Is there a C++ Standard Template Library class that provides efficient string concatenation functionality, similar to C#'s StringBuilder or Java's StringBuffer?
11 Answers
The C++ way would be to use std::stringstream or just plain string concatenations. C++ strings are mutable so the performance considerations of concatenation are less of a concern.
with regards to formatting, you can do all the same formatting on a stream, but in a different way, similar to cout
. or you can use a strongly typed functor which encapsulates this and provides a String.Format like interface e.g. boost::format
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98C++ strings are mutable: exactly. The entire reason
StringBuilder
exists is to cover the inefficiency of Java's immutable basic String type. In other wordsStringBuilder
is patchwork, so we should be glad we don't need such a class in C++.– boboboboApr 16, 2013 at 19:27 -
71@bobobobo immutable strings have other benefits though, its horses for courses– jk.Apr 16, 2013 at 19:29
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11Don't plain string concatenations create a new object, so the same problem as with immutability in Java? Consider all variables are strings in the following example: a = b + c + d + e + f; Isn't it going to call operator+ on b and c, then operator+ on the result and d, etc.? Jun 24, 2015 at 16:43
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17Hold on a minute people, the standard string class knows how to mutate itself but that does not mean the inefficiency is not there. As far as I know std::string cannot simply extend the size of its internal char*. That means mutating it in a way which requires more characters requires a reallocation and copying. It's no different than a vector of chars and it is certainly better to reserve the space you need in that case. Jul 31, 2016 at 0:36
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11@TrygveSkogsholm - it is no different than a vector of chars, but of course the "capacity" of the string can be larger than its size, so not all appends need a reallocation. In general strings will use an exponential growth strategy so appending still amortizes to a linear cost operation. That's different than Java's immutable Strings in which every append operation needs to copy all characters in both Strings to a new one, so a series of appends ends up as
O(n)
in general. Nov 18, 2017 at 19:33
The std::string.append
function isn't a good option because it doesn't accept many forms of data. A more useful alternative is to use std::stringstream
; like so:
#include <sstream>
// ...
std::stringstream ss;
//put arbitrary formatted data into the stream
ss << 4.5 << ", " << 4 << " whatever";
//convert the stream buffer into a string
std::string str = ss.str();
NOTE this answer has received some attention recently. I am not advocating this as a solution (it is a solution I have seen in the past, before the STL). It is an interesting approach and should only be applied over std::string
or std::stringstream
if after profiling your code you discover this makes an improvement.
I normally use either std::string
or std::stringstream
. I have never had any problems with these. I would normally reserve some room first if I know the rough size of the string in advance.
I have seen other people make their own optimized string builder in the distant past.
class StringBuilder {
private:
std::string main;
std::string scratch;
const std::string::size_type ScratchSize = 1024; // or some other arbitrary number
public:
StringBuilder & append(const std::string & str) {
scratch.append(str);
if (scratch.size() > ScratchSize) {
main.append(scratch);
scratch.resize(0);
}
return *this;
}
const std::string & str() {
if (scratch.size() > 0) {
main.append(scratch);
scratch.resize(0);
}
return main;
}
};
It uses two strings one for the majority of the string and the other as a scratch area for concatenating short strings. It optimise's appends by batching the short append operations in one small string then appending this to the main string, thus reducing the number of reallocations required on the main string as it gets larger.
I have not required this trick with std::string
or std::stringstream
. I think it was used with a third party string library before std::string, it was that long ago. If you adopt a strategy like this profile your application first.
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14Reinventing the wheel. std::stringstream is the proper answer. See good answers below.– Kobor42Apr 16, 2013 at 7:31
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13@Kobor42 I agree with you as I point out on the first and last line of my answer.– iainApr 16, 2013 at 12:37
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1I don't think the
scratch
string really accomplishes anything here. The number of reallocations of the main string is largely going to be a function of it's final size, not the number of append operations, unless thestring
implementation is really poor (i.e., doesn't use exponential growth). So "batching" up theappend
doesn't help because once the underlyingstring
is large it will only grow occasionally either way. On top of that it adds a bunch of redundant copy operations, and may more reallocations (hence calls tonew
/delete
) since you are appending to a short string. Nov 18, 2017 at 19:30 -
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i'm pretty sure
str.reserve(1024);
would be faster than this thing Apr 25, 2019 at 18:14
You can use .append() for simply concatenating strings.
std::string s = "string1";
s.append("string2");
I think you might even be able to do:
std::string s = "string1";
s += "string2";
As for the formatting operations of C#'s StringBuilder
, I believe snprintf
(or sprintf
if you want to risk writing buggy code ;-) ) into a character array and convert back to a string is about the only option.
