galaxy_ninja/galsec.py

# coding: utf-8
"""
    Galaxy kiloparsec extractor

"""
import numpy as np
from astropy.table import QTable, hstack
from astropy import units as u
from astropy.units.quantity import Quantity
from scipy.interpolate import griddata
from scipy.fft import fftn


def vect_r(position: np.array, vector: np.array) -> np.array:
    """Radial component of a vector

    Parameters
    ----------
    position : np.array (N, 3)
        (only reads x and y)
    vector : np.array (N, 3)
        (only reads x and y components)

    Returns
    -------
    np.array (N)
        Radial component
    """
    r = position[:, :2]
    ur = np.transpose((np.transpose(r) / np.sqrt(np.sum(r**2, axis=1))))
    return np.einsum("ij, ij -> i", vector[:, :2], ur)


def vect_phi(position: np.array, vector: np.array):
    """Azimuthal  component of a vecto

    Parameters
    ----------
    position : np.array (N, 3)
        (only reads x and y)
    vector : np.array (N, 3)
        (only reads x and y components)

    Returns
    -------
    np.array (N)
        Azimuthal  component
    """
    r = position[:, :2]
    r_norm = np.sqrt(np.sum(r**2, axis=1))
    rot = np.array([[0, -1], [1, 0]])
    uphi = np.transpose(np.einsum("ij, kj -> ik", rot, r) / r_norm)
    return np.einsum("ij,ij -> i", vector[:, :2], uphi)


def get_sfr(
    stars: QTable, time: Quantity[u.Myr], average_on: Quantity[u.Myr] = 30 * u.Myr
) -> Quantity[u.Msun / u.year]:
    """_summary_

    Parameters
    ----------
    stars : QTable
        _description_
    time : Quantity[u.Myr],
        time at wich the SFR should be computed
    average_on : Quantity, optional
        compute the sfr on the last `average_on` years, by default 30*u.Myr

    Returns
    -------
    float
        SFR in Msun/yr
    """
    try:
        mask = (stars["birth_time"] > max(time - average_on, 0 * u.Myr)) & (
            stars["birth_time"] < time
        )
        dtime = min(average_on, time).to(u.year)
        if dtime == 0:
            sfr = 0.0 * u.Msun / u.year
        else:
            sfr = np.sum(stars["mass"][mask]) / dtime
    except KeyError:
        sfr = 0.0 * u.Msun / u.year
    return sfr


def aggregate(
    grouped_data: QTable,
    weight_field: str = "mass",
    extensive_fields: str = ["mass", "ek"],
    weighted_fields: list = ["velr", "velphi", "velz"],
) -> QTable:
    """Aggregate wisely from grouped data

    Parameters
    ----------
    grouped_data : QTable
        should already have group information
    weight_field : str, optional
        the field used for the  weighting of the non extensive quantities, by default "mass"
    extensive_fields : str, optional
        these will be summed. Should include weight_field, by default ["mass", "ek"]
    weighted_fields : list, optional
        the field that will be weighted, by default ["velr", "velphi", "velz"]

    Returns
    -------
    QTable
        a tabble with the aggregated value for each group
    """
    assert weight_field in extensive_fields

    for field in weighted_fields:
        grouped_data[field] *= grouped_data[weight_field]

    binned_data = grouped_data[extensive_fields + weighted_fields].groups.aggregate(
        np.add
    )

    for field in weighted_fields:
        binned_data[field] /= binned_data[weight_field]  # weighted mean

        # Veocity dispersion
        grouped_data[field] /= grouped_data[weight_field]
        for i in range(len(grouped_data.groups)):
            slice = grouped_data.groups.indices[i], grouped_data.groups.indices[i + 1]
            grouped_data[slice[0] : slice[1]][field] -= binned_data[i][field]
        grouped_data[field] = grouped_data[weight_field] * grouped_data[field] ** 2
        binned_data[f"sigma_{field}"] = grouped_data[field,].groups.aggregate(
            np.add
        )[field]
        binned_data[f"sigma_{field}"] = np.sqrt(
            binned_data[f"sigma_{field}"] / binned_data[weight_field]
        )

    return binned_data


def get_bouncing_box_mask(
    data: QTable, r: Quantity[u.kpc], phi: Quantity[u.rad], size: Quantity[u.kpc]
):
    x = r * np.cos(phi)
    y = r * np.sin(phi)
    norm_inf = np.maximum(
        np.abs(data["position"][:, 0] - x), np.abs(data["position"][:, 1] - y)
    )
    mask = (norm_inf < size / 2) & (np.abs(data["position"][:, 2]) < size / 2)
    return mask


def regrid(
    position: Quantity,
    value: Quantity,
    resolution: Quantity[u.pc],
):
    min_x, max_x = position[:, 0].min(), position[:, 0].max()
    min_y, max_y = position[:, 1].min(), position[:, 1].max()
    min_z, max_z = position[:, 2].min(), position[:, 2].max()
    size = max([max_x - min_x, max_y - min_y, max_z - min_z])

