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/* Copyright (c) 2014-2016, Stanislaw Halik <sthalik@misaki.pl>
* Permission to use, copy, modify, and/or distribute this
* software for any purpose with or without fee is hereby granted,
* provided that the above copyright notice and this permission
* notice appear in all copies.
*/
#pragma once
#include "export.hpp"
#include <type_traits>
#include <utility>
#include <cmath>
namespace {
// last param to fool SFINAE into overloading
template<int i, int j, int>
struct equals
{
enum { value = i == j };
};
template<int i, int j, int min>
struct maybe_add_swizzle
{
enum { value = (i == 1 || j == 1) && (i >= min || j >= min) };
};
template<int i1, int j1, int i2, int j2>
struct is_vector_pair
{
enum { value = (i1 == i2 && j1 == 1 && j2 == 1) || (j1 == j2 && i1 == 1 && i2 == 1) };
};
template<int i, int j>
struct vector_len
{
enum { value = i > j ? i : j };
};
template<int a, int b, int c, int d>
struct is_dim3
{
enum { value = (a == 1 && c == 1 && b == 3 && d == 3) || (a == 3 && c == 3 && b == 1 && d == 1) };
enum { P = a == 1 ? 1 : 3 };
enum { Q = a == 1 ? 3 : 1 };
};
template<typename num, int h, int w, typename...ts>
struct is_arglist_correct
{
enum { value = h * w == sizeof...(ts) };
};
}
template<typename num, int h_, int w_>
class Mat
{
static_assert(h_ > 0 && w_ > 0, "must have positive mat dimensions");
num data[h_][w_];
public:
template<int Q = w_> typename std::enable_if<equals<Q, 1, 0>::value, num>::type
inline operator()(int i) const { return data[i][0]; }
template<int P = h_> typename std::enable_if<equals<P, 1, 1>::value, num>::type
inline operator()(int i) const { return data[0][i]; }
template<int Q = w_> typename std::enable_if<equals<Q, 1, 2>::value, num&>::type
inline operator()(int i) { return data[i][0]; }
template<int P = h_> typename std::enable_if<equals<P, 1, 3>::value, num&>::type
inline operator()(int i) { return data[0][i]; }
template<int Q = w_> typename std::enable_if<equals<Q, 1, 0>::value, num>::type
inline operator()(unsigned i) const { return data[i][0]; }
template<int P = h_> typename std::enable_if<equals<P, 1, 1>::value, num>::type
inline operator()(unsigned i) const { return data[0][i]; }
template<int Q = w_> typename std::enable_if<equals<Q, 1, 2>::value, num&>::type
inline operator()(unsigned i) { return data[i][0]; }
template<int P = h_> typename std::enable_if<equals<P, 1, 3>::value, num&>::type
inline operator()(unsigned i) { return data[0][i]; }
#define OPENTRACK_ASSERT_SWIZZLE static_assert(P == h_ && Q == w_, "")
template<int P = h_, int Q = w_> typename std::enable_if<maybe_add_swizzle<P, Q, 1>::value, num>::type
x() const { OPENTRACK_ASSERT_SWIZZLE; return operator()(0); }
template<int P = h_, int Q = w_> typename std::enable_if<maybe_add_swizzle<P, Q, 2>::value, num>::type
y() const { OPENTRACK_ASSERT_SWIZZLE; return operator()(1); }
template<int P = h_, int Q = w_> typename std::enable_if<maybe_add_swizzle<P, Q, 3>::value, num>::type
z() const { OPENTRACK_ASSERT_SWIZZLE; return operator()(2); }
template<int P = h_, int Q = w_> typename std::enable_if<maybe_add_swizzle<P, Q, 4>::value, num>::type
w() const { OPENTRACK_ASSERT_SWIZZLE; return operator()(3); }
template<int P = h_, int Q = w_> typename std::enable_if<maybe_add_swizzle<P, Q, 1>::value, num&>::type
x() { OPENTRACK_ASSERT_SWIZZLE; return operator()(0); }
template<int P = h_, int Q = w_> typename std::enable_if<maybe_add_swizzle<P, Q, 2>::value, num&>::type
y() { OPENTRACK_ASSERT_SWIZZLE; return operator()(1); }
template<int P = h_, int Q = w_> typename std::enable_if<maybe_add_swizzle<P, Q, 3>::value, num&>::type
z() { OPENTRACK_ASSERT_SWIZZLE; return operator()(2); }
template<int P = h_, int Q = w_> typename std::enable_if<maybe_add_swizzle<P, Q, 4>::value, num&>::type
w() { OPENTRACK_ASSERT_SWIZZLE; return operator()(3); }
