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socket_debug.py
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socket_debug.py
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# run from /home/apdlab/larpixv2/larpix-socket-testing
# after running env3
# cd ~/larpixv2/ ; source bin/activate
import subprocess,sys,os
import larpix
from larpix import Controller
#from larpix.io.zmq_io import ZMQ_IO
from larpix.io import PACMAN_IO
from larpix.logger.h5_logger import HDF5Logger
import time
import tkinter as tk
from tkinter import ttk
import h5py
import pandas as pd
import runpy
import simpleaudio as sa
import tcp_server_prod as tsp
import keyboard
#import t
#DumbFunc('another one')
sadSong = sa.WaveObject.from_wave_file('sounds/Sad_Trombone-Joe_Lamb-665429450.wav')
successSong = sa.WaveObject.from_wave_file('sounds/TaDaSoundBible.com-1884170640.wav')
doneSong = sa.WaveObject.from_wave_file('sounds/service-bell_daniel_simion.wav')
NumASICchannels = 64
def setv2channelmask():
DisabledChannels = [6,7,8,9,22,23,24,25,38,39,40,54,55,56,57]
for chan in DisabledChannels: TileChannelMask[chan]=0
TileChannelMask = [1] * NumASICchannels
#To enable only a few channels, set [0] above and list channel in EnabledChannels
# and uncomment the 2 lines below. To enable all channels do the reverse, set [1]
# and comment out the 2 lines below.
#EnabledChannels = [10,19,20,21,22,23,24,40]
#for chan in EnabledChannels: TileChannelMask[chan]=1
TileChannelMask
#[1, 1, 1, 1, 1, 1, 0, 0,
# 0, 0, 1, 1, 1, 1, 1, 1,
# 1, 1, 1, 1, 1, 1, 0, 0,
# 0, 0, 1, 1, 1, 1, 1, 1,
# 1, 1, 1, 1, 1, 1, 0, 0,
# 0, 1, 1, 1, 1, 1, 1, 1,
# 1, 1, 1, 1, 1, 1, 0, 0,
# 0, 0, 1, 1, 1, 1, 1, 1]
def init_controller():
c = Controller()
#c.io = ZMQ_IO('../configs/io/daq-srv1.json', miso_map={2:1})
c.io = PACMAN_IO(config_filepath='/home/apdlab/larpixv2/configs/io/pacman.json')
c.io.ping()
return c
def init_board(c,io_chan=1):
#c.load('../configs/controller/pcb-3_chip_info.json')
#c.load('../configs/controller/socket-board-v1.json')
if v2bState.get() == '0':
if io_chan==1:
c.load('/home/apdlab/larpixv2/configs/controller/v2_socket_channel_1.json')
elif io_chan==2:
c.load('/home/apdlab/larpixv2/configs/controller/v2_socket_channel_2.json')
elif io_chan==3:
c.load('/home/apdlab/larpixv2/configs/controller/v2_socket_channel_3.json')
elif io_chan==4:
c.load('/home/apdlab/larpixv2/configs/controller/v2_socket_channel_4.json')
else:
exit('bad IO channel specified')
elif v2bState.get() == '1':
_default_chip_id=2
_default_miso_ds = io_chan-1
_default_mosi = io_chan-1
#print('loading v2b json file')
c.add_chip(larpix.Key(1, io_chan, _default_chip_id),version='2b')
c.add_network_node(1, io_chan, c.network_names, 'ext', root=True)
c.add_network_link(1, io_chan, 'miso_us', ('ext',_default_chip_id), 0)
c.add_network_link(1, io_chan, 'miso_ds', (_default_chip_id,'ext'), _default_miso_ds)
c.add_network_link(1, io_chan, 'mosi', ('ext', _default_chip_id), _default_mosi)
'''
if io_chan==1:
c.load('/home/apdlab/larpixv2/configs/controller/v2b_socket_channel_1.json')
elif io_chan==2:
c.load('/home/apdlab/larpixv2/configs/controller/v2b_socket_channel_2.json')
elif io_chan==3:
c.load('/home/apdlab/larpixv2/configs/controller/v2b_socket_channel_3.json')
elif io_chan==4:
c.load('/home/apdlab/larpixv2/configs/controller/v2b_socket_channel_4.json')
else:
exit('bad IO channel specified')
'''
else :
exit('could not determine v2bState')
c.io.ping()
def measure_currents(c):
loop=0
looplimit=2
while loop<looplimit :
vddd_meas=c.io.get_vddd()
vdda_meas=c.io.get_vdda()
print('read vddd =',vddd_meas)
print('read vdda =',vdda_meas)
loop=loop+1
def powerdown_exit(c):
#Disable chip power and interface at end
# Disable Tile
c.io.disable_tile()
#zero supply voltages
c.io.set_vddd(0) # set vddd 0V
c.io.set_vdda(0) # set vdda 0V
exit()
def powerdown(c):
#Disable chip power and interface at end
# Disable Tile
c.io.disable_tile()
#zero supply voltages
c.io.set_vddd(0) # set vddd 0V
