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# Copyright (c) 2017 Weitian LI <weitian@aaronly.me>
# MIT license

"""
Solve the Fokker-Planck equation to derive the time evolution
of the electron spectrum (or number density distribution).
"""

import logging

import numpy as np


logger = logging.getLogger(__name__)


def TDMAsolver(a, b, c, d):
    """
    Tri-diagonal matrix algorithm (a.k.a Thomas algorithm) solver,
    which is much faster than the generic Gaussian elimination algorithm.

    a[i]*x[i-1] + b[i]*x[i] + c[i]*x[i+1] = d[i],
    where: a[0] = c[N-1] = 0

    Example
    -------
    >>> A = np.array([[10,  2, 0, 0],
                      [ 3, 10, 4, 0],
                      [ 0,  1, 7, 5],
                      [ 0,  0, 3, 4]], dtype=float)
    >>> a = np.array([     3, 1, 3], dtype=float)
    >>> b = np.array([10, 10, 7, 4], dtype=float)
    >>> c = np.array([ 2,  4, 5   ], dtype=float)
    >>> d = np.array([ 3,  4, 5, 6], dtype=float)
    >>> print(TDMAsolver(a, b, c, d))
    [ 0.14877589  0.75612053 -1.00188324  2.25141243]
    # compare against numpy linear algebra library
    >>> print(np.linalg.solve(A, d))
    [ 0.14877589  0.75612053 -1.00188324  2.25141243]

    References
    ----------
    [1] http://en.wikipedia.org/wiki/Tridiagonal_matrix_algorithm

    Credit
    ------
    [1] https://gist.github.com/cbellei/8ab3ab8551b8dfc8b081c518ccd9ada9
    """
    # Number of equations
    nf = len(d)
    # Copy the input arrays
    ac, bc, cc, dc = map(np.array, (a, b, c, d))
    for it in range(1, nf):
        mc = ac[it-1] / bc[it-1]
        bc[it] -= mc*cc[it-1]
        dc[it] -= mc*dc[it-1]

    xc = bc
    xc[-1] = dc[-1] / bc[-1]

    for il in range(nf-2, -1, -1):
        xc[il] = (dc[il] - cc[il]*xc[il+1]) / bc[il]

    return xc


class FokkerPlanckSolver:
    """
    Solve the Fokker-Planck equation:

    ∂u(x,t)   ∂  /                ∂u(x) \            u(x,t)
    ------- = -- | B(x)u(x) + C(x)----- | + Q(x,t) - ------
       ∂t     ∂x \                  ∂x  /            T(x,t)

    u(x,t) : distribution/spectrum w.r.t. x at different times
    B(x,t) : advection coefficient
    C(x,t) : diffusion coefficient (>0)
    Q(x,t) : injection coefficient (>=0)
    T(x,t) : escape coefficient

    NOTE: The no-flux boundary condition is used.

    Parameters
    ----------
    xmin, xmax : float
        The minimum and maximum bounds of the X (spatial/momentum) axis.
    x_np : int
        Number of (logarithmic grid) points/cells along the X axis
    tstep : float
        Specify to use the constant time step for solving the equation.
    f_advection : function
        Function f(x,t) to calculate the advection coefficient B(x,t)
    f_diffusion : function
        Function f(x,t) to calculate the diffusion coefficient C(x,t)
    f_injection : function
        Function f(x,t) to calculate the injection coefficient Q(x,t)
    f_escape : optional
        Function f(x,t) to calculate the escape coefficient T(x,t)
    buffer_np : int, optional
        Number of grid points taking as the buffer region near the lower
        boundary.  The densities within this buffer region will be replaced
        by extrapolating an power law to avoid unphysical accumulations.
        This fix is ignored if this parameter is not specified.

    References
    ----------
    [1] Park & Petrosian 1996, ApJS, 103, 255
        http://adsabs.harvard.edu/abs/1996ApJS..103..255P
    [2] Donnert & Brunetti 2014, MNRAS, 443, 3564
        http://adsabs.harvard.edu/abs/2014MNRAS.443.3564D
    """

    def __init__(self, xmin, xmax, x_np, tstep,
                 f_advection, f_diffusion, f_injection,
                 f_escape=None, buffer_np=None):
        self.xmin = xmin
        self.xmax = xmax
        self.x_np = x_np
        self.tstep = tstep
        self.f_advection = f_advection
        self.f_diffusion = f_diffusion
        self.f_injection = f_injection
        self.f_escape = f_escape
        self.buffer_np = buffer_np

    @property
    def x(self):
        """
        X values of the adopted logarithmic grid.
        """
        grid = np.logspace(np.log10(self.xmin), np.log10(self.xmax),
                           num=self.x_np)
        return grid

    @property
    def dx(self):
        """
        Values of dx[i] on the grid.

        dx[i] = (x[i+1] - x[i-1]) / 2

        NOTE:
        Extrapolate the x grid by 1 point beyond each side, therefore
        avoid NaN for the first and last element of dx[i].
        Otherwise, the following calculation of tridiagonal coefficients
        may be invalid on the boundary elements.

