You can try my fixed point class (Latest available @ https://github.com/eteran/cpp-utilities)

```
// From http://www.codef00.com/code/Fixed.h
// See also: http://stackoverflow.com/questions/79677/whats-the-best-way-to-do-fixed-point-math
/*
* Copyright (c) 2008
* Evan Teran
*
* Permission to use, copy, modify, and distribute this software and its
* documentation for any purpose and without fee is hereby granted, provided
* that the above copyright notice appears in all copies and that both the
* copyright notice and this permission notice appear in supporting
* documentation, and that the same name not be used in advertising or
* publicity pertaining to distribution of the software without specific,
* written prior permission. We make no representations about the
* suitability this software for any purpose. It is provided "as is"
* without express or implied warranty.
*/
#ifndef FIXED_20060211_H_
#define FIXED_20060211_H_
#include <ostream>
#include <exception>
#include <cstddef> // for std::size_t
#include <climits> // for CHAR_BIT
#include <stdint.h>
#include <boost/static_assert.hpp>
#include <boost/operators.hpp>
#include <boost/utility/enable_if.hpp>
namespace numeric {
template <std::size_t I, std::size_t F>
class Fixed;
namespace detail {
template <class T>
struct bit_size {
static const std::size_t size = sizeof(T) * CHAR_BIT;
};
// helper templates to make magic with types :)
// these allow us to determine resonable types from
// a desired size, they also let us infer the next largest type
// from a type which is nice for the division op
template <std::size_t T>
struct type_from_size {
static const bool is_specialized = false;
typedef void value_type;
};
#if defined(__GNUC__) && defined(__x86_64__)
template <>
struct type_from_size<128> {
static const bool is_specialized = true;
static const std::size_t size = 128;
typedef __int128 value_type;
typedef type_from_size<128> next_size;
};
#endif
template <>
struct type_from_size<64> {
static const bool is_specialized = true;
static const std::size_t size = 64;
typedef int64_t value_type;
typedef type_from_size<128> next_size;
};
template <>
struct type_from_size<32> {
static const bool is_specialized = true;
static const std::size_t size = 32;
typedef int32_t value_type;
typedef type_from_size<64> next_size;
};
template <>
struct type_from_size<16> {
static const bool is_specialized = true;
static const std::size_t size = 16;
typedef int16_t value_type;
typedef type_from_size<32> next_size;
};
template <>
struct type_from_size<8> {
static const bool is_specialized = true;
static const std::size_t size = 8;
typedef int8_t value_type;
typedef type_from_size<16> next_size;
};
// this is to assist in adding support for non-native base
// types (for adding big-int support), this should be fine
// unless your bit-int class doesn't nicely support casting
template<class B, class N>
B next_to_base(const N& rhs) {
return static_cast<B>(rhs);
}
struct divide_by_zero : std::exception {
};
template <std::size_t I, std::size_t F>
void divide(const Fixed<I,F> &numerator, const Fixed<I,F> &denominator, Fixed<I,F> "ient, Fixed<I,F> &remainder, typename boost::enable_if_c<detail::type_from_size<I+F>::next_size::is_specialized>::type* = 0) {
BOOST_STATIC_ASSERT(detail::type_from_size<I + F>::next_size::is_specialized);
typedef typename Fixed<I,F>::next_type next_type;
typedef typename Fixed<I,F>::base_type base_type;
static const std::size_t fractional_bits = Fixed<I,F>::fractional_bits;
next_type t(numerator.to_raw());
t <<= fractional_bits;
quotient = Fixed<I,F>::from_base(detail::next_to_base<base_type>(t / denominator.to_raw()));
remainder = Fixed<I,F>::from_base(detail::next_to_base<base_type>(t % denominator.to_raw()));
}
template <std::size_t I, std::size_t F>
void divide(Fixed<I,F> numerator, Fixed<I,F> denominator, Fixed<I,F> "ient, Fixed<I,F> &remainder, typename boost::disable_if_c<detail::type_from_size<I+F>::next_size::is_specialized>::type* = 0) {
// NOTE: division is broken for large types :-(
