def main():
# this setup stuff should eventually go into the data base
phi_node_dict = {}
node_prefix = "payload.mu_deserialization."
offsets = []
node_names = []
for j in range(2): # for both endcap+ and overlap+ 60 degrees sectors
for i in range(6): # 6 channels each
offsets.append(i*96 + 24)
for i in range(12): # for barrel 12*30 degree wedges
offsets.append((i * 48 + 576 - 24) % 576)
for j in range(2): # for both endcap- and overlap- 60 degrees sectors
for i in range(6): # 6 channels each
offsets.append(i*96 + 24)
for quad in range(9):
for channel in range(4):
node_name = node_prefix + "mu_quad{q}.phi_offset_{ch}".format(q=quad, ch=channel)
phi_node_dict[node_name] = offsets[quad*4+channel]
node_names.append(node_name)
opts = parse_options()
uhal.setLogLevelTo(uhal.LogLevel.ERROR)
cm = uhal.ConnectionManager("file://${MP7_TESTS}/etc/mp7/connections-test.xml")
board = cm.getDevice(opts.board)
board.getNode('ctrl.id').read()
try:
board.dispatch()
except:
# print something here when if times out
print 'MP7 access failed (name:', board.id(), 'uri:', board.uri(), ')'
sys.exit(-1)
if opts.mode == "read":
values = {}
for node, value in phi_node_dict.iteritems():
values[node] = board.getNode(node).read()
try:
board.dispatch()
except:
print 'read failed'
sys.exit(-1)
for node in node_names:
print node, " = ", hex(values[node]), " .. should be", hex(phi_node_dict[node])
return
if opts.mode == "write":
for node, value in phi_node_dict.iteritems():
board.getNode(node).write(value)
try:
board.dispatch()
except:
print 'write failed'
sys.exit(-1)
print "wrote values to phi offset registers."
def getinfo():
uhal.setLogLevelTo(uhal.LogLevel.WARNING)
cm = uhal.ConnectionManager(
'file://${TIMING_SHARE}/config/etc/connections.xml')
device = cm.getDevice('OVLD_TUN')
readMAC(device)
def init_board(library, deviceaddress, xmlfile):
global board
uhal.setLogLevelTo(uhal.LogLevel.INFO)
board = uhal.getDevice("glib",
"ipbusudp-2.0://" + deviceaddress + ":50001",
"file://" + xmlfile)
board.getClient().setTimeoutPeriod(10000)
nodeslist = board.getNodes()
deletelist = []
return nodeslist
def run(board, sdfile):
if not sdfile:
logging.error(
'No firmware image given. Listing image names on uSD...')
hlp.listFilesOnSD(board)
else:
logging.info("Rebooting FPGA with firmware image %s..." % sdfile)
uhal.setLogLevelTo(uhal.LogLevel.FATAL)
board.rebootFPGA(sdfile)
uhal.setLogLevelTo(uhal.LogLevel.ERROR)
def __init__(self,name,go=True,freq=100,odir="blah"):
self._name = name;
self._go = go;
self._freq = freq;
self._odir = odir;
self._manager = uhal.ConnectionManager("file://../data/vipram_connections.xml");
self._hw = self._manager.getDevice("Mezz1")
uhal.setLogLevelTo( uhal.LogLevel.ERROR )
self._ident = self._hw.getNode("VipMEM.Ident").read();
self._vers = self._hw.getNode("VipMEM.FWver").read();
self._hw.dispatch();
print "Firmware identity = ", hex(self._ident), ", firmware version = ", self._vers;
self._iSteps = 0;
self._fSteps = 32;
self._stepIncrement = 32;
self._blockSize = 1024;
###################
## define registers
self._registers = [];
self._registers.append( 'CheckData' ); # CheckData
for i in range(32-1,-1,-1): self._registers.append( 'Out'+str(i) );
self._registers.append( 'ReqL0' );
self._registers.append( 'Miss2' );
self._registers.append( 'Miss1' );
self._registers.append( 'Miss0' );
self._registers.append( 'RunMode' );
self._registers.append( 'Primary' );
self._registers.append( 'Latch' );
self._registers.append( 'EvRearm' );
for i in range(7): self._registers.append( "RA"+str(i) );
for i in range(5): self._registers.append( "CA"+str(i) );
for i in range(1,16): self._registers.append( "A"+str(i) );
self._registers.append( "A0" );
for i in range(1,16): self._registers.append( "B"+str(i) );
self._registers.append( "B0" );
for i in range(1,16): self._registers.append( "C"+str(i) );
self._registers.append( "C0" );
for i in range(1,16): self._registers.append( "D"+str(i) );
self._registers.append( "D0" );
print "registers size = ", len(self._registers);
###################
# power numbers
self._i_dvdd = [];
self._i_vdd = [];
self._i_prech = [];
self._difftimes = [];
def GetUhalDevice(LogLevel = uhal.LogLevel.WARNING):
uhal.setLogLevelTo(LogLevel)
global uhalDevice
if uhalDevice == 0:
f = "addresses.xml"
if not FileExists(f):
f = "common/addresses.xml"
if not FileExists(f):
f = "../common/addresses.xml"
if not FileExists(f):
print Error_("Could not find file \"addresses.xml\"")
raise
uhalDevice = uhal.getDevice("fpga", "ipbusudp-2.0://134.158.152.64:50001", "file://"+f)
# print "Creating device"
return uhalDevice
def useUhalParser(test_xml, HDLPath, regMapTemplate, pkgTemplate="",
verbose=False, debug=False, yml2hdl=False):
# configure logger
global log
log = logging.getLogger("main")
formatter = logging.Formatter('%(name)s %(levelname)s: %(message)s')
handler = logging.StreamHandler(sys.stdout)
handler.setFormatter(formatter)
log.addHandler(handler)
log.setLevel(logging.WARNING)
uhal.setLogLevelTo(uhal.LogLevel.WARNING)
if verbose:
log.setLevel(logging.INFO)
uhal.setLogLevelTo(uhal.LogLevel.INFO)
if debug:
log.setLevel(logging.DEBUG)
uhal.setLogLevelTo(uhal.LogLevel.DEBUG)
try:
device = uhal.getDevice(
"dummy", "ipbusudp-1.3://localhost:12345", "file://" + test_xml)
except Exception:
raise Exception(
"File '%s' does not exist or has incorrect format" % test_xml)
if not os.path.exists(HDLPath):
os.makedirs(HDLPath)
cwd = os.getcwd()
os.chdir(os.path.abspath(HDLPath))
for i in device.getNodes():
if i.count('.') == 0:
mytree = tree.tree(device.getNode(i), log, yml2hdl=yml2hdl)
mytree.generatePkg()
mytree.generateRegMap(regMapTemplate=regMapTemplate)
# test array-type
# findArrayType(mytree.root)
os.chdir(cwd)
class GEMDAQTestSuite:
"""
This python script will test the GLIB, optical links, OH, and VFAT2 functionalities.
Simply follow the instructions on the screen in order to diagnose the setup.
Thomas Lenzi - [email protected]
Jared Sturdy - [email protected] (Adapted for uHAL)
"""
uhal.setLogLevelTo(uhal.LogLevel.FATAL)
allTests = ["A", "B", "C", "D", "E", "F", "G", "H", "I", "J"]
def __init__(self,
slot,
gtx,
tests="",
test_params=TEST_PARAMS(),
debug=False):
"""
"""
self.slot = slot
self.gtx = gtx
self.tests = tests.upper().split(',')
if ("J" in self.tests):
self.tests.append("B")
pass
if ("I" in self.tests):
self.tests.append("E")
pass
if ("H" in self.tests):
self.tests.append("G")
pass
if ("G" in self.tests):
self.tests.append("E")
pass
if ("F" in self.tests):
self.tests.append("E")
pass
if ("E" in self.tests):
self.tests.append("B")
pass
if ("D" in self.tests):
self.tests.append("B")
pass
if ("C" in self.tests):
self.tests.append("A")
pass
if ("B" in self.tests):
self.tests.append("A")
pass
self.tests = list(set(self.tests))
self.test_params = test_params
self.debug = debug
self.uTCAslot = 170
if self.slot:
uTCAslot = 160 + self.slot
pass
if self.debug:
print self.slot, uTCAslot
pass
self.ipaddr = '192.168.0.%d' % (uTCAslot)
self.address_table = "file://${GEM_ADDRESS_TABLE_PATH}/glib_address_table.xml"
self.uri = "chtcp-2.0://localhost:10203?target=%s:50001" % (
self.ipaddr)
self.glib = uhal.getDevice("glib", self.uri, self.address_table)
self.oh_basenode = "GLIB.OptoHybrid_%d.OptoHybrid" % (self.gtx)
self.presentVFAT2sSingle = []
self.presentVFAT2sFifo = []
self.chipIDs = None
self.vfatmask = 0xff000000
self.test = {}
self.test["A"] = False
self.test["B"] = False
self.test["C"] = False
self.test["D"] = False
self.test["E"] = False
self.test["F"] = False
self.test["G"] = False
self.test["H"] = False
self.test["I"] = False
self.test["J"] = False
return
####################################################
def GLIBPresenceTest(self):
txtTitle("A. Testing the GLIB's presence")
print " Trying to read the GLIB board ID... If this test fails, the script will stop."
if (readRegister(self.glib, "GLIB.SYSTEM.BOARD_ID") != 0):
print Passed
else:
print Failed
sys.exit()
pass
self.test["A"] = True
print
####################################################
def OptoHybridPresenceTest(self):
txtTitle("B. Testing the OH's presence")
print " Trying to set the OptoHybrid registers... If this test fails, the script will stop."
# setReferenceClock( self.glib, self.gtx, 1)
setTriggerSource(self.glib, self.gtx, 1)
setTriggerThrottle(self.glib, self.gtx, 0)
if (getTriggerSource(self.glib, self.gtx) == 1):
print Passed
else:
print Failed, "oh_trigger_source %d" % (getTriggerSource(
self.glib, self.gtx))
sys.exit()
pass
# if (getReferenceClock(self.glib,self.gtx) == 1):
# print Passed
# else:
# print Failed, "oh_clk_src %d"%(getReferenceClock(self.glib,self.gtx))
# sys.exit()
# pass
if (getTriggerThrottle(self.glib, self.gtx) == 0):
print Passed
else:
print Failed, "oh_trg_throttle %d" % (getTriggerThrottle(
self.glib, self.gtx))
sys.exit()
pass
self.test["B"] = True
print
return
####################################################
def GLIBRegisterTest(self):
txtTitle("C. Testing the GLIB registers")
print " Performing single reads on the GLIB counters and ensuring they increment."
countersSingle = []
countersTest = True
for i in range(0, self.test_params.GLIB_REG_TEST):
countersSingle.append(
readRegister(self.glib, "GLIB.COUNTERS.IPBus.Strobe.Counters"))
pass
for i in range(1, self.test_params.GLIB_REG_TEST):
if (countersSingle[i - 1] + 1 != countersSingle[i]):
print "\033[91m > #%d previous %d, current %d \033[0m" % (
i, countersSingle[i - 1], countersSingle[i])
countersTest = False
pass
pass
if (countersTest):
print Passed
else:
print Failed
pass
self.test["C"] = countersTest
print
return
####################################################
def OptoHybridRegisterTest(self):
txtTitle("D. Testing the OH registers")
print " Performing single reads on the OptoHybrid counters and ensuring they increment."
countersSingle = []
countersTest = True
for i in range(0, self.test_params.OH_REG_TEST):
countersSingle.append(
readRegister(
self.glib,
"%s.COUNTERS.WB.MASTER.Strobe.GTX" % (self.oh_basenode)))
pass
for i in range(1, self.test_params.OH_REG_TEST):
if (countersSingle[i - 1] + 1 != countersSingle[i]):
print "\033[91m > #%d previous %d, current %d \033[0m" % (
i, countersSingle[i - 1], countersSingle[i])
countersTest = False
pass
pass
if (countersTest):
print Passed
else:
print Failed
pass
self.test["D"] = countersTest
print
return
####################################################
def VFAT2DetectionTest(self):
txtTitle("E. Detecting the VFAT2s over I2C")
print " Detecting VFAT2s on the GEM by reading out their chip ID."