c.io.set_vdda(0) # set vdda 0V
def wait_here():
trash=input('Hit <ENTER> key to proceed')
#test flipping bits in config register and see that they configure
def test_config_registers(c,chip):
#print(chip.config)
#invert chip config (for many registers)
# CSA GAIN
flipmask=0b1
chip.config.csa_gain=flipmask^chip.config.csa_gain
# CSA BYPASS ENABLE
flipmask=0b1
chip.config.csa_bypass_enable=flipmask^chip.config.csa_bypass_enable
# BYPASS CAPS EN
flipmask=0b1
chip.config.bypass_caps_en=flipmask^chip.config.bypass_caps_en
# PERIODIC RESET CYCLES
flipmask=0xFF_FFFF
chip.config.periodic_reset_cycles=flipmask^chip.config.periodic_reset_cycles
for chan in range(0,NumASICchannels):
# Pixel Trim DAC
#print('{:05b}'.format(chip.config.pixel_trim_dac[chan]))
#flipmask=int('11111',2)
flipmask=0b1_1111
chip.config.pixel_trim_dac[chan]=flipmask^chip.config.pixel_trim_dac[chan]
#print('{:05b}'.format(chip.config.pixel_trim_dac[chan]))
# CSA ENABLE
flipmask=0b1
chip.config.csa_enable[chan]=flipmask^chip.config.csa_enable[chan]
# CSA BYPASS SELECT
flipmask=0b1
chip.config.csa_bypass_select[chan]=flipmask^chip.config.csa_bypass_select[chan]
# CSA MONITOR SELECT
flipmask=0b1
chip.config.csa_monitor_select[chan]=flipmask^chip.config.csa_monitor_select[chan]
# CSA TESTPULSE ENABLE
flipmask=0b1
chip.config.csa_testpulse_enable[chan]=flipmask^chip.config.csa_testpulse_enable[chan]
# CHANNEL MASK
flipmask=0b1
chip.config.channel_mask[chan]=flipmask^chip.config.channel_mask[chan]
# EXTERNAL TRIGGER MASK
flipmask=0b1
chip.config.external_trigger_mask[chan]=flipmask^chip.config.external_trigger_mask[chan]
# CROSS TRIGGER MASK
flipmask=0b1
chip.config.cross_trigger_mask[chan]=flipmask^chip.config.cross_trigger_mask[chan]
# PERIODIC TRIGGER MASK
flipmask=0b1
chip.config.periodic_trigger_mask[chan]=flipmask^chip.config.periodic_trigger_mask[chan]
#print(chip.config)
#exit()
c.write_configuration(chip.chip_key)
verified,returnregisters=c.verify_configuration(chip.chip_key)
#print(verified)
if verified == False : # try again
print(returnregisters)
verified,returnregisters=c.verify_configuration(chip.chip_key)
if verified == False : # exit
#Disable chip power and interface at end
print("Verify config failed with flipped config")
#powerdown(c)
return 2
#invert chip config (for many registers) (returns to original)
# CSA GAIN
flipmask=0b1
chip.config.csa_gain=flipmask^chip.config.csa_gain
# CSA BYPASS ENABLE
flipmask=0b1
chip.config.csa_bypass_enable=flipmask^chip.config.csa_bypass_enable
# BYPASS CAPS EN
flipmask=0b1
chip.config.bypass_caps_en=flipmask^chip.config.bypass_caps_en
# PERIODIC RESET CYCLES
flipmask=0xFF_FFFF
chip.config.periodic_reset_cycles=flipmask^chip.config.periodic_reset_cycles
for chan in range(0,NumASICchannels):
# Pixel Trim DAC
#print('{:05b}'.format(chip.config.pixel_trim_dac[chan]))
#flipmask=int('11111',2)
flipmask=0b1_1111
chip.config.pixel_trim_dac[chan]=flipmask^chip.config.pixel_trim_dac[chan]
#print('{:05b}'.format(chip.config.pixel_trim_dac[chan]))
# CSA ENABLE
flipmask=0b1
chip.config.csa_enable[chan]=flipmask^chip.config.csa_enable[chan]
# CSA BYPASS SELECT
flipmask=0b1
chip.config.csa_bypass_select[chan]=flipmask^chip.config.csa_bypass_select[chan]
# CSA MONITOR SELECT
flipmask=0b1
chip.config.csa_monitor_select[chan]=flipmask^chip.config.csa_monitor_select[chan]
# CSA TESTPULSE ENABLE
flipmask=0b1
chip.config.csa_testpulse_enable[chan]=flipmask^chip.config.csa_testpulse_enable[chan]
# CHANNEL MASK
flipmask=0b1
chip.config.channel_mask[chan]=flipmask^chip.config.channel_mask[chan]
# EXTERNAL TRIGGER MASK
flipmask=0b1
chip.config.external_trigger_mask[chan]=flipmask^chip.config.external_trigger_mask[chan]
# CROSS TRIGGER MASK
flipmask=0b1
chip.config.cross_trigger_mask[chan]=flipmask^chip.config.cross_trigger_mask[chan]
# PERIODIC TRIGGER MASK
flipmask=0b1
chip.config.periodic_trigger_mask[chan]=flipmask^chip.config.periodic_trigger_mask[chan]
c.write_configuration(chip.chip_key)