    nb_points = int(np.ceil(((size / resolution).to(u.dimensionless_unscaled).value)))
    gx, gy, gz = np.mgrid[
        min_x.value : max_x.value : nb_points * 1j,
        min_y.value : max_y.value : nb_points * 1j,
        min_z.value : max_z.value : nb_points * 1j,
    ]

    grid = griddata(
        position.value,
        value.value,
        (gx, gy, gz),
        method="nearest",
    )

    import matplotlib.pyplot as plt

    plt.imshow(
        grid[:, :, len(grid) // 2].T,
        origin="lower",
        extent=[min_x.value, max_x.value, min_y.value, max_y.value],
    )
    plt.show()

    return (
        grid,
        (gx, gy, gz),
    )

def fft(
    position: Quantity,
    value: Quantity,
    resolution: Quantity[u.pc],
    ):
    
    grid, (gx, gy, gz) =  regrid(position, value, resolution)
        
    fftn(grid, overwrite_x=True)

class Galsec:
    """
    Galactic sector extractor
    """

    fluids = ["gas", "stars", "dm"]
    units = {
        "gas": {
            "position": u.kpc,
            "volume": u.kpc**3,
            "velocity": u.km / u.s,
            "mass": u.Msun,
        },
        "stars": {
            "position": u.kpc,
            "velocity": u.km / u.s,
            "mass": u.Msun,
            "birth_time": u.Myr,
        },
        "dm": {"position": u.kpc, "velocity": u.km / u.s, "mass": u.Msun},
    }

    def __init__(self, data: dict, copy=True) -> None:
        """Initiazise a Galaxasec object

        Parameters
        ----------
        cell_data : dict
            A dataset of cells in the following format:
            header:
                time     float  [Myr] time since the start of the simulation
                fluids   str list list of fluids included
            gas:
                position float array (Ngas, 3) [kpc], centered
                volume   float array (Ngas)    [pc^3]
                velocity float array (Ngas, 3) [km/s]
                mass     float array (Ngas)    [Msun]
            stars:
                position float array (Nstar, 3) [kpc], centered
                velocity float array (Nstar, 3) [km/s]
                mass     float array (Nstar)    [Msun]
                birth_time      float array (Nstar)    [Myr]
            dm:
                position float array (Ngas, 3) [kpc], centered
                velocity float array (Ngas, 3) [km/s]
                mass     float array (Ngas)    [Msun]
            maps:
                extent      float list  [xmin, xmax, ymin, ymax]  Coordinates of the edges of the map, centered
                gas_coldens float array (Nx, Ny) [Msun/pc^2]      Map of column density
        copy : bool, default=True
            Wheter the data should be copied.
        """

        self.data = {}
        if "fluids" in data["header"]:
            self.fluids = data["header"]["fluids"]

        for fluid in self.fluids:
            self.data[fluid] = QTable(data[fluid], units=self.units[fluid], copy=copy)

        self.time = data["header"]["time"] * u.Myr

        self.compute_derived_values()

    def compute_derived_values(self) -> None:
        """
        Helper function to computed values derivated from input data
        """
        for fluid in self.fluids:
            dset = self.data[fluid]
            dset["r"] = np.sqrt(
                np.sum(dset["position"][:, :2] ** 2, axis=1)
            )  # galactic radius
            dset["phi"] = np.angle(
                dset["position"][:, 0] + dset["position"][:, 1] * 1j
            )  # galactic longitude
            dset["phi"][dset["phi"] < 0] += (
                2 * np.pi * u.rad
            )  # rescaling to get only positive values
            dset["velphi"] = vect_phi(
                dset["position"], dset["velocity"]
            )  # azimuthal velocity
            dset["velr"] = vect_r(dset["position"], dset["velocity"])  # radial velocity
            dset["velz"] = dset["velocity"][:, 2]  # vertical velocity
            dset["ek"] = (dset["mass"] * np.sum(dset["velocity"] ** 2, axis=1)).to(
                u.erg
            )  # kinetic energy

    def ring_binning(self, delta_r: Quantity[u.kpc]):
        """Add radial bin informations to the dataset

        Parameters
        ----------
        delta_r : Quantity[u.kpc]
            spacing between two radial bins
        """
        for fluid in self.fluids:
            r_bin = np.trunc(self.data[fluid]["r"] / delta_r)
            r_bin = (r_bin + 0.5) * delta_r  # Store the middle value
            self.data[fluid]["r_bin"] = r_bin

    def sector_binning(self, delta_r: Quantity[u.kpc], delta_l: Quantity[u.kpc]):
        """Add sector bin information to the dataset

