Hash an arbitrary precision value (boost::multiprecision::cpp_int)
You can (ab)use the serialization support:
Support for serialization comes in two forms: Classes
number,debug_adaptor,logged_adaptorandrational_adaptorhave "pass through" serialization support which requires the underlying backend to be serializable.Backends
cpp_int,cpp_bin_float,cpp_dec_floatandfloat128have full support for Boost.Serialization.
So, let me cobble something together that works with boost and std unordered containers:
template <typename Map>
void test(Map const& map) {
std::cout << "\n" << __PRETTY_FUNCTION__ << "\n";
for(auto& p : map)
std::cout << p.second << "\t" << p.first << "\n";
}
int main() {
using boost::multiprecision::cpp_int;
test(std::unordered_map<cpp_int, std::string> {
{ cpp_int(1) << 111, "one" },
{ cpp_int(2) << 222, "two" },
{ cpp_int(3) << 333, "three" },
});
test(boost::unordered_map<cpp_int, std::string> {
{ cpp_int(1) << 111, "one" },
{ cpp_int(2) << 222, "two" },
{ cpp_int(3) << 333, "three" },
});
}
Let's forward the relevant hash<> implementations to our own hash_impl specialization that uses Multiprecision and Serialization:
namespace std {
template <typename backend>
struct hash<boost::multiprecision::number<backend> >
: mp_hashing::hash_impl<boost::multiprecision::number<backend> >
{};
}
namespace boost {
template <typename backend>
struct hash<multiprecision::number<backend> >
: mp_hashing::hash_impl<multiprecision::number<backend> >
{};
}
Now, of course, this begs the question, how is hash_impl implemented?
template <typename T> struct hash_impl {
size_t operator()(T const& v) const {
using namespace boost;
size_t seed = 0;
{
iostreams::stream<hash_sink> os(seed);
archive::binary_oarchive oa(os, archive::no_header | archive::no_codecvt);
oa << v;
}
return seed;
}
};
This looks pretty simple. That's because Boost is awesome, and writing a hash_sink device for use with Boost Iostreams is just the following straightforward exercise:
namespace io = boost::iostreams;
struct hash_sink {
hash_sink(size_t& seed_ref) : _ptr(&seed_ref) {}
typedef char char_type;
typedef io::sink_tag category;
std::streamsize write(const char* s, std::streamsize n) {
boost::hash_combine(*_ptr, boost::hash_range(s, s+n));
return n;
}
private:
size_t* _ptr;
};
Full Demo:
Live On Coliru
#include <iostream>
#include <iomanip>
#include <boost/archive/binary_oarchive.hpp>
#include <boost/multiprecision/cpp_int.hpp>
#include <boost/multiprecision/cpp_int/serialize.hpp>
#include <boost/iostreams/device/back_inserter.hpp>
#include <boost/iostreams/stream_buffer.hpp>
#include <boost/iostreams/stream.hpp>
#include <boost/functional/hash.hpp>
namespace mp_hashing {
namespace io = boost::iostreams;
struct hash_sink {
hash_sink(size_t& seed_ref) : _ptr(&seed_ref) {}
typedef char char_type;
typedef io::sink_tag category;
std::streamsize write(const char* s, std::streamsize n) {
boost::hash_combine(*_ptr, boost::hash_range(s, s+n));
return n;
}
private:
size_t* _ptr;
};
template <typename T> struct hash_impl {
size_t operator()(T const& v) const {
using namespace boost;
size_t seed = 0;
{
iostreams::stream<hash_sink> os(seed);
archive::binary_oarchive oa(os, archive::no_header | archive::no_codecvt);
oa << v;
}
return seed;
}
};
}
#include <unordered_map>
#include <boost/unordered_map.hpp>
namespace std {
template <typename backend>
struct hash<boost::multiprecision::number<backend> >
: mp_hashing::hash_impl<boost::multiprecision::number<backend> >
{};
}
namespace boost {
template <typename backend>
struct hash<multiprecision::number<backend> >
: mp_hashing::hash_impl<multiprecision::number<backend> >
{};
}
template <typename Map>
void test(Map const& map) {
std::cout << "\n" << __PRETTY_FUNCTION__ << "\n";
for(auto& p : map)
std::cout << p.second << "\t" << p.first << "\n";
}
int main() {
using boost::multiprecision::cpp_int;
test(std::unordered_map<cpp_int, std::string> {
{ cpp_int(1) << 111, "one" },
{ cpp_int(2) << 222, "two" },
{ cpp_int(3) << 333, "three" },
});
test(boost::unordered_map<cpp_int, std::string> {
{ cpp_int(1) << 111, "one" },
{ cpp_int(2) << 222, "two" },
{ cpp_int(3) << 333, "three" },
});
}
Prints
void test(const Map&) [with Map = std::unordered_map<boost::multiprecision::number<boost::multiprecision::backends::cpp_int_backend<> >, std::basic_string<char> >]
one 2596148429267413814265248164610048
three 52494017394792286184940053450822912768476066341437098474218494553838871980785022157364316248553291776
two 13479973333575319897333507543509815336818572211270286240551805124608
void test(const Map&) [with Map = boost::unordered::unordered_map<boost::multiprecision::number<boost::multiprecision::backends::cpp_int_backend<> >, std::basic_string<char> >]
three 52494017394792286184940053450822912768476066341437098474218494553838871980785022157364316248553291776
two 13479973333575319897333507543509815336818572211270286240551805124608
one 2596148429267413814265248164610048
As you can see, the difference in implementation between Boost's and the standard library's unordered_map show up in the different orderings for identical hashes.
Just to say that I've just added native hashing support (for Boost.Hash and std::hash) to git develop. It works for all the number types including those from GMP etc. Unfortunately that code won't be released until Boost-1.62 now.
The answer above that (ab)uses serialization support, is actually extremely cool and really rather clever ;) However, it wouldn't work if you wanted to use a vector-based hasher like CityHash, I added an example of using that by accessing the limbs directly to the docs: https://htmlpreview.github.io/?https://github.com/boostorg/multiprecision/blob/develop/doc/html/boost_multiprecision/tut/hash.html Either direct limb-access or the serialization tip will work with all previous releases of course.