125 lines
3.3 KiB
Cython
125 lines
3.3 KiB
Cython
import math
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cpdef float clamp(float value, float mn, float mx):
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return min(max(mn, value), mx)
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cpdef sign(float value):
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if value == 0:
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return 0
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elif value > 0:
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return 1
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else:
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return -1
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cpdef cpn(int p, int n):
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if p < 0 or p > n:
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return 0
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p = min(p, n - p)
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out = 1
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for i in range(1, p + 1):
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out = out * (n - p + i) / i
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return out
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cpdef float catmull(p, t): # WARNING: Worst math formula incomming
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return 0.5 * (
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(2 * p[1]) +
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(-p[0] + p[2]) * t +
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(2 * p[0] - 5 * p[1] + 4 * p[2] - p[3]) * (t ** 2) +
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(-p[0] + 3 * p[1] - 3 * p[2] + p[3]) * (t ** 3))
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cpdef Vec2 point_on_line(Vec2 p0, Vec2 p1, float length):
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cdef float full_length = (((p1.x - p0.x) ** 2) + ((p1.y - p0.y) ** 2)) ** 0.5
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cdef float n = full_length - length
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if full_length == 0: #Fix for something that seems unknown... (We warn if this happens)
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full_length = 1
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cdef float x = (n * p0.x + length * p1.x) / full_length
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cdef float y = (n * p0.y + length * p1.y) / full_length
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return Vec2(x, y)
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cpdef float angle_from_points(Vec2 p0, Vec2 p1):
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return math.atan2(p1.y - p0.y, p1.x - p0.x)
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cpdef float distance_from_points(array):
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cdef float distance = 0
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cdef int i
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for i in range(1, len(array)):
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distance += array[i].distance(array[i - 1])
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return distance
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cpdef Vec2 cart_from_pol(r, t):
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cdef float x = (r * math.cos(t))
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cdef float y = (r * math.sin(t))
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return Vec2(x, y)
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cpdef point_at_distance(array, float distance): #TODO: Optimize...
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cdef int i = 0
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cdef float x, y, current_distance = 0, new_distance = 0, angle
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cdef Vec2 coord, cart
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if len(array) < 2:
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return Vec2(0, 0)
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if distance == 0:
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return array[0]
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if distance_from_points(array) <= distance:
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return array[len(array) - 1]
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for i in range(len(array) - 2):
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x = (array[i].x - array[i + 1].x)
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y = (array[i].y - array[i + 1].y)
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new_distance = math.sqrt(x * x + y * y)
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current_distance += new_distance
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if distance <= current_distance:
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break
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current_distance -= new_distance
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if distance == current_distance:
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return array[i]
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else:
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angle = angle_from_points(array[i], array[i + 1])
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cart = cart_from_pol((distance - current_distance), angle)
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if array[i].x > array[i + 1].x:
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coord = Vec2((array[i].x - cart.x), (array[i].y - cart.y))
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else:
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coord = Vec2((array[i].x + cart.y), (array[i].y + cart.y))
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return coord
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cdef class Vec2(object):
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cdef public float x
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cdef public float y
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def __init__(self, x, y):
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self.x = x
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self.y = y
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def __richcmp__(x, y, op):
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if op == 2:#Py_EQ
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return x.__is_equal(y)
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else:#Py_NE
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return not x.__is_equal(y)
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def __is_equal(self, other):
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return self.x == other.x and self.y == other.y
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cpdef float distance(Vec2 self, Vec2 other):
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cdef float x = self.x - other.x
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cdef float y = self.y - other.y
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return (x*x + y*y) ** 0.5 #sqrt, lol
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cpdef Vec2 calc(Vec2 self, float value, Vec2 other): #I dont know what to call this function yet
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cdef float x = self.x + value * other.x
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cdef float y = self.y + value * other.y
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return Vec2(x, y)
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