the read-out crate in the atlas daq/ef prototype -1
DESCRIPTION
The Read-Out Crate in the ATLAS DAQ/EF prototype -1. The Read-Out Crate model The Read-Out Buffer The ROBin ROB performance ROC performance I/O module configurations Conclusions. G.Ambrosini, E.Arik, H.P.Beck, S.Cetin, T.Conka, A.Fernandes, D.Francis, - PowerPoint PPT PresentationTRANSCRIPT
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CHEP 2000Padova
Stefano Veneziano
The Read-Out Crate in the ATLAS DAQ/EF prototype -1
• The Read-Out Crate model
• The Read-Out Buffer
• The ROBin
• ROB performance
• ROC performance
• I/O module configurations
• Conclusions
Y.Hasegawa, M.Joos, G.Lehmann, J.Lopez, A.Mailov, L.Mapelli,
G.Mornacchi, Y.Nagasaka, M.Niculescu, K.Nurdan, J.Petersen,
D.Prigent, J.Rochez, L.Tremblet, G.Unel, S.Veneziano, Y.Yasu
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CHEP 2000Padova
Stefano Veneziano
ATLAS DAQ/EF
LDA
EF SubFarm
SFOQ
SFI
LDA
ReadoutBuffers
TRGQ
EBIF
Switching Network
Detector Electronics
Farm DAQ
SwitchSupervision
Mass Storage
DFM+ LDAQ
Front End DAQ
From triggerTo level 2
Event Builder
LDA
ReadoutBuffers
TRGQ
EBIF
systems (L2A, L2R, ROI)
consisting of read-out crates
consisting of sub-farm crates
Input Rate
75 - 100 kHz
Bandwidth
~100 MB/s
1- 2 kHz 4-5 GB/s
LDA
EF SubFarm
SFOQ
SFI
ROC
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CHEP 2000Padova
Stefano Veneziano
Read-Out Crate logical model
The ROC performs:• data collection from many readout links• event buffering during LVL2 latency• event fragment distribution to Event Builder and LVL2
External I/O channels
External I/O channels
Internal I/O channels
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CHEP 2000Padova
Stefano Veneziano
The I/O Module– Each I/O channel, external or
internal, has an associated Task
– A Task is activated on the occurence of stimuli (messages or event data)
– An I/O Module (IOM) is a collection of Tasks associated to an external I/O channel.
– All Tasks belonging to an IOM are scheduled within a single process and activated by polling conditions (scheduler)
– Event manager API
– All components within a ROC communicate via a well defined message passing protocol
• the baseline implementation of the ROC crate, VMEbus based one Single Board Computer (SBC) per IOM, has evolved to a collapsed solution, where a SBC can handle many external I/O channels.
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CHEP 2000Padova
Stefano Veneziano
Message passing• Based on circular buffers
• Supported buses: VMEbus, PVIC, PCI, CPU bus, EBIO (TCP/IP)
• Duplication of R/W pointers ==> no polling on the bus
• DMA and broadcast used where possible
PCI DMA
0
20
40
60
80
100
0 500 1000 1500 2000 2500
message size (bytes)
tim
e/m
ess
ag
e (
sec)
Two receivers
One receiver
0
5
10
15
20
25
30
35
0 200 400 600 800 1000 1200
message size (bytes)ti
me
/ m
es
sa
ge
(s
ec
)
Five receivers
One receiverPVIC
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CHEP 2000Padova
Stefano Veneziano
The MFCC based ROBin
The CES MFCC 8441 is a commercially available intelligent PMC– I/O: via user programmable 10k50ev front-end FPGA
– Same S/W environment as on SBC (LynxOS 3.0.1)
Today’s ROB implementation minimizes movement of event fragments over the system bus (need to receive and buffer events of 1 kB at 100 kHz), by using an add-on PMC card (one per Read-Out Link).
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CHEP 2000Padova
Stefano Veneziano
The ROBin software
• No device drivers, minimal operating system calls.
• Single process, scheduler, three tasks to manage one ROL, one internal I/O to ROB-host + firmware.