# Global Threshold Has to be done when channels already masked off or floods the controller.
flipmask=0xFF
chip.config.threshold_global=flipmask^chip.config.threshold_global
c.write_configuration(chip.chip_key)
verified,returnregisters=c.verify_configuration(chip.chip_key)
#print(verified)
if verified == False : # try again
print(returnregisters)
verified,returnregisters=c.verify_configuration(chip.chip_key)
if verified == False : # exit
#Disable chip power and interface at end
print("Verify config failed with restored config")
#powerdown(c)
return 1
# Global Threshold
flipmask=0xFF
chip.config.threshold_global=flipmask^chip.config.threshold_global
print("config with flipped bits succeeded")
return 0
def init_chips(c):
#zero supply voltages
c.io.set_vddd(0) # set vddd 0V
c.io.set_vdda(0) # set vdda 0V
time.sleep(1)
#Set correct voltages
c.io.set_vddd() # set default vddd (~1.8V)
c.io.set_vdda() # set default vdda (~1.8V)
# Disable Tile
c.io.disable_tile()
# Enable Tile
c.io.enable_tile()
# measure_currents and voltage
vddd,iddd = c.io.get_vddd()[1]
vdda,idda = c.io.get_vdda()[1]
print('VDDD:',vddd,'mV')
print('IDDD:',iddd,'mA')
print('VDDA:',vdda,'mV')
print('IDDA:',idda,'mA')
_uart_phase = 0
for ch in range(1,5):
c.io.set_reg(0x1000*ch + 0x2014, _uart_phase)
#print('set phase:',_uart_phase)
#reset larpix chips [set sw_rst_cycles to something long, i.e. 256,1024,
#set sw_rst_trig to 1, set sw_rst_trig to 0]
#(this issues hard reset and syncs the pacman and larpix clocks)
c.io.reset_larpix(length=10240)
# resets uart speeds on fpga
#print('c.network.items()= ',c.network.items())
#if v2bState.get() == '0':
for io_group, io_channels in c.network.items():
for io_channel in io_channels:
print('set uart speed on channel',io_channel,'...')
c.io.set_uart_clock_ratio(io_channel, 2, io_group=io_group)
# First bring up the network using as few packets as possible
c.io.group_packets_by_io_group = False # this throttles the data rate to avoid FIFO collisions
c.network.items()
#if False:
for io_group, io_channels in c.network.items():
#io_channels
for io_channel in io_channels:
print("io_group,io_channel:",io_group,",",io_channel)
c.init_network(io_group, io_channel,differential='True')
#if v2bState.get() == '0':
#c.init_network(io_group, io_channel,differential='True')
#if v2bState.get() == '1':
#c.init_network(io_group, io_channel,differential=True)
print('Finished init_network')
if False: # A test for success of making init_network
io_group=1
io_channel=4
print("io_group,io_channel:",io_group,",",io_channel)
c.init_network(io_group, io_channel)
#print(list(c.network[1][4]['miso_ds'].edges()))
#print(list(c.network[1][4]['miso_us'].edges()))
#print(list(c.network[1][4]['mosi'].edges()))
#exit()
# Brooke Power_up_network.py
if v2bState.get() == '1' :
#c = larpix.Controller()
#print('here')
#c.io = larpix.io.PACMAN_IO(relaxed=True)
#print('make network')
#if controller_config is None:
# c.add_chip(larpix.Key(1, _default_io_channel, _default_chip_id),version='2b')
# c.add_network_node(1, _default_io_channel, c.network_names, 'ext', root=True)
# c.add_network_link(1, _default_io_channel, 'miso_us', ('ext',_default_chip_id), 0)
# c.add_network_link(1, _default_io_channel, 'miso_ds', (_default_chip_id,'ext'), _default_miso_ds)
# c.add_network_link(1, _default_io_channel, 'mosi', ('ext', _default_chip_id), _default_mosi)
#else:
# c.load(controller_config)
#if reset:
# c.io.reset_larpix(length=10240)
# resets uart speeds on fpga
#for io_group, io_channels in c.network.items():
# for io_channel in io_channels:
# c.io.set_uart_clock_ratio(io_channel, clk_ctrl_2_clk_ratio_map[0], io_group=io_group)
''' Was forced in Brooke's startup. No longer needed, as controller.py should do it.
