A C++ cross-platform single-header library implementation for universally unique identifiers, simply know as either UUID or GUID (mostly on Windows). A UUID is a 128-bit number used to uniquely identify information in computer systems, such as database table keys, COM interfaces, classes and type libraries, and many others.
For information about UUID/GUIDs see:
Although the specification puts the uuid library in the std namespace, this implementation uses the namespace uuids for this purpose, in order to make the library usable without violating the restrictions imposed on the std namespace. The following types and utilities are available:
Basic types:
| Name | Description |
|---|---|
uuid |
a class representing a UUID; this can be default constructed (a nil UUID), constructed from a range (defined by a pair of iterators), or from a string. |
uuid_variant |
a strongly type enum representing the type of a UUID |
uuid_version |
a strongly type enum representing the version of a UUID |
Generators:
| Name | Description |
|---|---|
uuid_system_generator |
a function object that generates new UUIDs using operating system resources (CoCreateGuid on Windows, uuid_generate on Linux, CFUUIDCreate on Mac) |
basic_uuid_random_generator |
a function object that generates version 4 UUIDs using a pseudo-random number generator engine. |
uuid_random_generator |
a basic_uuid_random_generator using the Marsenne Twister engine, i.e. basic_uuid_random_generator<std::mt19937> |
uuid_name_generator |
a function object that generates version 5, name-based UUIDs using SHA1 hashing. |
Utilities:
| Name | Description |
|---|---|
std::swap<> |
specialization of swap for uuid |
std::hash<> |
specialization of hash for uuid (necessary for storing UUIDs in unordered associative containers, such as std::unordered_set) |
Other:
| Name | Description |
|---|---|
operator== and operator!= |
for UUIDs comparison for equality/inequality |
operator< |
for comparing whether one UUIDs is less than another. Although this operation does not make much logical sense, it is necessary in order to store UUIDs in a std::set. |
operator<< |
to write a UUID to an output stream using the canonical textual representation. |
to_string() |
creates a std::string with the canonical textual representation of a UUID. |
to_wstring() |
creates a std::wstring with the canonical textual representation of a UUID. |
This project is currently under development and should be ignored until further notice.
The following is a list of examples for using the library:
- Creating a nil UUID
uuid empty;
assert(empty.nil());
assert(empty.size() == 16);
- Creating a new UUID
uuid const guid = uuids::uuid_system_generator{}();
assert(!guid.nil());
assert(guid.size() == 16);
assert(guid.version() == uuids::uuid_version::random_number_based);
assert(guid.variant() == uuids::uuid_variant::rfc);
- Creating a new UUID with a default random generator
uuids::uuid_random_generator gen;
uuid const guid = gen();
assert(!guid.nil());
assert(guid.size() == 16);
assert(guid.version() == uuids::uuid_version::random_number_based);
assert(guid.variant() == uuids::uuid_variant::rfc);
- Creating a new UUID with a particular random generator
std::random_device rd;
std::ranlux48_base generator(rd());
uuids::basic_uuid_random_generator<std::ranlux48_base> gen(&generator);
uuid const guid = gen();
assert(!guid.nil());
assert(guid.size() == 16);
assert(guid.version() == uuids::uuid_version::random_number_based);
assert(guid.variant() == uuids::uuid_variant::rfc);
- Creating a new UUID with the name generator
uuids::uuid_name_generator gen;
uuid const guid = gen();
assert(!guid.nil());
assert(guid.size() == 16);
assert(guid.version() == uuids::uuid_version::name_based_sha1);
assert(guid.variant() == uuids::uuid_variant::rfc);
- Create a UUID from a string
using namespace std::string_literals;
auto str = "47183823-2574-4bfd-b411-99ed177d3e43"s;
uuid guid(str);
assert(guid.string() == str);
or
auto str = L"47183823-2574-4bfd-b411-99ed177d3e43"s;
uuid guid(str);
assert(guid.wstring() == str);
- Creating a UUID from an array
std::array<uuids::uuid::value_type, 16> arr{{
0x47, 0x18, 0x38, 0x23,
0x25, 0x74,
0x4b, 0xfd,
0xb4, 0x11,
0x99, 0xed, 0x17, 0x7d, 0x3e, 0x43}};
uuid guid(std::begin(arr), std::end(arr));
assert(id.string() == "47183823-2574-4bfd-b411-99ed177d3e43");
or
uuids::uuid::value_type arr[16] = {
0x47, 0x18, 0x38, 0x23,
0x25, 0x74,
0x4b, 0xfd,
0xb4, 0x11,
0x99, 0xed, 0x17, 0x7d, 0x3e, 0x43 };
uuid guid(std::begin(arr), std::end(arr));
assert(guid.string() == "47183823-2574-4bfd-b411-99ed177d3e43");
- Comparing UUIDS
uuid empty;
uuid guid = uuids::uuid_system_generator{}();
assert(empty == empty);
assert(guid == guid);
assert(empty != guid);
- Swapping UUIDS
uuid empty;
uuid guid = uuids::uuid_system_generator{}();
assert(empty.nil());
assert(!guid.nil());
std::swap(empty, guid);
assert(!empty.nil());
assert(guid.nil());
empty.swap(guid);
assert(empty.nil());
assert(!guid.nil());
- Converting to string
uuid empty;
assert(uuids::to_string(empty) == "00000000-0000-0000-0000-000000000000");
assert(uuids::to_wstring(empty) == L"00000000-0000-0000-0000-000000000000");
- Iterating through the UUID data
std::array<uuids::uuid::value_type, 16> arr{{
0x47, 0x18, 0x38, 0x23,
0x25, 0x74,
0x4b, 0xfd,
0xb4, 0x11,
0x99, 0xed, 0x17, 0x7d, 0x3e, 0x43}};
uuid guid;
assert(guid.nil());
std::copy(std::cbegin(arr), std::cend(arr), std::begin(guid));
assert(!guid.nil());
assert(guid.string() == "47183823-2574-4bfd-b411-99ed177d3e43");
size_t i = 0;
for (auto const & b : guid)
assert(arr[i++] == b);
- Using with an orderered associative container
uuids::uuid_random_generator gen;
std::set<uuids::uuid> ids{uuid{}, gen(), gen(), gen(), gen()};
assert(ids.size() == 5);
assert(ids.find(uuid{}) != ids.end());
- Using in an unordered associative container
uuids::uuid_random_generator gen;
std::unordered_set<uuids::uuid> ids{uuid{}, gen(), gen(), gen(), gen()};
assert(ids.size() == 5);
assert(ids.find(uuid{}) != ids.end());
- Hashing UUIDs
auto h1 = std::hash<std::string>{};
auto h2 = std::hash<uuid>{};
assert(h1(str) == h2(guid));
The library is supported on all major operating systems: Windows, Linux and Mac OS.
A testing project is available in the sources. To build and execute the tests do the following:
- Clone or download this repository
- Create a
builddirectory in the root directory of the sources - Run the command
cmake ..from thebuilddirectory; if you do not have CMake you must install it first. - Build the project created in the previous step
- Run the executable.
The SHA1 implementation is based on the TinySHA1 library.