// \param format Format of message
/// \param ap Variable argument list
///
void toString(string &dst, const char *format, va_list ap) throw();
///
/// \breif Format message
/// \param dst String to store formatted message
/// \param format Format of message
/// \param ... Variable argument list
///
void toString(string &dst, const char *format, ...) throw();
///
/// \breif Format message
/// \param format Format of message
/// \param ... Variable argument list
///
string toString(const char *format, ...) throw();

///
/// \breif Format message
/// \param format Format of message
/// \param ap Variable argument list
///
string toString(const char *format, va_list ap) throw();
2
  • With regards to the line vsnprintf((char *)dst.data(), dst.size() + 1, format, ap); -- Is it safe to assume the string's buffer has room for a terminating null character? Are there implementations that do not allocate size+1 characters. Would it be safer to do dst.resize(length+1); vsnprintf((char *)dst.data(), dst.size(), format, ap); dst.resize(length); Dec 21, 2016 at 19:21
  • Apparently the answer to my previous comment is: No it is NOT safe to assume there is a null character. Specifically with regards to the C++98 spec: "Accessing the value at data()+size() produces undefined behavior: There are no guarantees that a null character terminates the character sequence pointed by the value returned by this function. See string::c_str for a function that provides such guarantee. A program shall not alter any of the characters in this sequence." However, the C++11 spec indicates that data and c_str are synonyms. Dec 21, 2016 at 19:35
1

this can be tried out. simple. really does not use nuances of the string class though.

#include <stdarg.h>
#include <stdio.h>
#include <stdlib.h>
#include <assert.h>

#include <string>
#include <exception>
using namespace std;

//---------------------------------------------------------------------

class StringFormatter
{
public:
    static string format(const char *format, ...);
};

string StringFormatter::format(const char *format, ...)
{
    va_list  argptr;

    va_start(argptr, format);

        char   *ptr;
        size_t  size;
        FILE   *fp_mem = open_memstream(&ptr, &size);
        assert(fp_mem);

        vfprintf (fp_mem, format, argptr);
        fclose (fp_mem);

    va_end(argptr);

    string ret = ptr;
    free(ptr);

    return ret;
}

//---------------------------------------------------------------------

int main(void)
{
    string temp = StringFormatter::format("my age is %d", 100);
    printf("%s\n", temp.c_str());

    return 0;
}

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