# writeRegister(self.glib,"%s.GEB.Broadcast.Reset"%(self.oh_basenode), 0)
# readRegister(self.glib,"%s.GEB.Broadcast.Request.ChipID0"%(self.oh_basenode))
self.chipIDs = getAllChipIDs(self.glib, self.gtx)
for i in range(0, 24):
# missing VFAT shows 0x0003XX00 in I2C broadcast result
# 0x05XX0800
# XX is slot number
# so if ((result >> 16) & 0x3) == 0x3, chip is missing
# or if ((result) & 0x30000) == 0x30000, chip is missing
if (((readRegister(
self.glib, "%s.GEB.VFATS.VFAT%d.ChipID0" %
(self.oh_basenode, i)) >> 24) & 0x5) != 0x5):
self.presentVFAT2sSingle.append(i)
pass
if (self.chipIDs[i] not in [0x0000, 0xdead]):
self.presentVFAT2sFifo.append(i)
pass
pass
if (self.presentVFAT2sSingle == self.presentVFAT2sFifo):
print Passed
pass
else:
print Failed
pass
self.test["E"] = True
print " Detected", str(len(
self.presentVFAT2sSingle)), "VFAT2s:", str(
self.presentVFAT2sSingle)
print
self.vfatmask = setVFATTrackingMask(self.glib, self.gtx)
return
####################################################
def VFAT2I2CRegisterTest(self):
txtTitle("F. Testing the I2C communication with the VFAT2s")
print " Performing random read/write operation on each connect VFAT2."
self.test["F"] = True
for i in self.presentVFAT2sSingle:
validOperations = 0
for j in range(0, self.test_params.I2C_TEST):
writeData = random.randint(0, 255)
writeVFAT(self.glib, self.gtx, i, "ContReg3", writeData)
readData = (readVFAT(self.glib, self.gtx, i, "ContReg3")
& 0xff)
if (readData == writeData):
validOperations += 1
pass
else:
print "0x%02x not 0x%02x" % (readData, writeData)
pass
writeVFAT(self.glib, self.gtx, i, "ContReg3", 0)
if (validOperations == self.test_params.I2C_TEST):
print Passed, "#%d" % (i)
else:
print Failed, "#%d received %d, expected %d" % (
i, validOperations, self.test_params.I2C_TEST)
self.test["F"] = False
pass
pass
print
return
####################################################
def TrackingDataReadoutTest(self):
txtTitle("G. Reading out tracking data")
print " Sending triggers and testing if the Event Counter adds up."
broadcastWrite(self.glib, self.gtx, "ContReg0", 0x36)
self.test["G"] = True
for i in self.presentVFAT2sSingle:
t1_mode = 0
t1_type = 0
t1_n = self.test_params.TK_RD_TEST
t1_interval = 400
resetLocalT1(self.glib, self.gtx)
writeVFAT(self.glib, self.gtx, i, "ContReg0", 0x37)
setVFATTrackingMask(self.glib, self.gtx, ~(0x1 << i))
flushTrackingFIFO(self.glib, self.gtx)
nPackets = 0
timeOut = 0
ecs = []
sendL1A(self.glib, self.gtx, t1_interval, t1_n)
while ((readFIFODepth(self.glib, self.gtx)["Occupancy"]) !=
7 * self.test_params.TK_RD_TEST):
timeOut += 1
if (timeOut == 10 * self.test_params.TK_RD_TEST):
break
pass
while ((readFIFODepth(self.glib, self.gtx)["isEMPTY"]) != 1):
packets = readTrackingInfo(self.glib, self.gtx)
if (len(packets) == 0):
print "read data packet length is 0"
continue
ec = int((0x00000ff0 & packets[0]) >> 4)
nPackets += 1
ecs.append(ec)
pass
writeVFAT(self.glib, self.gtx, i, "ContReg0", 0x36)
if (nPackets != self.test_params.TK_RD_TEST):
print Failed, "#%d received %d, expected %d" % (
i, nPackets, self.test_params.TK_RD_TEST)
if self.debug:
raw_input("press enter to continue")
pass
else:
followingECS = True
for j in range(0, self.test_params.TK_RD_TEST - 1):
if (ecs[j + 1] == 0 and ecs[j] == 255):
pass
elif (ecs[j + 1] - ecs[j] != 1):
followingECS = False
print "\033[91m > #%d previous %d, current %d \033[0m" % (
i, ecs[j], ecs[j + 1])
pass
pass
if (followingECS):
print Passed, "#" + str(i)
else:
print Failed, "#%d received %d, expected %d, noncontinuous ECs" % (
i, nPackets, self.test_params.TK_RD_TEST)
if self.debug:
raw_input("press enter to continue")
pass
self.test["G"] = False
pass
pass
pass
print
return
####################################################
def SimultaneousTrackingDataReadoutTest(self):
txtTitle("H. Reading out tracking data")
print " Turning on all VFAT2s and looking that all the Event Counters add up."
self.test["H"] = True
if (self.test["G"]):
broadcastWrite(self.glib, self.gtx, "ContReg0", 0x37)
mask = 0
for i in self.presentVFAT2sSingle:
mask |= (0x1 << i)
pass
setVFATTrackingMask(self.glib, self.gtx, ~(mask))
sendResync(self.glib, self.gtx, 10, 1)
flushTrackingFIFO(self.glib, self.gtx)
t1_mode = 0
t1_type = 0
t1_n = self.test_params.TK_RD_TEST
t1_interval = 400
resetLocalT1(self.glib, self.gtx)
nPackets = 0
timeOut = 0
ecs = []
sendL1A(self.glib, self.gtx, t1_interval, t1_n)
while ((readFIFODepth(self.glib, self.gtx)["Occupancy"]) !=
len(self.presentVFAT2sSingle) *
self.test_params.TK_RD_TEST):
timeOut += 1
if (timeOut == 20 * self.test_params.TK_RD_TEST): break
pass
while ((readFIFODepth(self.glib, self.gtx)["isEMPTY"]) != 1):
packets = readTrackingInfo(self.glib, self.gtx)
ec = int((0x00000ff0 & packets[0]) >> 4)
nPackets += 1
ecs.append(ec)
pass
broadcastWrite(self.glib, self.gtx, "ContReg0", 0x36)
if (nPackets != len(self.presentVFAT2sSingle) *
self.test_params.TK_RD_TEST):
print Failed, "#%d received: %d, expected: %d" % (
i, nPackets, len(self.presentVFAT2sSingle) *
self.test_params.TK_RD_TEST)
else:
followingECS = True
for i in range(0, self.test_params.TK_RD_TEST - 1):
for j in range(0, len(self.presentVFAT2sSingle) - 1):
if (ecs[i * len(self.presentVFAT2sSingle) + j + 1] !=
ecs[i * len(self.presentVFAT2sSingle) + j]):
print "\033[91m > #%d saw %d, %d saw %d \033[0m" % (
j + 1,
ecs[i * len(self.presentVFAT2sSingle) + j + 1],
j, ecs[i * len(self.presentVFAT2sSingle) + j])
followingECS = False
pass
pass
if (ecs[(i + 1) * len(self.presentVFAT2sSingle)] == 0
and ecs[i * len(self.presentVFAT2sSingle)] == 255):
pass
elif (ecs[(i + 1) * len(self.presentVFAT2sSingle)] -
ecs[i * len(self.presentVFAT2sSingle)] != 1):
print "\033[91m > #%d previous %d, current %d \033[0m" % (
i, ecs[i * len(self.presentVFAT2sSingle)],
ecs[(i + 1) * len(self.presentVFAT2sSingle)])
followingECS = False
pass
pass
if (followingECS): print Passed
else:
print Failed
self.test["H"] = False
pass
pass
resetLocalT1(self.glib, self.gtx)
pass
metavar="errorRate")
parser.add_option("-u",
"--user",
action="store_true",
dest="userOnly",
help="print user information only",
metavar="userOnly")
(options, args) = parser.parse_args()
links = {}
for link in options.activeLinks:
pair = map(int, link.split(","))
links[pair[0]] = pair[1]
print "links", links
uhal.setLogLevelTo(uhal.LogLevel.FATAL)
uTCAslot = 175
if options.slot:
uTCAslot = 160 + options.slot
print options.slot, uTCAslot
ipaddr = '192.168.0.%d' % (uTCAslot)
address_table = "file://${BUILD_HOME}/data/glib_address_table.xml"
uri = "chtcp-2.0://localhost:10203?target=%s:50001" % (ipaddr)
glib = uhal.getDevice("glib", uri, address_table)
########################################
# IP address
########################################
print
print "--=======================================--"
help="character to trigger capture "
"- default: %(default)s")
parser_cap.add_argument("--nwords", dest='ncapture',
type=int, metavar='N', default=4,
help="Number of words to capture from each link"
"- default: 0x%(default)i")
parser_cap.add_argument("--expected", metavar='pattern.txt',
help="Pattern file with 1 word/line in hex")
args = parser.parse_args()
if args.verbose:
logging.basicConfig(level=logging.INFO)
uhal.setLogLevelTo(uhal.LogLevel.WARNING)
else:
uhal.setLogLevelTo(uhal.LogLevel.WARNING)
logging.basicConfig(level=logging.WARNING)
if not args.connection:
args.connection = os.environ['CTP6_CONNECTION']
if not args.links:
log.debug("Using all links")
args.links = range(48)
else:
args.links = list(api.expand_links(args.links))
hw_connection = 'file://%s' % args.connection
log.info("Setting up connection: %s", hw_connection)
def __init__(self, name, go=True, freq=100, odir="blah", vprech=38, vdd=38, dvdd=38):
self._name = name
self._go = go
self._freq = freq
self._odir = odir
self._vprech = vprech
self._vdd = vdd
self._dvdd = dvdd
self._manager = uhal.ConnectionManager("file://../data/vipram_connections.xml")
self._hw = self._manager.getDevice("Mezz1")
uhal.setLogLevelTo(uhal.LogLevel.ERROR)
# self._hw.dispatch();
self._hw.getNode("VipMEM.VPRECH").write(vprech)
self._hw.getNode("VipMEM.VDD").write(vdd)
self._hw.getNode("VipMEM.DVDD").write(dvdd)
# self._hw.dispatch();
self._ident = self._hw.getNode("VipMEM.Ident").read()
self._vers = self._hw.getNode("VipMEM.FWver").read()
self._VprechargeRead = self._hw.getNode("VipMEM.VPRECH").read()
self._VprechargeMea = self._hw.getNode("VipMEM.V_VPRECH").read()
self._VDDRead = self._hw.getNode("VipMEM.VDD").read()
self._VDDMea = self._hw.getNode("VipMEM.V_VDD").read()
self._DVDDRead = self._hw.getNode("VipMEM.DVDD").read()
self._DVDDMea = self._hw.getNode("VipMEM.V_DVDD").read()
self._hw.dispatch()
print "Firmware identity = ", hex(
self._ident
), ", firmware version = ", self._vers, ", Vpre bit = ", self._VprechargeRead, ", Vpre measured = ", self._VprechargeMea
