"""
Arguments:

VECTOR (Double[][], Scan vector: Eph,Elow,Ehigh or Eph,Ecenter)
SENSORS (list)
LATENCY (double)
MODE ('fixed' or 'swept')
TYPE ('CIS' or 'CFS')
STEP (double)
"""

LATENCY = 0.0


class SpectrumReader(ReadonlyRegisterBase, ReadonlyRegisterArray):
    def doRead(self):
        global VECTOR
        self.offset = Eph.getSetpoint().take() - VECTOR[0]
        self.setup()
        trig_scienta()
        time.sleep(0.5)
        return Scienta.getSpectrum().read()

    def getSize(self):
        return len(Scienta.getSpectrumX())


                        
class SpectrumReader1(SpectrumReader):
    def setup(self):
        global energy_scale_array, initial_energy_range               
        Scienta.getLowEnergy().write(initial_energy_range[0][0] + self.offset)
        Scienta.getHighEnergy().write(initial_energy_range[0][1] + self.offset)
        Scienta.getStepSize().write(initial_energy_range[0][2])        
        energy_scale_array = [Scienta.getLowEnergy().take(), Scienta.getHighEnergy().take(), Scienta.getStepSize().take()]

class SpectrumReader2(SpectrumReader):
    def setup(self):        
        global energy_scale_array, initial_energy_range
        Scienta.getLowEnergy().write(initial_energy_range[1][0] + self.offset)
        Scienta.getHighEnergy().write(initial_energy_range[1][1] + self.offset)
        Scienta.getStepSize().write(initial_energy_range[1][2])        
        energy_scale_array = energy_scale_array + [Scienta.getLowEnergy().take(), Scienta.getHighEnergy().take(), Scienta.getStepSize().take()]
        append_dataset(energy_scale_table,energy_scale_array)   

class SpectrumReader3(SpectrumReader):
    def setup(self):        
        global initial_energy_range,energy_scale_array, energy_scale_table
        Scienta.getLowEnergy().write(initial_energy_range[2][0] + self.offset)
        Scienta.getHighEnergy().write(initial_energy_range[2][1] + self.offset)        
        Scienta.getStepSize().write(initial_energy_range[2][2])        
        energy_scale_array = energy_scale_array + [Scienta.getLowEnergy().take(), Scienta.getHighEnergy().take(), Scienta.getStepSize().take()]
        append_dataset(energy_scale_table,energy_scale_array)    


class ImageReader(ReadonlyRegisterBase, ReadonlyRegisterMatrix):   
    def doRead(self):
        return Scienta.getDataMatrix().read()

    def getWidth(self):
        global initial_energy_range 
        return int( (initial_energy_range[self.index][1] - initial_energy_range[self.index][0]) / initial_energy_range[self.index][2])

    def getHeight(self):
        return Scienta.getDataMatrix().getHeight()


def measure_stuff():
    global energy_scale_array, energy_scale_table, VECTOR,pass_energy_hold,angle_time,angle_range,azi_range,bb
    reader1 = SpectrumReader1(); reader1.initialize()
    reader2 = SpectrumReader2(); reader2.initialize()
    #reader3 = SpectrumReader3(); reader3.initialize()
    image1 = ImageReader(); image1.initialize(); image1.index=0; set_device_alias(image1, "Image1")
    image2 = ImageReader(); image2.initialize(); image2.index=1; set_device_alias(image2, "Image2")
    #image3 = ImageReader(); image3.initialize(); image3.index=2; set_device_alias(image3, "Image3")


    Scienta.getDataMatrix()

    SENSORS = [RefCurrent, reader1, image1, reader2, image2]#, reader3, image3]

