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ex_collisions.py
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ex_collisions.py
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# coding=utf-8
"""Circles, collisions and gravity"""
import glfw
from OpenGL.GL import *
import OpenGL.GL.shaders
import numpy as np
import random
import sys
import os.path
sys.path.append(os.path.dirname(os.path.dirname(os.path.abspath(__file__))))
import grafica.basic_shapes as bs
import grafica.easy_shaders as es
import grafica.transformations as tr
import grafica.performance_monitor as pm
__author__ = "Daniel Calderon"
__license__ = "MIT"
# Example parameters
NUMBER_OF_CIRCLES = 10
CIRCLE_DISCRETIZATION = 20
RADIUS = 0.08
WINDOW_WIDTH = 600
WINDOW_HEIGHT = 600
# Convenience function to ease initialization
def createGPUShape(pipeline, shape):
gpuShape = es.GPUShape().initBuffers()
pipeline.setupVAO(gpuShape)
gpuShape.fillBuffers(shape.vertices, shape.indices, GL_STATIC_DRAW)
return gpuShape
class Circle:
def __init__(self, pipeline, position, velocity, r, g, b):
shape = bs.createColorCircle(CIRCLE_DISCRETIZATION, r, g, b)
# addapting the size of the circle's vertices to have a circle
# with the desired radius
scaleFactor = 2 * RADIUS
bs.scaleVertices(shape, 6, (scaleFactor, scaleFactor, 1.0))
self.pipeline = pipeline
self.gpuShape = createGPUShape(self.pipeline, shape)
self.position = position
self.radius = RADIUS
self.velocity = velocity
def action(self, gravityAceleration, deltaTime):
# Euler integration
self.velocity += deltaTime * gravityAceleration
self.position += self.velocity * deltaTime
def draw(self):
glUniformMatrix4fv(glGetUniformLocation(self.pipeline.shaderProgram, "transform"), 1, GL_TRUE,
tr.translate(self.position[0], self.position[1], 0.0)
)
self.pipeline.drawCall(self.gpuShape)
def rotate2D(vector, theta):
"""
Direct application of a 2D rotation
"""
sin_theta = np.sin(theta)
cos_theta = np.cos(theta)
return np.array([
cos_theta * vector[0] - sin_theta * vector[1],
sin_theta * vector[0] + cos_theta * vector[1]
], dtype = np.float32)
def collide(circle1, circle2):
"""
If there are a collision between the circles, it modifies the velocity of
both circles in a way that preserves energy and momentum.
"""
assert isinstance(circle1, Circle)
assert isinstance(circle2, Circle)
normal = circle2.position - circle1.position
normal /= np.linalg.norm(normal)
circle1MovingToNormal = np.dot(circle2.velocity, normal) > 0.0
circle2MovingToNormal = np.dot(circle1.velocity, normal) < 0.0
if not (circle1MovingToNormal and circle2MovingToNormal):
# obtaining the tangent direction
tangent = rotate2D(normal, np.pi/2.0)