print "Vdd bit = ", self._VDDRead, ", Vdd measured = ", self._VDDMea, "Dvdd bit = ", self._DVDDRead, ", Dvdd measured = ", self._DVDDMea
self._iSteps = 0
self._fSteps = 32
self._stepIncrement = 32
self._blockSize = 1024
###################
## define registers
self._registers = []
self._registers.append("CheckData")
# CheckData
for i in range(32 - 1, -1, -1):
self._registers.append("Out" + str(i))
self._registers.append("ReqL0")
self._registers.append("Miss2")
self._registers.append("Miss1")
self._registers.append("Miss0")
self._registers.append("RunMode")
self._registers.append("Primary")
self._registers.append("Latch")
self._registers.append("EvRearm")
for i in range(7):
self._registers.append("RA" + str(i))
for i in range(5):
self._registers.append("CA" + str(i))
for i in range(1, 16):
self._registers.append("A" + str(i))
self._registers.append("A0")
for i in range(1, 16):
self._registers.append("B" + str(i))
self._registers.append("B0")
for i in range(1, 16):
self._registers.append("C" + str(i))
self._registers.append("C0")
for i in range(1, 16):
self._registers.append("D" + str(i))
self._registers.append("D0")
print "registers size = ", len(self._registers)
###################
# power numbers
self._i_dvdd = []
self._i_vdd = []
self._i_prech = []
self._difftimes = []
def gemsupervisor(request):
global state
global m_AMC13manager
global m_AMCmanager
global verbosity
global m_filename
global form
global m_monitor
global lt
def updateStatus():
status = m_AMC13manager.device.getStatus()
status.SetHTML()
# Create pipe and dup2() the write end of it on top of stdout, saving a copy
# of the old stdout
out = OutputGrabber()
out.start()
status.Report(verbosity)
out.stop()
shtml = out.capturedtext
with open("webdaq/templates/amc13status.html", "w") as text_file:
text_file.write(shtml)
with open("webdaq/templates/amcstatus.html", "w") as text_file:
text_file.write(m_AMCmanager.getStatus(verbosity))
def parkData():
#call root converter
call_command = os.getenv(
'BUILD_HOME') + '/gem-light-dqm/gemtreewriter/bin/' + os.getenv(
'XDAQ_OS') + '/' + os.getenv('XDAQ_PLATFORM') + '/unpacker'
command_args = "/tmp/" + m_filename + ".dat sdram"
call([call_command + ' ' + command_args], shell=True)
#create dirs in tmp
for i in range(24):
call(["mkdir -p /tmp/dqm_hists/%s" % (i)], shell=True)
call(["mkdir -p /tmp/dqm_hists/OtherData"], shell=True)
call(["mkdir -p /tmp/dqm_hists/canvases"], shell=True)
#call dqm
call_command = os.getenv(
'BUILD_HOME') + '/gem-light-dqm/dqm-root/bin/' + os.getenv(
'XDAQ_OS') + '/' + os.getenv('XDAQ_PLATFORM') + '/dqm'
command_args = "/tmp/" + m_filename + ".raw.root"
os.system(call_command + ' ' + command_args)
#call dqm printer
call_command = os.getenv(
'BUILD_HOME') + '/gem-light-dqm/dqm-root/bin/' + os.getenv(
'XDAQ_OS') + '/' + os.getenv('XDAQ_PLATFORM') + '/gtprinter'
command_args = "/tmp/" + m_filename + ".analyzed.root"
os.system(call_command + ' ' + command_args)
#copy results to DQM display form
#call_command = "/home/mdalchen/work/ldqm-browser/LightDQM/LightDQM/test/"
call_command = os.getenv('LDQM_STATIC') + '/'
# call_command += m_filename[10:15]
# call_command += "/"
# call_command += m_filename[:9]
# call_command += "/"
# call_command += "TAMU/GEB-GTX0-Long/"
call(["mkdir -p " + call_command], shell=True)
call(["cp -r /tmp/" + m_filename + " " + call_command], shell=True)
if request.POST:
if 'configure' in request.POST:
form = ConfigForm(request.POST)
if form.is_valid():
amc13N = form.cleaned_data['amc13_choice']
amc_list = form.cleaned_data['amc_list']
amc_str = ""
for amcN in amc_list:
amc_str += str(amcN) + ","
amc_str = amc_str[:-1]
trigger_type = form.cleaned_data['trigger_type']
if trigger_type == '1':
lt = True
m_monitor = True
else:
lt = False
m_monitor = False
trigger_rate = int(form.cleaned_data['trigger_rate'])
verbosity = int(form.cleaned_data['verbosity'])
uhal.setLogLevelTo(uhal.LogLevel.ERROR)
#configure GLIB. Currently supports only one GLIB
try:
m_AMC13manager.connect(str(amc13N), verbosity)
m_AMC13manager.configureInputs(amc_str)
m_AMC13manager.reset()
for amcN in amc_list:
m_AMCmanager.connect(int(amcN))
m_AMCmanager.reset()
n_gtx = m_AMCmanager.activateGTX()
print "N GTX links %s" % (n_gtx)
# retrieve VFAT slot numberd and ChipIDs from HW
for gtx in range(n_gtx):
chipids = m_AMCmanager.getVFATs(gtx)
# retrieve VFAT slot numberd and ChipIDs from DB
vfats = VFAT.objects.all()
# Check if the VFATs are in DB, add if not
v_list = []
for chip in chipids.keys():
t_chipid = "0x%04x" % (chipids[chip])
if t_chipid in vfats.filter(
Slot=chip).values_list("ChipID",
flat=True):
pass
else:
print "Adding VFAT(ChipID = %s, Slot = %d)" % (
t_chipid, chip)
v = VFAT(ChipID=t_chipid, Slot=chip)
v.save()
v_list.append(
VFAT.objects.get(ChipID=t_chipid,
Slot=chip))
#t_chamberID = 'OHv2aM'#hard code now, read from HW later when available
t_chamberID = 'GTX-' + str(
gtx
) #use gtx link number now, read from HW later when available
print "t_chamberID = %s" % (t_chamberID)
g_list = []
gebs = GEB.objects.filter(ChamberID=t_chamberID)
t_flag = False
for geb in gebs:
if v_list == list(geb.vfats.all()):
t_flag = True
g_list.append(geb)
break
if t_flag:
pass
else:
print "Update DB"
g = GEB(Type="Long", ChamberID=t_chamberID)
g.save()
for v in v_list:
g.vfats.add(v)
g_list.append(g)
t_flag = False
#t_boardID = "47-20120013"#hard code now, read from HW later when available
t_boardID = "AMC-" + str(
amcN
) #hard code now, read from HW later when available
a_list = []
amcs = AMC.objects.filter(BoardID=t_boardID)
for amc in amcs:
if g_list == list(amc.gebs.all()):
t_flag = True
a_list.append(amc)
if t_flag:
pass
else:
print "Update DB"
a = AMC(Type="GLIB", BoardID=t_boardID)
a.save()
for g in g_list:
a.gebs.add(g)
a_list.append(a)
# create a new run. Some values are hard-coded for now
runs = Run.objects.filter(Period="2016T",
Type="bench",
Station="TAMU")
rns = list(
int(x)
for x in list(runs.values_list("Number", flat=True)))
nrs = u'%s' % (max(rns) + 1)
nrs = nrs.zfill(6)
t_date = str(datetime.date.today())
m_filename = "run" + str(
nrs) + "" + "_bench_TAMU_" + t_date
newrun = Run(Name=m_filename,
Type="bench",
Number=str(nrs),
Date=datetime.date.today(),
Period="2016T",
Station="TAMU")
newrun.save()
for a in a_list:
newrun.amcs.add(a)
m_AMC13manager.configureTrigger(lt, 2, 1,
int(trigger_rate), 0)
updateStatus()
state = 'configured'
except ValueError, e:
print colors.YELLOW, e, colors.ENDC
state = 'halted'
elif 'halt' in request.POST:
form = ConfigForm()
m_AMC13manager.reset()
state = 'halted'
elif 'run' in request.POST:
print "running"
#form = ConfigForm()
updateStatus()
nevents = int(request.POST['nevents'])
t = threading.Thread(target=m_AMC13manager.startDataTaking,
args=["/tmp/" + m_filename + ".dat"])
t.start()
state = 'running'
elif 'stop' in request.POST:
m_AMC13manager.stopDataTaking()
updateStatus()
sleep(1)
t_p = threading.Thread(target=parkData)
t_p.start()
state = 'configured'
elif "monitoring" in request.POST:
updateStatus()
def main():
parser = argparse.ArgumentParser()
parser.add_argument("command", choices=['reset', 'status', 'capture'],
help="Action to perform")
parser.add_argument("links", nargs='*', help="Specify links. "
"If none are specified, reset all.")
parser.add_argument("--connection",
help="Manually connection XML file. "
"If not specified, take from CTP6_CONNECTION env.")
parser.add_argument("--verbose", action='store_true',
help="Increase verbosity")
parser_rst = parser.add_argument_group('reset')
parser_stat = parser.add_argument_group('status')
parser_cap = parser.add_argument_group('capture')
# Reset arguments
parser_rst.add_argument("--power-down", action='store_true',
dest='power_down',
help="Additionally power down the links")
# Capture arguments
parser_cap.add_argument("--orbit-capture-char", dest='capture_char',
type=str, metavar='0xbc', default='0xbc',
help="character to trigger capture "
"- default: %(default)s")
parser_cap.add_argument("--nwords", dest='ncapture',
type=int, metavar='N', default=4,
help="Number of words to capture from each link"
"- default: 0x%(default)i")
parser_cap.add_argument("--expected", metavar='pattern.txt',
help="Pattern file with 1 word/line in hex")
args = parser.parse_args()
if args.verbose:
logging.basicConfig(level=logging.INFO)
uhal.setLogLevelTo(uhal.LogLevel.WARNING)
else:
uhal.setLogLevelTo(uhal.LogLevel.WARNING)
logging.basicConfig(level=logging.WARNING)
if not args.connection:
args.connection = os.environ['CTP6_CONNECTION']
if not args.links:
log.debug("Using all links")
args.links = range(48)
else:
args.links = list(api.expand_links(args.links))
hw_connection = 'file://%s' % args.connection
log.info("Setting up connection: %s", hw_connection)
manager = uhal.ConnectionManager(hw_connection)
hw = manager.getDevice('ctp6.frontend')
commands = {
'reset': do_reset,
'status': do_status,
'capture': do_capture
}
commands[args.command](hw, args)
log.info("done.")