for chip_key, chip in reversed(c.chips.items()):
c[chip_key].config.enable_piso_downstream = [0,0,0,1]
c[chip_key].config.i_tx_diff3=0
c[chip_key].config.tx_slices3=15
c.write_configuration(chip_key,125)
c.write_configuration(chip_key,'i_tx_diff3')
c.write_configuration(chip_key,'tx_slices3')
'''
#print('Brooke power up complete')
#print('Writing configuration')
#while True:
for chip in c.chips.values(): c.write_configuration(chip.chip_key)
for chip in c.chips.values():
verified,returnregisters=c.verify_configuration(chip.chip_key)
print(verified,returnregisters)
try:
while True: #Used during setup, not needed regularly
#while verified == False:
chip = list(c.chips.values())[0] # selects 1st chip in chain
print('Trying again on ',chip,' enter <CTRL-C> to quit')
#print('with config= ',chip.config)
#c.io.reset_larpix(length=10240)
c.write_configuration(chip.chip_key)
verified,returnregisters=c.verify_configuration(chip.chip_key)
print(verified)
print('Tried at ',time.strftime("%H:%M:%S"))
except KeyboardInterrupt:
pass
if False : #io_channel == 1: #Used during setup, runs prbs serial out on all uart channels not needed regularly
#while verified == False:
chip = list(c.chips.values())[0] # selects 1st chip in chain
c[chip.chip_key].config.enable_posi = [1,1,1,1]
c[chip.chip_key].config.enable_piso_downstream = [1,1,1,1]
c[chip.chip_key].config.test_mode_uart0 = 1
c[chip.chip_key].config.test_mode_uart1 = 1
c[chip.chip_key].config.test_mode_uart2 = 1
c[chip.chip_key].config.test_mode_uart3 = 1
c[chip.chip_key].config.v_cm_lvds_tx0 = 7
c[chip.chip_key].config.v_cm_lvds_tx1 = 7
c[chip.chip_key].config.v_cm_lvds_tx2 = 7
c[chip.chip_key].config.v_cm_lvds_tx3 = 7
c[chip.chip_key].config.tx_slices0 = 15
c[chip.chip_key].config.tx_slices1 = 15
c[chip.chip_key].config.tx_slices2 = 15
c[chip.chip_key].config.tx_slices3 = 15
c[chip.chip_key].config.i_tx_diff0=0
c[chip.chip_key].config.i_tx_diff1=0
c[chip.chip_key].config.i_tx_diff2=0
c[chip.chip_key].config.i_tx_diff3=0
print('Trying again on ',chip)
print('with config= ',chip.config)
#c.io.reset_larpix(length=10240) #Wipes config, don't do it here.
c.write_configuration(chip.chip_key)
#verified,returnregisters=c.verify_configuration(chip.chip_key)
#print(verified,returnregisters)
print('Tried at ',time.strftime("%H:%M:%S"))
print('Running prbs for debugging, will exit after')
#time.sleep(20)
wait_here()
exit()
if v2bState.get() == '0':
# Configure the IO for a slower UART and differential signaling
c.io.double_send_packets = True # double up packets to avoid 512 bug when configuring
for io_group, io_channels in c.network.items():
for io_channel in io_channels:
chip_keys = c.get_network_keys(io_group,io_channel,root_first_traversal=False)
chip_keys
for chip_key in chip_keys:
c[chip_key].config.clk_ctrl = 1
c[chip_key].config.enable_miso_differential = [1,1,1,1]
c.write_configuration(chip_key, 'enable_miso_differential')
c.write_configuration(chip_key, 'clk_ctrl')
#if v2bState.get() == '0':
for io_group, io_channels in c.network.items():
for io_channel in io_channels:
c.io.set_uart_clock_ratio(io_channel, 4, io_group=io_group)
c.io.double_send_packets = False
c.io.group_packets_by_io_group = True
#for chip in c.chips.values(): print(chip.config)
# Stolen from Brooke, power_up_network.py
if False:
for chip_key, chip in reversed(c.chips.items()):
c[chip_key].config.enable_piso_downstream = [0,0,0,1]
c[chip_key].config.i_tx_diff3=0
c[chip_key].config.tx_slices3=15
c.write_configuration(chip_key,125)
c.write_configuration(chip_key,'i_tx_diff3')
c.write_configuration(chip_key,'tx_slices3')
print('Writing configuration')
#while True:
for chip in c.chips.values(): c.write_configuration(chip.chip_key)
for chip in c.chips.values(): c.verify_configuration(chip.chip_key)
chip = list(c.chips.values())[0] # selects 1st chip in chain
#chip = list(c.chips.values())[1] # selects 2nd chip in chain
#chip = list(c.chips.values())[2] # selects 3rd chip in chain
#chip = list(c.chips.values())[3] # selects 3rd chip in chain
print(chip)
print(chip.chip_key)
#print(chip.config)
c.write_configuration(chip.chip_key)
verified,returnregisters=c.verify_configuration(chip.chip_key)
if verified == False : # try again
print(verified,returnregisters)
verified,returnregisters=c.verify_configuration(chip.chip_key)
if verified == False : # exit
print(verified,returnregisters)
#Disable chip power and interface at end
print('Configuration failed, exiting')
#powerdown(c)
return
print('Finished configuring chip ',chip)
return chip
def enable_channel(chan):