        References: Ref.[1],Eq.(8)
        """
        x = self.x
        # Extrapolate the x grid by 1 point beyond each side
        x2 = np.concatenate([
            [x[0]**2/x[1]],
            x,
            [x[-1]**2/x[-2]],
        ])
        dx_ = (x2[2:] - x2[:-2]) / 2
        return dx_

    @property
    def dx_phalf(self):
        """
        Values of dx[i+1/2] on the grid.

        dx[i+1/2] = x[i+1] - x[i]
        Thus the last element is NaN.

        References: Ref.[1],Eq.(8)
        """
        x = self.x
        dx_ = x[1:] - x[:-1]
        grid = np.concatenate([dx_, [np.nan]])
        return grid

    @property
    def dx_mhalf(self):
        """
        Values of dx[i-1/2] on the grid.

        dx[i-1/2] = x[i] - x[i-1]
        Thus the first element is NaN.
        """
        x = self.x
        dx_ = x[1:] - x[:-1]
        grid = np.concatenate([[np.nan], dx_])
        return grid

    @staticmethod
    def X_phalf(X):
        """
        Calculate the values at midpoints (+1/2) for the given quantity.

        X[i+1/2] = (X[i] + X[i+1]) / 2
        Thus the last element is NaN.

        References: Ref.[1],Eq.(10)
        """
        Xmid = (X[1:] + X[:-1]) / 2
        return np.concatenate([Xmid, [np.nan]])

    @staticmethod
    def X_mhalf(X):
        """
        Calculate the values at midpoints (-1/2) for the given quantity.

        X[i-1/2] = (X[i-1] + X[i]) / 2
        Thus the first element is NaN.
        """
        Xmid = (X[1:] + X[:-1]) / 2
        return np.concatenate([[np.nan], Xmid])

    @staticmethod
    def W(w):
        # References: Ref.[1],Eqs.(27,35)
        with np.errstate(invalid="ignore"):
            # Ignore NaN's
            w = np.abs(w)
            mask = (w < 0.1)  # Comparison on NaN gives False, as expected
        W = np.zeros(w.shape) * np.nan
        W[mask] = 1.0 / (1 + w[mask]**2/24 + w[mask]**4/1920)
        W[~mask] = (w[~mask] * np.exp(-w[~mask]/2) /
                    (1 - np.exp(-w[~mask])))
        return W

    @staticmethod
    def bound_w(w, wmin=1e-8, wmax=1e3):
        """
        Bound the absolute values of w within [wmin, wmax].

        To avoid the underflow/overflow during later W/Wplus/Wminus
        calculations.
        """
        with np.errstate(invalid="ignore"):
            # Ignore NaN's
            m1 = (np.abs(w) < wmin)
            m2 = (np.abs(w) > wmax)
        ww = np.array(w)
        ww[m1] = wmin * np.sign(ww[m1])
        ww[m2] = wmax * np.sign(ww[m2])
        return ww

    def Wplus(self, w):
        # References: Ref.[1],Eq.(32)
        ww = self.bound_w(w)
        W = self.W(ww)
        Wplus = W * np.exp(ww/2)
        return Wplus

    def Wminus(self, w):
        # References: Ref.[1],Eq.(32)
        ww = self.bound_w(w)
        W = self.W(ww)
        Wminus = W * np.exp(-ww/2)
        return Wminus

    def tridiagonal_coefs(self, tc, uc):
        """
        Calculate the coefficients for the tridiagonal system of linear
        equations corresponding to the original Fokker-Planck equation.

        -a[i]*u[i-1] + b[i]*u[i] - c[i]*u[i+1] = r[i],
        where: a[0] = c[N-1] = 0

        NOTE
        ----
        When i=0 or i=N-1, b[i] is invalid due to X[-1/2] or X[N-1/2] are
        invalid. Therefore, b[0] and b[N-1] should be alternatively
        calculated with (e.g., no-flux) boundary condition considered.