return 0
def __init__(self, dev_name, man_file, parsed_cfg):
uhal.setLogLevelTo(uhal.LogLevel.NOTICE
) ## Get rid of initial flood of IPBUS messages
self.isRunning = False
section_name = "Producer.fmctlu"
self.dev_name = dev_name
#man_file= parsed_cfg.get(section_name, "ConnectionFile")
self.manager = uhal.ConnectionManager(man_file)
self.hw = self.manager.getDevice(self.dev_name)
# #Get Verbose setting
self.verbose = parsed_cfg.getint(section_name, "verbose")
#self.nDUTs= 4 #Number of DUT connectors
self.nDUTs = parsed_cfg.getint(section_name, "nDUTs")
#self.nChannels= 6 #Number of trigger inputs
self.nChannels = parsed_cfg.getint(section_name, "nTrgIn")
#self.VrefInt= 2.5 #Internal DAC voltage reference
self.VrefInt = parsed_cfg.getfloat(section_name, "VRefInt")
#self.VrefExt= 1.3 #External DAC voltage reference
self.VrefExt = parsed_cfg.getfloat(section_name, "VRefExt")
#self.intRefOn= False #Internal reference is OFF by default
self.intRefOn = int(parsed_cfg.get(section_name, "intRefOn"))
self.fwVersion = self.hw.getNode("version").read()
self.hw.dispatch()
print "TLU V1E FIRMWARE VERSION= ", hex(self.fwVersion)
# Instantiate a I2C core to configure components
self.TLU_I2C = I2CCore(self.hw, 10, 5, "i2c_master", None)
#self.TLU_I2C.state()
enableCore = True #Only need to run this once, after power-up
self.enableCore()
####### EEPROM AX3 testing
doAtmel = False
if doAtmel:
self.ax3eeprom = ATSHA204A(self.TLU_I2C, 0x64)
print "shiftR\tdatBit\tcrcBit\tcrcReg \n", self.ax3eeprom._CalculateCrc(
[255, 12, 54, 28, 134, 89], 3)
self.ax3eeprom._wake(True, True)
print self.ax3eeprom._GetCommandPacketSize(8)
#self.eepromAX3read()
####### EEPROM AX3 testing end
# Instantiate clock chip and configure it (if necessary)
#self.zeClock=si5345(self.TLU_I2C, 0x68)
clk_addr = int(parsed_cfg.get(section_name, "I2C_CLK_Addr"), 16)
self.zeClock = si5345(self.TLU_I2C, clk_addr)
res = self.zeClock.getDeviceVersion()
if (int(parsed_cfg.get(section_name, "CONFCLOCK"), 16)):
#clkRegList= self.zeClock.parse_clk("./../../bitFiles/TLU_CLK_Config_v1e.txt")
clkRegList = self.zeClock.parse_clk(
parsed_cfg.get(section_name, "CLOCK_CFG_FILE"))
self.zeClock.writeConfiguration(clkRegList, self.verbose) ######
self.zeClock.checkDesignID()
# Instantiate DACs and configure them to use reference based on TLU setting
#self.zeDAC1=AD5665R(self.TLU_I2C, 0x13)
#self.zeDAC2=AD5665R(self.TLU_I2C, 0x1F)
dac_addr1 = int(parsed_cfg.get(section_name, "I2C_DAC1_Addr"), 16)
self.zeDAC1 = AD5665R(self.TLU_I2C, dac_addr1)
dac_addr2 = int(parsed_cfg.get(section_name, "I2C_DAC2_Addr"), 16)
self.zeDAC2 = AD5665R(self.TLU_I2C, dac_addr2)
self.zeDAC1.setIntRef(self.intRefOn, self.verbose)
self.zeDAC2.setIntRef(self.intRefOn, self.verbose)
# Instantiate the serial line expanders and configure them to default values
#self.IC6=PCA9539PW(self.TLU_I2C, 0x74)
exp1_addr = int(parsed_cfg.get(section_name, "I2C_EXP1_Addr"), 16)
self.IC6 = PCA9539PW(self.TLU_I2C, exp1_addr)
self.IC6.setInvertReg(0, 0x00) # 0= normal, 1= inverted
self.IC6.setIOReg(0, 0x00) # 0= output, 1= input
self.IC6.setOutputs(0, 0xFF) # If output, set to XX
self.IC6.setInvertReg(1, 0x00) # 0= normal, 1= inverted
self.IC6.setIOReg(1, 0x00) # 0= output, 1= input
self.IC6.setOutputs(1, 0xFF) # If output, set to XX
#self.IC7=PCA9539PW(self.TLU_I2C, 0x75)
exp2_addr = int(parsed_cfg.get(section_name, "I2C_EXP2_Addr"), 16)
self.IC7 = PCA9539PW(self.TLU_I2C, exp2_addr)
self.IC7.setInvertReg(0, 0x00) # 0= normal, 1= inverted
self.IC7.setIOReg(0, 0x00) # 0= output, 1= input
self.IC7.setOutputs(0, 0x00) # If output, set to XX
self.IC7.setInvertReg(1, 0x00) # 0= normal, 1= inverted
self.IC7.setIOReg(1, 0x00) # 0= output, 1= input
self.IC7.setOutputs(1, 0xB0) # If output, set to XX
#Instantiate Display
self.DISP = CFA632(self.TLU_I2C, 0x2A) #
#Instantiate Power/Led Module
dac_addr_module = int(
parsed_cfg.get(section_name, "I2C_DACModule_Addr"), 16)
exp1_addr = int(parsed_cfg.get(section_name, "I2C_EXP1Module_Addr"),
16)
exp2_addr = int(parsed_cfg.get(section_name, "I2C_EXP2Module_Addr"),
16)
pmtCtrVMax = parsed_cfg.getfloat(section_name, "PMT_vCtrlMax")
self.pwdled = PWRLED(self.TLU_I2C, dac_addr_module, pmtCtrVMax,
exp1_addr, exp2_addr)
#self.pwdled.setIndicatorRGB(1, [0, 0, 1])
#self.pwdled.setIndicatorRGB(2, [0, 0, 1])
#self.pwdled.setIndicatorRGB(3, [0, 0, 1])
#self.pwdled.setIndicatorRGB(4, [0, 0, 1])
#self.pwdled.setIndicatorRGB(5, [0, 0, 1])
#self.pwdled.setIndicatorRGB(6, [0, 0, 1])
#self.pwdled.setIndicatorRGB(7, [0, 0, 1])
#self.pwdled.setIndicatorRGB(8, [0, 0, 1])
#self.pwdled.setIndicatorRGB(9, [0, 0, 1])
#self.pwdled.setIndicatorRGB(10, [0, 0, 1])
#self.pwdled.setIndicatorRGB(11, [0, 0, 1])
self.pwdled.allGreen()
time.sleep(0.1)
self.pwdled.allBlue()
time.sleep(0.1)
self.pwdled.allBlack()
time.sleep(0.1)
#self.pwdled.kitt()
time.sleep(0.1)
#self.pwdled.allBlack()
#self.pwdled.allRed()
#time.sleep(0.1)
self.pwdled.allWhite()
parser.add_option('-b', action='store_true', dest='noX', default=False, help='no X11 windows')
parser.add_option('--go', action='store_true', dest='go', default=False, help='go!')
parser.add_option('--reset', action='store_true', dest='reset', default=False, help='go!')
(options, args) = parser.parse_args()
############################################
############################################################
def randuint32():
return randint(0, 0xffffffff)
if __name__ == '__main__':
manager = uhal.ConnectionManager("file://../data/vipram_connections.xml")
hw = manager.getDevice("Mezz1")
uhal.setLogLevelTo( uhal.LogLevel.NOTICE )
reg0 = hw.getNode("VipMEM.V_DVDD").read()
reg1 = hw.getNode("VipMEM.V_VDD").read()
reg2 = hw.getNode("VipMEM.V_VPRECH").read()
ireg0 = hw.getNode("VipMEM.I_DVDD").read()
ireg1 = hw.getNode("VipMEM.I_VDD").read()
ireg2 = hw.getNode("VipMEM.I_VPRECH").read()
vccreg = hw.getNode("VipMEM.V_VCC3V3").read()
tmpreg = hw.getNode("VipMEM.Temperature").read()
ltcreg = hw.getNode("VipMEM.LTC2991").read()
hw.dispatch();
(options, args) = parser.parse_args()
############################################
############################################################
def randuint32():
return randint(0, 0xffffffff)
if __name__ == '__main__':
manager = uhal.ConnectionManager("file://../data/vipram_connections.xml")
hw = manager.getDevice("Mezz1")
uhal.setLogLevelTo(uhal.LogLevel.NOTICE)
reg0 = hw.getNode("VipMEM.V_DVDD").read()
reg1 = hw.getNode("VipMEM.V_VDD").read()
reg2 = hw.getNode("VipMEM.V_VPRECH").read()
ireg0 = hw.getNode("VipMEM.I_DVDD").read()
ireg1 = hw.getNode("VipMEM.I_VDD").read()
ireg2 = hw.getNode("VipMEM.I_VPRECH").read()
vccreg = hw.getNode("VipMEM.V_VCC3V3").read()
tmpreg = hw.getNode("VipMEM.Temperature").read()
ltcreg = hw.getNode("VipMEM.LTC2991").read()
hw.dispatch()
from optparse import OptionParser
parser = OptionParser()
parser.add_option("-s", "--slot", type="int", dest="slot",
help="slot in uTCA crate", metavar="slot", default=4)
parser.add_option("-o", "--links", type="string", dest="activeLinks", action='append',
help="pair of connected optical links (GLIB,OH)", metavar="activeLinks", default=[])
(options, args) = parser.parse_args()
links = {}
for link in options.activeLinks:
pair = map(int, link.split(","))
links[pair[0]] = pair[1]
print "links", links
uhal.setLogLevelTo( uhal.LogLevel.FATAL )
if not links.keys():
print "No optical links specified, exiting"
exit(1)
# Create window
window = Window("Scan a VFAT2's threshold")
# Get GLIB access
glib = GLIB(options.slot,links)
glib.setWindow(window)
#########################################
# Introduction Window #
#########################################
def get_amc_version(xml_config):
uhal.setLogLevelTo(uhal.LogLevel.ERROR) #TODO: this is setting log level globally, which is not very nice...
