DS-DM: Difference between revisions

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* https://bitbucket.org/team-ds-dm/phasemeasurement - VX Phase measurement script
* https://bitbucket.org/team-ds-dm/phasemeasurement - VX Phase measurement script
* https://ladd00.triumf.ca/daqinv/frontend/list/178 - inventory database
* https://ladd00.triumf.ca/daqinv/frontend/list/178 - inventory database
* https://daq00.triumf.ca/elog-ds/DS-DAQ - DS-DAQ elog
* https://bitbucket.org/ttriumfdaq/dsproto_vx2740/src/develop/ - VX DSFE MIDAS frontend
* https://dsdaqgw.triumf.ca/vslice/ - vertical slice DAQ
* https://daq00.triumf.ca/DaqWiki/index.php/DarkSide - DS-DAQ Wiki page
* https://edev-group.triumf.ca/hw/exp/dark-side-20k/dark-side-iogc/rev0 - GPS and Rb Clock adapter board


= Onboard hardware =
= Onboard hardware =
Line 38: Line 43:
* USB UART for Enclustra serial console, micro-USB, 115200n8
* USB UART for Enclustra serial console, micro-USB, 115200n8
* clock chip: SI5394A-A-GM and oscillator CS-044-054.0M (54 MHz)
* clock chip: SI5394A-A-GM and oscillator CS-044-054.0M (54 MHz)
* U23 3.3V current meter and thermometer
* U23 3.3V current meter and thermometer, LTC2990IMS#TRPBF
* LEDs:
* LEDs:
** LED_FP A/B/C/D 0/1/2/3
** LED_FP A/B/C/D 0/1/2/3
Line 113: Line 118:
0 .. 7 -> N/C
0 .. 7 -> N/C


8 -> VX_RX(3)
8 -> VX_RX(3) - not used
9 -> VX_RX(2)
9 -> VX_RX(2) - busy VX to CDM
10 -> VX_RX(1)
10 -> VX_RX(1) - DS20K 125 MHz serial data VX to CDM
11 -> VX_RX(0)
11 -> VX_RX(0) - DS20K 62.5MHz clock VX to CDM


12 <- VX_TX(0)
12 <- VX_TX(0) - TRG CDM to VX
13 <- VX_TX(1)
13 <- VX_TX(1) - TSM CDM to VX, to be VETO CDM to VX
14 <- VX_TX(2) (set by jumper routed here or to VX CLKIN SYNC)
14 <- VX_TX(2) (set by jumper routed here or to VX CLKIN SYNC) - 125 MHz serial data CDM to VX
15 <- n/c (CLK routed to VX CLKIN CLK)
15 <- n/c (CLK routed to VX CLKIN CLK) - 62.5 MHz clock CDM to VX


16 - n/c
16 - n/c
Line 184: Line 189:
</pre>
</pre>


= Clock distribution =
= Clock distribution Rev0 =


Simplified:
Simplified:
Line 251: Line 256:
</pre>
</pre>


= I2C bus =
= Clock distribution Rev1 =


* I2C_SCL is J-ENC-A pin 111 I2C_SCL is FPGA I2C_SCL_PL AB13 (IO_L1N_TOL1D_64) and I2C_SCL_PS F18 (PS_MIO10)
Simplified:
* I2C_SDA is J-ENC-A pin 113 I2C_SDA is FPGA I2C_SDA_PL AH13 (IO_L7N_T1L1Q_AD13N_64) and I2C_SDA_PS G18 (PS_MIO11)


* XU8 secure EEPROM ATSHA204A at 0x64, this is 0110'010X -> linux _011'0010 is 0x32. (but responds to scan and read at 0x33)
* 125 MHz osc -> CLK_XO_125 -> MGTREFCLK0_A -> not used
* U4 ethernet mac chip, EEPROM at 1010 A2 A1 A0 X and MAC/serial_no at 1011 A2 A1 A0 X. A0=VCC, A1=VCC, A2=GND -> linux _101'0011 and _101'1011 is 0x53 and 0x5B.
* 125 MHz osc -> CLK3_XO_125 -> MGTREFCLK1_B -> SFP RX ref clock
* U6 clock chip, address 1101 0 A1 A0 X. A1=VCC, A0=N/C (internal pull-up) -> linux _110'1011 is 0x6b
* 125 MHz osc -> C.C. in1
* U23 voltmeter at 10011 ADR1 ADR0. ADR0=GND, ADR1=VCC -> linux _100'1110 is 0x4e
* SFP, address 1010000X -> linux _101'0000 is 0x50. additional SFP data at 0x51
* QSFP0, QSFP1, QSFP2, QSFP3 (QSFP0_SEL, QSFP1_SEL, QSFP2_SEL, QSFP3_SEL)


= I2C clock builder connection =
* C.C. in0 <- CLK_EXT1 (10 MHz GPS clock)
* C.C. in1 <- 125 MHz osc
* C.C. in2 <- CLK_CC_IN <- FPGA AK9,AK8 <- SFP RX recovered clock, 125 MHz
* C.C. in3 <- CLK_FB


* use Silicon Labs USB "Clock builder pro field programmer", www.silabs.com/CBProgrammer
* C.C. 125 MHz -> CLK_CC_OUT0 -> MGTREFCLK0_B -> QSFP RX and TX ref clock
* connect rainbow jumper cable pins:
* C.C. 125 MHz -> CLK_CC_OUT1 -> MGTREFCLK1_D -> SFP TX clock
** black - 1-GND to GND on DS-DM
* C.C. 125 MHz -> CLK_CC_OUT2 -> FPGA AG8,AH8 (GC) -> not used
** white - 3-SCLK to SCL on the DS-DM
* C.C. 62.5 MHz -> VX clock fanout
** grey - 7-SDA_SDIO to SDA on the DS-DM
* power up the DS-DM
* plug USB programmer into Windows laptop
* on Windows, run "ClockBuilder Pro"
* it should report "Field programmer detected", press "EVB GUI"
* in EVB GUI, press "Config", set I2C address 0x6B
* press "Scan", it should find Si5394A-A-GM
* select the "Status" tab, should see real-time status of clock chip


= GDM MGT configuration =
Complete:


* TX configuration:
<pre>
* GDM MGT transceivers are configured as "multilane" TX and RX.
125 MHz oscillator - U5 fan out -
* there is 12 TXes ("lanes")
  q0 -> CLK_XO_125 -> ENC C72,C74 -> FPGA R8,R7 MGTREFCLK0_A -> XDC CLK_XO_125_P -> VHDL not used
* MGT reference 125 MHz clock goes into [2:0]gtreclk00_in and [11:0]gtrefclk0_in
  q1 -> U6 C.C. in1
* one MGT is designated as "master"
  q2 -> CLK3_XO_125 -> ENC C7,C9 -> FPGA J8,J7 MGTREFCLK1_B -> XDC GDM missing, CDM CLK3_XO_125_P -> VHDL SFP RX reference clock (mgt_rx_ref_clk)
* PLL of master MGT converts reference clock into common TX clock and common tx_user_clk2 which becomes tx_data_clk
  q3 -> not used, was CLK2_XO_125
* common tx_user_clk2 aka tx_data_clk goes into all TXes and clocks tx_data.
 
* tx_user_clk2 aka tx_data_clk is 125 MHz but not same phase as MGT reference clock.
U6 C.C (clock cleaner) -
 
in0 <- CLK_EXT1 (GPS 10 MHz clock)
in1 <- 125 MHz oscillator via U5
in2 <- CLK_CC_IN <- ENC C142,C144 <- FPGA AK9,AK8 <- XDC GDM missing, CDM CLK_CC_IN1_P <- VHDL rx_clk
in3 <- CLK_FB


* RX interim configuration:
out0 -> CLK_CCA -> U12 (125 MHz)
* there is 12 RXes ("lanes")
out1 -> CLK_CCB -> VX1..6 (62.5 MHz)
* each RX produces it's own recovered RX clock
out2 -> CLK_CCC -> VX7..12 (62.5 MHz)
* "multilane" configuration assumes all RX recovered clocks run at the same frequency (TX on the other end are driven by common TX clock, see above), but have different phase
out3 -> CLK_FB into in3
* one RX recovered clock is designated as "master" (rx_user_clk2 aka rx_data_clk) and a phase-matching fifo/buffer is used to bring rx_data from all 12 RXes to this common rx_data_clk
* this works because each CDM SFP TX runs on the SFP RX recovered clock which is frequency-locked with the GDM QSFP TX clock.


* RX final configuration:
CLK_CCA -> U12 (125 MHz fan out) ->
* MGTs permit using the common TX clock (tx_user_clk2 aka tx_data_clk) as the common rx_data_clk (they are frequency locked through the CDM).
* this permits use of tx_data_clk as the main clock domain in the GDM and removes the need to bring rx_data into the tx_data_clk domain (actually this is done in the MGT RX phase matching fifo/buffer).


= Clock path =
Q0 -> not used
Q1 -> CLK_CC_OUT0 -> ENC C3,C5 -> FPGA L8,L7 MGTREFCLK0_B -> XDC GDM clk_mgtrefclk0_x0y1_p, CDM CLK_CC_OUT0_P -> VHDL  GDM mgt_b_ref_clk QSFP RX and TX reference clocks, CDM alternate rx_clk via clock mux
Q2 -> CLK_CC_OUT1 -> ENC B3,B5 -> FPGA B10,B9 MGTREFCLK1_D -> XDC CLK_CC_OUT1_P -> VHDL GDM not used, CDM mgt_tx_ref_clk SFP TX clock
Q3 -> CLK_CC_OUT2 -> ENC C151,C153 -> FPGA AG8,AH8 (GC) -> XDC GDM, CDM missing
Q4 -> not used
Q5 -> SMA J9/J10


<pre>
CLK_TP0 <-> ENC C69,C71 <-> FPGA N8,N7 MGTREFCLK1_A (not used) -> XDC CLK_TP0_P -> VHDL not used (DS-DM SMA J11, J12)
10 MHz ext clock or GDM 125 MHz oscillator
 
-> GDM QSFP MGT reference clock 125 MHz
Notes:
-> MGT PLL -> tx_data_clk 125 MHz (GDM main clock domain) and TX bit clock 2.5 GHz
* Enclustra ENC-B is J801, ENC-C is J900
-> GDM QSFP optic transmitter
* "(GC)" is clock-capable FPGA pin
-> CDM SFP optic receiver
* CLK_XO_125 (125 MHz osc) is not used in FPGA
-> CDM SFP MGT, RX reference clock is CDM 125 MHz oscillator
* 62.5 MHz VX clock does not go into the FPGA
-> MGT RX recovered clock 125 MHz (CDM main clock domain)
* CLK_EXT0 going to in1 of U5 cannot be used. only permitted frequency is 125 MHz (it drives the MGT reference clocks) and is this frequency is too high for LEMO cables and connectors
-> CC_CLK_IN -> CDM C.C. -> CC_CLK_OUT1 -> CDM SFP TX reference clock 125 MHz
-> MGT PLL -> tx_data_clk 125 MHz and TX bit clock 2.5 GHz
-> (tx_data phase matching fifo from CDM main clock domain to tx_data_clk)
-> CDM SFP optic transmitter
-> GDM QSFP RX optic receiver (12x)
-> GDM QSFP MGT (RX reference clock is same as TX reference clock)
-> MGT RX recovered clock (12x recovered clocks)
-> in multi-lane configuration, one of them is the "master" recovered clock rx_data_clk
-> (rx_data phase matching fifo from rx_data_clk to GDM main clock domain)
</pre>
</pre>


= Clock domains =
= I2C bus =


== GPS ==
* I2C_SCL is J-ENC-A pin 111 I2C_SCL is FPGA I2C_SCL_PL AB13 (IO_L1N_TOL1D_64) and I2C_SCL_PS F18 (PS_MIO10)
* I2C_SDA is J-ENC-A pin 113 I2C_SDA is FPGA I2C_SDA_PL AH13 (IO_L7N_T1L1Q_AD13N_64) and I2C_SDA_PS G18 (PS_MIO11)


* no GPS : GDM runs from internal 125 MHz oscillator
* XU8 secure EEPROM ATSHA204A at 0x64, this is 0110'010X -> linux _011'0010 is 0x32. (but responds to scan and read at 0x33)
* external 10 MHz clock : GDM runs from external 10 MHz clock and optional 1pps signal (use VME-NIMIO32 NIM outputs)
* U4 ethernet mac chip, EEPROM at 1010 A2 A1 A0 X and MAC/serial_no at 1011 A2 A1 A0 X. A0=VCC, A1=VCC, A2=GND -> linux _101'0011 and _101'1011 is 0x53 and 0x5B.
* GPS receiver : GDM runs from GPS 10 MHz clock and GPS IRIG serial data
* U6 clock chip, address 1101 0 A1 A0 X. A1=VCC, A0=N/C (internal pull-up) -> linux _110'1011 is 0x6b
* LNGS GPS:
* U23 voltmeter at 10011 ADR1 ADR0. ADR0=GND, ADR1=VCC -> linux _100'1110 is 0x4e
** provides 1pps and serial data over fiber from GPS receiver (master). LNGS xxx box is not used.
* SFP, address 1010000X -> linux _101'0000 is 0x50. additional SFP data at 0x51
** serial data goes to GDM, decoded, 1pps signal extracted, goes to LEMO output
* QSFP0, QSFP1, QSFP2, QSFP3 (QSFP0_SEL, QSFP1_SEL, QSFP2_SEL, QSFP3_SEL)
** 1pps from GDM is used to train the Rubidium clock which provides a 10 MHz clock
** 10 MHz output from Rubidium clock goes to GDM 10 MHz external clock input


== GDM ==
= I2C clock builder connection =


* AXI clock (100 MHz) - AXI registers
* use Silicon Labs USB "Clock builder pro field programmer", www.silabs.com/CBProgrammer
* 125 MHz oscillator - to clock cleaner
* connect rainbow jumper cable pins:
* 10 MHz external clock LEMO input - to clock cleaner
** black - 1-GND to GND on DS-DM
* FPGA 125 MHz clock CLK_CC_IN - to clock cleaner - not used (could be used for cascaded GDMs)
** white - 3-SCLK to SCL on the DS-DM
* 125 MHz oscillator - CLK3_XO_125 - mgt_b_ref_clk QSFP MGT reference clock (interim GDM design)
** grey - 7-SDA_SDIO to SDA on the DS-DM
* clock cleaner output 125 MHz fanout:
* power up the DS-DM
** CLK_CC_OUT0 - QSFP MGT reference clock (final design)
* plug USB programmer into Windows laptop
** CLK_CC_OUT1 - not used (CDM SFP reference clock)
* on Windows, run "ClockBuilder Pro"
** CLK_CC_OUT2 - not used
* it should report "Field programmer detected", press "EVB GUI"
* QSFP MGT TX data clock 125 MHz tx_data_clk (main clock domain)
* in EVB GUI, press "Config", set I2C address 0x6B
** QSFP TX data
* press "Scan", it should find Si5394A-A-GM
** QSFP RX data (in final design, rx_data_clk is same as tx_data_clk. inside the MGT, 12x phase matching fifos for RX data from 12x RX recovered clocks to rx_data_clk == tx_data_clk)
* select the "Status" tab, should see real-time status of clock chip
** ds20k block
* (in interim design, rx_data_clk is disconnected from tx_data_clk. rx_data_clk is the "multilane master clock" which is one of the 12x RX recovered clocks. inside the MGT, 12x phase matching fifos for RX data from 12x RX recovered clocks to rx_data_clk)


note: all these clocks are frequency locked to 125 MHz
= GDM MGT configuration =


== CDM ==
* TX configuration:
 
* GDM MGT transceivers are configured as "multilane" TX and RX.
* AXI clock (100 MHz) - AXI registers
* there is 12 TXes ("lanes")
* 10 MHz external clock LEMO input - to clock cleaner (not used)
* MGT reference 125 MHz clock goes into [2:0]gtreclk00_in and [11:0]gtrefclk0_in
* 125 MHz oscillator to fanout
* one MGT is designated as "master"
** to clock cleaner
* PLL of master MGT converts reference clock into common TX clock and common tx_user_clk2 which becomes tx_data_clk
** to SFP MGT RX reference clock: CLK3_XO_125 to mgt_rx_ref_clk to gtrefclk01_in
* common tx_user_clk2 aka tx_data_clk goes into all TXes and clocks tx_data.
* SFP MGT RX recovered clock 125 MHz
* tx_user_clk2 aka tx_data_clk is 125 MHz but not same phase as MGT reference clock.
** MGT PLL to MGT rx_user_clk2 aka rx_data_clk
** MGT rxrecclkout_out to mgt_rx_rec_clk to CLK_CC_IN to C.C.
* SFP MGT rx_user_clk2 aka rx_data_clk (250 MHz/8 bit, 125 MHz/16 bit, 62.5 MHz/32 bit data) (main clock domain)
** SFP RX data
** ds20k block
** VX TX clock PLLs
** VX RX clock PLLs
* C.C. fan out
** 62.5 MHz VX clocks (12x)
** CLK_CC_OUT0 (not used, GDM QSFP MGT reference clock)
** CLK_CC_OUT1 125 MHz to mgt_tx_ref_clk to gtrefclk00_in to SFP MGT TX reference clock
** CLK_CC_OUT2 (not used)
* SFP MGT tx_user_clk2 aka tx_data_clk
** SFP TX data
** TX data phase matching fifo from main clock domain to tx_data_clk
* VX TX clock PLLs
** 2 PLLs, 6 clocks each (12 total). phase of each clock independently adjusted via AXI registers
** VX TX data phase matching from main clock domain to VX TX clock (12 total)
** VX TX serializer
** VX TX LVDS transmitter
* VX RX clock PLLs
** 2 PLLs, 6 clocks each (12 total). phase of each clock independently adjusted via AXI registers
** VX RX LVDS receivers (12 total)
** VX RX deserializers (12 total)
** VX TX data phase matching from VX RX clock to main clock domain


== VX ==
* RX interim configuration:
* there is 12 RXes ("lanes")
* each RX produces it's own recovered RX clock
* "multilane" configuration assumes all RX recovered clocks run at the same frequency (TX on the other end are driven by common TX clock, see above), but have different phase
* one RX recovered clock is designated as "master" (rx_user_clk2 aka rx_data_clk) and a phase-matching fifo/buffer is used to bring rx_data from all 12 RXes to this common rx_data_clk
* this works because each CDM SFP TX runs on the SFP RX recovered clock which is frequency-locked with the GDM QSFP TX clock.


* everything runs on the VX main 125 MHz clock
* RX final configuration:
* correct phase of VX to CDM LVDS data is adjusted by scan of CDM VX RX PLL clock phase (VX to CDM link is now established)
* MGTs permit using the common TX clock (tx_user_clk2 aka tx_data_clk) as the common rx_data_clk (they are frequency locked through the CDM).
* correct phase of CDM to VX LVDS data is adjusted by scan of CDM VX RX PLL clock phase (link is established after VX to CDM idle data pattern changes from "VX RX data bad" to "good".
* this permits use of tx_data_clk as the main clock domain in the GDM and removes the need to bring rx_data into the tx_data_clk domain (actually this is done in the MGT RX phase matching fifo/buffer).
* after good phases are found by scan, they are not expected to change unless cables are changed, CDM and VX modules are changed or CDM firmware is rebuilt. (rebuild of VX firmware should not affect LVDS data phase).
* if there is excessive link errors, phase scan must be repeated.


= Board test plan =
= Clock path =
 
To test:
* Enclustra FPGA board
* SFP port - SFP_RS0/RS1 connected to QSFP0_SEL/1_SEL is wrong? our Finisar SFP says RS0, RS1 N/C, so probably okey.
* SW5 CLK_EXT1 NIM works. TTL needs to be tested. flipping SW5 CLK_EXT0 side from NIM to TTL makes CLK_EXT1 go LOS and OOF in the clock chip. R23 and R53 should be removed?
* BOOT_MODE 0 and 1


Partial:
NOTE: MUST REVIEW!!!
* U23 3.3V current meter and thermometer. V1,V2 is current monitor, same as in application note. V3,V4 is thermometer, same in application note, except capacitor C118 is 0.1u instead of 470pF. Tested ok: Tint, VCC, V1, V2, V1-V2. Test failed: TR2 reads 50-something degC instead of same as Tint.


Done:
<pre>
* LED_FP1A..D: tested ok. K.O. 15 sep 2022
10 MHz ext clock or GDM 125 MHz oscillator
* USB UART: tested ok. K.O. 15 sep 2022
-> GDM QSFP MGT reference clock 125 MHz
* J4A, J4B, J5A, J5B LEMO inputs (NIM/TTL) EXT_IN_LV(1..4). TTL threshold 1.7V, NIM threshold -0.3V. 50 Ohm termination. TTL straight, NIM inverted.
-> MGT PLL -> tx_data_clk 125 MHz (GDM main clock domain) and TX bit clock 2.5 GHz
* J6A, J6B LEMO clock inputs: 10 MHz TTL from chronobox works, 10 MHz NIM from IO32 works. 18-apr-2023
-> GDM QSFP optic transmitter
* J7A, J7B LEMO outputs EXT_OUT(1), EXT_OUT(2) (NIM/TTL) (tested 23nov2022, K.O.). TTL ???, NIM inverted.
-> CDM SFP optic receiver
** TTL out no 50 ohm termination: 0=0V, 1=5V, rise and fall time ~5 ns
-> CDM SFP MGT, RX reference clock is CDM 125 MHz oscillator
** TTL out with 50 ohm termination: 0=0V, 1=2.5V, rise and fall time <2ns
-> MGT RX recovered clock 125 MHz (CDM main clock domain)
** NIM out no 50 ohm termination: 0=+50mV, 1=-1.8V, rise and fall time ~3ns
-> CC_CLK_IN -> CDM C.C. -> CC_CLK_OUT1 -> CDM SFP TX reference clock 125 MHz
** NIM out with 50 ohm termination: 0=0V, 1=-0.9V, rise and fall time <2ns
-> MGT PLL -> tx_data_clk 125 MHz and TX bit clock 2.5 GHz
* ethernet MAC i2c chip (K.O. 20sep2022: can read: i2cdump 0 0x5b, nov2022 have u-boot driver)
-> (tx_data phase matching fifo from CDM main clock domain to tx_data_clk)
* CDM VX ports 2x(CLK, 3 tx, 4 rx) tested using test_cdm.exe and LVDS loopback in VX firmware.
-> CDM SFP optic transmitter
* SFP i2c tested KO 22jun2023
-> GDM QSFP RX optic receiver (12x)
* QSFP i2c tested KO 22jun2023
-> GDM QSFP MGT (RX reference clock is same as TX reference clock)
* i2c testing complete 22jun2023
-> MGT RX recovered clock (12x recovered clocks)
* QSFP rx,tx tested 26june2023. lane0,1,2 ok, lane3 tx not connected, laser is off. qsfp0,1,2,3 all lanes ok.
-> in multi-lane configuration, one of them is the "master" recovered clock rx_data_clk
* SFP rx,tx tested 26june2023. rx and tx okey. LOS ok, mod_absent ok.
-> (rx_data phase matching fifo from rx_data_clk to GDM main clock domain)
</pre>
 
= CDM rx_clk mux =
 
when CDM SFP is not connected, there is no SFP recovered clock and a mux is used to switch between clk_cc_out0 (power up default) and rx_clk_mgt (SFP recovered clock)


Failure:
== Test SFP disconnected ==
* ethernet: does not connect to alliedtelesys switch. connects to my USB-eth adapter at 100 Mbit speed. uboot mii status reports connection speed oscillating between 1000, 100 and 10. K.O. 16-sep-2022
* SFP LOS and mod_absent are swapped (in the FPGA pin definitions?)
* QSFP slot numbering is wrong.


= Checklist for newly build boards =
note: if I say "--cc-in1", CC seems to lock on the 10 MHz GPS external clock,
to prevent this, test sequence includes reloading the CC and the reset of MGT.


* put new board on workbench
<pre>
* check - vme connector present, vme extraction handles present
./test_cdm_local.exe --write32 0x30 0x0 ### rx_clk mux select CC clock
* check - standoff are removed from all thru-holes
./test_cdm_local.exe --load-cc
* plug Enclustra module
./test_cdm_local.exe --reset-mgt
* check - SW6 both switches are in the "PS" position
./test_cdm_local.exe --cdm-clocks
* connect micro-usb cable from linux PC
CDM clock frequency counters:
* connect ethernet from 1gige capable network switch
0x1030 mgt_rx_ref_clk_raw: 0x0773594e (125000014) should be ~125 MHz  <=== all 4 clocks wobble close to 125 MHz
* connect power from lab power supply - GND, +5V and -12V nominal, +5.7V and -12.5V actual
0x1034 rx_clk:            0x0773594f (125000015) should be ~125 MHz
* power up, +5V current 2.10-2.8A, -12V current 0.05A
0x1038 mgt_tx_ref_clk_raw: 0x0773594f (125000015) should be ~125 MHz
* on linux PC, open a new terminal, run: minicom -D /dev/ttyACM0
0x103C tx_clk:            0x0773594f (125000015) should be ~125 MHz
* in minicom window, observe messages about Xilinx first stage boot loader, etc
0x1040 clk_50MHz:          0x02faf080 (50000000) should be 50 MHz exactly
* on the ethernet switch, observe network link is 1gige speed (not 10mbit, not 100mbit).
0x1044 Block1_clk:        0x05f5e100 (100000000) should be 100 MHz exactly
* if everything boots okey, there will be a login prompt, login as root, password root.
./test_cdm_local.exe --write32 0x30 0x1 ### rx_clk mux select SFP recovered clock
* busybox devmem 0x80010000 # read firmware version number, i.e. 0xEDAD0A77
./test_cdm_local.exe --cdm-clocks
* TBW - test LEMO inputs
CDM clock frequency counters:
* TBW - test LEMO outputs
0x1030 mgt_rx_ref_clk_raw: 0x0773598b (125000075) should be ~125 MHz
* TBW - test VX connectors
0x1034 rx_clk:            0x076d58ec (124606700) should be ~125 MHz  <=== off frequency because there is no valid SFP recovered clock
* TBW - test SFP connector
0x1038 mgt_tx_ref_clk_raw: 0x0773598c (125000076) should be ~125 MHz
* TBW - test QSFP connector
0x103C tx_clk:            0x0773598b (125000075) should be ~125 MHz
0x1040 clk_50MHz:          0x02faf080 (50000000) should be 50 MHz exactly
0x1044 Block1_clk:        0x05f5e100 (100000000) should be 100 MHz exactly
</pre>


= Serial console =
= Clock domains =


* check that linux computer has correct udev rules to allow access to /dev/ttyACM devices, see https://daq00.triumf.ca/DaqWiki/index.php/SLinstall#Configure_USB_device_permissions and https://daq00.triumf.ca/DaqWiki/index.php/Ubuntu#Configure_USB_device_permissions
== GPS ==
* connect micro-USB cable to connector J-UCB, other end connect to linux computer
* observe /dev/ttyACM0 was created
* run "minicom -D /dev/ttyACM0" (default serial settings are ok, otherwise, 115200n8)
* should have gdm-cdm login
* username root, password root


= i2c =
* no GPS : GDM runs from internal 125 MHz oscillator
 
* external 10 MHz clock : GDM runs from external 10 MHz clock and optional 1pps signal (use VME-NIMIO32 NIM outputs)
<pre>
* GPS receiver : GDM runs from GPS 10 MHz clock and GPS IRIG serial data
ZynqMP> i2c bus
* LNGS GPS:
Bus 0: i2c@ff020000
** provides 1pps and serial data over fiber from GPS receiver (master). LNGS xxx box is not used.
ZynqMP> i2c dev 0
** serial data goes to GDM, decoded, 1pps signal extracted, goes to LEMO output
Setting bus to 0
** 1pps from GDM is used to train the Rubidium clock which provides a 10 MHz clock
ZynqMP> i2c probe 
** 10 MHz output from Rubidium clock goes to GDM 10 MHz external clock input
Valid chip addresses: 33 4E 53 5B 6B 77
 
ZynqMP> i2c md 0x5b 0x98
== GDM ==
0098: fc c2 3d 00 00 12 1a 6e 0a 90 85 04 94 10 08 50    ..=....n.......P
</pre>


<pre>
* AXI clock (100 MHz) - AXI registers
root@gdm-cdm:~# i2cdetect 0
* 125 MHz oscillator - to clock cleaner
Warning: Can't use SMBus Quick Write command, will skip some addresses
* 10 MHz external clock LEMO input - to clock cleaner
WARNING! This program can confuse your I2C bus, cause data loss and worse!
* FPGA 125 MHz clock CLK_CC_IN - to clock cleaner - not used (could be used for cascaded GDMs)
I will probe file /dev/i2c-0.
* 125 MHz oscillator - CLK3_XO_125 - mgt_b_ref_clk QSFP MGT reference clock (interim GDM design)
I will probe address range 0x03-0x77.
* clock cleaner output 125 MHz fanout:
Continue? [Y/n]
** CLK_CC_OUT0 - QSFP MGT reference clock (final design)
    0  1  2  3  4  5  6  7  8  9  a  b  c  d  e  f
** CLK_CC_OUT1 - not used (CDM SFP reference clock)
00:                                               
** CLK_CC_OUT2 - not used
10:                                               
* QSFP MGT TX data clock 125 MHz tx_data_clk (main clock domain)
20:                                               
** QSFP TX data
30: -- -- -- 33 -- -- -- --                       
** QSFP RX data (in final design, rx_data_clk is same as tx_data_clk. inside the MGT, 12x phase matching fifos for RX data from 12x RX recovered clocks to rx_data_clk == tx_data_clk)
40:                                                
** ds20k block
50: -- -- -- 53 -- -- -- -- -- -- -- 5b -- -- -- --
* (in interim design, rx_data_clk is disconnected from tx_data_clk. rx_data_clk is the "multilane master clock" which is one of the 12x RX recovered clocks. inside the MGT, 12x phase matching fifos for RX data from 12x RX recovered clocks to rx_data_clk)
60:                                               
70:                                               
root@gdm-cdm:~#
root@gdm-cdm:~# i2cdump 0 0x5b
No size specified (using byte-data access)
WARNING! This program can confuse your I2C bus, cause data loss and worse!
I will probe file /dev/i2c-0, address 0x5b, mode byte
Continue? [Y/n]
    0  1  2  3  4  5  6  7  8  9  a  b  c  d  e  f    0123456789abcdef
00: XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX    XXXXXXXXXXXXXXXX
10: XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX    XXXXXXXXXXXXXXXX
20: XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX    XXXXXXXXXXXXXXXX
30: XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX    XXXXXXXXXXXXXXXX
40: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
50: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
60: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
70: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
80: 0a 90 85 04 94 10 08 50 90 5b a0 00 a0 00 00 00    ???????P?[?.?...
90: 00 00 00 00 00 00 00 00 fc c2 3d 00 00 12 1a 6e    ........??=..??n
a0: 0a 90 85 04 94 10 08 50 90 5b a0 00 a0 00 00 00    ???????P?[?.?...
b0: 00 00 00 00 00 00 00 00 fc c2 3d 00 00 12 1a 6e    ........??=..??n
c0: XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX    XXXXXXXXXXXXXXXX
d0: XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX    XXXXXXXXXXXXXXXX
e0: XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX    XXXXXXXXXXXXXXXX
f0: XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX    XXXXXXXXXXXXXXXX
root@gdm-cdm:~#
</pre>


<pre>
note: all these clocks are frequency locked to 125 MHz
root@gdm0:~# i2cdetect -r 0
    0  1  2  3  4  5  6  7  8  9  a  b  c  d  e  f
00:                        -- -- -- -- -- -- -- --
10: -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- --
20: -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- --
30: -- -- -- 33 -- -- -- -- -- -- -- -- -- -- -- --
40: -- -- -- -- -- -- -- -- -- -- -- -- -- -- 4e --
50: -- -- -- 53 -- -- -- -- -- -- -- 5b -- -- -- --
60: -- -- -- -- -- -- -- -- -- -- -- 6b -- -- -- --
70: -- -- -- -- -- -- -- --                       
root@gdm0:~#
</pre>


<pre>
== CDM ==
root@cdm0:~# i2cdetect -r 0
    0  1  2  3  4  5  6  7  8  9  a  b  c  d  e  f
00:                        -- -- -- -- -- -- -- --
10: -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- --
20: -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- --
30: -- -- -- 33 -- -- -- -- -- -- -- -- -- -- -- --
40: -- -- -- -- -- -- -- -- -- -- -- -- -- -- 4e --
50: 50 51 -- 53 -- -- -- -- -- -- -- 5b -- -- -- --
60: -- -- -- -- -- -- -- -- -- -- -- 6b -- -- -- --
70: -- -- -- -- -- -- -- --                       
root@cdm0:~#
</pre>


* 0x33 - XU8 secure EEPROM (should be at 0x32)
* AXI clock (100 MHz) - AXI registers
* 0x4e - U23 current and temperature monitor
* 10 MHz external clock LEMO input - to clock cleaner (not used)
* 0x50, 0x51 - SFP
* 125 MHz oscillator to fanout
* 0x50 - QSFP, 4 QSFP modules enabled by GPIO QSFP0_SEL, QSFP1_SEL, QSFP2_SEL, QSFP3_SEL
** to clock cleaner
* 0x53, 0x5b - ethernet mac eeprom
** to SFP MGT RX reference clock: CLK3_XO_125 to mgt_rx_ref_clk to gtrefclk01_in
* 0x6b - U6 clock chip
* SFP MGT RX recovered clock 125 MHz
** MGT PLL to MGT rx_user_clk2 aka rx_data_clk
** MGT rxrecclkout_out to mgt_rx_rec_clk to CLK_CC_IN to C.C.
* SFP MGT rx_user_clk2 aka rx_data_clk (250 MHz/8 bit, 125 MHz/16 bit, 62.5 MHz/32 bit data) (main clock domain)
** SFP RX data
** ds20k block
** VX TX clock PLLs
** VX RX clock PLLs
* C.C. fan out
** 62.5 MHz VX clocks (12x)
** CLK_CC_OUT0 (not used, GDM QSFP MGT reference clock)
** CLK_CC_OUT1 125 MHz to mgt_tx_ref_clk to gtrefclk00_in to SFP MGT TX reference clock
** CLK_CC_OUT2 (not used)
* SFP MGT tx_user_clk2 aka tx_data_clk
** SFP TX data
** TX data phase matching fifo from main clock domain to tx_data_clk
* VX TX clock PLLs
** 2 PLLs, 6 clocks each (12 total). phase of each clock independently adjusted via AXI registers
** VX TX data phase matching from main clock domain to VX TX clock (12 total)
** VX TX serializer
** VX TX LVDS transmitter
* VX RX clock PLLs
** 2 PLLs, 6 clocks each (12 total). phase of each clock independently adjusted via AXI registers
** VX RX LVDS receivers (12 total)
** VX RX deserializers (12 total)
** VX TX data phase matching from VX RX clock to main clock domain


== U23 ==
== VX ==


* internal temperature only
* everything runs on the VX main 125 MHz clock
* correct phase of VX to CDM LVDS data is adjusted by scan of CDM VX RX PLL clock phase (VX to CDM link is now established)
* correct phase of CDM to VX LVDS data is adjusted by scan of CDM VX RX PLL clock phase (link is established after VX to CDM idle data pattern changes from "VX RX data bad" to "good".
* after good phases are found by scan, they are not expected to change unless cables are changed, CDM and VX modules are changed or CDM firmware is rebuilt. (rebuild of VX firmware should not affect LVDS data phase).
* if there is excessive link errors, phase scan must be repeated.


<pre>
= Board test plan =
root@gdm0:~# i2cset -y 0 0x4e 0x01 0x00 b  # control register: "repeat mode, internal temperature only"
 
root@gdm0:~# i2cset -y 0 0x4e 0x02 0xff b # trigger
To test:
root@gdm0:~# i2cget -y 0 0x4e 0x00 b # status register
* Enclustra FPGA board
0x03 # "Tint ready" and "busy", "busy is always 1 in repeat mode"
* SFP port - SFP_RS0/RS1 connected to QSFP0_SEL/1_SEL is wrong? our Finisar SFP says RS0, RS1 N/C, so probably okey.
root@gdm0:~# i2cdump -y 0 0x4e b
* SW5 CLK_EXT1 NIM works. TTL needs to be tested. flipping SW5 CLK_EXT0 side from NIM to TTL makes CLK_EXT1 go LOS and OOF in the clock chip. R23 and R53 should be removed?
    0  1  2  3  4  5  6  7  8  9  a  b  c  d  e  f    0123456789abcdef
* BOOT_MODE 0 and 1
00: 03 00 03 03 81 db 2a ce 2a 8e 00 6f 00 45 20 3f    ?.????*?*?.o.E ?
10: 01 00 01 01 01 db 2a ce 2a 8e 00 6f 00 45 20 3f    ?.????*?*?.o.E ?
...
readback:
reg0 - 03 - Tint ready
reg1 - 00 - what we put there
reg2 - trigger
reg3 - not used
reg4 - Tint MSB 0x81, bit 0x80 is "DV, data valid", bit 0x40 is "SS, sensor short", 0x20 is "SO, sensor open"
reg5 - Tint LSB 0xDB, Tint = 0x01DB = 475 * 0.0625 degC = 29.6 degC
reg6..F - stale data
</pre>


* Tint, V1, V2, TR2, VCC
Partial:
* U23 3.3V current meter and thermometer. V1,V2 is current monitor, same as in application note. V3,V4 is thermometer, same in application note, except capacitor C118 is 0.1u instead of 470pF. Tested ok: Tint, VCC, V1, V2, V1-V2. Test failed: TR2 reads 50-something degC instead of same as Tint.


<pre>
Done:
root@gdm0:~# i2cset -y 0 0x4e 0x01 0x18 b  # control register: "repeat mode, V1, V2, TR2"
* LED_FP1A..D: tested ok. K.O. 15 sep 2022
root@gdm0:~# i2cset -y 0 0x4e 0x02 0xff b # trigger
* USB UART: tested ok. K.O. 15 sep 2022
root@gdm0:~# i2cget -y 0 0x4e 0x00 b # status register
* J4A, J4B, J5A, J5B LEMO inputs (NIM/TTL) EXT_IN_LV(1..4). TTL threshold 1.7V, NIM threshold -0.3V. 50 Ohm termination. TTL straight, NIM inverted.
0x7f # all data is ready
* J6A, J6B LEMO clock inputs: 10 MHz TTL from chronobox works, 10 MHz NIM from IO32 works. 18-apr-2023
root@gdm0:~# i2cdump -y 0 0x4e b
* J7A, J7B LEMO outputs EXT_OUT(1), EXT_OUT(2) (NIM/TTL) (tested 23nov2022, K.O.). TTL ???, NIM inverted.
    0  1 2 3  4  5  6  7  8  9  a  b  c  d  e  f    0123456789abcdef
** TTL out no 50 ohm termination: 0=0V, 1=5V, rise and fall time ~5 ns
00: 7f 18 7f 7f 81 b9 aa d0 aa 8f 83 5e 83 5e a0 41    ???????????^?^?A
** TTL out with 50 ohm termination: 0=0V, 1=2.5V, rise and fall time <2ns
10: 01 18 01 01 01 b9 2a d0 2a 8f 03 5e 03 5e 20 41    ??????*?*??^?^ A
** NIM out no 50 ohm termination: 0=+50mV, 1=-1.8V, rise and fall time ~3ns
reg0 - 7F - all data ready
** NIM out with 50 ohm termination: 0=0V, 1=-0.9V, rise and fall time <2ns
reg1 - 18 - what we put there
* ethernet MAC i2c chip (K.O. 20sep2022: can read: i2cdump 0 0x5b, nov2022 have u-boot driver)
reg2 - trigger
* CDM VX ports 2x(CLK, 3 tx, 4 rx) tested using test_cdm.exe and LVDS loopback in VX firmware.
reg3 - not used
* SFP i2c tested KO 22jun2023
reg4 - Tint MSB and DV, SS, SO.
* QSFP i2c tested KO 22jun2023
reg5 - Tint LSB 0x1b9*0.0625 = 27.5 degC
* i2c testing complete 22jun2023
reg6 - V1 MSB 0xaa, bit 0x80 is DV, bit 0x40 is sign
* QSFP rx,tx tested 26june2023. lane0,1,2 ok, lane3 tx not connected, laser is off. qsfp0,1,2,3 all lanes ok.
reg7 - V1 LSB 0xd0, V1 = 0x2ad0*305.18/1000000 = 3.3447 V (correct)
* SFP rx,tx tested 26june2023. rx and tx okey. LOS ok, mod_absent ok.
reg8 - V2 MSB 0xaa, ditto
reg9 - V2 LSB 0x8f, V2 = 0x2a8f*305.18/1000000 = 3.3249 V (correct, smaller than V1)
regA - V3 MSB or TR2 MSB 0x83, 0x80=DV, 0x40=SS, 0x20=SO
regB - V3 LSB or TR2 LSB 0x5e. TR2 = 0x35e*0.0625 = 53.875 degC (wrong, thermistor Q5 is next to U23, should read same as Tint)
regC - V4 MSB or TR2 MSB
regD - V4 LSB or TR2 LSB
regE - VCC MSB 0xa0, bit 0x80 is DV, 0x40 is sign
regF - VCC LSB 0x41, VCC = 2.5+0x2041*305.18/1000000 = 5.019 V (correct, VCC is +5V)


3V3_SW current is (V2-V1)/0.020 = 0.99 A (about right?)
Failure:
</pre>
* ethernet: does not connect to alliedtelesys switch. connects to my USB-eth adapter at 100 Mbit speed. uboot mii status reports connection speed oscillating between 1000, 100 and 10. K.O. 16-sep-2022
* SFP LOS and mod_absent are swapped (in the FPGA pin definitions?)
* QSFP slot numbering is wrong.