        Parameters
        ----------
        delta_r : Quantity[u.kpc]
            spacing between two radial bins
        delta_l : Quantity[u.kpc]
            spacing (in spatial units) between two azimuthal bins
        """

        self.ring_binning(delta_r)

        for fluid in self.fluids:
            delta_phi = (delta_l / self.data[fluid]["r_bin"]) * u.rad
            phi_bin = (np.trunc(self.data[fluid]["phi"] / delta_phi) + 0.5) * delta_phi
            self.data[fluid]["phi_bin"] = phi_bin

    def sector_analysis(
        self,
        delta_r: Quantity[u.kpc] = u.kpc,
        delta_l: Quantity[u.kpc] = u.kpc,
        rmin: Quantity[u.kpc] = 1 * u.kpc,
        rmax: Quantity[u.kpc] = 12 * u.kpc,
        zmin: Quantity[u.kpc] = -0.5 * u.kpc,
        zmax: Quantity[u.kpc] = 0.5 * u.kpc,
    ):
        """Compute the aggration of quantities in sectors bins

        Parameters
        ----------
        delta_r : Quantity[u.kpc], optional
            spacing between two radial bins, by default u.kpc
        delta_l : Quantity[u.kpc], optional
            spacing (in spatial units) between two azimuthal bins, by default u.kpc
        rmin : Quantity[u.kpc], optional
            filter out bin below that radius, by default 1*u.kpc
        rmax : Quantity[u.kpc], optional
            filter out bin beyond that radius, by default 12*u.kpc
        """

        self.sector_binning(delta_r, delta_l)
        self.grouped_data = {}
        self.sectors = {}

        for fluid in self.fluids:
            if fluid == "gas":
                extensive_fields = ["mass", "ek", "volume"]
            else:
                extensive_fields = ["mass", "ek"]
            filtered_data = self.data[fluid][
                (self.data[fluid]["r"] > rmin)
                & (self.data[fluid]["r"] < rmax)
                & (self.data[fluid]["position"][:, 2] > zmin)
                & (self.data[fluid]["position"][:, 2] < zmax)
            ]
            self.grouped_data[fluid] = filtered_data.group_by(["r_bin", "phi_bin"])
            self.sectors[fluid] = hstack(
                [
                    self.grouped_data[fluid]["r_bin", "phi_bin"].groups.aggregate(
                        np.fmin
                    ),
                    aggregate(
                        self.grouped_data[fluid], extensive_fields=extensive_fields
                    ),
                ]
            )
            self.sectors[fluid].rename_column("r_bin", "r")
            self.sectors[fluid].rename_column("phi_bin", "phi")

        self.sectors["stars"]["sfr"] = (
            np.zeros(len(self.sectors["stars"]["mass"])) * u.Msun / u.year
        )
        for i, group in enumerate(self.grouped_data["stars"].groups):
            self.sectors["stars"]["sfr"][i] = get_sfr(group, self.time)

        self.sectors["stars"]["sfr"][i] = get_sfr(group, self.time)

    def ring_analysis(
        self,
        delta_r: Quantity[u.kpc] = u.kpc,
        rmin: Quantity[u.kpc] = 1 * u.kpc,
        rmax: Quantity[u.kpc] = 12 * u.kpc,
        zmin: Quantity[u.kpc] = -0.5 * u.kpc,
        zmax: Quantity[u.kpc] = 0.5 * u.kpc,
    ):
        """Compute the aggration of quantities in radial bins

        Parameters
        ----------
        delta_r : Quantity[u.kpc], optional
            spacing between two radial bins, by default u.kpc
        rmin : Quantity[u.kpc], optional
            filter out bin below that radius, by default 1*u.kpc
        rmax : Quantity[u.kpc], optional
            filter out bin beyond that radius, by default 12*u.kpc
        """

        self.ring_binning(delta_r)
        grouped_data = {}
        self.rings = {}

        for fluid in self.fluids:
            if fluid == "gas":
                extensive_fields = ["mass", "ek", "volume"]
            else:
                extensive_fields = ["mass", "ek"]
            filtered_data = self.data[fluid][
                (self.data[fluid]["r"] > rmin)
                & (self.data[fluid]["r"] < rmax)
                & (self.data[fluid]["position"][:, 2] > zmin)
                & (self.data[fluid]["position"][:, 2] < zmax)
            ]
            grouped_data[fluid] = filtered_data.group_by(["r_bin"])
            self.rings[fluid] = hstack(
                [
                    grouped_data[fluid][
                        "r_bin",
                    ].groups.aggregate(np.fmin),
                    aggregate(grouped_data[fluid], extensive_fields=extensive_fields),
                ]
            )
            self.rings[fluid].rename_column("r_bin", "r")

        self.rings["stars"]["sfr"] = (
            np.zeros(len(self.rings["stars"]["mass"])) * u.Msun / u.year
        )
        for i, group in enumerate(grouped_data["stars"].groups):
            self.rings["stars"]["sfr"][i] = get_sfr(group, self.time)