device = amc13.AMC13(xml_config)
return (hex(device.read(device.Board.T1, 'STATUS.FIRMWARE_VERS')),
hex(device.read(device.Board.T2, 'STATUS.FIRMWARE_VERS')))
def main(localSlavesYAML, remoteSlavesYAML, CMyaml, outputDir):
#address table top node
top = ET.Element("node", {"id": "top"})
#local slaves
RecreateDir(outputDir + "address_table/modules")
slavesFile = open(localSlavesYAML)
slaves = yaml.load(slavesFile)
for slave in slaves['UHAL_MODULES']:
if "XML" in slaves['UHAL_MODULES'][slave]:
for iFile in range(0, len(slaves['UHAL_MODULES'][slave]["XML"])):
#copy XML files
xmlFile = slaves['UHAL_MODULES'][slave]["XML"][iFile]
try:
shutil.copyfile(os.path.abspath(xmlFile),
outputDir + xmlFile)
except OSError:
pass
if iFile == 0:
relPath = slaves['UHAL_MODULES'][slave]['XML'][iFile]
relPath = relPath[relPath.find("module"):]
slaves['UHAL_MODULES'][slave]['XML'][iFile] = relPath
AddAddressTableNode(slave, slaves['UHAL_MODULES'][slave], top)
remoteSlaves = list()
#append CM.yaml remote slaves
try:
if type(CMyaml) == type(' '):
CMFile = open(CMyaml)
remotes = yaml.load(CMFile)
if remotes:
for remote in remotes:
filename = "os/" + remote + "_slaves.yaml"
remoteSlaves.append(filename)
except IOError:
pass
#remote slaves (explicit)
if type(remoteSlavesYAML) == type(list()):
for CM in remoteSlavesYAML:
remoteSlaves.append(CM)
#go through all found remote slaves
for CM in remoteSlaves:
slavesFile = open(CM)
slaves = yaml.load(slavesFile)
nameCM = os.path.basename(CM)[0:os.path.basename(CM).find("_")]
for slave in slaves['UHAL_MODULES']:
if "XML" in slaves['UHAL_MODULES'][slave]:
for iFile in range(0,
len(slaves['UHAL_MODULES'][slave]["XML"])):
#change the file path to be relative on the apollo
relPath = slaves['UHAL_MODULES'][slave]['XML'][iFile]
relPath = nameCM + "_" + relPath[relPath.find("module"):]
slaves['UHAL_MODULES'][slave]['XML'][iFile] = relPath
AddAddressTableNode(slave, slaves['UHAL_MODULES'][slave], top)
#generate the final address table file
BuildAddressTable(outputDir + "address_table/address_apollo.xml", top)
#generate a connections file
connFile = open(outputDir + "address_table/connections.xml", "w")
connFile.write('<?xml version="1.0" encoding="UTF-8"?>\n')
connFile.write('\n')
connFile.write('<connections>\n')
connFile.write(
' <!-- be sure to use the same file in both "uri" and "address_table" -->\n'
)
connFile.write(
' <connection id="test.0" uri="uioaxi-1.0:///opt/address_table/address_apollo.xml" address_table="file:///opt/address_table/address_apollo.xml" />\n'
)
connFile.write('</connections>\n')
connFile.close()
#check files
uhal.setLogLevelTo(uhal.LogLevel.WARNING)
try:
device = uhal.getDevice(
"dummy", "ipbusudp-1.3://localhost:12345",
"file://" + outputDir + "address_table/address_apollo.xml")
except Exception:
raise Exception("File '%s' does not exist or has incorrect format" %
outputDir + "address_table/address_apollo.xml")
#!/usr/bin/python
import uhal
import time
import sys
from I2CuHal import I2CCore
from si5344 import si5344
uhal.setLogLevelTo(uhal.LogLevel.INFO)
manager = uhal.ConnectionManager("file://connections.xml")
hw = manager.getDevice(sys.argv[1])
hw.getNode("io.freq_ctr.ctrl.chan_sel").write(0)
hw.getNode("io.freq_ctr.ctrl.en_crap_mode").write(0)
hw.dispatch()
time.sleep(2)
fq = hw.getNode("io.freq_ctr.freq.count").read()
fv = hw.getNode("io.freq_ctr.freq.valid").read()
hw.dispatch()
print "Freq:", int(fv), int(fq) * 119.20928 / 1000000
hw.getNode("daq.timing.csr.ctrl.en_ext_sync").write(0)
f_stat = hw.getNode("csr.stat").read()
hw.dispatch()
print "csr.stat", hex(f_stat)
f_ctrl = hw.getNode("csr.ctrl").read()
hw.dispatch()
print "csr.ctrl:", hex(f_ctrl)
def __init__(self, name, go=True, freq=100, odir="blah"):
self._name = name
self._go = go
self._freq = freq
self._odir = odir
self._manager = uhal.ConnectionManager(
"file://../data/vipram_connections.xml")
self._hw = self._manager.getDevice("Mezz1")
uhal.setLogLevelTo(uhal.LogLevel.ERROR)
#self._hw.dispatch();
self._hw.getNode("VipMEM.VPRECH").write(38)
self._hw.getNode("VipMEM.VDD").write(38)
self._hw.getNode("VipMEM.DVDD").write(38)
#self._hw.dispatch();
self._ident = self._hw.getNode("VipMEM.Ident").read()
self._vers = self._hw.getNode("VipMEM.FWver").read()
self._VprechargeRead = self._hw.getNode("VipMEM.VPRECH").read()
self._VprechargeMea = self._hw.getNode("VipMEM.V_VPRECH").read()
self._VDDRead = self._hw.getNode("VipMEM.VDD").read()
self._VDDMea = self._hw.getNode("VipMEM.V_VDD").read()
self._DVDDRead = self._hw.getNode("VipMEM.DVDD").read()
self._DVDDMea = self._hw.getNode("VipMEM.V_DVDD").read()
self._hw.dispatch()
print "Firmware identity = ", hex(
self._ident
), ", firmware version = ", self._vers, ", Vpre bit = ", self._VprechargeRead, ", Vpre measured = ", self._VprechargeMea
print "Vdd bit = ", self._VDDRead, ", Vdd measured = ", self._VDDMea, "Dvdd bit = ", self._DVDDRead, ", Dvdd measured = ", self._DVDDMea
self._iSteps = 0
self._fSteps = 32
self._stepIncrement = 32
self._blockSize = 1024
###################
## define registers
self._registers = []
self._registers.append('CheckData')
# CheckData
for i in range(32 - 1, -1, -1):
self._registers.append('Out' + str(i))
self._registers.append('ReqL0')
self._registers.append('Miss2')
self._registers.append('Miss1')
self._registers.append('Miss0')
self._registers.append('RunMode')
self._registers.append('Primary')
self._registers.append('Latch')
self._registers.append('EvRearm')
for i in range(7):
self._registers.append("RA" + str(i))
for i in range(5):
self._registers.append("CA" + str(i))
for i in range(1, 16):
self._registers.append("A" + str(i))
self._registers.append("A0")
for i in range(1, 16):
self._registers.append("B" + str(i))
self._registers.append("B0")
for i in range(1, 16):
self._registers.append("C" + str(i))
self._registers.append("C0")
for i in range(1, 16):
self._registers.append("D" + str(i))
self._registers.append("D0")
print "registers size = ", len(self._registers)
###################
# power numbers
self._i_dvdd = []
self._i_vdd = []
self._i_prech = []
self._difftimes = []
def main():
parser = argparse.ArgumentParser()
parser.add_argument("command",
choices=['reset', 'status', 'capture'],
help="Action to perform")
parser.add_argument("links",
nargs='*',
help="Specify links. "
"If none are specified, reset all.")
parser.add_argument("--connection",
help="Manually connection XML file. "
"If not specified, take from CTP6_CONNECTION env.")
parser.add_argument("--verbose",
action='store_true',
help="Increase verbosity")
parser_rst = parser.add_argument_group('reset')
parser_stat = parser.add_argument_group('status')
parser_cap = parser.add_argument_group('capture')
# Reset arguments
parser_rst.add_argument("--power-down",
action='store_true',
dest='power_down',
help="Additionally power down the links")
# Capture arguments
parser_cap.add_argument("--orbit-capture-char",
dest='capture_char',
type=str,
metavar='0xbc',
default='0xbc',
help="character to trigger capture "
"- default: %(default)s")
parser_cap.add_argument("--nwords",
dest='ncapture',
type=int,
metavar='N',
default=4,
help="Number of words to capture from each link"
"- default: 0x%(default)i")
parser_cap.add_argument("--expected",
metavar='pattern.txt',
help="Pattern file with 1 word/line in hex")
args = parser.parse_args()
if args.verbose:
logging.basicConfig(level=logging.INFO)
uhal.setLogLevelTo(uhal.LogLevel.WARNING)
else:
uhal.setLogLevelTo(uhal.LogLevel.WARNING)
logging.basicConfig(level=logging.WARNING)
if not args.connection:
args.connection = os.environ['CTP6_CONNECTION']
if not args.links:
log.debug("Using all links")
args.links = range(48)
else:
args.links = list(api.expand_links(args.links))
hw_connection = 'file://%s' % args.connection
log.info("Setting up connection: %s", hw_connection)
manager = uhal.ConnectionManager(hw_connection)
hw = manager.getDevice('ctp6.frontend')
commands = {'reset': do_reset, 'status': do_status, 'capture': do_capture}
commands[args.command](hw, args)
log.info("done.")
return 0
# 0 <= ret <= (2^32-1)
val = randint(0, 4294967295)
if len(bin(val).replace("0b", "")) > 32: #dirty check for me
print hex(val)
return val
def get_lut_16bit_word(address):
from random import randint
# 0 <= ret <= (2^32-1)
val = randint(0, 65535)
if len(bin(val).replace("0b", "")) > 16: #dirty check for me
print hex(val)
return val
opts, args = parse_options()
uhal.setLogLevelTo(uhal.LogLevel.ERROR)
hlp.initLogging(logging.DEBUG)
cm = uhal.ConnectionManager(opts.connectionFile)
board = cm.getDevice( opts.board )
# run a simple access test
hlp.testAccess(board)
v = board.getNode('ctrl.id').read()
try:
board.dispatch()
except:
import sys
# print something here when if times out
print 'MP7 access failed (name:',board.id(),'uri:',board.uri(),')'
class VFATSCurveTools:
"""
This set of tools provides functionality to produce S-Curve results for VFAT2 chips
@author: Hugo DeWitt
@modifiedby: Christine McClean
Jared Sturdy - [email protected] (Adapted for uHAL)
"""
uhal.setLogLevelTo(uhal.LogLevel.FATAL)
def __init__(self,
glib,
slot,
gtx,
scan_params,
doLatency=False,
debug=False):
"""
"""
self.glib = glib
self.slot = slot
self.gtx = gtx
self.scan_params = scan_params
self.doLatency = doLatency
self.THRESH_ABS = scan_params.THRESH_ABS
self.THRESH_REL = scan_params.THRESH_REL
self.THRESH_MIN = scan_params.THRESH_MIN
self.THRESH_MAX = scan_params.THRESH_MAX
self.LAT_ABS = scan_params.LAT_ABS
self.LAT_MIN = scan_params.LAT_MIN
self.LAT_MAX = scan_params.LAT_MAX
self.N_EVENTS_THRESH = scan_params.N_EVENTS_THRESH
self.N_EVENTS_LAT = scan_params.N_EVENTS_LAT
self.N_EVENTS_SCURVE = scan_params.N_EVENTS_SCURVE
self.N_EVENTS_TRIM = scan_params.N_EVENTS_TRIM
self.VCAL_MIN = scan_params.VCAL_MIN
self.VCAL_MAX = scan_params.VCAL_MAX
self.MAX_TRIM_IT = scan_params.MAX_TRIM_IT
self.CHAN_MIN = scan_params.CHAN_MIN
self.CHAN_MAX = scan_params.CHAN_MAX
self.DAC_DEF = scan_params.DAC_DEF
self.T1_PARAMS_N = scan_params.T1_PARAMS_N
self.T1_PARAMS_INTERVAL = scan_params.T1_PARAMS_INTERVAL
self.T1_PARAMS_DELAY = scan_params.T1_PARAMS_DELAY
self.debug = debug
self.startTime = None
self.subname = None
self.f = None
self.m = None
self.z = None
self.h = None
self.g = None
return
def cleanup(self, debug=False):
"""
"""
self.startTime = None
self.subname = None
self.f = None
self.m = None
self.z = None
self.h = None
self.g = None
return
def setupVFAT(self, vfat, debug=False):
"""
"""
print "------------------------------------------------------"
print "-------------- Testing VFAT2 position %2d -------------" % (
vfat)
print "------------------------------------------------------"
if vfat not in range(0, 24):
print "Invalid VFAT specified %d is no in [0,23]" % (vfat)
sys.exit(-1)
pass
self.TotVCal = {}
self.TotVCal["0"] = []
self.TotVCal["16"] = []
self.TotVCal["31"] = []
self.TotFoundVCal = []
self.VCal_ref = {}
self.VCal_ref["0"] = 0
self.VCal_ref["31"] = 0
self.VCal_ref["avg"] = 0
import datetime
self.startTime = datetime.datetime.now().strftime("%d_%m_%Y_%Hh%M")
chipID = getChipID(self.glib, self.gtx, vfat)
self.subname = "AMC_%02d_OH_%02d_VFAT2_%d_ID_0x%04x" % (
self.slot, self.gtx, vfat, chipID)
self.f = open("%s_Data_%s" % (self.startTime, self.subname), 'w')
self.m = open(
"%s_SCurve_by_channel_%s" % (self.startTime, self.subname), 'w')
self.z = open("%s_Setting_%s" % (self.startTime, self.subname), 'w')
self.h = open("%s_VCal_%s" % (self.startTime, self.subname), 'w')
self.g = open("%s_TRIM_DAC_value_%s" % (self.startTime, self.subname),
'w')
self.m.close()
self.h.close()
self.g.close()
self.z.write("%s-%s\n" %
(time.strftime("%Y/%m/%d"), time.strftime("%H:%M:%S")))
self.z.write("chip ID: 0x%04x\n" % (chipID))