* Tint, V1-V2, TR2, VCC
= Checklist for newly build boards =


<pre>
* put new board on workbench
root@gdm0:~# i2cset -y 0 0x4e 0x01 0x19 b  # control register: "repeat mode, V1-V2, TR2"
* check - vme connector present, vme extraction handles present
root@gdm0:~# i2cset -y 0 0x4e 0x02 0xff b # trigger
* check - standoff are removed from all thru-holes
root@gdm0:~# i2cget -y 0 0x4e 0x00 b # status register
* plug Enclustra module
0x7f # all data is ready
* check - SW6 both switches are in the "PS" position
root@gdm0:~# i2cdump -y 0 0x4e b
* connect micro-usb cable from linux PC
    0  1  2  3  4  5  6  7  8  9  a  b  c  d  e  f    0123456789abcdef
* connect ethernet from 1gige capable network switch
00: 7f 19 7f 7f 81 69 83 f2 83 f2 83 3a 83 3a a0 44    ?????i?????:?:?D
* connect power from lab power supply - GND, +5V and -12V nominal, +5.7V and -12.5V actual
10: 01 19 01 01 01 69 03 f2 03 f2 03 3a 03 3a 20 44    ?????i?????:?: D
* power up, +5V current 2.10-2.8A, -12V current 0.05A
reg0 - 7F - all data ready
* on linux PC, open a new terminal, run: minicom -D /dev/ttyACM0
reg1 - 18 - what we put there
* in minicom window, observe messages about Xilinx first stage boot loader, etc
reg2 - trigger
* on the ethernet switch, observe network link is 1gige speed (not 10mbit, not 100mbit).
reg3 - not used
* if everything boots okey, there will be a login prompt, login as root, password root.
reg4 - Tint MSB and DV, SS, SO.
* busybox devmem 0x80010000 # read firmware version number, i.e. 0xEDAD0A77
reg5 - Tint LSB 0x169*0.0625 = 22.5 degC
* TBW - test LEMO inputs
reg6 - V1 or V1-V2 MSB 0x83, bit 0x80 is DV, bit 0x40 is sign
* TBW - test LEMO outputs
reg7 - V1 or V1-V2 LSB 0xf2, V1-V2 = 0x3f2*19.42/1000000 = 0.0196142 V (correct, compare with V1 and V2 measured above)
* TBW - test VX connectors
reg8 - V2 or V1-V2 MSB
* TBW - test SFP connector
reg9 - V2 or V1-V2 LSB
* TBW - test QSFP connector
regA - V3 MSB or TR2 MSB 0x83, 0x80=DV, 0x40=SS, 0x20=SO
 
regB - V3 LSB or TR2 LSB 0x3a. TR2 = 0x33a*0.0625 = 51.625 degC (wrong, thermistor Q5 is next to U23, should read same as Tint)
= Serial console =
regC - V4 MSB or TR2 MSB
regD - V4 LSB or TR2 LSB
regE - VCC MSB 0xa0, bit 0x80 is DV, 0x40 is sign
regF - VCC LSB 0x44, VCC = 2.5+0x2044*305.18/1000000 = 5.021 V (correct, VCC is +5V)


3V3_SW current is (V2-V1)/0.020 = 0.9807 A (about right?)
* check that linux computer has correct udev rules to allow access to /dev/ttyACM devices, see https://daq00.triumf.ca/DaqWiki/index.php/SLinstall#Configure_USB_device_permissions and https://daq00.triumf.ca/DaqWiki/index.php/Ubuntu#Configure_USB_device_permissions
</pre>
* connect micro-USB cable to connector J-UCB, other end connect to linux computer
* observe /dev/ttyACM0 was created
* run "minicom -D /dev/ttyACM0" (default serial settings are ok, otherwise, 115200n8)
* should have gdm-cdm login
* username root, password root


== SFP ==
= i2c =


<pre>
<pre>
root@cdm0:~# i2cdump 0 0x50
ZynqMP> i2c bus
    1  2  3  4  5  6  7  8  9  a  b  c  d  e  f    0123456789abcdef
Bus 0: i2c@ff020000
00: 03 04 07 00 00 00 00 40 40 0c 00 01 3d 00 00 00    ???....@@?.?=...
ZynqMP> i2c dev 0
10: 0c 02 00 1e 46 49 4e 49 53 41 52 20 43 4f 52 50    ??.?FINISAR CORP
Setting bus to 0
20: 2e 20 20 20 00 00 90 65 46 54 4c 46 38 35 32 36    .  ..?eFTLF8526
ZynqMP> i2c probe 
30: 50 33 42 4e 4c 20 20 20 41 20 20 20 03 52 00 9d    P3BNL  A  ?R.?
Valid chip addresses: 33 4E 53 5B 6B 77
40: 00 1a 00 00 4e 33 41 42 34 4c 56 20 20 20 20 20    .?..N3AB4LV   
ZynqMP> i2c md 0x5b 0x98
50: 20 20 20 20 32 30 30 33 31 39 20 20 68 f0 03 de        200319  h???
0098: fc c2 3d 00 00 12 1a 6e 0a 90 85 04 94 10 08 50    ..=....n.......P
60: 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00    ................
70: 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00    ................
80: 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00    ................
90: 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00    ................
a0: 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00    ................
b0: 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00    ................
c0: 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00    ................
d0: 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00    ................
e0: 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00    ................
f0: 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00    ................
root@cdm0:~#
root@cdm0:~# i2cdump 0 0x51
    0  1  2  3  4  5  6  7  8  9  a  b  c  d  e  f    0123456789abcdef
00: 5a 00 d8 00 55 00 e2 00 90 88 71 48 8c a0 75 30    Z.?.U.?.??qH??u0
10: 21 34 01 f4 1b 58 03 e8 31 2d 04 eb 1f 07 06 31    !4???X??1-?????1
20: 31 2d 00 64 27 10 00 9e 00 00 00 00 00 00 00 00    1-.d'?.?........
30: 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00    ................
40: 00 00 00 00 3f 80 00 00 00 00 00 00 01 00 00 00    ....??......?...
50: 01 00 00 00 01 00 00 00 01 00 00 00 00 00 00 b7   ?...?...?......?
60: 19 9f 80 c5 0e 17 12 c4 1f 99 00 00 00 00 30 00    ??????????....0.
70: 00 00 00 00 00 00 00 00 ff ff ff ff ff ff ff 01    ...............?
80: 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00    ................
90: 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00    ................
a0: 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00    ................
b0: 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00    ................
c0: 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00    ................
d0: 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00    ................
e0: 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00    ................
f0: 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00    ................
root@cdm0:~#
</pre>
</pre>
== QSFP ==


<pre>
<pre>
QSFP i2c enable lines, active low:
root@gdm-cdm:~# i2cdetect 0
 
Warning: Can't use SMBus Quick Write command, will skip some addresses
QSFP0_SEL - JENC-A 82 - PS-MIO40 - linux gpio 378
WARNING! This program can confuse your I2C bus, cause data loss and worse!
QSFP1_SEL - JENC-A 84 - PS-MIO41 - linux gpio 379
I will probe file /dev/i2c-0.
QSFP2_SEL - JENC-A 100 - PS-MIO44 - linux gpio 382
I will probe address range 0x03-0x77.
QSFP3_SEL - JENC-A 106 - PS-MIO43 - linux gpio 381 (notice 2 and 3 are out of order)
Continue? [Y/n]
</pre>
    0  1  2  3  4  5  6  7  8  9  a  b  c  d  e  f
 
00:                                               
<pre>
10:                                                
# cat /sys/kernel/debug/gpio
20:                                               
gpiochip0: GPIOs 338-511, parent: platform/ff0a0000.gpio, zynqmp_gpio:
30: -- -- -- 33 -- -- -- --                       
# echo 378 >> /sys/class/gpio/export ### SEL0 338+40
40:                                               
# echo 379 >> /sys/class/gpio/export ### SEL1 338+41
50: -- -- -- 53 -- -- -- -- -- -- -- 5b -- -- -- --  
# echo 381 >> /sys/class/gpio/export ### SEL3 338+43
60:                                               
# echo 382 >> /sys/class/gpio/export ### SEL2 338+44
70:                                               
# cat /sys/kernel/debug/gpio
root@gdm-cdm:~#  
gpiochip0: GPIOs 338-511, parent: platform/ff0a0000.gpio, zynqmp_gpio:
root@gdm-cdm:~# i2cdump 0 0x5b
  gpio-378 (                    |sysfs              ) in hi
No size specified (using byte-data access)
  gpio-379 (                    |sysfs              ) in hi
WARNING! This program can confuse your I2C bus, cause data loss and worse!
  gpio-381 (                    |sysfs              ) in hi
I will probe file /dev/i2c-0, address 0x5b, mode byte
  gpio-382 (                    |sysfs              ) in hi
Continue? [Y/n]
root@gdm0:~# echo out >> /sys/class/gpio/gpio381/direction
    0  1  2  3  4  5  6  7 8 9 a b c d e f    0123456789abcdef
root@gdm0:~# echo out >> /sys/class/gpio/gpio382/direction
00: XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX    XXXXXXXXXXXXXXXX
root@gdm0:~# echo out >> /sys/class/gpio/gpio378/direction
10: XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX    XXXXXXXXXXXXXXXX
root@gdm0:~# echo out >> /sys/class/gpio/gpio379/direction
20: XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX    XXXXXXXXXXXXXXXX
root@gdm0:~#
30: XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX    XXXXXXXXXXXXXXXX
root@gdm0:~# cat /sys/kernel/debug/gpio
40: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
gpiochip0: GPIOs 338-511, parent: platform/ff0a0000.gpio, zynqmp_gpio:
50: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
gpio-378 (                    |sysfs              ) out lo
60: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
gpio-379 (                    |sysfs              ) out lo
70: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
gpio-381 (                    |sysfs              ) out lo
80: 0a 90 85 04 94 10 08 50 90 5b a0 00 a0 00 00 00    ???????P?[?.?...
gpio-382 (                    |sysfs              ) out lo
90: 00 00 00 00 00 00 00 00 fc c2 3d 00 00 12 1a 6e    ........??=..??n
root@gdm0:~#
a0: 0a 90 85 04 94 10 08 50 90 5b a0 00 a0 00 00 00    ???????P?[?.?...
echo 1 >> /sys/class/gpio/gpio381/value
b0: 00 00 00 00 00 00 00 00 fc c2 3d 00 00 12 1a 6e    ........??=..??n
echo 1 >> /sys/class/gpio/gpio382/value
c0: XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX    XXXXXXXXXXXXXXXX
echo 1 >> /sys/class/gpio/gpio378/value
d0: XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX    XXXXXXXXXXXXXXXX
echo 1 >> /sys/class/gpio/gpio379/value
e0: XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX    XXXXXXXXXXXXXXXX
cat /sys/kernel/debug/gpio
f0: XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX    XXXXXXXXXXXXXXXX
root@gdm0:~# cat /sys/kernel/debug/gpio
root@gdm-cdm:~#  
gpiochip0: GPIOs 338-511, parent: platform/ff0a0000.gpio, zynqmp_gpio:
</pre>
gpio-378 (                    |sysfs              ) out hi
 
gpio-379 (                    |sysfs              ) out hi
<pre>
gpio-381 (                    |sysfs              ) out hi
root@gdm0:~# i2cdetect -r 0
gpio-382 (                    |sysfs              ) out hi
root@gdm0:~#
root@gdm0:~# i2cdetect -y -r 0
     0  1  2  3  4  5  6  7  8  9  a  b  c  d  e  f
     0  1  2  3  4  5  6  7  8  9  a  b  c  d  e  f
00:                        -- -- -- -- -- -- -- --  
00:                        -- -- -- -- -- -- -- --  
Line 738: Line 624:
70: -- -- -- -- -- -- -- --                         
70: -- -- -- -- -- -- -- --                         
root@gdm0:~#  
root@gdm0:~#  
NOTICE NOTHING AT ADDRESS 0x50
</pre>
</pre>


<pre>
<pre>
ENABLE QSFP0, OBSERVE IT IS AT ADDRESS 0x50
root@cdm0:~# i2cdetect -r 0
 
root@gdm0:~# echo 0 >> /sys/class/gpio/gpio378/value
root@gdm0:~# i2cdetect -y -r 0
     0  1  2  3  4  5  6  7  8  9  a  b  c  d  e  f
     0  1  2  3  4  5  6  7  8  9  a  b  c  d  e  f
00:                        -- -- -- -- -- -- -- --  
00:                        -- -- -- -- -- -- -- --  
Line 753: Line 634:
30: -- -- -- 33 -- -- -- -- -- -- -- -- -- -- -- --  
30: -- -- -- 33 -- -- -- -- -- -- -- -- -- -- -- --  
40: -- -- -- -- -- -- -- -- -- -- -- -- -- -- 4e --  
40: -- -- -- -- -- -- -- -- -- -- -- -- -- -- 4e --  
50: 50 -- -- 53 -- -- -- -- -- -- -- 5b -- -- -- --  
50: 50 51 -- 53 -- -- -- -- -- -- -- 5b -- -- -- --  
60: -- -- -- -- -- -- -- -- -- -- -- 6b -- -- -- --  
60: -- -- -- -- -- -- -- -- -- -- -- 6b -- -- -- --  
70: -- -- -- -- -- -- -- --                         
70: -- -- -- -- -- -- -- --                         
root@gdm0:~#  
root@cdm0:~#  
root@gdm0:~# i2cdump -y 0 0x50
</pre>
No size specified (using byte-data access)
 
    0  1  2  3  4  5  6  7  8  9  a  b  c  d  e  f    0123456789abcdef
* 0x33 - XU8 secure EEPROM (should be at 0x32)
00: 0d 00 02 8e 00 00 01 00 00 05 55 00 05 00 00 00    ?.??..?..?U.?...
* 0x4e - U23 current and temperature monitor
10: 00 00 00 00 00 00 1e b8 00 00 81 a0 00 00 00 00    ......??..??....
* 0x50, 0x51 - SFP
20: 00 00 12 12 00 01 00 01 00 01 0e e0 0f 20 0e e0    ..??.?.?.???? ??
* 0x50 - QSFP, 4 QSFP modules enabled by GPIO QSFP0_SEL, QSFP1_SEL, QSFP2_SEL, QSFP3_SEL
30: 00 00 1f a0 1e 3b 1f 72 00 01 00 00 00 00 00 00    ..???;?r.?......
* 0x53, 0x5b - ethernet mac eeprom
40: 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00    ................
* 0x6b - U6 clock chip
50: 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00    ................
 
60: 00 00 00 00 00 00 00 00 00 00 1f 00 00 00 08 00    ..........?...?.
== U23 ==
70: 00 00 00 00 00 00 00 ff ff ff ff ff ff ff ff 00    ................
80: 0d 00 0c 04 00 00 00 40 40 02 d5 05 67 00 00 96    ?.??...@@???g..?
90: 00 00 c8 00 46 49 4e 49 53 41 52 20 43 4f 52 50    ..?.FINISAR CORP
a0: 20 20 20 20 07 00 90 65 46 54 4c 34 31 30 51 44        ?.?eFTL410QD
b0: 34 43 20 20 20 20 20 20 41 20 42 68 07 d0 00 43    4C      A Bh??.C
c0: 00 07 0f de 58 37 39 41 43 30 52 20 20 20 20 20    .???X79AC0R   
d0: 20 20 20 20 32 32 30 33 30 39 20 20 3c 10 00 9e        220309  <?.?
e0: 20 20 20 20 20 20 20 20 20 20 20 20 20 20 20 20                   
f0: 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00    ................
root@gdm0:~#
</pre>


== ethernet mac eeprom ==
NOTE: Text reads double of Tint. not sure why. K.O. 21-mar-2024.


* correct chip with 84-bit ethernet mac address
* internal temperature only


<pre>
<pre>
root@cdm1:~# i2cdump 0 0x53
root@gdm0:~# i2cset -y 0 0x4e 0x01 0x00 b  # control register: "repeat mode, internal temperature only"
root@gdm0:~# i2cset -y 0 0x4e 0x02 0xff b # trigger
root@gdm0:~# i2cget -y 0 0x4e 0x00 b # status register
0x03 # "Tint ready" and "busy", "busy is always 1 in repeat mode"
root@gdm0:~# i2cdump -y 0 0x4e b
     0  1  2  3  4  5  6  7  8  9  a  b  c  d  e  f    0123456789abcdef
     0  1  2  3  4  5  6  7  8  9  a  b  c  d  e  f    0123456789abcdef
00: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff   ................
00: 03 00 03 03 81 db 2a ce 2a 8e 00 6f 00 45 20 3f   ?.????*?*?.o.E ?
10: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
10: 01 00 01 01 01 db 2a ce 2a 8e 00 6f 00 45 20 3f   ?.????*?*?.o.E ?
20: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff   ................
...
30: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
readback:
40: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
reg0 - 03 - Tint ready
50: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
reg1 - 00 - what we put there
60: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
reg2 - trigger
70: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
reg3 - not used
80: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
reg4 - Tint MSB 0x81, bit 0x80 is "DV, data valid", bit 0x40 is "SS, sensor short", 0x20 is "SO, sensor open"
90: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
reg5 - Tint LSB 0xDB, Tint = 0x01DB = 475 * 0.0625 degC = 29.6 degC
a0: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
reg6..F - stale data
b0: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
</pre>
c0: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
 
d0: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
* Tint, V1, V2, TR2, VCC
e0: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
f0: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
root@cdm1:~#


root@cdm1:~# i2cdump 0 0x5b
<pre>
root@gdm0:~# i2cset -y 0 0x4e 0x01 0x18 b  # control register: "repeat mode, V1, V2, TR2"
root@gdm0:~# i2cset -y 0 0x4e 0x02 0xff b # trigger
root@gdm0:~# i2cget -y 0 0x4e 0x00 b # status register
0x7f # all data is ready
root@gdm0:~# i2cdump -y 0 0x4e b
     0  1  2  3  4  5  6  7  8  9  a  b  c  d  e  f    0123456789abcdef
     0  1  2  3  4  5  6  7  8  9  a  b  c  d  e  f    0123456789abcdef
00: XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX    XXXXXXXXXXXXXXXX
00: 7f 18 7f 7f 81 b9 aa d0 aa 8f 83 5e 83 5e a0 41   ???????????^?^?A
10: XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX    XXXXXXXXXXXXXXXX
10: 01 18 01 01 01 b9 2a d0 2a 8f 03 5e 03 5e 20 41   ??????*?*??^?^ A
20: XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX    XXXXXXXXXXXXXXXX
reg0 - 7F - all data ready
30: XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX    XXXXXXXXXXXXXXXX
reg1 - 18 - what we put there
40: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
reg2 - trigger
50: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
reg3 - not used
60: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
reg4 - Tint MSB and DV, SS, SO.
70: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
reg5 - Tint LSB 0x1b9*0.0625 = 27.5 degC
80: 0a 80 c2 04 34 10 08 32 a8 4b a0 00 a0 00 00 00   ????4??2?K?.?...
reg6 - V1 MSB 0xaa, bit 0x80 is DV, bit 0x40 is sign
90: 00 00 00 00 00 00 00 00 00 00 fc c2 3d 1a 51 3c    ..........??=?Q<
reg7 - V1 LSB 0xd0, V1 = 0x2ad0*305.18/1000000 = 3.3447 V (correct)
a0: 0a 80 c2 04 34 10 08 32 a8 4b a0 00 a0 00 00 00   ????4??2?K?.?...
reg8 - V2 MSB 0xaa, ditto
b0: 00 00 00 00 00 00 00 00 00 00 fc c2 3d 1a 51 3c    ..........??=?Q<
reg9 - V2 LSB 0x8f, V2 = 0x2a8f*305.18/1000000 = 3.3249 V (correct, smaller than V1)
c0: XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX    XXXXXXXXXXXXXXXX
regA - V3 MSB or TR2 MSB 0x83, 0x80=DV, 0x40=SS, 0x20=SO
d0: XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX    XXXXXXXXXXXXXXXX
regB - V3 LSB or TR2 LSB 0x5e. TR2 = 0x35e*0.0625 = 53.875 degC (wrong, thermistor Q5 is next to U23, should read same as Tint)
e0: XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX    XXXXXXXXXXXXXXXX
regC - V4 MSB or TR2 MSB
f0: XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX    XXXXXXXXXXXXXXXX
regD - V4 LSB or TR2 LSB
root@cdm1:~#
regE - VCC MSB 0xa0, bit 0x80 is DV, 0x40 is sign
</pre>
regF - VCC LSB 0x41, VCC = 2.5+0x2041*305.18/1000000 = 5.019 V (correct, VCC is +5V)


* wrong "602" chip with 64-bit IPv6 address
3V3_SW current is (V2-V1)/0.020 = 0.99 A (about right?)
</pre>
 
* Tint, V1-V2, TR2, VCC


<pre>
<pre>
root@cdm0:~# i2cdump 0 0x53
root@gdm0:~# i2cset -y 0 0x4e 0x01 0x19 b  # control register: "repeat mode, V1-V2, TR2"
root@gdm0:~# i2cset -y 0 0x4e 0x02 0xff b # trigger
root@gdm0:~# i2cget -y 0 0x4e 0x00 b # status register
0x7f # all data is ready
root@gdm0:~# i2cdump -y 0 0x4e b
     0  1  2  3  4  5  6  7  8  9  a  b  c  d  e  f    0123456789abcdef
     0  1  2  3  4  5  6  7  8  9  a  b  c  d  e  f    0123456789abcdef
00: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
00: 7f 19 7f 7f 81 69 83 f2 83 f2 83 3a 83 3a a0 44   ?????i?????:?:?D
10: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
10: 01 19 01 01 01 69 03 f2 03 f2 03 3a 03 3a 20 44   ?????i?????:?: D
20: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
reg0 - 7F - all data ready
30: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
reg1 - 18 - what we put there
40: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
reg2 - trigger
50: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
reg3 - not used
60: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
reg4 - Tint MSB and DV, SS, SO.
70: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
reg5 - Tint LSB 0x169*0.0625 = 22.5 degC
80: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
reg6 - V1 or V1-V2 MSB 0x83, bit 0x80 is DV, bit 0x40 is sign
90: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
reg7 - V1 or V1-V2 LSB 0xf2, V1-V2 = 0x3f2*19.42/1000000 = 0.0196142 V (correct, compare with V1 and V2 measured above)
a0: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
reg8 - V2 or V1-V2 MSB
b0: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
reg9 - V2 or V1-V2 LSB
c0: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
regA - V3 MSB or TR2 MSB 0x83, 0x80=DV, 0x40=SS, 0x20=SO
d0: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
regB - V3 LSB or TR2 LSB 0x3a. TR2 = 0x33a*0.0625 = 51.625 degC (wrong, thermistor Q5 is next to U23, should read same as Tint)
e0: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
regC - V4 MSB or TR2 MSB
f0: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
regD - V4 LSB or TR2 LSB
root@cdm0:~# i2cdump 0 0x5b
regE - VCC MSB 0xa0, bit 0x80 is DV, 0x40 is sign
    0  1  2  3  4  5  6  7  8  9  a  b  c  d  e  f    0123456789abcdef
regF - VCC LSB 0x44, VCC = 2.5+0x2044*305.18/1000000 = 5.021 V (correct, VCC is +5V)
00: XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX    XXXXXXXXXXXXXXXX
 
10: XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX    XXXXXXXXXXXXXXXX
3V3_SW current is (V2-V1)/0.020 = 0.9807 A (about right?)
20: XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX    XXXXXXXXXXXXXXXX
30: XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX    XXXXXXXXXXXXXXXX
40: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
50: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
60: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
70: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
80: 0a 90 85 04 94 10 08 51 10 5b a0 00 a0 00 00 00   ???????Q?[?.?...
90: 00 00 00 00 00 00 00 00 fc c2 3d 00 00 12 1a 2e    ........??=..??.
a0: 0a 90 85 04 94 10 08 51 10 5b a0 00 a0 00 00 00   ???????Q?[?.?...
b0: 00 00 00 00 00 00 00 00 fc c2 3d 00 00 12 1a 2e    ........??=..??.
c0: XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX    XXXXXXXXXXXXXXXX
d0: XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX    XXXXXXXXXXXXXXXX
e0: XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX    XXXXXXXXXXXXXXXX
f0: XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX    XXXXXXXXXXXXXXXX
root@cdm0:~#
</pre>
</pre>


= read ethernet mac address from i2c =
== SFP ==
 
(this code is copied from uboot command line i2c code)
 
in uboot sources board/xilinx/common/board.c replace original function with this:


<pre>
<pre>
// special code to read ethernet MAC address from the DS-DM-Rev0 board. K.O. Sep-2022
root@cdm0:~# i2cdump 0 0x50
 
    0  1  2  3  4  5  6  7  8  9  a  b  c  d  e  f    0123456789abcdef
int zynq_board_read_rom_ethaddr(unsigned char *ethaddr)
00: 03 04 07 00 00 00 00 40 40 0c 00 01 3d 00 00 00    ???....@@?.?=...
{
10: 0c 02 00 1e 46 49 4e 49 53 41 52 20 43 4f 52 50    ??.?FINISAR CORP
        struct udevice *bus;
20: 2e 20 20 20 00 00 90 65 46 54 4c 46 38 35 32 36    .  ..?eFTLF8526
int ret;
30: 50 33 42 4e 4c 20 20 20 41 20 20 20 03 52 00 9d    P3BNL  A  ?R.?
        int busnum = 0;
40: 00 1a 00 00 4e 33 41 42 34 4c 56 20 20 20 20 20    .?..N3AB4LV   
 
50: 20 20 20 20 32 30 30 33 31 39 20 20 68 f0 03 de        200319  h???
ret = uclass_get_device_by_seq(UCLASS_I2C, busnum, &bus);
60: 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00    ................
if (ret) {
70: 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00    ................
          printf("%s: No bus %d\n", __func__, busnum);
80: 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00    ................
          return ret;
90: 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00    ................
}
a0: 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00    ................
 
b0: 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00    ................
        int chip_addr = 0x5B;
c0: 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00    ................
 
d0: 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00    ................
        struct udevice *dev;
e0: 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00    ................
 
f0: 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00    ................
        ret = i2c_get_chip(bus, chip_addr, 1, &dev);
root@cdm0:~#
if (ret) {
root@cdm0:~# i2cdump 0 0x51
          printf("%s: Bus %d no chip 0x%02x\n", __func__, busnum, chip_addr);
    0  1  2  3  4  5  6  7  8  9  a  b  c  d  e  f    0123456789abcdef
          return ret;
00: 5a 00 d8 00 55 00 e2 00 90 88 71 48 8c a0 75 30    Z.?.U.?.??qH??u0
}
10: 21 34 01 f4 1b 58 03 e8 31 2d 04 eb 1f 07 06 31    !4???X??1-?????1
20: 31 2d 00 64 27 10 00 9e 00 00 00 00 00 00 00 00    1-.d'?.?........
30: 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00    ................
40: 00 00 00 00 3f 80 00 00 00 00 00 00 01 00 00 00    ....??......?...
50: 01 00 00 00 01 00 00 00 01 00 00 00 00 00 00 b7    ?...?...?......?
60: 19 9f 80 c5 0e 17 12 c4 1f 99 00 00 00 00 30 00    ??????????....0.
70: 00 00 00 00 00 00 00 00 ff ff ff ff ff ff ff 01    ...............?
80: 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00    ................
90: 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00    ................
a0: 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00    ................
b0: 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00    ................
c0: 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00    ................
d0: 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00    ................
e0: 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00    ................
f0: 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00    ................
root@cdm0:~#
</pre>


        int dev_addr = 0x98;
== QSFP ==


        unsigned char data[8];
<pre>
         
QSFP i2c enable lines, active low:
        ret = dm_i2c_read(dev, dev_addr, data, 8);


if (ret) {
QSFP0_SEL - JENC-A 82 - PS-MIO40 - linux gpio 378
          printf("%s: Bus %d chip 0x%02x read error %d\n", __func__, busnum, chip_addr, ret);
QSFP1_SEL - JENC-A 84 - PS-MIO41 - linux gpio 379
          return ret;
QSFP2_SEL - JENC-A 100 - PS-MIO44 - linux gpio 382
}
QSFP3_SEL - JENC-A 106 - PS-MIO43 - linux gpio 381 (notice 2 and 3 are out of order)
 
        printf("%s: Bus %d chip 0x%02x addr 0x%02x read: 0x %02x %02x %02x %02x %02x %02x %02x %02x\n", __func__, busnum, chip_addr, dev_addr, data[0], data[1], data[2], data[3], data[4], data[5], data[6], data[7]);
 
        // see Atmel-8807-SEEPROM-AT24MAC402-602-Datasheet.pdf
 
        if (data[0] == 0) {
          // eiu-48 chip
          ethaddr[0] = data[2];
          ethaddr[1] = data[3];
          ethaddr[2] = data[4];
          ethaddr[3] = data[5];
          ethaddr[4] = data[6];
          ethaddr[5] = data[7];
        } else {
          // eiu-64 chip
          ethaddr[0] = data[0];
          ethaddr[1] = data[1];
          ethaddr[2] = data[2];
          ethaddr[3] = data[5];
          ethaddr[4] = data[6];
          ethaddr[5] = data[7];
        }
 
        printf("%s: ethaddr %02x:%02x:%02x:%02x:%02x:%02x\n", __func__, ethaddr[0], ethaddr[1], ethaddr[2], ethaddr[3], ethaddr[4], ethaddr[5]);
 
        return ret;
}
</pre>
</pre>


also this should have worked if i2c_xxx() functions were enabled in uboot:
<pre>
<pre>
i2c_set_bus_num(0);
# cat /sys/kernel/debug/gpio
i2c_probe(0x5b);
gpiochip0: GPIOs 338-511, parent: platform/ff0a0000.gpio, zynqmp_gpio:
i2c_read(0x5b, 0x9a, ethaddr, 6);
# echo 378 >> /sys/class/gpio/export ### SEL0 338+40
</pre>
# echo 379 >> /sys/class/gpio/export ### SEL1 338+41
 
# echo 381 >> /sys/class/gpio/export ### SEL3 338+43
= read ethernet mac address from i2c (SHOULD WORK) =
# echo 382 >> /sys/class/gpio/export ### SEL2 338+44
 
# cat /sys/kernel/debug/gpio
from: https://stackoverflow.com/questions/43637540/is-there-linux-or-u-boot-support-to-read-a-mac-address-from-a-chip-at-startup
gpiochip0: GPIOs 338-511, parent: platform/ff0a0000.gpio, zynqmp_gpio:
 
gpio-378 (                   |sysfs              ) in  hi
<pre>
gpio-379 (                   |sysfs              ) in  hi
#ethernet related setup
gpio-381 (                   |sysfs              ) in  hi
setup_eth=run readmac buildmac
gpio-382 (                    |sysfs              ) in  hi
#read mac address from eeprom
root@gdm0:~# echo out >> /sys/class/gpio/gpio381/direction
readmac=i2c dev 0; i2c read 50 FA.1 6 $loadaddr
root@gdm0:~# echo out >> /sys/class/gpio/gpio382/direction
#build the ethaddr variable
root@gdm0:~# echo out >> /sys/class/gpio/gpio378/direction
#not very nice, but does the job
root@gdm0:~# echo out >> /sys/class/gpio/gpio379/direction
buildmac=\
root@gdm0:~#
e=" "; sep=" " \
root@gdm0:~# cat /sys/kernel/debug/gpio
for i in 0 1 2 3 4 5 ; do\
gpiochip0: GPIOs 338-511, parent: platform/ff0a0000.gpio, zynqmp_gpio:
setexpr x $loadaddr + $i\
gpio-378 (                    |sysfs              ) out lo
setexpr.b b *$x\
gpio-379 (                    |sysfs              ) out lo
e="$e$sep$b"\
gpio-381 (                   |sysfs              ) out lo
sep=":"\
gpio-382 (                    |sysfs              ) out lo
done &&\
root@gdm0:~#
setenv ethaddr $e
echo 1 >> /sys/class/gpio/gpio381/value
echo 1 >> /sys/class/gpio/gpio382/value
echo 1 >> /sys/class/gpio/gpio378/value
echo 1 >> /sys/class/gpio/gpio379/value
cat /sys/kernel/debug/gpio
root@gdm0:~# cat /sys/kernel/debug/gpio
gpiochip0: GPIOs 338-511, parent: platform/ff0a0000.gpio, zynqmp_gpio:
gpio-378 (                    |sysfs              ) out hi
gpio-379 (                    |sysfs              ) out hi
gpio-381 (                    |sysfs              ) out hi
gpio-382 (                    |sysfs              ) out hi
root@gdm0:~#
root@gdm0:~# i2cdetect -y -r 0
    0  1  2  3  4  5  6  7  8  9  a  b  c  d  e  f
00:                        -- -- -- -- -- -- -- --  
10: -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- --
20: -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- --
30: -- -- -- 33 -- -- -- -- -- -- -- -- -- -- -- --
40: -- -- -- -- -- -- -- -- -- -- -- -- -- -- 4e --
50: -- -- -- 53 -- -- -- -- -- -- -- 5b -- -- -- --
60: -- -- -- -- -- -- -- -- -- -- -- 6b -- -- -- --
70: -- -- -- -- -- -- -- --                       
root@gdm0:~#
 
NOTICE NOTHING AT ADDRESS 0x50
</pre>
</pre>


= read ethernet mac address from i2c (DOES NOT WORK) =
<pre>
ENABLE QSFP0, OBSERVE IT IS AT ADDRESS 0x50


this method does not work: inside board/xilinx/common/board.c:int zynq_board_read_rom_ethaddr(unsigned char *ethaddr), uclass_get_device_by_ofnode(UCLASS_I2C_EEPROM, eeprom, &dev) returns ENODEV and read from i2c does not happen. K.O. Sep-2022
root@gdm0:~# echo 0 >> /sys/class/gpio/gpio378/value
root@gdm0:~# i2cdetect -y -r 0
    0  1  2  3  4  5  6  7  8  9  a  b  c d  e  f
00:                        -- -- -- -- -- -- -- --
10: -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- --
20: -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- --
30: -- -- -- 33 -- -- -- -- -- -- -- -- -- -- -- --
40: -- -- -- -- -- -- -- -- -- -- -- -- -- -- 4e --
50: 50 -- -- 53 -- -- -- -- -- -- -- 5b -- -- -- --
60: -- -- -- -- -- -- -- -- -- -- -- 6b -- -- -- --
70: -- -- -- -- -- -- -- --                       
root@gdm0:~#
root@gdm0:~# i2cdump -y 0 0x50
No size specified (using byte-data access)
    0  1  2  3  4  5  6  7  8  9  a  b  c  d  e  f    0123456789abcdef
00: 0d 00 02 8e 00 00 01 00 00 05 55 00 05 00 00 00    ?.??..?..?U.?...
10: 00 00 00 00 00 00 1e b8 00 00 81 a0 00 00 00 00    ......??..??....
20: 00 00 12 12 00 01 00 01 00 01 0e e0 0f 20 0e e0    ..??.?.?.???? ??
30: 00 00 1f a0 1e 3b 1f 72 00 01 00 00 00 00 00 00    ..???;?r.?......
40: 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00    ................
50: 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00    ................
60: 00 00 00 00 00 00 00 00 00 00 1f 00 00 00 08 00    ..........?...?.
70: 00 00 00 00 00 00 00 ff ff ff ff ff ff ff ff 00    ................
80: 0d 00 0c 04 00 00 00 40 40 02 d5 05 67 00 00 96    ?.??...@@???g..?
90: 00 00 c8 00 46 49 4e 49 53 41 52 20 43 4f 52 50    ..?.FINISAR CORP
a0: 20 20 20 20 07 00 90 65 46 54 4c 34 31 30 51 44        ?.?eFTL410QD
b0: 34 43 20 20 20 20 20 20 41 20 42 68 07 d0 00 43    4C      A Bh??.C
c0: 00 07 0f de 58 37 39 41 43 30 52 20 20 20 20 20    .???X79AC0R   
d0: 20 20 20 20 32 32 30 33 30 39 20 20 3c 10 00 9e        220309  <?.?
e0: 20 20 20 20 20 20 20 20 20 20 20 20 20 20 20 20                   
f0: 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00    ................
root@gdm0:~#
</pre>


Read:
== ethernet mac eeprom ==
* https://support.xilinx.com/s/question/0D52E00006hpKlsSAE/uboot-and-ethernet-mac-address-from-eeprom?language=en_US (last answer)
* https://github.com/Xilinx/u-boot-xlnx/blob/master/board/xilinx/common/board.c (zynq_board_read_rom_ethaddr())


Note:
* correct chip with 84-bit ethernet mac address
* 0x5B is the i2c chip address
* 0x9A is the data offset inside the chip, see datasheet or i2c read dump above.


Edit:
* emacs -nw PetaLinux_GDM_CDM/project-spec/meta-user/recipes-bsp/u-boot/files/platform-top.h
<pre>
<pre>
#include <configs/xilinx_zynqmp.h>
root@cdm1:~# i2cdump 0 0x53
#include <configs/platform-auto.h>
    0  1  2  3  4  5  6  7  8  9  a  b  c  d  e  f    0123456789abcdef
//#define CONFIG_I2C_EEPROM                                                                                                                                                                 
00: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
//#define CONFIG_SYS_I2C_EEPROM_ADDR 0x5b                                                                                                                                                   
10: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
//#define CONFIG_SYS_I2C_EEPROM_ADDR_OVERFLOW 0x0                                                                                                                                           
20: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
#define CONFIG_ZYNQ_GEM_I2C_MAC_OFFSET 0x9A
30: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
#error HERE!
40: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
</pre>
50: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
* emacs -nw PetaLinux_GDM_CDM/project-spec/meta-user/recipes-bsp/device-tree/files/system-user.dtsi
60: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
<pre>
70: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
/include/ "system-conf.dtsi"
80: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
/ {
90: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
chosen {
a0: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
   xlnx,eeprom = &eeprom;
b0: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
};
c0: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
};
d0: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
e0: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff   ................
f0: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
root@cdm1:~#


&i2c0 {
root@cdm1:~# i2cdump 0 0x5b
eeprom: eeprom@5b { /* u88 */
    0  1  2  3  4  5  6  7  8  9  a  b  c  d  e  f    0123456789abcdef
compatible = "atmel,24mac402";
00: XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX    XXXXXXXXXXXXXXXX
reg = <0x5b>;
10: XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX    XXXXXXXXXXXXXXXX
};
20: XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX    XXXXXXXXXXXXXXXX
};
30: XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX    XXXXXXXXXXXXXXXX
</pre>
40: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
* components/yocto/workspace/sources/u-boot-xlnx/configs/xilinx_zynqmp_virt_defconfig
50: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
<pre>
60: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
CONFIG_ZYNQ_GEM_I2C_MAC_OFFSET=0x9A
70: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
80: 0a 80 c2 04 34 10 08 32 a8 4b a0 00 a0 00 00 00    ????4??2?K?.?...
90: 00 00 00 00 00 00 00 00 00 00 fc c2 3d 1a 51 3c    ..........??=?Q<
a0: 0a 80 c2 04 34 10 08 32 a8 4b a0 00 a0 00 00 00    ????4??2?K?.?...
b0: 00 00 00 00 00 00 00 00 00 00 fc c2 3d 1a 51 3c    ..........??=?Q<
c0: XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX    XXXXXXXXXXXXXXXX
d0: XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX    XXXXXXXXXXXXXXXX
e0: XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX    XXXXXXXXXXXXXXXX
f0: XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX    XXXXXXXXXXXXXXXX
root@cdm1:~#
</pre>
</pre>
 
 
= enable VX clock =
* wrong "602" chip with 64-bit IPv6 address


<pre>
<pre>
devmem 0x80010010 32 0x8; sleep 1; devmem 0x80010010 32 0x0;
root@cdm0:~# i2cdump 0 0x53
si5394-i2c-file /media/sd-mmcblk1p1/00_freerun.txt 0 0x6b
    0  2  3  4  5  6  7  8  9  a  b  c  d  e  f    0123456789abcdef
</pre>
00: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
 
10: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
= clock chip configuration =
20: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
 
30: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
file CDM_v3.0_IN1_fixed_and_IN2_RX_Recovered_VX_62.5MHz_Si5394-RevA-Registers.txt:
40: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
 
50: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
* VCO is 14 GHz
60: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
* Tvco is 71.43 ps
70: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
* N0 divider is 14, frequency is 1000 MHz
80: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
* out0 from N0 divider 0x3 is (3+1)*2 = 8, freq 125 MHz
90: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
* out1 from N0 divider 0x7 is (7+1)*2 = 16, freq 62.5 MHz
a0: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
* out2 from N0 divider 0x7 is (7+1)*2 = 16, freq 62.5 MHz
b0: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
* out3 from N0 divider 0x3 is (3+1)*2 = 8, freq 125 MHz is the feedback for zero delay
c0: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
d0: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
e0: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
f0: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
root@cdm0:~# i2cdump 0 0x5b
    0  1 2 3  4  5  6  7  8 9  a  b  c  d  e  f    0123456789abcdef
00: XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX    XXXXXXXXXXXXXXXX
10: XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX    XXXXXXXXXXXXXXXX
20: XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX    XXXXXXXXXXXXXXXX
30: XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX    XXXXXXXXXXXXXXXX
40: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
50: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
60: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
70: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
80: 0a 90 85 04 94 10 08 51 10 5b a0 00 a0 00 00 00    ???????Q?[?.?...
90: 00 00 00 00 00 00 00 00 fc c2 3d 00 00 12 1a 2e    ........??=..??.
a0: 0a 90 85 04 94 10 08 51 10 5b a0 00 a0 00 00 00    ???????Q?[?.?...
b0: 00 00 00 00 00 00 00 00 fc c2 3d 00 00 12 1a 2e    ........??=..??.
c0: XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX    XXXXXXXXXXXXXXXX
d0: XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX    XXXXXXXXXXXXXXXX
e0: XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX    XXXXXXXXXXXXXXXX
f0: XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX    XXXXXXXXXXXXXXXX
root@cdm0:~#
</pre>
 
= read ethernet mac address from i2c =
 
(this code is copied from uboot command line i2c code)


= clock chip monitoring =
in uboot sources board/xilinx/common/board.c replace original function with this:


from si5395-94-92-family.pdf:
<pre>
* reg 0x1: page select, set to 0 or set to 5 to read 0x53F
// special code to read ethernet MAC address from the DS-DM-Rev0 board. K.O. Sep-2022
* reg 0x2: 0x94
 
* reg 0x3: 0x53 -> device is a si5394
int zynq_board_read_rom_ethaddr(unsigned char *ethaddr)
* reg 0xC: LOSXAXB
{
* reg 0xD: LOS and OOF for the 4 clock inputs
        struct udevice *bus;
* reg 0xE: LOL and HOLD
int ret;
* reg 0xF: CAL_PLL
        int busnum = 0;
* reg 0x11: sticky bits for reg 0xC
 
* reg 0x12: sticky bits for reg 0xD
ret = uclass_get_device_by_seq(UCLASS_I2C, busnum, &bus);
* reg 0x13: sticky bits for reg 0xE
if (ret) {
* reg 0x14: sticky bits for reg 0xF
          printf("%s: No bus %d\n", __func__, busnum);
* reg 0x1C: device reset
          return ret;
* reg 0x1E: low power, hard reset, SYNC
}
* reg 0x507: currently selected input clock
* reg 0x52A: input clock select
* reg 0x53F: HOLD_HIST_VALID and FASTLOCK_STATUS


= arm and linux benchmark =
        int chip_addr = 0x5B;


memory benchmark:
        struct udevice *dev;


<pre>
        ret = i2c_get_chip(bus, chip_addr, 1, &dev);
daq13$ arm-linux-gnueabi-gcc -o memcpy.armv7 memcpy.cc -march=armv7 -static -O2
if (ret) {
scp memcpy.armv7 to ...
          printf("%s: Bus %d no chip 0x%02x\n", __func__, busnum, chip_addr);
root@gdm-cdm:~# ./memcpy.armv7
          return ret;
memcpy      1 KiBytes:  1288 MB/sec
}
memcpy      2 KiBytes:  1924 MB/sec
memcpy      4 KiBytes:  2554 MB/sec
memcpy      8 KiBytes:  3054 MB/sec
memcpy      16 KiBytes:  3262 MB/sec
memcpy      32 KiBytes:  3250 MB/sec
memcpy      64 KiBytes:  3456 MB/sec
memcpy    128 KiBytes:  3556 MB/sec
memcpy    256 KiBytes:  3780 MB/sec
memcpy    512 KiBytes:  3795 MB/sec
memcpy    1024 KiBytes:  3789 MB/sec
memcpy    2048 KiBytes:   3729 MB/sec
memcpy    4096 KiBytes:  3717 MB/sec
memcpy    8192 KiBytes:  3687 MB/sec
memcpy  16384 KiBytes:  3632 MB/sec
memcpy  32768 KiBytes:  3529 MB/sec
memcpy  65536 KiBytes:  3318 MB/sec
memcpy  131072 KiBytes:  2893 MB/sec
root@gdm-cdm:~#
</pre>


ethernet receive:
        int dev_addr = 0x98;


<pre>
        unsigned char data[8];
daq13:bin$ ./ttcp -t -s -n 100000 10.0.0.24
         
ttcp-t: buflen=8192, nbuf=100000, align=16384/0, port=5001  tcp  -> 10.0.0.24
        ret = dm_i2c_read(dev, dev_addr, data, 8);
ttcp-t: socket
ttcp-t: connect
ttcp-t: 819200000 bytes in 7.25 real seconds = 110358.39 KB/sec +++
ttcp-t: 100000 I/O calls, msec/call = 0.07, calls/sec = 13794.80
ttcp-t: 0.0user 0.2sys 0:07real 3% 0i+0d 760maxrss 0+2pf 1461+31csw
daq13:bin$


root@gdm-cdm:~# ./ttcp.armv7 -r -s
if (ret) {
ttcp-r: buflen=8192, nbuf=2048, align=16384/0, port=5001  tcp
          printf("%s: Bus %d chip 0x%02x read error %d\n", __func__, busnum, chip_addr, ret);
ttcp-r: socket
          return ret;
ttcp-r: accept from 10.0.0.25
}
ttcp-r: 819200000 bytes in 7.27 real seconds = 110098.22 KB/sec +++
ttcp-r: 212040 I/O calls, msec/call = 0.04, calls/sec = 29181.53
ttcp-r: 0.1user 5.7sys 0:07real 81% 0i+0d 584maxrss 0+2pf 125601+2699csw
root@gdm-cdm:~#
</pre>


ethernet transmit:
        printf("%s: Bus %d chip 0x%02x addr 0x%02x read: 0x %02x %02x %02x %02x %02x %02x %02x %02x\n", __func__, busnum, chip_addr, dev_addr, data[0], data[1], data[2], data[3], data[4], data[5], data[6], data[7]);


<pre>
        // see Atmel-8807-SEEPROM-AT24MAC402-602-Datasheet.pdf
root@gdm-cdm:~# ./ttcp.armv7 -t -s -n 100000 10.0.0.25
ttcp-t: buflen=8192, nbuf=100000, align=16384/0, port=5001  tcp  -> 10.0.0.25
ttcp-t: socket
ttcp-t: connect
ttcp-t: 819200000 bytes in 6.95 real seconds = 115078.69 KB/sec +++
ttcp-t: 100000 I/O calls, msec/call = 0.07, calls/sec = 14384.84
ttcp-t: 0.0user 0.7sys 0:06real 11% 0i+0d 584maxrss 0+2pf 1162+1017csw
root@gdm-cdm:~#


daq13:bin$ ./ttcp -r -s
        if (data[0] == 0) {
ttcp-r: buflen=8192, nbuf=2048, align=16384/0, port=5001  tcp
          // eiu-48 chip
ttcp-r: socket
          ethaddr[0] = data[2];
ttcp-r: accept from 10.0.0.24
          ethaddr[1] = data[3];
ttcp-r: 819200000 bytes in 6.97 real seconds = 114841.84 KB/sec +++
          ethaddr[2] = data[4];
ttcp-r: 161335 I/O calls, msec/call = 0.04, calls/sec = 23160.01
          ethaddr[3] = data[5];
ttcp-r: 0.0user 1.9sys 0:06real 28% 0i+0d 760maxrss 0+2pf 80646+51csw
          ethaddr[4] = data[6];
daq13:bin$
          ethaddr[5] = data[7];
        } else {
          // eiu-64 chip
          ethaddr[0] = data[0];
          ethaddr[1] = data[1];
          ethaddr[2] = data[2];
          ethaddr[3] = data[5];
          ethaddr[4] = data[6];
          ethaddr[5] = data[7];
        }
 
        printf("%s: ethaddr %02x:%02x:%02x:%02x:%02x:%02x\n", __func__, ethaddr[0], ethaddr[1], ethaddr[2], ethaddr[3], ethaddr[4], ethaddr[5]);
 
        return ret;
}
</pre>
 
also this should have worked if i2c_xxx() functions were enabled in uboot:
<pre>
i2c_set_bus_num(0);
i2c_probe(0x5b);
i2c_read(0x5b, 0x9a, ethaddr, 6);
</pre>
</pre>


= Install Xilinx tools =
= read ethernet mac address from i2c (SHOULD WORK) =
 
from: https://stackoverflow.com/questions/43637540/is-there-linux-or-u-boot-support-to-read-a-mac-address-from-a-chip-at-startup


* install Vivado 2020.2
<pre>
<pre>
login at https://www.xilinx.com/myprofile.html
#ethernet related setup
go to "Downloads"
setup_eth=run readmac buildmac
go to archive,
#read mac address from eeprom
find 2020.2
readmac=i2c dev 0; i2c read 50 FA.1 6 $loadaddr
download Xilinx_Unified_2020.2_1118_1232_Lin64.bin
#build the ethaddr variable
sh ./Xilinx_Unified_2020.2_1118_1232_Lin64.bin
#not very nice, but does the job
banner window should open with spinner "downloading installation data"
buildmac=\
"a newer version is available" -> say "continue"
e=" "; sep=" " \
next
for i in 0 1 2 3 4 5 ; do\
"select install type" window:
setexpr x $loadaddr + $i\
provide email and password,
setexpr.b b *$x\
select "download image"
e="$e$sep$b"\
select directory /home/olchansk/Xilinx/Downloads/2020.2\
sep=":"\
select "linux" and "full image"
done &&\
next
setenv ethaddr $e
download summary: space required 38.52 Gbytes
</pre>
download
 
installation progress
= read ethernet mac address from i2c (DOES NOT WORK) =
downloading spinner, 16 M/s 47 minutes...
 