# Configure one channel to be on.
chip.config.channel_mask = [1] * NumASICchannels # Turn off all channels
chip.config.channel_mask[chan]=0 # turn ON this channel
c.write_configuration(chip.chip_key)
c.verify_configuration(chip.chip_key)
# Set global threshold
def setGlobalThresh(c,chip,Thresh=50):
#print(chip.chip_key)
#print(id(chip.config))
chip.config.threshold_global=Thresh
c.write_configuration(chip.chip_key)
#c.verify_configuration(chip.chip_key)
# Turn on a series of channels (a list would be better) on analog
# monitor and loop to the next one every 5 seconds.
def AnalogDisplayLoop(c,chip,firstChan=0,lastChan=NumASICchannels-1):
for chan in range(firstChan,lastChan+1):
AnalogDisplay(c,chip,chan)
time.sleep(10)
wait_here()
# set a really long periodic reset (std=4096, this is 1M)
#chip.config.reset_cycles=1000000
# Turn on and display one channel on analog monitor
def AnalogDisplay(c,chip,chan):
# Configure one channel to be on.
chip.config.channel_mask = [1] * NumASICchannels # Turn off all channels
chip.config.channel_mask[chan]=0 # turn ON this channel
# Enable analog monitor on one channel at a time
c.enable_analog_monitor(chip.chip_key,chan)
print("Running Analog mon on channel ",chan)
c.write_configuration(chip.chip_key)
c.verify_configuration(chip.chip_key)
#time.sleep(5) # move to the loop
#c.disable_analog_monitor(chip.chip_key)
# Loop over approximately all channels and output analog mon for 5 seconds.
#AnalogDisplayLoop(0,NumASICchannels-1)
# Capture Data for channels in sequence
def ReadChannelLoop(c,chip,firstChan=0,lastChan=NumASICchannels-1,monitor=0):
#sleeptime=0.1
#c.start_listening()
#for chan in reversed(range(firstChan,lastChan+1)): # used for a test
for chan in range(firstChan,lastChan+1):
#print("Running chip ",chip," chan ",chan)
if TileChannelMask[chan]!=0:
ReadChannel(c,chip,chan,monitor)
#time.sleep(sleeptime)
#c.stop_listening()
chip.config.channel_mask = [1] * NumASICchannels # Turn off all channels
chip.config.periodic_trigger_mask = [1] * NumASICchannels # Turn off all channels
c.write_configuration(chip.chip_key)
def ReadChannel(c,chip,chan,monitor=0):
# Configure one channel to be on.
print("Running chip ",chip," chan ",chan)
chip.config.channel_mask = [1] * NumASICchannels # Turn off all channels
chip.config.channel_mask[chan]=0 # turn ON this channel
chip.config.periodic_trigger_mask = [1] * NumASICchannels
chip.config.periodic_trigger_mask[chan]=0 # turn ON this channel
#if chan < NumASICchannels-1 :
# chip.config.channel_mask[chan+1]= not TileChannelMask[chan+1]
#if chan < NumASICchannels-2 :
# chip.config.channel_mask[chan+2]= not TileChannelMask[chan+2]
#if chan < NumASICchannels-3 :
# chip.config.channel_mask[chan+3]= not TileChannelMask[chan+3]
#for thischan in range(0,NumASICchannels): # turn ON ALL channels (test 20210331)
# chip.config.channel_mask[thischan] = not TileChannelMask[thischan]
if monitor==1:
# Enable analog monitor on channel
c.enable_analog_monitor(chip.chip_key,chan)
print("Running Analog mon for Pulser on channel ",chan)
c.write_configuration(chip.chip_key)
print('***************************************')
print('**** READ CHANNEL ****')
print('***************************************')
#print(chip.config)
#c.verify_configuration(chip.chip_key)
loop=0
looplimit=1
while loop<looplimit :
# Read some Data (this also delays a bit)
c.run(0.1,'test')
#print(c.reads[-1])
print("read ",len(c.reads[-1])," packets")
wait_here()
loop=loop+1
def get_baseline_selftrigger(c,chip):
# Capture Baseline for all channels one by one
# Turn on periodic_reset
chip.config.enable_periodic_reset = 1
# Reduce global threshold to get baseline data
chip.config.threshold_global=5
# Extend the time for conversion as long as possible
#chip.config.sample_cycles=150
#chip.config.sample_cycles=1 #(set to default starting 2/21/2020)
c.write_configuration(chip.chip_key)
c.verify_configuration(chip.chip_key)
subprocess.run(["rm","testing.h5"])
#logger declared and switched enabledc.
