x11ma/script/old_scripts/EnergyScan_backup.py

import os
import traceback
import thread

############################PGM+ID1+ID2###################################################

if str(SET_OFFSETS) == "1":
    print "Setting offsets"
    #print file_prefix
    if RUNTYPE in ["+/-", "+" , "-"]:  
        caput(OTF_MODE1,1) # circ + in ID1 
        caput(OTF_MODE2,2) # circ - in ID2
    elif RUNTYPE in ["LH/LV", "LH", "LV"]:
        caput(OTF_MODE1,0)
        caput(OTF_MODE2,0)
        wait_channel(OTF_DONE, 1, type = 'i')
        caput(OTF_ALPHA1, 0.0)  # LH in ID1
        caput(OTF_ALPHA2, 90.0) # LV in ID2
        wait_channel(OTF_DONE, 1, type = 'i') 
    else:
        raise Exception("Invalid run type: " +  RUNTYPE) 
       
    caput(OTF_OFF1,OFFSET1)
    caput(OTF_OFF2,OFFSET2-40) #detune ID2
    wait_channel(OTF_DONE, 1, type = 'i')
    print "Offsets are set"
    import sys
    sys.exit(0)
else:
    print "Running full script"

file_prefix = time.strftime("%y%m%d")
input_path =  "/sls/X11MA/Data1/public/X11MA/temp/"+file_prefix+"/"
output_path = input_path #+file_prefix+"/" #"/sls/X11MA/Data1/public/e10989/"+file_prefix+"/"


#Parameters
"""
E1 = 680
E2 = 750
TIME = 2 #min
DELAY = 10.0 #s
OFFSET1 = 1.0 #eV
OFFSET2 = -1.0 #eV
PREFIX = 'Data'
RUNTYPE = "+/-"
ROUNDS = 1
PLOT_TYPE = 1
"""
print "\nStarting energy scan - Parameters: ",
print E1,E2,TIME,DELAY,OFFSET1,OFFSET2,RUNTYPE#,ALPHA1,ALPHA2


###############################################################################
# Plotting
###############################################################################

task = None
running = False


def _startPlot(type):
    global running
    sep = "\t"
    line_sep = "\r\n"
    print "Starting plot: type " + str(type)
    running = True
    p = plot(None,name="Energy")[0]
    s = p.getSeries(0)
    cur = 0
    time.sleep(3.0)
    MCP1 = []
    MCP2 = []
    while running: 
        try:
            if  otf_start.read() == 0:
                break
            e = energy.read()
            if (MCP_1 == 1 or MCP_2 == 1):
                aK1=keithley_1a.read()
                #aP=FillingPattern.read()
                #aPr = []
                #for z in aP:
                #    aPr.append(z)
                aPr = FillingPattern.read().tolist()
                SumaP=0
                CamaP=0
                for z in xrange(0,480):
                    SumaP = SumaP + aPr[z]
                for z in xrange(460,470):
                    CamaP = CamaP + aPr[z]
                aK1norm = aK1 * CamaP / SumaP
            if MCP_1 == 1:
                #a1=MCPArray1.read()
                #a1r = []
                #for i in a1: 
                #    a1r.append(i)
                a1r = MCPArray1.read().tolist()
                Sum1a1 = 0
                Cam1a1 = 0
                Sum2a1 = 0
                Cam2a1 = 0
                MCP1.append(line_sep)
                MCP1.append(e)
                for i in xrange(0,480):
                    Sum1a1 = Sum1a1 + a1r[i]
                for i in xrange(Cam_start,Cam_end+1):
                    Cam1a1 = Cam1a1 + a1r[i]
                Cam1a1 = a1r[Cam_start]
                
                MCP1.append(Sum1a1)
                MCP1.append(Cam1a1)
                MCP1.append(aK1norm)
                
                if NrCounters.read() > 460:     
                    for i in xrange(480,960):
                        Sum2a1 = Sum2a1 + a1r[i]
                    for i in xrange(Cam_start+480,Cam_end+481):
                        Cam2a1 = Cam2a1 + a1r[i] 
                    Cam2a1 = a1r[Cam_start+480]
                    MCP1.append(Sum2a1)
                    MCP1.append(Cam2a1)
                if Save_array_data == 1:
                    MCP1.append(a1r)
            if MCP_2 == 1:
                #a2=MCPArray2.read()
                #a2r = []
                #for j in a2:                    
                #    a2r.append(j)
                a2r = MCPArray2.read().tolist()
                Sum1a2 = 0
                Cam1a2 = 0
                Sum2a2 = 0
                Cam2a2 = 0
                MCP2.append(line_sep)
                MCP2.append(e)
                for j in xrange(0,480):
                    Sum1a2 = Sum1a2 + a2r[j]
                for j in xrange(Cam_start,Cam_end+1):
                    Cam1a2 = Cam1a2 + a2r[j]
                Cam1a2 = a2r[Cam_end]
                
