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Present Online Architecture ALICE Mar.2012P. Vande Vyvre – CERN/PH3 GDC TDSM CTP LTU TTC FERO LTU TTC RCU LDC BUSY Rare/All Event Fragment Sub-event Event File Storage Network PDS L0, L1a, L2 360 DDLs D-RORC EDM LDC D-RORC Load Bal. LDC D-RORC HLT Farm FEP H-RORC DDL H-RORC 10 DDLs 10 D-RORC 10 HLT LDC 120 DDLs DA DQM DSS Event Building Network 430 D-RORC 125 Detector LDC 75 GDC 30 TDSM 18 DSS 60 DA/DQM 75 TDS Archiving on Tape in the Computing Centre (Meyrin)
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ALICE Online Upgrade
P. VANDE VYVRE – CERN/PH
ALICE meeting in Budapest – March 2012
ALICE Mar.2012 2
A quick look to the past:the DDL and the D-RORC
•Project started in 1995•Strong push from the management:
George Vesztergombi and now Peter Levai •Work of a solid and competent team:
Ervin Denes, Tivadar Kiss, Gyorgy Rubin, Csaba Soos, and many others contributed to this successful project
•The Budapest team delivered to the ALICE experiment a common and reliable solution for the data transfer from the detectors to the online systems : the DDL and the D-RORC
P. VANDE VYVRE CERN-PH
ALICE Mar.2012 3
Present Online Architecture
P. Vande Vyvre – CERN/PH
GDC TDSM
CTP
LTU
TTC
FERO FERO
LTU
TTC
RCU RCU
LDCLDC
BUSY BUSY
Rare/All
Event Fragment
Sub-event
Event
FileStorage Network
PDS
L0, L1a, L2
L0, L1a, L2
360 DDLsD-RORCD-RORC
EDM
LDC
D-RORC D-RORC
Load Bal. LDC LDC
D-RORC D-RORC
HLT Farm
FEPFEP
H-RORC H-RORC
DDL
H-RORC
10 DDLs
10 D-RORC
10 HLT LDC
120 DDLs
DADQM DSS
Event Building Network
430 D-RORC
125 Detector LDC
75 GDC30 TDSM 18 DSS60 DA/DQM
75 TDS
Archiving on Tapein the ComputingCentre (Meyrin)
ALICE Mar.2012 4
DDL and D-RORC
P. Vande Vyvre – CERN/PH
•~ 500 DDLs and ~450 D-RORCs
•Collect all the data of ALICE (~2 PB/year)
•Configure the electronics of several detectors, in particular the biggest one (TPC)
•Goal for the future: Repeat this success story !
ALICE Mar.2012 5
ALICE Upgrade Strategy• Input from Luciano and PBM, Thorsten and Volker, DAQ team • Strategy recently approved by ALICE presents a global and coherent
plan to upgrade the experiment for 2018 (Long Shutdown 2 LS2)• “Upgrade Strategy for the ALICE Central Barrel”
https://aliceinfo.cern.ch/ArtSubmission/node/108•Key concepts for running the experiment at high rate
• Pipelined electronics• Triggering the TPC would limit this rate → Continuous readout• Reduce the data volume by topological trigger and online reconstruction
•Major upgrade of the detector electronics and of the online systems• Online upgrade design:
•Data buffer and processing off detector •Fast Trigger Processor (FTP): 2 hw trigger levels to accommodate
various detector latencies and max. readout rate•HLT: 2 sw trigger levels:
• ITS, TRD, TOF, EMC (reduce the rate before building TPC event)• Final decision using the data from all detectors
•Common DAQ /HLT farm to minimize cost while preserving the present flexibility of running modes
P. VANDE VYVRE CERN-PH
ALICE Mar.2012 6
Trigger Rates
P. VANDE VYVRE CERN-PH
• Key concepts for running ALICE at high rate• Hardware trigger-less architecture whenever needed and affordable• Pipelined electronics and continuous readout• Reduction of the data volume by topological trigger and 2 steps online reconstruction
Trigger Levels
DetectorsTrigger with
pp beamsTrigger with Pb-Pb beams
Frequency (kHz)
Latency Frequency (kHz)
Latency
No Trigger ITS, TPC, TRD, EMCal, PHOS