c.logger = HDF5Logger("testing.h5", buffer_length=1000000)
#c.logger = HDF5Logger("testing.h5", buffer_length=10000)
c.logger.enable()
c.logger.is_enabled()
c.verify_configuration(chip.chip_key)
print(chip.config)
ReadChannelLoop(c,chip,0,NumASICchannels-1,0)
print("the end")
c.logger.disable()
#c.logger.flush()
#c.logger.close()
import socket_baselines
def get_baseline_periodicselftrigger(c,chip):
# Capture Baseline for all channels one by one
# Turn on periodic_reset
chip.config.enable_periodic_reset = 1
#chip.config.periodic_reset_cycles = 1000000
# Reduce global threshold to get baseline data
chip.config.threshold_global=255
# Extend the time for conversion as long as possible
#chip.config.sample_cycles=150
#chip.config.sample_cycles=1 #(set to default starting 2/21/2020)
# for v2 sample_cycles -> adc_hold_delay
#chip.config.adc_hold_delay=150
#chip.config.adc_hold_delay=1 #(set to default starting 2/21/2020)
# enable periodic trigger
chip.config.enable_periodic_trigger=1
chip.config.periodic_trigger_mask= [1] * NumASICchannels # Turn off all channels
# swapped line above 0 (on) to 1 (off) on 17-NOV-2021 LMM
# I suspect this was causing the leakage. Different behavior v2 and v2b with masking.
chip.config.enable_hit_veto = 0
# set trigger period (100ns*period_trigger_cycles)
chip.config.periodic_trigger_cycles=1000 # 1k = 0.1ms
#chip.config.periodic_trigger_cycles=10000 # 10k = 1ms
#chip.config.periodic_trigger_cycles=20000 # 20k = 2ms
#chip.config.periodic_trigger_cycles=100000 # 100k = 10ms
#chip.config.periodic_trigger_cycles=7500000 # 750k = 75ms
#chip.config.periodic_trigger_cycles=1000000 # 1000k = 100ms
c.write_configuration(chip.chip_key)
c.verify_configuration(chip.chip_key)
subprocess.run(["rm","testing.h5"])
#logger declared and switched enabled.
c.logger = HDF5Logger("testing.h5", buffer_length=1000000)
#c.logger = HDF5Logger("testing.h5", buffer_length=10000)
c.logger.enable()
c.logger.is_enabled()
#c.verify_configuration(chip.chip_key)
#print(chip.config)
print("Starting ReadChannelLoop...")
Monitor = 1 # display analog mon (1) or not (0)
ReadChannelLoop(c,chip,0,NumASICchannels-1,Monitor)
print("the end")
textBox.config(bg="yellow")
doneSong.play()
window.update()
c.logger.disable()
#c.logger.flush()
#c.logger.close()
# turn off periodic trigger channels
chip.config.periodic_trigger_mask= [1] * NumASICchannels
chip.config.enable_periodic_trigger=0
c.write_configuration(chip.chip_key)
#import socket_baselines
os.environ['socket_PlotBaselineChannels']=LoadHTMLplotsState.get()
runpy.run_module(mod_name='socket_baselines')
nBadBaselineChannels=os.getenv('socket_BadBaselineChannels')
print(nBadBaselineChannels)
if int(nBadBaselineChannels) == 0 :
textBox.config(bg="green")
successSong.play()
window.update()
else :
textBox.config(bg="red") # flashing?
sadSong.play()
window.update()
return nBadBaselineChannels
def get_baseline_periodicexttrigger(c,chip):
# Capture Baseline for all channels
# Turn on periodic_reset
chip.config.enable_periodic_reset = 1
# Reduce global threshold to get baseline data
chip.config.threshold_global=255
# Extend the time for conversion as long as possible
#chip.config.sample_cycles=255
# No more sample_cycles in v2?
#chip.config.sample_cycles=1 #(set to default starting 2/21/2020)
c.write_configuration(chip.chip_key)
c.verify_configuration(chip.chip_key)
subprocess.run(["rm","testing2.h5"])
chip.config.channel_mask = [0] * NumASICchannels # Turn ON all channels
chip.config.external_trigger_mask = [0] * NumASICchannels # Turn ON all channels
c.write_configuration(chip.chip_key)
c.verify_configuration(chip.chip_key)
print(chip.config)
#logger declared and switched enabledc.
