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ecgsyn.js/mini-odeint/mini-odeint.hpp
John K. Luebs 78a00f71cc update
2024-11-09 13:08:47 -06:00

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#ifndef MINI_ODEINT_H_
#define MINI_ODEINT_H_
#include <array>
#include <cassert>
#include <cmath>
#include <span>
namespace mini_odeint {
template <typename T> struct DormandPrince {
using value_type = T;
static constexpr std::size_t stages = 7;
static constexpr std::size_t order = 5;
static constexpr std::size_t estimator_order = 4;
static constexpr std::size_t dense_order = 5;
static constexpr std::array<T, stages> c{
0.0, 1.0 / 5.0, 3.0 / 10.0, 4.0 / 5.0, 8.0 / 9.0, 1.0, 1.0};
static constexpr std::array<std::array<T, stages - 1>, stages> a{
{{0.0, 0.0, 0.0, 0.0, 0.0},
{1.0 / 5.0, 0.0, 0.0, 0.0, 0.0},
{3.0 / 40.0, 9.0 / 40.0, 0.0, 0.0, 0.0},
{44.0 / 45.0, -56.0 / 15.0, 32.0 / 9.0, 0.0, 0.0},
{19372.0 / 6561.0, -25360.0 / 2187.0, 64448.0 / 6561.0, -212.0 / 729.0,
0.0},
{9017.0 / 3168.0, -355.0 / 33.0, 46732.0 / 5247.0, 49.0 / 176.0,
-5103.0 / 18656.0},
{35.0 / 384.0, 0.0, 500.0 / 1113.0, 125.0 / 192.0, -2187.0 / 6784.0,
11.0 / 84.0}}};
static constexpr std::array<T, stages> b_hat{
35.0 / 384.0, 0.0, 500.0 / 1113.0, 125.0 / 192.0, -2187.0 / 6784.0,
11.0 / 84.0, 0.0};
static constexpr std::array<T, stages> b{5179.0 / 57600.0, 0.0,
7571.0 / 16695.0, 393.0 / 640.0,
-92097.0 / 339200.0, 187.0 / 2100.0,
1.0 / 40.0};
static constexpr std::array<std::array<T, dense_order>, stages> p{
{{1.0, -32272833064.0 / 11282082432.0, 34969693132.0 / 11282082432.0,
-13107642775.0 / 11282082432.0, 157015080.0 / 11282082432.0},
{0.0, 0.0, 0.0, 0.0, 0.0},
{0.0, 1323431896.0 * 100.0 / 32700410799.0,
-2074956840.0 * 100.0 / 32700410799.0,
914128567.0 * 100.0 / 32700410799.0,
-15701508.0 * 100.0 / 32700410799.0},
{0.0, -889289856.0 * 25.0 / 5641041216.0,
2460397220.0 * 25.0 / 5641041216.0, -1518414297.0 * 25.0 / 5641041216.0,
94209048.0 * 25.0 / 5641041216.0},
{0.0, 259006536.0 * 2187.0 / 199316789632.0,
-687873124.0 * 2187.0 / 199316789632.0,
451824525.0 * 2187.0 / 199316789632.0,
-52338360.0 * 2187.0 / 199316789632.0},
{0.0, -361440756.0 * 11.0 / 2467955532.0,
946554244.0 * 11.0 / 2467955532.0, -661884105.0 * 11.0 / 2467955532.0,
106151040.0 * 11.0 / 2467955532.0},
{0.0, 44764047.0 / 29380423.0, -127201567 / 29380423.0,
90730570.0 / 29380423.0, -8293050.0 / 29380423.0}}};
};
template <typename T> struct scalar_type {
using type = T;
};
template <typename T, std::size_t N> struct scalar_type<T[N]> {
using type = T;
};
template <typename T, std::size_t N> struct scalar_type<std::array<T, N>> {
using type = T;
};
template <typename T> using scalar_type_t = typename scalar_type<T>::type;
template <typename T> struct is_std_array : std::false_type {};
template <typename T, std::size_t N>
struct is_std_array<std::array<T, N>> : std::true_type {};
template <typename T>
inline constexpr bool is_std_array_v = is_std_array<T>::value;
template <typename T>
requires std::is_trivially_copyable_v<T>
class OdeVector {
using Scalar = scalar_type_t<T>;
T value;
public:
OdeVector() = default;
explicit OdeVector(T value) : value(std::move(value)) {}
friend constexpr OdeVector operator*(OdeVector lhs, const Scalar &rhs) {
return lhs *= rhs;
}
friend constexpr OdeVector operator*(const Scalar &lhs, OdeVector rhs) {
