I was using a map with a std::string key and while everything was working fine I wasn't getting the performance I expected. I searched for places to optimize and improved things only a little and that's when a colleague said, "that string key is going to be slow."

I read dozens of questions and they consistently say:

"don't use a char * as a key"
"std::string keys are never your bottleneck"
"the performance difference between a char * and a std::string is a myth."

I reluctantly tried a char * key and there was a difference, a big difference.

I boiled the problem down to a simple example:

#include <stdio.h>
#include <stdlib.h>
#include <map>


#include <string>
typedef std::map<std::string, int> Map;


#include <string.h>
struct char_cmp { 
    bool operator () (const char *a,const char *b) const 
        return strcmp(a,b)<0;
typedef std::map<const char *, int, char_cmp> Map;


Map m;

bool test(const char *s)
    Map::iterator it = m.find(s);
    return it != m.end();

int main(int argc, char *argv[])
    m.insert( Map::value_type("hello", 42) );

    const int lcount = atoi(argv[1]);
    for (int i=0 ; i<lcount ; i++) test("hello");

First the std::string version:

$ g++ -O3 -o test test.cpp -DUSE_STRING
$ time ./test 20000000
real    0m1.893s

Next the 'char *' version:

g++ -O3 -o test test.cpp             
$ time ./test 20000000
real    0m0.465s

That's a pretty big performance difference and about the same difference I see in my larger program.

Using a char * key is a pain to handle freeing the key and just doesn't feel right. C++ experts what am I missing? Any thoughts or suggestions?

  • 10
    As you have just shown, always take all blanket statements with a grain of salt. – Mysticial Aug 27 '12 at 4:04
  • 5
    Your test may not be a fair comparison between std::string and char*. In your "char *" version of Map, you are not allocating the memory to your key, while your "std::string" version of the Map, a new string for the key is allocated every time. – LMC Aug 27 '12 at 4:07
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    I just realized that my first comment was a blanket statement. – Mysticial Aug 27 '12 at 4:08
  • 1
    @Mysticial is +1 a lol – Adrian Cornish Aug 27 '12 at 4:09
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    @LokiAstari: Not always, no. For some very specifically constrained situations you do have to get closer to the metal. – Matthieu M. Aug 27 '12 at 9:42

You are using a const char * as a lookup key for find(). For the map containing const char* this is the correct type that find expects and the lookup can be done directly.

The map containing std::string expects the parameter of find() to be a std::string, so in this case the const char* first has to be converted to a std::string. This is probably the difference you are seeing.

  • Right, I think that's exactly where the performance difference lies. I'm a bit shocked that there's that big of a penalty. – uroc Aug 27 '12 at 4:21
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    @uroc: The code does 20000000 string copies (one in every iteration), that will take some time. Especially compared to a lookup in a map with only a single element, which should be rather fast. – sth Aug 27 '12 at 4:26
  • The map in my actual program is much bigger, but it wasn't relevant to the problem so I neglected to add that to the sample code. The only way I see to improve this is to switch to char pointers. – uroc Aug 27 '12 at 4:28
  • @uroc: So your real lookup keys are char* already? Because if they are std:string they don't need to be converted on lookup and the performance penalty seen in the sample program shouldn't apply. – sth Aug 27 '12 at 4:32
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    @sth: it's an issue with associative containers in general. There is an operator< that compares a std::string and a char const* without allocating a string, but the associative containers force the conversion. It's a pain... – Matthieu M. Aug 27 '12 at 9:43

As sth noted, the issue is one of specifications of the associative containers (sets and maps), in that their member search methods always force a conversion to the key_type, even if an operator< exists that would accept to compare your key against the keys in the map despite their different types.

On the other hand, the functions in <algorithm> do not suffer from this, for example lower_bound is defined as:

template< class ForwardIt, class T >
ForwardIt lower_bound( ForwardIt first, ForwardIt last, const T& value );

template< class ForwardIt, class T, class Compare >
ForwardIt lower_bound( ForwardIt first, ForwardIt last, const T& value, Compare comp );

So, an alternative could be:

std::vector< std::pair< std::string, int > >

And then you could do:

std::lower_bound(vec.begin(), vec.end(), std::make_pair("hello", 0), CompareFirst{})

Where CompareFirst is defined as:

struct CompareFirst {
     template <typename T, typename U>
     bool operator()(T const& t, U const& u) const { return t.first < u.first; }

Or even build a completely custom comparator (but it's a bit harder).