"download image has been created successfully". Ok.
this method does not work: inside board/xilinx/common/board.c:int zynq_board_read_rom_ethaddr(unsigned char *ethaddr), uclass_get_device_by_ofnode(UCLASS_I2C_EEPROM, eeprom, &dev) returns ENODEV and read from i2c does not happen. K.O. Sep-2022
check contents of /home/olchansk/Xilinx/Downloads/2020.2
 
ls -l /home/olchansk/Xilinx/Downloads/2020.2
Read:
total 67
* https://support.xilinx.com/s/question/0D52E00006hpKlsSAE/uboot-and-ethernet-mac-address-from-eeprom?language=en_US (last answer)
drwxr-xr-x 2 olchansk users    9 Sep 1 16:22 bin
* https://github.com/Xilinx/u-boot-xlnx/blob/master/board/xilinx/common/board.c (zynq_board_read_rom_ethaddr())
drwxr-xr-x 3 olchansk users  15 Sep  1 16:23 data
 
drwxr-xr-x 4 olchansk users    4 Sep  1 16:22 lib
Note:
drwxr-xr-x 2 olchansk users  644 Sep  1 16:22 payload
* 0x5B is the i2c chip address
drwxr-xr-x 2 olchansk users    7 Sep  1 16:22 scripts
* 0x9A is the data offset inside the chip, see datasheet or i2c read dump above.
drwxr-xr-x 4 olchansk users    4 Sep  1 16:22 tps
 
-rwxr-xr-x 1 olchansk users 3256 Nov 18  2020 xsetup
Edit:
daq13:2020.2$
* emacs -nw PetaLinux_GDM_CDM/project-spec/meta-user/recipes-bsp/u-boot/files/platform-top.h
./xsetup
spinned loading installation data
xilinx design tools 2022.1 now available -> say continue
"welcome" -> next
"select product" -> vivado -> next -> vivado hl system edition -> next
select devices: only zynq ultrascale+ mpsoc -> next
select destination: /opt/Xilinx (as root, mkdir /opt/Xilinx, chmod olchansk.users /opt/Xilinx)
install ...
complete
move /home/olchansk/Xilinx/Downloads/2020.2 to /daq/daqstore/olchansk/Xilinx/Downloads/
</pre>
* install petalinux 2020.2
<pre>
<pre>
./xsetup
#include <configs/xilinx_zynqmp.h>
"a newer version is available" -> say "continue"
#include <configs/platform-auto.h>
next
//#define CONFIG_I2C_EEPROM                                                                                                                                                                 
"select product to install" -> select Petalinux (Linux only) -> next
//#define CONFIG_SYS_I2C_EEPROM_ADDR 0x5b                                                                                                                                                   
"select destination directory" -> select "/opt/Xilinx" (disk space required 2.64 GB) -> next
//#define CONFIG_SYS_I2C_EEPROM_ADDR_OVERFLOW 0x0                                                                                                                                           
"summary" -> install ...
#define CONFIG_ZYNQ_GEM_I2C_MAC_OFFSET 0x9A
error about missing /tmp/tmp-something files
#error HERE!
"installation completed successfully" (hard to dismiss, "ok" button is partially cut-off)
done?
I think it failed, /opt/Xilinx/PetaLinux/2020.2/bin is empty except for petalinux-v2020.2-final-installer.run
try to run it by hand, same error about /tmp/tmp-something files. strange...
notice it complains about "truncate", which truncate finds ~/bin/truncate, get rid of it,
try again
now complains about missing texinfo and zlib1g:i386
apt install texinfo -> ok
apt install zlib1g:i386 -> installs bunch of gcc stuff -> ok
try again
reports "already installed" -> delete /opt/Xilinx/.xinstall/PetaLinux_2020.2/, delete entries in ~/.Xilinx/registry/installedSW.xml
try again
success
</pre>
</pre>
* install vivado 2022.1 and petalinux 2022.1 - everything is pretty much the same
* emacs -nw PetaLinux_GDM_CDM/project-spec/meta-user/recipes-bsp/device-tree/files/system-user.dtsi
 
= Petalinux =
 
* cd PetaLinux_GDM_CDM
* petalinux-config
* enable i2c MAC address and DHCP
<pre>
<pre>
git clone https://bitbucket.org:/team-ds-dm/ds-dm-u-boot-xlnx.git
/include/ "system-conf.dtsi"
cd ds-dm-u-boot-xlnx
/ {
git checkout ds-dm-u-boot-xlnx
chosen {
  xlnx,eeprom = &eeprom;
};
};


linux-components ->
&i2c0 {
uboot -> ext-local-src
eeprom: eeprom@5b { /* u88 */
external u-boot local source -> ds-dm-u-boot-xlnx (path to the customized uboot git repository)
compatible = "atmel,24mac402";
reg = <0x5b>;
};
};
</pre>
</pre>
* enable DHCP
* components/yocto/workspace/sources/u-boot-xlnx/configs/xilinx_zynqmp_virt_defconfig
<pre>
<pre>
Subsystem AUTO Hardware Settings -> Ethernet Settings
CONFIG_ZYNQ_GEM_I2C_MAC_OFFSET=0x9A
randomize MAC address -> NO
ethernet mac address -> leave empty
obtain ip address automatically -> YES
</pre>
</pre>
* set hostname and product names
 
= RTC chip =
 
* DS3231 RTC chip
* FPGA connections:
<pre>
<pre>
Firmware Version Configuration ->
I2C SCL <- J-ENC A85 <- FPGA E17 <- XDC TP_S <- VHDL TP_S is output
Host name -> "ds-dm"
I2C SDA <-> J-ENC A87 <-> FPGA D17 <-> XDC TP_S <- VHDL TP_S is output
Product name -> "Petalinux_GDM_CDM"
1pps -> J-ENC B129 -> FPGA AE3 -> XDC "free pin"
1pps -> J-ENC C160 -> FPGA AH12 -> XDC "slow_io"
</pre>
</pre>
* configure linux kernel
 
= enable VX clock =
 
<pre>
<pre>
petalinux-config -c kernel
devmem 0x80010010 32 0x8; sleep 1;  devmem 0x80010010 32 0x0;
si5394-i2c-file /media/sd-mmcblk1p1/00_freerun.txt 0 0x6b
</pre>
</pre>
* enable NFS-Root
<pre>
petalinux-config
Image Packaging Configuration > Root File System Type -> set to NFS
Location of NFS root directory set to "/nfsroot"


petalinux-config -c kernel
= clock chip configuration =
Networking support > IP: kernel level configuration
 
enable DHCP, BOOTP, RARP
file CDM_v3.0_IN1_fixed_and_IN2_RX_Recovered_VX_62.5MHz_Si5394-RevA-Registers.txt:
File systems > Network file systems > Root file systems on NFS
</pre>
* manually fix linux kernel command line:
<pre>
grep nfsroot PetaLinux_GDM_CDM/project-spec/configs/config
edit CONFIG_SUBSYSTEM_BOOTARGS_GENERATED to read
earlycon console=ttyPS0,115200 clk_ignore_unused panic=60 root=/dev/nfs nfsroot=/nfsroot/%s ip=dhcp rw
</pre>
* check configuration in
** PetaLinux_GDM_CDM/project-spec/configs/config
** PetaLinux_GDM_CDM/project-spec/configs/rootfs_config
** PetaLinux_GDM_CDM/components/plnx_workspace/device-tree/device-tree/system-conf.dtsi


= JTAG server =
* VCO is 14 GHz
* Tvco is 71.43 ps
* N0 divider is 14, frequency is 1000 MHz
* out0 from N0 divider 0x3 is (3+1)*2 = 8, freq 125 MHz
* out1 from N0 divider 0x7 is (7+1)*2 = 16, freq 62.5 MHz
* out2 from N0 divider 0x7 is (7+1)*2 = 16, freq 62.5 MHz
* out3 from N0 divider 0x3 is (3+1)*2 = 8, freq 125 MHz is the feedback for zero delay


localhost:3121
= clock chip monitoring =


= ds20k block =
from si5395-94-92-family.pdf:
 
* reg 0x1: page select, set to 0 or set to 5 to read 0x53F
<pre>
* reg 0x2: 0x94
module ds20k
* reg 0x3: 0x53 -> device is a si5394
  (
* reg 0xC: LOSXAXB
  //    CLOCK INPUTs
* reg 0xD: LOS and OOF for the 4 clock inputs
  input wire clk,
* reg 0xE: LOL and HOLD
  input reset, // pulse for power-up reset
* reg 0xF: CAL_PLL
  input wire pll_is_locked, // clock cleaner PLL is locked to selected input clock
* reg 0x11: sticky bits for reg 0xC
* reg 0x12: sticky bits for reg 0xD
* reg 0x13: sticky bits for reg 0xE
* reg 0x14: sticky bits for reg 0xF
* reg 0x1C: device reset
* reg 0x1E: low power, hard reset, SYNC
* reg 0x507: currently selected input clock
* reg 0x52A: input clock select
* reg 0x535: FORCE_HOLD
* reg 0x53F: HOLD_HIST_VALID and FASTLOCK_STATUS


  //    REGISTER_DATA
= arm and linux benchmark =
 
  input wire [255:0] [31:0] register_data_in,
  output reg [255:0] [31:0] register_data_out,
  input wire register_write_strobe, // pulse when AXI write transaction puts new data in register_data_in
  input wire register_read_ack, // pulse after AXI read transaction captures data from register_data_out, used to read from FIFO
 
  //    GDM QSFP FIBER LINKS
  output reg [11:0] [15:0] qsfp_tx_data,
  output reg [11:0] [1:0]  qsfp_tx_ctrl,
  input wire [11:0] [15:0] qsfp_rx_data_error, // not sure what this is.
  input wire [11:0] [15:0] qsfp_rx_data,
  input wire [11:0] [1:0]  qsfp_rx_ctrl,
  input wire [11:0] qsfp_rx_is_good, // single bit indicating that RX link is up and data is good.


  // CDM SFP FIBER LINKS
memory benchmark:
  output reg [15:0] sfp_tx_data,
  output reg [1:0]  sfp_tx_ctrl,
  input wire [15:0] sfp_rx_data,
  input wire [1:0]  sfp_rx_ctrl,
  input wire        sfp_rx_is_good, // single bit indicating that RX link is up and data is good.
     
  //    VX_RXs
  input wire [3:0] vx1_rx,
  input wire [3:0] vx2_rx, 
  input wire [3:0] vx3_rx, 
  input wire [3:0] vx4_rx, 
  input wire [3:0] vx5_rx, 
  input wire [3:0] vx6_rx, 
  input wire [3:0] vx7_rx, 
  input wire [3:0] vx8_rx,
  input wire [3:0] vx9_rx, 
  input wire [3:0] vx10_rx,   
  input wire [3:0] vx11_rx,
  input wire [3:0] vx12_rx,
 
  //    VX_TXs
  output reg [2:0] vx1_tx_out,
  output reg [2:0] vx2_tx_out,
  output reg [2:0] vx3_tx_out,
  output reg [2:0] vx4_tx_out,
  output reg [2:0] vx5_tx_out,
  output reg [2:0] vx6_tx_out,
  output reg [2:0] vx7_tx_out,
  output reg [2:0] vx8_tx_out,
  output reg [2:0] vx9_tx_out,
  output reg [2:0] vx10_tx_out,
  output reg [2:0] vx11_tx_out,
  output reg [2:0] vx12_tx_out,


  // remove input wire gdm_trg,
<pre>
  // remove input wire gdm_tsm,
daq13$ arm-linux-gnueabi-gcc -o memcpy.armv7 memcpy.cc -march=armv7 -static -O2
 
scp memcpy.armv7 to ...
  //   LEMO INPUTs
root@gdm-cdm:~# ./memcpy.armv7
  input wire [4:1] ext_in_lv_async, // direct connection to LEMO connectors, not clocked
memcpy      1 KiBytes:  1288 MB/sec
      
memcpy      2 KiBytes:  1924 MB/sec
   //    LEMO OUTPUTs
memcpy      4 KiBytes:  2554 MB/sec
   output reg [2:1] ext_out, // direct connection to LEMO connectors, not clocked
memcpy      8 KiBytes:  3054 MB/sec
   
memcpy      16 KiBytes:  3262 MB/sec
  //   FRONT PANEL LEDs
memcpy      32 KiBytes:  3250 MB/sec
  output reg [3:0] fp_led_out, // direct connection to LEMO connectors, not clocked
memcpy      64 KiBytes:   3456 MB/sec
memcpy    128 KiBytes:  3556 MB/sec
memcpy    256 KiBytes:  3780 MB/sec
memcpy     512 KiBytes:  3795 MB/sec
memcpy   1024 KiBytes:  3789 MB/sec
memcpy    2048 KiBytes:  3729 MB/sec
memcpy   4096 KiBytes:  3717 MB/sec
memcpy   8192 KiBytes:   3687 MB/sec
memcpy  16384 KiBytes:  3632 MB/sec
memcpy  32768 KiBytes:  3529 MB/sec
memcpy  65536 KiBytes:  3318 MB/sec
memcpy  131072 KiBytes:  2893 MB/sec
root@gdm-cdm:~#
</pre>
 
ethernet receive:


  //   trigger and tsm output
<pre>
  // remove output reg trg_out,
daq13:bin$ ./ttcp -t -s -n 100000 10.0.0.24
  // remove output reg tsm_out
ttcp-t: buflen=8192, nbuf=100000, align=16384/0, port=5001  tcp  -> 10.0.0.24
  );
ttcp-t: socket
ttcp-t: connect
ttcp-t: 819200000 bytes in 7.25 real seconds = 110358.39 KB/sec +++
ttcp-t: 100000 I/O calls, msec/call = 0.07, calls/sec = 13794.80
ttcp-t: 0.0user 0.2sys 0:07real 3% 0i+0d 760maxrss 0+2pf 1461+31csw
daq13:bin$
 
root@gdm-cdm:~# ./ttcp.armv7 -r -s
ttcp-r: buflen=8192, nbuf=2048, align=16384/0, port=5001  tcp
ttcp-r: socket
ttcp-r: accept from 10.0.0.25
ttcp-r: 819200000 bytes in 7.27 real seconds = 110098.22 KB/sec +++
ttcp-r: 212040 I/O calls, msec/call = 0.04, calls/sec = 29181.53
ttcp-r: 0.1user 5.7sys 0:07real 81% 0i+0d 584maxrss 0+2pf 125601+2699csw
root@gdm-cdm:~#
</pre>
</pre>


= world view =
ethernet transmit:
 
Note:
* red lines: clocks
* green lines: AXI/Avalon packet streams
* blue lines: serial data
 
[[File:GDM-CDM-VX.drawio.svg]]
 
= Firmware registers =
 
== Block 0 ==


<pre>
<pre>
0 | ALL | ALL | RO | USR_ACCESSE2 see https://docs.xilinx.com/r/en-US/ug974-vivado-ultrascale-libraries/USR_ACCESSE2
root@gdm-cdm:~# ./ttcp.armv7 -t -s -n 100000 10.0.0.25
ttcp-t: buflen=8192, nbuf=100000, align=16384/0, port=5001  tcp  -> 10.0.0.25
ttcp-t: socket
ttcp-t: connect
ttcp-t: 819200000 bytes in 6.95 real seconds = 115078.69 KB/sec +++
ttcp-t: 100000 I/O calls, msec/call = 0.07, calls/sec = 14384.84
ttcp-t: 0.0user 0.7sys 0:06real 11% 0i+0d 584maxrss 0+2pf 1162+1017csw
root@gdm-cdm:~#
 
daq13:bin$ ./ttcp -r -s
ttcp-r: buflen=8192, nbuf=2048, align=16384/0, port=5001  tcp
ttcp-r: socket
ttcp-r: accept from 10.0.0.24
ttcp-r: 819200000 bytes in 6.97 real seconds = 114841.84 KB/sec +++
ttcp-r: 161335 I/O calls, msec/call = 0.04, calls/sec = 23160.01
ttcp-r: 0.0user 1.9sys 0:06real 28% 0i+0d 760maxrss 0+2pf 80646+51csw
daq13:bin$
</pre>
</pre>


== Block 1 ==
= Install Xilinx tools =
 
== Block 2 ==
 
== Block 3 ==
 
DS20k registers:
 
* busybox devmem 0x80013000 32


* install Vivado 2020.2
<pre>
<pre>
reg | version   | xDM | xx | description
login at https://www.xilinx.com/myprofile.html
  0 | 0x20230731 | ALL | RO | ds20k version
go to "Downloads"
  1 | 0x20230731 | ALL | RW | scratch read/write register
go to archive,
  2 | 0x20230731 | ALL | RW | configure inputs and outputs
find 2020.2
  3 | 0x20230731 | ALL | RW | FP_LED mux
download Xilinx_Unified_2020.2_1118_1232_Lin64.bin
  4 | 0x20230731 | ALL | RW | EXT_OUT mux
sh ./Xilinx_Unified_2020.2_1118_1232_Lin64.bin
  5 | 0x20230731 | ALL | RO | VX_RX state
banner window should open with spinner "downloading installation data"
  6 | 0x20230731 | ALL | RO | VX_RX, LEMO_IN, VX_TX, FP_LED, EXT_OUT state
"a newer version is available" -> say "continue"
  7 | 0x20230731 | ALL | RW | LED_OUT, EXT_OUT, VX_TX outputs
next
  8 | 0x20230731 | ALL | RW | VX_TX mux and config
"select install type" window:
  9 | 0x20230731 | ALL | RW | trigger config
provide email and password,
10 | -         | ALL | RO | status register
select "download image"
11 | 0x20230731 | ALL | RO | trigger counter
select directory /home/olchansk/Xilinx/Downloads/2020.2\
  12 | 0x20230731 | ALL | RO | time slice marker counter
select "linux" and "full image"
13 | -         | GDM | RO | GPS 1pps period, 125 MHz
next
14 | -         | GDM | RO | Ru clock 1pps period, 125 MHz
download summary: space required 38.52 Gbytes
  15 | 0x20230811 | CDM | RO | SFP RX status
download
  16 | 0x20230811 | CDM | RW | SFP TX control
installation progress
  17 | 0x20230811 | GDM | RO | QSFP RX data 0, 1
downloading spinner, 16 M/s 47 minutes...
  18 |            |.    |.  | 2, 3
"download image has been created successfully". Ok.
19 |            |.   |.  | 4, 5
check contents of /home/olchansk/Xilinx/Downloads/2020.2
  20 |            |.    |.  | 6, 7
ls -l /home/olchansk/Xilinx/Downloads/2020.2
21 |            |    |.   | 8, 9
total 67
22 |            |.   |.  | 10, 11
drwxr-xr-x 2 olchansk users    9 Sep 1 16:22 bin
23 | 0x20230811 | GDM | RW | QSFP TX control
drwxr-xr-x 3 olchansk users  15 Sep 1 16:23 data
</pre>
drwxr-xr-x 4 olchansk users    4 Sep 1 16:22 lib
 
drwxr-xr-x 2 olchansk users  644 Sep 1 16:22 payload
=== Register 0 0x80013000 ds20k version ===
drwxr-xr-x 2 olchansk users    7 Sep 1 16:22 scripts
 
drwxr-xr-x 4 olchansk users   4 Sep  1 16:22 tps
ds20k version 0xYYYYMMDD
-rwxr-xr-x 1 olchansk users 3256 Nov 18 2020 xsetup
 
daq13:2020.2$
=== Register 1 0x80013004 scratch ===
./xsetup
 
spinned loading installation data
scratch read-write register
xilinx design tools 2022.1 now available -> say continue
 
"welcome" -> next
=== Register 2 0x80013008 input and output config ===
"select product" -> vivado -> next -> vivado hl system edition -> next
 
select devices: only zynq ultrascale+ mpsoc -> next
select destination: /opt/Xilinx (as root, mkdir /opt/Xilinx, chmod olchansk.users /opt/Xilinx)
install ...
complete
move /home/olchansk/Xilinx/Downloads/2020.2 to /daq/daqstore/olchansk/Xilinx/Downloads/
</pre>
* install petalinux 2020.2
<pre>
<pre>
bit | version | fpga name      | description
./xsetup
  0 | ALL    | lemo_enable    | enable LEMO input 1
"a newer version is available" -> say "continue"
  1 |.       |                | 2
next
  2 |        |.               | 3
"select product to install" -> select Petalinux (Linux only) -> next
  3 |        |                | 4
"select destination directory" -> select "/opt/Xilinx" (disk space required 2.64 GB) -> next
  4 | ALL.    | lemo_invert    | invert LEMO input 1
"summary" -> install ...
  5 |        |                | 2
error about missing /tmp/tmp-something files
  6 |        |                | 3
"installation completed successfully" (hard to dismiss, "ok" button is partially cut-off)
  7 |        |                | 4
done?
  9 | ALL    | ext_out_disable | disable LEMO output 1
I think it failed, /opt/Xilinx/PetaLinux/2020.2/bin is empty except for petalinux-v2020.2-final-installer.run
10 |        |                | 2
try to run it by hand, same error about /tmp/tmp-something files. strange...
11 | ALL.    | ext_out_invert  | invert LEMO output 1
notice it complains about "truncate", which truncate finds ~/bin/truncate, get rid of it,
12 |        |                | 2
try again
now complains about missing texinfo and zlib1g:i386
apt install texinfo -> ok
apt install zlib1g:i386 -> installs bunch of gcc stuff -> ok
try again
reports "already installed" -> delete /opt/Xilinx/.xinstall/PetaLinux_2020.2/, delete entries in ~/.Xilinx/registry/installedSW.xml
try again
success
</pre>
</pre>
* install vivado 2022.1 and petalinux 2022.1 - everything is pretty much the same


=== Register 3 0x8001300C FP_LED control ===
= Petalinux =


* cd PetaLinux_GDM_CDM
* petalinux-config
* enable i2c MAC address and DHCP
<pre>
<pre>
wire [15:0] led_out_mux_sel  = register_data_in[3][15:0];
git clone https://bitbucket.org:/team-ds-dm/ds-dm-u-boot-xlnx.git
wire [3:0]  led_out_invert  = register_data_in[2][19:16];
cd ds-dm-u-boot-xlnx
</pre>
git checkout ds-dm-u-boot-xlnx


<pre>
linux-components ->
led_out_mux_sel is 4 groups (one per LED) of 4 bits (choice 0..15):
uboot -> ext-local-src
mux | version | fpga name      | description
external u-boot local source -> ds-dm-u-boot-xlnx (path to the customized uboot git repository)
  0 | ALL.    |                | power on default
</pre>
  1 | ALL    | led_out_reg    | register 7 bits
* enable DHCP
  2 | -       | -               | reserved for "PLL locked"
<pre>
  3 | -       | -               | reserved for "SFP link is good"
Subsystem AUTO Hardware Settings -> Ethernet Settings
  4 | ALL.    | lemo_in_sync[1] | LEMO input 1
randomize MAC address -> NO
  5 | ALL    | lemo_in_sync[2] | LEMO input 2
ethernet mac address -> leave empty
  6 | ALL    | lemo_in_sync[3] | LEMO input 3
obtain ip address automatically -> YES
  7 | ALL    | lemo_in_sync[4] | LEMO input 4
  8 | ALL    | ext_out[1]      | LEMO output 1
  9 | ALL    | ext_out[2]      | LEMO output 2
10 |
11 |
12 |
13 |
14 |
15 | ALL    |                | fixed logic level 1
</pre>
</pre>
 
* set hostname and product names
=== Register 4 0x80013010 LEMO OUT control ===
 
<pre>
<pre>
wire [7:0] ext_out_mux_sel = register_data_in[4][7:0];
Firmware Version Configuration ->
Host name -> "ds-dm"
Product name -> "Petalinux_GDM_CDM"
</pre>
</pre>
 
* configure linux kernel
<pre>
<pre>
ext_out_mux_sel is 2 groups (one per LEMO) of 4 bits (choice 0..15):
petalinux-config -c kernel
0 - power on default
1 - ext_out_reg register 7
2 - trg_pulser
3 - vx1_tx_out[0] for VX loopback test
4 - vx1_rx[3] for VX loopback test
5 - vx1_rx3_sync for VX loopback test
6
7
8
9
10
11
12
13
14
15 - fixed logic level 1
</pre>
</pre>
 
* enable NFS-Root
=== Register 5 0x80013014 VX_RX status ===
 
<pre>
<pre>
assign register_data_out[5] = {
petalinux-config
                vx8_rx[3], vx8_rx[2], vx8_rx[1], vx8_rx[0],
Image Packaging Configuration > Root File System Type -> set to NFS
                vx7_rx[3], vx7_rx[2], vx7_rx[1], vx7_rx[0],
Location of NFS root directory set to "/nfsroot"
                vx6_rx[3], vx6_rx[2], vx6_rx[1], vx6_rx[0],
 
                vx5_rx[3], vx5_rx[2], vx5_rx[1], vx5_rx[0],
petalinux-config -c kernel
                vx4_rx[3], vx4_rx[2], vx4_rx[1], vx4_rx[0],
Networking support > IP: kernel level configuration
                vx3_rx[3], vx3_rx[2], vx3_rx[1], vx3_rx[0],
enable DHCP, BOOTP, RARP
                vx2_rx[3], vx2_rx[2], vx2_rx[1], vx2_rx[0],
File systems > Network file systems > Root file systems on NFS
                vx1_rx[3], vx1_rx[2], vx1_rx[1], vx1_rx[0]
</pre>
                };
* manually fix linux kernel command line:
<pre>
grep nfsroot PetaLinux_GDM_CDM/project-spec/configs/config
edit CONFIG_SUBSYSTEM_BOOTARGS_GENERATED to read
earlycon console=ttyPS0,115200 clk_ignore_unused panic=60 root=/dev/nfs nfsroot=/nfsroot/%s ip=dhcp rw
</pre>
</pre>
* check configuration in
** PetaLinux_GDM_CDM/project-spec/configs/config
** PetaLinux_GDM_CDM/project-spec/configs/rootfs_config
** PetaLinux_GDM_CDM/components/plnx_workspace/device-tree/device-tree/system-conf.dtsi
= JTAG server =
localhost:3121


=== Register 6 0x80013018 VX_RX, LEMO_IN, VX_TX, FP_LED, EXT_OUT state ===
= ds20k block =


<pre>
<pre>
assign register_data_out[6] = {
module ds20k
                vx2_tx_out[2], vx2_tx_out[1], vx2_tx_out[0], vx1_tx_out[2],
  (
                vx1_tx_out[1], vx1_tx_out[0], ext_out[2], ext_out[1],
  //    CLOCK INPUTs
                fp_led_out[3], fp_led_out[2], fp_led_out[1], fp_led_out[0],
  input wire clk,
                ext_in_lv[4], ext_in_lv[3], ext_in_lv[2], ext_in_lv[1],
  input reset, // pulse for power-up reset
                vx12_rx[3], vx12_rx[2], vx12_rx[1], vx12_rx[0],
  input wire pll_is_locked, // clock cleaner PLL is locked to selected input clock
                vx11_rx[3], vx11_rx[2], vx11_rx[1], vx11_rx[0],
                vx10_rx[3], vx10_rx[2], vx10_rx[1], vx10_rx[0],
                vx9_rx[3], vx9_rx[2], vx9_rx[1], vx9_rx[0]
                };
</pre>


<pre>
  //    REGISTER_DATA
bit | version | fpga name      | description
 
  0 | ALL    | vx9_rx          | VX_RX
  input wire [255:0] [31:0] register_data_in,
  1 |        |                |
  output reg [255:0] [31:0] register_data_out,
  2 |        |                |
  input wire register_write_strobe, // pulse when AXI write transaction puts new data in register_data_in
  3 |        |                |
  input wire register_read_ack, // pulse after AXI read transaction captures data from register_data_out, used to read from FIFO
  4 | ALL    | vx10_rx        | VX_RX
 
  5 |        |                |
  //    GDM QSFP FIBER LINKS
  6 |        |                |
  output reg [11:0] [15:0] qsfp_tx_data,
  7 |        |                |
  output reg [11:0] [1:0] qsfp_tx_ctrl,
  8 | ALL    | vx11_rx        | VX_RX
  input wire [11:0] [15:0] qsfp_rx_data_error, // not sure what this is.
  9 |        |                |
  input wire [11:0] [15:0] qsfp_rx_data,
  10 |        |                |
  input wire [11:0] [1:0] qsfp_rx_ctrl,
11 |        |                |
  input wire [11:0] qsfp_rx_is_good, // single bit indicating that RX link is up and data is good.
12 | ALL    | vx12_rx        | VX_RX
13 |        |                |
14 |        |                |
15 |        |                |
16 | ALL    | ext_in_lv      | LEMO inputs
17 |        |                |
18 |        |                |
19 |        |                |
20 | ALL    | FP_LED          | FP_LEDs
21 |        |                |
22 |        |                |
23 |        |                |
24 | ALL    | ext_out[1]     | LEMO outputs
25 |        | ext_out[2]     |
26 | ALL    | vx1_tx          | VX1_TX
27 |        |                |
28 |        |                |
29 | ALL    | vx2_tx          | VX2_TX
30 |        |                |
31 |        |                |
</pre>


=== Register 7 0x8001301C LED_OUT, EXT_OUT, VX_TX outputs ===
  // CDM SFP FIBER LINKS
 
  output reg [15:0] sfp_tx_data,
<pre>
  output reg [1:0]  sfp_tx_ctrl,
   wire [3:0] led_out_reg = register_data_in[7][3:0];
  input wire [15:0] sfp_rx_data,
   wire [2:1] ext_out_reg = register_data_in[7][5:4];
  input wire [1:0]  sfp_rx_ctrl,
   // register_data_in[7][6];
  input wire        sfp_rx_is_good, // single bit indicating that RX link is up and data is good.
   // register_data_in[7][7];
     
   wire [7:0] vx_tx_out_reg = register_data_in[7][15:8];
  //    VX_RXs
</pre>
  input wire [3:0] vx1_rx,
  input wire [3:0] vx2_rx,
  input wire [3:0] vx3_rx, 
  input wire [3:0] vx4_rx, 
  input wire [3:0] vx5_rx, 
  input wire [3:0] vx6_rx, 
   input wire [3:0] vx7_rx, 
  input wire [3:0] vx8_rx,
  input wire [3:0] vx9_rx, 
   input wire [3:0] vx10_rx,   
  input wire [3:0] vx11_rx,
  input wire [3:0] vx12_rx,
 
   //   VX_TXs
  output reg [2:0] vx1_tx_out,
  output reg [2:0] vx2_tx_out,
  output reg [2:0] vx3_tx_out,
  output reg [2:0] vx4_tx_out,
  output reg [2:0] vx5_tx_out,
   output reg [2:0] vx6_tx_out,
  output reg [2:0] vx7_tx_out,
   output reg [2:0] vx8_tx_out,
  output reg [2:0] vx9_tx_out,
  output reg [2:0] vx10_tx_out,
  output reg [2:0] vx11_tx_out,
  output reg [2:0] vx12_tx_out,


<pre>
  // remove input wire gdm_trg,
bit | version | fpga name      | description
  // remove input wire gdm_tsm,
  0 | ALL    | led_out_reg    | FP_LED 1
 
  1 |        |                | 2
  //    LEMO INPUTs
  2 |        |                | 3
  input wire [4:1] ext_in_lv_async, // direct connection to LEMO connectors, not clocked
  3 |        |                | 4
   
  4 | ALL    | ext_out_reg    | LEMO OUT 1
  //    LEMO OUTPUTs
  5 |        |                | 2
  output reg [2:1] ext_out, // direct connection to LEMO connectors, not clocked
  6 | -       |                |
   
  7 | -       |                |
  //    FRONT PANEL LEDs
  8 | ALL    | vx_tx_out_reg  | VX1_TX 0
  output reg [3:0] fp_led_out, // direct connection to LEMO connectors, not clocked
  9 |        |                | 1
 
10 |        |                | 2
  //    trigger and tsm output
11 |        |                | -
  // remove output reg trg_out,
12 | ALL    |                | VX2_TX 0
  // remove output reg tsm_out
13 |        |                | 1
  );
14 |        |                | 2
</pre>
15 |        |                | -
 
16 | -       |                |
= world view =
17 |        |                |
 
18 |        |                |
Note:
19 |        |                |
* red lines: clocks
20 |        |                |
* green lines: AXI/Avalon packet streams
21 |        |                |
* blue lines: serial data
22 |        |                |
 
23 |        |                |
[[File:GDM-CDM-VX.drawio.svg]]
24 |        |                |
 
25 |        |                |
== description ==
26 |        |                |
 
27 |        |                |
same thing, in words:
28 |        |                |
 
29 |        |                |
<pre>
30 |        |                |
detector
31 |        |                |
digitizer, 125 MHz
digital filter
digital discriminator
hit map, 64 bits at 125 MHz (could be 250 MHz, filter and discriminator clock)
packetizer, 64 bits -> id, timestamp, 8x 8-bit words, eop
8/10 serializer, 12.5 MHz parallel in, 125 MHz serial out
lvds line to CDM vx_rx
BBB: also VX busy to lvds line to CDM vx_rx, do not want to depend on serial comm for vx busy, do not want to inject async data into the hit map packet stream
--- CDM
lvds line capture in IBUF register, vxN_rx clock, 125 MHz clock, from PLL with adjustable phase, scan phase to find sweet spot
vx rx 10/8 deserializer, vxN_rx clock, stobes out parallel data every 10 clocks at 12.5 MHz
vx rx phase transfer from vxN_rx clock to main CDM clock, have 10 clocks for transfer to happen
from here everything is on the CDM main clock
vx rx packet adapter, 12.5 MHz 8-bit packets to 125 MHz 16-bit packets, internal FIFO to avoid data overrun
sfp tx mux, all VX packet streams into one CDM sfp tx packet stream
BBB: capture VX RX busy to CDM main clock (IBUF register), grand-or becomes vx_rx_busy
sfp tx packetizer (data,eop,vx_rx_busy -> data,k)
sfp tx 16/20 serializer, 16 bit at 125 MHz in, 2500 MHz serial out (20 bits at 125 MHz)
sfp tx fiber link to GDM, 2 Gigabits/sec
--- GDM
qsfp rx deserializer, 16 bit at 125 MHz output on main GDM clock
qsfp rx depacketizer (data,k -> packet data,eop; qsfp_rx_busy)
qsfp rx demux, hit map packets routed to GDM trigger logic block
GDM trigger logic block looks at hit map, generates yes/no trigger decision, encodes it as a trigger packet
TSM generator encodes GPS time data as a TSM packet
qsfp tx mux - trigger packets, tsm packets, etc to qsfp tx packet stream
qsfp tx packetizer (data,eop;trg,tsm,bsy -> data,k)
NB: the same tx data is sent to all 12 qsfp tx ports, to make sure we do not accidentally desync the CDMs.
qsfp tx 16/20 serializer, 16-bit at 125 MHz to 20-bit at 250 MHz to 2500 MHz serial out
qsfp tx fiber link to CDM, 2 Gigabits/sec
--- CDM
sfp rx 20/16 deserializer, 16-bit at 125 MHz
sfp rx depacketizer, (data,k -> data,eop;trg_in,tsm_in,bsy_in)
sfp rx demux (in reality, noop, all packets go to same place, vx tx)
vx tx mux (packets from GDM, packets with simulated waveforms from CDM midas frontend via AXI FIFO)
vx tx packet adapter 16-bit at 125 MHz to 8-bit at 12.5 MHz strobed every 10 clocks. NB: most important, this 10-clock strobe runs in sync between all CDMs!
vx tx phase transfer from main CDM clock to vxN_tx clock, have 10 clocks for transfer to happen
from here we run on the vxN_tx clock
vx txN serializer, 8-bit at 12.5 MHz to 125 MHz serial
vx_txN OBUF register, vxN_rx clock, 125 MHz clock, from PLL with adjustable phase, scan phase to find sweet spot
lvds line to vx
BBB: bsy_in from GDM is converted from pulse to level, goes out lvds line to vx, sync to vxN_tx clock
TTT: trg_in from GDM is a pulse, does out lvds line to vx, sync to vxN_tx clock.
NB: tsm is always a packet, bsy is always a signal (no packet), trg can be a packet or signal.
--- VX
lvds data captured by 125 MHz ADC sampling clock (CAEN base firmware logic)
lvds data connected to Yair's block
10/8 deserializer
depacketizer (data,k -> data,eop) to avoid accidental desync, we do not send any no trg, no tsm, no bsy K-codes.
demux
trigger packets go their way (4x 64 bit words of data go to event header: timestamps, hitmap data)
tsm packets go their way (4x 64 bit words of data go to tsm event header: timestamps, GPS time data)
BBB: bsy from lvds line stops waveform acquisition
TTT: trg from lvds line cause waveform acquisition, same as trg packet, but has no timestamp and other data attached to it.
</pre>
</pre>


=== Register 8 0x80013020 VX_TX config ===
= Firmware registers =
 
== Block 0 ==


<pre>
<pre>
wire [3:0] vx_tx_mux_sel = register_data_in[8][3:0];
0 | ALL | ALL | RO | USR_ACCESSE2 see https://docs.xilinx.com/r/en-US/ug974-vivado-ultrascale-libraries/USR_ACCESSE2
</pre>
</pre>


<pre>
== Block 1 ==
vx_tx_mux_sel is 4 bits (choice 0..15):
 
0 - power on default, control by vx_tx_out_reg
== Block 2 ==
1 - GDM
 
2 - CDM
== Block 3 ==
3 - pulser loopback test
4 - pulser loopback test
5 - 62.5 MHz output
6 - 125 MHz output
7
8
9
10
11
12
13
14
15
</pre>


=== Register 9 0x80013024 trigger control ===
=== DS20k block register map ===


<pre>
* busybox devmem 0x80013000 32
  wire [7:0] trg_src_mask      = register_data_in[9][7:0];
  wire [7:0] tsm_src_mask      = register_data_in[9][15:8];
  wire      trg_pulser_enable = register_data_in[9][16];
  wire      tsm_pulser_enable = register_data_in[9][17];
  wire      trg_software      = register_data_in[9][18];
  wire      tsm_software      = register_data_in[9][19];
  // bits 20:31 not used
</pre>


<pre>
Note: R=readable, W=writable, L=latched by CMD_LATCH, B=reset on begin of run
wire [7:0]      xxx_src_bits =
                    {
                    sfp_rx[1],
                    sfp_rx[0],
                    tsm_pulser & tsm_pulser_enable,
                    trg_pulser & trg_pulser_enable,
                    lemo_in_sync[4],
                    lemo_in_sync[3],
                    lemo_in_sync[2],
                    lemo_in_sync[1]
                    };
</pre>


<pre>
<pre>
trg_src_mask and tsm_src_mask bits:
reg | version    | xDM | xx | description
0 - LEMO IN 1
  0 | 0x20230731 | ALL | RO | ds20k version
1 - LEMO IN 2
  0 | 0x20240118 | ALL | RW | ds20k version and command
2 - LEMO IN 3
  1 | 0x20230731 | ALL | RW | scratch read/write register
3 - LEMO IN 4
  2 | 0x20230731 | ALL | RW | configure inputs and outputs
4 - trg_pulser
  3 | 0x20230731 | ALL | RW | FP_LED mux
5 - tsm_pulser
  4 | 0x20230731 | ALL | RW | EXT_OUT mux
6 - sfp_rx[0]
  5 | 0x20230731 | ALL | RO | VX_RX state
7 - sfp_rx[1]
  6 | 0x20230731 | ALL | RO | VX_RX, LEMO_IN, VX_TX, FP_LED, EXT_OUT state
  7 | 0x20230731 | ALL | RW | LED_OUT, EXT_OUT, VX_TX outputs
  8 | 0x20230731 | ALL | RW | VX_TX mux and config
  9 | 0x20230731 | ALL | RW | trigger config
10 | 0x20231013 | ALL | RO | status register
11 | 0x20230731 | ALL | RO | trigger counter
12 | 0x20230731 | ALL | RO | time slice marker counter
13 | 0x20240814 | ALL | RO | GPS 1pps period, 125 MHz
14 | 0x20240814 | ALL | RO | Ru clock 1pps period, 125 MHz
15 | 0x20230811 | CDM | RO | SFP RX status
16 | 0x20230811 | CDM | RW | SFP TX control
17 | 0x20230811 | GDM | RO | QSFP RX data 0, 1
18 |            |.    |.  | 2, 3
19 |            |.    |.  | 4, 5
20 |            |.    |.  | 6, 7
21 |            |    |.  | 8, 9
22 |            |.    |.  | 10, 11
23 | 0x20230811 | GDM | RW | QSFP TX control
24 | 0x20231013 | ALL | RW | trigger pulser period
25 | 0x20231013 | ALL | RW | trigger pulser burst control
26 | 0x20231013 | ALL | RW | tsm pulser period
27 | 0x20231204 | ALL | RW | data fifo CPU to FPGA
28 | 0x20231204 | ALL | RW | packet loopback control
28 | 0x20240118 | ALL | RW | data fifo FPGA to CPU
29 | 0x20231208 | GDM | RW | bitmap of active qsfp ports
29 | 0x20240118 | ALL | RW | packet loopback control
29 | 0x20240510 | ALL | RW | packet routing
30 | 0x20231208 | GDM | RO | qsfp link status ports 0..7
31 | 0x20231208 | GDM | RO | qsfp link status ports 8..11
32 | 0x20240118 | GDM | RW | enabled QSFP ports
33 | 0x20240118 | CDM | RW | enabled VX ports
34,35 | 0x20240118 | ALL | RO | time stamp 64 bits
36,37 | 0x20240118 | ALL | RO | old time stamp
38,39,40 | 0x20240118 | CDM | RO | VX busy counters
41,42,43 | 0x20240118 | GDM | RO | QSFP busy counters
44 | 0x20240118 | CDM | RO | cdm_bsy_up_counter and cdm_bsy_pulse_counter
45 | 0x20240118 | CDM | RO | cdm_veto_pulse_counter and cdm_veto_up_counter
46 | 0x20240118 | GDM | RO | gdm_bsy_pulse_counter and gdm_bsy_up_counter
47 | 0x20240118 | GDM | RO | gdm_bsy_refresh_counter
48 | 0x20240118 | GDM | RO |  gdm_veto_up_counter and gdm_veto_pulse_counter
49,50,51 | 0x20240424 | CDM | RO | VX RX serial data monitor, 8 bits per VX port
52,53    | 0x20240424 | CDM | RO | VX serial link status, 4 bits per VX port
54 | 0x20240424 | CDM | RO | VX TX serial data monitor
55 | 0x20240430 | ALL | RO | QSFP, SFP and VX link loss counters
56 | 0x20240510 | ALL | RO | sfp_rx_packet_counter
57 | same      | ALL | RO | sfp_tx_packet_counter
58 | same      | ALL | RO | qsfp_rx_packet_counter[0]
59 | same      | ALL | RO | qsfp_tx_packet_counter
60 | same      | ALL | RO | vx_rx_packet_counter[0]
61 | same      | ALL | RO | vx_tx_packet_counter
62 | 0x20240719 | CDM | RO | cdm_hitmap_period, ports 0, 1
63 | same      | CDM | RO | ports 2, 3
64 | same      | CDM | RO | ports 4, 5
65 | same      | CDM | RO | ports 6, 7
66 | same      | CDM | RO | ports 8, 9
67 | same      | CDM | RO | ports 10, 11
68 | 0x20240814 | ALL | RW | GPS control and status
69 | 0x20241104 | CDM | RO | vx_tx_trg_packet_counter, counter of TRG packets CDM->VX
70 | 0x20241104 | CDM | RO | vx_tx_tsm_packet_counter, counter of TSM packets CDM->VX
71 | 0x20241104 | ALL | RO | packet error bits
72,73 | 0x20241104 | CDM | ROL | vx_tx_trg_data_latched[63:0] trigger packet data
74,75 | 0x20241104 | CDM | ROL | vx_tx_tsm_data_latched[63:0] tsm packet data (truncated to 64 bits)
76 | 0x20241104 | CDM | ROL | cdm_hitmap_trigger_counter_latched, counter of hitmap triggers generated in the CDM
77,78,79 | 0x20241104 | CDM | ROL | vx_rx_hitmap_data_latched | VX_RX 80 bits of HITMAP packet from VX
</pre>
</pre>


=== Register 10 0x80013028 status register ===
=== Register 0 0x80013000 ds20k version ===
 
on read: ds20k version 0xYYYYMMDD
 
on write:
*  0 - noop - as of version 0x20240118, write a zero after writing a command
*  1 - cmd_reset - reset logic to good state
*  2 - cmd_arm_ts - arm timestamp reset
*  3 - cmd_trg - issue a trigger
*  4 - cmd_tsm - issue a tsm
*  5 - cmd_vx_rx_reset - reset the VX receive path
*  6 - cmd_vx_tx_reset - reset the VX transmit path
*  7 - cmd_hitmap_trg - generate a hitmap trigger and data packet
*  8 - cmd_trg_pulser_reset - reset the trigger pulser
*  9 - cmd_tsm_pulser_reset - reset the tsm pulser
* 10 - cmd_bor_start - start begin-of-run trigger sequence
* 11 - cmd_bor_clear - after run has started, clear begin-of-run status bits
* 12 - cmd_latch - latch counters & etc into AXI registers for coherent readout
 
=== Register 1 0x80013004 scratch ===
 
scratch read-write register
 
=== Register 2 0x80013008 input and output config ===


<pre>
<pre>
bit | version | fpga name      | description
bit | version | fpga name      | description
   0 |         |                 |  
   0 | ALL    | lemo_enable    | enable LEMO input 1
   1 |        |                |  
   1 |        |                | 2
   2 |        |                |  
   2 |        |                | 3
   3 |        |                |  
   3 |        |                | 4
   4 |         |                 |  
   4 | ALL    | lemo_invert    | invert LEMO input 1
   5 |        |                |  
   5 |        |                | 2
   6 |        |                |  
   6 |        |                | 3
   7 |        |                |  
   7 |        |                | 4
  8 |        |                |
   9 | ALL    | ext_out_disable | disable LEMO output 1
   9 |         |                 |  
  10 |        |                | 2
  10 |        |                |  
  11 | ALL    | ext_out_invert  | invert LEMO output 1
  11 |         |                 |  
  12 |        |                | 2
  12 |        |                |  
</pre>
  13 |        |                |
 