Continuous read-out at 10 MHz
Level 0 (hw) TOF (Pb-Pb) 2000 1.2 s 50 1.2 s
Level 1 (hw) TOF (p-p), Muon 10-20 10 s 20 10 s
Level 2 (sw) 10-25 1 s
Level 3 (sw) 5-25 10 s
ALICE Mar.2012 7
Present TPC Readout
P. VANDE VYVRE CERN-PH
RCUCTP
FEC
DAQ
HLT
216
160 MB/s
216
DDL 2.0 Gb/s
216
DDL 2.0 Gb/s
FEC
1
12
216
TTC
FEC216
160 MB/sFEC
1
13
• Present readout : •Links: DDL at 2 Gb/s. 216 DDLs for the TPC used at 1.6 Gb/s •PC adapters: D-RORC and H-RORC•Up to 6 RORCs/PC
DRORC
HRORC
ALICE Mar.2012 8
Future evolution of DDL & RORC
P. Vande Vyvre – CERN/PH
•New common DAQ/HLT DDL2 and RORC2•Prototype under design by Heiko Engel (Udo Kebschull’s team/Frankfurt) and Tivadar Kiss (Budapest) (Ready in 2012)
• It will address the upgrade needs with the present architecture for the period (2014-16) between Long Shutdown 1 (LS1) and LS2
• Includes 12 DDL2 links at 6 Gb/s. 6 links to DAQ LDC 36 Gb/s.•PCIe V2 8 lanes (500 MB/s/lane) 32 Gb/s of I/O capacity. •Data processing in the FPGA (e.g cluster finding)
444
• Currently: 5 links at 2Gb/s per PC 10 Gb/s of I/O capacity
• Prototype under development• 12 links at 6 Gb/s• 6 links to DAQ LDC 36 Gb/s.• PCIe Gen2 8 lanes (500 MB/s/lane)
32 Gb/s of I/O capacity• Final system
• 12 links at 10 Gb/s per PC• PCIe Gen3 16 lanes I/O 128 Gb/s
ALICE Mar.2012 9
Readout Upgrade
P. VANDE VYVRE CERN-PH
FEC2 EPN600
10.0 or 40Gb/s
FLP 10 Gb/s~7000
Network
DAQ and HLT systems
600
10.0 or 40Gb/s• Upgrade readout:
•Non-zero suppressed TPC data 57 Tb/s (570 kchannels x 10 bits x 10 MHz)•~7000 links at 10 Gb/s for TPC. ~7800 links for the whole experiment.•TBD: FEC2 characteristics (GEM readout, very simple FEC vs more links)
• DDL3 and RORC3 for LS2 upgrade (ALICE common solution)•Address the needs of the new architecture for the period after LS2 (2018)•DDL3 links at 10 Gb/s
• Exact requirements to be addressed (radiation tolerance/hardness)• Different physical layers possible (CERN GBT, Eth, FCS, wavelength multiplex.)
• First-Level Processors (FLPs)•~650 FLPs needed: 12 detector links 10 Gb/s, 1 network link at 10 or 40 Gb/s •Data readout and first-level data processing:
• ZS, cluster finder and compression could be performed by the RORC FPGA• Regional online reconstruction
ALICE Mar.2012 10
Continuous Readout
P. Vande Vyvre – CERN/PH
Time t+3x t+2x t+x tt-x t-2x
TRD
EMC
TPC
ITS
TOF
Events n+2 n+1n
FLP
Event Building &Processing
ALICE Mar.2012 11
Online reconstruction
P. Vande Vyvre – CERN/PH
• 50 kHz Pb–Pb collisions inspected with the least possible bias using topological triggers and on-line particle identification
• HI run 2011: online cluster finding data compression factor of 4 for TPC• Two HLT scenarios for the upgrade:
1. Partial event reconstruction: Further factor of 5 → overall reduction factor of 20. Close to what could be achieved and tested now. Rate to tape: 5 kHz.
2. Full event reconstruction: Overall data reduction by a factor of 100. Rate to tape: 25 kHz.HI run 2018: min. bias event size ~75 MB ~4-1 MB after data volume reduction. Throughput to mass storage: 20 GB/s.
• Target rate after LS2 can only be reached with online reconstruction• Build on success of last year with TPC cluster finding • Extremely ambitious: online calibration and data processing• Essential to gain experience with using online results as basis of offline
reconstruction, e.g. the cluster finding. Mandatory to reach the necessary data reduction factor after LS2.
