sf-op/script/Diagnostics/WireScan.py

import traceback

has_args = get_exec_pars().source != CommandSource.ui  #Must be checked before callin "run"
is_script = get_exec_pars().source == CommandSource.script


run("Devices/Elements")
run("Devices/WireScanner")
run("Diagnostics/sig_process_wrapper")

#set_exec_pars(layout="default")

#Paramter parsing
prefix     = args[0] if has_args else SINDI01-DWSC090 # "S10DI01-DWSC010" #"S10CB07-DWSC440"  #"SINDI01-DWSC090" 
scan_type  = args[1] if has_args else WireScanner.WireX1
scan_range = args[2] if has_args else []
cycles     = args[3] if has_args else 2
#velocity   = args[4] if has_args else 200
n_shot     = args[4] if has_args else 200
bpms       = args[5] if has_args else [] #get_wire_scanners_bpms(prefix)
blms       = args[6] if has_args else get_wire_scanners_blms(prefix)
bkgrd      = args[7] if has_args else 10
plt        = args[8] if has_args else plot(None, title = "Wire Scan")[0]
save_raw   = args[9] if has_args else False
bunch      = args[10] if has_args else 1
do_elog    = True if (has_args and (not is_script) and (plt is not None)) else False
print has_args, do_elog

print "WireScan parameters: ", prefix, scan_type, scan_range, cycles, n_shot, bpms, blms, bkgrd, bunch


SET_BLM_WS_MODE = True
SET_BLM_WS_SETTLING_TIME = 2.0
SET_BLM_WS_BS_READBACK_TIMEOUT = 10000 #ms

#TODO: configure biggerCAJ buffer size and set back to 10000
SAMPLE_CHANNEL_SIZE = 2049 #10000 
SAMPLE_CHANNEL_EMPTY_VALUE = 0.0

BPM_SENSORS = [("x","X"+str(bunch)), ("y","Y"+str(bunch)), ("q","Q"+str(bunch))] #(logic name suffix, channel suffix)

#Plot setup
if plt is not None:
    plt.clear()
    plt.removeMarker(None)
    plt.getAxis(plt.AxisId.X).setLabel("Position");
    plt.getAxis(plt.AxisId.Y).setLabel("");
    plt.getAxis(plt.AxisId.Y2).setLabel("");
    plt.setLegendVisible(True);       
snapshots = []

if scan_range is None or len(scan_range) !=4:
    if scan_type in  [WireScanner.WireX2, WireScanner.WireY2, WireScanner.Set2]:
        scan_range = [ caget(prefix+":W2X_START_SP", 'd'), \
                       caget(prefix+":W2X_END_SP", 'd'), \
                       caget(prefix+":W2Y_START_SP", 'd'), \
                       caget(prefix+":W2Y_END_SP", 'd') ]
    else:
        scan_range = [ caget(prefix+":W1X_START_SP", 'd'), \
                       caget(prefix+":W1X_END_SP", 'd'), \
                       caget(prefix+":W1Y_START_SP", 'd'), \
                       caget(prefix+":W1Y_END_SP", 'd') ]          


rr = get_repetition_rate()
velocity_x = abs(scan_range[1]-scan_range[0])*rr/n_shot
velocity_y = abs(scan_range[3]-scan_range[2])*rr/n_shot


#Creating WireScanner object
print "Creating scanner..."
if prefix not in get_wire_scanners():
    raise Exception("Invalid wire scan: " + prefix)    
scanner = WireScanner(prefix, scan_range, cycles, None, True)