  14 |         |                 |  
=== Register 3 0x8001300C FP_LED control ===
15 |         |                |  
 
16 |         |                 |  
<pre>
17 |         |                 |  
wire [15:0] led_out_mux_sel = register_data_in[3][15:0];
18 |         |                 |  
wire [3:0] led_out_invert  = register_data_in[3][19:16];
19 |         |                 |  
</pre>
20 |         |                 |  
 
21 |         |                 |  
<pre>
22 |         |                 |  
led_out_mux_sel is 4 groups (one per LED) of 4 bits (choice 0..15):
23 |         |                 |  
mux | version    | fpga name      | description
24 |         |                 |  
  0 | ALL        |                | power on default
25 |         |                 |  
  1 | ALL        | led_out_reg    | register 7 bits
26 |         |                 |  
  2 | 0x20231013 | pll_locked      | clock chip PLL is locked
27 |         |                 |  
  3 | 0x20231013 | sfp_link_status | SFP link is good
28 |        |                 |
  3 | 0x20240118 | sfp_link_status or qsfp_tx_link_rx_status | SFP/QSFP link is good
29 |        |                 |
  4 | ALL        | lemo_in_sync[1] | LEMO input 1
30 |         |                 |  
  5 | ALL        | lemo_in_sync[2] | LEMO input 2
31 |         |                |  
  6 | ALL        | lemo_in_sync[3] | LEMO input 3
  7 | ALL        | lemo_in_sync[4] | LEMO input 4
  8 | ALL        | ext_out[1]      | LEMO output 1
  9 | ALL        | ext_out[2]      | LEMO output 2
  A | 0x20231013 | trg_in          | trigger
  B | 0x20231013 | tsm_in          | time slice marker
  C | 0x20240118 | gdm_bsy         | GDM busy: OR of all CDM busy
  D | 0x20240118 | cdm_bsy         | CDM busy: OR of all VX busy
  E | 0x20240118 | cdm_veto        | GDM busy -> GDM veto -> CDM veto -> VX trigger veto
  F | ALL        |                | fixed logic level 1
</pre>
</pre>


=== Register 11 0x8001302C trg_counter ===
=== Register 4 0x80013010 LEMO OUT control ===


trigger counter
<pre>
wire [7:0] ext_out_mux_sel = register_data_in[4][7:0];
</pre>


=== Register 12 0x80013030 tsm_counter ===
<pre>
ext_out_mux_sel is 2 groups (one per LEMO) of 4 bits (choice 0..15):


time slice marker counter
mux | version    | fpga name      | description
  0 | ALL        |                | power on default
  1 | ALL        | ext_out_reg    | register 7
  2 | ALL        | trg_pulser      | pulser trigger
  3 | 0x20240724 | vx1_tx_out[2]  | vx1 serial data out
  4 | 0x20240724 | vx1_rx[1]      | vx1 serial data in
  5 | 0x20240724 | vx_rx_iob[0]    | vx1 serial data in captured by IOB register
  6 | ALL        | lemo_in_async[1]| test synchronizer
  7 | ALL        | lemo_in_sync[1] | test synchronizer
  8 | 0x20240724 | trg_in_pulse    | trigger signal
  9 | 0x20240724 | tsm_in_pulse    | time slice marker signal
  A | 0x20240118 | cdm_bsy        | CDM busy from VX
  B | 0x20240118 | gdm_bsy        | GDM busy from CDM
  C | 0x20240118 | cdm_veto        | veto from GDM to CDM to VX
  D | 0x20240118 | vx1_rx[1]      | serial data VX to CDM
  E | not used (sink)
  F | ALL        | 1              | fixed logic level 1
</pre>


=== Register 13 0x80013034 GPS 1pps period ===
=== Register 5 0x80013014 VX_RX status ===
 
reserved
 
=== Register 14 0x80013038 Rb clock 1pps period ===
 
reserved
 
=== Register 15 0x8001303C SFP RX status ===


<pre>
<pre>
bit | ds20k version | fpga signal name | description
assign register_data_out[5] = {
  0 | ALL        | sfp_rx_data[15:0]   | cdm sfp received data
                vx8_rx[3], vx8_rx[2], vx8_rx[1], vx8_rx[0],
16 | same      | sfp_rx_data_is_k[0] |
                vx7_rx[3], vx7_rx[2], vx7_rx[1], vx7_rx[0],
17 | same      | sfp_rx_data_is_k[1] |
                vx6_rx[3], vx6_rx[2], vx6_rx[1], vx6_rx[0],
18 |            | 0                   |
                vx5_rx[3], vx5_rx[2], vx5_rx[1], vx5_rx[0],
19 |            | 0                   |
                vx4_rx[3], vx4_rx[2], vx4_rx[1], vx4_rx[0],
20 | 0x20231013 | sfp_link_status    | sfp link connected, exchanging data
                vx3_rx[3], vx3_rx[2], vx3_rx[1], vx3_rx[0],
21 | same      | sfp_link_rx_status  | sfp link receiving correct idle pattern from GDM TX
                vx2_rx[3], vx2_rx[2], vx2_rx[1], vx2_rx[0],
22 | same      | sfp_link_error      | sfp link receiver error (badk or overflow)
                vx1_rx[3], vx1_rx[2], vx1_rx[1], vx1_rx[0]
23 | same      | sfp_rx_data_error  | sfp transceiver state machine is in error state
                };
24 |            |                    |
25 |            |                    |
26 |            |                    |
27 |            |                    |
28 |            |                    |
29 |            |                    |
30 |            |                    |
31 |            |                    |
</pre>
</pre>


=== Register 16 0x80013040 SFP TX control ===
=== Register 6 0x80013018 VX_RX, LEMO_IN, VX_TX, FP_LED, EXT_OUT state ===


<pre>
<pre>
  wire [15:0] sfp_tx_data_reg = register_data_in[16][15:0];
assign register_data_out[6] = {
  wire [1:0] sfp_tx_ctrl_reg = register_data_in[16][17:16];
                vx2_tx_out[2], vx2_tx_out[1], vx2_tx_out[0], vx1_tx_out[2],
  wire sfp_tx_sel_lpb        = register_data_in[16][29]; // serial loopback
                vx1_tx_out[1], vx1_tx_out[0], ext_out[2], ext_out[1],
  wire sfp_tx_sel_trg        = register_data_in[16][30]; // 16 individual bits
                fp_led_out[3], fp_led_out[2], fp_led_out[1], fp_led_out[0],
  wire sfp_tx_sel_reg        = register_data_in[16][31]; // from register
                ext_in_lv[4], ext_in_lv[3], ext_in_lv[2], ext_in_lv[1],
</pre>
                vx12_rx[3], vx12_rx[2], vx12_rx[1], vx12_rx[0],
 
                vx11_rx[3], vx11_rx[2], vx11_rx[1], vx11_rx[0],
=== Register 17-22 0x80013044 QSFP RX data ===
                vx10_rx[3], vx10_rx[2], vx10_rx[1], vx10_rx[0],
 
                vx9_rx[3], vx9_rx[2], vx9_rx[1], vx9_rx[0]
QSFP RX data links 0..11
                };
 
=== Register 23 0x800130xx QSFP TX control ===
 
<pre>
  wire [15:0] qsfp_tx_data_reg = register_data_in[23][15:0];
  wire [1:0] qsfp_tx_ctrl_reg = register_data_in[23][17:16];
  wire qsfp_tx_sel_lpb        = register_data_in[23][29]; // loopback
  wire qsfp_tx_sel_trg        = register_data_in[23][30]; // 16 individual bits
  wire qsfp_tx_sel_reg        = register_data_in[23][31]; // data from register
</pre>
</pre>
= Firmware registers branch develop_ko =
== Register map ==


<pre>
<pre>
   0 | ALL | ALL | RO | USR_ACCESSE2 see https://docs.xilinx.com/r/en-US/ug974-vivado-ultrascale-libraries/USR_ACCESSE2
bit | version | fpga name      | description
   1 | ALL | ALL | RW | read write scratch register
   0 | ALL     | vx9_rx          | VX_RX
   2 | ALL | CDM | ?? | MGT not used
  1 |        |                 |  
   3 | ALL | CDM | RO | MGT debug_data
   2 |        |                |  
   4 | ALL | CDM | RW | clk_config_vec
  3 |         |                 |  
  5 | ALL | CDM | ?? | not used
   4 | ALL     | vx10_rx        | VX_RX
  6 | ALL | CDM | RO | CDM_link_data_processing:o_error_time
  5 |         |                 |  
  7 | ALL | CDM | RO | CDM_link_data_processing:o_error_count
   6 |        |                |  
 
  7 |         |                 |  
255 | ALL | ALL | RW | control register
   8 | ALL     | vx11_rx        | VX_RX
  9 |        |                |  
10 |        |                |
11 |        |                |
12 | ALL     | vx12_rx        | VX_RX
13 |         |                 |  
14 |        |                |
15 |        |                |
16 | ALL     | ext_in_lv      | LEMO inputs
17 |         |                 |  
18 |        |                |
19 |        |                |
20 | ALL     | FP_LED          | FP_LEDs
21 |        |                |
22 |         |                 |  
23 |        |                |
24 | ALL     | ext_out[1]      | LEMO outputs
25 |        | ext_out[2]      |
26 | ALL    | vx1_tx          | VX1_TX
27 |        |                |
28 |        |                |
29 | ALL     | vx2_tx          | VX2_TX
30 |        |                |
31 |        |                 |  
</pre>
</pre>


== register 0 0x80010000 ==
=== Register 7 0x8001301C LED_OUT, EXT_OUT, VX_TX outputs ===


GDM:
<pre>
<pre>
0 - gdm_link_interface:i_mgt_rst
  wire [3:0] led_out_reg = register_data_in[7][3:0];
2 - gdm_link_interface:i_link_down_latched_rst
  wire [2:1] ext_out_reg = register_data_in[7][5:4];
8 - GDM_link_data_processing:i_rst
  // register_data_in[7][6];
10..9 - GDM_link_data_processing:i_data_mode
  // register_data_in[7][7];
  wire [7:0] vx_tx_out_reg = register_data_in[7][15:8];
</pre>
</pre>


CDM:
<pre>
<pre>
0 - cdm_link_interface:i_mgt_rst
bit | version | fpga name      | description
2 - cdm_link_interface:i_link_down_latched_rst
  0 | ALL    | led_out_reg    | FP_LED 1
8 - CDM_link_data_processing:i_rst
  1 |        |                | 2
10..9 - CDM_link_data_processing:i_data_mode
  2 |        |                | 3
</pre>
  3 |        |                | 4
 
  4 | ALL    | ext_out_reg    | LEMO OUT 1
== register 1 0x80010004 ==
  5 |        |                | 2
 
  6 | -       |                |
GDM:
  7 | -       |                |
<pre>
  8 | ALL    | vx_tx_out_reg  | VX1_TX 0
nlinks-1..0 - gdm_link_interface:i_rx_slide_trigger
  9 |        |                | 1
</pre>
10 |        |                | 2
 
11 |        |                | -
CDM:
12 | ALL    |                | VX2_TX 0
<pre>
13 |        |                | 1
nlinks-1..0 - cdm_link_interface:i_rx_slide_trigger
14 |        |                | 2
</pre>
15 |        |                | -
 
16 | -      |                |
== register 2 0x80010008 ==
17 |        |                |
 
18 |        |                |
GDM:
19 |        |                |
<pre>
20 |        |                |
nlinks-1..0 - gdm_link_interface:o_link_power_good
21 |        |                |
nlinks+15..16 - gdm_link_interface:o_link_status
22 |        |                |
23 |        |                |
24 |        |                |
25 |        |                |
26 |        |                |
27 |        |                |
28 |        |                |
29 |        |                |
30 |        |                |
31 |        |                |
</pre>
</pre>


CDM:
=== Register 8 0x80013020 VX_TX config ===
<pre>
nlinks-1..0 - cdm_link_interface:o_link_power_good
nlinks+15..16 - cdm_link_interface:o_link_status
</pre>
 
== register 3 0x8001000c ==


GDM: simple loopback register
CDM:
<pre>
<pre>
31..0 - debug_data - cdm_link_interface:o_debug
wire [3:0] vx_tx_mux_sel = register_data_in[8][3:0];
vx_tx_loopback          = register_data_in[8][31];
</pre>
</pre>


o_debug:
<pre>
<pre>
rx_link_rst & rx_error & rx_link_up & rx_receiving_data &
vx_tx_mux_sel is 4 bits (choice 0..15):
std_logic_vector(rx_state_count) & tx_state_count_on_rx_clk & i_rx_ctrl3(0) &
0 - power on default, control by vx_tx_out_reg
i_rx_ctrl1(1 downto 0) & i_rx_ctrl0(1 downto 0) &
1 - GDM
rx_data_is_k28p1_k28p5 &
2 - CDM
i_rx_data;
3 - pulser loopback test
4 - pulser loopback test
5 - 62.5 MHz output
6 - 125 MHz output
7 - trg, tsm, serial
8 - trg, tsm, lvds serial rx to serial tx loopback
9 - GPS box control (ds20k rev 0x20240814)
10
11
12
13
14
15 - production config: trg, veto, serial
</pre>
</pre>


== register 4 0x80010010 ==
=== Register 9 trg and tsm source ===
 
from version 0x20240724


GDM write:
<pre>
<pre>
0 - clk_config_vec(0) - CLK_IN_SEL_LS(0)
  wire [15:0] trg_src_mask      = register_data_in[9][15:0];
1 - clk_config_vec(1) - CLK_IN_SEL_LS(1)
  wire [31:16] tsm_src_mask      = register_data_in[9][31:16];
2 - clk_config_vec(2) - CLK_EXT_SEL_LS
3 - clk_config_vec(3) - CLK_RSTn_LS
</pre>
</pre>


GDM read:
<pre>
<pre>
0 - clk_config_vec(0) - CLK_IN_SEL_LS(0)
  wire [15:0]      trg_src_bits =
1 - clk_config_vec(1) - CLK_IN_SEL_LS(1)
                    {
2 - clk_config_vec(2) - CLK_EXT_SEL_LS
                    1'b0,            // 15
3 - clk_config_vec(3) - CLK_RSTn_LS
                    1'b0,            // 14
4 - clk_config_vec(4) - CLK_LOSXTn_LS
                    vx_tx_tsm_done,  // 13
5 - clk_config_vec(5) - CLK_LOLn_LS
                    vx_tx_trg_done,  // 12
6 - clk_config_vec(6) - CLK_INTn_LS
7 - constant 1
31..8 - constant 0
</pre>


== register 5 0x80010014 ==
                    1'b0, // gdm_hitmap_trigger, // 11
                    cdm_hitmap_trigger, // 10
                    sfp_rx_tsm,      // 9
                    sfp_rx_trg,      // 8


not used
                    sfp_rx_data[1],  // 7
                    sfp_rx_data[0],  // 6
                    tsm_pulser,      // 5
                    trg_pulser,      // 4


== register 6 0x80010018 ==
                    lemo_in_sync[4], // 3
                    lemo_in_sync[3], // 2
                    lemo_in_sync[2], // 1
                    lemo_in_sync[1]  // 0
                    };
 
  wire [15:0]      trg_bits = trg_src_bits & trg_src_mask;
  wire [15:0]      tsm_bits = trg_src_bits & tsm_src_mask;
</pre>


GDM:
before that:
<pre>
3..0 - GDM_link_data_processing:i_status_select
</pre>


CDM:
<pre>
<pre>
31..0 - CDM_link_data_processing:o_error_count
  wire [7:0] trg_src_mask      = register_data_in[9][7:0];
  wire [7:0] tsm_src_mask      = register_data_in[9][15:8];
  wire      trg_pulser_enable = register_data_in[9][16];
  wire      tsm_pulser_enable = register_data_in[9][17];
  wire      trg_software      = register_data_in[9][18];
  wire      tsm_software      = register_data_in[9][19];
  // bits 20:31 not used
</pre>
</pre>


== register 7 0x8001001c ==
GDM:
<pre>
<pre>
31..0 - GDM_link_data_processing:o_status_vector
wire [7:0]      xxx_src_bits =
                    {
                    sfp_rx_data[1],
                    sfp_rx_data[0],
                    tsm_pulser & tsm_pulser_enable,
                    trg_pulser & trg_pulser_enable,
                    lemo_in_sync[4],
                    lemo_in_sync[3],
                    lemo_in_sync[2],
                    lemo_in_sync[1]
                    };
</pre>
</pre>


CDM:
<pre>
<pre>
31..0 - CDM_link_data_processing:o_error_count
trg_src_mask and tsm_src_mask bits:
</pre>
0 - LEMO IN 1
1 - LEMO IN 2
2 - LEMO IN 3
3 - LEMO IN 4
4 - trg_pulser
5 - tsm_pulser
6 - sfp_rx_data[0] // to become sfp_trg_in, selected from sfp_rx_data[0], cdm_rx trg_out and gdm trigger packet
7 - sfp_rx_data[1] // to become sfp_tsm_in, selected from sfp_rx_data[1], cdm_rx tsm_out and gdm tsm packet
</pre>


== register 246 0x800103d8 ==
=== Register 10 0x80013028 status register ===


VX_RX
<pre>
bit | version    | fpga name      | description
  0 | 0x20231013 | pll_locked      | clock chip PLL is locked
  1 | 0x20240118 | ts_reset_armed  | timestamp reset is armed
  2 | 0x20240118 | qsfp_tx_link_rx_status | QSFP link status is good for all enabled ports
  3 | 0x20240424 | vx_tx_link_rx_status  | VX link status is good for all enabled ports
  4 | 0x20240118 | cdm_bsy        | VX busy grand-or
  5 | 0x20240118 | gdm_bsy        | QSFP busy grand-or
  6 | 0x20240118 | gdm_veto        | gdm_veto = gdm_busy
  7 | 0x20240118 | cdm_veto        | CDM veto from GDM to VX
  8 | 0x20240725 | bor_started    | begin-of-run sequence started
  9 | 0x20240725 | bor_finished    | begin-of-run sequence fininished, see commands 10 and 11
10 |        |                |
11 |        |                |
12 |        |                |
13 |        |                |
14 |        |                |
15 |        |                |
16 |        |                |
17 |        |                |
18 |        |                |
19 |        |                |
20 |        |                |
21 |        |                |
22 |        |                |
23 |        |                |
24 |        |                |
25 |        |                |
26 |        |                |
27 |        |                |
28 |        |                |
29 |        |                |
30 |        |                |
31 |        |                |
</pre>


== register 247 0x800103dc ==
=== Register 11 0x8001302C trg_counter ===


VX_RX, LEMO_IN, FP_LED, LEMO_OUT, VX_TX
trigger counter


== control register 255 0x800103fc ==
=== Register 12 0x80013030 tsm_counter ===


<pre>
time slice marker counter
31..28 | ALL | function mux, 4 bits: 0 - outputs driven by control register, 1 - dsvslice GDM production, 2 - dsvslice CDM production, 3, 4, 5 - LVDS loopback, see source code
27 | ALL | lemo_in(4) invert
26 | ALL | lemo_in(3) invert
25 | ALL | lemo_in(2) invert
24 | ALL | lemo_in(1) invert
23 | ALL | lemo_in(4) enable
22 | ALL | lemo_in(3) enable
21 | ALL | lemo_in(2) enable
20 | ALL | lemo_in(1) enable
19 | ALL | software_trigger
18 | ALL | lemo_trigger_enable
17 | ALL | pulser_trigger_enable
16 | ALL | trigger_enable
15 | ALL | gdm_trigger_enable
14
13 | ALL | drive ext_out(2) LEMO output
12 | ALL | drive ext_out(1) LEMO output
11 | ALL | fp_led_out(3) front panel LEDs
10 | ALL | fp_led_out(2)
9 | ALL | fp_led_out(1)
8 | ALL | fp_led_out(0)
7 | ALL | not used
6 | ALL | vx2_tx_out(2)
5 | ALL | vx2_tx_out(1)
4 | ALL | vx2_tx_out(0)
3 | ALL | not used
2 | ALL | vx1_tx_out(2)
1 | ALL | vx1_tx_out(1)
0 | ALL | vx1_tx_out(0)
</pre>


== Power up sequence ==
=== Register 13 0x80013034 GPS 1pps period ===


* on the CDM:
GPS 1pps period in 8 ns clocks
<pre>
busybox devmem 0x80010010 32 0x8
sleep 1;
busybox devmem 0x80010010 32 0x0
#/home/dsdaq/si5394-i2c-file /home/dsdaq/CDM_v2.0_IN1_fixed_and_IN2_RX_Recovered_Si5394-RevA-Registers.txt  0 0x6b
/home/dsdaq/si5394-i2c-file /home/dsdaq/CDM_v3.0_IN1_fixed_and_IN2_RX_Recovered_VX_62.5MHz_Si5394-RevA-Registers.txt 0 0x6b
busybox devmem 0x80010004 32 0x1;  # link startup mode reset until phase-aligned
busybox devmem 0x80010000 32 0x5;  # reset link and link status registers
sleep 1;  # just holds reset high
busybox devmem 0x80010000 32 0x0; # lower reset and let links lock
sleep 2;  # give links time to lock
busybox devmem 0x80010008 32;  # read status 0x00000003 means locked and phase aligned
busybox devmem 0x8001000c 32  # read data, 0x1B1C 3CBC lower 16 bits are K-Codes K.28.1 (3C) and K.28.5 (BC) when locked and phase aligned
</pre>


= Build firmware =
=== Register 14 0x80013038 Rb clock 1pps period ===


== Build from git clone ==
PRS-10 Rb clock 1pps output period in 8 ns clocks


THESE ARE K.O.'s NOTES FOR CREATING THE PETALINUX DIRECTORY.
=== Register 15 0x8001303C SFP RX status ===


THEY DO NOT WORK!
<pre>
bit | ds20k version | fpga signal name | description
  0 | ALL        | sfp_rx_data[15:0]  | cdm sfp received data
16 | same      | sfp_rx_data_is_k[0] |
17 | same      | sfp_rx_data_is_k[1] |
18 |            | 0                  |
19 | 0x20231204 | sfp_rx_sel_lpb      | sfp tx->rx loopback
20 | 0x20231013 | sfp_link_status    | sfp link connected, exchanging data
21 | same      | sfp_link_rx_status  | sfp link receiving correct idle pattern from GDM TX
22 | same      | sfp_link_error      | sfp link receiver error (badk or overflow)
23 | same      | sfp_rx_data_error  | sfp transceiver state machine is in error state
24 |            |                    |
25 |            |                    |
26 |            |                    |
27 |            |                    |
28 |            |                    |
29 |            |                    |
30 |            |                    |
31 |            |                    |
</pre>


COPY PETALINUX FROM A WORKING PROJECT AND USE "make gdm" and "make cdm" AS DESCRIBED BELOW.
=== Register 16 SFP TX control ===


* git clone git@edev-group.triumf.ca:fw/exp/darkside/gcdm.git
<pre>
* #Makefile change VIVADO_SETTINGS_SCRIPT := /opt/Xilinx/Vivado/2022.1/settings64.sh
  wire [15:0] sfp_tx_data_reg = register_data_in[16][15:0];
* #. /opt/Xilinx/Vivado/2022.1/settings64.sh
  wire [1:0]  sfp_tx_ctrl_reg = register_data_in[16][17:16];
* . /opt/Xilinx/Vivado/2020.2/settings64.sh
  // 18
* make clean
  // 19
* make all_from_scratch
  // 20:23
* . /opt/Xilinx/PetaLinux/2020.2/tool/settings.sh
  wire qsfp_tx_enable_trg    = register_data_in[23][24]; // enable QSFP TX trg_in_pulse k-code
* make petalinux_create
  wire qsfp_tx_enable_tsm    = register_data_in[23][25]; // enable QSFP TX tsm_in_pulse k-code
* make petalinux_rebuild_new_hw_des
  // 26
* bomb out: The TMPDIR: /home/olchansk/git/ds-dm-gcdm/PetaLinux_GDM_CDM/build/tmp can't be located on nfs.
  // 27
* mkdir /tmp/build_tmp
  //wire sfp_rx_sel_loopback    = register_data_in[16][28]; // TX->RX serial loopback
* rm -rf /home/olchansk/git/ds-dm-gcdm/PetaLinux_GDM_CDM/build/tmp/
  wire sfp_tx_sel_loopback    = register_data_in[16][29]; // RX->TX serial loopback
* ln -s /tmp/build_tmp /home/olchansk/git/ds-dm-gcdm/PetaLinux_GDM_CDM/build/tmp
  wire sfp_tx_sel_trg        = register_data_in[16][30]; // 16 individual bits
* try again
  wire sfp_tx_sel_reg        = register_data_in[16][31]; // from register
* grinds, loads a whole bunch of packages...
</pre>
* finishes with desire to copy things to /tftpboot
 
* make sdcard_cp_to wants to copy files from PetaLinux_GDM_CDM/images/linux/ to SD card
=== Register 17-22 QSFP RX data ===


== Build firmware ==
QSFP RX data links 0..11


NOTE: directory Petalinux_GDM_CDM should already exist!
=== Register 23 QSFP TX control ===


<pre>
<pre>
. /opt/Xilinx/Vivado/2020.2/settings64.sh
  wire [15:0] qsfp_tx_data_reg = register_data_in[23][15:0];
. /opt/Xilinx/PetaLinux/2020.2/tool/settings.sh
  wire [1:0]  qsfp_tx_ctrl_reg = register_data_in[23][17:16];
make clean_gdm  # remove gdm build tree
  wire qsfp_rx_sel_lpb        = register_data_in[23][28]; // TX->RX loopback
make gdm        # build or rebuild GDM
  wire qsfp_tx_sel_lpb        = register_data_in[23][29]; // RX->TX loopback
make copy_gdm   # copy to gdm0
  wire qsfp_tx_sel_trg        = register_data_in[23][30]; // 16 individual bits
make clean_cdm  # remove cdm build tree
   wire qsfp_tx_sel_reg         = register_data_in[23][31]; // data from register
make cdm         # build or rebuild CDM
make copy_cdm    # copy to cdm0 and cdm1
</pre>
</pre>


copy to SD card:
=== Register 24 0x80013060 trigger pulser period ===
 
trigger pulser period in units of 8 ns (125 MHz clock)
 
=== Register 25 0x80013064 trigger burst pulser ===
 
<pre>
<pre>
open a root shell
  wire [7:0]        conf_burst_count  = conf_pulser_burst_ctrl[31:24];
format 16 GB Sd card per above
  wire [23:0]        conf_burst_period = conf_pulser_burst_ctrl[23:0];
cd .../ds-dm-gcdm
make copy
</pre>
</pre>


= build times =
=== Register 26 0x80013068 tsm pulser period ===
 
time slice marker period in units of 8 ns (125 MHz clock)
 
=== Register 27 0x8001306C data write fifo ===
 
<pre>
  wire        fifo_reset = register_data_in[27][31];
  wire        fifo_to_fpga_wr1 = register_data_in[27][27];
  wire        fifo_to_fpga_wr2 = register_data_in[27][26];
  wire [16:0] fifo_to_fpga_din = register_data_in[27][16:0];
</pre>


<pre>
<pre>
CDM 12-june-2023 69aabc1c25130d970bc375aca684bd68849e6685
  assign register_data_out[27][31:24] = register_data_in[27][31:24]; // echo write bits
daq13 AMD-5700G 1688.61user 399.33system 23:28.84elapsed 148%CPU
  assign register_data_out[27][23] = fifo_to_fpga_full;
dsdaqgw AMD-7700 1090.55user 247.34system 16:03.55elapsed 138%CPU
  assign register_data_out[27][22] = fifo_to_fpga_empty;
dsdaqgw AMD-7700 CDM incremental 196.68user 67.62system 7:35.42elapsed 58%CPU
dsdaqgw AMD-7700 CDM incremental 684.72user 94.17system 7:30.17elapsed 173%CPU
dsdaqgw AMD-7700 GDM incremental 849.84user 99.79system 9:04.56elapsed 174%CPU
</pre>
</pre>


= prepare bootable sd card =
=== Register 28 0x80013070 data read fifo ===


== format the sd card ==
<pre>
  wire        fifo_reset = register_data_in[28][31];
  wire        fifo_from_fpga_rd1 = register_data_in[28][25];
  wire        fifo_from_fpga_rd2 = register_data_in[28][24];
</pre>


this only needs to be done once
<pre>
  assign register_data_out[28][31:24] = register_data_in[28][31:24]; // echo write bits
  assign register_data_out[28][21] = fifo_from_fpga_full;
  assign register_data_out[28][20] = fifo_from_fpga_empty;
  assign register_data_out[28][16:0] = fifo_from_fpga_dout;
</pre>


* become root
=== Register 29 0x80013074 packet routing ===
* cd ~olchansk/git/ds-dm-gcdm
* use "lsblk" to identify the SD card (should show as 8/16/32 GB block device)/ /dev/sdd in this case
* make sdcard_format SDCARD_DEVICE=/dev/sdd
* disconnect sd card, reconnect the sd card (to detect new partition tables, etc)


== copy CDM boot files ==
Control packet routing and loopbacks:


<pre>
<pre>
cd /home/dsdmdev/git/ds-dm-gcdm
  wire [3:0]  dn_route_ctrl            = register_data_in[29][3:0];
make copy
  wire [3:0]  up_route_ctrl            = register_data_in[29][7:4];
  wire [3:0]  fifo_to_fpga_route_ctrl  = register_data_in[29][11:8];
  //wire [3:0]  spare_route_ctrl        = register_data_in[29][15:12];
 
  wire        dn_mux_trg_enable        = register_data_in[29][16];
  wire        dn_mux_tsm_enable        = register_data_in[29][17];
  wire        dn_mux_sfp_rx_fifo_enable = register_data_in[29][18];
  // 19
  // 20..23
 
  wire        up_mux_vx_rx_enable      = register_data_in[29][24];
  // 25
  // 26
  // 27
  wire        fifo_from_fpga_hitmap_enable      = register_data_in[29][28];
  // 29..31
</pre>
</pre>


== copy boot files to the sd card ==
fifo_to_fpga output routing:
* 0 - to down packet mux
* 1 - to up packet mux
* 2 - to fifo_from_fpga mux
* 3 - not used
 
down packet mux inputs:
* fifo_to_fpga_0
* trg_pkt16 enabled by dn_mux_trg_enable
* tsm_pkt16 enabled by dn_mux_tsm_enable
* sfp_rx_fifo_pkt16 enabled by dn_mux_sfp_rx_fifo_enable
* up_pkt16_2 loopback from up packet mux
 
down packet mux output routing:
* 0 - to vx_tx_pkt16 to VX TX (vx_link_tx and vx_ser_tx)
* 1 - to fifo_from_fpga mux
* 2 - to up packet mux loopback
* 3 - to qsfp_tx_pkt16 to GDM QSFP TX (cdm_link_tx)
 
up packet mux inputs:
* vx_rx_pkt16 enabled by up_mux_vx_rx_enable data from 12 VX RX links
* fifo_to_fpga_1
* dn_pkt16_2 loopback from down packet mux
 
up packet mux output routing:
* 0 - to sfp_tx_pkt16 to CDM SFP TX (VX data to GDM)
* 1 - to fifo_from_fpga mux
* 2 - to down packet mux loop loopback
* 3 - not used
 
fifo_from_fpga mux inputs:
* fifo_to_fpga_2
* dn_pkt16_1 from down packet mux
* up_pkt16_1 from up packet mux
* qsfp_tx_pkt16 from GDM QSFP link 0 (there is no GDM QSFP 12-to-1 mux)
* hitmap_pkt16 enabled by fifo_from_fpga_hitmap_enable in register 29
 
=== Register 30 0x80013078 qsfp link status ports 0..7 ===
 
<pre>
assign register_data_out[30] =
    {
      qsfp_rx_data_error[7], qsfp_link_error[7], qsfp_link_status[7], qsfp_link_rx_status[7], // 7
      qsfp_rx_data_error[6], qsfp_link_error[6], qsfp_link_status[6], qsfp_link_rx_status[6], // 6
      qsfp_rx_data_error[5], qsfp_link_error[5], qsfp_link_status[5], qsfp_link_rx_status[5], // 5
      qsfp_rx_data_error[4], qsfp_link_error[4], qsfp_link_status[4], qsfp_link_rx_status[4], // 4
      qsfp_rx_data_error[3], qsfp_link_error[3], qsfp_link_status[3], qsfp_link_rx_status[3], // 3
      qsfp_rx_data_error[2], qsfp_link_error[2], qsfp_link_status[2], qsfp_link_rx_status[2], // 2
      qsfp_rx_data_error[1], qsfp_link_error[1], qsfp_link_status[1], qsfp_link_rx_status[1], // 1
      qsfp_rx_data_error[0], qsfp_link_error[0], qsfp_link_status[0], qsfp_link_rx_status[0]  // 0
      };
</pre>
 
=== Register 31 0x8001307C qsfp link status ports 8..11 ===


* as root: identify partition labels, run "blkid", should say "BOOT", "rootfs" and "data"
* mount
<pre>
<pre>
mkdir /media/olchansk/BOOT
assign register_data_out[31] =
mkdir /media/olchansk/rootfs
    {
mkdir /media/olchansk/data
      4'b0000,
mount -L BOOT /media/olchansk/BOOT
      4'b0000,
mount -L rootfs /media/olchansk/rootfs
      4'b0000,
mount -L data /media/olchansk/data
      4'b0000,
cp PetaLinux_GDM_CDM/images/linux/BOOT.BIN /media/olchansk/BOOT/
      qsfp_rx_data_error[11], qsfp_link_error[11], qsfp_link_status[11], qsfp_link_rx_status[11], // 11
cp PetaLinux_GDM_CDM/images/linux/boot.scr /media/olchansk/BOOT/
      qsfp_rx_data_error[10], qsfp_link_error[10], qsfp_link_status[10], qsfp_link_rx_status[10], // 10
cp PetaLinux_GDM_CDM/images/linux/image.ub /media/olchansk/BOOT/
      qsfp_rx_data_error[9],  qsfp_link_error[9],  qsfp_link_status[9],  qsfp_link_rx_status[9],  // 9
umount /media/olchansk/BOOT
      qsfp_rx_data_error[8],  qsfp_link_error[8],  qsfp_link_status[8],  qsfp_link_rx_status[8]  // 8
umount /media/olchansk/rootfs
      };
umount /media/olchansk/data
eject /dev/sdd
</pre>
</pre>


= boot messages =
=== Register 32 0x80013080 bitmap of enabled qsfp ports ===


<pre>
<pre>
Xilinx Zynq MP First Stage Boot Loader
  wire [11:0] qsfp_mask      = register_data_in[32][11:0];
Release 2020.2  Sep 24 2022 -  13:29:15
  wire        qsfp_bsy_force = register_data_in[32][12];
NOTICE: ATF running on XCZU4CG/silicon v4/RTL5.1 at 0xfffea000
  // not used                  = register_data_in[32][15:13];
NOTICEBL31: v2.2(release):xlnx_rebase_v2.2_2020.3
  wire [15:0] gdm_veto_extend = register_data_in[32][31:16];
NOTICE:  BL31: Built : 18:02:46, Sep 28 2022
</pre>


On the GDM:


U-Boot 2020.01 (Sep 28 2022 - 18:03:39 +0000)
qsfp_rx_bsy[11..0] are pulses received from the CDMs


Model: DarkSide 20k DM
qsfp_rx_bsy_or is the grand-or of qsfp_rx_bsy masked by qsfp_mask
Board: Xilinx ZynqMP
DRAM:  2 GiB
usb dr_mode not found
PMUFW:  v1.1
EL Level:      EL2
Chip ID:        zu4
NAND:  0 MiB
MMC:  mmc@ff160000: 0, mmc@ff170000: 1
In:    serial@ff000000
Out:  serial@ff000000
Err:  serial@ff000000
Bootmode: SD_MODE1
Reset reason:  SOFT
Net: 
ZYNQ GEM: ff0b0000, mdio bus ff0b0000, phyaddr -1, interface rgmii-id


Warning: ethernet@ff0b0000 (eth0) using random MAC address - d6:62:5f:13:00:44
if qsfp_rx_bsy_or is high, gdm_bsy goes up and stays up for vx_bsy_extend*2 clocks
eth0: ethernet@ff0b0000
ZYNQ GEM: ff0e0000, mdio bus ff0e0000, phyaddr -1, interface rgmii-id
Could not get PHY for eth1: addr -1


Hit any key to stop autoboot:  0
gdm_veto = gdm_bsy (bsy of any one VX causes trigger veto to all of them)
ZynqMP>
CTRL-A Z for help | 115200 8N1 | NOR | Minicom 2.7.1 | VT102 | Online 122:2 | ttyACM0                                     
</pre>


= Software =
gdm_veto transition 0->1 causes gdm_veto_pulse. as long as gdm_veto is high, gdm_veto_pulse is generated every gdm_veto_extend clocks


* ssh cdm0 # or gdm0
gdm_veto_pulse is sent to all CDMs.
* sudo apt install i2c-tools libi2c-dev
* git clone https://bitbucket.org/team-ds-dm/ds-dm-software
* cd ds-dm-software
* make


== test_cdm.exe ==
For this to work right, cdm_bsy_extend should not be bigger than gdm_veto_extend.


=== CDM SFP status ===
=== Register 33 0x80013084 bitmap of enabled VX ports ===


<pre>
<pre>
# /home/dsdaq/online/ds-dm-software/test_cdm.exe --sfp
  wire [11:0]  vx_mask      = register_data_in[33][11:0];
DS-DM mapping /dev/mem at 0x80010000
  wire        vx_bsy_force = register_data_in[33][12];
DS-DM FPGA firmware revision 0xbb2f0ae7
  // not used                = register_data_in[33][15:13];
CDM firmware 0xbb2f0ae7
  wire [15:0] vx_bsy_extend = register_data_in[33][31:16];
arg 1: [--sfp]
</pre>
Polling SFP status...
 
identifier 0x03
On the CDM:
connector 0x07
 
encoding  0x01
cdm_bsy is a grand-or of all vx_bsy masked by vx_mask (list of active VXes).
wavelength 0x0352 (850 nm)
 
vendor_name [FINISAR CORP.  ]
vx_bsy_extend controls how often state of cdm_bsy is sent to the GDM. when cdm_bsy goes 0->1, we send a cdm_bsy_pulse and keep resending it every vx_bsy_extend clocks as long as cdm_bsy stays high.
vendor_pn  [FTLF8526P3BNL  ]
 
vendor_rev  []
cdm_bsy_pulse is sent to the GDM.
vendor_sn  [N3AB9M8        ]
 
vendor_date [200319 ]
sfp_rx_veto is the received from the GDM
dm_type    0x68
 
temp 29.0 C
if sfp_rx_veto goes up, cdm_veto goes up and stays up for gdm_veto_extend clocks.
vcc  3.323 V
 
tx_bias  7.250 mA
for this to work right, CDM gdm_veto_extend must be bigger than GDM gdm_veto_extend.
tx_power 478.4 uW
 
rx_power 2.3 uW
cdm_veto goes to VXes on v1_tx_out[1] which is LVDS input 13.
SFP good 1, status: temp 30.6 C, tx_bias 7.4 mA, tx_power 476 uW, rx_power 818 uW
 
...
=== Register 34, 35 0x80013088, 8C current timestamp ===
</pre>
 
current 64-bit timestamp, 125 MHz


=== GDM QSFP status ===
=== Register 36, 37 0x80013090, 94 old timestamp ===


<pre>
old 64-bit timestamp, 125 MHz. timestamp saved at run start when it is reset to 0.
root@gdm0:~# /home/dsdaq/online/ds-dm-software/test_cdm.exe --qsfp3 --qsfp
 
DS-DM mapping /dev/mem at 0x80010000
=== Register 38, 39, 40 0x80013098, 9C, A0 VX busy counters ===
DS-DM FPGA firmware revision 0x53aee418
 
CDM firmware 0x53aee418
8 bits per VX port, counters overflow to 255, reset at run start.
arg 1: [--qsfp3]
 
gpiochip0: GPIOs 338-511, parent: platform/ff0a0000.gpio, zynqmp_gpio:
=== Register 41, 42, 43 0x800130A4, A8, AC QSFP busy counters ===
gpio-378 (                    |sysfs              ) out hi
 
gpio-379 (                    |sysfs              ) out hi
8 bits per QSFP port, counters overflow to 255, reset at run start.
gpio-381 (                    |sysfs              ) out lo
 
gpio-382 (                    |sysfs              ) out hi
=== Register 44, 45, 46, 47, 48 0x800130B0, B4, B8, BC, C0 CDM and GDM busy and veto counters ===
arg 2: [--qsfp]
Polling QSFP status...
identifier 0x0d
status    0x02
los        0x8f
temp      28.2 C
vcc        3.323 V
rx_power    0.1  0.1  0.1  0.1 uW
tx_bias      7.6  7.6  7.6  0.0 mA
tx_power  792.2 773.8 823.0  0.1 uW
vendor_name [FINISAR CORP    ]
vendor_pn  [FTL410QD4C      ]
vendor_rev  [A ]
wavelength  850
max_temp    70 C
vendor_sn  [X79AC0R        ]
vendor_date [220309  ]
QSFP good 1, status: temp 27.7 C, los 0x8b, tx_bias 7.5 7.6 7.6 0.0 mA, tx_power 792 772 821  0 uW, rx_power  0  0 466  0 uW
</pre>


=== GDM clock status ===
* cdm_busy = grand-or of all VX busy for enabled VXes
* gdm_busy = grand-or of all CDM busy for enabled CDMs
* gdm_veto = gdm_busy


<pre>
<pre>
/home/dsdaq/online/ds-dm-software/test_cdm.exe --cc
44 | lo 16 bits | cdm_bsy_up_counter      | CDM busy, increments when cdm_busy goes 0->1
/home/dsdaq/online/ds-dm-software/test_cdm.exe --gdm-clocks
44 | hi 16 bits | cdm_bsy_pulse_counter  | CDM busy to GDM, increments for each cdm_bsy_pulse sent to the GDM
</pre>
 
45 | lo 16 bits | cdm_veto_pulse_counter  | CDM veto from GDM, increments for each sfp_rx_veto received from the GDM
45 | hi 16 bits | cdm_veto_up_counter    | CDM veto to VX, increments each time cdm_veto is set to 1.


* clock chip not loaded, not running:
46 | lo 16 bits | gdm_bsy_pulse_counter  | GDM busy from CDM, increments for each qsfp_rx_busy received from CDMs (unless they overlap)
46 | hi 16 bits | gdm_bsy_up_counter      | GDM busy, increments each time gdm_bsy goes 0->1


<pre>
47 | lo 16 bits | gdm_bsy_refresh_counter | GDM busy, increments each time gdm_bsy is extended by new qsfp_rx_busy
root@gdm0:~# /home/dsdaq/online/ds-dm-software/test_cdm.exe --cc
  47 | hi 16 bits | spare                  |
DS-DM mapping /dev/mem at 0x80010000
DS-DM FPGA firmware revision 0x6d2ebce6
CDM firmware 0x6d2ebce6
Polling CC status...
Clock chip registers: 0x06 0x00 0x94 0x53 0x00 0x00 0x0f 0x16 0x04 0x00 0x01 0x68 0x09 0x00 0x02 0xf2 0x00 0x1f 0xf0 0x22 0xf2, 0x507: 0x00, 0x52A: 0x00, 0x53F: 0x04
Clock chip state 0, status: SYSINCAL XAXB_ERR LOL CAL_PLL IN0 IN_SEL_0 FASTLOCK_STATUS


root@gdm0:~# /home/dsdaq/online/ds-dm-software/test_cdm.exe --gdm-clocks
48 | lo 16 bits | gdm_veto_up_counter    | GDM veto, increments each time gdm_veto goes 0->1
DS-DM mapping /dev/mem at 0x80010000
48 | hi 16 bits | gdm_veto_pulse_counter  | GDM veto to CDM, increments for each gdm_veto_pulse sent to the CDM
DS-DM FPGA firmware revision 0x6d2ebce6
CDM firmware 0x6d2ebce6
GDM clock frequency counters:
0x1030 mgt_rx_ref_clk_raw: 0x1f7caf52 (528265042) should be ~125 MHz
0x1034 rx_clk:            0x00000000 (0) should be ~125 MHz
0x1038 mgt_tx_ref_clk_raw: 0x1f7caf52 (528265042) should be ~125 MHz
0x103C tx_clk:            0x00000000 (0) should be ~125 MHz
0x1040 clk_50MHz:          0x02faf080 (50000000) should be 50 MHz exactly
0x1044 Block1_clk:        0x05f5e100 (100000000) should be 100 MHz exactly
</pre>
</pre>


* clock chip good (IN0 - external 10 MHz clock)
=== Register 49, 50, 51 0x800130xx VX RX serial data monitor ===
 
VX RX data, 8-bit per VX channel. k-bit is omitted.


<pre>
<pre>
root@gdm0:~# /home/dsdaq/online/ds-dm-software/test_cdm.exe --cc
  assign register_data_out[49][7:0]  = vx_rx_data[0]; // vx1
DS-DM mapping /dev/mem at 0x80010000
  assign register_data_out[49][15:8]  = vx_rx_data[1]; // vx2
DS-DM FPGA firmware revision 0x6d2ebce6
  assign register_data_out[49][23:16] = vx_rx_data[2]; // vx3
CDM firmware 0x6d2ebce6
  assign register_data_out[49][31:24] = vx_rx_data[3]; // vx4
Polling CC status...
 