                MCP2.append(Sum1a2)
                MCP2.append(Cam1a2)
                MCP2.append(aK1norm)
                if NrCounters.read() > 460:     
                    for j in xrange(480,960):
                        Sum2a2 = Sum2a2 + a2r[j]
                    for j in xrange(Cam_start+480,Cam_end+481):
                        Cam2a2 = Cam2a2 + a2r[j]
                    Cam2a2 =  a2r[Cam_end+481]
                    MCP2.append(Sum2a2)
                    MCP2.append(Cam2a2)
                if Save_array_data == 1:
                    MCP2.append(a2r)
            time.sleep(SamplingTime.read()*0.001)
            if (abs(e-cur)) > 0.1:            
                v = abs((keithley_2a.read() / ((keithley_1a if (type==1) else keithley_3a).read() )))
                s.appendData(e,v)    
                cur = e                                  
            #    time.sleep(0.2)
        except:
            pass
    print "Done Plotting"
    if MCP_1 == 1:
        output_file_MCP1 = output_path+"MCP_1_"+file_prefix+"_" + suffix + ".dat"
        MCP1out = open(output_file_MCP1, "a+")
        sMCP1 = sep.join(str(x) for x in MCP1) + line_sep       #    MCP1.write("%s" + sep % i)
        sMCP1out = sep + "rbkenergy" + sep + "Sum1" + sep + "Cam1" + sep + "Keithley1_norm"
        if NrCounters.read() > 460:     
            sMCP1out = sMCP1out + sep + "Sum2" + sep  + "Cam2"
        if Save_array_data == 1:
            sMCP1out = sMCP1out + sep + "Array"
        sMCP1out = sMCP1out + line_sep + sMCP1                
        MCP1out.write(sMCP1out)
        MCP1out.close()
        print "Saved MCP signal data"
    if MCP_2 == 1:     
        output_file_MCP2 = output_path+"MCP_2_"+file_prefix+"_" + suffix + ".dat"
        MCP2out = open(output_file_MCP2, "a+")
        sMCP2 = sep.join(str(y) for y in MCP2) + line_sep      
        sMCP2out = sep + "rbkenergy" + sep + "Sum1" + sep + "Cam1" + sep + "Keithley1_norm"
        if NrCounters.read() > 460:     
            sMCP2out = sMCP2out + sep + "Sum2" + sep  + "Cam2"
        if Save_array_data == 1:
            sMCP2out = sMCP2out + sep + "Array"
        sMCP2out = sMCP2out + line_sep + sMCP2                
        MCP2out.write(sMCP2out)
        MCP2out.close()  
        print "Saved MCP I_0 data"   
def startPlot(type = 1):
    global task
    task = fork((_startPlot,(type,)),)        

def stopPlot():
    global task, running
    running = False
    ret = join(task)

    
############################PGM+ID1+ID2###################################################


def switchpol(activeID, runtype):
    global pol_str
    if activeID == 1:
        caput(OTF_OFF1,OFFSET1)
        caput(OTF_OFF2,OFFSET2-40) #detune ID2
        if runtype in ["+/-", "+"]:
            pol_str = "circ +"
        elif runtype in ["LH/LV", "LH"]:
            pol_str = "Lin. Horizontal"
    elif activeID == 2:
        caput(OTF_OFF1,OFFSET1-40) #detune ID1
        caput(OTF_OFF2,OFFSET2)
        if runtype in ["+/-", "-"]: 
            pol_str = "circ -"
        elif runtype in ["LH/LV", "LV"]:
            pol_str = "Lin. Vertical"
    else:
        raise Exception("Invalid parameter")


pol_str = None
polswitch = 1

fid = get_next_fid(input_path, "o" + file_prefix)