// especially when dealing with negative quantities
typedef typename Fixed<I,F>::base_type base_type;
static const int bits = Fixed<I,F>::total_bits;
if(denominator == 0) {
throw divide_by_zero();
} else {
int sign = 0;
if(numerator < 0) {
sign ^= 1;
numerator = -numerator;
}
if(denominator < 0) {
sign ^= 1;
denominator = -denominator;
}
base_type n = numerator.to_raw();
base_type d = denominator.to_raw();
base_type x = 1;
base_type answer = 0;
while((n >= d) && (((d >> (bits - 1)) & 1) == 0)) {
x <<= 1;
d <<= 1;
}
while(x != 0) {
if(n >= d) {
n -= d;
answer |= x;
}
x >>= 1;
d >>= 1;
}
quotient = answer;
remainder = n;
if(sign) {
quotient = -quotient;
}
}
}
// this is the usual implementation of multiplication
template <std::size_t I, std::size_t F>
void multiply(const Fixed<I,F> &lhs, const Fixed<I,F> &rhs, Fixed<I,F> &result, typename boost::enable_if_c<detail::type_from_size<I+F>::next_size::is_specialized>::type* = 0) {
BOOST_STATIC_ASSERT(detail::type_from_size<I + F>::next_size::is_specialized);
typedef typename Fixed<I,F>::next_type next_type;
typedef typename Fixed<I,F>::base_type base_type;
static const std::size_t fractional_bits = Fixed<I,F>::fractional_bits;
next_type t(static_cast<next_type>(lhs.to_raw()) * static_cast<next_type>(rhs.to_raw()));
t >>= fractional_bits;
result = Fixed<I,F>::from_base(next_to_base<base_type>(t));
}
// this is the fall back version we use when we don't have a next size
// it is slightly slower, but is more robust since it doesn't
// require and upgraded type
template <std::size_t I, std::size_t F>
void multiply(const Fixed<I,F> &lhs, const Fixed<I,F> &rhs, Fixed<I,F> &result, typename boost::disable_if_c<detail::type_from_size<I+F>::next_size::is_specialized>::type* = 0) {
typedef typename Fixed<I,F>::base_type base_type;
static const std::size_t fractional_bits = Fixed<I,F>::fractional_bits;
static const std::size_t integer_mask = Fixed<I,F>::integer_mask;
static const std::size_t fractional_mask = Fixed<I,F>::fractional_mask;
// more costly but doesn't need a larger type
const base_type a_hi = (lhs.to_raw() & integer_mask) >> fractional_bits;
const base_type b_hi = (rhs.to_raw() & integer_mask) >> fractional_bits;
const base_type a_lo = (lhs.to_raw() & fractional_mask);
const base_type b_lo = (rhs.to_raw() & fractional_mask);
const base_type x1 = a_hi * b_hi;
const base_type x2 = a_hi * b_lo;
const base_type x3 = a_lo * b_hi;
const base_type x4 = a_lo * b_lo;
result = Fixed<I,F>::from_base((x1 << fractional_bits) + (x3 + x2) + (x4 >> fractional_bits));
}
}
// lets us do things like "typedef numeric::fixed_from_type<int32_t>::fixed_type fixed";
// NOTE: that we will use a type of equivalent size, not neccessarily the type
// specified. Should make little to no difference to the user
template <class T>
struct fixed_from_type {
typedef Fixed<detail::bit_size<T>::size / 2, detail::bit_size<T>::size / 2> fixed_type;
};
/*
* inheriting from boost::operators enables us to be a drop in replacement for base types
* without having to specify all the different versions of operators manually
*/
template <std::size_t I, std::size_t F>
class Fixed : boost::operators<Fixed<I,F> >, boost::shiftable<Fixed<I,F> > {
BOOST_STATIC_ASSERT(detail::type_from_size<I + F>::is_specialized);
public:
static const std::size_t fractional_bits = F;
static const std::size_t integer_bits = I;
static const std::size_t total_bits = I + F;
typedef detail::type_from_size<total_bits> base_type_info;
typedef typename base_type_info::value_type base_type;
typedef typename base_type_info::next_size::value_type next_type;
public:
static const std::size_t base_size = base_type_info::size;
static const base_type fractional_mask = ~((~base_type(0)) << fractional_bits);
static const base_type integer_mask = ~fractional_mask;
public:
static const base_type one = base_type(1) << fractional_bits;
public: // constructors
Fixed() : data_(0) {
}
Fixed(long n) : data_(base_type(n) << fractional_bits) {
// TODO: assert in range!