Clock chip registers: 0x06 0x00 0x94 0x53 0x00 0x00 0x00 0x00 0x00 0x00 0x01 0x68 0x00 0x44 0x00 0xd0 0x01 0x1f 0xff 0x22 0xf2, 0x507: 0x3f, 0x52A: 0x01, 0x53F: 0x00
  assign register_data_out[50][7:0]  = vx_rx_data[4]; // vx5
Clock chip state 1, status:  LOS_IN2 OOF_IN2 IN0 IN_SEL_REGCTRL IN_SEL_0
  assign register_data_out[50][15:8]  = vx_rx_data[5]; // vx6
  assign register_data_out[50][23:16] = vx_rx_data[6]; // vx7
  assign register_data_out[50][31:24] = vx_rx_data[7]; // vx8
 
  assign register_data_out[51][7:0]  = vx_rx_data[8]; // vx9
  assign register_data_out[51][15:8]  = vx_rx_data[9]; // vx10
  assign register_data_out[51][23:16] = vx_rx_data[10]; // vx11
  assign register_data_out[51][31:24] = vx_rx_data[11]; // vx12
</pre>
 
=== Register 52, 53 VX link status ===


root@gdm0:~# /home/dsdaq/online/ds-dm-software/test_cdm.exe --gdm-clocks
<pre>
DS-DM mapping /dev/mem at 0x80010000
  assign register_data_out[52] =
DS-DM FPGA firmware revision 0x6d2ebce6
    {
CDM firmware 0x6d2ebce6
      vx_rx_error[7], vx_link_error[7], vx_link_status[7], vx_link_rx_status[7], // 7
GDM clock frequency counters:
      vx_rx_error[6], vx_link_error[6], vx_link_status[6], vx_link_rx_status[6], // 6
0x1030 mgt_rx_ref_clk_raw: 0x07735a3b (125000251) should be ~125 MHz
      vx_rx_error[5], vx_link_error[5], vx_link_status[5], vx_link_rx_status[5], // 5
0x1034 rx_clk:            0x07735a3c (125000252) should be ~125 MHz
      vx_rx_error[4], vx_link_error[4], vx_link_status[4], vx_link_rx_status[4], // 4
0x1038 mgt_tx_ref_clk_raw: 0x07735a3b (125000251) should be ~125 MHz
      vx_rx_error[3], vx_link_error[3], vx_link_status[3], vx_link_rx_status[3], // 3
0x103C tx_clk:            0x07735a3c (125000252) should be ~125 MHz
      vx_rx_error[2], vx_link_error[2], vx_link_status[2], vx_link_rx_status[2], // 2
0x1040 clk_50MHz:          0x02faf080 (50000000) should be 50 MHz exactly
      vx_rx_error[1], vx_link_error[1], vx_link_status[1], vx_link_rx_status[1], // 1
0x1044 Block1_clk:        0x05f5e100 (100000000) should be 100 MHz exactly
      vx_rx_error[0], vx_link_error[0], vx_link_status[0], vx_link_rx_status[0]  // 0
      };
 
  assign register_data_out[53] =
    {
      //4'b0000,
      1'b0, ~vx_rx_deser_rdy[0], vx_rx_code_err[0], vx_rx_disp_err[0],
      //4'b0000,
      //4'b0000,
      //4'b0000,
      vx_rx_monitor[0],
      vx_rx_error[11], vx_link_error[11], vx_link_status[11], vx_link_rx_status[11], // 11
      vx_rx_error[10], vx_link_error[10], vx_link_status[10], vx_link_rx_status[10], // 10
      vx_rx_error[9],  vx_link_error[9],  vx_link_status[9],  vx_link_rx_status[9],  //  9
      vx_rx_error[8],  vx_link_error[8],  vx_link_status[8],  vx_link_rx_status[8]  //  8
      };
</pre>
</pre>


=== CDM clock status ===
vx_rx_monitor (12-bit) is from deserializer_10b.sv:


<pre>
<pre>
/home/dsdaq/online/ds-dm-software/test_cdm.exe --cc
  assign monitor_out[9:0] = lastByte[9:0];
/home/dsdaq/online/ds-dm-software/test_cdm.exe --cdm-clocks
  assign monitor_out[10]  = comma;
  assign monitor_out[11]  = ready;
</pre>
</pre>


* clock chip not loaded, not running:
=== Register 54 VX TX serial data monitor ===


* contents of vx_tx_monitor from vx_ser_tx.sv:
<pre>
<pre>
root@cdm1:~# /home/dsdaq/online/ds-dm-software/test_cdm.exe --cc
  assign monitor_out[8:0]  = data_to_encoder; // 8-bit + k
DS-DM mapping /dev/mem at 0x80010000
  assign monitor_out[9]    = valid;
DS-DM FPGA firmware revision 0x6d2ebec9
  assign monitor_out[15:10] = 0;
CDM firmware 0x6d2ebec9
  assign monitor_out[25:16] = encoded_data; // 10-bit
Polling CC status...
  assign monitor_out[26]    = encoded_valid;
Clock chip registers: 0x06 0x00 0x94 0x53 0x00 0x00 0x0f 0x16 0x04 0x00 0x01 0x68 0x19 0x00 0x02 0xf2 0x00 0x1f 0xf0 0x22 0xf2, 0x507: 0x00, 0x52A: 0x00, 0x53F: 0x04
  assign monitor_out[27]    = 0;
Clock chip state 0, status:  SYSINCAL XAXB_ERR LOL CAL_PLL IN0 IN_SEL_0 FASTLOCK_STATUS
  assign monitor_out[31:28] = 0;
 
root@cdm1:~# /home/dsdaq/online/ds-dm-software/test_cdm.exe --cdm-clocks
DS-DM mapping /dev/mem at 0x80010000
DS-DM FPGA firmware revision 0x6d2ebec9
CDM firmware 0x6d2ebec9
CDM clock frequency counters:
0x1030 mgt_rx_ref_clk_raw: 0x07735851 (124999761) should be ~125 MHz
0x1034 rx_clk:            0x00000000 (0) should be ~125 MHz
0x1038 mgt_tx_ref_clk_raw: 0x0127fefa (19398394) should be ~125 MHz
0x103C tx_clk:            0x00000000 (0) should be ~125 MHz
0x1040 clk_50MHz:          0x02faf080 (50000000) should be 50 MHz exactly
0x1044 Block1_clk:        0x05f5e100 (100000000) should be 100 MHz exactly
</pre>
</pre>


* clock chip uses internal clock (IN1 - internal oscillator), observe rx_clk frequency is not same as others
=== Register 55 QSFP, SFP, VX link loss counters ===


<pre>
<pre>
root@cdm1:~# /home/dsdaq/online/ds-dm-software/test_cdm.exe --cc
assign register_data_out[55] = {
DS-DM mapping /dev/mem at 0x80010000
  vx_rx_error_counter,
DS-DM FPGA firmware revision 0x6d2ebec9
  qsfp_link_rx_status_drop_counter,
CDM firmware 0x6d2ebec9
  sfp_link_rx_status_drop_counter,
Polling CC status...
  vx_link_rx_status_drop_counter
Clock chip registers: 0x06 0x00 0x94 0x53 0x00 0x00 0x00 0x00 0x00 0x00 0x01 0x68 0x00 0x00 0x00 0xd0 0x01 0x1f 0xfe 0x22 0xf2, 0x507: 0x7f, 0x52A: 0x02, 0x53F: 0x02
};
Clock chip state 1, status:  IN1 IN_SEL_1 HOLD_HIST_VALID
</pre>
 
<pre>
24..31 - CDM VX RX error counters, count any errors in the VX RX data path (bad serial data, fifo overflow, etc)
16..23 - GDM QSFP link loss counter, increments on qsfp_tx_link_rx_status 1->0 (reg10)
8..15 - CDM SFP  link loss counter, increments on sfp_link_rx_status    1->0 (reg15)
0...7 - CDM VX  link loss counter, increments on vx_tx_link_rx_status  1->0 (reg10)
</pre>
 
=== Register 68 GPS control and status ===


root@cdm1:~# /home/dsdaq/online/ds-dm-software/test_cdm.exe --cdm-clocks
<pre>
DS-DM mapping /dev/mem at 0x80010000
assign register_data_out[68] =
DS-DM FPGA firmware revision 0x6d2ebec9
    {
CDM firmware 0x6d2ebec9
      8'b00000000,      // 23+8
CDM clock frequency counters:
      rb_1pps_counter,  // 16+8 bits
0x1030 mgt_rx_ref_clk_raw: 0x07735853 (124999763) should be ~125 MHz
      gps_1pps_counter, // 8+8 bits
0x1034 rx_clk:            0x07735b0a (125000458) should be ~125 MHz
      1'b0,
0x1038 mgt_tx_ref_clk_raw: 0x07735853 (124999763) should be ~125 MHz
      1'b0,
0x103C tx_clk:            0x07735852 (124999762) should be ~125 MHz
      rb_ser_in,  // 5
0x1040 clk_50MHz:          0x02faf080 (50000000) should be 50 MHz exactly
      gps_data_in, // 4
0x1044 Block1_clk:        0x05f5e100 (100000000) should be 100 MHz exactly
      gps_aux_out, // 3
      gps_aux_in,  // 2
      rb_1pps_in,  // 1
      gps_1pps_in  // 0
      };
</pre>
</pre>


=== CDM link status, PRBS test mode ===
=== Register 71 packet error bits ===


<pre>
<pre>
# /home/dsdaq/online/ds-dm-software/test_cdm.exe --cdm-link
assign register_data_out[71] =
# /home/dsdaq/online/ds-dm-software/test_cdm.exe --link-test2
    {
      8'b00000000,  // 23+8 bits
      8'b00000000,  // 16+8 bits
      8'b00000000,  //  8+8 bits
      1'b0, // 7
      1'b0, // 6
      1'b0, // 5
      1'b0, // 4
      cdm_hitmap_encode_error_latch, // 3
      cdm_hitmap_pkt16_error_latch,  // 2
      vx_tx_tsm_pkt8_error_latch,    // 1
      vx_tx_trg_pkt8_error_latch    // 0
      };
</pre>
</pre>
* fiber disconnected, no link:
 
= Firmware registers branch develop_ko =
 
== Register map ==
 
<pre>
<pre>
CDM firmware:   0xbb2f0ae7
  0 | ALL | ALL | RO | USR_ACCESSE2 see https://docs.xilinx.com/r/en-US/ug974-vivado-ultrascale-libraries/USR_ACCESSE2
0x1000 SFP c.c. status: 0x00000031
   1 | ALL | ALL | RW | read write scratch register
    CLK_IN_SEL_LS   0x1
  2 | ALL | CDM | ?? | MGT not used
    CLK_EXT_SEL_LS  0
  3 | ALL | CDM | RO | MGT debug_data
    CLK_CLK_RSTn_LS 0
   4 | ALL | CDM | RW | clk_config_vec
    CLK_LOSXTn_LS   1
  5 | ALL | CDM | ?? | not used
    CLK_LOLn_LS    1
  6 | ALL | CDM | RO | CDM_link_data_processing:o_error_time
    CLK_INTn_LS    0
   7 | ALL | CDM | RO | CDM_link_data_processing:o_error_count
0x1008 SFP link reset:  0x00000000
0x1010 SFP link status: 0x00000025
    sfp_mod_absent_N      1
    sfp_rx_los_N          0
    link_power_good        1
    rx_link_up            0
    rx_receiving_data      0
    rx_error              1
    rx_lnk_up_and_running  0
    tx_link_up            0
    tx_sending_data        0
    tx_link_up_and_running 0
    link_up_and_running    0
0x1014 SFP link data:   0x466a8187
    rx_data    0x8187
    k28p1_k28p5 0
    rx_ctrl0    0x1
    rx_ctrl1    0x1
    rx_ctrl3    0x1
    tx_state    0x1
    rx_state    0x6
    rx_receiving_data 0
    rx_link_up        0
    rx_error          1
    rx_link_rst      0
0x2000 link test mode: 0x00000200, seconds: 0x00079093, errors: 0xffffffff
</pre>
</pre>
* fiber connected, good link:
 
== register 0 0x80010000 ==
 
GDM:
<pre>
0 - gdm_link_interface:i_mgt_rst
2 - gdm_link_interface:i_link_down_latched_rst
8 - GDM_link_data_processing:i_rst
10..9 - GDM_link_data_processing:i_data_mode
</pre>
 
CDM:
<pre>
<pre>
CDM firmware:   0xbb2f0ae7
0 - cdm_link_interface:i_mgt_rst
0x1000 SFP c.c. status: 0x000000b2
2 - cdm_link_interface:i_link_down_latched_rst
    CLK_IN_SEL_LS  0x2
8 - CDM_link_data_processing:i_rst
    CLK_EXT_SEL_LS  0
10..9 - CDM_link_data_processing:i_data_mode
    CLK_CLK_RSTn_LS 0
</pre>
    CLK_LOSXTn_LS  1
 
    CLK_LOLn_LS    1
== register 1 0x80010004 ==
    CLK_INTn_LS    0
 
0x1008 SFP link reset: 0x00000000
GDM:
0x1010 SFP link status: 0x000007dc
<pre>
    sfp_mod_absent_N      0
nlinks-1..0 - gdm_link_interface:i_rx_slide_trigger
    sfp_rx_los_N          0
    link_power_good        1
    rx_link_up            1
    rx_receiving_data      1
    rx_error              0
    rx_lnk_up_and_running  1
    tx_link_up            1
    tx_sending_data        1
    tx_link_up_and_running 1
    link_up_and_running    1
0x1014 SFP link data:   0x35c02774
    rx_data    0x2774
    k28p1_k28p5 0
    rx_ctrl0    0x0
    rx_ctrl1    0x0
    rx_ctrl3    0x0
    tx_state    0x3
    rx_state    0x5
    rx_receiving_data 1
    rx_link_up        1
    rx_error          0
    rx_link_rst      0
0x2000 link test mode: 0x00000200, seconds: 0x00078a8c, errors: 0x00000000
</pre>
</pre>


=== GDM link status, PRBS test mode ===
CDM:
 
<pre>
<pre>
1 link connected, no errors:
nlinks-1..0 - cdm_link_interface:i_rx_slide_trigger
# /home/dsdaq/online/ds-dm-software/test_cdm.exe --gdm-link
# /home/dsdaq/online/ds-dm-software/test_cdm.exe --link-test2
GDM firmware:    0x6b2ee010
0x1014: 0x00000008, 18: 0x00000008, 1C: 0x00000000, 24: 0x00000fff
0x2000: 0x00000200, time: 0x00078aa4, errors:
0xffffffff 0xffffffff 0xffffffff
0x00000000 0xffffffff 0xffffffff
0xffffffff 0xffffffff 0xffffffff
0xffffffff 0xffffffff 0xffffffff
</pre>
</pre>


= dsvslice integration =
== register 2 0x80010008 ==


== VX setup ==
GDM:
<pre>
nlinks-1..0 - gdm_link_interface:o_link_power_good
nlinks+15..16 - gdm_link_interface:o_link_status
</pre>


* general
CDM:
** Start acq from user code = y, all others = n (as of Mar 2023: will start when first trigger received)
<pre>
** Use NIM IO = y
nlinks-1..0 - cdm_link_interface:o_link_power_good
** Use external clock = y
nlinks+15..16 - cdm_link_interface:o_link_status
** LVDS quartet is input = n, y, n, y
</pre>
** LVDS quartet mode = User, User, User, User


* trigger from front panel NIM:
== register 3 0x8001000c ==
** Trigger on external signal = y, all others = n
** connect CDM EXT_OUT(2) to VX "TrigIn"


* trigger from LVDS "Sync" mode
GDM: simple loopback register
** Trigger on LVDS Sync signal = y, all others = n
** LVDS quartet mode = User, Sync, User, User


* trigger from LVDS "User" mode
CDM:
** Trigger on LVDS pair 12 signal = y, all others = n
<pre>
** LVDS quartet is input = n, y, n, y
31..0 - debug_data - cdm_link_interface:o_debug
** LVDS quartet mode = User, User, User, User
</pre>


== GDM setup ==
o_debug:
<pre>
rx_link_rst & rx_error & rx_link_up & rx_receiving_data &
std_logic_vector(rx_state_count) & tx_state_count_on_rx_clk & i_rx_ctrl3(0) &
i_rx_ctrl1(1 downto 0) & i_rx_ctrl0(1 downto 0) &
rx_data_is_k28p1_k28p5 &
i_rx_data;
</pre>


* GDM is gdm0
== register 4 0x80010010 ==
* set inputs to NIM mode
* set outputs to TTL mode (this GDM has wrong NIM output circuit)
* use top QSFP slot, connect split cable 1 into CDM01, cable 2 into CDM02
* connect non-inverted NIM trigger signal to top-LEMO-left EXT_IN_LV(1)
* connect non-inverted NIM TSM signal to top-LEME-right EXT_IN_LV(2)
* GDM LEDs: TRIG, TSM, trigger enabled, trigger_out
* GDM LEMO_OUT: trigger, trigger


== CDM setup ==
GDM write:
<pre>
0 - clk_config_vec(0) - CLK_IN_SEL_LS(0)
1 - clk_config_vec(1) - CLK_IN_SEL_LS(1)
2 - clk_config_vec(2) - CLK_EXT_SEL_LS
3 - clk_config_vec(3) - CLK_RSTn_LS
</pre>


* set CDM LEMO inputs to NIM
GDM read:
* set CDM LEMO outputs to NIM
<pre>
* CDM01 is cdm0
0 - clk_config_vec(0) - CLK_IN_SEL_LS(0)
* CDM02 is cdm1
1 - clk_config_vec(1) - CLK_IN_SEL_LS(1)
* connect GDM fiber links to SFP port
2 - clk_config_vec(2) - CLK_EXT_SEL_LS
* connect 1st VX port of CDM01 to VX1
3 - clk_config_vec(3) - CLK_RSTn_LS
* connect 1st VX port of CDM02 to VX2
4 - clk_config_vec(4) - CLK_LOSXTn_LS
* connect LEMO EXT_OUT(2) to VX "TrigIn", CDM01 to VX1, CDM02 to VX2
5 - clk_config_vec(5) - CLK_LOLn_LS
* power up
6 - clk_config_vec(6) - CLK_INTn_LS
* CDM LEDs: GDM TRIG, GDM TSM, trigger enabled, trigger out
7 - constant 1
* CDM LEMO_OUT: gdm_trg, trigger
31..8 - constant 0
</pre>


== After power up ==
== register 5 0x80010014 ==


* start the CDM frontend from the MIDAS "Programs" page. To start manually, see the Start Command on the Programs page.
not used
* CDM frontend should enable the VX clock, disable the trigger
* from the MIDAS status page, goto the CDM page
* in the CDM01, CDM02 data table, the 2nd number should read 0x35c08008, if it does not and the last 4 digits randomly change, reset the GDM links:
** in order GDM, CDM01, CDM02, press "reset1" of each board, then press "reset4", then press "reset0", 2nd number should read as above. if it does not, STOP HERE.
* start a run
* CDM frontend will enable the trigger
* GDM frontend will enable the trigger
* LEDs on the GDM should flash, LEDs on the CDM should flash, TrigIn and TrigOut of the VX should flash
* stop a run
* GDM frontend will disable the trigger
* CDM frontend will disable the trigger


== Phase measurement ==
== register 6 0x80010018 ==


* pip3 install matplotlib
GDM:
* pip3 install scipy
* export PYTHONPATH=$HOME/packages/midas/python
* #git clone https://github.com/J033X071C/PhaseMeasurement
* git clone https://bitbucket.org/team-ds-dm/phasemeasurement.git
* cd phasemeasurement
* python3 ./phaseMeasurement.py --help
<pre>
<pre>
daq00:PhaseMeasurement$ python3 ./phaseMeasurement.py --help
3..0 - GDM_link_data_processing:i_status_select
usage: phaseMeasurement.py [-h] fileName numberEvents numberVX sizeEvents stopEvent minHist maxHist numberBin writeToTXT saveAsPDF
</pre>


Read data from midas file (in .lz4 format) to calculate phase between the clock of VX1 and VX2
CDM:
<pre>
31..0 - CDM_link_data_processing:o_error_count
</pre>


positional arguments:
== register 7 0x8001001c ==
  fileName      Name of the file we want to read data from (Example: run00389.mid.lz4)
  numberEvents  Number of events recorded in the file
  numberVX      Number of VX used in this run (usually 2...)
  sizeEvents    Number of points per event
  stopEvent    Number of events you want to go through to calculate phase
  minHist      Minimal value for the x axis of the phase measurement histogram (in ns)
  maxHist      Maximal value for the x axis of the phase measurement histogram (in ns)
  numberBin    Number of bins wanted for the generated histogram
  writeToTXT    Write argument as yes to generate text file with results of calculation
  saveAsPDF    Save generated plots to PDF files


optional arguments:
GDM:
  -h, --help    show this help message and exit
<pre>
daq00:PhaseMeasurement$
31..0 - GDM_link_data_processing:o_status_vector
</pre>
</pre>
* try an old file with
 
* python3 ./phaseMeasurement.py run00877.mid.lz4 10000 2 10000 500 -20 20 81 yes yes
CDM:
<pre>
<pre>
bin size = 0.494 ns
31..0 - CDM_link_data_processing:o_error_count
num_events =  347
</pre>
mean = -1.705 ns
 
rms = 3.087 ns
= GDM, CDM, VX packet communications =
mean_error = 0.166 ns
 
centroid = -1.706 ns.
* timestamp math
width (sigma) = 0.363 ns.
<pre>
error on the centroid = 0.016558 ns.
1 clock is 8 ns is 125 MHz
8 bits of clocks is 256 clocks is 2048 ns is ~2 usec
16 bits of clocks is ~500 usec is 0.5 msec
24 bits of clocks is ~134 msec
32 bits of clocks is ~34 sec
40 bits of clocks is ~8.7 ksec is 2.4 hours
48 bits of clocks is ~625 hours is ~26 days
56 bits of clocks is ~6.6 kdays is ~18 kyears
62 bits of clocks is ~10 Mhours is 427 kdays is ~1.1 kyears
64 bits of clocks is ~4.4 kyears
</pre>
* 0x02 - TRG packet, 8 bytes, 80 adc clocks, 640 ns on lvds link
<pre>
0 - 0x02
1 - trg_counter[7:0]
2 - ts64 low byte 0
3 - ts64 byte 1
4 - ts64 byte 2
5 - ts64 high byte 3
6 - trg_in_latch[7:0]
7 - trg_in_latch[15:8]
</pre>
* 0x03 - HITMAP_TRG packet, 12 bytes, 120 adc clocks, 960 ns on lvds link
<pre>
0 - 0x03
1 - trg_counter[7:0]
2 - ts64 low byte 0
3 - ts64 byte 1
4 - ts64 byte 2
5 - ts64 high byte 3
6 - vx_bitmap[7:0]
7 - vx_bitmap[15:8]
8 - vx_bitmap[23:16]
9 - vx_bitmap[31:24]
10 - vx_bitmap[39:32]
11 - vx_bitmap[47:40]
</pre>
* 0x10 - TSM packet, 26 bytes, 260 adc clocks, 2080 ns on lvds link
<pre>
0 - 0x10
1 - tsm_counter[7:0]
2 - gdm_ts64 low byte 0
3 - 1
4 - 2
5 - 3
6 - 4
7 - 5
8 - 6
9 - gdm_ts64 high byte 7
10 - gps_ts64 low byte 0
11 - 1
12 - 2
13 - 3
14 - 4
15 - 5
16 - 6
17 - gps_ts64 high byte 7
18 - gps_data64 low byte 0
19 - 1
20 - 2
21 - 3
22 - 4
23 - 5
24 - 6
25 - gps_data64 high byte 7
</pre>
* 0x81 - VX hitmap packet, 10 bytes, 100 adc clocks, 800 ns on lvds link, 48 ns on fiber link
<pre>
0 - 0x81
1 - VX ID
2 - hitmap low byte, nits 7:0
3 - 15:8
4 - 23:16
5 - 31:24
6 - ...:32
7 - ...
8 - ...
9 - hitmap low byte, bits 63:...
</pre>
</pre>
* ls -l *.txt *.pdf
* 0x82 - CDM hitmap packet, 108 bytes, not sent on lvds link, not sent on fiber link
<pre>
<pre>
dsdaq@dsvslice:~/online/PhaseMeasurement$ ls -l *.txt *.pdf
0 - 0x82
-rw-rw-r-- 1 dsdaq dsdaq 64728 Dec 14 16:56 run00877.mid.lz4_Plots.pdf
1 - cdm_hitmap_trigger_counter[7:0]
-rw-rw-r-- 1 dsdaq dsdaq  274 Dec 14 16:56 run00877.mid.lz4.txt
2 - ts64 byte 0
dsdaq@dsvslice:~/online/PhaseMeasurement$
3 - ts64 byte 1
4 - ts64 byte 2
5 - ts64 byte 3
6 - ts64 byte 4
7 - ts64 byte 5
8 - ts64 byte 6
9 - ts64 byte 7
10 - cdm_hitmap_or12 byte 0 (7:0)
11 - cdm_hitmap_or12 byte 1 (11:8) plus 4 bits: 12=0, 13=0, 14=0, 15=cdm_hitmap_grand_or
12 - cdm_hitmap_data, low byte, 12*64 bits = 768 bits = 48 words = 96 bytes
...
107 - cdm_hitmap_data, high byte
</pre>
</pre>


== Standalone link test ==
= AXI bus timing =


<pre>
* AXI 100 MHz clock, 10 ns, 32-bit data
CDM: program clock chip
* AXI single-dword read: 36 clock repeat rate, 360 ns is 2.777 MHz, 4 bytes per transfer is 11.11 Mbytes/sec
busybox devmem 0x80011000 32 0x8
* AXI single-qword read: 13 clock repeat rate, 130 ns is 7.7 MHz, 4 bytes per transfer is 30 Mbytes/sec, not accounting for the gap
busybox devmem 0x80011000 32 0x0
* AXI memcpy read: 4 transfers at 13 clocks, gap, 4 transfers at 13 clocks, gap, etc. below 30 Mbytes/sec.
/home/dsdaq/si5394-i2c-file CDM_v3.0_IN1_fixed_and_IN2_RX_Recovered_VX_62.5MHz_Si5394-RevA-Registers.txt  0 0x6b
[[Image:Ds-dm-axi-read.png|100px]]
[[Image:Ds-dm-axi-read-64.png|100px]]
[[Image:Ds-dm-axi-read-memcpy.png|100px]]
* AXI single-dword write: 20 clocks repeat rate, 200 ns is 5 MHz, 4 bytes per transfer is 20 Mbytes/sec
* AXI single-qword write: 13+20 clocks repeat rate, 330 ns is 3 MHz, 16 bytes per burst is 48 Mbytes/sec
[[Image:Ds-dm-axi-write.png|100px]]
[[Image:Ds-dm-axi-write-64.png|100px]]


GDM, CDM: link reset
= AXI bus addresses =
busybox devmem 0x80011008 32 1


GDM, CDM: release reset
* see AXI/AMBA addresses assigned inthe FPGA project: (s_axi/reg0 is the DS-DM AXI registers)
busybox devmem 0x80011008 32 0
<pre>
daq00:ds-dm-gcdm$ grep assign_bd_address scripts/GDM_CDM_XU8_bd.tcl
  assign_bd_address -offset 0x80010000 -range 0x00004000 -target_address_space [get_bd_addr_spaces zynq_ultra_ps_e/Data] [get_bd_addr_segs axi_register_interfa_0/s_axi/reg0] -force
  assign_bd_address -offset 0x000400000000 -range 0x40000000 -target_address_space [get_bd_addr_spaces zynq_ultra_ps_e/Data] [get_bd_addr_segs ddr4/C0_DDR4_MEMORY_MAP/C0_DDR4_ADDRESS_BLOCK] -force
  assign_bd_address -offset 0x80000000 -range 0x00010000 -target_address_space [get_bd_addr_spaces zynq_ultra_ps_e/Data] [get_bd_addr_segs system_management_wiz/S_AXI_LITE/Reg] -force
daq00:ds-dm-gcdm$
</pre>


CDM: link status (NOTE: SFP LOS and mod_absent are swapped!!!)
* see AXI/AMBA addresses exported from FPGA project to Linux kernel: (uio for debug bridge should say "debug bridge")
busybox devmem 0x80011010 32
<pre>
0x00000024 <- fiber plugged
root@gdm0:~# cat /sys/class/uio/uio*/name
0x00000025 <- fiber unplugged
axi-pmon
0x00000027 <- SFP unplugged
axi-pmon
0x000007DC <- successful link with GDM
axi-pmon
axi-pmon
root@gdm0:~#
root@gdm0:~# ls -l /sys/class/uio/
total 0
lrwxrwxrwx 1 root root 0 Oct 18 01:36 uio0 -> ../../devices/platform/amba/ffa00000.perf-monitor/uio/uio0
lrwxrwxrwx 1 root root 0 Oct 18 01:36 uio1 -> ../../devices/platform/amba/fd0b0000.perf-monitor/uio/uio1
lrwxrwxrwx 1 root root 0 Oct 18 01:36 uio2 -> ../../devices/platform/amba/fd490000.perf-monitor/uio/uio2
lrwxrwxrwx 1 root root 0 Oct 18 01:36 uio3 -> ../../devices/platform/amba/ffa10000.perf-monitor/uio/uio3
root@gdm0:~# ls -l /sys/class/uio/../../devices/platform/amba/
total 0
-rw-r--r-- 1 root root 4096 Oct 18 19:37 driver_override
drwxr-xr-x 3 root root    0 Oct 18 01:36 fd070000.memory-controller
drwxr-xr-x 4 root root    0 Oct 18 01:36 fd0b0000.perf-monitor
drwxr-xr-x 4 root root    0 Oct 18 01:36 fd400000.zynqmp_phy
drwxr-xr-x 4 root root    0 Oct 18 01:36 fd490000.perf-monitor
drwxr-xr-x 4 root root    0 Oct 18 01:36 fd500000.dma
drwxr-xr-x 4 root root    0 Oct 18 01:36 fd510000.dma
drwxr-xr-x 4 root root    0 Oct 18 01:36 fd520000.dma
drwxr-xr-x 4 root root    0 Oct 18 01:36 fd530000.dma
drwxr-xr-x 4 root root    0 Oct 18 01:36 fd540000.dma
drwxr-xr-x 4 root root    0 Oct 18 01:36 fd550000.dma
drwxr-xr-x 4 root root    0 Oct 18 01:36 fd560000.dma
drwxr-xr-x 4 root root    0 Oct 18 01:36 fd570000.dma
drwxr-xr-x 4 root root    0 Oct 18 01:36 fd6e0000.cci
drwxr-xr-x 5 root root    0 Oct 18 01:36 ff000000.serial
drwxr-xr-x 4 root root    0 Oct 18 01:36 ff020000.i2c
drwxr-xr-x 6 root root    0 Oct 18 01:36 ff0a0000.gpio
drwxr-xr-x 4 root root    0 Oct 18 01:36 ff0b0000.ethernet
drwxr-xr-x 4 root root    0 Oct 18 01:36 ff0e0000.ethernet
drwxr-xr-x 4 root root    0 Oct 18 01:36 ff0f0000.spi
drwxr-xr-x 5 root root    0 Oct 18 01:36 ff160000.mmc
drwxr-xr-x 5 root root    0 Oct 18 01:36 ff170000.mmc
drwxr-xr-x 3 root root    0 Oct 18 01:36 ff960000.memory-controller
drwxr-xr-x 4 root root    0 Oct 18 01:36 ff9d0000.usb0
drwxr-xr-x 4 root root    0 Oct 18 01:36 ffa00000.perf-monitor
drwxr-xr-x 4 root root    0 Oct 18 01:36 ffa10000.perf-monitor
drwxr-xr-x 4 root root    0 Oct 18 01:36 ffa50000.ams
drwxr-xr-x 5 root root    0 Oct 18 01:36 ffa60000.rtc
drwxr-xr-x 4 root root    0 Oct 18 01:36 ffa80000.dma
drwxr-xr-x 4 root root    0 Oct 18 01:36 ffa90000.dma
drwxr-xr-x 4 root root    0 Oct 18 01:36 ffaa0000.dma
drwxr-xr-x 4 root root    0 Oct 18 01:36 ffab0000.dma
drwxr-xr-x 4 root root    0 Oct 18 01:36 ffac0000.dma
drwxr-xr-x 4 root root    0 Oct 18 01:36 ffad0000.dma
drwxr-xr-x 4 root root    0 Oct 18 01:36 ffae0000.dma
drwxr-xr-x 4 root root    0 Oct 18 01:36 ffaf0000.dma
-r--r--r-- 1 root root 4096 Oct 18 19:37 modalias
lrwxrwxrwx 1 root root    0 Oct 18 19:37 of_node -> ../../../firmware/devicetree/base/amba
drwxr-xr-x 2 root root    0 Oct 18 19:37 power
lrwxrwxrwx 1 root root    0 Oct 18 01:36 subsystem -> ../../../bus/platform
-rw-r--r-- 1 root root 4096 Oct 18 01:36 uevent
root@gdm0:~#
</pre>


CDM: link state machine and data
= Build firmware =
busybox devmem 0x80011014 32
0x35C06FF6


CDM: set link to counting mode
== Build from git clone ==
busybox devmem 0x80012000 32 0x101
busybox devmem 0x80012000 32 0x100


CDM: time counter and error counter
THESE ARE K.O.'s NOTES FOR CREATING THE PETALINUX DIRECTORY.
root@cdm1:~# busybox devmem 0x80012000 32
0x00000100 <--- link mode
root@cdm1:~# busybox devmem 0x80012004 32
0x0000058C <--- seconds counter
root@cdm1:~# busybox devmem 0x80012004 32
0x0000058D
root@cdm1:~# busybox devmem 0x80012008 32
0x00000000 <--- error counter


GDM: no link
THEY DO NOT WORK!
root@gdm0:~# busybox devmem 0x80011014 32
0x00000000
root@gdm0:~# busybox devmem 0x80011018 32
0x00000000
root@gdm0:~# busybox devmem 0x8001101c 32
0x00000000
root@gdm0:~# busybox devmem 0x80011024 32
0x00000FFF
root@gdm0:~#


GDM: good link channel 10, counting mode
COPY PETALINUX FROM A WORKING PROJECT AND USE "make gdm" and "make cdm" AS DESCRIBED BELOW.
root@gdm0:~# busybox devmem 0x80012000 32 0x101
root@gdm0:~# busybox devmem 0x80012000 32 0x100
root@gdm0:~# busybox devmem 0x80012008 32
0x3A8B68C2
root@gdm0:~# busybox devmem 0x80012008 32
0x42E03BEF
root@gdm0:~# busybox devmem 0x8001200c 32
0xDA090972
root@gdm0:~# busybox devmem 0x8001200c 32
0xDE6F22E9
root@gdm0:~# busybox devmem 0x80012019 32
Bus error
root@gdm0:~# busybox devmem 0x80012010 32
0xFFFFFFFF
root@gdm0:~# busybox devmem 0x80012014 32
0xFFFFFFFF
root@gdm0:~# busybox devmem 0x80012018 32
0xFFFFFFFF
root@gdm0:~# busybox devmem 0x8001201c 32
0xFFFFFFFF
root@gdm0:~# busybox devmem 0x80012020 32
0xFFFFFFFF
root@gdm0:~# busybox devmem 0x80012024 32
0xFFFFFFFF
root@gdm0:~# busybox devmem 0x80012028 32
0x00000000
root@gdm0:~# busybox devmem 0x8001202c 32
0xFFFFFFFF
root@gdm0:~# busybox devmem 0x80012030 32
0xFFFFFFFF
root@gdm0:~# busybox devmem 0x80012034 32
0xFFFFFFFF
root@gdm0:~#
</pre>


mapping of link channels:
* git clone git@edev-group.triumf.ca:fw/exp/darkside/gcdm.git
* #Makefile change VIVADO_SETTINGS_SCRIPT := /opt/Xilinx/Vivado/2022.1/settings64.sh
* #. /opt/Xilinx/Vivado/2022.1/settings64.sh
* . /opt/Xilinx/Vivado/2020.2/settings64.sh
* make clean
* make all_from_scratch
* . /opt/Xilinx/PetaLinux/2020.2/tool/settings.sh
* make petalinux_create
* make petalinux_rebuild_new_hw_des
* bomb out: The TMPDIR: /home/olchansk/git/ds-dm-gcdm/PetaLinux_GDM_CDM/build/tmp can't be located on nfs.
* mkdir /tmp/build_tmp
* rm -rf /home/olchansk/git/ds-dm-gcdm/PetaLinux_GDM_CDM/build/tmp/
* ln -s /tmp/build_tmp /home/olchansk/git/ds-dm-gcdm/PetaLinux_GDM_CDM/build/tmp
* try again
* grinds, loads a whole bunch of packages...
* finishes with desire to copy things to /tftpboot
* make sdcard_cp_to wants to copy files from PetaLinux_GDM_CDM/images/linux/ to SD card
 
== Build firmware ==
 
NOTE: directory Petalinux_GDM_CDM should already exist!


<pre>
<pre>
qsfp0 lane0 - 0x0100 - link 8
#. /opt/Xilinx/Vivado/2020.2/settings64.sh
qsfp0 lane1 - 0x0200 - link 9
. /opt/Xilinx/Vivado/2022.2/settings64.sh
qsfp0 lane2 - 0x0400 - link 10
. /opt/Xilinx/PetaLinux/2020.2/tool/settings.sh
qsfp0 lane3 - n/c
make clean_gdm  # remove gdm build tree
qsfp1 lane0 - 0x0800 - link 11
make gdm        # build or rebuild GDM
qsfp1 lane1 - 0x0010 - link 4
make copy_gdm    # copy to gdm0
qsfp1 lane2 - 0x0020 - link 5
make clean_cdm  # remove cdm build tree
qsfp1 lane3 - n/c
make cdm        # build or rebuild CDM
qsfp2 lane0 - 0x0040 - link 6
make copy_cdm    # copy to cdm0 and cdm1
qsfp2 lane1 - 0x0080 - link 7
qsfp2 lane2 - 0x0001 - link 0
qsfp2 lane3 - n/c
qsfp3 lane0 - 0x0002 - link 1
qsfp3 lane1 - 0x0004 - link 2
qsfp3 lane2 - 0x0008 - link 3
qsfp3 lane3 - n/c
</pre>
</pre>


script to start the test with 2 CDMs:
copy to SD card:
 
<pre>
<pre>
ssh dsdaq@dsvslice
open a root shell
ssh root@gdm0 busybox devmem 0x80011008 32 1
format 16 GB Sd card per above
ssh root@cdm0 busybox devmem 0x80011008 32 1
cd .../ds-dm-gcdm
ssh root@cdm1 busybox devmem 0x80011008 32 1
make copy
ssh root@gdm0 busybox devmem 0x80011008 32 0
ssh root@cdm1 busybox devmem 0x80011008 32 0
ssh root@cdm0 busybox devmem 0x80011008 32 0
ssh root@gdm0 /home/dsdaq/online/ds-dm-software/test_cdm.exe --link-test2
ssh root@cdm0 /home/dsdaq/online/ds-dm-software/test_cdm.exe --link-test2
ssh root@cdm1 /home/dsdaq/online/ds-dm-software/test_cdm.exe --link-test2
</pre>
</pre>


== LEMO trigger DGM to CDM to VX ==
= build times =
 
on the GDM:


<pre>
<pre>
/home/dsdaq/si5394-i2c-file /home/dsdaq/GDM_v1.0_IN0_EXT1_and_IN1_fixed_Si5394-RevA-Registers.txt 0 0x6b
CDM 12-june-2023 69aabc1c25130d970bc375aca684bd68849e6685
busybox devmem 0x80011008 32 0x1
daq13 AMD-5700G 1688.61user 399.33system 23:28.84elapsed 148%CPU
busybox devmem 0x80011008 32 0x0
dsdaqgw AMD-7700 1090.55user 247.34system 16:03.55elapsed 138%CPU
/home/dsdaq/online/ds-dm-software/test_cdm.exe --writereg 23 0x80001230 # QSFP TX fixed pattern
dsdaqgw AMD-7700 CDM incremental 196.68user 67.62system 7:35.42elapsed 58%CPU
/home/dsdaq/online/ds-dm-software/test_cdm.exe --writereg 2 0xff # enable LEMO inputs
dsdaqgw AMD-7700 CDM incremental 684.72user 94.17system 7:30.17elapsed 173%CPU
/home/dsdaq/online/ds-dm-software/test_cdm.exe --writereg 3 0x7654 # enable LED, one per LEMO input
dsdaqgw AMD-7700 GDM incremental 849.84user 99.79system 9:04.56elapsed 174%CPU
/home/dsdaq/online/ds-dm-software/test_cdm.exe --writereg 9 0x0F0F # enable LEMO to trg_in and tsm_in
/home/dsdaq/online/ds-dm-software/test_cdm.exe --writereg 23 0x40001230 # enable trg_in and tsm_in output to QSFP
</pre>
</pre>


on the CDM:
= prepare bootable sd card =
 
== format the sd card ==
 
this only needs to be done once
 
* become root
* cd ~olchansk/git/ds-dm-gcdm
* use "lsblk" to identify the SD card (should show as 8/16/32 GB block device)/ /dev/sdd in this case
* make sdcard_format SDCARD_DEVICE=/dev/sdd
* disconnect sd card, reconnect the sd card (to detect new partition tables, etc)
 
== copy CDM boot files ==


<pre>
<pre>
/home/dsdaq/si5394-i2c-file /home/dsdaq/CDM_v3.0_IN1_fixed_and_IN2_RX_Recovered_VX_62.5MHz_Si5394-RevA-Registers.txt 0 0x6b
cd /home/dsdmdev/git/ds-dm-gcdm
/home/dsdaq/online/ds-dm-software/test_cdm.exe --cdm-clocks
make copy
/home/dsdaq/online/ds-dm-software/test_cdm.exe --sfp
busybox devmem 0x80011008 32 1
busybox devmem 0x80011008 32 0
/home/dsdaq/online/ds-dm-software/test_cdm.exe --cdm-link
/home/dsdaq/online/ds-dm-software/test_cdm.exe --writereg 9 0x8040 # trg_in from sfp[0], tsm_in form sfp[1]
/home/dsdaq/online/ds-dm-software/test_cdm.exe 11 # trg_in counter
/home/dsdaq/online/ds-dm-software/test_cdm.exe 12 # tsm_in counter
</pre>
</pre>


== GPS receiver VCL-2705 ==
== copy boot files to the sd card ==


* Valiant VCL-2705 GPS receiver
* as root: identify partition labels, run "blkid", should say "BOOT", "rootfs" and "data"
* https://www.valiantcom.com/time-distribution/gps-receiver-irig-b.html
* mount
* USB connection is /dev/ttyACM0, 115200 bps, "GNSSAUX" prompt
* minicom -D /dev/ttyACM0 -b 115200
* user manual download instructoins - see sheet of paper with user name and password in the shipping box
* usb commands:
<pre>
<pre>
gnss-help
mkdir /media/olchansk/BOOT
gnss-showver -> F/W: Ver 1.7 Feb 17 2020 16:20:43
mkdir /media/olchansk/rootfs
mkdir /media/olchansk/data
mount -L BOOT /media/olchansk/BOOT
mount -L rootfs /media/olchansk/rootfs
mount -L data /media/olchansk/data
cp PetaLinux_GDM_CDM/images/linux/BOOT.BIN /media/olchansk/BOOT/
cp PetaLinux_GDM_CDM/images/linux/boot.scr /media/olchansk/BOOT/
cp PetaLinux_GDM_CDM/images/linux/image.ub /media/olchansk/BOOT/
umount /media/olchansk/BOOT
umount /media/olchansk/rootfs
umount /media/olchansk/data
eject /dev/sdd
</pre>


gnss-showselftest -> no antenna connected
= boot messages =
Overall  : FAIL
EPROM Test: PASS
Antenna  : NOT DETECTED
GNSS      : COMMUNICATION OK


gnss-showsettings
<pre>
GNSS NMEA BAUDRATE        :115200
Xilinx Zynq MP First Stage Boot Loader
GNSS ANTENNA LENGTH      :30 meters
Release 2020.2  Sep 24 2022  - 13:29:15
GNSS USER CONFIGURED DELAY:-65 nanoseconds
NOTICE: ATF running on XCZU4CG/silicon v4/RTL5.1 at 0xfffea000
GNSS 1PPS PULSE WIDTH    :200 milliseconds
NOTICE: BL31: v2.2(release):xlnx_rebase_v2.2_2020.3
GNSS MODE                :GPS
NOTICE: BL31: Built : 18:02:46, Sep 28 2022
GNSS STATUS              :STATIONARY


GNSSAUX> gnss-showserial
SERIAL :2704H01V17MAX310


GNSSAUX> gnss-showmode
U-Boot 2020.01 (Sep 28 2022 - 18:03:39 +0000)
GNSS MODE : GPS


GNSSAUX> gnss-showstatus
Model: DarkSide 20k DM
GNSS STATUS: STATIONARY
Board: Xilinx ZynqMP
DRAM:  2 GiB
usb dr_mode not found
PMUFW:  v1.1
EL Level:      EL2
Chip ID:        zu4
NAND:  0 MiB
MMC:  mmc@ff160000: 0, mmc@ff170000: 1
In:    serial@ff000000
Out:  serial@ff000000
Err:  serial@ff000000
Bootmode: SD_MODE1
Reset reason:  SOFT
Net: 
ZYNQ GEM: ff0b0000, mdio bus ff0b0000, phyaddr -1, interface rgmii-id


GNSSAUX> gnss-showalarms
Warning: ethernet@ff0b0000 (eth0) using random MAC address - d6:62:5f:13:00:44
CURRENT ALARMS GNSS
eth0: ethernet@ff0b0000
ANTENNA  : NOT DETECTED
ZYNQ GEM: ff0e0000, mdio bus ff0e0000, phyaddr -1, interface rgmii-id
Could not get PHY for eth1: addr -1


GNSSAUX> gnss-showerrors
Hit any key to stop autoboot:  0  
CURRENT ALARMS GNSS
ZynqMP>
ANTENNA : **NOT DETECTED
CTRL-A Z for help | 115200 8N1 | NOR | Minicom 2.7.1 | VT102 | Online 122:2 | ttyACM0                                     
ERROR STATISTICS GNSS
</pre>
RMC GOOD DURATION : Secs 0
RMC BAD DURATION  : Secs 0
LOCK GOOD SECS DURATION  : Secs 0
LOCK BAD SECS DURATION  : Secs 0
SATINFO GOOD ITERATIONS  :0
SATINFO REJECT ITERATIONS :0
SATINFO NOTALKER ITERATIONS  :0
CURRENT MONITOR STATE GNSS
STATE :Phase-1 HUNTING ANTENNA DETECT


GNSSAUX> gnss-showsatinfo
= load FPGA from u-boot =
GNSS RECEIVER ANTENNA Not Detected !


