There are several posts on the internet that suggest that you should use
std::vector<unsigned char> or something similar for binary data.
But I'd much rather prefer a
std::basic_string variant for that, since it provides many convenient string manipulation functions. And AFAIK, since C++11, the standard guarantees what every known C++03 implementation already did: that
std::basic_string stores its contents contiguously in memory.
At first glance then,
std::basic_string<unsigned char> might be a good choice.
I don't want to use
std::basic_string<unsigned char>, however, because almost all operating system functions only accept
char*, making an explicit cast necessary. Also, string literals are
const char*, so I would need an explicit cast to
const unsigned char* every time I assigned a string literal to my binary string, which I would also like to avoid. Also, functions for reading from and writing to files or networking buffers similarly accept
const char* pointers.
std::string, which is basically a typedef for
The only potential remaining issue (that I can see) with using
std::string for binary data is that
char (which can be signed).
signed char, and
unsigned char are three different types and
char can be either unsigned or signed.
So, when an actual byte value of
11111111b is returned from
std::string:operator as char, and you want to check its value, its value can be either
char is unsigned) or it might be "something negative" (if
char is signed, depending on your number representation).
Similarly, if you want to explicitly append the actual byte value
11111111b to a
std::string, simply appending
(char) (255) might be implementation-defined (and even raise a signal) if
char is signed and the
char conversation results in an overflow.
So, is there a safe way around this, that makes
std::string binary-safe again?
If a program attempts to access the stored value of an object through a glvalue of other than one of the following types the behavior is undefined:
- a type that is the signed or unsigned type corresponding to the dynamic type of the object,
- a char or unsigned char type.
Which, if I understand it correctly, seems to allow using an
unsigned char* pointer to access and manipulate the contents of a
std::string and makes this also well-defined. It just reinterprets the bit pattern as an
unsigned char, without any change or information loss, the latter namely because all bits in a
signed char, and
unsigned char must be used for the value representation.
I could then use this
unsigned char* interpretation of the contents of
std::string as a means to access and change the byte values in the
[0, 255] range, in a well-defined and portable manner, regardless of the signedness of
This should solve any problems arising from a potentially signed
Are my assumptions and conclusions correct?
Also, is the
unsigned char* interpretation of the same bit pattern (i.e.
10101010b) guaranteed to be the same on all implementations? Put differently, does the standard guarantee that "looking through the eyes of an
unsigned char", the same bit pattern always leads to the same numerical value (assuming the number of bits in a byte is the same)?
Can I thus safely (that is, without any undefined or implementation-defined behavior) use
std::string for storing and manipulating binary data in C++11?