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Not in the same way as printf or .NET's String.Format though, are they? Mar 17, 2010 at 15:25
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1
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2@jk - they're the only way when comparing the formatting ability of .NET's StringBuilder, which is what the original question specifically asked. I did say "I believe" so I could be wrong, but can you show me a way to get StringBuilder's functionality in C++ without using printf? Mar 17, 2010 at 16:41
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Since std::string
in C++ is mutable you can use that. It has a += operator
and an append
function.
If you need to append numerical data use the std::to_string
functions.
If you want even more flexibility in the form of being able to serialise any object to a string then use the std::stringstream
class. But you'll need to implement your own streaming operator functions for it to work with your own custom classes.
A convenient string builder for c++
Like many people answered before, std::stringstream is the method of choice. It works good and has a lot of conversion and formatting options. IMO it has one pretty inconvenient flaw though: You can not use it as a one liner or as an expression. You always have to write:
std::stringstream ss;
ss << "my data " << 42;
std::string myString( ss.str() );
which is pretty annoying, especially when you want to initialize strings in the constructor.
The reason is, that a) std::stringstream has no conversion operator to std::string and b) the operator << ()'s of the stringstream don't return a stringstream reference, but a std::ostream reference instead - which can not be further computed as a string stream.
The solution is to override std::stringstream and to give it better matching operators:
namespace NsStringBuilder {
template<typename T> class basic_stringstream : public std::basic_stringstream<T>
{
public:
basic_stringstream() {}
operator const std::basic_string<T> () const { return std::basic_stringstream<T>::str(); }
basic_stringstream<T>& operator<< (bool _val) { std::basic_stringstream<T>::operator << (_val); return *this; }
basic_stringstream<T>& operator<< (char _val) { std::basic_stringstream<T>::operator << (_val); return *this; }
basic_stringstream<T>& operator<< (signed char _val) { std::basic_stringstream<T>::operator << (_val); return *this; }
basic_stringstream<T>& operator<< (unsigned char _val) { std::basic_stringstream<T>::operator << (_val); return *this; }
basic_stringstream<T>& operator<< (short _val) { std::basic_stringstream<T>::operator << (_val); return *this; }
basic_stringstream<T>& operator<< (unsigned short _val) { std::basic_stringstream<T>::operator << (_val); return *this; }
basic_stringstream<T>& operator<< (int _val) { std::basic_stringstream<T>::operator << (_val); return *this; }
basic_stringstream<T>& operator<< (unsigned int _val) { std::basic_stringstream<T>::operator << (_val); return *this; }
basic_stringstream<T>& operator<< (long _val) { std::basic_stringstream<T>::operator << (_val); return *this; }
basic_stringstream<T>& operator<< (unsigned long _val) { std::basic_stringstream<T>::operator << (_val); return *this; }
basic_stringstream<T>& operator<< (long long _val) { std::basic_stringstream<T>::operator << (_val); return *this; }
basic_stringstream<T>& operator<< (unsigned long long _val) { std::basic_stringstream<T>::operator << (_val); return *this; }
basic_stringstream<T>& operator<< (float _val) { std::basic_stringstream<T>::operator << (_val); return *this; }
basic_stringstream<T>& operator<< (double _val) { std::basic_stringstream<T>::operator << (_val); return *this; }
basic_stringstream<T>& operator<< (long double _val) { std::basic_stringstream<T>::operator << (_val); return *this; }
basic_stringstream<T>& operator<< (void* _val) { std::basic_stringstream<T>::operator << (_val); return *this; }
basic_stringstream<T>& operator<< (std::streambuf* _val) { std::basic_stringstream<T>::operator << (_val); return *this; }
basic_stringstream<T>& operator<< (std::ostream& (*_val)(std::ostream&)) { std::basic_stringstream<T>::operator << (_val); return *this; }
basic_stringstream<T>& operator<< (std::ios& (*_val)(std::ios&)) { std::basic_stringstream<T>::operator << (_val); return *this; }
basic_stringstream<T>& operator<< (std::ios_base& (*_val)(std::ios_base&)){ std::basic_stringstream<T>::operator << (_val); return *this; }
basic_stringstream<T>& operator<< (const T* _val) { return static_cast<basic_stringstream<T>&>(std::operator << (*this,_val)); }
basic_stringstream<T>& operator<< (const std::basic_string<T>& _val) { return static_cast<basic_stringstream<T>&>(std::operator << (*this,_val.c_str())); }
};
typedef basic_stringstream<char> stringstream;
typedef basic_stringstream<wchar_t> wstringstream;
}
With this, you can write things like
std::string myString( NsStringBuilder::stringstream() << "my data " << 42 )
even in the constructor.