GNSSAUX> gnss-showsats
* https://xilinx-wiki.atlassian.net/wiki/spaces/A/pages/124682257/U-Boot+FPGA+Driver
Total Sats: 0


GNSSAUX> gnss-showmyloc
<pre>
GNSS RECEIVER ANTENNA Not Detected !
ZynqMP> fpga info
Xilinx Device
Descriptor @ 0x000000007fddb2c0
Family:        ZynqMP PL
Interface type: csu_dma configuration interface (ZynqMP)
Device Size:    1 bytes
Cookie:        0x0 (0)
Device name:    zu4
Device Function Table @ 0x000000007fda5fe8
PCAP status    0xa0002fde
ZynqMP>
</pre>


GNSSAUX> gnss-show1ppsstate
* cp CDM_XU8_top.bit /tftpboot/fpga.bit
GNSS RECEIVER ANTENNA Not Detected !


GNSSAUX> gnss-showjamstatus
<pre>
Not Available !
dhcp
tftpb 0x10000000 fpga.bit
fpga loadb 0 0x10000000 ${filesize}
</pre>


GNSSAUX> gnss-showspoofstatus
<pre>
Not Available !
ZynqMP> dhcp
BOOTP broadcast 1
DHCP client bound to address 192.168.0.100 (1 ms)
*** Warning: no boot file name; using 'C0A80064.img'
Using ethernet@ff0b0000 device
TFTP from server 192.168.0.1; our IP address is 192.168.0.100
Filename 'C0A80064.img'.
Load address: 0x8000000
Loading: *
TFTP error: 'file /tftpboot/C0A80064.img not found for 192.168.0.100' (1)
Not retrying...
ZynqMP> tftpb 0x10000000 fpga.bit
Using ethernet@ff0b0000 device
TFTP from server 192.168.0.1; our IP address is 192.168.0.100
Filename 'fpga.bit'.
Load address: 0x10000000
Loading: #################################################################
        #################################################################
        #################################################################
        #################################################################
        #################################################################
        #################################################################
        #################################################################
        #################################################################
        ############
        6.2 MiB/s
done
Bytes transferred = 7797807 (76fc2f hex)
ZynqMP> fpga loadb 0 0x10000000 ${filesize}
  design filename = "CDM_XU8_top;UserID=0XFFFFFFFF;Version=2022.2"
  part number = "xczu4cg-fbvb900-1-e"
  date = "2024/08/14"
  time = "14:18:22"
  bytes in bitstream = 7797692
zynqmp_align_dma_buffer: Align buffer at 0000000010000073 to 000000000fffff80(swap 0)
ZynqMP>
</pre>


--- antenna connected, can see the sky ---
= load FPGA from Linux =
 
* https://xilinx-wiki.atlassian.net/wiki/spaces/A/pages/18841847/Solution+ZynqMP+PL+Programming


GNSSAUX> gnss-showselftest
== this will reset the CPU ==
Overall  : PASS
<pre>
EPROM Test: PASS
cp fpga.bit /lib/firmware/
Antenna  : DETECTED
echo fpga.bit > /sys/class/fpga_manager/fpga0/firmware
GNSS      : COMMUNICATION OK
</pre>


GNSSAUX> gnss-showalarms
* make .bin file:
CURRENT ALARMS GNSS
<pre>
ANTENNA  : DETECTED
bootgen -image CDM_XU8_top.bif -arch zynqmp -o ./fpga.bin -w
GNSS LOCK : AVAILABLE
</pre>
* cat CDM_XU8_top.bif
<pre>
dsdaqgw:ds-dm-gcdm$ cat CDM_XU8_top.bif
all:
{
        [destination_device = pl] ./Vivado_CDM_XU8/CDM_XU8.runs/impl_1/CDM_XU8_top.bit
}
dsdaqgw:ds-dm-gcdm$
</pre>


GNSSAUX> gnss-showerrors
== this will reset the CPU ==
CURRENT ALARMS GNSS
ANTENNA : DETECTED
GNSS LOCK : AVAILABLE
ERROR STATISTICS GNSS
RMC GOOD DURATION  : Mins 1,Secs 34
RMC BAD DURATION  : Secs 55
LOCK GOOD SECS DURATION  : Mins 1,Secs 34
LOCK BAD SECS DURATION  : Secs 55
SATINFO GOOD ITERATIONS  :3
SATINFO REJECT ITERATIONS :0
SATINFO NOTALKER ITERATIONS  :0
CURRENT MONITOR STATE GNSS
STATE :Phase-4 NORMAL OPERATION, Monitoring GNSSLOCK


GNSSAUX> gnss-showsatinfo
<pre>
GNSS MODE :GPS
cp fpga.bin /lib/firmware/
SATELLITE INFORMATION  TALKER:GPS
echo fpga.bin > /sys/class/fpga_manager/fpga0/firmware
NMEA ID : 01-32
</pre>
NO OF SATELLITES IN VIEW: 08
NO OF XXGSV MSGS        : 03
SatNo  PRN NO (SV ID)      ELEVATION (degs)    AZIMUTH (degs)      C/No (SNR)
1      0                  0                  0                  0                 
2      0                  0                  0                  0                 
3      0                  0                  0                  0                 
4      0                  0                  0                  0                 
5      0                  0                  0                  0                 
6      0                  0                  0                  0                 
7      0                  0                  0                  0                 
8      0                  0                  0                  0                 
<<<<<< End of Sat Info >>>>>>


GNSSAUX> gnss-showsats
== this will reset the CPU ==
Total Sats: 8


GNSSAUX> gnss-showmyloc
<pre>
GNSS RECEIVER LOCATION:
root@dsdm:~# ./fpgautil -b fpga.bin -f Full
Latitude : 4914.81911
</pre>
Longitude: 12313.69595


GNSSAUX> gnss-show1ppsstate
== this will reset the CPU ==
GPS 1PPS STATE: LOCKED


GNSSAUX> gnss-showmyloc       
<pre>
DTSO file from here: https://xilinx-wiki.atlassian.net/wiki/spaces/A/pages/18841847/Solution+ZynqMP+PL+Programming
echo 0 > /sys/class/fpga_manager/fpga0/flags
mount -t configfs configfs /configfs
root@dsdm:~# dtc -O dtb -o fpga.dtbo -b 0 -@ fpga.dtso
root@dsdm:~# cp fpga.dtbo /lib/firmware/
root@dsdm:~# cp fpga.bit /lib/firmware/
root@dsdm:~# rmdir /configfs/device-tree/overlays/fpga
root@dsdm:~# mkdir /configfs/device-tree/overlays/fpga
root@dsdm:~# echo -n "fpga.dtbo" > /configfs/device-tree/overlays/fpga/path
</pre>


GNSS RECEIVER LOCATION:
= fpgautil =
Latitude : 4914.80688
Longitude: 12313.69531


enter into google maps search box as: 49 14.80688, -123 13.69531, observe the space, the moved dot and the minus.
* https://github.com/Xilinx/meta-xilinx/blob/master/meta-xilinx-core/recipes-bsp/fpga-manager-script/files/fpgautil.c


GNSSAUX> gnss-resetgnss
<pre>
git clone https://github.com/Xilinx/meta-xilinx.git
cd meta-xilinx/meta-xilinx-core/recipes-bsp/fpga-manager-script/files/
scp fpgautil.c root@dsdm:
ssh root@dsdm
make fpgautil
ls -l ./fpgautil
</pre>


Executing....Please Wait....
<pre>
$$$$$END
root@dsdm:~# ls -l ./fpgautil
-rwxr-xr-x 1 root root 72256 Aug 16 00:15 ./fpgautil
root@dsdm:~# ./fpgautil
 
fpgautil: FPGA Utility for Loading/reading PL Configuration
 
Usage: fpgautil -b <bin file path> -o <dtbo file path>
 
Options: -b <binfile> (Bin file path)
        -o <dtbofile> (DTBO file path)
        -f <flags> Optional: <Bitstream type flags>
  f := <Full | Partial >
        -n <Fpga region info>  FPGA Regions represent FPGA's
                                and partial reconfiguration
                                regions of FPGA's in the
                                Device Tree
Default: <full>
  -s <secure flags> Optional: <Secure flags>
  s := <AuthDDR | AuthOCM | EnUsrKey | EnDevKey | AuthEnUsrKeyDDR | AuthEnUsrKeyOCM | AuthEnDevKeyDDR | AuthEnDevKeyOCM>
  -k <AesKey> Optional: <AES User Key>
  -r <Readback> Optional: <file name>
Default: By default Read back contents will be stored in readback.bin file
  -t Optional: <Readback Type>
  0 - Configuration Register readback
  1 - Configuration Data Frames readback
Default: 0 (Configuration register readback)
  -R Optional: Remove overlay from a live tree
Examples:
(Load Full bitstream using Overlay)
fpgautil -b top.bit.bin -o can.dtbo -f Full -n full
(Load Partial bitstream using Overlay)
fpgautil -b rm0.bit.bin -o rm0.dtbo -f Partial -n PR0
(Load Full bitstream using sysfs interface)
fpgautil -b top.bit.bin -f Full
(Load Partial bitstream using sysfs interface)
fpgautil -b rm0.bit.bin -f Partial
(Load Authenticated bitstream through the sysfs interface)
fpgautil -b top.bit.bin -f Full -s AuthDDR
(Load Parital Encrypted Userkey bitstream using Overlay)
fpgautil -b top.bit.bin -o pl.dtbo -f Partial -s EnUsrKey -k <32byte key value>
(Read PL Configuration Registers)
fpgautil -b top.bit.bin -r
(Remove Partial Overlay)
fpgautil -R -n PR0
(Remove Full Overlay)
fpgautil -R -n full
Note: fpgautil -R is responsible for only removing the dtbo file from the livetree. it will not remove the PL logic from the FPGA region.
root@dsdm:~#
</pre>
 
= fw_printenv =
 
to access u-boot environment from Linux:
* apt install -y libubootenv-tool
* create /etc/fw_env.config
<pre>
/media/BOOT/uboot.env 0 0x40000
/media/BOOT/uboot-redund.env 0 0x40000
</pre>
* if uboot.env files do not exist, run "saveenv" from u-boot command prompt
* fw_printenv and fw_setenv should work
 
= Boot from network =
 
== u-boot ==
 
<pre>
ZynqMP> setenv bootcmd run bootcmd_dhcp
ZynqMP> saveenv
ZynqMP> reset
</pre>
</pre>


* 1PPS BNC output: period 1 sec, pulse width 200 ms, 3.3V into 1MOhm, 1.38V into 50Ohm.
== boot.scr ==
* IRIG-B BNC output: 5.6V into 1MOhm, 2.4V into 50Ohm.
* IRIG-B format selector: default is all up.


== Rb clock PRS10 ==
<pre>
# boot.scr
# mkimage -C none -A arm -T script -d boot.scr boot.scr.uimg
echo Loading FPGA!
#tftpb 0x10000000 fpga.bit
tftpb 0x10000000 {ipaddr}.bit
fpga loadb 0 0x10000000 ${filesize}
echo Booting Linux!
run bootcmd_pxe
echo Done!
</pre>


* https://www.thinksrs.com/products/prs10.html
* 10 MHz output is sine wave around 5V peak to peak
* 1PPS BNC output is 10 usec pulse, 5V into 1MHohm.
* RS232 connection: minicom -D /dev/ttyUSB0 -b 9600
* ser2net config: localhost,3001:raw:600:usb-5-2-1.0:9600  -XONXOFF -RTSCTS LOCAL
* ssh daq13, cd /home/olchansk/git/ser2net, ./ser2net -c ~/daq/ds/ser2net.conf -d
* ssh daq13, cd ~/daq/ds, python3 prs10.py
* RS232 commands:
<pre>
<pre>
ID?
mkimage -C none -A arm -T script -d boot.scr boot.scr.uimg
PRS10_3.56_SN_105719
</pre>
VB1
SN?
RS1 -- reset
ST? -- status
FC? -- 10MHz OCXO drive voltage DAC settings
DS? -- "detected signals"
GA? -- gain of frequency lock loop between ovenized oscillator and Rb cell, 0=use ovenized oscillator only
MO? -- magnetic offset of the Rb cell, range 2300..3600, if out of range, unit must be set to different operating mode, see prs10m.pdf
MR? -- magnetic read
TT? -- time-tag, time in ns between 1PPS out and 1PPS in
TS? -- time slope, ???
TO? -- time offset, ???
PS? -- pulse slope, ???
PL? -- 0=phase lock off, 1=phase lock on, lock to 1PPS input
PT? -- phase lock integrator time constant, PT8 is integrator time constant 18.2 hours, natural time constant 2.25 hours
PF? -- phase lock stability factor, PF2 is "1"
PI? -- phase lock integrator


Analog to digital 12 bit ADC, values 0.000 to 4.998
== tftpboot ==


AD0? -- Spare (J204)
<pre>
AD1? -- +24V(heater supply) divided by 10.
cp /home/olchansk/git/ds-dm-gcdm/boot.scr.uimg /tftpboot
AD2? -- +24V(electronics supply) divided by 10
ln -s /home/olchansk/git/ds-dm-gcdm/PetaLinux_GDM_CDM/images/linux /tftpboot/xilinx-dsdm
AD3? -- Drain voltage to lamp FET divided by 10
mkdir /tftpboot/pxelinux.cfg
AD4? -- Gate voltage to lamp FET divided by 10
cat > /tftpboot/pxelinux.cfg/default-arm-zynqmp <<EOF
AD5? -- Crystal heater control voltage
LABEL Linux
AD6? -- Resonance cell heater control voltage
  KERNEL xilinx-dsdm/Image
AD7? -- Discharge lamp heater control voltage
  FDT xilinx-dsdm/system.dtb
AD8? -- Amplified ac photosignal
  #INITRD rootfs.cpio.gz.u-boot
AD9? -- Photocell’s I/V converter voltage divided by 4
EOF
AD10? -- Case temperature (10 mV/°C)
</pre>
AD11? -- Crystal thermistors
AD12? -- Cell thermistors
AD13? -- Lamp thermistors
AD14? -- Frequency calibration pot / external calibration voltage
AD15? -- Analog ground


A/D via CPU E-port:
== boot sequence ==


AD16? -- Varactor voltage for 22.48 MHz VCXO (inside RF synthesizer) / 4
* xilinx magic load BOOT.BIN from SD card
AD17? -- Varactor voltage for 360 MHz VCO (output of RF synthesizer) / 4
* load FPGA form BOOT.BIN
AD18? -- Gain control voltage for amplifier which drives frequency multiplier / 4
* load and run u-boot from BOOT.BIN or from image.ub
AD19? -- RF synthesizer’s lock indicator voltage (nominally 4.8 V when locked )
* u-boot load environment from ??? probably SD card uboot-redund.env, this includes our bootcmd
* run bootcmd which run bootcmd_dhcp which does:
* from /tftpboot:
* load and run boot.scr.uimg which does:
* load FPGA image xilinx-dsdm/${ipaddr}.bit
* run bootcmd_pxe which does:
* load pxelinux.cfg/default-arm-zynqmp which does:
* load xilinx-dsdm/Image ### this is the linux kernel
* load xilinx-dsdm/system.dtb ### this is the device tree
* start linux kernel
* linux kernel does dhcp
* linux kernel does nfs mount /nfsroot/%s,vers=3,tcp ### %s is replaced by the hostname supplied by DHCP
* userland starts and runs to console and ssh login.


ST?
= Xilinx ILA =
 
References:
* https://github.com/Xilinx/XilinxVirtualCable/tree/master
* https://xilinx-wiki.atlassian.net/wiki/spaces/A/pages/644579329/Xilinx+Virtual+Cable
* https://support.xilinx.com/s/article/974879?language=en_US
* https://docs.xilinx.com/v/u/en-US/pg245-debug-bridge
* https://docs.xilinx.com/r/2020.2-English/ug908-vivado-programming-debugging/Initializing-Vivado-IDE-hw_server
* (we do not use this one) https://github.com/paulscherrerinstitute/xvcSupport/blob/master/README.md


ST1 : Power supplies and Discharge Lamp
Build xvcserver_cdm.exe: (it is built as a static executable, can be copied and run anywhere)
ST1 bit, Condition which sets bit, Corrective Action
<pre>
0 -- +24 for electronic < +22 Vdc
ssh dsdaq@gdm0
1 -- +24 for electronics > +30 Vdc
cd /home/dsdaq/online/ds-dm-software
2 -- +24 for heaters <+22 Vdc
git pull ### get latest version
3 -- +24 for heaters > +30 Vdc
make xvcserver_cdm.exe
4 -- Lamp light level too low
ssh root@gdm0
5 -- Lamp light level too high
/home/dsdaq/online/ds-dm-software/xvcserver_cdm.exe
6 -- Gate voltage too low
INFO: To connect to this xvcServer instance, use url: TCP:gdm0:2542
7 -- Gate voltage too high
</pre>


ST2: RF Synthesizer
To activate and use the vivado logic analyzer:
ST2 bit, Condition which sets bit, Corrective Action
* data path: vivado -> hw_server -> xvcserver -> mmap axi bus -> debug bridge -> jtag -> ILA
0 -- RF synthesizer PLL unlocked
* define ILAs in the code
1 -- RF crystal varactor too low
* instantiate the xilinx debug bridge at AXI bus address 0x80020000 (FIXME!!! this collides with Ian's AXI addresses)
2 -- RF crystal varactor too high
* build and boot the new FPGA firmware. updating the linux kernel is not necessary.
3 -- RF VCO control too low
* login root@gdm0, run: /home/dsdaq/online/ds-dm-software/xvcserver_cdm.exe -v ### with "-v" for the first time to see that vivado does connect to it, without "-v", normally.
4 -- RF VCO control too high
* login dsdaqgw, run: hw_server -s tcp:localhost:3121 -e "set auto-open-servers xilinx-xvc:gdm0:2542" ### tells us to connect to port localhost:3121
5 -- RF AGC control too low
* login dsdaqgw, run vivado, open project, open hardware manager, open target, open new target, "connect to remote server", hostname "localhost", port "3121", next (bombs, try again, 3 times), popup add virtual cable, enter hostname "gdm0" port "2542", "ok", it shows in "hardware targets", "next", "finish", error popup "[Common 17-163] Missing value for option 'objects', please type 'set_property -help' for usage info", ignore it, in "hardware", right click the "gdm0" one, open target, under "hardware" and "debug bridge" we should see all the ILAs, under "hardware device properties", the "probes file" should have the ".ltx" file generated by vivado "Vivado_GDM_XU8/GDM_XU8.runs/impl_1/debug_nets.ltx", click on an ILA, a waveform should open.
6 -- RF AGC control too high
7 -- Bad PLL parameter


ST3: Temperature Controllers
= Software =
ST3 bit, Condition which sets bit
0 -- Lamp temp below set point
1 -- Lamp temp above set point
2 -- Crystal temp below set point
3 -- Crystal temp above set point
4 -- Cell temp below set point
5 -- Cell temp above set point
6 -- Case temperature too low
7 -- Case temperature too high


ST4: Frequency Lock-Loop Control
* ssh cdm0 # or gdm0
ST4 bit, Condition which sets bit
* sudo apt install i2c-tools libi2c-dev
0 -- Frequency lock control is off
* git clone https://bitbucket.org/team-ds-dm/ds-dm-software
1 -- Frequency lock is disabled
* cd ds-dm-software
2 -- 10 MHz EFC is too high
* make
3 -- 10 MHz EFC is too low
 
4 -- Analog cal voltage > 4.9 V
== test_cdm.exe ==
5 -- Analog cal voltage < 0.1
6 -- not used
7 -- not used


ST5: Frequency Lock to External 1pps
=== CDM SFP status ===
ST5 bit, Condition which sets bit
0 -- PLL disabled
1 -- < 256 good 1pps inputs
2 -- PLL active
3 -- > 256 bad 1pps inputs
4 -- Excessive time interval
5 -- PLL restarted
6 -- f control saturated
7 -- No 1pps input


ST6: System Level Events
<pre>
ST6 bit and Condition which sets bit
# /home/dsdaq/online/ds-dm-software/test_cdm.exe --sfp
0 Lamp restart
DS-DM mapping /dev/mem at 0x80010000
1 Watchdog time-out and reset
DS-DM FPGA firmware revision 0xbb2f0ae7
2 Bad interrupt vector
CDM firmware 0xbb2f0ae7
3 EEPROM write failure
arg 1: [--sfp]
4 EEPROM data corruption
Polling SFP status...
5 Bad command syntax
identifier 0x03
6 Bad command parameter
connector  0x07
7 Unit has been reset
encoding  0x01
wavelength 0x0352 (850 nm)
vendor_name [FINISAR CORP.  ]
vendor_pn  [FTLF8526P3BNL  ]
vendor_rev  [A  ]
vendor_sn  [N3AB9M8        ]
vendor_date [200319  ]
dm_type    0x68
temp 29.0 C
vcc  3.323 V
tx_bias  7.250 mA
tx_power 478.4 uW
rx_power 2.3 uW
SFP good 1, status: temp 30.6 C, tx_bias 7.4 mA, tx_power 476 uW, rx_power 818 uW
...
</pre>
</pre>
* ST? on warm start
 
=== GDM QSFP status ===
 
<pre>
<pre>
received: PRS_10
root@gdm0:~# /home/dsdaq/online/ds-dm-software/test_cdm.exe --qsfp3 --qsfp
received: 255,255,255,243,34,255
DS-DM mapping /dev/mem at 0x80010000
received: 0,0,0,1,34,0
DS-DM FPGA firmware revision 0x53aee418
...
CDM firmware 0x53aee418
received:  0,0,0,1,34,0
arg 1: [--qsfp3]
received:  0,0,0,0,2,0
gpiochip0: GPIOs 338-511, parent: platform/ff0a0000.gpio, zynqmp_gpio:
...
gpio-378 (                    |sysfs              ) out hi
received: 0,0,0,0,2,0
gpio-379 (                    |sysfs              ) out hi
received:  0,0,0,0,4,0
gpio-381 (                    |sysfs              ) out lo
gpio-382 (                    |sysfs              ) out hi
arg 2: [--qsfp]
Polling QSFP status...
identifier 0x0d
status    0x02
los        0x8f
temp      28.2 C
vcc        3.323 V
rx_power    0.1  0.1  0.1   0.1 uW
tx_bias      7.6  7.6  7.6  0.0 mA
tx_power  792.2 773.8 823.0  0.1 uW
vendor_name [FINISAR CORP    ]
vendor_pn  [FTL410QD4C      ]
vendor_rev  [A ]
wavelength  850
max_temp    70 C
vendor_sn  [X79AC0R        ]
vendor_date [220309 ]
QSFP good 1, status: temp 27.7 C, los 0x8b, tx_bias 7.5 7.6 7.6 0.0 mA, tx_power 792 772 821  0 uW, rx_power  0   0 466  0 uW
</pre>
</pre>
* ST? on loss of external 1PPS
 
=== GDM clock status ===
 
<pre>
<pre>
...
/home/dsdaq/online/ds-dm-software/test_cdm.exe --cc
received:  0,0,0,0,4,0
/home/dsdaq/online/ds-dm-software/test_cdm.exe --gdm-clocks
disconnect 1PPS input
received:  0,0,0,0,132,0
...
reconnect 1PPS input
received:  0,0,0,0,132,0
received:  0,0,0,0,4,0
...
</pre>
</pre>
* ST? on coldish start
 
* clock chip not loaded, not running:
 
<pre>
<pre>
daq13:ds$ python3 prs10.py
root@gdm0:~# /home/dsdaq/online/ds-dm-software/test_cdm.exe --cc
Connected
DS-DM mapping /dev/mem at 0x80010000
received [  ] old [ b'' ] counter:  0
DS-DM FPGA firmware revision 0x6d2ebce6
received [ PRS_10 ] old [  ] counter: 0
CDM firmware 0x6d2ebce6
received [ 255,255,255,243,34,255 ] old [ PRS_10 ] counter: 0
Polling CC status...
received [ 80,0,0,1,34,1 ] old [ 255,255,255,243,34,255 ] counter0
Clock chip registers: 0x06 0x00 0x94 0x53 0x00 0x00 0x0f 0x16 0x04 0x00 0x01 0x68 0x09 0x00 0x02 0xf2 0x00 0x1f 0xf0 0x22 0xf2, 0x507: 0x00, 0x52A: 0x00, 0x53F: 0x04
received [ 0,0,1,1,34,0 ] old [ 80,0,0,1,34,1 ] counter: 0
Clock chip state 0, statusSYSINCAL XAXB_ERR LOL CAL_PLL IN0 IN_SEL_0 FASTLOCK_STATUS
received [ 0,0,0,1,34,0 ] old [ 0,0,1,1,34,0 ] counter: 0
 
received [ 0,0,16,1,34,0 ] old [ 0,0,0,1,34,0 ] counter: 6
root@gdm0:~# /home/dsdaq/online/ds-dm-software/test_cdm.exe --gdm-clocks
received [ 0,0,20,1,34,0 ] old [ 0,0,16,1,34,0 ] counter: 5
DS-DM mapping /dev/mem at 0x80010000
received [ 0,0,4,1,34,0 ] old [ 0,0,20,1,34,0 ] counter: 8
DS-DM FPGA firmware revision 0x6d2ebce6
received [ 0,0,0,1,34,0 ] old [ 0,0,4,1,34,0 ] counter:  3
CDM firmware 0x6d2ebce6
received [ 0,0,0,0,2,0 ] old [ 0,0,0,1,34,0 ] counter: 49
GDM clock frequency counters:
received [ 0,0,0,0,4,0 ] old [ 0,0,0,0,2,0 ] counter: 250
0x1030 mgt_rx_ref_clk_raw: 0x1f7caf52 (528265042) should be ~125 MHz
...
0x1034 rx_clk:            0x00000000 (0) should be ~125 MHz
0x1038 mgt_tx_ref_clk_raw: 0x1f7caf52 (528265042) should be ~125 MHz
0x103C tx_clk:             0x00000000 (0) should be ~125 MHz
0x1040 clk_50MHz:         0x02faf080 (50000000) should be 50 MHz exactly
0x1044 Block1_clk:         0x05f5e100 (100000000) should be 100 MHz exactly
</pre>
</pre>
* ST? on cold start, note: no bump in the 10MHz clock as reported by DS-DM clock chip
 
* clock chip good (IN0 - external 10 MHz clock)
 
<pre>
<pre>
Connected
root@gdm0:~# /home/dsdaq/online/ds-dm-software/test_cdm.exe --cc
received [  ] old [ b'' ] counter:  0
DS-DM mapping /dev/mem at 0x80010000
received [ PRS_10 ] old [  ] counter: 0
DS-DM FPGA firmware revision 0x6d2ebce6
received [ 255,255,255,243,34,255 ] old [ PRS_10 ] counter: 0
CDM firmware 0x6d2ebce6
received [ 80,0,21,1,34,1 ] old [ 255,255,255,243,34,255 ] counter0
Polling CC status...
received [ 64,0,21,1,34,0 ] old [ 80,0,21,1,34,1 ] counter: 0
Clock chip registers: 0x06 0x00 0x94 0x53 0x00 0x00 0x00 0x00 0x00 0x00 0x01 0x68 0x00 0x44 0x00 0xd0 0x01 0x1f 0xff 0x22 0xf2, 0x507: 0x3f, 0x52A: 0x01, 0x53F: 0x00
received [ 0,0,21,1,34,0 ] old [ 64,0,21,1,34,0 ] counter: 0
Clock chip state 1, statusLOS_IN2 OOF_IN2 IN0 IN_SEL_REGCTRL IN_SEL_0
received [ 0,0,20,1,34,0 ] old [ 0,0,21,1,34,0 ] counter: 158
 
received [ 0,0,4,1,34,0 ] old [ 0,0,20,1,34,0 ] counter: 23
root@gdm0:~# /home/dsdaq/online/ds-dm-software/test_cdm.exe --gdm-clocks
received [ 0,0,0,1,34,0 ] old [ 0,0,4,1,34,0 ] counter: 47
DS-DM mapping /dev/mem at 0x80010000
received [ 0,0,0,0,2,0 ] old [ 0,0,0,1,34,0 ] counter: 40
DS-DM FPGA firmware revision 0x6d2ebce6
received [ 0,0,0,0,4,0 ] old [ 0,0,0,0,2,0 ] counter: 249
CDM firmware 0x6d2ebce6
GDM clock frequency counters:
0x1030 mgt_rx_ref_clk_raw: 0x07735a3b (125000251) should be ~125 MHz
0x1034 rx_clk:             0x07735a3c (125000252) should be ~125 MHz
0x1038 mgt_tx_ref_clk_raw: 0x07735a3b (125000251) should be ~125 MHz
0x103C tx_clk:             0x07735a3c (125000252) should be ~125 MHz
0x1040 clk_50MHz:         0x02faf080 (50000000) should be 50 MHz exactly
0x1044 Block1_clk:         0x05f5e100 (100000000) should be 100 MHz exactly
</pre>
 