A vector of pair is generally more efficient in read-heavy loads, so it's really to store a configuration for example.

I do advise to provide methods to wrap the accesses. lower_bound is pretty low-level.


If your in C++ 11, the copy constructor is not called unless the string is changed. Because std::string is a C++ construct, at least 1 dereference is needed to get at the string data.

My guess would be the time is taken up in an extra dereference (which if done 10000 times is costly), and std::string is likely doing appropriate null pointer checks, which again eats up cycles.


Store the std::string as a pointer and then you lose the copy constructor overhead.

But after you have to remember to handle the deletes.

The reason std::string is slow is that is constructs itself. Calls the copy constructor, and then at the end calls delete. If you create the string on the heap you lose the copy construction.

  • I think the speed difference is the creation of the temporary std::string when find is called as @sth pointed out. I see no way to optimize that away. My next problem is how to properly handle the deletes. In my destructor I was just running over all pairs and freeing the 'char *' pointers and then calling clear on the map. – uroc Aug 27 '12 at 4:25
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    Do not guess - profile the code - I am a 100% right in guessing that you are 100% wrong where you think the bottle neck is ;-) - programmers are terrible at guessing where this is - after 22 years I always am surprised. – Adrian Cornish Aug 27 '12 at 4:29
  • Can the peeps that gave me the -1's add why you think so? – Adrian Cornish Aug 27 '12 at 4:45
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    storing std::string as pointer or not in map is doubtless not the problem. Come on, he is only having 1 string instance in the map, while he is doing million times of search. Please don't guess, prove that's the problem instead. More important, having std::map<std::string*, int> is so ugly and should be avoided unless you know you need to do so. – Adrian Shum Aug 27 '12 at 4:45
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    The extra copy could be avoided with std::move nowadays. – Niclas Larsson Apr 12 '16 at 8:38

After compilation the 2 "Hello" string literals will have the same memory address. On the char * case you use this memory addresses as keys.

In the string case every "Hello"s will be converted to a different object. This is a small part (really really small) of your performance difference.

A bigger part can be that as all the "Hello"s you are using has the same memory address strcmp will always get 2 equivalent char pointers and I'm quite sure that it early checks for this case :) So it will never really iterate on the all characters but the std::string comparison will.

  • This is indeed a large and easily overlooked problem with a std::string key: the operator< is not constant time. If you have long keys with common prefixes (not unlikely in some applications), it can lead to horrible performance. – Olivier Nov 8 '17 at 15:00

One solution to this is use a custom key class that acts as a cross between a const char * and a std::string, but has a boolean to tell at run time if it is "owning" or "non-owning". That way you can insert a key into the map which owns it's data (and will free it on destruction), and then compare with a key that does not own it's data. (This is a similar concept to the rust Cow<'a, str> type).

The below example also inherits from boost's string_ref to avoid having to re-implement hash functions etc.

NOTE this has the dangerous effect that if you accidentally insert into the map with the non-owning version, and the string you are pointing at goes out of scope, the key will point at already freed memory. The non-owning version can only be used for lookups.

#include <iostream>
#include <map>
#include <cstring>

#include <boost/utility/string_ref.hpp>

class MaybeOwned: public boost::string_ref {
  // owning constructor, takes a std::string and copies the data
  // deletes it's copy on destruction
  MaybeOwned(const std::string& string):
      (char *)malloc(string.size() * sizeof(char)),
    memcpy((void *)data(), (void *)string.data(), string.size());

  // non-owning constructor, takes a string ref and points to the same data
  // does not delete it's data on destruction
  MaybeOwned(boost::string_ref string):

  // non-owning constructor, takes a c string and points to the same data
  // does not delete it's data on destruction
  MaybeOwned(const char * string):

  // move constructor, tells source that it no longer owns the data if it did
  // to avoid double free
  MaybeOwned(MaybeOwned&& other):
    other.owned = false;

  // I was to lazy to write a proper copy constructor
  // (it would need to malloc and memcpy again if it owned the data)
  MaybeOwned(const MaybeOwned& other) = delete;

  // free owned data if it has any
  ~MaybeOwned() {
    if (owned) {
      free((void *)data());

  bool owned;

int main()
  std::map<MaybeOwned, std::string> map;
  map.emplace(std::string("key"), "value");
  map["key"] += " here";
  std::cout << map["key"] << "\n";

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