c.logger = HDF5Logger("testing2.h5", buffer_length=1000000)
#c.logger = HDF5Logger("testing.h5", buffer_length=10000)
c.logger.enable()
c.logger.is_enabled()
c.run(10,'test')
print("read ",len(c.reads[-1]))
print("the end")
c.logger.disable()
#c.logger.flush()
#c.logger.close()
import socket_baselines2
def PulseChannelLoop(firstChan=0,lastChan=NumASICchannels-1,amp=0,monitor=0):
for chan in range(firstChan,lastChan+1):
PulseChannel(chan,amp,monitor)
def PulseChannel(chan,amp=0,monitor=0):
# Configure one channel to be on.
chip.config.channel_mask = [1] * NumASICchannels # Turn off all channels
chip.config.channel_mask[chan]=0 # turn ON this channel
if (monitor==1):
# Enable analog monitor on channel
c.enable_analog_monitor(chip.chip_key,chan)
print("Running Analog mon for Pulser on channel ",chan)
c.write_configuration(chip.chip_key)
#c.verify_configuration(chip.chip_key)
loop=0
looplimit=5
while loop<looplimit :
c.enable_testpulse(chip.chip_key, [chan], start_dac=200)
c.issue_testpulse(chip.chip_key, amp, min_dac=100)
# Read some Data (this also delays a bit)
#c.run(1,'test')
print(c.reads[-1])
loop=loop+1
def get_charge_injection():
# Run some pulser
# Turn on periodic_reset
chip.config.enable_periodic_reset = 1
# Reduce global threshold to get some data
chip.config.global_threshold=50
# Extend the time for conversion as long as possible
chip.config.sample_cycles=255
chip.config.channel_mask = [1] * NumASICchannels # Turn off all channels
chip.config.external_trigger_mask = [1] * NumASICchannels # Turn OFF ext trig all channels
c.write_configuration(chip.chip_key)
c.verify_configuration(chip.chip_key)
PulseChannelLoop(0,NumASICchannels-1,10,0)
def get_leakage_data():
# This part is not quite ready yet.
# Still not ready 20200212 - required thresh values depend on channel
# and you only want ot do it on channels that are good so far.
# Turn off periodic_reset
chip.config.enable_periodic_reset = 0 # turn off periodic reset
chip.config.channel_mask = [1] * NumASICchannels # Turn off all channels
c.write_configuration(chip.chip_key)
c.verify_configuration(chip.chip_key)
for thresh in [25,27,30,35]:
setGlobalThresh(thresh)
outfile = "testing" + str(thresh) + ".h5"
print("Writing ",outfile)
#logger declared and switched enabledc.
c.logger = HDF5Logger(outfile, buffer_length=1000000)
#c.logger = HDF5Logger("testing.h5", buffer_length=10000)
c.logger.enable()
c.logger.is_enabled()
# Configure one channel to be on.
for chan in range(NumASICchannels):
print("running channel ",chan)
if socket_baselines.mean[chan] > 240 or socket_baselines.sdev[chan] < 2 : continue
chip.config.channel_mask = [1] * NumASICchannels # Turn off all channels
chip.config.channel_mask[chan]=0 # turn ON this channel
c.write_configuration(chip.chip_key)
c.verify_configuration(chip.chip_key)
# Read some Data (this also delays a bit)
c.run(1,'test')
print(c.reads[-1])
print("the end")
c.logger.disable()
#c.logger.flush()
c.logger.close()
def get_ThreshLevels(c,chip):
#ChipSN = mychipIDBox[0].get()
tempstatus = h5py.File("CurrentRun.tmp",mode='r')
dset = tempstatus['CurrentRun']
ChipSN = dset.attrs['ChipSN']
tempstatus.close()
#open hdf5 output file
#ThreshDataFile = h5py("RateVsThreshData.h5",mode='a')
RateThreshFrame = pd.DataFrame(columns = ['runtime','thresh','numsamples','dt','ChanName','Chan','ChipSN'])
runtime=time.time()
for chan in range(NumASICchannels):
if TileChannelMask[chan]==1:
print("running channel ",chan)
chip.config.channel_mask = [1] * NumASICchannels # Turn off all channels
chip.config.channel_mask[chan]=0 # turn ON this channel
c.write_configuration(chip.chip_key)
c.verify_configuration(chip.chip_key)
thresh=128
step = 16
rate = 0
sampleTime = 0.30 # if you use smaller, need to use packet times for better precision
stepthresh = 10
while rate < 300 and ( thresh >= 1 and step >= 2 ) :
setGlobalThresh(c,chip,thresh)
# Read some Data (this also delays a bit)
c.run(sampleTime,'test')
#numsamples=len(c.reads[-1]['packet_type'==0])
numsamples=len(c.reads[-1])
print("Read ",numsamples," samples")
# find duration of samples (first/last)
sampleIter=0
firstTime=0
lastTime=0
while sampleIter<numsamples :
#if c.reads[-1].packets[sampleIter].chip_key != None :
if c.reads[-1].packets[sampleIter].packet_type == 0 :
#print(c.reads[-1].packets[sampleIter].packet_type)