#List of stream channels
channels = [("m_pos", scanner.motor_bs_readback.get_name()), 
            ("cur_cycle", scanner.curr_cycl.get_name()),
            ("scanning", scanner.status_channels[0].get_name())]                

for i in range (len(blms)):
    channels.append (("blm" + str(i+1), blms[i] + ":B" + str(bunch) + "_LOSS"))
    if plt is not None:
        series = LinePlotSeries(blms[i], None, min(i+1, 2))
        plt.addSeries(series)     
        series.setLinesVisible(False)
        series.setPointSize(2)
    if save_raw:    
        channels.append (("blm" + str(i+1) + "_raw" , blms[i] + ":LOSS_SIGNAL_RAW"))
for i in range (len(bpms)):
    for sensor in BPM_SENSORS:
        channels.append (("bpm" + str(i+1) + "_" + sensor[0], bpms[i] + ":" + sensor[1]))

if SET_BLM_WS_MODE and (len(blms)>0):
    channels.append(("blm1_ws_mode", blms[0] + ":WS_RUNNING"))   
channels.append(("beam_ok", "SIN-CVME-TIFGUN-EVR0:BEAMOK"))       
       
    
#Metadata
set_attribute("/", "Wire Scanner", prefix)    
set_attribute("/", "Scan Type", scan_type)    
set_attribute("/", "Range", scan_range)    
set_attribute("/", "Cycles", cycles)    
set_attribute("/", "Scan Points", n_shot)  
set_attribute("/", "Motor Velocity X", velocity_x*math.sqrt(2))  
set_attribute("/", "Wire Velocity X", velocity_x)
set_attribute("/", "Motor Velocity Y", velocity_y*math.sqrt(2))  
set_attribute("/", "Wire Velocity Y", velocity_y)
set_attribute("/", "Background Measures", bkgrd)
set_attribute("/", "BPMs", bpms)
set_attribute("/", "BLMs", blms)
set_attribute("/", "Bunch", bunch)

filename = get_exec_pars().path



#Stream creation
print "Starting stream..."
st = Stream("pulse_id", dispatcher)
for c in channels:
    if c[1].endswith("LOSS_SIGNAL_RAW"):
        st.addWaveform(c[0], c[1], int(100.0 / get_repetition_rate()), 0)   
    else:
        st.addScalar(c[0], c[1], int(100.0 / get_repetition_rate()), 0)    
st.initialize()
st.start()
st.waitCacheChange(10000)    #Wait stream be running before starting scan


class Timestamp(Readable):
    def read(self):        
        return st.getTimestamp()

        

   
#Pseudo-device returning the wire position
class w_pos(Readable):
    def read(self):
        return scanner.get_sel_wire_pos(st.getChild("m_pos").take())

#End of  scan checking
scan_complete, cur_cycle, wire = None, None, None
rec =None

def check_end_scan(record, scan):
    global scan_complete,cur_cycle
    global rec
    rec = record
    if record[4]<1:
        print "Data aquisition completed"
        scan_complete=True
        scan.abort()
        record.cancel() #So it won't be saved
    else:
        position = record[0]
        if record[3] != cur_cycle:
            cur_cycle = record[3]
            get_context().dataManager.splitScanData(scan)
            #if plt is not None: for s in plt.getAllSeries(): s.clear()
        if plt is not None:    
            for i in range (len(blms)):
                plt.getSeries(i).appendData(position, record[5 + i])                

scanner.park(wait=True)        
#Process background
def do_background():
    #Store Background
    if bkgrd>0:
        #scanner.park(wait=True)        
        set_exec_pars(group = "background")
        r = mscan (st, st.getReadables()[4:], bkgrd)    
        for i in range(len(r.getReadables())):
            d = r.getReadable(i)              
            try:
                path = get_exec_pars().group + "/data/"+ r.getReadables()[i].name
                set_attribute(path, "Mean", mean(d))            
                set_attribute(path, "Sigma", stdev(d) )   
            except: 
                pass                             

def set_blm_gain(scan_type, index):
    if SET_BLM_WS_MODE and len(blms)>0:    
         if scan_type == WireScanner.Set1:
            scan_type = (WireScanner.WireX1 if index == 0  else WireScanner.WireY1)
         if scan_type == WireScanner.Set2:
            scan_type = (WireScanner.WireX2 if index == 0  else WireScanner.WireY2)
         cfg_gain = get_setting(blms[0] + "GainWs" + scan_type)
         print "cfg_gain = " , cfg_gain
         if cfg_gain is not None:
             set_blm_ws_gain(blms[0],cfg_gain)    
             print "Set = " , blms[0]
     


