# -*- coding: utf-8 -*-
"""
Optical system design demo



"""

import initExample ## Add path to library (just for examples; you do not need this)

from optics import *

import pyqtgraph as pg

import numpy as np
from pyqtgraph import Point

app = pg.mkQApp("Optics Demo")

w = pg.GraphicsLayoutWidget(show=True, border=0.5)
w.resize(1000, 900)
w.show()



### Curved mirror demo

view = w.addViewBox()
view.setAspectLocked()
#grid = pg.GridItem()
#view.addItem(grid)
view.setRange(pg.QtCore.QRectF(-50, -30, 100, 100))

optics = []
rays = []
m1 = Mirror(r1=-100, pos=(5,0), d=5, angle=-15)
optics.append(m1)
m2 = Mirror(r1=-70, pos=(-40, 30), d=6, angle=180-15)
optics.append(m2)

allRays = []
for y in np.linspace(-10, 10, 21):
    r = Ray(start=Point(-100, y))
    view.addItem(r)
    allRays.append(r)

for o in optics:
    view.addItem(o)
    
t1 = Tracer(allRays, optics)



### Dispersion demo

optics = []

view = w.addViewBox()

view.setAspectLocked()
#grid = pg.GridItem()
#view.addItem(grid)
view.setRange(pg.QtCore.QRectF(-10, -50, 90, 60))

optics = []
rays = []
l1 = Lens(r1=20, r2=20, d=10, angle=8, glass='Corning7980')
optics.append(l1)

allRays = []
for wl in np.linspace(355,1040, 25):
    for y in [10]:
        r = Ray(start=Point(-100, y), wl=wl)
        view.addItem(r)
        allRays.append(r)

for o in optics:
    view.addItem(o)

t2 = Tracer(allRays, optics)



### Scanning laser microscopy demo

w.nextRow()
view = w.addViewBox(colspan=2)

optics = []


#view.setAspectLocked()
view.setRange(QtCore.QRectF(200, -50, 500, 200))



## Scan mirrors
scanx = 250
scany = 20
m1 = Mirror(dia=4.2, d=0.001, pos=(scanx, 0), angle=315)
m2 = Mirror(dia=8.4, d=0.001, pos=(scanx, scany), angle=135)

## Scan lenses
l3 = Lens(r1=23.0, r2=0, d=5.8, pos=(scanx+50, scany), glass='Corning7980')  ## 50mm  UVFS  (LA4148)
l4 = Lens(r1=0, r2=69.0, d=3.2, pos=(scanx+250, scany), glass='Corning7980')  ## 150mm UVFS  (LA4874)

## Objective
obj = Lens(r1=15, r2=15, d=10, dia=8, pos=(scanx+400, scany), glass='Corning7980')

IROptics = [m1, m2, l3, l4, obj]



## Scan mirrors
scanx = 250
scany = 30
m1a = Mirror(dia=4.2, d=0.001, pos=(scanx, 2*scany), angle=315)
m2a = Mirror(dia=8.4, d=0.001, pos=(scanx, 3*scany), angle=135)

## Scan lenses
l3a = Lens(r1=46, r2=0, d=3.8, pos=(scanx+50, 3*scany), glass='Corning7980') ## 100mm UVFS  (LA4380)
l4a = Lens(r1=0, r2=46, d=3.8, pos=(scanx+250, 3*scany), glass='Corning7980') ## 100mm UVFS  (LA4380)

## Objective
obja = Lens(r1=15, r2=15, d=10, dia=8, pos=(scanx+400, 3*scany), glass='Corning7980')

IROptics2 = [m1a, m2a, l3a, l4a, obja]



for o in set(IROptics+IROptics2):
    view.addItem(o)
    
IRRays = []
IRRays2 = []

for dy in [-0.4, -0.15, 0, 0.15, 0.4]:
    IRRays.append(Ray(start=Point(-50, dy), dir=(1, 0), wl=780))
    IRRays2.append(Ray(start=Point(-50, dy+2*scany), dir=(1, 0), wl=780))
    
for r in set(IRRays+IRRays2):
    view.addItem(r)

IRTracer = Tracer(IRRays, IROptics)
IRTracer2 = Tracer(IRRays2, IROptics2)

phase = 0.0
def update():
    global phase
    if phase % (8*np.pi) > 4*np.pi:
        m1['angle'] = 315 + 1.5*np.sin(phase)
        m1a['angle'] = 315 + 1.5*np.sin(phase)
    else:
        m2['angle'] = 135 + 1.5*np.sin(phase)
        m2a['angle'] = 135 + 1.5*np.sin(phase)
    phase += 0.2
    
timer = QtCore.QTimer()
timer.timeout.connect(update)
timer.start(40)





## Start Qt event loop unless running in interactive mode or using pyside.
if __name__ == '__main__':
    import sys
    if (sys.flags.interactive != 1) or not hasattr(QtCore, 'PYQT_VERSION'):
        QtGui.QApplication.instance().exec_()