return rhs *= lhs;
}
friend constexpr OdeVector operator+(OdeVector lhs, const OdeVector &rhs) {
return lhs += rhs;
}
friend constexpr OdeVector operator+(const T &lhs, OdeVector rhs) {
return rhs += OdeVector{lhs};
}
friend constexpr OdeVector operator+(OdeVector lhs, const T &rhs) {
return lhs += OdeVector{rhs};
}
const OdeVector &operator*=(const Scalar &rhs) {
if constexpr (std::is_bounded_array_v<T>) {
for (std::size_t i = 0; i < std::extent_v<T>; ++i) {
value[i] *= rhs;
}
} else if constexpr (is_std_array_v<T>) {
for (std::size_t i = 0; i < std::tuple_size_v<T>; ++i) {
value[i] *= rhs;
}
} else {
value *= rhs;
}
return *this;
}
constexpr OdeVector &operator+=(const OdeVector &rhs) {
if constexpr (std::is_bounded_array_v<T>) {
for (std::size_t i = 0; i < std::extent_v<T>; ++i) {
value[i] += rhs.value[i];
}
} else if constexpr (is_std_array_v<T>) {
for (std::size_t i = 0; i < std::tuple_size_v<T>; ++i) {
value[i] += rhs.value[i];
}
} else {
value += rhs.value;
}
return *this;
}
constexpr OdeVector &operator=(const T &rhs) {
value = rhs;
return *this;
}
explicit constexpr operator const T &() const { return value; }
};
template <typename E> struct Vec2 {
using value_type = E;
E x, y;
constexpr Vec2() = default;
constexpr Vec2(E x, E y) : x(std::move(x)), y(std::move(y)) {}
constexpr explicit Vec2(std::array<E, 3> v) : x(v[0]), y(v[1]) {}
friend constexpr Vec2 operator+(Vec2 lhs, const Vec2 &rhs) {
return lhs += rhs;
}
friend constexpr Vec2 operator-(Vec2 lhs, const Vec2 &rhs) {
return lhs -= rhs;
}
friend constexpr Vec2 operator*(Vec2 lhs, const value_type &rhs) {
return lhs *= rhs;
}
friend constexpr Vec2 operator*(const value_type &lhs, Vec2 rhs) {
return rhs *= lhs;
}
friend constexpr Vec2 operator/(Vec2 lhs, const value_type &rhs) {
return lhs /= rhs;
}
constexpr Vec2 operator-() const { return Vec2{-x, -y}; }
constexpr Vec2 &operator+=(const Vec2 &rhs) {
x += rhs.x;
y += rhs.y;
return *this;
}
constexpr Vec2 &operator-=(const Vec2 &rhs) {
x -= rhs.x;
y -= rhs.y;
return *this;
}
constexpr Vec2 &operator*=(const value_type &rhs) {
x *= rhs;
y *= rhs;
return *this;
}
constexpr Vec2 &operator/=(const value_type &rhs) {
x /= rhs;
y /= rhs;
return *this;
}
};
template <typename E> struct Vec3 {
using value_type = E;
E x, y, z;
constexpr Vec3() = default;
constexpr Vec3(E x, E y, E z)
: x(std::move(x)), y(std::move(y)), z(std::move(z)) {}
explicit constexpr Vec3(const std::array<E, 3> &v)
: x(v[0]), y(v[1]), z(v[2]) {}
explicit constexpr Vec3(std::span<const E, 3> v)
: x(v[0]), y(v[1]), z(v[2]) {}
friend constexpr Vec3 operator+(Vec3 lhs, const Vec3 &rhs) {
return lhs += rhs;
}
friend constexpr Vec3 operator-(Vec3 lhs, const Vec3 &rhs) {
return lhs -= rhs;
}
friend constexpr Vec3 operator*(Vec3 lhs, const value_type &rhs) {
return lhs *= rhs;
}
friend constexpr Vec3 operator*(const value_type &lhs, Vec3 rhs) {
return rhs *= lhs;
}
friend constexpr Vec3 operator/(Vec3 lhs, const value_type &rhs) {
return lhs /= rhs;
}
constexpr Vec3 operator-() const { return Vec3{-x, -y, -z}; }
constexpr Vec3 &operator+=(const Vec3 &rhs) {
x += rhs.x;
y += rhs.y;
z += rhs.z;
return *this;
}
constexpr Vec3 &operator-=(const Vec3 &rhs) {
x -= rhs.x;
y -= rhs.y;
z -= rhs.z;
return *this;
}
constexpr Vec3 &operator*=(const value_type &rhs) {
x *= rhs;
