Exemplo n.º 1
0
 def _vertices(self, N, length, pos):
     self.length = length
     alpha = pi / N
     theta = 2 * alpha
     b = length / (2 * sin(alpha))
     P0 = Vector(b, 0)
     pos = Vector(*pos)
     return [(P0.rotated(n * theta)) + pos for n in range(N)]
Exemplo n.º 2
0
# -*- coding: utf8 -*-

from FGAme.mathutils import Vector, dot, area, center_of_mass, clip, pi
from FGAme.mathutils import shadow_x, shadow_y

from FGAme.physics.collision import Collision
from FGAme.physics import Circle, AABB, Poly, Rectangle
from FGAme.util import multifunction

u_x = Vector(1, 0)
DEFAULT_DIRECTIONS = [u_x.rotated(n * pi / 12) for n in
                      [0, 1, 2, 3, 4, 5, 7, 8, 9, 10, 11]]


class CollisionError(Exception):

    '''Declara que não existem colisões disponíveis para os dois tipos de
    objetos'''
    pass


def get_collision_generic(A, B):
    '''Retorna uma colisão genérica definido pela CBB dos objetos A e B'''

    rA = A.cbb_radius
    rB = B.cbb_radius
    delta = B._pos - A._pos
    if delta.norm() < rA + rB:
        n = delta.normalized()
        D = rA + rB - delta.norm()
        pos = A._pos + (rA - D / 2) * n
Exemplo n.º 3
0
from FGAme.mathutils import Vector, dot, area, center_of_mass, clip, pi

from FGAme.physics.collision import (Collision, get_collision,
                                     get_collision_aabb)
from FGAme.physics.elements import (Circle, AABB, Poly, Rectangle)

u_x = Vector(1, 0)
DEFAULT_DIRECTIONS = [
    u_x.rotated(n * pi / 12) for n in [0, 1, 2, 3, 4, 5, 7, 8, 9, 10, 11]
]

###############################################################################
# Colisões entre figuras primitivas simples
###############################################################################

get_collision[AABB, AABB] = get_collision_aabb


@get_collision.dispatch(Circle, Circle)
def circle_collision(A, B):
    '''Testa a colisão pela distância dos centros'''

    delta = B.pos - A.pos
    if delta.norm() < A.radius + B.radius:
        n = delta.normalized()
        D = A.radius + B.radius - delta.norm()
        pos = A.pos + (A.radius - D / 2) * n
        return Collision(A, B, pos=pos, n=n)
    else:
        return None
Exemplo n.º 4
0
def test_vector_rotation():
    v = Vector(1, 0)
    assert (v.rotated(pi / 2) - Vector(0, 1)).norm() < 1e-6, v
Exemplo n.º 5
0
def test_vector_norm():
    v = Vector(1, 2)
    u = v.normalized()
    r = v.rotated(pi / 3)
    assert abs(u.norm() - 1) < 1e-6, u.norm()
    assert abs(v.norm() - r.norm()) < 1e-6, (v.norm(), r.norm())