    Scienta.setAcquisitionMode(ch.psi.pshell.epics.Scienta.AcquisitionMode.Swept)


    adjust_sensors()
    set_adc_averaging()
    set_preference(Preference.PLOT_TYPES, {'Scienta spectrum':1})

    for ll in range(len(azi_range)):
            ManipulatorPhi.move(azi_range[ll])
            for jj in range(len(angle_range)):
                tic = time.time()
                ManipulatorTheta.move(angle_range[jj])
                print 'current theta is ', ManipulatorTheta.take(), ' and current azimuth is ' , ManipulatorPhi.take()
                Scienta.setPassEnergy(pass_energy_hold)
                #print ' Flag 1'
                Scienta.getStepTime().write(angle_time[jj])
                #print ' Flag 2'
                sleep(1)
                bb = bb+1
                energy_scale_table = "scan " + str(bb) + "/EnergyScale"
                print energy_scale_table
                create_dataset(energy_scale_table, 'd', dimensions=[0,9])
                vscan(Eph, SENSORS, VECTOR, True, LATENCY,False, before_read=wait_beam, after_read = after_readout)
                toc = time.time()
                tictoc = round((toc-tic)/60*100)/100
                print 'time taken is ', tictoc, ' minutes' 
            
global initial_energy_range,energy_scale_array, energy_scale_table, VECTOR,pass_energy_hold,angle_time,angle_range,azi_range,SENSORS
bb = 0
SENSORS = []
#################### O 1s PhD scan ##############################
print ' ######################################################'
print ' **            Begin O 1s PhD                        **'
tic_whole = time.time()
VECTOR = [ 638.0]
for nn in range(63):
    VECTOR.append(VECTOR[-1]+4)


pass_energy_hold = 100

initial_energy_range = [[95.5, 105.0, 0.1], 
                        [105.1, 115.0, 0.5]]

angle_time = [0.4, 0.5, 0.6]
energy_scale_array = []

azi_range = [-45.0]
angle_range = [-9.2+20.0, -9.2+40.0, -9.2+60.0]
#measure_stuff()


toc_whole = time.time()
tictoc = round(toc_whole-tic_whole)
print ' **            End O 1s PhD                          **'
print ' ** time taken was ', math.floor(tictoc/3600), ' hours and ', round((tictoc-math.floor(tictoc/3600)*3600)/60), ' minutes.'
print ' ######################################################'

#################### C 1s PhD scan ##############################
print ' ######################################################'
print ' **            Begin C 1s PhD                        **'
tic_whole = time.time()
VECTOR = [ 340.0]
for nn in range(63):
    VECTOR.append(VECTOR[-1]+4)
#nn = 0


initial_energy_range = [[45.0, 53.0, 0.1], 
                        [53.5, 63.0, 0.5]]
pass_energy_hold = 50
angle_time = [0.4,0.4,0.5]
azi_range = [-90.0, -45.0]
angle_range = [-9.2+30.0, -9.2+60.0]

measure_stuff()
toc_whole = time.time()
tictoc = round(toc_whole-tic_whole)
print ' ** time taken was ', math.floor(tictoc/3600), ' hours and ', round((tictoc-math.floor(tictoc/3600)*3600)/60), ' minutes.'
print ' **           End C 1s PhD                          **'
print ' ######################################################'

#################### Si 2p PhD scan ##############################
print ' ######################################################'
print ' **            Begin Si 2p PhD                       **'
tic_whole = time.time()
VECTOR = [ 170.0]
for nn in range(63):
    VECTOR.append(VECTOR[-1]+4)
#nn = 0


initial_energy_range = [[62.0, 67.0, 0.1], 
                        [67.5, 77, 0.5]]
pass_energy_hold = 20
angle_time = [0.4,0.4,0.5]
azi_range = [-90.0,-45.0]
angle_range = [-9.2, -9.2+30.0, -9.2+60.0]

measure_stuff()
toc_whole = time.time()
tictoc = round(toc_whole-tic_whole)
print ' ** time taken was ', math.floor(tictoc/3600), ' hours and ', round((tictoc-math.floor(tictoc/3600)*3600)/60), ' minutes.'
print ' **           End Si 2p PhD                          **'
print ' ######################################################'


#toc = time.time()