# should make sure all chips are off first?
writeAllVFATs(self.glib,
self.gtx,
reg="ContReg0",
value=0x0,
mask=0xff000000)
setTriggerSource(self.glib, self.gtx, 1)
biasVFAT(self.glib, self.gtx, vfat)
self.z.write("ipreampin: 168\n")
self.z.write("ipreampfeed: 80\n")
self.z.write("ipreampout: 150\n")
self.z.write("ishaper: 150\n")
self.z.write("ishaperfeed: 100\n")
self.z.write("icomp: 75\n")
self.z.write("vthreshold2: 0\n")
self.z.write("vthreshold1: 0\n")
print
sendL1ACalPulse(self.glib, self.gtx, self.T1_PARAMS_DELAY,
self.T1_PARAMS_INTERVAL, self.T1_PARAMS_N)
stopLocalT1(self.glib, self.gtx)
self.z.write("DACs default value: %s\n" % (self.DAC_DEF))
for channel in range(self.CHAN_MIN, self.CHAN_MAX):
## old script had *all* channels set up to receive a pulse at this point, why?
setChannelRegister(self.glib,
self.gtx,
vfat,
channel,
mask=0x0,
pulse=0x0,
trim=self.DAC_DEF)
pass
return
def scanThresholdByVFAT(self, vfat, debug=False):
"""
"""
configureScanModule(self.glib,
self.gtx,
SCAN_THRESH_TRIG,
vfat,
scanmin=self.THRESH_MIN,
scanmax=self.THRESH_MAX,
stepsize=1,
numtrigs=self.N_EVENTS_THRESH,
debug=debug)
startScanModule(self.glib, self.gtx)
if (debug):
printScanConfiguration(self.glib, self.gtx)
print "LocalT1Controller status %d" % (getLocalT1Status(
self.glib, self.gtx))
pass
data_threshold = getScanResults(self.glib,
self.gtx,
self.THRESH_MAX - self.THRESH_MIN,
debug=debug)
return data_threshold
def scanLatencyByVFAT(self, vfat, debug=False):
"""
"""
channel = 10
setChannelRegister(self.glib,
self.gtx,
vfat,
channel,
mask=0x0,
pulse=0x1,
trim=self.DAC_DEF)
writeVFAT(self.glib, self.gtx, vfat, "VCal", 0xff)
configureScanModule(self.glib,
self.gtx,
SCAN_LATENCY,
vfat,
scanmin=self.LAT_MIN,
scanmax=self.LAT_MAX,
stepsize=1,
numtrigs=self.N_EVENTS_LAT,
debug=debug)
startScanModule(self.glib, self.gtx)
if (debug):
printScanConfiguration(self.glib, self.gtx)
print "LocalT1Controller status %d" % (getLocalT1Status(
self.glib, self.gtx))
pass
data_latency = getScanResults(self.glib,
self.gtx,
self.LAT_MAX - self.LAT_MIN,
debug=debug)
setChannelRegister(self.glib,
self.gtx,
vfat,
channel,
mask=0x0,
pulse=0x0,
trim=self.DAC_DEF)
writeVFAT(self.glib, self.gtx, vfat, "VCal", 0x0)
return data_latency
def scanVCalByVFAT(self, vfat, channel, trim, ntrigs, debug=False):
"""
"""
setChannelRegister(self.glib,
self.gtx,
vfat,
channel,
mask=0x0,
pulse=0x1,
trim=trim)
if debug:
print "Channel %d register 0x%08x" % (
channel, getChannelRegister(self.glib, self.gtx, vfat,
channel))
pass
configureScanModule(self.glib,
self.gtx,
SCAN_VCAL,
vfat,
channel=channel,
scanmin=self.VCAL_MIN,
scanmax=self.VCAL_MAX,
stepsize=1,
numtrigs=ntrigs,
debug=debug)
startScanModule(self.glib, self.gtx)
if (debug):
printScanConfiguration(self.glib, self.gtx)
print "LocalT1Controller status %d" % (getLocalT1Status(
self.glib, self.gtx))
pass
data_scurve = getScanResults(self.glib,
self.gtx,
self.VCAL_MAX - self.VCAL_MIN,
debug=debug)
setChannelRegister(self.glib,
self.gtx,
vfat,
channel,
mask=0x0,
pulse=0x0,
trim=trim,
debug=True)
if debug:
print "Channel %d register 0x%08x" % (
channel, getChannelRegister(self.glib, self.gtx, vfat,
channel))
pass
return data_scurve
def runAllChannels(self, vfat, debug=False):
"""
"""
# for each channel, disable the cal pulse
for channel in range(self.CHAN_MIN, self.CHAN_MAX):
setChannelRegister(self.glib,
self.gtx,
vfat,
channel,
mask=0x0,
pulse=0x0,
trim=self.DAC_DEF)
pass
for channel in range(self.CHAN_MIN, self.CHAN_MAX):
if self.debug and (channel > 10):
continue
self.scanChannel(vfat, channel, debug=debug)
pass
return
def scanChannel(self, vfat, channel, debug=False):
"""
"""
print "--------------------- Channel %03d ---------------------------" % (
channel)
self.m = open(
"%s_SCurve_by_channel_%s" % (self.startTime, self.subname), 'a')
for trim in [0, 16, 31]:
print "---------------- S-Curve data trimDAC %2d --------------------" % (
trim)
data_scurve = self.scanVCalByVFAT(vfat,
channel,
trim,
ntrigs=self.N_EVENTS_SCURVE,
debug=debug)
if (trim == 16):
self.m.write("SCurve_%d\n" % (channel))
pass
try:
if debug:
print "Length of returned data_scurve = %d" % (
len(data_scurve))
print "First data word: 0x%08x" % (data_scurve[0])
for d in range(0, len(data_scurve)):
"%d ==> %3.4f" % ((data_scurve[d] & 0xff000000) >> 24,
(data_scurve[d] & 0xffffff) /
(1. * self.N_EVENTS_SCURVE))
pass
pass
passed = False
for d in data_scurve:
VCal = (d & 0xff000000) >> 24
Eff = (d & 0xffffff) / (1. * self.N_EVENTS_SCURVE)
if self.debug:
print "%d => %3.4f" % (VCal, Eff)
pass
if (Eff >= 0.48 and not passed):
if not passed:
print "%d => %3.4f" % (VCal, Eff)
self.TotVCal["%s" % (trim)].append(VCal)
pass
passed = True
if trim in [0, 31]:
break # stop scanning for high and low trim values
pass
if (trim == 16):
self.m.write(
"%d\t%f\n" %
(VCal, Eff)) # write to file for trim == 16
pass
pass
# if self.doQC3:
# return
except:
ex = sys.exc_info()[0]
print "Caught exception: %s" % (ex)
print "Error while reading the data, they will be ignored"
self.m.close()
pass
pass
self.m.close()
return
def adjustTrims(self, vfat, debug=False):
"""
"""
print
print "------------------------ TrimDAC routine ------------------------"
print
self.h = open("%s_VCal_%s" % (self.startTime, self.subname), 'a')
if debug:
for trim in [0, 16, 31]:
print "TotVCal[%d](length = %d) = %s" % (
trim, len(self.TotVCal["%d" %
(trim)]), self.TotVCal["%d" %
(trim)])
pass
pass
try:
self.VCal_ref["0"] = sum(self.TotVCal["0"]) / len(
self.TotVCal["0"])
print "VCal_ref[0] %d" % (self.VCal_ref["0"])
self.VCal_ref["31"] = sum(self.TotVCal["31"]) / len(
self.TotVCal["31"])
print "VCal_ref[31] %d" % (self.VCal_ref["31"])
self.VCal_ref["avg"] = (self.VCal_ref["0"] +
self.VCal_ref["31"]) / 2
print "VCal_ref[avg] %d" % (self.VCal_ref["avg"])
self.h.write("%s\n" % (self.TotVCal["0"]))
self.h.write("%s\n" % (self.TotVCal["31"]))
except:
ex = sys.exc_info()[0]
print "Caught exception: %s" % (ex)
print "S-Curve did not work"
self.h.close() # changed from self.f.close()
return False
self.g = open("%s_TRIM_DAC_value_%s" % (self.startTime, self.subname),
'a')
for channel in range(self.CHAN_MIN, self.CHAN_MAX):
if self.debug and (channel > 10):
continue
self.adjustChannelTrims(vfat, channel, debug)
pass
self.h.write("%s\n" % (self.TotFoundVCal))
# VCalList = [] ## where is this used???
# minVcal = 0 ## where is this used???
self.h.close()
self.g.close()
return True
def adjustChannelTrims(self, vfat, channel, debug=False):
"""
"""
TRIM_IT = 0
print "TrimDAC Channel%d" % (channel)
trimDAC = 16
foundGood = False
foundVCal = None # this was not properly scoped previosly, where do we want to initialize it?