I have to confess I didn't measure the performance, since I have not used it in an environment which makes heavy use of string building yet, but I assume it won't be much worse than std::stringstream, since everything is done via references (except the conversion to string, but thats a copy operation in std::stringstream as well)
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This is neat. I don't see why
std::stringstream
doesn't behave this way. Jun 7, 2020 at 19:57
std::string's += doesn't work with const char* (what stuff like "string to add" appear to be), so definitely using stringstream is the closest to what is required - you just use << instead of +
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"std::string's += doesn't work with const char*" Yes, it does, and it has since at least C++98... m.cplusplus.com/reference/string/string/operator+= May 26, 2022 at 20:22
The Rope container may be worth if have to insert/delete string into the random place of destination string or for a long char sequences. Here is an example from SGI's implementation:
crope r(1000000, 'x'); // crope is rope<char>. wrope is rope<wchar_t>
// Builds a rope containing a million 'x's.
// Takes much less than a MB, since the
// different pieces are shared.
crope r2 = r + "abc" + r; // concatenation; takes on the order of 100s
// of machine instructions; fast
crope r3 = r2.substr(1000000, 3); // yields "abc"; fast.
crope r4 = r2.substr(1000000, 1000000); // also fast.
reverse(r2.mutable_begin(), r2.mutable_end());
// correct, but slow; may take a
// minute or more.
I wanted to add something new because of the following:
At a first attemp I failed to beat
std::ostringstream
's operator<<
efficiency, but with more attemps I was able to make a StringBuilder that is faster in some cases.
Everytime I append a string I just store a reference to it somewhere and increase the counter of the total size.
The real way I finally implemented it (Horror!) is to use a opaque buffer(std::vector < char > ):
- 1 byte header (2 bits to tell if following data is :moved string, string or byte[])
- 6 bits to tell lenght of byte[]
for byte [ ]
- I store directly bytes of short strings (for sequential memory access)
for moved strings (strings appended with std::move
)
- The pointer to a
std::string
object (we have ownership) - set a flag in the class if there are unused reserved bytes there
for strings
- The pointer to a
std::string
object (no ownership)
There's also one small optimization, if last inserted string was mov'd in, it checks for free reserved but unused bytes and store further bytes in there instead of using the opaque buffer (this is to save some memory, it actually make it slightly slower, maybe depend also on the CPU, and it is rare to see strings with extra reserved space anyway)
This was finally slightly faster than std::ostringstream
but it has few downsides:
- I assumed fixed lenght char types (so 1,2 or 4 bytes, not good for UTF8), I'm not saying it will not work for UTF8, Just I don't checked it for laziness.
- I used bad coding practise (opaque buffer, easy to make it not portable, I believe mine is portable by the way)
- Lacks all features of
ostringstream
- If some referenced string is deleted before mergin all the strings: undefined behaviour.
conclusion? use
std::ostringstream
It already fix the biggest bottleneck while ganing few % points in speed with mine implementation is not worth the downsides.
Regular std::string is the equivalent to StringBuffer in Java as it is mutable. If I simplify a lot, Java strings are something like immutable global constants which causes creating new objects everytime they have to change. In contrast StringBuffer (and std::string) is the equivalent of a dynamic array of chars. Appending to it is O*(1). Worst case of append is O(n) but k consecutive calls to append lead to k.O(1) operations => O*(1).
Read more about amortized complexity analysisof insertion into dynamic array.
std::ostringstream
.