        References: Ref.[1],Eqs.(16,18,34)
        """
        x = self.x
        dx = self.dx
        dx_phalf = self.dx_phalf
        dx_mhalf = self.dx_mhalf
        dt = self.tstep
        B = np.array([self.f_advection(x_, tc) for x_ in x])
        C = np.array([self.f_diffusion(x_, tc) for x_ in x])
        Q = np.array([self.f_injection(x_, tc) for x_ in x])
        #
        B_phalf = self.X_phalf(B)
        B_mhalf = self.X_mhalf(B)
        C_phalf = self.X_phalf(C)
        C_mhalf = self.X_mhalf(C)
        w_phalf = dx_phalf * B_phalf / C_phalf
        w_mhalf = dx_mhalf * B_mhalf / C_mhalf
        Wplus_phalf = self.Wplus(w_phalf)
        Wplus_mhalf = self.Wplus(w_mhalf)
        Wminus_phalf = self.Wminus(w_phalf)
        Wminus_mhalf = self.Wminus(w_mhalf)
        #
        a = (dt/dx) * (C_mhalf/dx_mhalf) * Wminus_mhalf
        a[0] = 0.0  # Fix a[0] which is NaN
        c = (dt/dx) * (C_phalf/dx_phalf) * Wplus_phalf
        c[-1] = 0.0  # Fix c[-1] which is NaN
        b = 1 + (dt/dx) * ((C_mhalf/dx_mhalf) * Wplus_mhalf +
                           (C_phalf/dx_phalf) * Wminus_phalf)
        # Calculate b[0] & b[-1], considering the no-flux boundary condition
        b[0] = 1 + (dt/dx[0]) * (C_phalf[0]/dx_phalf[0])*Wminus_phalf[0]
        b[-1] = 1 + (dt/dx[-1]) * (C_mhalf[-1]/dx_mhalf[-1])*Wplus_mhalf[-1]
        # Escape from the system
        if self.f_escape is not None:
            T = np.array([self.f_escape(x_, tc) for x_ in x])
            b += dt / T
        # Right-hand side
        r = dt * Q + uc
        return (a, b, c, r)

    def fix_boundary(self, uc):
        """
        Truncate the lower end (i.e., near the lower boundary) of the
        distribution/spectrum and then extrapolate as a power law, in order
        to avoid the unphysical pile-up of electrons at the lower regime.

        TODO:
        Fit a power law to the same number (``buffer_np``) of data points,
        then extrapolate it to fix the lower buffer region.

        References: Ref.[2],Sec.(3.3)
        """
        if self.buffer_np is None:
            return uc

        uc = np.asarray(uc)
        x = self.x
        # Calculate the power-law index
        xa = x[self.buffer_np]
        xb = x[self.buffer_np+1]
        ya = uc[self.buffer_np]
        yb = uc[self.buffer_np+1]
        if ya > 0 and yb > 0:
            # Truncate and extrapolate as a power law
            s = np.log(yb/ya) / np.log(xb/xa)
            uc[:self.buffer_np] = ya * (x[:self.buffer_np] / xa) ** s
        return uc

    def time_step(self):
        """
        Adaptively determine the time step for solving the equation.

        TODO/XXX
        """
        pass

    def solve_step(self, tc, uc):
        """
        Solve the Fokker-Planck equation by a single step.
        """
        a, b, c, r = self.tridiagonal_coefs(tc=tc, uc=uc)
        TDM_a = -a[1:]  # Also drop the first element
        TDM_b = b
        TDM_c = -c[:-1]  # Also drop the last element
        TDM_rhs = r
        t2 = tc + self.tstep
        u2 = TDMAsolver(TDM_a, TDM_b, TDM_c, TDM_rhs)
        u2 = self.fix_boundary(u2)
        # Clear negative number densities
        # u2[u2 < 0] = 0
        return (t2, u2)

    def solve(self, u0, tstart, tstop):
        """
        Solve the Fokker-Planck equation from ``tstart`` to ``tstop``,
        with initial spectrum/distribution ``u0``.
        """
        uc = u0
        tc = tstart
        logger.info("Solving Fokker-Planck equation: " +
                    "time: %.3f - %.3f" % (tstart, tstop))
        nstep = int((tstop - tc) / self.tstep)
        logger.info("Constant time step: %.3f (#%d steps)" %
                    (self.tstep, nstep))
        i = 0
        while tc < tstop:
            i += 1
            logger.debug("[%d/%d] t=%.3f ..." % (i, nstep, tc))
            tc, uc = self.solve_step(tc, uc)
        return uc