=== CDM clock status ===
 
<pre>
/home/dsdaq/online/ds-dm-software/test_cdm.exe --cc
/home/dsdaq/online/ds-dm-software/test_cdm.exe --cdm-clocks
</pre>
</pre>
* clock chip not loaded, not running:
<pre>
root@cdm1:~# /home/dsdaq/online/ds-dm-software/test_cdm.exe --cc
DS-DM mapping /dev/mem at 0x80010000
DS-DM FPGA firmware revision 0x6d2ebec9
CDM firmware 0x6d2ebec9
Polling CC status...
Clock chip registers: 0x06 0x00 0x94 0x53 0x00 0x00 0x0f 0x16 0x04 0x00 0x01 0x68 0x19 0x00 0x02 0xf2 0x00 0x1f 0xf0 0x22 0xf2, 0x507: 0x00, 0x52A: 0x00, 0x53F: 0x04
Clock chip state 0, status:  SYSINCAL XAXB_ERR LOL CAL_PLL IN0 IN_SEL_0 FASTLOCK_STATUS
root@cdm1:~# /home/dsdaq/online/ds-dm-software/test_cdm.exe --cdm-clocks
DS-DM mapping /dev/mem at 0x80010000
DS-DM FPGA firmware revision 0x6d2ebec9
CDM firmware 0x6d2ebec9
CDM clock frequency counters:
0x1030 mgt_rx_ref_clk_raw: 0x07735851 (124999761) should be ~125 MHz
0x1034 rx_clk:            0x00000000 (0) should be ~125 MHz
0x1038 mgt_tx_ref_clk_raw: 0x0127fefa (19398394) should be ~125 MHz
0x103C tx_clk:            0x00000000 (0) should be ~125 MHz
0x1040 clk_50MHz:          0x02faf080 (50000000) should be 50 MHz exactly
0x1044 Block1_clk:        0x05f5e100 (100000000) should be 100 MHz exactly
</pre>
* clock chip uses internal clock (IN1 - internal oscillator), observe rx_clk frequency is not same as others
<pre>
root@cdm1:~# /home/dsdaq/online/ds-dm-software/test_cdm.exe --cc
DS-DM mapping /dev/mem at 0x80010000
DS-DM FPGA firmware revision 0x6d2ebec9
CDM firmware 0x6d2ebec9
Polling CC status...
Clock chip registers: 0x06 0x00 0x94 0x53 0x00 0x00 0x00 0x00 0x00 0x00 0x01 0x68 0x00 0x00 0x00 0xd0 0x01 0x1f 0xfe 0x22 0xf2, 0x507: 0x7f, 0x52A: 0x02, 0x53F: 0x02
Clock chip state 1, status:  IN1 IN_SEL_1 HOLD_HIST_VALID
root@cdm1:~# /home/dsdaq/online/ds-dm-software/test_cdm.exe --cdm-clocks
DS-DM mapping /dev/mem at 0x80010000
DS-DM FPGA firmware revision 0x6d2ebec9
CDM firmware 0x6d2ebec9
CDM clock frequency counters:
0x1030 mgt_rx_ref_clk_raw: 0x07735853 (124999763) should be ~125 MHz
0x1034 rx_clk:            0x07735b0a (125000458) should be ~125 MHz
0x1038 mgt_tx_ref_clk_raw: 0x07735853 (124999763) should be ~125 MHz
0x103C tx_clk:            0x07735852 (124999762) should be ~125 MHz
0x1040 clk_50MHz:          0x02faf080 (50000000) should be 50 MHz exactly
0x1044 Block1_clk:        0x05f5e100 (100000000) should be 100 MHz exactly
</pre>
* clock chip uses SFP recovered clock (IN2 - sfp rx recovered clock), observe mgt_rx_ref_clk_raw (CDM 125 MHz oscillator) is different from others (SFP RX recovered clock)
<pre>
root@cdm1:~# /home/dsdaq/online/ds-dm-software/test_cdm.exe --cc
DS-DM mapping /dev/mem at 0x80010000
DS-DM FPGA firmware revision 0x6d2ef81a
CDM firmware 0x6d2ef81a
Polling CC status...
Clock chip registers: 0x06 0x00 0x94 0x53 0x00 0x00 0x00 0x00 0x00 0x00 0x01 0x68 0x00 0x00 0x00 0xd0 0x01 0x1f 0xfe 0x22 0xf2, 0x507: 0xbf, 0x52A: 0x02, 0x53F: 0x02
Clock chip state 1, status:  IN2 IN_SEL_1 HOLD_HIST_VALID
^C
root@cdm1:~# /home/dsdaq/online/ds-dm-software/test_cdm.exe --cdm-clocks
DS-DM mapping /dev/mem at 0x80010000
DS-DM FPGA firmware revision 0x6d2ef81a
CDM firmware 0x6d2ef81a
CDM clock frequency counters:
0x1030 mgt_rx_ref_clk_raw: 0x0773581b (124999707) should be ~125 MHz
0x1034 rx_clk:            0x07735ad6 (125000406) should be ~125 MHz
0x1038 mgt_tx_ref_clk_raw: 0x07735ad7 (125000407) should be ~125 MHz
0x103C tx_clk:            0x07735ad6 (125000406) should be ~125 MHz
0x1040 clk_50MHz:          0x02faf080 (50000000) should be 50 MHz exactly
0x1044 Block1_clk:        0x05f5e100 (100000000) should be 100 MHz exactly
^C
</pre>
=== CDM link status, PRBS test mode ===
<pre>
# /home/dsdaq/online/ds-dm-software/test_cdm.exe --cdm-link
# /home/dsdaq/online/ds-dm-software/test_cdm.exe --link-test2
</pre>
* fiber disconnected, no link:
<pre>
CDM firmware:    0xbb2f0ae7
0x1000 SFP c.c. status: 0x00000031
    CLK_IN_SEL_LS  0x1
    CLK_EXT_SEL_LS  0
    CLK_CLK_RSTn_LS 0
    CLK_LOSXTn_LS  1
    CLK_LOLn_LS    1
    CLK_INTn_LS    0
0x1008 SFP link reset:  0x00000000
0x1010 SFP link status: 0x00000025
    sfp_mod_absent_N      1
    sfp_rx_los_N          0
    link_power_good        1
    rx_link_up            0
    rx_receiving_data      0
    rx_error              1
    rx_lnk_up_and_running  0
    tx_link_up            0
    tx_sending_data        0
    tx_link_up_and_running 0
    link_up_and_running    0
0x1014 SFP link data:  0x466a8187
    rx_data    0x8187
    k28p1_k28p5 0
    rx_ctrl0    0x1
    rx_ctrl1    0x1
    rx_ctrl3    0x1
    tx_state    0x1
    rx_state    0x6
    rx_receiving_data 0
    rx_link_up        0
    rx_error          1
    rx_link_rst      0
0x2000 link test mode: 0x00000200, seconds: 0x00079093, errors: 0xffffffff
</pre>
* fiber connected, good link:
<pre>
CDM firmware:    0xbb2f0ae7
0x1000 SFP c.c. status: 0x000000b2
    CLK_IN_SEL_LS  0x2
    CLK_EXT_SEL_LS  0
    CLK_CLK_RSTn_LS 0
    CLK_LOSXTn_LS  1
    CLK_LOLn_LS    1
    CLK_INTn_LS    0
0x1008 SFP link reset:  0x00000000
0x1010 SFP link status: 0x000007dc
    sfp_mod_absent_N      0
    sfp_rx_los_N          0
    link_power_good        1
    rx_link_up            1
    rx_receiving_data      1
    rx_error              0
    rx_lnk_up_and_running  1
    tx_link_up            1
    tx_sending_data        1
    tx_link_up_and_running 1
    link_up_and_running    1
0x1014 SFP link data:  0x35c02774
    rx_data    0x2774
    k28p1_k28p5 0
    rx_ctrl0    0x0
    rx_ctrl1    0x0
    rx_ctrl3    0x0
    tx_state    0x3
    rx_state    0x5
    rx_receiving_data 1
    rx_link_up        1
    rx_error          0
    rx_link_rst      0
0x2000 link test mode: 0x00000200, seconds: 0x00078a8c, errors: 0x00000000
</pre>
=== GDM link status, PRBS test mode ===
<pre>
1 link connected, no errors:
# /home/dsdaq/online/ds-dm-software/test_cdm.exe --gdm-link
# /home/dsdaq/online/ds-dm-software/test_cdm.exe --link-test2
GDM firmware:    0x6b2ee010
0x1014: 0x00000008, 18: 0x00000008, 1C: 0x00000000, 24: 0x00000fff
0x2000: 0x00000200, time: 0x00078aa4, errors:
0xffffffff 0xffffffff 0xffffffff
0x00000000 0xffffffff 0xffffffff
0xffffffff 0xffffffff 0xffffffff
0xffffffff 0xffffffff 0xffffffff
</pre>
=== CDM link status ===
<pre>
root@cdm1:~# /home/dsdaq/online/ds-dm-software/test_cdm.exe --link-test0
root@cdm1:~# /home/dsdaq/online/ds-dm-software/test_cdm.exe --cc
DS-DM mapping /dev/mem at 0x80010000
DS-DM FPGA firmware revision 0x6d2ef81a
CDM firmware 0x6d2ef81a
Polling CC status...
Clock chip registers: 0x06 0x00 0x94 0x53 0x00 0x00 0x00 0x00 0x00 0x00 0x01 0x68 0x00 0x00 0x00 0xd0 0x01 0x1f 0xfe 0x22 0xf2, 0x507: 0xbf, 0x52A: 0x02, 0x53F: 0x02
Clock chip state 1, status:  IN2 IN_SEL_1 HOLD_HIST_VALID
root@cdm1:~# /home/dsdaq/online/ds-dm-software/test_cdm.exe --cdm-clocks
DS-DM mapping /dev/mem at 0x80010000
DS-DM FPGA firmware revision 0x6d2ef81a
CDM firmware 0x6d2ef81a
CDM clock frequency counters:
0x1030 mgt_rx_ref_clk_raw: 0x077357a0 (124999584) should be ~125 MHz
0x1034 rx_clk:            0x07735a5c (125000284) should be ~125 MHz
0x1038 mgt_tx_ref_clk_raw: 0x07735a5b (125000283) should be ~125 MHz
0x103C tx_clk:            0x07735a5b (125000283) should be ~125 MHz
0x1040 clk_50MHz:          0x02faf080 (50000000) should be 50 MHz exactly
0x1044 Block1_clk:        0x05f5e100 (100000000) should be 100 MHz exactly
root@cdm1:~# /home/dsdaq/online/ds-dm-software/test_cdm.exe --cdm-link
DS-DM mapping /dev/mem at 0x80010000
DS-DM FPGA firmware revision 0x6d2ef81a
CDM firmware 0x6d2ef81a
CDM firmware:    0x6d2ef81a
0x1000 SFP c.c. status: 0x000000b2
    CLK_IN_SEL_LS  0x2
    CLK_EXT_SEL_LS  0
    CLK_CLK_RSTn_LS 0
    CLK_LOSXTn_LS  1
    CLK_LOLn_LS    1
    CLK_INTn_LS    0
0x1008 SFP link reset:  0x00000000
0x1010 SFP link status: 0x000007dc
    sfp_mod_absent_N      0
    sfp_rx_los_N          0
    link_power_good        1
    rx_link_up            1
    rx_receiving_data      1
    rx_error              0
    rx_lnk_up_and_running  1
    tx_link_up            1
    tx_sending_data        1
    tx_link_up_and_running 1
    link_up_and_running    1
0x1014 SFP link data:  0x35c6bcbc
    rx_data    0xbcbc
    k28p1_k28p5 0
    rx_ctrl0    0x3
    rx_ctrl1    0x0
    rx_ctrl3    0x0
    tx_state    0x3
    rx_state    0x5
    rx_receiving_data 1
    rx_link_up        1
    rx_error          0
    rx_link_rst      0
0x2000 link test mode: 0x00000000, seconds: 0x00001671, errors: 0xffffffff
root@cdm1:~# /home/dsdaq/online/ds-dm-software/test_cdm.exe 15
DS-DM mapping /dev/mem at 0x80010000
DS-DM FPGA firmware revision 0x6d2ef81a
CDM firmware 0x6d2ef81a
reg[15] is 0x0033bcbc (3390652)
</pre>
=== GDM link status ===
<pre>
root@gdm0:~# /home/dsdaq/online/ds-dm-software/test_cdm.exe --link-test0
root@gdm0:~# /home/dsdaq/online/ds-dm-software/test_cdm.exe --cc
DS-DM mapping /dev/mem at 0x80010000
DS-DM FPGA firmware revision 0x6d2ebce6
CDM firmware 0x6d2ebce6
Polling CC status...
Clock chip registers: 0x06 0x00 0x94 0x53 0x00 0x00 0x00 0x00 0x00 0x00 0x01 0x68 0x00 0x44 0x00 0xd0 0x01 0x1f 0xff 0x22 0xf2, 0x507: 0x3f, 0x52A: 0x01, 0x53F: 0x02
Clock chip state 1, status:  LOS_IN2 OOF_IN2 IN0 IN_SEL_REGCTRL IN_SEL_0 HOLD_HIST_VALID
root@gdm0:~# /home/dsdaq/online/ds-dm-software/test_cdm.exe --gdm-clocks
DS-DM mapping /dev/mem at 0x80010000
DS-DM FPGA firmware revision 0x6d2ebce6
CDM firmware 0x6d2ebce6
GDM clock frequency counters:
0x1030 mgt_rx_ref_clk_raw: 0x07735a0a (125000202) should be ~125 MHz
0x1034 rx_clk:            0x07735a0a (125000202) should be ~125 MHz
0x1038 mgt_tx_ref_clk_raw: 0x07735a0a (125000202) should be ~125 MHz
0x103C tx_clk:            0x07735a0a (125000202) should be ~125 MHz
0x1040 clk_50MHz:          0x02faf080 (50000000) should be 50 MHz exactly
0x1044 Block1_clk:        0x05f5e100 (100000000) should be 100 MHz exactly
register 0x1018 bit 0x800
root@gdm0:~# /home/dsdaq/online/ds-dm-software/test_cdm.exe --gdm-link
DS-DM mapping /dev/mem at 0x80010000
DS-DM FPGA firmware revision 0x6d2ebce6
CDM firmware 0x6d2ebce6
GDM firmware:    0x6d2ebce6
0x1014: 0x00000800, 18: 0x00000800, 1C: 0x00000000, 24: 0x00000fff
0x2000: 0x00000000, time: 0x00003d2f, errors:
0xffffffff 0xffffffff 0xffffffff
0xffffffff 0xffffffff 0xffffffff
0xffffffff 0xffffffff 0xffffffff
0xffffffff 0xffffffff 0xffffffff
link data alternates 0xbcbc and 0x1cbc
root@gdm0:~# /home/dsdaq/online/ds-dm-software/test_cdm.exe 22
DS-DM mapping /dev/mem at 0x80010000
DS-DM FPGA firmware revision 0x6d2ebce6
CDM firmware 0x6d2ebce6
reg[22] is 0xbcbc93ab (-1128492117)
root@gdm0:~# /home/dsdaq/online/ds-dm-software/test_cdm.exe 22
DS-DM mapping /dev/mem at 0x80010000
DS-DM FPGA firmware revision 0x6d2ebce6
CDM firmware 0x6d2ebce6
reg[22] is 0x1cbc1aaf (482089647)
root@gdm0:~#
</pre>
=== Run trg and tsm ===
<pre>
on the GDM:
ssh root@gdm00
./test_cdm.exe --gdm-clocks
./test_cdm.exe --load-cc
./test_cdm.exe --cc
./test_cdm.exe --reset-mgt
./test_cdm.exe --gdm-clocks
./test_cdm.exe --writereg 2 0xff # enable LEMO NIM inputs
./test_cdm.exe --writereg 3 0xba54 # LEDs: lemo1, lemo2, trg, tsm
./test_cdm.exe --writereg 4 0x99 $ # LEMO out is trg_in_pulse
./test_cdm.exe --writereg 9 0x32010 # trg and tsm from trg_pulser and tsm_pulse
./test_cdm.exe --writereg 24 1250000 # trg pulser 100 Hz
./test_cdm.exe --writereg 26 125000000 # tsm pulser 1 Hz
./test_cdm.exe --writereg 23 0x40000000 # route trg_in and tsm_in to qsfp tx bits 0 and 1
./test_cdm.exe --counters # observe counters are counting at 100 Hz and 1 Hz
on the CDM:
ssh root@cdm01
./test_cdm.exe --cdm-clocks
./test_cdm.exe --load-cc
./test_cdm.exe --reset-mgt
./test_cdm.exe --cdm-clocks
./test_cdm.exe --cdm-link # issue --reset-mgt on CDM and GDM until link is good
./test_cdm.exe --writereg 2 0xff # enable LEMO NIM inputs
./test_cdm.exe --writereg 3 0xba54 # enable LEDs: lemo1, lemo2, trg, tsm
./test_cdm.exe --writereg 4 0x99 # enable LEMO output trg_in
./test_cdm.exe --writereg 9 0x8040 # enable trg_in and tsm_in from sfp rx bits 0 and 1
./test_cdm.exe --writereg 7 0xff00 # drive VX LVDS lines to logic level 0
./test_cdm.exe --writereg 8 0x2 # VX LVDS with trg and tsm, misrouted in second VX
#./test_cdm.exe --writereg 8 0x7 # VX LVDS with tsm
./test_cdm.exe --counters # observe counters are counting at 100 Hz and 1 Hz
</pre>
switch GDM and CDM to packetizer trg and tsm:
<pre>
on the GDM:
/home/dsdaq/online/ds-dm-software/test_cdm.exe --writereg 23 0x00000000
on the CDM:
/home/dsdaq/online/ds-dm-software/test_cdm.exe --writereg 9 0x0804
/home/dsdaq/online/ds-dm-software/test_cdm.exe --counters # observe counters are counting at 100 Hz and 1 Hz
</pre>
=== Run packet loopback ===
GDM CPU -> fifo_to_fpga -> GDM QSFP -> CDM SFP -> fifo_from_fpga -> CDM CPU
On the GDM: (CDM is connected to first QSFP port)
<pre>
/home/dsdaq/online/ds-dm-software/test_cdm.exe --load-cc
/home/dsdaq/online/ds-dm-software/test_cdm.exe --reset-mgt
/home/dsdaq/online/ds-dm-software/test_cdm.exe --gdm-link
/home/dsdaq/online/ds-dm-software/test_cdm.exe --writereg 32 1 ### tell GDM to use first QSFP port
/home/dsdaq/online/ds-dm-software/test_cdm.exe --gdm-link ### confirm link status is "3"
/home/dsdaq/online/ds-dm-software/test_cdm.exe --writereg 29 2 ### enable GDM packet data injection
/home/dsdaq/online/ds-dm-software/test_cdm.exe --test-fifo-write-loop
</pre>
One the CDM:
<pre>
/home/dsdaq/online/ds-dm-software/test_cdm.exe --load-cc
/home/dsdaq/online/ds-dm-software/test_cdm.exe --reset-mgt
/home/dsdaq/online/ds-dm-software/test_cdm.exe --cdm-link
/home/dsdaq/online/ds-dm-software/test_cdm.exe --writereg 29 3 ### enable CDM packet data injection
/home/dsdaq/online/ds-dm-software/test_cdm.exe --test-fifo-read
</pre>
= dsvslice integration =
== VX setup ==
* general
** Start acq from user code = y, all others = n (as of Mar 2023: will start when first trigger received)
** Use NIM IO = y
** Use external clock = y
** LVDS quartet is input = n, y, n, y
** LVDS quartet mode = User, User, User, User
* trigger from front panel NIM:
** Trigger on external signal = y, all others = n
** connect CDM EXT_OUT(2) to VX "TrigIn"
* trigger from LVDS "Sync" mode
** Trigger on LVDS Sync signal = y, all others = n
** LVDS quartet mode = User, Sync, User, User
* trigger from LVDS "User" mode
** Trigger on LVDS pair 12 signal = y, all others = n
** LVDS quartet is input = n, y, n, y
** LVDS quartet mode = User, User, User, User
== GDM setup ==
* GDM is gdm0
* set inputs to NIM mode
* set outputs to TTL mode (this GDM has wrong NIM output circuit)
* use top QSFP slot, connect split cable 1 into CDM01, cable 2 into CDM02
* connect non-inverted NIM trigger signal to top-LEMO-left EXT_IN_LV(1)
* connect non-inverted NIM TSM signal to top-LEME-right EXT_IN_LV(2)
* GDM LEDs: TRIG, TSM, trigger enabled, trigger_out
* GDM LEMO_OUT: trigger, trigger
== CDM setup ==
* set CDM LEMO inputs to NIM
* set CDM LEMO outputs to NIM
* CDM01 is cdm0
* CDM02 is cdm1
* connect GDM fiber links to SFP port
* connect 1st VX port of CDM01 to VX1
* connect 1st VX port of CDM02 to VX2
* connect LEMO EXT_OUT(2) to VX "TrigIn", CDM01 to VX1, CDM02 to VX2
* power up
* CDM LEDs: GDM TRIG, GDM TSM, trigger enabled, trigger out
* CDM LEMO_OUT: gdm_trg, trigger
== After power up ==
* start the CDM frontend from the MIDAS "Programs" page. To start manually, see the Start Command on the Programs page.
* CDM frontend should enable the VX clock, disable the trigger
* from the MIDAS status page, goto the CDM page
* outdated: in the CDMx data tables, the 2nd number should read 0x35c08008, if it does not and the last 4 digits randomly change, reset the GDM links
*if the FEs complain - do in order: for GDM, CDM01, CDM02, ..., press "reset mgt" of each board, then press "unreset mgt", if it does not help, STOP HERE
* start a run
* CDM frontend will enable the trigger
* GDM frontend will enable the trigger
* LEDs on the GDM should flash, LEDs on the CDM should flash, TrigIn and TrigOut of the VX should flash
* stop a run
* GDM frontend will disable the trigger
* CDM frontend will disable the trigger
== Phase measurement ==
* pip3 install matplotlib
* pip3 install scipy
* export PYTHONPATH=$HOME/packages/midas/python
* #git clone https://github.com/J033X071C/PhaseMeasurement
* git clone https://bitbucket.org/team-ds-dm/phasemeasurement.git
* cd phasemeasurement
* python3 ./phaseMeasurement.py --help
<pre>
daq00:PhaseMeasurement$ python3 ./phaseMeasurement.py --help
usage: phaseMeasurement.py [-h] fileName numberEvents numberVX sizeEvents stopEvent minHist maxHist numberBin writeToTXT saveAsPDF
Read data from midas file (in .lz4 format) to calculate phase between the clock of VX1 and VX2
positional arguments:
  fileName      Name of the file we want to read data from (Example: run00389.mid.lz4)
  numberEvents  Number of events recorded in the file
  numberVX      Number of VX used in this run (usually 2...)
  sizeEvents    Number of points per event
  stopEvent    Number of events you want to go through to calculate phase
  minHist      Minimal value for the x axis of the phase measurement histogram (in ns)
  maxHist      Maximal value for the x axis of the phase measurement histogram (in ns)
  numberBin    Number of bins wanted for the generated histogram
  writeToTXT    Write argument as yes to generate text file with results of calculation
  saveAsPDF    Save generated plots to PDF files
optional arguments:
  -h, --help    show this help message and exit
daq00:PhaseMeasurement$
</pre>
* try an old file with
* python3 ./phaseMeasurement.py run00877.mid.lz4 10000 2 10000 500 -20 20 81 yes yes
<pre>
bin size = 0.494 ns
num_events =  347
mean = -1.705 ns
rms = 3.087 ns
mean_error = 0.166 ns
centroid = -1.706 ns.
width (sigma) = 0.363 ns.
error on the centroid = 0.016558 ns.
</pre>
* ls -l *.txt *.pdf
<pre>
dsdaq@dsvslice:~/online/PhaseMeasurement$ ls -l *.txt *.pdf
-rw-rw-r-- 1 dsdaq dsdaq 64728 Dec 14 16:56 run00877.mid.lz4_Plots.pdf
-rw-rw-r-- 1 dsdaq dsdaq  274 Dec 14 16:56 run00877.mid.lz4.txt
dsdaq@dsvslice:~/online/PhaseMeasurement$
</pre>
* scope settings (from email message)
<pre>
From fcote-lortie@triumf.ca  Thu Dec 15 17:11:46 2022
From: Francis Cote-Lortie <fcote-lortie@triumf.ca>
To: Konstantin Olchanski <olchansk@triumf.ca>
Subject: Re: How to use scope as a waveform generator
Date: Fri, 16 Dec 2022 01:11:44 +0000
  1.  Turn the power on (bottom left of the scope)
  2.  Access the waveform generator display by pressing the Gen button (bottom right of the scope)
  3.  The waveform generator display allows you to choose wave type (sine, square, etc.), frequency, amplitude, offset, etc. The display is a touch screen. Make the
waveform you want by using the different options.
  4.  Turn the output on (first option on the display) by pressing on the button. It will go from 0 to 1.
    The settings that we are using right now are:
      Type of waveform: Sine wave
      Offset: 0 V
      Amplitude: 1 Vpp
      Frequency: 50 kHz
      Noise: 0 V
________________________________
From: Francis Cote-Lortie <fcote-lortie@triumf.ca>
Sent: Thursday, December 15, 2022 4:58 PM
To: Konstantin Olchanski <olchansk@triumf.ca>
Subject: Re: How to use scope as a waveform generator
  1.  Turn the power on (bottom left of the scope)
  2.  Access the waveform generator display by pressing the Gen button (bottom right of the scope)
  3.  The waveform generator display allows you to choose wave type (sine, square, etc.), frequency, amplitude, offset, etc. The display is a touch screen. Make the
waveform you want by using the different options.
  4.  Turn the output on (first option on the display)
    The settings that we are using right now are:
      Type of waveform: Sine wave
      Offset: 0 V
      Amplitude: 1 Vpp
      Frequency: 50 kHz
      Noise: 0 V
________________________________
From: Francis Cote-Lortie
Sent: Thursday, December 15, 2022 4:54 PM
To: Konstantin Olchanski <olchansk@triumf.ca>
Subject: How to use scope as a waveform generator
  1.  Turn the power on (bottom left of the scope)
  2.  Access the waveform generator display by pressing the Gen button (bottom right of the scope)
  3.  The waveform generator display allows you to choose wave type (sine, square, etc.), frequency, amplitude, offset, etc. The display is a touch screen. Make the
waveform you want by using the different options.
  4.  Turn the output on (first option on the display)
</pre>
== Standalone link test ==
<pre>
CDM: program clock chip
busybox devmem 0x80011000 32 0x8
busybox devmem 0x80011000 32 0x0
/home/dsdaq/si5394-i2c-file CDM_v3.0_IN1_fixed_and_IN2_RX_Recovered_VX_62.5MHz_Si5394-RevA-Registers.txt  0 0x6b
GDM, CDM: link reset
busybox devmem 0x80011008 32 1
GDM, CDM: release reset
busybox devmem 0x80011008 32 0
CDM: link status (NOTE: SFP LOS and mod_absent are swapped!!!)
busybox devmem 0x80011010 32
0x00000024 <- fiber plugged
0x00000025 <- fiber unplugged
0x00000027 <- SFP unplugged
0x000007DC <- successful link with GDM
CDM: link state machine and data
busybox devmem 0x80011014 32
0x35C06FF6
CDM: set link to counting mode
busybox devmem 0x80012000 32 0x101
busybox devmem 0x80012000 32 0x100
CDM: time counter and error counter
root@cdm1:~# busybox devmem 0x80012000 32
0x00000100 <--- link mode
root@cdm1:~# busybox devmem 0x80012004 32
0x0000058C <--- seconds counter
root@cdm1:~# busybox devmem 0x80012004 32
0x0000058D
root@cdm1:~# busybox devmem 0x80012008 32
0x00000000 <--- error counter
GDM: no link
root@gdm0:~# busybox devmem 0x80011014 32
0x00000000
root@gdm0:~# busybox devmem 0x80011018 32
0x00000000
root@gdm0:~# busybox devmem 0x8001101c 32
0x00000000
root@gdm0:~# busybox devmem 0x80011024 32
0x00000FFF
root@gdm0:~#
GDM: good link channel 10, counting mode
root@gdm0:~# busybox devmem 0x80012000 32 0x101
root@gdm0:~# busybox devmem 0x80012000 32 0x100
root@gdm0:~# busybox devmem 0x80012008 32
0x3A8B68C2
root@gdm0:~# busybox devmem 0x80012008 32
0x42E03BEF
root@gdm0:~# busybox devmem 0x8001200c 32
0xDA090972
root@gdm0:~# busybox devmem 0x8001200c 32
0xDE6F22E9
root@gdm0:~# busybox devmem 0x80012019 32
Bus error
root@gdm0:~# busybox devmem 0x80012010 32
0xFFFFFFFF
root@gdm0:~# busybox devmem 0x80012014 32
0xFFFFFFFF
root@gdm0:~# busybox devmem 0x80012018 32
0xFFFFFFFF
root@gdm0:~# busybox devmem 0x8001201c 32
0xFFFFFFFF
root@gdm0:~# busybox devmem 0x80012020 32
0xFFFFFFFF
root@gdm0:~# busybox devmem 0x80012024 32
0xFFFFFFFF
root@gdm0:~# busybox devmem 0x80012028 32
0x00000000
root@gdm0:~# busybox devmem 0x8001202c 32
0xFFFFFFFF
root@gdm0:~# busybox devmem 0x80012030 32
0xFFFFFFFF
root@gdm0:~# busybox devmem 0x80012034 32
0xFFFFFFFF
root@gdm0:~#
</pre>
mapping of link channels:
<pre>
qsfp0 lane0 - 0x0100 - link 8
qsfp0 lane1 - 0x0200 - link 9
qsfp0 lane2 - 0x0400 - link 10
qsfp0 lane3 - n/c
qsfp1 lane0 - 0x0800 - link 11
qsfp1 lane1 - 0x0010 - link 4
qsfp1 lane2 - 0x0020 - link 5
qsfp1 lane3 - n/c
qsfp2 lane0 - 0x0040 - link 6
qsfp2 lane1 - 0x0080 - link 7
qsfp2 lane2 - 0x0001 - link 0
qsfp2 lane3 - n/c
qsfp3 lane0 - 0x0002 - link 1
qsfp3 lane1 - 0x0004 - link 2
qsfp3 lane2 - 0x0008 - link 3
qsfp3 lane3 - n/c
</pre>
script to start the test with 2 CDMs:
<pre>
ssh dsdaq@dsvslice
ssh root@gdm0 busybox devmem 0x80011008 32 1
ssh root@cdm0 busybox devmem 0x80011008 32 1
ssh root@cdm1 busybox devmem 0x80011008 32 1
ssh root@gdm0 busybox devmem 0x80011008 32 0
ssh root@cdm1 busybox devmem 0x80011008 32 0
ssh root@cdm0 busybox devmem 0x80011008 32 0
ssh root@gdm0 /home/dsdaq/online/ds-dm-software/test_cdm.exe --link-test2
ssh root@cdm0 /home/dsdaq/online/ds-dm-software/test_cdm.exe --link-test2
ssh root@cdm1 /home/dsdaq/online/ds-dm-software/test_cdm.exe --link-test2
</pre>
== LEMO trigger GDM to CDM to VX ==
on the GDM:
<pre>
/home/dsdaq/si5394-i2c-file /home/dsdaq/GDM_v1.0_IN0_EXT1_and_IN1_fixed_Si5394-RevA-Registers.txt 0 0x6b
busybox devmem 0x80011008 32 0x1
busybox devmem 0x80011008 32 0x0
/home/dsdaq/online/ds-dm-software/test_cdm.exe --writereg 23 0x80001230 # QSFP TX fixed pattern
/home/dsdaq/online/ds-dm-software/test_cdm.exe --writereg 2 0xff # enable LEMO inputs
/home/dsdaq/online/ds-dm-software/test_cdm.exe --writereg 3 0x7654 # enable LED, one per LEMO input
/home/dsdaq/online/ds-dm-software/test_cdm.exe --writereg 9 0x0F0F # enable LEMO to trg_in and tsm_in
/home/dsdaq/online/ds-dm-software/test_cdm.exe --writereg 23 0x40001230 # enable trg_in and tsm_in output to QSFP
</pre>
on the CDM:
<pre>
/home/dsdaq/si5394-i2c-file /home/dsdaq/CDM_v3.0_IN1_fixed_and_IN2_RX_Recovered_VX_62.5MHz_Si5394-RevA-Registers.txt 0 0x6b
/home/dsdaq/online/ds-dm-software/test_cdm.exe --cdm-clocks
/home/dsdaq/online/ds-dm-software/test_cdm.exe --sfp
busybox devmem 0x80011008 32 1
busybox devmem 0x80011008 32 0
/home/dsdaq/online/ds-dm-software/test_cdm.exe --cdm-link
/home/dsdaq/online/ds-dm-software/test_cdm.exe --writereg 9 0x8040 # trg_in from sfp[0], tsm_in form sfp[1]
/home/dsdaq/online/ds-dm-software/test_cdm.exe 11 # trg_in counter
/home/dsdaq/online/ds-dm-software/test_cdm.exe 12 # tsm_in counter
</pre>
== GPS receiver VCL-2705 ==
* Valiant VCL-2705 GPS receiver
* https://www.valiantcom.com/time-distribution/gps-receiver-irig-b.html
* USB connection is /dev/ttyACM0, 115200 bps, "GNSSAUX" prompt
* minicom -D /dev/ttyACM0 -b 115200
* user manual download instructoins - see sheet of paper with user name and password in the shipping box
* usb commands:
<pre>
gnss-help
gnss-showver -> F/W: Ver 1.7 Feb 17 2020 16:20:43
gnss-showselftest -> no antenna connected
Overall  : FAIL
EPROM Test: PASS
Antenna  : NOT DETECTED
GNSS      : COMMUNICATION OK
gnss-showsettings
GNSS NMEA BAUDRATE        :115200
GNSS ANTENNA LENGTH      :30 meters
GNSS USER CONFIGURED DELAY:-65 nanoseconds
GNSS 1PPS PULSE WIDTH    :200 milliseconds
GNSS MODE                :GPS
GNSS STATUS              :STATIONARY
GNSSAUX> gnss-showserial
SERIAL :2704H01V17MAX310
GNSSAUX> gnss-showmode
GNSS MODE : GPS
GNSSAUX> gnss-showstatus
GNSS STATUS: STATIONARY
GNSSAUX> gnss-showalarms
CURRENT ALARMS GNSS
ANTENNA  : NOT DETECTED
GNSSAUX> gnss-showerrors
CURRENT ALARMS GNSS
ANTENNA : **NOT DETECTED
ERROR STATISTICS GNSS
RMC GOOD DURATION  : Secs 0
RMC BAD DURATION  : Secs 0
LOCK GOOD SECS DURATION  : Secs 0
LOCK BAD SECS DURATION  : Secs 0
SATINFO GOOD ITERATIONS  :0
SATINFO REJECT ITERATIONS :0
SATINFO NOTALKER ITERATIONS  :0
CURRENT MONITOR STATE GNSS
STATE :Phase-1 HUNTING ANTENNA DETECT
GNSSAUX> gnss-showsatinfo
GNSS RECEIVER ANTENNA Not Detected !
GNSSAUX> gnss-showsats
Total Sats: 0
GNSSAUX> gnss-showmyloc
GNSS RECEIVER ANTENNA Not Detected !
GNSSAUX> gnss-show1ppsstate
GNSS RECEIVER ANTENNA Not Detected !
GNSSAUX> gnss-showjamstatus
Not Available !
GNSSAUX> gnss-showspoofstatus
Not Available !
--- antenna connected, can see the sky ---
GNSSAUX> gnss-showselftest
Overall  : PASS
EPROM Test: PASS
Antenna  : DETECTED
GNSS      : COMMUNICATION OK
GNSSAUX> gnss-showalarms
CURRENT ALARMS GNSS
ANTENNA  : DETECTED
GNSS LOCK : AVAILABLE
GNSSAUX> gnss-showerrors
CURRENT ALARMS GNSS
ANTENNA : DETECTED
GNSS LOCK : AVAILABLE
ERROR STATISTICS GNSS
RMC GOOD DURATION  : Mins 1,Secs 34
RMC BAD DURATION  : Secs 55
LOCK GOOD SECS DURATION  : Mins 1,Secs 34
LOCK BAD SECS DURATION  : Secs 55
SATINFO GOOD ITERATIONS  :3
SATINFO REJECT ITERATIONS :0
SATINFO NOTALKER ITERATIONS  :0
CURRENT MONITOR STATE GNSS
STATE :Phase-4 NORMAL OPERATION, Monitoring GNSSLOCK
GNSSAUX> gnss-showsatinfo
GNSS MODE :GPS
SATELLITE INFORMATION  TALKER:GPS
NMEA ID : 01-32
NO OF SATELLITES IN VIEW: 08
NO OF XXGSV MSGS        : 03
SatNo  PRN NO (SV ID)      ELEVATION (degs)    AZIMUTH (degs)      C/No (SNR)
1      0                  0                  0                  0                 
2      0                  0                  0                  0                 
3      0                  0                  0                  0                 
4      0                  0                  0                  0                 
5      0                  0                  0                  0                 
6      0                  0                  0                  0                 
7      0                  0                  0                  0                 
8      0                  0                  0                  0                 
<<<<<< End of Sat Info >>>>>>
GNSSAUX> gnss-showsats
Total Sats: 8
GNSSAUX> gnss-showmyloc
GNSS RECEIVER LOCATION:
Latitude : 4914.81911
Longitude: 12313.69595
GNSSAUX> gnss-show1ppsstate
GPS 1PPS STATE: LOCKED
GNSSAUX> gnss-showmyloc       
GNSS RECEIVER LOCATION:
Latitude : 4914.80688
Longitude: 12313.69531
enter into google maps search box as: 49 14.80688, -123 13.69531, observe the space, the moved dot and the minus.
GNSSAUX> gnss-resetgnss
Executing....Please Wait....
$$$$$END
</pre>
* 1PPS BNC output: period 1 sec, pulse width 200 ms, 3.3V into 1MOhm, 1.38V into 50Ohm.
* IRIG-B BNC output: 5.6V into 1MOhm, 2.4V into 50Ohm.
* IRIG-B format selector: default is all up.
== Rb clock PRS10 ==
* https://www.thinksrs.com/products/prs10.html
* 10 MHz output is sine wave around 5V peak to peak
* 1PPS BNC output is 10 usec pulse, 5V into 1MHohm.
* RS232 connection: minicom -D /dev/ttyUSB0 -b 9600
* ser2net config: localhost,3001:raw:600:usb-5-2-1.0:9600  -XONXOFF -RTSCTS LOCAL
* ssh daq13, cd /home/olchansk/git/ser2net, ./ser2net -c ~/daq/ds/ser2net.conf -d
* ssh daq13, cd ~/daq/ds, python3 prs10.py
* RS232 commands:
<pre>
ID?
PRS10_3.56_SN_105719
VB1
SN?
RS1 -- reset
ST? -- status
FC? -- 10MHz OCXO drive voltage DAC settings
DS? -- "detected signals"
GA? -- gain of frequency lock loop between ovenized oscillator and Rb cell, 0=use ovenized oscillator only
MO? -- magnetic offset of the Rb cell, range 2300..3600, if out of range, unit must be set to different operating mode, see prs10m.pdf
MR? -- magnetic read
TT? -- time-tag, time in ns between 1PPS out and 1PPS in
TS? -- time slope, ???
TO? -- time offset, ???
PS? -- pulse slope, ???
PL? -- 0=phase lock off, 1=phase lock on, lock to 1PPS input
PT? -- phase lock integrator time constant, PT8 is integrator time constant 18.2 hours, natural time constant 2.25 hours
PF? -- phase lock stability factor, PF2 is "1"
PI? -- phase lock integrator
Analog to digital 12 bit ADC, values 0.000 to 4.998
AD0? -- Spare (J204)
AD1? -- +24V(heater supply) divided by 10.
AD2? -- +24V(electronics supply) divided by 10
AD3? -- Drain voltage to lamp FET divided by 10
AD4? -- Gate voltage to lamp FET divided by 10
AD5? -- Crystal heater control voltage
AD6? -- Resonance cell heater control voltage
AD7? -- Discharge lamp heater control voltage
AD8? -- Amplified ac photosignal
AD9? -- Photocell’s I/V converter voltage divided by 4
AD10? -- Case temperature (10 mV/°C)
AD11? -- Crystal thermistors
AD12? -- Cell thermistors
AD13? -- Lamp thermistors
AD14? -- Frequency calibration pot / external calibration voltage
AD15? -- Analog ground
A/D via CPU E-port:
AD16? -- Varactor voltage for 22.48 MHz VCXO (inside RF synthesizer) / 4
AD17? -- Varactor voltage for 360 MHz VCO (output of RF synthesizer) / 4
AD18? -- Gain control voltage for amplifier which drives frequency multiplier / 4
AD19? -- RF synthesizer’s lock indicator voltage (nominally 4.8 V when locked )
ST?
ST1 : Power supplies and Discharge Lamp
ST1 bit, Condition which sets bit, Corrective Action
0 -- +24 for electronic < +22 Vdc
1 -- +24 for electronics > +30 Vdc
2 -- +24 for heaters <+22 Vdc
3 -- +24 for heaters > +30 Vdc
4 -- Lamp light level too low
5 -- Lamp light level too high
6 -- Gate voltage too low
7 -- Gate voltage too high
ST2: RF Synthesizer
ST2 bit, Condition which sets bit, Corrective Action
0 -- RF synthesizer PLL unlocked
1 -- RF crystal varactor too low
2 -- RF crystal varactor too high
3 -- RF VCO control too low
4 -- RF VCO control too high
5 -- RF AGC control too low
6 -- RF AGC control too high
7 -- Bad PLL parameter
ST3: Temperature Controllers
ST3 bit, Condition which sets bit
0 -- Lamp temp below set point
1 -- Lamp temp above set point
2 -- Crystal temp below set point
3 -- Crystal temp above set point
4 -- Cell temp below set point
5 -- Cell temp above set point
6 -- Case temperature too low
7 -- Case temperature too high
ST4: Frequency Lock-Loop Control
ST4 bit, Condition which sets bit
0 -- Frequency lock control is off
1 -- Frequency lock is disabled
2 -- 10 MHz EFC is too high
3 -- 10 MHz EFC is too low
4 -- Analog cal voltage > 4.9 V
5 -- Analog cal voltage < 0.1
6 -- not used
7 -- not used
ST5: Frequency Lock to External 1pps
ST5 bit, Condition which sets bit
0 -- PLL disabled
1 -- < 256 good 1pps inputs
2 -- PLL active
3 -- > 256 bad 1pps inputs
4 -- Excessive time interval
5 -- PLL restarted
6 -- f control saturated
7 -- No 1pps input
ST6: System Level Events
ST6 bit and Condition which sets bit
0 Lamp restart
1 Watchdog time-out and reset
2 Bad interrupt vector
3 EEPROM write failure
4 EEPROM data corruption
5 Bad command syntax
6 Bad command parameter
7 Unit has been reset
</pre>
* ST? on warm start
<pre>
received:  PRS_10
received:  255,255,255,243,34,255
received:  0,0,0,1,34,0
...
received:  0,0,0,1,34,0
received:  0,0,0,0,2,0
...
received:  0,0,0,0,2,0
received:  0,0,0,0,4,0
</pre>
* ST? on loss of external 1PPS
<pre>
...
received:  0,0,0,0,4,0
disconnect 1PPS input
received:  0,0,0,0,132,0
...
reconnect 1PPS input
received:  0,0,0,0,132,0
received:  0,0,0,0,4,0
...
</pre>
* ST? on coldish start
<pre>
daq13:ds$ python3 prs10.py
Connected
received [  ] old [ b'' ] counter:  0
received [ PRS_10 ] old [  ] counter:  0
received [ 255,255,255,243,34,255 ] old [ PRS_10 ] counter:  0
received [ 80,0,0,1,34,1 ] old [ 255,255,255,243,34,255 ] counter:  0
received [ 0,0,1,1,34,0 ] old [ 80,0,0,1,34,1 ] counter:  0
received [ 0,0,0,1,34,0 ] old [ 0,0,1,1,34,0 ] counter:  0
received [ 0,0,16,1,34,0 ] old [ 0,0,0,1,34,0 ] counter:  6
received [ 0,0,20,1,34,0 ] old [ 0,0,16,1,34,0 ] counter:  5
received [ 0,0,4,1,34,0 ] old [ 0,0,20,1,34,0 ] counter:  8
received [ 0,0,0,1,34,0 ] old [ 0,0,4,1,34,0 ] counter:  3
received [ 0,0,0,0,2,0 ] old [ 0,0,0,1,34,0 ] counter:  49
received [ 0,0,0,0,4,0 ] old [ 0,0,0,0,2,0 ] counter:  250
...
</pre>
* ST? on cold start, note: no bump in the 10MHz clock as reported by DS-DM clock chip
<pre>
Connected
received [  ] old [ b'' ] counter:  0
received [ PRS_10 ] old [  ] counter:  0
received [ 255,255,255,243,34,255 ] old [ PRS_10 ] counter:  0
received [ 80,0,21,1,34,1 ] old [ 255,255,255,243,34,255 ] counter:  0
received [ 64,0,21,1,34,0 ] old [ 80,0,21,1,34,1 ] counter:  0
received [ 0,0,21,1,34,0 ] old [ 64,0,21,1,34,0 ] counter:  0
received [ 0,0,20,1,34,0 ] old [ 0,0,21,1,34,0 ] counter:  158
received [ 0,0,4,1,34,0 ] old [ 0,0,20,1,34,0 ] counter:  23
received [ 0,0,0,1,34,0 ] old [ 0,0,4,1,34,0 ] counter:  47
received [ 0,0,0,0,2,0 ] old [ 0,0,0,1,34,0 ] counter:  40
received [ 0,0,0,0,4,0 ] old [ 0,0,0,0,2,0 ] counter:  249
</pre>
= det fac integration test =
Connections:
* GPS receiver "IRIG-B SEL" both switches "up" - both "on", IRIG-B format B004
* GPS receiver USB-B -> long cable -> daq13 USB-A
* GPS receiver "1PPS out" -> long BNC cable -> BNC-T -> scope (5V, no 50ohm) and Rb clock BNC "1PPS in"
* GPS receiver "IRIG-B 50ohms" -> long BNC cable -> BNC-T -> scope (5V, no 50ohm) and DS-DM LEMO input 1 (TTL mode)
* Rb clock RS232 -> RS232 straight cable -> RS232-to-USB adapter -> daq13 USB-A
* Rb clock "1PPS out" BNC -> scope (5V, no 50ohm, trig threshold rising edge 2V)
* Rb clock "10MHz output 50 Ohm" BNC -> lemo -> lemo-T -> scope (sine wave, 5V, no 50ohm) and DS-DM clock input.
Programs to run:
* on daq13: cd /home/olchansk/git/ser2net, ./ser2net -c ~/daq/ds/ser2net.conf -d
<pre>
localhost,3001:raw:600:usb-5-2-1.0:9600  -XONXOFF -RTSCTS LOCAL
</pre>
* on daq13: cd /home/olchansk/daq/ds, python3 prs10.py ### connects to ser2net
<pre>
daq13:ds$ python3 prs10.py
Connected
received [  ] old [ b'' ] counter:  0
received [ PRS_10 ] old [  ] counter:  0
received [ 255,255,255,243,34,255 ] old [ PRS_10 ] counter:  0
received [ 80,0,21,1,34,1 ] old [ 255,255,255,243,34,255 ] counter:  0
received [ 64,0,21,1,34,0 ] old [ 80,0,21,1,34,1 ] counter:  0
received [ 0,0,21,1,34,0 ] old [ 64,0,21,1,34,0 ] counter:  0
received [ 0,0,20,1,34,0 ] old [ 0,0,21,1,34,0 ] counter:  158
received [ 0,0,4,1,34,0 ] old [ 0,0,20,1,34,0 ] counter:  23
received [ 0,0,0,1,34,0 ] old [ 0,0,4,1,34,0 ] counter:  47
received [ 0,0,0,0,2,0 ] old [ 0,0,0,1,34,0 ] counter:  40
received [ 0,0,0,0,4,0 ] old [ 0,0,0,0,2,0 ] counter:  249
received [ 0,0,0,0,132,0 ] old [ 0,0,0,0,4,0 ] counter:  12096
received [ 0,0,0,0,20,0 ] old [ 0,0,0,0,132,0 ] counter:  2
received [ 0,0,0,0,148,0 ] old [ 0,0,0,0,20,0 ] counter:  0
received [ 0,0,0,0,4,0 ] old [ 0,0,0,0,148,0 ] counter:  575
received [ 0,0,0,0,132,0 ] old [ 0,0,0,0,4,0 ] counter:  11449
received [ 0,0,0,0,4,0 ] old [ 0,0,0,0,132,0 ] counter:  0
received [ 0,0,0,0,132,0 ] old [ 0,0,0,0,4,0 ] counter:  2755
received [ 0,0,0,0,4,0 ] old [ 0,0,0,0,132,0 ] counter:  0
received [ 0,0,0,0,132,0 ] old [ 0,0,0,0,4,0 ] counter:  34386
received [ 0,0,0,0,4,0 ] old [ 0,0,0,0,132,0 ] counter:  0
received [ 0,0,0,0,132,0 ] old [ 0,0,0,0,4,0 ] counter:  41035
received [ 0,0,0,0,4,0 ] old [ 0,0,0,0,132,0 ] counter:  0
received [ 0,0,0,0,132,0 ] old [ 0,0,0,0,4,0 ] counter:  113401
received [ 0,0,0,0,4,0 ] old [ 0,0,0,0,132,0 ] counter:  0
received [ 0,0,0,0,132,0 ] old [ 0,0,0,0,4,0 ] counter:  33375
received [ 0,0,0,0,4,0 ] old [ 0,0,0,0,132,0 ] counter:  0
received [ 0,0,0,0,132,0 ] old [ 0,0,0,0,4,0 ] counter:  54767
received [ 0,0,0,0,4,0 ] old [ 0,0,0,0,132,0 ] counter:  0
received [ 0,0,0,0,132,0 ] old [ 0,0,0,0,4,0 ] counter:  85059
received [ 0,0,0,0,4,0 ] old [ 0,0,0,0,132,0 ] counter:  0
received [ 0,0,0,0,132,0 ] old [ 0,0,0,0,4,0 ] counter:  33222
received [ 0,0,0,0,4,0 ] old [ 0,0,0,0,132,0 ] counter:  0
received [ 0,0,0,0,132,0 ] old [ 0,0,0,0,4,0 ] counter:  119234
received [ 0,0,0,0,4,0 ] old [ 0,0,0,0,132,0 ] counter:  0
received [ 0,0,0,0,132,0 ] old [ 0,0,0,0,4,0 ] counter:  121990
received [ 0,0,0,0,4,0 ] old [ 0,0,0,0,132,0 ] counter:  0
received [ 0,0,0,0,132,0 ] old [ 0,0,0,0,4,0 ] counter:  128184
received [ 0,0,0,0,4,0 ] old [ 0,0,0,0,132,0 ] counter:  0
received [ 0,0,0,0,132,0 ] old [ 0,0,0,0,4,0 ] counter:  56002
received [ 0,0,0,0,4,0 ] old [ 0,0,0,0,132,0 ] counter:  0
received [ 0,0,0,0,132,0 ] old [ 0,0,0,0,4,0 ] counter:  428237
received [ 0,0,0,0,4,0 ] old [ 0,0,0,0,132,0 ] counter:  0
received [ 0,0,0,0,132,0 ] old [ 0,0,0,0,4,0 ] counter:  8250
received [ 0,0,0,0,4,0 ] old [ 0,0,0,0,132,0 ] counter:  0
received [ 0,0,0,0,132,0 ] old [ 0,0,0,0,4,0 ] counter:  1388
received [ 0,0,0,0,4,0 ] old [ 0,0,0,0,132,0 ] counter:  0
received [ 0,0,0,0,132,0 ] old [ 0,0,0,0,4,0 ] counter:  30506
received [ 0,0,0,0,4,0 ] old [ 0,0,0,0,132,0 ] counter:  0
received [ 0,0,0,0,132,0 ] old [ 0,0,0,0,4,0 ] counter:  142704
received [ 0,0,0,0,4,0 ] old [ 0,0,0,0,132,0 ] counter:  0
received [ 0,0,0,0,132,0 ] old [ 0,0,0,0,4,0 ] counter:  179451
received [ 0,0,0,0,4,0 ] old [ 0,0,0,0,132,0 ] counter:  0
received [ 0,0,0,0,132,0 ] old [ 0,0,0,0,4,0 ] counter:  106182
received [ 0,0,0,0,4,0 ] old [ 0,0,0,0,132,0 ] counter:  0
received [ 0,0,0,0,132,0 ] old [ 0,0,0,0,4,0 ] counter:  68747
received [ 0,0,0,0,4,0 ] old [ 0,0,0,0,132,0 ] counter:  0
received [ 0,0,0,0,132,0 ] old [ 0,0,0,0,4,0 ] counter:  65424
received [ 0,0,0,0,4,0 ] old [ 0,0,0,0,132,0 ] counter:  0
received [ 0,0,0,0,132,0 ] old [ 0,0,0,0,4,0 ] counter:  157587
received [ 0,0,0,0,4,0 ] old [ 0,0,0,0,132,0 ] counter:  0
received [ 0,0,0,0,132,0 ] old [ 0,0,0,0,4,0 ] counter:  6932
received [ 0,0,0,0,4,0 ] old [ 0,0,0,0,132,0 ] counter:  0
received [ 0,0,0,0,132,0 ] old [ 0,0,0,0,4,0 ] counter:  1388
received [ 0,0,0,0,4,0 ] old [ 0,0,0,0,132,0 ] counter:  0
received [ 0,0,0,0,132,0 ] old [ 0,0,0,0,4,0 ] counter:  20255
received [ 0,0,0,0,4,0 ] old [ 0,0,0,0,132,0 ] counter:  0
received [ 0,0,0,0,132,0 ] old [ 0,0,0,0,4,0 ] counter:  4
received [ 0,0,0,0,4,0 ] old [ 0,0,0,0,132,0 ] counter:  0
received [ 0,0,0,0,132,0 ] old [ 0,0,0,0,4,0 ] counter:  225941
received [ 0,0,0,0,4,0 ] old [ 0,0,0,0,132,0 ] counter:  0
received [ 0,0,0,0,132,0 ] old [ 0,0,0,0,4,0 ] counter:  72183
received [ 0,0,0,0,4,0 ] old [ 0,0,0,0,132,0 ] counter:  0
received [ 0,0,0,0,132,0 ] old [ 0,0,0,0,4,0 ] counter:  26970
received [ 0,0,0,0,4,0 ] old [ 0,0,0,0,132,0 ] counter:  1
39287
</pre>
* on ds-dm: ./test_cdm.exe --irigb ### note sbs mismatch is because I should wrap around at 16 bits
<pre>
dataframe: S00000000S100001010S...S001010101S000001000S, sec: 00, min: 51, hrs: 22, day of year: 300, year: 2023, date: 27 oct, sbs: 16724 should be 82260
dataframe: S10000000S100001010S...S101010101S000001000S, sec: 01, min: 51, hrs: 22, day of year: 300, year: 2023, date: 27 oct, sbs: 16725 should be 82261
dataframe: S01000000S100001010S...S011010101S000001000S, sec: 02, min: 51, hrs: 22, day of year: 300, year: 2023, date: 27 oct, sbs: 16726 should be 82262
dataframe: S11000000S100001010S...S111010101S000001000S, sec: 03, min: 51, hrs: 22, day of year: 300, year: 2023, date: 27 oct, sbs: 16727 should be 82263
dataframe: S00100000S100001010S...S000110101S000001000S, sec: 04, min: 51, hrs: 22, day of year: 300, year: 2023, date: 27 oct, sbs: 16728 should be 82264
dataframe: S10100000S100001010S...S100110101S000001000S, sec: 05, min: 51, hrs: 22, day of year: 300, year: 2023, date: 27 oct, sbs: 16729 should be 82265
</pre>
= DS-IOGC GPS interface board =
* Rev0 git repository: https://edev-group.triumf.ca/hw/exp/dark-side-20k/dark-side-iogc/rev0/-/tree/main?ref_type=heads
* Rev0 schematics: https://edev-group.triumf.ca/hw/exp/dark-side-20k/dark-side-iogc/rev0/-/blob/main/Altium/Project%20Outputs%20for%20DS-IOGC-Rev0/SCH-DS-IOGC-Rev0.pdf?ref_type=heads
* Rev0 schematics: [[:Image:SCH-DS-IOGC-Rev0.pdf|SCH-DS-IOGC-Rev0]]
* Rev1 git repository: https://edev-group.triumf.ca/hw/exp/dark-side-20k/dark-side-iogc/rev1/
* Rev1 schematics: [[:Image:SCH-DS-IOGC-Rev1.pdf|SCH-DS-IOGC-Rev1]]
== Changes Rev0 to Rev1 ==
<pre>
From: Peter Margetak <pmargetak@triumf.ca>
Subject: IOGC REV1 review
Date: Wed, 4 Sep 2024 07:31:19 +0000
Hi Konstantin,
Pls have a look at SCH for new rev. I'd like to send it to mfr next week so if you can comment by early next week. Meanwhile I work on layout and other stuff.
Changes:
New ICs - all powered +5V
U20 - inverters for  RUclk RX/TX
U21 - non inverting line driver for RU-1pps-out (so you don't have to route if via GDM to see it on scope)
U22 - non inverting buffer for ext 1pps input
All Lemo connectors have the same position but they are double lemos now => new panel needed
@Marek Walczak<mailto:mwalczak@triumf.ca> you can print it ahead once pcb is done + update IOGC docs and panel description
J2A/B - Test ports for RU-1pps in and out
J5A/B - inputs for external GPS data and External source of 1pps
J6A/B  - aux in/out for GDM
SW1 - no change - select RX/TX  USB/GDM
SW2 - select latch sensitivity for rising/falling edge
SW3 - select source of GPS data (opto or ext)  AND select source of 1pps input (latch or ext)
p.
</pre>
== PRS-10 Rb clock device ==
The Rb clock PRS-10 device provides these connections:
<pre>
RS232 RX input - serial communication, non-standard RS232
RS232 TX output - serial communication, non-standard RS232
10 MHz clock output - coax 50 Ohm high resolution 10 MHz clock
1pps output - 1 Hz clock corresponding to the 10 MHz clock
1pps input - 1pps signal from GPS receiver
</pre>
Mode of operation:
* 10 MHz clock is always running
* 1pps output is always running
* if 1pps input from GPS received is present, after 256 pulses PRS-10 will sync it's 1pps output with the 1pps input by adjusting the frequency of the 10 MHz clock
* when unlocked: 1pps output and 1pps input unrelated
* when locked to GPS: 1pps output and 1pps input always go up and down at the same time
Theory of operation:
* 10 MHz clock is produced by a high-quality crystal (stable on the scale of seconds)
* crystal oscillator is synchronized to a Rb cell (stable on the scale of hours and days)
* Rb cell resonant frequency is synchronized to the GPS 1pps signal (stable on the scale of months and years)
== Rev1 connections ==
* LEMO connectors (front panel)
<pre>
LEMO J2A output - Rb clock 1pps in monitor
LEMO J2B output - Rb clock 1pps out monitor
LEMO J5A input  - GPS IRIG-B from GPS receiver to FPGA (VCL-2705)
LEMO J5B input  - GPS 1pps from GPS receiver to PRS-10 (VCL-2705)
LEMO J6A output - AUX-OUT from FPGA (dual-LEMO PCB-side)
LEMO J6B input  - AUX-IN to FPGA (dual-LEMO away-from -PCB)
</pre>
* SMB connectors (back)
<pre>
SMB J3 output - GPS 1pps loopback to LNGS
SMB J4 input - LNGS GPS data input
</pre>
* LEDs
<pre>
D1 - same as LEMO J2A out (Rb clock 1pps in)
D2 - same as SMB J3 out (GPS 1pps from LNGS or from a GPS receiver)
D5 - controlled by FPGA-OUT-LED1
D6 - controlled by FPGA-OUT-LED2
D7 - PRS-10 24V power ok
</pre>
* switches
<pre>
SW1A and SW1B - route PRS-10 RS232 to USB or to FPGA
SW2A - route PRS-10 1pps input from SMB J4 (LNGS) or from LEMO J5B (GPS receiver 1pps)
SW2B - route FPGA-IN-GPSDATA input from SMB J4 (LNGS) or from LEMO J5A (GPS receiver IRIG-B data)
SW3 - LNGS 1pps from rising edge or from falling edge of SMB J4 (LNGS)
</pre>
== Rb clock cable ==
<pre>
Rb clock ----- DS-IOGC side, pin numbers are as labeled on the cable connectors
1 - 1pps out - 8 - 1pps out                    --- correct
2 - nc
3 - nc
4 - TXD      - 3  - RU-DATA-OUT - USB-RX input --- correct
5 - 1pps in  - 2  - 1pps in                    --- correct
6 - +24V    - 10 - +24V                      --- should by pin 1 to use both +24V pins?
7 - RXD      - 15 - RU-DATA-IN - USB-TX output --- correct
8 - nc
9 - +24V    - 10 - +24V --- correct
10 - GND    - 9  - GND  --- correct
</pre>
== VX connections ==
<pre>
VXA_TX0 - FPGA-OUT-LED2 - D6 LED ("10 MHz clock")
VXA_TX1 - FPGA-OUT-LED1 - D5 LED ("GPS DATA")
VXA_TX2 - FPGA-OUT-RU1PPS-EN - enable 1pps to Rb clock
VXA_TX3 - not used (62.5 Hz clock)
VXB_TX0 - FPGA-TX - PRS-10 RS-232 out
VXB_TX1 - FPGA-OUT-AUX - 5V TTL J5 LEMO out
VXB_TX2 - FPGA-OUT-OPTO1PPS-EN - PRS-10 power enable
VXB_TX3 - not used (62.5 MHz clock)
VXA_RX0 - FPGA-IN-OPTO1PPS - 1pps from GPS
VXA_RX1 - FPGA-IN-GPSDATA - J4 GPS data
VXA_RX2 - n/c
VXA_RX3 - n/c
VXB_RX0 - n/c
VXB_RX1 - FPGA-IN-AUX - J5 LEMO TTL input
VXB_RX2 - FPGA-RX - PRS-10 RS-232 in
VXB_RX3 - FPGA-IN_RU1PPS - PRS-10 1pps output
</pre>
== test sequence ==
* ./test_cdm_local.exe --writereg 7 0 ### clear reg 7
* ./test_cdm_local.exe --writereg 8 0 ### set vx_tx mux to vx_tx control from reg 7
* connect blue cable to GDM port 6 (next to the ethernet connector)
* ./test_cdm_local.exe --writereg 7 0x4000 ### power up
* test LEDs:
* ./test_cdm_local.exe --writereg 7 0x4100 ### right LED D6
* ./test_cdm_local.exe --writereg 7 0x4200 ### left LED D5
* test AUX-IN and AUX-OUT:
* ./test_cdm_local.exe --writereg 7 0x6000 ### J6A LEMO (PCB-side) measure +5VDC
* install LEMO jumper between LEMO J6A and J6B
* write 0x4000 then ./test_cdm_local.exe 6 ### reads 0x5C, bit 5 0x20 reads 0
* write 0x6000 then ./test_cdm_local.exe 6 ### reads 0x7C, bit 5 0x20 reads 1
* write 0x4000 to clear all bits
* test the 10 MHz clock:
* init the c.c: ./test_cdm_local.exe --load-cc
* connect 10 MHz clock output to DS-DM LEMO J6-LEFT (CLK_EXT1)
* 10 MHz output ok - IN0 is good: ./test_cdm_local.exe --cc
<pre>
Clock chip state 1, status:  OOF_IN2 IN1 IN_SEL_1 HOLD_HIST_VALID
</pre>
* without 10 MHz reports IN0 LOS (no signal) and OOF (wrong frequency)
<pre>
Clock chip state 1, status:  LOS_IN0 OOF_IN0 OOF_IN2 IN1 IN_SEL_1 HOLD_HIST_VALID
</pre>
* test GPS IRIG-B data:
* connect GPS IRIG-B signal to J6B (dual-LEMO away from PCB)
* IRIG-B via AUX-IN is ok: ./test_cdm_local.exe --irigb
<pre>
dataframe: S00100110S111001000S...S011110000S010000000S, sec: 34, min: 17, hrs: 00, day of year: 223, year: 2024, date: 10 aug, sbs:  1054 should be  1054
</pre>
* test GPS 1pps signal:
* connect GPS 1pps to J5B (dual-LEMO away from PCB)
* ./test_cdm_local.exe --writereg 8 9 ### set vx_tx mux to GPS control, hard enables PRS-10 power and PRS-10 1pps in
* observe 1pps counters in reg 68 count at 1 Hz: rb_1pps 0x51->0x52, gps_1pps 0xd5->oxd6
<pre>
root@dsdm:~# ./test_cdm_local.exe 68
ds20k_reg[68] is 0x0051d520 (5362976)
ds20k_reg[68] is 0x0052d624 (5428772)
...
</pre>
* observe PRS-10 can see the 1pps signal "130" changes to "2" after 243 seconds to "4"
* observe period of GPS and PRS-10 1pps is identical (plus/minus 1 clock)
<pre>
root@dsdm:~# ./test_cdm_local.exe 13 14
ds20k_reg[13] is 0x077356d4 (124999380)
ds20k_reg[14] is 0x077356d4 (124999380)
</pre>
* observe GDM/CDM clocks are exactly 125 MHz, we are running on DS-DM internal oscillator
<pre>
root@dsdm:~# ./test_cdm_local.exe --gdm-clocks
GDM clock frequency counters:
0x1030 mgt_rx_ref_clk_raw: 0x07735943 (125000003) should be ~125 MHz
0x1034 rx_clk:            0x07735943 (125000003) should be ~125 MHz
0x1038 mgt_tx_ref_clk_raw: 0x07735943 (125000003) should be ~125 MHz
0x103C tx_clk:            0x07735943 (125000003) should be ~125 MHz
0x1040 clk_50MHz:          0x02faf080 (50000000) should be 50 MHz exactly
0x1044 Block1_clk:        0x05f5e100 (100000000) should be 100 MHz exactly
</pre>
* switch CC to external clock:
<pre>
root@dsdm:~# ./test_cdm_local.exe --cc-in0
CC use clock input 0: 10 MHz LEMO external clock
root@dsdm:~# ./test_cdm_local.exe --cc
Polling CC status...
Clock chip state 1, status:  IN0 IN_SEL_REGCTRL IN_SEL_0 HOLD_HIST_VALID
</pre>
* observe rx_clk and tx_clk are now slightly off: they run from PRS-10 10 MHz clock and are measured against the DS-DM internal oscillator.
<pre>
root@dsdm:~# ./test_cdm_local.exe --gdm-clocks
DS-DM mapping /dev/mem at 0x80010000
DS-DM FPGA firmware build 0x94b12519, ds20k version 0x20240814
DS-DM firmware build 0x94b12519, ds20k version 0x20240814
GDM clock frequency counters:
0x1030 mgt_rx_ref_clk_raw: 0x077358e1 (124999905) should be ~125 MHz
0x1034 rx_clk:            0x07735b49 (125000521) should be ~125 MHz
0x1038 mgt_tx_ref_clk_raw: 0x07735b49 (125000521) should be ~125 MHz
0x103C tx_clk:            0x07735b49 (125000521) should be ~125 MHz
0x1040 clk_50MHz:          0x02faf080 (50000000) should be 50 MHz exactly
0x1044 Block1_clk:        0x05f5e100 (100000000) should be 100 MHz exactly
</pre>
* observe GPS and PRS-10 1pps period is now exactly 125*10^6 of 8ns clocks  (equal to 1 second)
<pre>
root@dsdm:~# ./test_cdm_local.exe 13 14
ds20k_reg[13] is 0x0773593f (124999999)
ds20k_reg[14] is 0x0773593f (124999999)
</pre>
* look at them repeatedly, observe reg 13 "GPS 1pps period" has some wobble, reg 14 "Rb clock 1pps period" is steady. this is as expected: if GPS 1pps was steady, we do not need to Rb clock. PRS-10 1pps is derived from the PRS-10 10 MHz clock and is measured against the 125 MHz clock derived from the same 10 MHz clock in the GDM FPGA.
Rev0 Test status:
* GPS 1pps to SMB-in ok (LED flashes)
* GPS 1pps to FPGA ok
* GPS data to FPGA ok
* GPS 1pps to PRS-10 enabled from FPGA ok
* PRS-10 Rb clock 1pps out to FPGA ok
* PRS-10 Rb clock 1pps out to FPGA to LEMO AUX out ok
* can see GPS 1pps, IRIG-B, PRS-10 1pps out, 10 MHz on the scope, ok
* PRS-10 syncs on leading edge (0->1) of GPS 1pps signal, ok
* reg 13 and 14 1pps periods are identical, ok
* CC locks on PRS-10 10 MHz clock, DS-DM runs on PRS-10 clock, ok
* NOT TESTED - smb output
* NOT TESTED - optical converter fiber to SMB
* NOT TESTED - optical converter SMB to fiber
* NOT TESTED - SMB loopback
* NOT TESTED - fiber loopback
Rev1 Test status: (21 Nov 2024)
* power up ok
* LEDs ok
* LEMO AUX-IN, AUX-out ok
* GPS IRIG-B to FPGA via AUX-IN ok
* PRS-10 Rb clock 1pps out to FPGA ok
* PRS-10 Rb clock 10 MHz to C.C. ok
* PRS-10 RS-232 ok
= VX busy logic =


= DS-20K DAQ =
= DS-20K DAQ =

Latest revision as of 17:08, 21 November 2024

DS-DM

DarkSide-20k Global and Crate Data Manager board (GDM and CDM).

