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Target releasealpha 1.0
Epic

LNFDCS-121 - Getting issue details... STATUS

Document status
DRAFT
Document owner

Alessandro Stecchi

Designer
Alessandro Stecchi 
Developers

Alessandro Stecchi Andrea Michelotti 

QA
Alessandro Stecchi 

Goals

  • improve the stability of the DAFNE orbit acquisition system;
  • replace the phisical DEVIL204 with a virtual machine;
  • get rid of the 4 LEXTEL couples by employing the SIS3153 VME Ethernet controllers.

Overall strategy

  • develop and debug the new DEVIL204 along with the regular run of the legacy system;

  • due to safety reasons, the development of the new DEVIL204 takes place on the virtual machine vldantedev038 that temporarily mounts a copy of the dcs_lv12/source_linux actual directory.
    Any VIs and data files created/modified/removed concern the directories:

    /u2/dcs/source_linux/0_classes/GOD/
    /u2/dcs/source_linux/devils/DISARMED/DEVIL204-NEW/
    /u2/dcs/source_linux/lib/lv-vme-chaos-driver/

    Any derogation from this assumption will be highlighted.

Repository

TypeLink / PathNote

git

https://baltig.infn.it/lnf-da-control/lv-dcs-new204
Branch: main

New DEVIL 204 LabVIEW project (for standard "vldantedev" machines)
The only file included in the git repo is GOD.lvproj (no VIs are included in the git repo at this moment.)

Hardware description

TypeDescription
ProcessorStandard DANTE virtual machine vldantedevxxx
VME controllers

Nr. 4 VME controller SIS3153 USB-0 USB3.0-VME Interface with 1 Gbps SFP Tranceiver

VME hardwareStandard Apple DEVILs (364-5-6-7), HP DVM+MUX
HardwareBergotz modules for BPM signal acquisition

Programming languages

LanguageRequired Add ons/Plugins/Extensions/Libraries
LabVIEW 12.0.1f5 (32-bit)

liblv2vmechaos.lvlib (for SIS3153 usage)
git repo: https://baltig.infn.it/chaos-lnf-control/lv-vme-chaos-driver.git
Branch: lv12

Warnings and Fixes to be done


#

Title

User Story

Importance

Notes

1

LNFDCS-137 - Getting issue details... STATUS

As a developer I want a new DEVIL204 control so that I can put it into the new DEVIL204



2

DEVIL204-Global write to memcached LNFDCS-132 - Getting issue details... STATUS

As a developer I want GGODSta.vi and GGODDyn.vi have the "append" and "write" cases ENABLED so that I can validate real memcached write operations.Must Have
  • GGODSta.vi and GGODDyn.vi have the "append" and "write" cases DISABLED for debugging
3
DEVIL204-Update DBFiles LNFDCS-133 - Getting issue details... STATUS
As a developer I want updated versionof DEVILs' DBFiles  so that I can use them for loading data.Must Have
  • At this moment, DBFiles of DEVILs 364, 365, 366, 367 on /u2/dcs/db/DBFile3/ differ from those used by Apple (e.g. DEVIL365 has 24 components instead of 23). 
4
DEVIL204-Program data loading LNFDCS-134 - Getting issue details... STATUS
As a developer I want valid orbit values (that is equal to legacy Apple data) so that I can use the same UI.Must Have
5

DEVIL204-Optimize bundleORB VIs LNFDCS-135 - Getting issue details... STATUS

As a developer I want a fast ORB dataset recontruction so that I can obtain a real time orbit acquisition.Must Have
  • The VIs .../0_classes/GOD/library/fetchORB[Sta|Dyn].vi and their SubVIs .../0_classes/GOD/library/bundleORB[Sta|Dyn].vi must be optimized by moving the code that parses the descriptors in the "init" frame so that it is executed only once.
6