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CHEP 2000Padova
Stefano Veneziano
ROBin firmware
• Firmware on FPGA from VHDL synthesis (40/66 MHz clk):•PPC master and slave•interface to ROL protocol (S-link)•Buffer manager and DMA manager state machines•2 kB data fragment buffering•communication to ROBin task via two FIFOs (EM pages stats)
PPC
ROL (S-link)603
sdram
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CHEP 2000Padova
Stefano Veneziano
ROBin interactionROBin application interacts with ROB-host and event data source (FE-FPGA)
The following ROB performance results rely on test programs running on the ROB-host on:• Event Location• Event Deletion• Event Retrieval
Scheduler loop
ROBinROB-host PCI
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CHEP 2000Padova
Stefano Veneziano
Event location
•Messages over the PPC-PCI-PPC buses
•No S-Link I/O
•No broadcast mechanism
•Best arrangement of events into memory (one event per class)
EM_GetById - sequential IDs
0.0
10.0
20.0
30.0
40.0
50.0
60.0
0 1 2 3 4
number of MFCCs
rate
(kH
z)
PPC MEM
PCI bus
RIO2 8062
PPC MEM
MFCC 8441 PMC
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CHEP 2000Padova
Stefano Veneziano
Event retrieval
• Messages: single cycles
• Event data transfer: DMA
• Transfer bandwidth: ~50 MB/s
EM_GetByIdCopy
0
10
20
30
40
50
0 256 512 768 1024
event size (bytes)
rate
(kH
z).
1 MFCC2 MFCCs3 MFCCs4 MFCCs
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CHEP 2000Padova
Stefano Veneziano
Event deletion
• No input of new events, only messages over the system bus.
• Messages sent in DMA mode
• Several delete requests packed into one message
• Delete requests get acknowledged
EM_DeleteById
0
100
200
300
400
500
600
0 10 20 30 40 50 60
L2R group size
rate
(k
Hz)
1 MFCC2 MFCCs3 MFCCs4 MFCCs
No event regeneration# pages/event = 1# events/class = 1
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CHEP 2000Padova
Stefano Veneziano
S-Link measurements
• Rate dominated by event fragment input traffic
• Max. input rate in best conditions = 145 MB/s (with no messages from ROB-host)
(SLIDAS max bandwidth is 160 MB/s)
EM_DeleteById (with SLIDAS, single cycle message passing, preliminary)
0
25
50
75
100
125
150
0 10 20 30 40 50
L2R group size
rate
(kH
z)
1016 bytes/event504 bytes/event248 bytes/eventpages/event=1
One ROBwith one ROBin
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CHEP 2000Padova
Stefano Veneziano
ROC measurements
• No S-Link, input emulated
• All ROB<->ROBin messages sent in single cycle mode
• rate dominated by PCI traffic and ultimately by MFCC CPU to ~120 kHz0
20
40
60
80
100
120
140
0 1 2 3 4
number of MFCCs
eve
nt
rate
(kH
z)
1% L2A
5% L2A
PPC MEMDMA
PPC MEMDMA
PCI bus PCI bus
VMEbus
PVICPVIC PMC PVIC PMC
RIO2 8062 RIO2 8062DMA DMA
Event data
(Messages)
Messages+
Event data
Input fragments
+Messages
+Event data
PPC
Not used
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CHEP 2000Padova
Stefano Veneziano
I/O modules configurations
ROC Event Rates
0
20
40
60
80
100
120
140
160
180
200
even
t ra
te (
kHz)
TRG + EBIF + ROBs
TRG/ EBIF + ROBs
TRG + EBIF/ ROBs
TRG/ EBIF/ROBs
One ROBNo ROBins
T E R R R
TE E ER R R
TE
R R RT
E E ER R RT T T
To further minimize data movement and message passing, more than one external input can be handled by an IOM
TRG ROLs
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CHEP 2000Padova
Stefano Veneziano
ROC Event Rates with ROBins
ROC Event Rate vs. # ROBins
80
90
100
110
120
0 1 2 3 4 5
Number of ROBins per ROB
Eve
nt
Ra
te (
kHz)
TRG + EBIF + ROBsTRG/EBIF + ROBsTRG + EBIF/ROBsTRG/EBIF/ROBs
Max event rate increases when data collection (ROBins to EBIF) is done on the same SBC.Expected ATLAS max ROL bandwitdh 1KBX75(100) kHz
1KB event fragments
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CHEP 2000Padova
Stefano Veneziano
Conclusions
• A Read-Out Crate based on the DAQ/-1 design and deployed on COTS components has the functionality required by the ATLAS Trigger/DAQ community
• Software layering and minimal dependence of the software packages on the operating system adds flexibility without a degradation of performance. It also facilitates porting (move to Motorola/Linux or Intel/Linux)
• The requirements of many Read-Out Links per Read-Out Buffer have lead to the design of the ROBIN, capable of receiving Event data fragments at the expected Level-1 rates.