#Scan   
def do_scan(index):    
    global scan_complete, cur_cycle, wire
    wire = "y" if (index==1) or (scan_type in [WireScanner.WireY1, WireScanner.WireY2]) else "x"
    if wire == "x":        
        scanner.set_velocity(velocity_x)
    else:
        scanner.set_velocity(velocity_y)
    
    set_exec_pars(group=wire+"_{count}", reset=True)               
    scanner.set_selection(get_scan_selection(scan_type, index))    
    if plt is not None:
        if wire == "x":        
            plt.getAxis(plt.AxisId.X).setRange(scan_range[0], scan_range[1])        
        else:
            plt.getAxis(plt.AxisId.X).setRange(scan_range[2], scan_range[3])    

    
    set_blm_gain(scan_type, index)
            
    scanner.init(wait=True)
    scanner.curr_cycl.write(0)
    scan_complete=False
    cur_cycle = 1.0

    if plt is not None:
        for s in plt.getAllSeries():
            s.clear()
        plt.removeMarker(None)
    try:     
        scanner.scan()        #scanner.waitState(State.Busy, 60000)  Not needed as stream  filter will make the wait
        st.getChild("scanning").waitValue(1.0, 10000)    
        #print st.getValues()     

        #TODO: Check what the problem is
        #mscan (st, [w_pos(),] + st.getReadables() + [Timestamp(),], -1, -1, take_initial = True, after_read = check_end_scan)                           

        l=[w_pos()] ; l.extend(st.getReadables()); l.append(Timestamp())
        print "Start scan"
        mscan (st, l, -1, -1, take_initial = True, after_read = check_end_scan)                           
        print "End scan"
        #tscan([w_pos()] + st.getReadables() + [Timestamp(),], 10, 0.5)
    except:        
        print sys.exc_info()[1]
        if not scanner.isReady():
            print "Aborting  scan"
            scanner.abort()
        if not scan_complete:
            raise
    finally:        
        #Combining data of multiple series
        #s=plt.getSeries(0)
        #indexes = sorted(range(len(s.x)),key=lambda x:s.x[x])
        #x,y = [s.x[x] for x in indexes], [s.y[x] for x in indexes]
        #plot(y, xdata = x)          
        print "Calculating"
        calculate()        
        print "Ok"
        img_file = os.path.abspath(filename + "_" + get_exec_pars().group[0:1] + ".png")
        time.sleep(0.1) #Give some time to plot finish (async)
        if plt is not None:
            plt.saveSnapshot(img_file, "png")
            snapshots.append(img_file)     
        print "Finished"

msg = ""
ret = []
def calculate():
    global msg
    stats, samples_val, samples_pos = [], [],[]
    for i in range(len(blms)):
        msg += "Wire " + wire + "  -  BLM " + str(i+1) + ":\n"
        try:          
            bg = get_attributes("background/data/blm" + str(i+1))["Mean"] if bkgrd>0 else 0.0
            samples = [[], [], [], [], [], []]   
            for cycle in range (cycles):  
                pos_path = wire+"_" + ("%04d" % (cycle+1)) + "/data/w_pos"  
                print "Loading ", pos_path
                pos = load_data(pos_path+"/value")
                path = wire+"_" + ("%04d" % (cycle+1)) + "/data/blm" + str(i+1)
                print "Loading ", path
                data = load_data(path+"/value")         
                print "OK"
                sp = data #blm_remove_spikes(data)
                sig = sp if bg is None else [v-bg for v in sp]   
                                    
