DicePlayer/diceplayer/environment/system.py

from diceplayer import logger
from diceplayer.environment.molecule import Molecule
from diceplayer.utils.misc import BOHR2ANG

import numpy as np
from numpy import linalg
from typing_extensions import List, Tuple

import math
from copy import deepcopy


class System:
    """
    System class declaration. This class is used throughout the DicePlayer program to represent the system containing the molecules.

    Atributes:
        molecule (List[Molecule]): List of molecules of the system
        nmols (List[int]): List of number of molecules in the system
    """

    def __init__(self) -> None:
        """
        Initializes an empty system object that will be populated afterwards
        """
        self.nmols: List[int] = []
        self.molecule: List[Molecule] = []

    def add_type(self, m: Molecule) -> None:
        """
        Adds a new molecule type to the system

        Args:
            m (Molecule): The instance of the new type of molecule
        """
        if isinstance(m, Molecule) is False:
            raise TypeError("Error: molecule is not a Molecule instance")
        self.molecule.append(m)

    def update_molecule(self, position: np.ndarray) -> None:
        """Updates the position of the molecule in the Output file

        Args:
            position (np.ndarray): numpy position vector
        """

        position_in_ang = (position * BOHR2ANG).tolist()
        self.add_type(deepcopy(self.molecule[0]))

        for atom in self.molecule[-1].atom:
            atom.rx = position_in_ang.pop(0)
            atom.ry = position_in_ang.pop(0)
            atom.rz = position_in_ang.pop(0)

        rmsd, self.molecule[0] = self.rmsd_fit(-1, 0)
        self.molecule.pop(-1)

        logger.info("Projected new conformation of reference molecule with RMSD fit")
        logger.info(f"RMSD = {rmsd:>8.5f} Angstrom")

    def rmsd_fit(self, p_index: int, r_index: int) -> Tuple[float, Molecule]:
        projecting_mol = self.molecule[p_index]
        reference_mol = self.molecule[r_index]

        if len(projecting_mol.atom) != len(reference_mol.atom):
            raise RuntimeError(
                "Error in RMSD fit procedure: molecules have different number of atoms"
            )
        dim = len(projecting_mol.atom)

        new_projecting_mol = deepcopy(projecting_mol)
        new_reference_mol = deepcopy(reference_mol)

        new_projecting_mol.center_of_mass_to_origin()
        new_reference_mol.center_of_mass_to_origin()

        x = []
        y = []

        for atom in new_projecting_mol.atom:
            x.extend([atom.rx, atom.ry, atom.rz])

        for atom in new_reference_mol.atom:
            y.extend([atom.rx, atom.ry, atom.rz])

        x = np.array(x).reshape(dim, 3)
        y = np.array(y).reshape(dim, 3)

        r = np.matmul(y.T, x)
        rr = np.matmul(r.T, r)

        try:
            evals, evecs = linalg.eigh(rr)
        except Exception as err:
            raise RuntimeError(
                "Error: diagonalization of RR matrix did not converge"
            ) from err

        a1 = evecs[:, 2].T
        a2 = evecs[:, 1].T
        a3 = np.cross(a1, a2)

        A = np.array([a1[0], a1[1], a1[2], a2[0], a2[1], a2[2], a3[0], a3[1], a3[2]])
        A = A.reshape(3, 3)

        b1 = np.matmul(r, a1.T).T  # or np.dot(r, a1)
        b1 /= linalg.norm(b1)
        b2 = np.matmul(r, a2.T).T  # or np.dot(r, a2)
        b2 /= linalg.norm(b2)
        b3 = np.cross(b1, b2)