if c.reads[-1].packets[sampleIter].channel_id == chan :
firstTime = c.reads[-1].packets[sampleIter].timestamp
sampleIter=numsamples # To end the loop
#print("End time at ",numsamples-sampleIter-1)
sampleIter=sampleIter+1
sampleIter=0
while sampleIter<numsamples :
#if c.reads[-1].packets[sampleIter].packet_type == Packet_v2.DATA_PACKET :
#if c.reads[-1].packets[numsamples-sampleIter-1].chip_key != None :
if c.reads[-1].packets[numsamples-sampleIter-1].packet_type == 0 :
#print(c.reads[-1].packets[numsamples-sampleIter-1].packet_type)
if c.reads[-1].packets[numsamples-sampleIter-1].channel_id == chan :
lastTime = c.reads[-1].packets[numsamples-sampleIter-1].timestamp
sampleIter=numsamples # to end the loop
#print("End time at ",numsamples-sampleIter-1)
sampleIter=sampleIter+1
dt = lastTime-firstTime
if dt < 0 : dt =dt+2**24
if dt == 0 : dt = dt+sampleTime*5E6
dt = dt / 5E6
#print(dt,"<- delta and first time: ",firstTime,"Last time: ",lastTime)
#rate = numsamples/sampleTime
rate = numsamples/dt
print("Channel ",chan," Thresh ",thresh," Rate ",rate)
textchan = 'ch{:02d}'.format(chan)
RateThreshFrame=RateThreshFrame.append({'runtime':runtime,'thresh':thresh,'numsamples':numsamples,
'dt':dt,'ChanName':textchan,'Chan':chan,'ChipSN':ChipSN},ignore_index=True)
print('len(RateThreshFrame.index)=',len(RateThreshFrame.index))
thresh = thresh - step
if rate > stepthresh and step > 2 :
thresh = thresh + step +step
step = int(step/2)
if step < 4 : sampleTime=1.0
if rate < 100 : stepthresh = stepthresh + stepthresh
setGlobalThresh(c,chip,255)
#print("c.reads is ",len(c.reads)," long")
#print("c.reads is ",sys.getsizeof(c.reads)," long")
c.reads.clear()
#print("c.reads is ",len(c.reads)," long")
#print("c.reads is ",sys.getsizeof(c.reads)," long")
print("the end") # of chan loop
#summaryFrame.to_csv("t.csv",mode='a',header=True)
#RateThreshFrame.to_csv("RateThresh.csv",mode='a',header=False)
RateThreshFrame.to_hdf("RateThresh.h5",mode='a',key='RateVsThreshV1')
def RunControl():
HOST = '192.168.12.138' # apdlab pc interface address
PORT = 38630 # Port to listen on (non-privileged ports are > 1023)
Hello='H\r'
Start='S\r'
Ready='R\r'
EOL='EOL\r'
Result0='0\r'
Result1='1\r'
Result2='2\r'
Result3='3\r'
Result4='4\r'
Result5='5\r'
Result6='6\r'
Result7='7\r'
Result8='8\r'
Result9='9\r'
if UseTCPIPControlState.get() == '0' : # if TCPIPControl is not checked, just RunTests()
totalBadChannels = RunTests() # Single chip test mode
# Increment SN if check box enabled
if SNAutoIncrement.get() == '1' :
SNUp()
else :
window.children['!frame'].children['!button'].configure(text='Running TCPIPcontrol...')
#tsp.DumbFunc('in RunControl')
# Start the server
print('Starting TCPIP server connection')
conn, addr = tsp.OpenSocketConn(HOST,PORT)
while True :
message = tsp.CheckSocketForData(conn)
if message == bytes(Hello,"utf-8") :
print('Received Hello from Chip Handler')
#Send Ready (or EOL) back
print('Sending Ready to Chip Handler')
conn.sendall(bytes(Ready,"utf-8"))
# Load a chip
# Wait for Start
message = tsp.CheckSocketForData(conn)
if message == bytes(Start,"utf-8") :
print('Received Start from Chip Handler')
#Send Ready (or EOL) back
print('Starting tests')
# Run Tests
ResultNum=RunTests()
#time.sleep(5)
#ResultNum=0 # Fake result for testing
# Send results to Chip Handler
if ResultNum == 0 :
print('Result was ',ResultNum,' sending ',Result1)
conn.sendall(bytes(Result1,"utf-8"))
if ResultNum < 0 :
print('Result was ',ResultNum,' sending ',Result3)
conn.sendall(bytes(Result3,"utf-8"))
else:
print('Result was ',ResultNum,' sending ',Result2)
conn.sendall(bytes(Result2,"utf-8"))
# Get another chip (what happens after 180 tests?)
# Increment SN if check box enabled
if SNAutoIncrement.get() == '1' :
SNUp()
# Close the server
return
#def RunTests(c,chip):
def RunTests():
#Change run button to running
window.children['!frame'].children['!button'].configure(text='Running...')
#make text box red
textBox.config(bg="red")
# grey out selection boxes
for myiter in testCheckframe.children:
# print('disabling ', myiter)
testCheckframe.children[myiter].state(['disabled'])
window.update()
if v2bState.get() == '0': setv2channelmask()
print("Running tests for Chip SN: ",mychipIDBox[0].get())
ChipSN=mychipIDBox[0].get()
testID=0
currentTests=[]
for test in buttonVars:
currentTests.append(buttonVars[testID].get())
testID=testID+1