                #print [com, rms]
                [off, amp, com, sigma] = profile_gauss_stats(pos, sig, off=None, amp=None, com=None, sigma=None)
                set_attribute(path, "Gauss COM", float("nan") if (com is None) else com)            
                set_attribute(path, "Gauss Sigma", float("nan") if (sigma is None) else sigma)                                            

                #[rms_com, rms_sigma] = profile_rms_stats(pos, sig,noise_std=0, n_sigma=3.5)
                [rms_com, rms_sigma] =  profile_rms_stats_with_estimate(pos, sig, com_estimate = com, window_size = sigma * 3.5)
                set_attribute(path, "RMS COM", float("nan") if (rms_com is None) else rms_com)            
                set_attribute(path, "RMS Sigma", float("nan") if (rms_sigma is None) else  rms_sigma)            


                if i==0: #Write channels for BLM 1
                     samples_val.extend(sig)
                     samples_pos.extend(pos)
        
                samples[0].append(rms_com);samples[1].append(rms_sigma);
                samples[2].append(com);samples[3].append(sigma);samples[4].append(amp);samples[5].append(off)
                #print [off, amp, com, sigma]
        
                #from mathutils import Gaussian
                #g = Gaussian(amp, com, sigma)
                #gauss = [g.value(v)+off for v in pos]
                #plot([data, sp, sig, gauss], ["data", "sp", "signal", "gauss", ], xdata = pos, title="Fit blm" + str(i+1) + " - " + str(cycle+1))         
                ret.extend([rms_com, rms_sigma, com, sigma, filename + "|"+ pos_path +"/value",  filename + "|"+ path +"/value"])  
        
            stats.append([])
            for sample in samples:
                sample =  [v for v in sample if v is not None]
                stats[i].append( (mean(sample), stdev(sample)) if len(sample)>0 else (float("nan"), float("nan")) )
            if plt is not None:    
                plt.addMarker(stats[i][2][0], None, "Gcom=" + "%.2f" % stats[i][2][0], plt.getSeries(i).color)
                plt.addMarker(stats[i][0][0], None, "Rcom=" + "%.2f" % stats[i][0][0], plt.getSeries(i).color.brighter())
                
            msg += "    RMS COM: " + "%.4f" % stats[i][0][0]  +  " +- " +"%.4f" % stats[i][0][1] + "\n"  #unichr(0x03C3) + "="
            msg += "    RMS Sigma: " + "%.4f" % stats[i][1][0]  +  " +- " + "%.4f" % stats[i][1][1] + "\n"
            msg += "    Gauss COM: " + "%.4f" % stats[i][2][0]  + " +- " + "%.4f" % stats[i][2][1] + "\n"
            msg += "    Gauss Sigma: " + "%.4f" % stats[i][3][0]  +  " +- " + "%.4f" % stats[i][3][1] + "\n"

            if i==0: #Write channels for BLM 1
                scanner.set_out_com(bunch,wire,stats[i][0][0])
                scanner.set_out_rms(bunch,wire,stats[i][1][0])
                scanner.set_out_mean(bunch,wire,stats[i][2][0])
                scanner.set_out_sigma(bunch,wire,stats[i][3][0] )                
                scanner.set_out_amp(bunch,wire,stats[i][4][0])                
                scanner.set_out_off(bunch,wire,stats[i][5][0])
                if len(samples_pos) > SAMPLE_CHANNEL_SIZE:
                    samples_pos = samples_pos[0:SAMPLE_CHANNEL_SIZE]
                else:
                    samples_pos += [SAMPLE_CHANNEL_EMPTY_VALUE] * (SAMPLE_CHANNEL_SIZE - len(samples_pos))
                if len(samples_val) > SAMPLE_CHANNEL_SIZE:
                    samples_val = samples_pos[0:SAMPLE_CHANNEL_SIZE]
                else:
                    samples_val += [SAMPLE_CHANNEL_EMPTY_VALUE] * (SAMPLE_CHANNEL_SIZE - len(samples_val))                
                scanner.set_out_pos(bunch,wire,samples_pos)
                scanner.set_out_samples(bunch,wire,samples_val)                      