# Projecting the velocity vector over the normal and tangent directions
# for both circles, 1 and 2.
v1n = np.dot(circle1.velocity, normal) * normal
v1t = np.dot(circle1.velocity, tangent) * tangent
v2n = np.dot(circle2.velocity, normal) * normal
v2t = np.dot(circle2.velocity, tangent) * tangent
# swaping the normal components...
# this means that we applying energy and momentum conservation
circle1.velocity = v2n + v1t
circle2.velocity = v1n + v2t
def areColliding(circle1, circle2):
assert isinstance(circle1, Circle)
assert isinstance(circle2, Circle)
difference = circle2.position - circle1.position
distance = np.linalg.norm(difference)
collisionDistance = circle2.radius + circle1.radius
return distance < collisionDistance
def collideWithBorder(circle):
# Right
if circle.position[0] + circle.radius > 1.0:
circle.velocity[0] = -abs(circle.velocity[0])
# Left
if circle.position[0] < -1.0 + circle.radius:
circle.velocity[0] = abs(circle.velocity[0])
# Top
if circle.position[1] > 1.0 - circle.radius:
circle.velocity[1] = -abs(circle.velocity[1])
# Bottom
if circle.position[1] < -1.0 + circle.radius:
circle.velocity[1] = abs(circle.velocity[1])
# A class to store the application control
class Controller:
def __init__(self):
self.fillPolygon = True
self.circleCollisions = False
self.useGravity = False
# we will use the global controller as communication with the callback function
controller = Controller()
# This function will be executed whenever a key is pressed or released
def on_key(window, key, scancode, action, mods):
if action != glfw.PRESS:
return
global controller
if key == glfw.KEY_SPACE:
controller.fillPolygon = not controller.fillPolygon
print("Fill polygons?", controller.fillPolygon)
elif key == glfw.KEY_ESCAPE:
glfw.set_window_should_close(window, True)
elif key == glfw.KEY_1:
controller.circleCollisions = not controller.circleCollisions
print("Collisions among circles?", controller.circleCollisions)
elif key == glfw.KEY_2:
controller.useGravity = not controller.useGravity
print("Gravity?", controller.useGravity)
else:
print('Unknown key')
if __name__ == "__main__":
# Initialize glfw
if not glfw.init():
sys.exit(1)
# Creating a glfw window
title = "Circles, collisions and gravity"
window = glfw.create_window(WINDOW_WIDTH, WINDOW_HEIGHT, title, None, None)
if not window:
glfw.terminate()
glfw.set_window_should_close(window, True)
glfw.make_context_current(window)
# Connecting the callback function 'on_key' to handle keyboard events
glfw.set_key_callback(window, on_key)
# Creating our shader program and telling OpenGL to use it
pipeline = es.SimpleTransformShaderProgram()
glUseProgram(pipeline.shaderProgram)
# Setting up the clear screen color
glClearColor(0.15, 0.15, 0.15, 1.0)
# Creating shapes on GPU memory
circles = []
for i in range(NUMBER_OF_CIRCLES):
position = np.array([
random.uniform(-1.0 + RADIUS, 1.0 - RADIUS),
random.uniform(-1.0 + RADIUS, 1.0 - RADIUS)
])
velocity = np.array([
random.uniform(-1.0, 1.0),
random.uniform(-1.0, 1.0)
])
r, g, b = random.uniform(0,1), random.uniform(0,1), random.uniform(0,1)
circle = Circle(pipeline, position, velocity, r, g, b)
circles += [circle]
perfMonitor = pm.PerformanceMonitor(glfw.get_time(), 0.5)
# glfw will swap buffers as soon as possible
glfw.swap_interval(0)
gravityAcceleration = np.array([0.0, -1.0], dtype=np.float32)
noGravityAcceleration = np.array([0.0, 0.0], dtype=np.float32)
# Application loop
while not glfw.window_should_close(window):
# Measuring performance
perfMonitor.update(glfw.get_time())
glfw.set_window_title(window, title + str(perfMonitor))
# Using GLFW to check for input events
glfw.poll_events()
# Using the time as the theta parameter
theta = glfw.get_time()
deltaTime = perfMonitor.getDeltaTime()
if controller.useGravity:
acceleration = gravityAcceleration
else:
acceleration = noGravityAcceleration
# Physics!
for circle in circles:
# moving each circle
circle.action(acceleration, deltaTime)
# checking and processing collisions against the border
collideWithBorder(circle)
# checking and processing collisions among circles
if controller.circleCollisions:
for i in range(len(circles)):
for j in range(i+1, len(circles)):
if areColliding(circles[i], circles[j]):
collide(circles[i], circles[j])
# Clearing the screen
glClear(GL_COLOR_BUFFER_BIT)
# Filling or not the shapes depending on the controller state
if (controller.fillPolygon):
glPolygonMode(GL_FRONT_AND_BACK, GL_FILL)
else:
glPolygonMode(GL_FRONT_AND_BACK, GL_LINE)
# drawing all the circles
for circle in circles:
circle.draw()
# Once the drawing is rendered, buffers are swap so an uncomplete drawing is never seen.
glfw.swap_buffers(window)
# freeing GPU memory
for circle in circles:
circle.gpuShape.clear()
glfw.terminate()