###############################################################################
#Prepare scan
###############################################################################
if ID1 == 1:
    caput ("X11PHS-E:OPT","PGM+ID1")
elif ID2 == 1:
    caput ("X11PHS-E:OPT","PGM+ID2")
else:
    caput ("X11PHS-E:OPT","PGM+ID1+ID2")

number_of_scans = 1
if RUNTYPE in ["+/-", "+", "-"]:
    caput(OTF_MODE1,1) # circ + in ID1 
    caput(OTF_MODE2,2) # circ - in ID2
    wait_channel(OTF_DONE, 1, type = 'i')
    if RUNTYPE == "+/-":
        number_of_scans = 2 * ROUNDS
    else: 
        number_of_scans = ROUNDS
elif RUNTYPE in ["LH/LV", "LH", "LV"]:
    caput(OTF_MODE1,0)
    caput(OTF_MODE2,0)
    wait_channel(OTF_DONE, 1, type = 'i')
    caput(OTF_ALPHA1, 0.0)  # LH in ID1
    caput(OTF_ALPHA2, 90.0) # LV in ID2
    #wait_channel(OTF_DONE, 1, type = 'i')
    if RUNTYPE == "LH/LV":
        number_of_scans = 2 * ROUNDS
    else:
        number_of_scans = ROUNDS
else:
    raise Exception("Invalid run type: " +  RUNTYPE)

if RUNTYPE in ["-", "LV"]:
    switchpol(2, RUNTYPE) # tune ID2 --> polarization: C- or LV
    polswitch = 0
elif RUNTYPE in ["+/-", "+", "LH/LV", "LH"]:
    switchpol(1, RUNTYPE) # tune ID1 --> polarization: C+ or LH
time.sleep(1.0)

wait_channel(OTF_DONE, 1, type = 'i')

open_vg10()
time.sleep(0.5)
open_vg11()
time.sleep(0.5)
open_vg12()
time.sleep(0.5)
open_vg13()

for scan_no  in range(number_of_scans):
    suffix = ("%03d" % fid)
    input_file = input_path + "o" + file_prefix + "_" + suffix + ".dat" 

    caput(OTF_E1, E1)
    caput(OTF_E2, E2)
    caput(OTF_TIME, TIME)
    caput(OTF_FTS,file_prefix)
    caput(OTF_FID,fid)
    time.sleep(2.0) 
    caput(OTF_ESET, E1)
    #wait_channel(OTF_DONE, 1, type = 'i')
    time.sleep(DELAY)    
    time.sleep(2.0)

    startPlot(PLOT_TYPE)
    #Start the OTF scan
    #caput(OTF_START, 'GO')
    otf_start.write(1)
    time.sleep(3.0)
    print "Running scan " + str(scan_no+1) + " out of " + str(number_of_scans)
    try:
        #wait_channel(OTF_START, 'STOP', timeout = int(TIME*60), type = 's')
        otf_start.waitValue(0, (15 + int(TIME*60)) *1000)        
    except:
        print "********    OTF STOP TIMEOUT   **********"
        otf_start.write(0)    
    finally:
        stopPlot()
        
    time.sleep(5.0)    
    #Convert file
    output_file = output_path + "os" + file_prefix + "_" + suffix + ".dat"

    print("Converting data file: " + output_file);               
    convert_file(input_file, output_file, pol_str)
    plot_file(output_file, file_prefix+"_" + suffix) #"Scan " + str(scan_no+1))
    print "Finished scan " + str(scan_no+1) + " out of " + str(number_of_scans)
    
    if RUNTYPE in ["+/-", "LH/LV"]:
        if polswitch == 1:
            switchpol(2, RUNTYPE) # tune ID2 --> polarization: C- or LV
            polswitch = 0
        else:
            polswitch = 1
            switchpol(1, RUNTYPE) # tune ID1 --> polarization: C+ or LH
    else:
        print "running in one polarization mode, no switching"
        
    time.sleep(3.0)
    
    time.sleep(5.0)
    #TODO: wait for file instead of sleep
    #Convert file
    output_file = output_path + "os" + file_prefix + "_" + suffix + ".dat"

    print("Converting data file: " + output_file);               
    convert_file(input_file, output_file, pol_str)
    plot_file(output_file, file_prefix+"_" + suffix) #"Scan " + str(scan_no+1))
    print "Finished scan " + str(scan_no+1) + " out of " + str(number_of_scans)
    
    if RUNTYPE in ["+/-", "LH/LV"]:
        if polswitch == 1:
            switchpol(2, RUNTYPE) # tune ID2 --> polarization: C- or LV
            polswitch = 0
        else:
            polswitch = 1
            switchpol(1, RUNTYPE) # tune ID1 --> polarization: C+ or LH
    else:
        print "running in one polarization mode, no switching"
        
    time.sleep(3.0)
    fid = fid + 1

caput(OTF_ESET, E1) 
close_vg13()

print "Finished Energy scan"

print("Success")