y *= rhs;
z *= rhs;
return *this;
}
constexpr Vec3 &operator/=(const value_type &rhs) {
x /= rhs;
y /= rhs;
z /= rhs;
return *this;
}
};
namespace func {
inline auto inf_norm(std::ranges::range auto v) {
return *std::ranges::max_element(v, {}, [](auto n) { return std::abs(n); });
}
inline std::floating_point auto inf_norm(std::floating_point auto v) {
return std::abs(v);
}
template <typename T> inline auto inf_norm(const OdeVector<T> &v) {
return inf_norm(static_cast<const T &>(v));
}
template <typename E> inline E inf_norm(const Vec2<E> &v) {
return std::max(std::abs(v.x), std::abs(v.y));
}
template <typename E> inline E inf_norm(const Vec3<E> &v) {
return std::max({std::abs(v.x), std::abs(v.y), std::abs(v.z)});
}
} // namespace func
template <typename Vector, typename Scalar = scalar_type_t<Vector>,
typename Tableau = DormandPrince<Scalar>>
requires std::same_as<Scalar, typename Tableau::value_type>
inline std::size_t explicitRungeKutta(std::span<Vector> ys,
std::span<Scalar const> ts, Vector y0,
Scalar tol, auto &&dydx)
requires requires(decltype(dydx) f) {
{ f(Vector{}, Scalar{}) } -> std::same_as<Vector>;
}
{
const auto stages = Tableau::stages;
const auto dense_order = Tableau::dense_order;
const auto order = Tableau::order;
const auto &a = Tableau::a;
const auto &p = Tableau::p;
const auto &c = Tableau::c;
const auto &b = Tableau::b;
const auto &b_hat = Tableau::b_hat;
static_assert(c.back() == 1.0, "last c value must be 1.0");
OdeVector<Vector> y_hat_n{y0};
ys[0] = y0;
std::size_t it = 1;
std::array<OdeVector<Vector>, stages> k;
const auto N = ts.size();
if (!N) {
return 0;
}
auto t_n = ts[0];
auto h_n = ts[N - 1] - t_n;
k[stages - 1] = dydx(y0, t_n);
while (t_n < ts[N - 1]) {
auto step_rejected = true;
while (step_rejected) {
// reuse last k (we have asserted that the last c value is 1.0)
const auto last_k_store = k[stages - 1];
k[0] = k[stages - 1];
for (std::size_t i = 1; i < stages; ++i) {
OdeVector<Vector> sum_ak{};
for (std::size_t j = 0; j < i; ++j) {
sum_ak += a[i][j] * k[j];
}
k[i] =
dydx(static_cast<Vector>(y_hat_n + h_n * sum_ak), t_n + c[i] * h_n);
}
// calculate final value and error
OdeVector<Vector> error{};
OdeVector<Vector> sum_bk{};
for (std::size_t i = 0; i < stages; ++i) {
sum_bk += b_hat[i] * k[i];
error += (b_hat[i] - b[i]) * k[i];
}
const auto y_hat_np1 = y_hat_n + h_n * sum_bk;
// check if step is successful, ie error is within tolerance
const auto E_hp1 = func::inf_norm(h_n * error);
if (E_hp1 < tol) {
// if moved over any requested times then interpolate their values
const auto t_np1 = t_n + h_n;
while (it < N && t_np1 >= ts[it]) {
const auto sigma = (ts[it] - t_n) / h_n;
OdeVector<Vector> Phi{};
for (std::size_t i = 0; i < stages; ++i) {
auto term = sigma;
auto b_i = term * p[i][0];
for (std::size_t j = 1; j < dense_order; ++j) {
term *= sigma;
b_i += term * p[i][j];
}
Phi += b_i * k[i];
}
ys[it] = static_cast<Vector>(y_hat_n + h_n * Phi);
++it;
}
// move to next step
step_rejected = false;
y_hat_n = y_hat_np1;
t_n = t_np1;
} else {
// failed step, reset last k back to stored value
k[stages - 1] = last_k_store;
}
// adapt step size
h_n *= 0.9 * std::pow(tol / E_hp1, 1.0 / (order + 1.0));
}
}
assert(it == N);
return it;
}
} // namespace mini_odeint
#endif // MINI_ODEINT_H_
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