def main():
sys.path.append(".")
import DEBUG
global Cam
global Light
#t = threading.Thread(target = ui)
#t.start()
sol = []
Step = 2
Size = 30
for i in range(-Size, Size, Step):
for j in range(-Size, Size, Step):
sq1 = matrix.mat3x3([[i, j, 3], [i, j + Step, 3], [i + Step, j,
3]])
"""
sq2 = matrix.mat3x3([
[i,j+Step,1],
[i+Step,j+Step,1],
[i+Step,j,1]
])"""
sol.append(sq1)
#sol.append(sq2)
MatGraph.MultiplyMeshAndMatrix(sol,
matrix.RotationMatrix("X", math.pi / 2))
global TranslationMatrix
DEBUG.init()
Graphics.initDisplayHandler(DEBUG.window, DEBUG.ScreenSize, 100,
15 * math.pi / 180)
DEBUG.HandleWindowEvents()
theta = 0
phi = 0
vtheta = 0
#for p in sys.path:
#Test2 = Load3DElement("GPlaneur/Tests/Graphipsa3D/MeshFiles/GAMIIIING.obj")
#MatGraph.MultiplyMeshAndMatrix(Test,matrix.RotationMatrix("Y",theta))
#MatGraph.MultiplyMeshAndMatrix(Test,matrix.RotationMatrix("X",math.pi/6))
#MatGraph.MultiplyMeshAndMatrix(Test,matrix.RotationMatrix("Z",math.pi/6))
#Test2 = Load3DElement("Tests/Graphipsa3D/MeshFiles/teapot.obj")
Cam = vector([0, 0, 0])
vUp = vector([0, 1, 0])
vLookDir = vector([0, 0, 1])
vTarget = vector([0, 0, 1])
#print(pygame.display.Info())
Step = 2
Size = 60
offset = 0
LastCamPos = 0
miniOffset = 0
while DEBUG.ISRUNNING:
#thetaa += math.pi/512
#Cam.v[2] -= DEBUG.JoystickAxis[3]/16
phi += DEBUG.JoystickAxis[1] / 32
vForward = vector([(-vLookDir.v[0]) * DEBUG.JoystickAxis[3] / 1,
(-vLookDir.v[1]) * DEBUG.JoystickAxis[3] / 1,
(-vLookDir.v[2]) * DEBUG.JoystickAxis[3] / 1])
Cam += vForward
#print(Cam)
#vTarget = ([0,0,1])
vLookDir = vector([0, math.sin(phi), math.cos(phi)])
#vLookDir = vector([-math.sin(theta),0,math.cos(theta)])
#vLookDir = vector([1,0,0])
vTarget = Cam + vLookDir
subMat = PointAt(Cam, vTarget, vUp)
mtView = LookAtMatrix(subMat)
#print(vTarget)
sol = []
#print(offset)
if Cam.v[2] > Size + offset - 60:
offset = int(Cam.v[2])
miniOffset = Cam.v[2] - offset
for i in range(-30, 30, Step):
for j in range(offset, Size + offset, Step):
sq1 = matrix.mat3x3([[i, 6, j - miniOffset],
[i + Step, 6, j - miniOffset],
[i, 6, j + Step - miniOffset]])
sol.append(sq1)
#Tst2 = sol.copy()
#MatGraph.MultiplyMeshAndMatrix(Tst2,matrix.RotationMatrix("X",math.pi/2))
#MatGraph.AddMeshAndMatrix(Tst2,matrix.mat3x3([[0,3,0],[0,3,0],[0,3,0]]))
#MatGraph.MultiplyMeshAndMatrix(Test,matrix.RotationMatrix("Y",-thetaa))
#MatGraph.AddMeshAndMatrix(Test,TranslationMatrix)
#MatGraph.MultiplyMeshAndMatrix(Test,matrix.RotationMatrix("X",thetaa))
#MatGraph.MultiplyMeshAndMatrix(Test,matrix.RotationMatrix("X",math.pi/6))
#MatGraph.MultiplyMeshAndMatrix(Test,matrix.RotationMatrix("Z",math.pi/6))
#FillMesh(Test,(255,255,255),Cam,Light,matView)
#FillMesh(Tst2,(0,255,0),Cam,Light,matView)
FillMesh(sol, (255, 255, 255), Cam, Light, mtView)
#DrawMesh(Test,(255,255,255))
DEBUG.HandleWindowEvents()
DEBUG.quit()
def Init():
DEBUG.init()
Graphics.initDisplayHandler(DEBUG.window, DEBUG.ScreenSize, 100,
15 * math.pi / 180)
import Graphics
import matrix
import DEBUG
import MatGraph
import math
from Mesh import *
import random
from typing import List
from dataclasses import dataclass
import threading
DEBUG.init()
Graphics.initDisplayHandler(DEBUG.window,(1920,1080),100,30*math.pi/180)
def PointAt(pos,target,up):
NewForward = target-pos
#print(NewForward.v)
try:
size = math.sqrt(NewForward.v[0]**2+NewForward.v[0]**2+NewForward.v[0]**2)
NewForward.v[0] /= size
NewForward.v[1] /= size
NewForward.v[2] /= size
except:
pass
a = NewForward * MatGraph.DotProduct(up,NewForward)
NewUp = up - a