while (foundGood == False):
data_trim = self.scanVCalByVFAT(vfat,
channel,
trimDAC,
ntrigs=self.N_EVENTS_SCURVE,
debug=debug)
if debug:
print "First data word: 0x%08x" % (data_trim[0])
pass
try:
for d in data_trim:
VCal = (d & 0xff000000) >> 24
Eff = (d & 0xffffff) / (1. * self.N_EVENTS_SCURVE)
if (Eff >= 0.48):
print "%d => %3.4f" % (VCal, Eff)
foundVCal = VCal
break
pass
pass
except:
ex = sys.exc_info()[0]
print "Caught exception: %s" % (ex)
print "Error while reading the data, they will be ignored"
continue
if (foundVCal > self.VCal_ref["avg"] and TRIM_IT < self.MAX_TRIM_IT
and trimDAC < 31):
trimDAC += 1
TRIM_IT += 1
elif (foundVCal < self.VCal_ref["avg"]
and TRIM_IT < self.MAX_TRIM_IT and trimDAC > 0):
trimDAC -= 1
TRIM_IT += 1
else:
self.g.write("%d\n" % (trimDAC))
self.TotFoundVCal.append(foundVCal)
self.f.write("S_CURVE_%d\n" % (channel))
for d in data_trim:
self.f.write("%d\t%f\n" %
((d & 0xff000000) >> 24,
(d & 0xffffff) / (1. * self.N_EVENTS_TRIM)))
pass
break
pass
return
def setAllTrims(self, vfat, debug=False):
"""
"""
self.g = open("%s_TRIM_DAC_value_%s" % (self.startTime, self.subname),
'r')
for channel in range(self.CHAN_MIN, self.CHAN_MAX):
if self.debug and (channel > 10):
continue
trimDAC = (self.g.readline()).rstrip('\n')
print "Setting channel %d trimDAC to %s" % (channel, trimDAC)
setChannelRegister(self.glib,
self.gtx,
vfat,
channel,
mask=0x0,
pulse=0x0,
trim=int(trimDAC))
pass
self.g.close()
return
########################## Main routine per VFAT ######################
def runScanRoutine(self, vfat, debug=False):
"""
"""
chipID = getChipID(self.glib, self.gtx, vfat)
print "AMC%02d OH%02d VFAT%02d 0x%04x" % (self.slot, self.gtx, vfat,
chipID)
print
########################## Setup the VFAT ######################
print "Setup the VFAT"
self.setupVFAT(vfat)
########################## Initial threshold scan ######################
print "Initial threshold scan"
data_threshold = self.scanThresholdByVFAT(vfat, debug=debug)
print "Length of returned data_threshold = %d" % (len(data_threshold))
threshold = 0
noise = 100 * (data_threshold[0] & 0xffffff) / (1. *
self.N_EVENTS_THRESH)
if debug:
print "First data word: 0x%08x" % (data_threshold[0])
pass
print "%d = %3.4f" % (((data_threshold[0] & 0xff000000) >> 24), noise)
for d in range(1, len(data_threshold) - 1):
noise = 100 * (data_threshold[d]
& 0xffffff) / (1. * self.N_EVENTS_THRESH)
lastnoise = 100 * (data_threshold[d - 1]
& 0xffffff) / (1. * self.N_EVENTS_THRESH)
nextnoise = 100 * (data_threshold[d + 1]
& 0xffffff) / (1. * self.N_EVENTS_THRESH)
passAbs = (noise) < self.THRESH_ABS
passLastRel = (lastnoise - noise) < self.THRESH_REL
passNextRel = abs(noise - nextnoise) < self.THRESH_REL
print "%d = %3.4f" % ((
(data_threshold[d] & 0xff000000) >> 24), noise)
if passAbs and passLastRel and passNextRel:
# why is the threshold set to the previous value?
threshold = (data_threshold[d] >> 24)
setVFATThreshold(self.glib,
self.gtx,
vfat,
vt1=(threshold),
vt2=0)
print "Threshold set to: %d" % (threshold)
self.f.write("Threshold set to: %d\n" % (threshold))
self.z.write("vthreshold1: %d\n" % (threshold))
break
pass
# self.z.close()
if threshold == 0 or threshold == 255:
print "ignored"
for d in range(0, len(data_threshold)):
self.f.write("%d\t%f\n" %
((data_threshold[d] & 0xff000000) >> 24, 100 *
(data_threshold[d] & 0xffffff) /
(1. * self.N_EVENTS_THRESH)))
pass
self.f.close()
return
for d in range(0, len(data_threshold)):
self.f.write("%d\t%f\n" %
((data_threshold[d] & 0xff000000) >> 24, 100 *
(data_threshold[d] & 0xffffff) /
(1. * self.N_EVENTS_THRESH)))
pass
##################Parts of the routine require the L1A+CalPulse ######################
startLocalT1(self.glib, self.gtx)
########################## Initial latency scan ######################
if self.doLatency:
print "Initial latency scan"
data_latency = self.scanLatencyByVFAT(vfat, debug=debug)
print "Length of returned data_latency = %d" % (len(data_latency))
if not len(data_latency):
print "data_latency is empty"
return
if debug:
print "First data word: 0x%08x" % (data_latency[0])
pass
eff = 100 * (data_latency[0] & 0xffffff) / (1. * self.N_EVENTS_LAT)
print "%d = %3.4f" % (((data_latency[0] & 0xff000000) >> 24), eff)
for d in range(1, len(data_latency) - 1):
eff = 100 * (data_latency[d] & 0xffffff) / (1. *
self.N_EVENTS_LAT)
lasteff = 100 * (data_latency[d - 1]
& 0xffffff) / (1. * self.N_EVENTS_LAT)
nexteff = 100 * (data_latency[d + 1]
& 0xffffff) / (1. * self.N_EVENTS_LAT)
print "%d = %3.4f" % ((
(data_latency[d] & 0xff000000) >> 24), eff)
if (eff) > self.LAT_ABS and (nexteff) > self.LAT_ABS and (
lasteff) <= self.LAT_ABS:
latency = (data_latency[d + 1] >> 24)
writeVFAT(self.glib, self.gtx, vfat, "Latency", (latency))
print "Latency set to: %d" % (latency)
self.f.write("Latency set to: %d\n" % (latency))
self.z.write("latency: %d\n" % (latency))
#if not debug:
break
#pass
pass
pass
else:
writeVFAT(self.glib, self.gtx, vfat, "Latency", (37))
print "Latency set to: %d" % (37)
self.f.write("Latency set to: %d\n" % (37))
self.z.write("latency: %d\n" % (37))
pass
self.z.close()
################## Run S-Curves on all channels ######################
print "Run S-Curves on all channels"
self.runAllChannels(vfat, debug=debug)
# if self.doQC3:
# return
################## Adjust the trim for each channel ######################
print "Adjust the trim for each channel"
if self.adjustTrims(vfat, debug=debug):
################# Set all the TrimDACs to the right value #################
print "Set all the TrimDACs to the right value"
self.setAllTrims(vfat, debug=debug)
pass
########################## Final threshold scan ######################
print "Final threshold scan"
stopLocalT1(self.glib, self.gtx)
self.f.write("second_threshold\n")
data_threshold = self.scanThresholdByVFAT(vfat, debug=debug)
if not len(data_threshold):
print "data_threshold is empty"
return
if debug:
print "First data word: 0x%08x" % (data_threshold[0])
pass
for d in data_threshold:
self.f.write("%d\t%f\n" %
((d & 0xff000000) >> 24, 100 * (d & 0xffffff) /
(1. * self.N_EVENTS_THRESH)))
pass
########################## Final latency scan ######################
if self.doLatency:
print "Final latency scan"
startLocalT1(self.glib, self.gtx)
data_latency = self.scanLatencyByVFAT(vfat, debug=debug)
print "Length of returned data_latency = %d" % (len(data_latency))
if not len(data_latency):
print "data_latency is empty"
return
if debug:
print "First data word: 0x%08x" % (data_latency[0])
pass
eff = 100 * (data_latency[0] & 0xffffff) / (1. * self.N_EVENTS_LAT)
print "%d = %3.4f" % (((data_latency[0] & 0xff000000) >> 24), eff)
for d in range(1, len(data_latency) - 1):
eff = 100 * (data_latency[d] & 0xffffff) / (1. *
self.N_EVENTS_LAT)
lasteff = 100 * (data_latency[d - 1]
& 0xffffff) / (1. * self.N_EVENTS_LAT)
nexteff = 100 * (data_latency[d + 1]
& 0xffffff) / (1. * self.N_EVENTS_LAT)
print "%d = %3.4f" % ((
(data_latency[d] & 0xff000000) >> 24), eff)
if (eff) > self.LAT_ABS and (nexteff) > self.LAT_ABS and (
lasteff) <= self.LAT_ABS:
writeVFAT(self.glib, self.gtx, vfat, "Latency", (d + 1))
print "Latency set to: %d" % (d + 1)
break
pass
pass
else:
pass
self.f.close()
self.cleanup()
if debug:
raw_input("enter to finish")
pass
##################### Stop local T1 controller ######################
resetLocalT1(self.glib, self.gtx)
return
def get_hw(self):
uhal.setLogLevelTo(uhal.LogLevel.DEBUG)
self.hw = uhal.getDevice("HappyDaq.udp.0", self.device_uri,
self.address_table_uri)
return self.hw
def gemsupervisor(request):
global state
global m_AMC13manager
global m_AMCmanager
global verbosity
global m_filename
global form
global m_monitor
global lt
def updateStatus():
status = m_AMC13manager.device.getStatus()
status.SetHTML()
# Create pipe and dup2() the write end of it on top of stdout, saving a copy
# of the old stdout
out = OutputGrabber()
out.start()
status.Report(verbosity)
out.stop()
shtml = out.capturedtext
with open("webdaq/templates/amc13status.html", "w") as text_file:
text_file.write(shtml)
with open("webdaq/templates/amcstatus.html", "w") as text_file:
text_file.write(m_AMCmanager.getStatus(verbosity))
def parkData():
#call root converter
call_command = os.getenv('BUILD_HOME')+'/gem-light-dqm/gemtreewriter/bin/'+os.getenv('XDAQ_OS')+'/'+os.getenv('XDAQ_PLATFORM')+'/unpacker'
command_args = "/tmp/"+m_filename+".dat sdram"
call([call_command+' '+command_args],shell=True)
#create dirs in tmp
for i in range (24):
call(["mkdir -p /tmp/dqm_hists/%s"%(i)],shell=True)
call(["mkdir -p /tmp/dqm_hists/OtherData"],shell=True)
call(["mkdir -p /tmp/dqm_hists/canvases"],shell=True)
#call dqm
call_command = os.getenv('BUILD_HOME')+'/gem-light-dqm/dqm-root/bin/'+os.getenv('XDAQ_OS')+'/'+os.getenv('XDAQ_PLATFORM')+'/dqm'
command_args = "/tmp/"+m_filename+".raw.root"
os.system(call_command+' '+command_args)
#call dqm printer
call_command = os.getenv('BUILD_HOME')+'/gem-light-dqm/dqm-root/bin/'+os.getenv('XDAQ_OS')+'/'+os.getenv('XDAQ_PLATFORM')+'/gtprinter'
command_args = "/tmp/"+m_filename+".analyzed.root"
os.system(call_command+' '+command_args)
#copy results to DQM display form
#call_command = "/home/mdalchen/work/ldqm-browser/LightDQM/LightDQM/test/"
call_command = os.getenv('LDQM_STATIC')+'/'
# call_command += m_filename[10:15]
# call_command += "/"
# call_command += m_filename[:9]
# call_command += "/"
# call_command += "TAMU/GEB-GTX0-Long/"
call(["mkdir -p "+call_command],shell=True)
call(["cp -r /tmp/"+m_filename+" "+call_command],shell=True)
