"""
Various transforms used for by the 3D code
"""

import numpy as np
import numpy.linalg as linalg

from matplotlib import cbook


@cbook.deprecated("3.1")
def line2d(p0, p1):
    """
    Return 2D equation of line in the form ax+by+c = 0
    """
    # x + x1  = 0
    x0, y0 = p0[:2]
    x1, y1 = p1[:2]
    #
    if x0 == x1:
        a = -1
        b = 0
        c = x1
    elif y0 == y1:
        a = 0
        b = 1
        c = -y1
    else:
        a = y0 - y1
        b = x0 - x1
        c = x0*y1 - x1*y0
    return a, b, c


@cbook.deprecated("3.1")
def line2d_dist(l, p):
    """
    Distance from line to point
    line is a tuple of coefficients a, b, c
    """
    a, b, c = l
    x0, y0 = p
    return abs((a*x0 + b*y0 + c) / np.hypot(a, b))


def _line2d_seg_dist(p1, p2, p0):
    """distance(s) from line defined by p1 - p2 to point(s) p0

    p0[0] = x(s)
    p0[1] = y(s)

    intersection point p = p1 + u*(p2-p1)
    and intersection point lies within segment if u is between 0 and 1
    """

    x21 = p2[0] - p1[0]
    y21 = p2[1] - p1[1]
    x01 = np.asarray(p0[0]) - p1[0]
    y01 = np.asarray(p0[1]) - p1[1]

    u = (x01*x21 + y01*y21) / (x21**2 + y21**2)
    u = np.clip(u, 0, 1)
    d = np.hypot(x01 - u*x21, y01 - u*y21)

    return d


@cbook.deprecated("3.1")
def line2d_seg_dist(p1, p2, p0):
    """distance(s) from line defined by p1 - p2 to point(s) p0

    p0[0] = x(s)
    p0[1] = y(s)

    intersection point p = p1 + u*(p2-p1)
    and intersection point lies within segment if u is between 0 and 1
    """
    return _line2d_seg_dist(p1, p2, p0)


@cbook.deprecated("3.1", alternative="np.linalg.norm")
def mod(v):
    """3d vector length"""
    return np.sqrt(v[0]**2+v[1]**2+v[2]**2)


def world_transformation(xmin, xmax,
                         ymin, ymax,
                         zmin, zmax):
    dx, dy, dz = (xmax-xmin), (ymax-ymin), (zmax-zmin)
    return np.array([[1/dx, 0,    0,    -xmin/dx],
                     [0,    1/dy, 0,    -ymin/dy],
                     [0,    0,    1/dz, -zmin/dz],
                     [0,    0,    0,    1]])


def view_transformation(E, R, V):
    n = (E - R)
    ## new
#    n /= np.linalg.norm(n)
#    u = np.cross(V,n)
#    u /= np.linalg.norm(u)
#    v = np.cross(n,u)
#    Mr = np.diag([1.]*4)
#    Mt = np.diag([1.]*4)
#    Mr[:3,:3] = u,v,n
#    Mt[:3,-1] = -E
    ## end new

    ## old
    n = n / np.linalg.norm(n)
    u = np.cross(V, n)
    u = u / np.linalg.norm(u)
    v = np.cross(n, u)
    Mr = [[u[0], u[1], u[2], 0],
          [v[0], v[1], v[2], 0],
          [n[0], n[1], n[2], 0],
          [0,    0,    0,    1]]
    #
    Mt = [[1, 0, 0, -E[0]],
          [0, 1, 0, -E[1]],
          [0, 0, 1, -E[2]],
          [0, 0, 0, 1]]
    ## end old

    return np.dot(Mr, Mt)


def persp_transformation(zfront, zback):
    a = (zfront+zback)/(zfront-zback)
    b = -2*(zfront*zback)/(zfront-zback)
    return np.array([[1, 0, 0, 0],
                     [0, 1, 0, 0],
                     [0, 0, a, b],
                     [0, 0, -1, 0]])


def ortho_transformation(zfront, zback):
    # note: w component in the resulting vector will be (zback-zfront), not 1
    a = -(zfront + zback)
    b = -(zfront - zback)
    return np.array([[2, 0, 0, 0],
                     [0, 2, 0, 0],
                     [0, 0, -2, 0],
                     [0, 0, a, b]])


def _proj_transform_vec(vec, M):
    vecw = np.dot(M, vec)
    w = vecw[3]
    # clip here..
    txs, tys, tzs = vecw[0]/w, vecw[1]/w, vecw[2]/w
    return txs, tys, tzs


@cbook.deprecated("3.1")
def proj_transform_vec(vec, M):
    return _proj_transform_vec(vec, M)


def _proj_transform_vec_clip(vec, M):
    vecw = np.dot(M, vec)
    w = vecw[3]
    # clip here.
    txs, tys, tzs = vecw[0] / w, vecw[1] / w, vecw[2] / w
    tis = (0 <= vecw[0]) & (vecw[0] <= 1) & (0 <= vecw[1]) & (vecw[1] <= 1)
    if np.any(tis):
        tis = vecw[1] < 1
    return txs, tys, tzs, tis


@cbook.deprecated("3.1")
def proj_transform_vec_clip(vec, M):
    return _proj_transform_vec_clip(vec, M)


def inv_transform(xs, ys, zs, M):
    iM = linalg.inv(M)
    vec = _vec_pad_ones(xs, ys, zs)
    vecr = np.dot(iM, vec)
    try:
        vecr = vecr / vecr[3]
    except OverflowError:
        pass
    return vecr[0], vecr[1], vecr[2]


def _vec_pad_ones(xs, ys, zs):
    return np.array([xs, ys, zs, np.ones_like(xs)])


@cbook.deprecated("3.1")
def vec_pad_ones(xs, ys, zs):
    return _vec_pad_ones(xs, ys, zs)


def proj_transform(xs, ys, zs, M):
    """
    Transform the points by the projection matrix
    """
    vec = _vec_pad_ones(xs, ys, zs)
    return _proj_transform_vec(vec, M)


transform = proj_transform


def proj_transform_clip(xs, ys, zs, M):
    """
    Transform the points by the projection matrix
    and return the clipping result
    returns txs,tys,tzs,tis
    """
    vec = _vec_pad_ones(xs, ys, zs)
    return _proj_transform_vec_clip(vec, M)


def proj_points(points, M):
    return np.column_stack(proj_trans_points(points, M))


def proj_trans_points(points, M):
    xs, ys, zs = zip(*points)
    return proj_transform(xs, ys, zs, M)


@cbook.deprecated("3.1")
def proj_trans_clip_points(points, M):
    xs, ys, zs = zip(*points)
    return proj_transform_clip(xs, ys, zs, M)


def rot_x(V, alpha):
    cosa, sina = np.cos(alpha), np.sin(alpha)
    M1 = np.array([[1, 0, 0, 0],
                   [0, cosa, -sina, 0],
                   [0, sina, cosa, 0],
                   [0, 0, 0, 1]])
    return np.dot(M1, V)