DEVIL204-Database LNFDCS-122 - Getting issue details... STATUS

As a developer I want all the data available in the new program global variables so that I can develop the acquisition code.Must Have
7DEVIL204-DBFilesAs a developer I want the DEVIL204 DBSta and DBDyn in the real working directory so that the DCS can find them where espected.Must Have
  • At this moment the DBFiles have been copied into the directory
    /u2/dcs/source_linux/0_classes/GOD/DBFile2_temporary
  • The LoadRTDB204.vi uses this temporary path
8DEVIL204-HWMaskArray LNFDCS-136 - Getting issue details... STATUS Fix the HW maskMust Have

Al momento la difficoltà maggiore è quella di riottenere una tabella di ordinamento tramite i VIs:
precompileORB.vi
precompileORB_IR.vi
I suddetti VIs sono stati modificati per quanto riguarda il recupero degli indirizzi ma ci sono degli errori.

File ".../0_classes/GOD/configuration/<file name>.lst"

Path: /u2/dcs/source_linux/0_classes/GOD/configuration/

File content
Name azimuth[m] allHOffset[mm] allVOffset[mm] IROffset [mm] refOrbH[m] refOrbV[mm] rotationAngle IP1/IP2 azimuth [m]

GGODSta.vi / DEVIL204.DBSta

This global is initialized with data from the DBSta file. The DBSta file contains dummy data (all zeros) and is only used to correctly dimension the arrays.
The filling of the global with actual data is done via the GODStartup.vi program using the file:

/u2/dcs/source_linux/0_classes/GOD/configuration/<file name>.lst


Static fork descriptor
%GOD
#GOD**001
@HCI(S) [(I32),(DBL),DU32,DU32,DU32,DU32,DU32,DU32,HI32,HI32,HI32,HI32,HI32,HI32,HI32,HI32,HI32:4,HI32:64,HI32:64,DU16:4,DU16:4,DU16:4,DU16:4,(DBL):64,DBL:64,DBL:64,DBL:64,(DBL):64,DBL:64,DBL:64,DBL:64,(DBL):64,(DBL):64,DBL:64,DBL:64,DBL:64,DBL:64,DBL:64,DBL:64,DBL:64,DBL:64,DBL:64]


GGODDyn.vi / DEVIL204.DBDyn

This global is initialized with data from the DBDyn file. The DBSta file contains almost only dummy data and is mainly used to correctly dimension the arrays.
The filling of the global with actual data is done via the GODStartup.vi program using:

  • the content of the dynamic fork of the ORB element of DEVIL364 (the master of the 4 DEVILs)
  • the value of a string hard coded into the DEVIL204 control program.

Dynamic fork descriptor
%GOD
#GOD**001
@HCI(S) [(DBL),DI32,DU32,DU32,DI32,TF,TF,TF,TF,DI32,DU16:32,TF,TF,TF,TF,DI32,DI32,DI32,DI32,DI32,DI32,DI32,DU16:4,DU16:4,DU16:4,DU16:4]


GGODConnection.vi

The purpose of this global is to keep all program data in one place, but a reorganization in the final version is strongly recommended. At the present moment some fields contain constant values (saved as defaults), others are written at init by the application. 

Variables

Data type

Name

Type

Description

Data type

Name

Type

Description

abcDEVILconstant[ 364, 365 ,366, 367 ] (see fig. 1-a, 1-b)
abcelementconstant

[ ORBRAK63, ORBRAK71, ORBRAK70, ORBRAK66 ]
The sequence is sorted according to the direction of the beam for the electronic mode: clockwise, starting from rack 063 (DEVIL364)

abccontrollerIPconstant[ 192.168.192.91, 192.168.192.92, 192.168.192.93, 192.168.192.94 ]
The sequence is sorted according to the direction of the beam for the electronic mode: clockwise, starting from rack 063 (DEVIL364)
U32vme handle
Written at startup by the initHWGOD.vi
U32DEVILBaseAddressconstant0xE0000000 for all 4 DEVILs
U32DEVILBufferOffsetconstant0x200000 (2 MB) for all 4 DEVILs
abcHCIDynDescriptorconstant

It varies depending on the DEVIL36X.DBDyn content

In order to fill the ORBHCIDyn cluster with data read from the SIS3153 interface, we read "HCIDynNumOfLongwords" longwords starting from "HCIDynOffset. Data are then passed to the VI
.../0_classes/GOD/library/VMEMemToORBDyn.vi
that reconstructs the ORBHCIDyn cluster by using the "HCIDynDescriptor".