        B = np.array([b1[0], b1[1], b1[2], b2[0], b2[1], b2[2], b3[0], b3[1], b3[2]])
        B = B.reshape(3, 3).T

        rot_matrix = np.matmul(B, A)
        x = np.matmul(rot_matrix, x.T).T

        rmsd = 0
        for i in range(dim):
            rmsd += (
                (x[i, 0] - y[i, 0]) ** 2
                + (x[i, 1] - y[i, 1]) ** 2
                + (x[i, 2] - y[i, 2]) ** 2
            )
        rmsd = math.sqrt(rmsd / dim)

        for i in range(dim):
            new_projecting_mol.atom[i].rx = x[i, 0]
            new_projecting_mol.atom[i].ry = x[i, 1]
            new_projecting_mol.atom[i].rz = x[i, 2]

        reference_mol.center_of_mass()

        projected_mol = new_projecting_mol.translate(reference_mol.com)

        return rmsd, projected_mol

    # def center_of_mass_distance(self, a: int, b: int) -> float:
    #     """
    #     Calculates the distance between the center of mass of two molecules
    #
    #     Args:
    #         a (Molecule): First Molecule Instance
    #         b (Molecule): Second Molecule Instance
    #
    #     Returns:
    #         float: module of the distance between the two center of masses
    #     """
    #
    #     com1 = self.molecule[a].center_of_mass()
    #     com2 = self.molecule[b].center_of_mass()
    #     dx = com1[0] - com2[0]
    #     dy = com1[1] - com2[1]
    #     dz = com1[2] - com2[2]
    #     distance = math.sqrt(dx**2 + dy**2 + dz**2)
    #
    #     return distance

    # def nearest_image(
    #     self,
    #     index_r: int,
    #     index_m: int,
    #     lx: float,
    #     ly: float,
    #     lz: float,
    #     criterium=None,
    # ) -> Tuple[float, Molecule]:
    #
    #     if criterium in None:
    #         criterium = "com"
    #
    #     if criterium != "com" and criterium != "min":
    #         raise RuntimeError("Error in value passed to function nearest_image")
    #
    #     min_dist = 1e20
    #
    #     for i in range(-1, 2):
    #         for j in range(-1, 2):
    #             for k in range(-1, 2):
    #
    #                 tr_vector = [i * lx, j * ly, k * lz]
    #                 self.add_molecule(self.molecule[index_m].translate(tr_vector))
    #
    #                 if criterium == "com":
    #                     dist = self.center_of_mass_distance(index_r, -1)
    #                 else:
    #                     dist = self.minimum_distance(index_r, -1)
    #
    #                 if dist < min_dist:
    #                     min_dist = dist
    #                     nearestmol = deepcopy(self.molecule[-1])
    #
    #     self.molecule.pop(-1)
    #
    #     return min_dist, nearestmol

    # def print_geom(self, cycle: int, fh: TextIO) -> None:
    #     """
    #             Print the geometry of the molecule in the Output file
    #
    #             Args:
    #                 cycle (int): Number of the cycle
    #                 fh (TextIO): Output file
    #             """
    #
    #     fh.write("Cycle # {}\n".format(cycle))
    #     fh.write("Number of site: {}\n".format(len(self.molecule[0].atom)))
    #     for atom in self.molecule[0].atom:
    #         symbol = atomsymb[atom.na]
    #         fh.write(
    #             "{:<2s}    {:>10.6f}  {:>10.6f}  {:>10.6f}\n".format(
    #                 symbol, atom.rx, atom.ry, atom.rz
    #             )
    #         )
    #
    def print_charges_and_dipole(self, cycle: int) -> None:
        """
        Print the charges and dipole of the molecule in the Output file

        Args:
            cycle (int): Number of the cycle
            fh (TextIO): Output file
        """

        logger.info("Cycle # {}\n".format(cycle))
        logger.info("Number of site: {}\n".format(len(self.molecule[0].atom)))

        chargesAndDipole = self.molecule[0].charges_and_dipole()

        logger.info(
            "{:>10.6f}  {:>10.6f}  {:>10.6f}  {:>10.6f}  {:>10.6f}\n".format(
                chargesAndDipole[0],
                chargesAndDipole[1],
                chargesAndDipole[2],
                chargesAndDipole[3],
                chargesAndDipole[4],
            )
        )