ALICE Mar.2012 12
Processing Power
P. Vande Vyvre – CERN/PH
Current HLTCurrently HLT processing rates with full TPC reconstruction:
• Either ~200 Hz central events (65 MB) or ~800Hz min bias events• 216 front-end nodes (equivalent to the FLPs)
• TPC cluster finder on H-RORC FPGA and coordinates transformation by the CPU• 60 tracking nodes with GPU (equivalent of the EPNs)
HLT• Assuming linear scaling of rates and
using current HLT technology:• Level 2 (reconstruction using ITS, TRD, EMC)
• 50 kHz min bias events (15 MB, ~4 times less CPU) →50 kHz/800Hz*60 nodes*1/4= 1250 nodes (CPU+GPU)
• Level 3 (full reconstruction incl. TPC)• 25 kHz central events →
25 kHz/200Hz*60 nodes = 7500 nodes (CPU+GPU)• 8750 nodes of 2011 → 1250 nodes of 2018
Event Processing nodes ~1250 EPNs
• Current HLT processing nodes:• Intel Xeon E5520, 2.2 GHz 4 cores
Global track merging + reconstruction, some trigger algorithms
• Nvidia GTX480/580 ~90% of the tracking
• Performance gain 33%/yr during 7 yearsFactor 7 from 2011 to 2018
• Overall chip performance gain →Significant R&D on computing and algorithms concepts
ALICE Mar.2012 13
Network Routers and Switchesfor the Event Building
P. Vande Vyvre – CERN/PH
•Present DAQ network (Force 10 now DELL)•Exascale E1200i 3.5 Tb/s•Capacity of present DAQ router not adequate
•Technology 1: Ethernet (Brocade MLX Series)•MLX32e up to 15.3 Tb/s, 32 line card slots
Up to 256x10GbE ports, 32x100GbE ports•Line cards: 2x100 Gb/s or 8x10 Gb/s
• Technology 2: Infiniband (Mellanox)• MIS6500 up to 51.8 Tb/s, 648 ports at 40 Gb/s
ALICE Mar.2012 14
Network Layout Infiniband
P. Vande Vyvre – CERN/PH
Event building and HLT network
- 3 data flows- Total network throughput: 17.2 Tb/s
- Input to HLT L2: 10 MB/evt at 50 kHz → 500 GB/s → 4.0 Tb/sAll detectors but TPC
- Input of TPC to HLT L3: 65 MB/evt at 25 kHz → 1625 GB/s → 13.0 Tb/s-Output of HLT L3 (data recording):20 GB/s → 0.2 Tb/s
Two possible technologies (Ethernet and Infiniband)
120 x 40 Gb/s
…
120 x 40 Gb/s 120 x 40 Gb/s
1 475
1
1 475
2
1 475
4
Infiniband (Mellanox)MIS6500 up to 51.8 Tb/s, 648 ports at 40 Gb/s• Data traffic: ~650 FLPs and ~1250 EPN
Total ~1900 ports 40 GbE. • Satellite routers:
500 ports: data traffic to/from the nodes120 ports: data traffic to/from the main router
• Total throughput:4x120x40 Gb/s = 19.2 Tb/s
ALICE Mar.2012 15
Upgrade Online (after LS2)
P. VANDE VYVRE CERN-PH
10 Gb/sor
40 Gb/s
FLP 10 Gb/s
L2
Network
DAQ and HLT
10 Gb/sor
40 Gb/s
FLP
EPNFLP
TPC
TRD
Muon
FTPL0L1
FLPTOFEPN
FLPITS
L3
L3
FLP
FLPPHOS
FLPEMC
Trigger Detectors ~ 650 FLPs ~1250 EPNs
~7800 DDL3
ALICE Mar.2012 16
Next Steps
P. Vande Vyvre – CERN/PH
•Major upgrade foreseen for the online systems during LS2• Improve the Strategy Note (Mar ‘12)•More detailed and optimized cost estimate (Mar ‘12)
•Prototyping, some using the present online systems (‘12)•Continue to gain experience with using HLT online results as basis of
offline reconstruction, e.g. the cluster finding•Essential to reach the necessary data reduction factors after LS2
•R&D program (‘12-’16)•Fast Trigger Processor•Readout links•Event-building and HLT dataflow network •Online reconstruction: online use of “offline software”•Efficient use of new computing platforms (many-cores and GPUs)
•Online Conceptual Design Report (TBD)•Requirements from detectors•Key results from R&D