U32HCIDynOffsetconstantPosition of the dynamic fork in the DEVIL memory. It varies depending on the lenght of other data written before in memory
U32HCIDynNumOfLongwordsconstantThe 4 HCIDyn have different length but we use a safe value to fetch any of them without missing any piece of data. The value is set to 64 longwords.
abcHCIStaDescriptorconstant

 It varies depending on the DEVIL36X.DBSta content

In order to fill the ORBHCISta cluster with data read from the SIS3153 interface, we read "HCIStaNumOfLongwords" longwords starting from "HCIStaOffset. Data are then passed to the VI
.../0_classes/GOD/library/VMEMemToORBSta.vi
that reconstructs the ORBHCISta cluster by using the "HCIStaDescriptor".

U32HCIStaOffsetconstantPosition of the static fork in the DEVIL memory. It varies depending on the lenght of other data written before in memory.
U32HCIStaNumOfLongwordsconstantThe 4 HCISta have different length but we use a safe value to fetch any of them without missing any piece of data. The value is set to 240 longwords.


Turn for electronsTurn for positrons



Figure 1-a: The sequence [0,1,2,3] is sorted according to the direction of the electrons beam: starting from rack 063 (DEVIL364 > 365 > 366 > 367)

Figure 1-b: The sequence [1,0,3,2] is sorted according to the direction of the positrons beam:, starting from rack 071 (DEVIL365 > 364 > 367 > 366)

initHWGOD.vi

Open the IP connections with the four VME SIS3153 controllers and return the connection handles.
The VME access is A32, D32 and "block transfer" is enabled.
The VME mapped size is 4 MByte (that is the whole Apple DEVIL memory).
The vme_base_address is set to E0000000 (which is the DEVIL extended base address).

Controls

Data type

Name

Description

BoolddInLegacy data-dependency input

Indicators

Data type

Name

Description

BoolddOut

Legacy data-dependency output.
The connector pane pattern for all initHWXXX VIs is fixed and mandatory and – for (wrong) historical reasons – it has no indicator returning the error.
The error is returned in ddOut as a boolean obtained from the status element of the output error cluster of the vme_open SubVI.

ddOut = True indicates that an error occourred in the vme_open

Details

The connector pane pattern for all initHWXXX VIs is fixed and mandatory and – for (wrong) historical reasons – does not return any errors.

Examples

---

GODStartup.vi

This is the real data loader of the GODSta.vi 

Controls

Data type

Name

Description

errorClustererrorIn

Indicators

Data type

Name

Description

errorClustererrorOut

Details

Configuration folder /u2/dcs/source_linux/0_classes/GOD/configuration
has been copied from vldafneafp to vldantedev038

Examples

---

closeGOD.vi

Close the IP connections with the four VME SIS3153 controllers and dispose the connection handles.

Controls

Data type

Name

Description

BoolddInLegacy data-dependency input
errorClustererrorIn


Indicators

Data type

Name

Description

BoolddOutLegacy data-dependency output
errorClustererrorOut

Details

---

Examples

---

Turn for electronsTurn for positrons



Figure 1-a: The sequence [0,1,2,3] is sorted according to the direction of the electrons beam: starting from rack 063 (DEVIL364 > 365 > 366 > 367)

Figure 1-b: The sequence [1,0,3,2] is sorted according to the direction of the positrons beam:, starting from rack 071 (DEVIL365 > 364 > 367 > 366)

Details

---

Examples

---

readDEVILBufferLine.vi

This VI reads and returns the last data acquired from the 4 DEVILs. It doesn't perform any data reordering (see "Details" paragraph below).