// parameters w_ and h_ are rebound so that SFINAE occurs
// removing them causes a compile-time error -sh 20150811
template<int R, int S, int P = h_, int Q = w_>
typename std::enable_if<is_vector_pair<R, S, P, Q>::value, num>::type
norm() const
{
static_assert(P == h_ && Q == w_, "");
return std::sqrt(dot(*this));
}
template<int R, int S, int P = h_, int Q = w_>
typename std::enable_if<is_vector_pair<R, S, P, Q>::value, num>::type
dot(const Mat<num, R, S>& p2) const
{
static_assert(P == h_ && Q == w_, "");
num ret = 0;
constexpr int len = vector_len<R, S>::value;
for (int i = 0; i < len; i++)
ret += operator()(i) * p2(i);
return ret;
}
template<int R, int S, int P = h_, int Q = w_>
typename std::enable_if<is_dim3<P, Q, R, S>::value, Mat<num, is_dim3<P, Q, R, S>::P, is_dim3<P, Q, R, S>::Q>>::type
cross(const Mat<num, R, S>& p2) const
{
static_assert(P == h_ && Q == w_, "");
decltype(*this)& p1 = *this;
return Mat<num, R, S>(p1.y() * p2.z() - p1.y() * p2.z(),
p1.x() * p2.z() - p1.x() * p2.z(),
p1.x() * p2.y() - p1.y() * p2.x());
}
Mat<num, h_, w_> operator+(const Mat<num, h_, w_>& other) const
{
Mat<num, h_, w_> ret;
for (int j = 0; j < h_; j++)
for (int i = 0; i < w_; i++)
ret(j, i) = data[j][i] + other.data[j][i];
return ret;
}
Mat<num, h_, w_> operator-(const Mat<num, h_, w_>& other) const
{
Mat<num, h_, w_> ret;
for (int j = 0; j < h_; j++)
for (int i = 0; i < w_; i++)
ret(j, i) = data[j][i] - other.data[j][i];
return ret;
}
Mat<num, h_, w_> operator+(const num& other) const
{
Mat<num, h_, w_> ret;
for (int j = 0; j < h_; j++)
for (int i = 0; i < w_; i++)
ret(j, i) = data[j][i] + other;
return ret;
}
Mat<num, h_, w_> operator-(const num& other) const
{
Mat<num, h_, w_> ret;
for (int j = 0; j < h_; j++)
for (int i = 0; i < w_; i++)
ret(j, i) = data[j][i] - other;
return ret;
}
template<int p>
Mat<num, h_, p> operator*(const Mat<num, w_, p>& other) const
{
Mat<num, h_, p> ret;
for (int k = 0; k < h_; k++)
for (int i = 0; i < p; i++)
{
ret(k, i) = 0;
for (int j = 0; j < w_; j++)
ret(k, i) += data[k][j] * other(j, i);
}
return ret;
}
inline num operator()(int j, int i) const { return data[j][i]; }
inline num& operator()(int j, int i) { return data[j][i]; }
inline num operator()(unsigned j, unsigned i) const { return data[j][i]; }
inline num& operator()(unsigned j, unsigned i) { return data[j][i]; }
template<typename... ts, int h__ = h_, int w__ = w_,
typename = typename std::enable_if<is_arglist_correct<num, h__, w__, ts...>::value>::type>
Mat(const ts... xs) : data{static_cast<num>(xs)...}
{
static_assert(h__ == h_ && w__ == w_, "");
}
Mat()
{
for (int j = 0; j < h_; j++)
for (int i = 0; i < w_; i++)
data[j][i] = num(0);
}
Mat(const num* mem)
{
for (int j = 0; j < h_; j++)
for (int i = 0; i < w_; i++)
data[j][i] = mem[i*h_+j];
}
operator num*() { return reinterpret_cast<num*>(data); }
operator const num*() const { return reinterpret_cast<const num*>(data); }
// XXX add more operators as needed, third-party dependencies mostly
// not needed merely for matrix algebra -sh 20141030
template<int h__ = h_>
static typename std::enable_if<h_ == w_, Mat<num, h__, h__>>::type eye()
{
static_assert(h_ == h__, "");
Mat<num, h_, h_> ret;
for (int j = 0; j < h_; j++)
for (int i = 0; i < w_; i++)
ret.data[j][i] = 0;
for (int i = 0; i < h_; i++)
ret.data[i][i] = 1;
return ret;
}
Mat<num, w_, h_> t() const
{
Mat<num, w_, h_> ret;
for (int j = 0; j < h_; j++)
for (int i = 0; i < w_; i++)
ret(i, j) = data[j][i];
return ret;
}
};
template<typename num, int h, int w>
Mat<num, h, w> operator*(num scalar, const Mat<num, h, w>& mat)
{
return mat * scalar;
}
template<typename num, int h_, int w_>
Mat<num, h_, w_> operator*(const Mat<num, h_, w_>& self, num other)
{
Mat<num, h_, w_> ret;
for (int j = 0; j < h_; j++)
for (int i = 0; i < w_; i++)
ret(j, i) = self(j, i) * other;
return ret;
}
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