}
Fixed(unsigned long n) : data_(base_type(n) << fractional_bits) {
// TODO: assert in range!
}
Fixed(int n) : data_(base_type(n) << fractional_bits) {
// TODO: assert in range!
}
Fixed(unsigned int n) : data_(base_type(n) << fractional_bits) {
// TODO: assert in range!
}
Fixed(float n) : data_(static_cast<base_type>(n * one)) {
// TODO: assert in range!
}
Fixed(double n) : data_(static_cast<base_type>(n * one)) {
// TODO: assert in range!
}
Fixed(const Fixed &o) : data_(o.data_) {
}
Fixed& operator=(const Fixed &o) {
data_ = o.data_;
return *this;
}
private:
// this makes it simpler to create a fixed point object from
// a native type without scaling
// use "Fixed::from_base" in order to perform this.
struct no_scale {};
Fixed(base_type n, const no_scale &) : data_(n) {
}
public:
static Fixed from_base(base_type n) {
return Fixed(n, no_scale());
}
public: // comparison operators
bool operator==(const Fixed &o) const {
return data_ == o.data_;
}
bool operator<(const Fixed &o) const {
return data_ < o.data_;
}
public: // unary operators
bool operator!() const {
return !data_;
}
Fixed operator~() const {
Fixed t(*this);
t.data_ = ~t.data_;
return t;
}
Fixed operator-() const {
Fixed t(*this);
t.data_ = -t.data_;
return t;
}
Fixed& operator++() {
data_ += one;
return *this;
}
Fixed& operator--() {
data_ -= one;
return *this;
}
public: // basic math operators
Fixed& operator+=(const Fixed &n) {
data_ += n.data_;
return *this;
}
Fixed& operator-=(const Fixed &n) {
data_ -= n.data_;
return *this;
}
Fixed& operator&=(const Fixed &n) {
data_ &= n.data_;
return *this;
}
Fixed& operator|=(const Fixed &n) {
data_ |= n.data_;
return *this;
}
Fixed& operator^=(const Fixed &n) {
data_ ^= n.data_;
return *this;
}
Fixed& operator*=(const Fixed &n) {
detail::multiply(*this, n, *this);
return *this;
}
Fixed& operator/=(const Fixed &n) {
Fixed temp;
detail::divide(*this, n, *this, temp);
return *this;
}
Fixed& operator>>=(const Fixed &n) {
data_ >>= n.to_int();
return *this;
}
Fixed& operator<<=(const Fixed &n) {
data_ <<= n.to_int();
return *this;
}
public: // conversion to basic types
int to_int() const {
return (data_ & integer_mask) >> fractional_bits;
}
unsigned int to_uint() const {
return (data_ & integer_mask) >> fractional_bits;
}
float to_float() const {
return static_cast<float>(data_) / Fixed::one;
}
double to_double() const {
return static_cast<double>(data_) / Fixed::one;
}
base_type to_raw() const {
return data_;
}
public:
void swap(Fixed &rhs) {
using std::swap;
swap(data_, rhs.data_);
}
public:
base_type data_;
};
template <std::size_t I, std::size_t F>
std::ostream &operator<<(std::ostream &os, const Fixed<I,F> &f) {
os << f.to_double();
return os;
}
template <std::size_t I, std::size_t F>
const std::size_t Fixed<I,F>::fractional_bits;
template <std::size_t I, std::size_t F>
const std::size_t Fixed<I,F>::integer_bits;
template <std::size_t I, std::size_t F>
const std::size_t Fixed<I,F>::total_bits;
}
#endif
```

It is designed to be a near drop in replacement for floats/doubles and has a choose-able precision. It does make use of boost to add all the necessary math operator overloads, so you will need that as well (I believe for this it is just a header dependency, not a library dependency).

BTW, common usage could be something like this:

```
typedef Fixed<16, 16> fixed;
fixed f;
```

The only real rule is that the number have to add up to a native size of your system such as 8, 16, 32, 64.