                try:
                    gauss = Gaussian(stats[i][4][0], stats[i][2][0], stats[i][3][0])
                    gauss = [gauss.value(v)+stats[i][5][0] for v in samples_pos]                    
                except:      
                    traceback.print_exc()              
                    gauss = [0.0] * SAMPLE_CHANNEL_SIZE
                scanner.set_out_gauss(bunch,wire,gauss)                      
        except Exception, e:
            print >> sys.stderr, traceback.format_exc()
            msg += str(e)+ "\n"
                        

def get_scan_time():
    global bkgrd, scan_type, scan_range, velocity_x, velocity_y
    ret = 0
    if not scan_type in [WireScanner.WireY1, WireScanner.WireY2]:    
        ret +=  abs(scan_range[0] - scan_range[1])/velocity_x    #X SCAN
    if not scan_type in [WireScanner.WireX1, WireScanner.WireX2]:
        ret +=  abs(scan_range[2] - scan_range[3])/velocity_y    #Y SCAN
    ret += 2.0                                        #ACC/DEC
    ret *= cycles
    ret += bkgrd * (1.0/get_repetition_rate())        #BACK   
    print "Scan time = " + str(ret), 
    ret = ret * 2.0 + 10.0 #Tolernces
    print "; with tolerance = " + str(ret), 
    return ret
    
print "Starting scan..."         
try:     
    if SET_BLM_WS_MODE and len(blms)>0:
        start_blm_ws(blms[0], get_scan_time())                
        #TODO: Wait for stream variable indicate bllm is in ws mode
        print "Waiting for WS mode..."         
        #time.sleep(SET_BLM_WS_SETTLING_TIME)
        st.getChild("blm1_ws_mode").waitValue(1, SET_BLM_WS_BS_READBACK_TIMEOUT)
    print "Reading background..."         
    do_background()       
    st.setFilter(scanner.curr_cycl.get_name() + ">0 AND SIN-CVME-TIFGUN-EVR0:BEAMOK == 1")    #scanner.status_channels[0].get_name() + ">0"  not used because we must the transition to know when the finished        
    print "Executing scan 1..."         
    do_scan(0)
    if scan_type in [WireScanner.Set1, WireScanner.Set2]:        
        print "Executing scan 2..."         
        do_scan(1)                             
finally:
    if SET_BLM_WS_MODE and len(blms)>0:
        stop_blm_ws(blms[0])        
    print "Closing scanner"
    scanner.close()
    print "Closing stream"
    st.close()       
           
print msg

# save the entry in the logbook
if do_elog:
    if get_option("Generated data file:\n" + filename +"\n\n" + msg + "\n\n" + "Save to ELOG?", "YesNo") == "Yes":    
        log_msg = "Data file: " + filename
        log_msg = log_msg + "\nWire Scanner: " + prefix
        log_msg = log_msg + "\nScan Type: " + str(scan_type)
        log_msg = log_msg + "\nRange: " + str(scan_range)
        log_msg = log_msg + "\nCycles: " + str(cycles)
        log_msg = log_msg + "\nScan Points: " + str(n_shot)
        log_msg = log_msg + "\nWire Velocity X: " + str(velocity_x)
        log_msg = log_msg + "\nWire Velocity Y: " + str(velocity_y)
        log_msg = log_msg + "\nBackground Measures: " + str(bkgrd)
        log_msg = log_msg + "\nBPMs: " + str(bpms)
        log_msg = log_msg + "\nBLMs: " + str(blms)
        log_msg = log_msg + "\nBunch: " + str(bunch)
        
        log_msg = log_msg + "\n" + msg
        elog("Wire Scan", log_msg, snapshots)

set_exec_pars(open=False)
print ret
set_return(ret)