if request.POST:
if 'configure' in request.POST:
form = ConfigForm(request.POST)
if form.is_valid():
amc13N = form.cleaned_data['amc13_choice']
amc_list = form.cleaned_data['amc_list']
amc_str = ""
for amcN in amc_list:
amc_str += str(amcN) + ","
amc_str = amc_str[:-1]
trigger_type = form.cleaned_data['trigger_type']
if trigger_type == '1':
lt=True
m_monitor = True
else:
lt=False
m_monitor = False
trigger_rate = int(form.cleaned_data['trigger_rate'])
verbosity = int(form.cleaned_data['verbosity'])
uhal.setLogLevelTo(uhal.LogLevel.ERROR)
#configure GLIB. Currently supports only one GLIB
try:
m_AMC13manager.connect(str(amc13N),verbosity)
m_AMC13manager.configureInputs(amc_str)
m_AMC13manager.reset()
for amcN in amc_list:
m_AMCmanager.connect(int(amcN))
m_AMCmanager.reset()
n_gtx = m_AMCmanager.activateGTX()
print "N GTX links %s" %(n_gtx)
# retrieve VFAT slot numberd and ChipIDs from HW
for gtx in range(n_gtx):
chipids = m_AMCmanager.getVFATs(gtx)
# retrieve VFAT slot numberd and ChipIDs from DB
vfats = VFAT.objects.all()
# Check if the VFATs are in DB, add if not
v_list = []
for chip in chipids.keys():
t_chipid = "0x%04x"%(chipids[chip])
if t_chipid in vfats.filter(Slot=chip).values_list("ChipID", flat=True):
pass
else:
print "Adding VFAT(ChipID = %s, Slot = %d)"%(t_chipid,chip)
v = VFAT(ChipID = t_chipid, Slot = chip)
v.save()
v_list.append(VFAT.objects.get(ChipID = t_chipid, Slot = chip))
#t_chamberID = 'OHv2aM'#hard code now, read from HW later when available
t_chamberID = 'GTX-'+str(gtx) #use gtx link number now, read from HW later when available
print "t_chamberID = %s" %(t_chamberID)
g_list = []
gebs = GEB.objects.filter(ChamberID=t_chamberID)
t_flag = False
for geb in gebs:
if v_list == list(geb.vfats.all()):
t_flag = True
g_list.append(geb)
break
if t_flag:
pass
else:
print "Update DB"
g = GEB(Type="Long",ChamberID = t_chamberID)
g.save()
for v in v_list:
g.vfats.add(v)
g_list.append(g)
t_flag = False
#t_boardID = "47-20120013"#hard code now, read from HW later when available
t_boardID = "AMC-"+str(amcN)#hard code now, read from HW later when available
a_list = []
amcs = AMC.objects.filter(BoardID = t_boardID)
for amc in amcs:
if g_list == list(amc.gebs.all()):
t_flag = True
a_list.append(amc)
if t_flag:
pass
else:
print "Update DB"
a = AMC(Type="GLIB",BoardID = t_boardID)
a.save()
for g in g_list:
a.gebs.add(g)
a_list.append(a)
# create a new run. Some values are hard-coded for now
runs = Run.objects.filter(Period = "2016T", Type = "bench", Station = "TAMU")
rns = list(int(x) for x in list(runs.values_list("Number", flat=True)))
nrs = u'%s'%(max(rns)+1)
nrs = nrs.zfill(6)
t_date = str(datetime.date.today())
m_filename = "run"+str(nrs)+""+"_bench_TAMU_"+t_date
newrun = Run(Name=m_filename, Type = "bench", Number = str(nrs), Date = datetime.date.today(), Period = "2016T", Station = "TAMU")
newrun.save()
for a in a_list:
newrun.amcs.add(a)
m_AMC13manager.configureTrigger(lt,2,1,int(trigger_rate),0)
updateStatus()
state = 'configured'
except ValueError,e:
print colors.YELLOW,e,colors.ENDC
state = 'halted'
elif 'halt' in request.POST:
form = ConfigForm()
m_AMC13manager.reset()
state = 'halted'
elif 'run' in request.POST:
print "running"
#form = ConfigForm()
updateStatus()
nevents = int(request.POST['nevents'])
t = threading.Thread(target = m_AMC13manager.startDataTaking, args = ["/tmp/"+m_filename+".dat"])
t.start()
state = 'running'
elif 'stop' in request.POST:
m_AMC13manager.stopDataTaking()
updateStatus()
sleep(1)
t_p = threading.Thread(target = parkData)
t_p.start()
state = 'configured'
elif "monitoring" in request.POST:
updateStatus()
#!/usr/bin/python
# This script resets the board
from __future__ import print_function
import uhal
import time
import sys
import collections
uhal.setLogLevelTo(uhal.LogLevel.ERROR)
manager = uhal.ConnectionManager("file://connections.xml")
board = manager.getDevice(sys.argv[1])
board.getClient().setTimeoutPeriod(10000)
v = board.getNode("csr.id").read()
board.dispatch()
print("Board ID:", hex(v))
board.getNode("daq.timing.csr.ctrl.rst").write(1) # Hold clk40 domain in reset
board.dispatch()
board.getNode("csr.ctrl.soft_rst").write(1) # Reset ipbus registers
board.dispatch()
def main():
# configure logger
global log
log = logging.getLogger("main")
formatter = logging.Formatter('%(name)s %(levelname)s: %(message)s')
handler = logging.StreamHandler(sys.stdout)
handler.setFormatter(formatter)
log.addHandler(handler)
log.setLevel(logging.WARNING)
#tell uHAL to calm down.
uhal.setLogLevelTo(uhal.LogLevel.WARNING)
#command line
parser = argparse.ArgumentParser(
description="Create auto-generated files for the build system.")
parser.add_argument("--slavesFile",
"-s",
help="YAML file storing the slave info for generation",
required=True)
parser.add_argument("--addSlaveTCLPath",
"-t",
help="Path for AddSlaves.tcl",
required=True)
parser.add_argument("--addressTablePath",
"-a",
help="Path for address table generation yaml",
required=True)
parser.add_argument("--dtsiPath",
"-d",
help="Path for dtsi yaml",
required=True)
args = parser.parse_args()
#AddSlaves tcl file
tclFile = open(args.addSlaveTCLPath + "/AddSlaves.tcl", "w")
tclFile.write(
"#================================================================================\n"
)
tclFile.write("# Configure and add AXI slaves\n")
tclFile.write("# Auto-generated by \n")
tclFile.write(
"#================================================================================\n"
)
#dtsi yaml file
dtsiYAMLFile = open(args.dtsiPath + "/slaves.yaml", "w")
dtsiYAML = dict()
#address table yaml file
addressTableYAMLFile = open(args.addressTablePath + "/slaves.yaml", "w")
aTableYAML = dict()
#source slave yaml to drive the rest of the build
slavesFile = open(args.slavesFile)
slaves = yaml.load(slavesFile)
for slave in slaves['AXI_SLAVES']:
#update all the files for this slave
LoadSlave(slave, slaves["AXI_SLAVES"][slave], tclFile, dtsiYAML,
aTableYAML, "")
dtsiYAML = {"DTSI_CHUNKS": dtsiYAML}
aTableYAML = {"UHAL_MODULES": aTableYAML}
dtsiYAMLFile.write(
yaml.dump(dtsiYAML, Dumper=MyDumper, default_flow_style=False))
addressTableYAMLFile.write(
yaml.dump(aTableYAML, Dumper=MyDumper, default_flow_style=False))
######################################################################
if __name__ == '__main__':
if len(sys.argv) < 3:
print "Please specify the device IP address" \
" and the top-level address table file to use"
sys.exit(1)
device_ip = sys.argv[1]
device_uri = "ipbusudp-2.0://" + device_ip + ":50001"
address_table_name = sys.argv[2]
address_table_uri = "file://" + address_table_name
uhal.setLogLevelTo(uhal.LogLevel.WARNING)
hw = uhal.getDevice("dummy", device_uri, address_table_uri)
reg_name_base = "sysmon."
regs = ["temp", "vccint", "vccaux", "vrefp", "vrefn", "vccbram"]
max_len = max([len(i) for i in regs])
print "IPBus SysMon/XADC demo:"
for reg_name_spec in regs:
reg_name = reg_name_base + reg_name_spec
node = hw.getNode(reg_name)
val_raw = node.read()
hw.dispatch()
# NOTE: Yes, flexible but ugly.
val = val_raw.value()
def __init__(self, dev_name, man_file):
uhal.setLogLevelTo(uhal.LogLevel.NOTICE
) ## Get rid of initial flood of IPBUS messages
self.dev_name = dev_name
self.manager = uhal.ConnectionManager(man_file)
self.hw = self.manager.getDevice(self.dev_name)
#self.fwVersion = self.hw.getNode("version").read()
#self.hw.dispatch()
#print "--", self.dev_name, "FIRMWARE VERSION= " , hex(self.fwVersion)
# Instantiate a I2C core to configure components
#self.i2c_master= I2CCore(self.hw, 10, 5, "i2c_master", None)
self.i2c_master = I2CCore(self.hw, 10, 5, "io.i2c", None)
# Instantiate a secondary I2C core for SFP cage (not working yet)
#self.i2c_secondary= I2CCore(self.hw, 10, 5, "io.usfp_i2c", None)
# Enable the I2C interface on enclustra
enableCore = True #Only need to run this once, after power-up
self._enableCore()
# Instantiate EEPROM
self.zeEEPROM = E24AA025E48T(self.i2c_master, 0x57)
# Instantiate clock chip
self.zeClock = si5345(self.i2c_master, 0x68)
res = self.zeClock.getDeviceVersion()
self.zeClock.checkDesignID()
# Instantiate expander for the equalizers (IC28)
self.exp_EQ = PCA9539PW(self.i2c_master, 0x74)
self.exp_EQ.setInvertReg(0, 0x00) # 0= normal
self.exp_EQ.setIOReg(0, 0x00) # 0= output <<<<<<<<<<<<<<<<<<<
self.exp_EQ.setInvertReg(1, 0x00) # 0= normal
self.exp_EQ.setIOReg(1, 0x00) # 0= output <<<<<<<<<<<<<<<<<<<
# Instantiate expander for SFP signals (IC29)
self.exp_SFP = PCA9539PW(self.i2c_master, 0x75)
self.exp_SFP.setInvertReg(0, 0x00) # 0= normal
self.exp_SFP.setIOReg(0, 0x00) # 0= output <<<<<<<<<<<<<<<<<<<
self.exp_SFP.setInvertReg(1, 0x00) # 0= normal
self.exp_SFP.setIOReg(1, 0xFF) # FF= input <<<<<<<<<<<<<<<<<<<
# Instantiate expander for LED control (IC27)
self.exp_LED = PCA9539PW(self.i2c_master, 0x76)
self.exp_LED.setInvertReg(0, 0x00) # 0= normal
self.exp_LED.setIOReg(0, 0x00) # 0= output (LED) <<<<<<<<<<<<<<<<<<<
self.exp_LED.setInvertReg(1, 0x00) # 0= normal
self.exp_LED.setIOReg(1, 0x00) # 0= output <<<<<<<<<<<<<<<<<<<
# Instantiate I2C multiplexer
self.mux_I2C = PCA9548ADW(self.i2c_master, 0x73)
# Instantiate a generic SFP transceiver for one of the 8 downstream
self.SFP_ds = SFPI2C(self.i2c_master, 0x50)
# Instantiate CDR for upstream and multiplexer
self.cdr_UPS = ADN2814ACPZ(self.i2c_master, 0x40)
self.cdr_MUX = ADN2814ACPZ(self.i2c_master, 0x60)
#Instantiate Display
doDisplaytest = False
if doDisplaytest:
self.DISP = LCD09052(self.i2c_master, 0x3A) #3A
self.DISP.clear()
self.DISP.test()