Controls

Data type

Name

Description

booleaninit

T = initialize, F = regular run
init = T: some constant values are loaded into the VI shift registers.

init = F: reads the socket "socketNumber" from the VME memory of the DEVIL "DEVILIndex" and returns the two parts 

I32DEVILIndex

Index in the range [0, 1, 2, 3] corresponding to:

INDEX   0,   1,   2,   3
DEVIL 364, 365, 366, 367
RACK   63,  71,  70,  66
I32socketNumberPointer to the acquisition buffer in the range [0, 1926]
[DBL]part XArray of 32 DBL components containing the raw values of the X signals coming from both electron and positron BPMs. The components are in the same order of the values in the DEVIL memory locations.
[DBL]part YArray of 32 DBL components containing the raw values of the Y signals coming from both electron and positron BPMs. The components are in the same order of the values in the DEVIL memory locations.
errorClustererrorIn

When true, the VI does nothing and simply passes the error out.

Indicators

Data type

Name

Description

[DBL]part XArray of 32 DBL: see corresponding control description above. The array is returned both for read and write operations.
[DBL]part XArray of 32 DBL: see corresponding control description above. The array is returned both for read and write operations.
errorClustererrorOut[ACQ numbers mismatch (num0, num1, num2, num3)]

Details

Each one of the 4 DEVILs has a circular buffer of 1927 lines named "sockets". Write operations of the four circular buffers are synchronized via a common stobe so that the four write pointers are always alligned. At each strobe, each DEVIL stores a "socket" composed as:

  • Header
DBL   ACQNum [0, 1926];
DBL   timestamp (LabVIEW Time Stamp cast to DBL).
      example: 00:00:00.000 PM
               MM/DD/YYYY

The socket header is written twice: at the beginning of the socket (before part X) and again in the middle of the socket (before part Y) the content of the two headers being the same; this is due to historical reasons and – although it is a waste of memory space – it was left in order not to compromise the functioning of other pieces of code that access the same memory area.

  • part X
[DBL]   32 values of the BPM X signals from the Bergoz modules read from that DEVIL;
  • part Y
[DBL]   32 values of the BPM Y signals from the Bergoz modules read from that DEVIL.

The 32 components in part X and Y are ordered according to the cabling and do not necessarily follow the sequence of the BPMs along the vacuum chamber. Moreover the 32 values refer to both e- and e+ rings for which the BPMs sequence is obviously different. As a consequence, part X and Y must be considered as raw containers and their content must be further processed in order to reconstruct the real orbit.

Examples

---

GRawBuffer.vi

This VI is a functional global that stores, holds and returns the last X and Y parts acquired from the 4 DEVILs. It doesn't perform any data reordering. Data are not queued: each write operation with the same DEVILIndex overwrites the previous one.

Controls

Data type

Name

Description

I32DEVILIndex

Index in the range [0, 1, 2, 3] corresponding to:

INDEX   0,   1,   2,   3
DEVIL 364, 365, 366, 367
RACK   63,  71,  70,  66
enummode

[init, read, write X and Y, write X, write Y] (read)

  • init: the internal shift register are initialized (all zeros);
  • read: returns "part X" and "part Y" from the arrays specified by "DEVILIndex";
  • write X and Y: stores simultaneously"part X" and "part Y" into the arrays specified by DEVILIndex. Both inputs must have 32 components otherwise no one of them will be stored;
  • write X: stores "part X" only to the buffer specified by DEVILIndex. The array must have 32 components otherwise it will not be stored. The "part Y" array is kept unmodified;
  • write Y: stores "part Y" to the buffer specified by DEVILIndex. The array must have 32 components otherwise it will not be stored. The "part X" array is kept unmodified.
[DBL]part XArray of 32 DBL components containing the raw values of the X signals coming from both electron and positron BPMs. The components are in the same order of the values in the DEVIL memory locations.
[DBL]part XArray of 32 DBL components containing the raw values of the Y signals coming from both electron and positron BPMs. The components are in the same order of the values in the DEVIL memory locations.
errorClustererrorIn


Indicators

Data type

Name

Description

[DBL]part XSee corresponding control description above. The X array is returned both for read and write operations.
[DBL]part XSee corresponding control description above. The Y array is returned both for read and write operations.
errorClustererrorOut

Details

Write operation for both X and Y arrays: DEVILIndex selects the same lines of the two blocks and stores the two arrays. The previous content of the two lines is overwritten.

Examples

---


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