Global Data Manager (GDM):

  • clock distribution to CDM boards (including GPS/atomic clock source)
  • collection of trigger data from CDM boards, processing and distribution of trigger decision to CDM boards
  • run control
  • integration with GPS 10MHz and 1pps clocks and GPS/IRIG date and time information

Crate Data Manager (CDM):

  • clock distribution from GDM to CAEN VX digitizers
  • receive trigger data from CAEN VX digitizers
  • send trigger data to GDM
  • run control and dead time control

Links

Onboard hardware

  • jtag chain: arm_dap_0 0x5BA00477, xczu4_1 0x04721093
  • Eclustra Mercury+ XU8 module: ME-XU8-4CG-1E-D11E-R2.1
    • Xilinx® Zynq Ultrascale+™ MPSoC XCZU4CG-1FBVB900E
    • DDR4 ECC SDRAM (PS) 2 GB
    • DDR4 SDRAM (PL) 1GB
  • ethernet mac chip: AT24MAC402-SSHM-T ("602" chip is wrong)
  • USB UART for Enclustra serial console, micro-USB, 115200n8
  • clock chip: SI5394A-A-GM and oscillator CS-044-054.0M (54 MHz)
  • U23 3.3V current meter and thermometer, LTC2990IMS#TRPBF
  • LEDs:
    • LED_FP A/B/C/D 0/1/2/3
    • led1 - 3V3_SW_ON, SOM_POWER_GOOD - Enclustra FPGA module 3.3V power is good
    • led2 - LTM4624 PGOOD
    • led3 - FPGA_DONE - FPGA has booted
    • led4 - TP-S-1, PCLK_P
    • led5 - TP-S-2, PCLK_N
  • LEMO connectors (top to bottom)
    • J4 - input (NIM/TTL) (EXT_IN_LV(1), EXT_IN_LV(2))
    • J5 - input (NIM/TTL) (EXT_IN_LV(3), EXT_IN_LV(4))
    • J6 - external clock (GPS 10MHz and PPS)
    • J7 - output (NIM/TTL) (EXT_OUT(1), EXT_OUT(2))
  • SMA connectors
    • J9, J10 - CLK_CCA from U6 C.C.
    • J11, J12 - CLK_TP0
  • RJ45 ethernet connector (100mbit: green light on, yellow light flashes when there is traffic)
  • SFP connector (SFP is FTLF8526P3BNL, 6 Gbit/sec, 850 nm, 300m 50/125um OM3 MMF)
  • 4 QSFP connectors (GDM)
  • 6 VX connectors (CDM)

Buttons, jumpers and switches

Buttons:

  • PB1 - HRST - reboot FPGA (power-on reset)
  • PB2 - SRST - (SRSTn) - reboot ARM CPU

Switches:

  • SW1 - boot mode BM0, BM1 [-->]
  • SW2 - LEMO output NIM<->TTL
  • SW3 - LEMO input 1 and 2 NIM/TTL
  • SW4 - LEMO input 2 and 4 NIM/TTL
  • SW5 - LEMO clock input NIM/TTL
  • SW6 - serial console select. [PS<--PL] PS is ARM CPU, PL is FPGA.

Front panel

| top
|
| LED-FP1 | LED_FP(0,1,2,3)
|
| SFP J???
|
| LEMO J4-LEFT, J4-RIGHT | EXT_IN_LV(1), EXT_IN_LV(2)
| LEMO J5-LEFT, J5-RIGHT | EXT_IN_LV(3), EXT_IN_LV(4)
| LEMO J6-LEFT, J6-RIGHT | CLK_EXT1, CLK_EXT0 (125 MHz only) 
| LEMO J7-LEFT, J7-RIGHT | EXT_OUT(1), EXT_OUT(2)
|
| J-VX-1
| J-VX-2 or QSFP-1
| J-VX-3 or QSFP-2
| J-VX-4 or QSFP-3
| J-VX-5 or QSFP-4
| J-VX-6
|
| RJ45 J3 ethernet
|
| bottom

VX adapter board

LVDS I/O connector

34 pin connector: 0|:::: :::: :::: :::: :|15,16 n/c

split-cable connection

0 .. 7 -> N/C

8 -> VX_RX(3) - not used
9 -> VX_RX(2) - busy VX to CDM
10 -> VX_RX(1) - DS20K 125 MHz serial data VX to CDM
11 -> VX_RX(0) - DS20K 62.5MHz clock VX to CDM

12 <- VX_TX(0) - TRG CDM to VX
13 <- VX_TX(1) - TSM CDM to VX, to be VETO CDM to VX
14 <- VX_TX(2) (set by jumper routed here or to VX CLKIN SYNC) - 125 MHz serial data CDM to VX
15 <- n/c (CLK routed to VX CLKIN CLK) - 62.5 MHz clock CDM to VX

16 - n/c

one-to-one connection

0 -> VX2_RX(3)
1 -> VX2_RX(2)
2 -> VX2_RX(0)
3 -> VX2_RX(1)

4 <- CLK
5 <- VX2_TX(0)
6 <- VX2_TX(1)
7 <- VX2_TX(2)

8 -> VX1_RX(3)
9 -> VX1_RX(2)
10 -> VX1_RX(1)
11 -> VX1_RX(0)

12 <- VX1_TX(0)
13 <- VX1_TX(1)
14 <- VX1_TX(2) (set by jumper routed here or to VX CLKIN SYNC)
15 <- n/c (CLK routed to VX CLKIN CLK)

16 - n/c

Board schematics

  • File:SCH-DS-xDM-Rev0.PDF
  • note: FPGA pin annotations ("IO", "SCLK", "PCLK", etc) on the schematics are bogus, instead, trace them to the FPGA pins.
  • note: ENC A is J800, ENC B is J801, ENC C is J900 (schematic name to enclustra name)
  • note: Enclustra special pins: "GC" is "clock capable", "HDGC" is "clock capable", "MGTREFCLK" is MGT reference clocks.
  • board modifications:
    • ethernet mac chip
    • NIM output (no U15, etc)
    • RJ45 wrong pinout (board mod or special ethernet cable)
    • 125 MHz clock mods (TBW)
    • disconnect QSFP0_SEL from SFP_RS0 and QSFP1_SEL from SFP_RS1, these signals are not used by modern SFPs
    • provide SFP i2c modsel to allow SFP and QSFP at the same time on address 0x50

FPGA MGT blocks

* SFP - ENC B45,B47 and B48,B50 - FPGA D5,D6 MGTHTX0_D and D1,D2 MGTHRX0_D
* QSFP0 TX0 - ENC C13,C17 - FPGA H5,H6 MGTHTX0_C
* QSFP0 TX1 - ENC C21,C25 - FPGA G7,G8 MGTHTX1_C
* QSFP0 TX2 - ENC C29,C23 - FPGA F5,F6 MGTHTX2_C
* QSFP1 TX0 - ENC C37,C41 - FPGA E7,E8 MGTHTX3_C
* QSFP1 TX1 - ENC C45,C47 - FPGA P5,P6 MGTHTX0_B
* QSFP1 TX2 - ENC C51,C53 - FPGA M5,M6 MGTHTX1_B
* QSFP2 TX0 - ENC C57,C59 - FPGA L3,L4 MGTHRX2_B
* QSFP2 TX1 - ENC C63,C65 - FPGA K5,K6 MGTHTX3_B
* QSFP2 TX2 - ENC C75,C77 - FPGA W3,W4 MGTHTX0_A
* QSFP3 TX0 - ENC C79,C81 - FPGA V5,V6 MGTHTX1_A
* QSFP3 TX1 - ENC C85,C87 - FPGA T5,T6 MGTHRX2_A
* QSFP3 TX2 - ENC C89,C91 - FPGA R3,R4 MGTHTX3_A

Clock distribution Rev0

Simplified:

  • 125 MHz osc -> CLK_XO_125 -> MGTREFCLK0_A -> not used
  • 125 MHz osc -> CLK3_XO_125 -> MGTREFCLK1_B -> SFP RX ref clock, QSFP RX and TX ref clock (this is not final design!)
  • (disconnected) 125 MHz osc -> CLK2_XO_125 -> FPGA AG8,AH8 (GC)
  • 125 MHz osc -> C.C. in1
  • C.C. in0 <- CLK_EXT1 (10 MHz GPS clock)
  • C.C. in1 <- 125 MHz osc
  • (disconnected) C.C. in2 <- CLK_CC_IN <- MGTREFCLK0_D <- SFP RX clock (cannot be used because of uncontrollable phase)
  • C.C. in2 <- CLK2_XO_125 <- FPGA AG8,AH8 (GC) <- SFP RX recovered 125 MHz clock
  • C.C. in3 <- CLK_FB
  • C.C. 125 MHz -> CLK_CC_OUT0 -> MGTREFCLK0_B -> QSFP RX and TX ref clock (final design)
  • C.C. 125 MHz -> CLK_CC_OUT1 -> MGTREFCLK1_D -> SFP TX clock
  • C.C. 62.5 MHz -> VX clock fanout

proposed changes:

  • add C.C. 125 MHz -> new CLK_CC_OUT2 (old CLK2_XO_125) -> FPGA AG8,AH8 (GC)
  • change C.C. in2 <- new CLK_CC_IN <- FPGA AK8,AK9 (non-GC)

Complete:

125 MHz oscillator - U5 fan out -
  q0 -> CLK_XO_125 -> ENC C72,C74 -> FPGA R7,R8 MGTREFCLK0_A (not used)
  q1 -> U6 C.C. in1
  q2 -> CLK3_XO_125 -> ENC C7,C9 -> FPGA J7,J8 MGTREFCLK1_B -> SFP RX reference clock, QSFP RX and TX reference clocks (not final design!)
  q3 -> disconnected on the board, was CLK2_XO_125 -> ENC C151,C153 -> FPGA AG8,AH8 (GC)

U6 C.C (clock cleaner) -

in0 <- CLK_EXT1 (presumably GPS 10 MHz ref clock)
in1 <- 125 MHz oscillator via U5
in2 <- (was: CLK_CC_IN <- ENC B10,B12 <- FPGA D9,D10 MGTREFCLK0_D <- SFP RX clock, 125 MHz)
in2 <- CLK2_XO_125 <- ENC C151,B153 <- FPGA AG8,AH8 (GC) <- mgt_link_data_to_processing.rx_data_clk (SFP RX data clock, 125 MHz)
in3 <- CLK_FB

out0 -> CLK_CCA -> U12 (125 MHz)
out1 -> CLK_CCB -> VX1..6 (62.5 MHz)
out2 -> CLK_CCC -> VX7..12 (62.5 MHz)
out3 -> CLK_FB into in3

CLK_CCA -> U12 (125 MHz fan out) ->

Q0 -> not used
Q1 -> CLK_CC_OUT0 -> ENC C3-5 -> FPGA L7,L8 MGTREFCLK0_B -> QSFP RX and TX reference clocks (final design)
Q2 -> CLK_CC_OUT1 -> ENC B3-5 -> FPGA B9,B10 MGTREFCLK1_D -> SFP TX clock
Q3 -> not used
Q4 -> not used
Q5 -> SMA J9/J10

CLK_TP0 - FPGA N7,N8 MGTREFCLK1_A - ENC C69,C71 - DS-DM SMA J11, J12 (NOT IN CDM PROJECT)

Notes:
* CLK_XO_125 (125 MHz osc) is not used
* 62.5 MHz VX clock does not go into the FPGA
* CLK_EXT0 going to in1 of U5 cannot be used. only permitted frequency is 125 MHz (it drives the MGT reference clocks) and is this frequency is too high for LEMO cables and connectors

Proposed modifications:
- CLK_CC_IN: from FPGA output pin (ENC C142,C144 - FPGA AK8,AK9) to clock cleaner in2 (instead of CLK2_XO_125 pins)
- CLK_CCA -> U12 -> currently unused out3 -> CLK2_XO_125 FPGA pins
- repurpose CLK_EXT0 at GPS 1pps/IRIG input to FPGA

Clock distribution Rev1

Simplified:

  • 125 MHz osc -> CLK_XO_125 -> MGTREFCLK0_A -> not used
  • 125 MHz osc -> CLK3_XO_125 -> MGTREFCLK1_B -> SFP RX ref clock
  • 125 MHz osc -> C.C. in1
  • C.C. in0 <- CLK_EXT1 (10 MHz GPS clock)
  • C.C. in1 <- 125 MHz osc
  • C.C. in2 <- CLK_CC_IN <- FPGA AK9,AK8 <- SFP RX recovered clock, 125 MHz
  • C.C. in3 <- CLK_FB
  • C.C. 125 MHz -> CLK_CC_OUT0 -> MGTREFCLK0_B -> QSFP RX and TX ref clock
  • C.C. 125 MHz -> CLK_CC_OUT1 -> MGTREFCLK1_D -> SFP TX clock
  • C.C. 125 MHz -> CLK_CC_OUT2 -> FPGA AG8,AH8 (GC) -> not used
  • C.C. 62.5 MHz -> VX clock fanout

Complete:

125 MHz oscillator - U5 fan out -
  q0 -> CLK_XO_125 -> ENC C72,C74 -> FPGA R8,R7 MGTREFCLK0_A -> XDC CLK_XO_125_P -> VHDL not used
  q1 -> U6 C.C. in1
  q2 -> CLK3_XO_125 -> ENC C7,C9 -> FPGA J8,J7 MGTREFCLK1_B -> XDC GDM missing, CDM CLK3_XO_125_P -> VHDL SFP RX reference clock (mgt_rx_ref_clk)
  q3 -> not used, was CLK2_XO_125

U6 C.C (clock cleaner) -

in0 <- CLK_EXT1 (GPS 10 MHz clock)
in1 <- 125 MHz oscillator via U5
in2 <- CLK_CC_IN <- ENC C142,C144 <- FPGA AK9,AK8 <- XDC GDM missing, CDM CLK_CC_IN1_P <- VHDL rx_clk
in3 <- CLK_FB

out0 -> CLK_CCA -> U12 (125 MHz)
out1 -> CLK_CCB -> VX1..6 (62.5 MHz)
out2 -> CLK_CCC -> VX7..12 (62.5 MHz)
out3 -> CLK_FB into in3

CLK_CCA -> U12 (125 MHz fan out) ->

Q0 -> not used
Q1 -> CLK_CC_OUT0 -> ENC C3,C5 -> FPGA L8,L7 MGTREFCLK0_B -> XDC GDM clk_mgtrefclk0_x0y1_p, CDM CLK_CC_OUT0_P -> VHDL  GDM mgt_b_ref_clk QSFP RX and TX reference clocks, CDM alternate rx_clk via clock mux
Q2 -> CLK_CC_OUT1 -> ENC B3,B5 -> FPGA B10,B9 MGTREFCLK1_D -> XDC CLK_CC_OUT1_P -> VHDL GDM not used, CDM mgt_tx_ref_clk SFP TX clock
Q3 -> CLK_CC_OUT2 -> ENC C151,C153 -> FPGA AG8,AH8 (GC) -> XDC GDM, CDM missing
Q4 -> not used
Q5 -> SMA J9/J10

CLK_TP0 <-> ENC C69,C71 <-> FPGA N8,N7 MGTREFCLK1_A (not used) -> XDC CLK_TP0_P -> VHDL not used (DS-DM SMA J11, J12)

Notes:
* Enclustra ENC-B is J801, ENC-C is J900
* "(GC)" is clock-capable FPGA pin
* CLK_XO_125 (125 MHz osc) is not used in FPGA
* 62.5 MHz VX clock does not go into the FPGA
* CLK_EXT0 going to in1 of U5 cannot be used. only permitted frequency is 125 MHz (it drives the MGT reference clocks) and is this frequency is too high for LEMO cables and connectors

I2C bus

  • I2C_SCL is J-ENC-A pin 111 I2C_SCL is FPGA I2C_SCL_PL AB13 (IO_L1N_TOL1D_64) and I2C_SCL_PS F18 (PS_MIO10)
  • I2C_SDA is J-ENC-A pin 113 I2C_SDA is FPGA I2C_SDA_PL AH13 (IO_L7N_T1L1Q_AD13N_64) and I2C_SDA_PS G18 (PS_MIO11)
  • XU8 secure EEPROM ATSHA204A at 0x64, this is 0110'010X -> linux _011'0010 is 0x32. (but responds to scan and read at 0x33)
  • U4 ethernet mac chip, EEPROM at 1010 A2 A1 A0 X and MAC/serial_no at 1011 A2 A1 A0 X. A0=VCC, A1=VCC, A2=GND -> linux _101'0011 and _101'1011 is 0x53 and 0x5B.
  • U6 clock chip, address 1101 0 A1 A0 X. A1=VCC, A0=N/C (internal pull-up) -> linux _110'1011 is 0x6b
  • U23 voltmeter at 10011 ADR1 ADR0. ADR0=GND, ADR1=VCC -> linux _100'1110 is 0x4e
  • SFP, address 1010000X -> linux _101'0000 is 0x50. additional SFP data at 0x51
  • QSFP0, QSFP1, QSFP2, QSFP3 (QSFP0_SEL, QSFP1_SEL, QSFP2_SEL, QSFP3_SEL)

I2C clock builder connection

  • use Silicon Labs USB "Clock builder pro field programmer", www.silabs.com/CBProgrammer
  • connect rainbow jumper cable pins:
    • black - 1-GND to GND on DS-DM
    • white - 3-SCLK to SCL on the DS-DM
    • grey - 7-SDA_SDIO to SDA on the DS-DM
  • power up the DS-DM
  • plug USB programmer into Windows laptop
  • on Windows, run "ClockBuilder Pro"
  • it should report "Field programmer detected", press "EVB GUI"
  • in EVB GUI, press "Config", set I2C address 0x6B
  • press "Scan", it should find Si5394A-A-GM
  • select the "Status" tab, should see real-time status of clock chip

GDM MGT configuration

  • TX configuration:
  • GDM MGT transceivers are configured as "multilane" TX and RX.
  • there is 12 TXes ("lanes")
  • MGT reference 125 MHz clock goes into [2:0]gtreclk00_in and [11:0]gtrefclk0_in
  • one MGT is designated as "master"
  • PLL of master MGT converts reference clock into common TX clock and common tx_user_clk2 which becomes tx_data_clk
  • common tx_user_clk2 aka tx_data_clk goes into all TXes and clocks tx_data.
  • tx_user_clk2 aka tx_data_clk is 125 MHz but not same phase as MGT reference clock.
  • RX interim configuration:
  • there is 12 RXes ("lanes")
  • each RX produces it's own recovered RX clock
  • "multilane" configuration assumes all RX recovered clocks run at the same frequency (TX on the other end are driven by common TX clock, see above), but have different phase
  • one RX recovered clock is designated as "master" (rx_user_clk2 aka rx_data_clk) and a phase-matching fifo/buffer is used to bring rx_data from all 12 RXes to this common rx_data_clk
  • this works because each CDM SFP TX runs on the SFP RX recovered clock which is frequency-locked with the GDM QSFP TX clock.
  • RX final configuration:
  • MGTs permit using the common TX clock (tx_user_clk2 aka tx_data_clk) as the common rx_data_clk (they are frequency locked through the CDM).
  • this permits use of tx_data_clk as the main clock domain in the GDM and removes the need to bring rx_data into the tx_data_clk domain (actually this is done in the MGT RX phase matching fifo/buffer).

Clock path

NOTE: MUST REVIEW!!!

10 MHz ext clock or GDM 125 MHz oscillator
-> GDM QSFP MGT reference clock 125 MHz
-> MGT PLL -> tx_data_clk 125 MHz (GDM main clock domain) and TX bit clock 2.5 GHz
-> GDM QSFP optic transmitter
-> CDM SFP optic receiver
-> CDM SFP MGT, RX reference clock is CDM 125 MHz oscillator
-> MGT RX recovered clock 125 MHz (CDM main clock domain)
-> CC_CLK_IN -> CDM C.C. -> CC_CLK_OUT1 -> CDM SFP TX reference clock 125 MHz
-> MGT PLL -> tx_data_clk 125 MHz and TX bit clock 2.5 GHz
-> (tx_data phase matching fifo from CDM main clock domain to tx_data_clk)
-> CDM SFP optic transmitter
-> GDM QSFP RX optic receiver (12x)
-> GDM QSFP MGT (RX reference clock is same as TX reference clock)
-> MGT RX recovered clock (12x recovered clocks)
-> in multi-lane configuration, one of them is the "master" recovered clock rx_data_clk
-> (rx_data phase matching fifo from rx_data_clk to GDM main clock domain)

CDM rx_clk mux

when CDM SFP is not connected, there is no SFP recovered clock and a mux is used to switch between clk_cc_out0 (power up default) and rx_clk_mgt (SFP recovered clock)

Test SFP disconnected

note: if I say "--cc-in1", CC seems to lock on the 10 MHz GPS external clock, to prevent this, test sequence includes reloading the CC and the reset of MGT.

./test_cdm_local.exe --write32 0x30 0x0 ### rx_clk mux select CC clock
./test_cdm_local.exe --load-cc
./test_cdm_local.exe --reset-mgt
./test_cdm_local.exe --cdm-clocks
CDM clock frequency counters:
0x1030 mgt_rx_ref_clk_raw: 0x0773594e (125000014) should be ~125 MHz  <=== all 4 clocks wobble close to 125 MHz
0x1034 rx_clk:             0x0773594f (125000015) should be ~125 MHz
0x1038 mgt_tx_ref_clk_raw: 0x0773594f (125000015) should be ~125 MHz
0x103C tx_clk:             0x0773594f (125000015) should be ~125 MHz
0x1040 clk_50MHz:          0x02faf080 (50000000) should be 50 MHz exactly
0x1044 Block1_clk:         0x05f5e100 (100000000) should be 100 MHz exactly
./test_cdm_local.exe --write32 0x30 0x1 ### rx_clk mux select SFP recovered clock
./test_cdm_local.exe --cdm-clocks
CDM clock frequency counters:
0x1030 mgt_rx_ref_clk_raw: 0x0773598b (125000075) should be ~125 MHz
0x1034 rx_clk:             0x076d58ec (124606700) should be ~125 MHz  <=== off frequency because there is no valid SFP recovered clock
0x1038 mgt_tx_ref_clk_raw: 0x0773598c (125000076) should be ~125 MHz
0x103C tx_clk:             0x0773598b (125000075) should be ~125 MHz
0x1040 clk_50MHz:          0x02faf080 (50000000) should be 50 MHz exactly
0x1044 Block1_clk:         0x05f5e100 (100000000) should be 100 MHz exactly

Clock domains

GPS

  • no GPS : GDM runs from internal 125 MHz oscillator
  • external 10 MHz clock : GDM runs from external 10 MHz clock and optional 1pps signal (use VME-NIMIO32 NIM outputs)
  • GPS receiver : GDM runs from GPS 10 MHz clock and GPS IRIG serial data
  • LNGS GPS:
    • provides 1pps and serial data over fiber from GPS receiver (master). LNGS xxx box is not used.
    • serial data goes to GDM, decoded, 1pps signal extracted, goes to LEMO output
    • 1pps from GDM is used to train the Rubidium clock which provides a 10 MHz clock
    • 10 MHz output from Rubidium clock goes to GDM 10 MHz external clock input

GDM

  • AXI clock (100 MHz) - AXI registers
  • 125 MHz oscillator - to clock cleaner
  • 10 MHz external clock LEMO input - to clock cleaner
  • FPGA 125 MHz clock CLK_CC_IN - to clock cleaner - not used (could be used for cascaded GDMs)
  • 125 MHz oscillator - CLK3_XO_125 - mgt_b_ref_clk QSFP MGT reference clock (interim GDM design)
  • clock cleaner output 125 MHz fanout:
    • CLK_CC_OUT0 - QSFP MGT reference clock (final design)
    • CLK_CC_OUT1 - not used (CDM SFP reference clock)
    • CLK_CC_OUT2 - not used
  • QSFP MGT TX data clock 125 MHz tx_data_clk (main clock domain)
    • QSFP TX data
    • QSFP RX data (in final design, rx_data_clk is same as tx_data_clk. inside the MGT, 12x phase matching fifos for RX data from 12x RX recovered clocks to rx_data_clk == tx_data_clk)
    • ds20k block
  • (in interim design, rx_data_clk is disconnected from tx_data_clk. rx_data_clk is the "multilane master clock" which is one of the 12x RX recovered clocks. inside the MGT, 12x phase matching fifos for RX data from 12x RX recovered clocks to rx_data_clk)

note: all these clocks are frequency locked to 125 MHz

CDM

  • AXI clock (100 MHz) - AXI registers
  • 10 MHz external clock LEMO input - to clock cleaner (not used)
  • 125 MHz oscillator to fanout
    • to clock cleaner
    • to SFP MGT RX reference clock: CLK3_XO_125 to mgt_rx_ref_clk to gtrefclk01_in
  • SFP MGT RX recovered clock 125 MHz
    • MGT PLL to MGT rx_user_clk2 aka rx_data_clk
    • MGT rxrecclkout_out to mgt_rx_rec_clk to CLK_CC_IN to C.C.
  • SFP MGT rx_user_clk2 aka rx_data_clk (250 MHz/8 bit, 125 MHz/16 bit, 62.5 MHz/32 bit data) (main clock domain)
    • SFP RX data
    • ds20k block
    • VX TX clock PLLs
    • VX RX clock PLLs
  • C.C. fan out
    • 62.5 MHz VX clocks (12x)
    • CLK_CC_OUT0 (not used, GDM QSFP MGT reference clock)
    • CLK_CC_OUT1 125 MHz to mgt_tx_ref_clk to gtrefclk00_in to SFP MGT TX reference clock
    • CLK_CC_OUT2 (not used)
  • SFP MGT tx_user_clk2 aka tx_data_clk
    • SFP TX data
    • TX data phase matching fifo from main clock domain to tx_data_clk
  • VX TX clock PLLs
    • 2 PLLs, 6 clocks each (12 total). phase of each clock independently adjusted via AXI registers
    • VX TX data phase matching from main clock domain to VX TX clock (12 total)
    • VX TX serializer
    • VX TX LVDS transmitter
  • VX RX clock PLLs
    • 2 PLLs, 6 clocks each (12 total). phase of each clock independently adjusted via AXI registers
    • VX RX LVDS receivers (12 total)
    • VX RX deserializers (12 total)
    • VX TX data phase matching from VX RX clock to main clock domain

VX

  • everything runs on the VX main 125 MHz clock
  • correct phase of VX to CDM LVDS data is adjusted by scan of CDM VX RX PLL clock phase (VX to CDM link is now established)
  • correct phase of CDM to VX LVDS data is adjusted by scan of CDM VX RX PLL clock phase (link is established after VX to CDM idle data pattern changes from "VX RX data bad" to "good".
  • after good phases are found by scan, they are not expected to change unless cables are changed, CDM and VX modules are changed or CDM firmware is rebuilt. (rebuild of VX firmware should not affect LVDS data phase).
  • if there is excessive link errors, phase scan must be repeated.

Board test plan

To test:

  • Enclustra FPGA board
  • SFP port - SFP_RS0/RS1 connected to QSFP0_SEL/1_SEL is wrong? our Finisar SFP says RS0, RS1 N/C, so probably okey.
  • SW5 CLK_EXT1 NIM works. TTL needs to be tested. flipping SW5 CLK_EXT0 side from NIM to TTL makes CLK_EXT1 go LOS and OOF in the clock chip. R23 and R53 should be removed?
  • BOOT_MODE 0 and 1

Partial:

  • U23 3.3V current meter and thermometer. V1,V2 is current monitor, same as in application note. V3,V4 is thermometer, same in application note, except capacitor C118 is 0.1u instead of 470pF. Tested ok: Tint, VCC, V1, V2, V1-V2. Test failed: TR2 reads 50-something degC instead of same as Tint.

Done:

  • LED_FP1A..D: tested ok. K.O. 15 sep 2022
  • USB UART: tested ok. K.O. 15 sep 2022
  • J4A, J4B, J5A, J5B LEMO inputs (NIM/TTL) EXT_IN_LV(1..4). TTL threshold 1.7V, NIM threshold -0.3V. 50 Ohm termination. TTL straight, NIM inverted.
  • J6A, J6B LEMO clock inputs: 10 MHz TTL from chronobox works, 10 MHz NIM from IO32 works. 18-apr-2023
  • J7A, J7B LEMO outputs EXT_OUT(1), EXT_OUT(2) (NIM/TTL) (tested 23nov2022, K.O.). TTL ???, NIM inverted.
    • TTL out no 50 ohm termination: 0=0V, 1=5V, rise and fall time ~5 ns
    • TTL out with 50 ohm termination: 0=0V, 1=2.5V, rise and fall time <2ns
    • NIM out no 50 ohm termination: 0=+50mV, 1=-1.8V, rise and fall time ~3ns
    • NIM out with 50 ohm termination: 0=0V, 1=-0.9V, rise and fall time <2ns
  • ethernet MAC i2c chip (K.O. 20sep2022: can read: i2cdump 0 0x5b, nov2022 have u-boot driver)
  • CDM VX ports 2x(CLK, 3 tx, 4 rx) tested using test_cdm.exe and LVDS loopback in VX firmware.
  • SFP i2c tested KO 22jun2023
  • QSFP i2c tested KO 22jun2023
  • i2c testing complete 22jun2023
  • QSFP rx,tx tested 26june2023. lane0,1,2 ok, lane3 tx not connected, laser is off. qsfp0,1,2,3 all lanes ok.
  • SFP rx,tx tested 26june2023. rx and tx okey. LOS ok, mod_absent ok.

Failure:

  • ethernet: does not connect to alliedtelesys switch. connects to my USB-eth adapter at 100 Mbit speed. uboot mii status reports connection speed oscillating between 1000, 100 and 10. K.O. 16-sep-2022
  • SFP LOS and mod_absent are swapped (in the FPGA pin definitions?)
  • QSFP slot numbering is wrong.

Checklist for newly build boards

  • put new board on workbench
  • check - vme connector present, vme extraction handles present
  • check - standoff are removed from all thru-holes
  • plug Enclustra module
  • check - SW6 both switches are in the "PS" position
  • connect micro-usb cable from linux PC
  • connect ethernet from 1gige capable network switch
  • connect power from lab power supply - GND, +5V and -12V nominal, +5.7V and -12.5V actual
  • power up, +5V current 2.10-2.8A, -12V current 0.05A
  • on linux PC, open a new terminal, run: minicom -D /dev/ttyACM0
  • in minicom window, observe messages about Xilinx first stage boot loader, etc
  • on the ethernet switch, observe network link is 1gige speed (not 10mbit, not 100mbit).
  • if everything boots okey, there will be a login prompt, login as root, password root.
  • busybox devmem 0x80010000 # read firmware version number, i.e. 0xEDAD0A77
  • TBW - test LEMO inputs
  • TBW - test LEMO outputs
  • TBW - test VX connectors
  • TBW - test SFP connector
  • TBW - test QSFP connector

Serial console

i2c

ZynqMP> i2c bus
Bus 0:  i2c@ff020000
ZynqMP> i2c dev 0
Setting bus to 0
ZynqMP> i2c probe  
Valid chip addresses: 33 4E 53 5B 6B 77
ZynqMP> i2c md 0x5b 0x98
0098: fc c2 3d 00 00 12 1a 6e 0a 90 85 04 94 10 08 50    ..=....n.......P
root@gdm-cdm:~# i2cdetect 0
Warning: Can't use SMBus Quick Write command, will skip some addresses
WARNING! This program can confuse your I2C bus, cause data loss and worse!
I will probe file /dev/i2c-0.
I will probe address range 0x03-0x77.
Continue? [Y/n] 
     0  1  2  3  4  5  6  7  8  9  a  b  c  d  e  f
00:                                                 
10:                                                 
20:                                                 
30: -- -- -- 33 -- -- -- --                         
40:                                                 
50: -- -- -- 53 -- -- -- -- -- -- -- 5b -- -- -- -- 
60:                                                 
70:                                                 
root@gdm-cdm:~# 
root@gdm-cdm:~# i2cdump 0 0x5b
No size specified (using byte-data access)
WARNING! This program can confuse your I2C bus, cause data loss and worse!
I will probe file /dev/i2c-0, address 0x5b, mode byte
Continue? [Y/n] 
     0  1  2  3  4  5  6  7  8  9  a  b  c  d  e  f    0123456789abcdef
00: XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX    XXXXXXXXXXXXXXXX
10: XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX    XXXXXXXXXXXXXXXX
20: XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX    XXXXXXXXXXXXXXXX
30: XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX    XXXXXXXXXXXXXXXX
40: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
50: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
60: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
70: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
80: 0a 90 85 04 94 10 08 50 90 5b a0 00 a0 00 00 00    ???????P?[?.?...
90: 00 00 00 00 00 00 00 00 fc c2 3d 00 00 12 1a 6e    ........??=..??n
a0: 0a 90 85 04 94 10 08 50 90 5b a0 00 a0 00 00 00    ???????P?[?.?...
b0: 00 00 00 00 00 00 00 00 fc c2 3d 00 00 12 1a 6e    ........??=..??n
c0: XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX    XXXXXXXXXXXXXXXX
d0: XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX    XXXXXXXXXXXXXXXX
e0: XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX    XXXXXXXXXXXXXXXX
f0: XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX    XXXXXXXXXXXXXXXX
root@gdm-cdm:~# 
root@gdm0:~# i2cdetect -r 0
     0  1  2  3  4  5  6  7  8  9  a  b  c  d  e  f
00:                         -- -- -- -- -- -- -- -- 
10: -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- 
20: -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- 
30: -- -- -- 33 -- -- -- -- -- -- -- -- -- -- -- -- 
40: -- -- -- -- -- -- -- -- -- -- -- -- -- -- 4e -- 
50: -- -- -- 53 -- -- -- -- -- -- -- 5b -- -- -- -- 
60: -- -- -- -- -- -- -- -- -- -- -- 6b -- -- -- -- 
70: -- -- -- -- -- -- -- --                         
root@gdm0:~# 
root@cdm0:~# i2cdetect -r 0
     0  1  2  3  4  5  6  7  8  9  a  b  c  d  e  f
00:                         -- -- -- -- -- -- -- -- 
10: -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- 
20: -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- 
30: -- -- -- 33 -- -- -- -- -- -- -- -- -- -- -- -- 
40: -- -- -- -- -- -- -- -- -- -- -- -- -- -- 4e -- 
50: 50 51 -- 53 -- -- -- -- -- -- -- 5b -- -- -- -- 
60: -- -- -- -- -- -- -- -- -- -- -- 6b -- -- -- -- 
70: -- -- -- -- -- -- -- --                         
root@cdm0:~# 
  • 0x33 - XU8 secure EEPROM (should be at 0x32)
  • 0x4e - U23 current and temperature monitor
  • 0x50, 0x51 - SFP
  • 0x50 - QSFP, 4 QSFP modules enabled by GPIO QSFP0_SEL, QSFP1_SEL, QSFP2_SEL, QSFP3_SEL
  • 0x53, 0x5b - ethernet mac eeprom
  • 0x6b - U6 clock chip

U23

NOTE: Text reads double of Tint. not sure why. K.O. 21-mar-2024.

  • internal temperature only
root@gdm0:~# i2cset -y 0 0x4e 0x01 0x00 b  # control register: "repeat mode, internal temperature only"
root@gdm0:~# i2cset -y 0 0x4e 0x02 0xff b # trigger
root@gdm0:~# i2cget -y 0 0x4e 0x00 b # status register
0x03 # "Tint ready" and "busy", "busy is always 1 in repeat mode"
root@gdm0:~# i2cdump -y 0 0x4e b
     0  1  2  3  4  5  6  7  8  9  a  b  c  d  e  f    0123456789abcdef
00: 03 00 03 03 81 db 2a ce 2a 8e 00 6f 00 45 20 3f    ?.????*?*?.o.E ?
10: 01 00 01 01 01 db 2a ce 2a 8e 00 6f 00 45 20 3f    ?.????*?*?.o.E ?
...
readback:
reg0 - 03 - Tint ready
reg1 - 00 - what we put there
reg2 - trigger
reg3 - not used
reg4 - Tint MSB 0x81, bit 0x80 is "DV, data valid", bit 0x40 is "SS, sensor short", 0x20 is "SO, sensor open"
reg5 - Tint LSB 0xDB, Tint = 0x01DB = 475 * 0.0625 degC = 29.6 degC
reg6..F - stale data
  • Tint, V1, V2, TR2, VCC
root@gdm0:~# i2cset -y 0 0x4e 0x01 0x18 b  # control register: "repeat mode, V1, V2, TR2"
root@gdm0:~# i2cset -y 0 0x4e 0x02 0xff b # trigger
root@gdm0:~# i2cget -y 0 0x4e 0x00 b # status register
0x7f # all data is ready
root@gdm0:~# i2cdump -y 0 0x4e b
     0  1  2  3  4  5  6  7  8  9  a  b  c  d  e  f    0123456789abcdef
00: 7f 18 7f 7f 81 b9 aa d0 aa 8f 83 5e 83 5e a0 41    ???????????^?^?A
10: 01 18 01 01 01 b9 2a d0 2a 8f 03 5e 03 5e 20 41    ??????*?*??^?^ A
reg0 - 7F - all data ready
reg1 - 18 - what we put there
reg2 - trigger
reg3 - not used
reg4 - Tint MSB and DV, SS, SO.
reg5 - Tint LSB 0x1b9*0.0625 = 27.5 degC
reg6 - V1 MSB 0xaa, bit 0x80 is DV, bit 0x40 is sign
reg7 - V1 LSB 0xd0, V1 = 0x2ad0*305.18/1000000 = 3.3447 V (correct)
reg8 - V2 MSB 0xaa, ditto
reg9 - V2 LSB 0x8f, V2 = 0x2a8f*305.18/1000000 = 3.3249 V (correct, smaller than V1)
regA - V3 MSB or TR2 MSB 0x83, 0x80=DV, 0x40=SS, 0x20=SO
regB - V3 LSB or TR2 LSB 0x5e. TR2 = 0x35e*0.0625 = 53.875 degC (wrong, thermistor Q5 is next to U23, should read same as Tint)
regC - V4 MSB or TR2 MSB
regD - V4 LSB or TR2 LSB
regE - VCC MSB 0xa0, bit 0x80 is DV, 0x40 is sign
regF - VCC LSB 0x41, VCC = 2.5+0x2041*305.18/1000000 = 5.019 V (correct, VCC is +5V)

3V3_SW current is (V2-V1)/0.020 = 0.99 A (about right?)
  • Tint, V1-V2, TR2, VCC
root@gdm0:~# i2cset -y 0 0x4e 0x01 0x19 b  # control register: "repeat mode, V1-V2, TR2"
root@gdm0:~# i2cset -y 0 0x4e 0x02 0xff b # trigger
root@gdm0:~# i2cget -y 0 0x4e 0x00 b # status register
0x7f # all data is ready
root@gdm0:~# i2cdump -y 0 0x4e b
     0  1  2  3  4  5  6  7  8  9  a  b  c  d  e  f    0123456789abcdef
00: 7f 19 7f 7f 81 69 83 f2 83 f2 83 3a 83 3a a0 44    ?????i?????:?:?D
10: 01 19 01 01 01 69 03 f2 03 f2 03 3a 03 3a 20 44    ?????i?????:?: D
reg0 - 7F - all data ready
reg1 - 18 - what we put there
reg2 - trigger
reg3 - not used
reg4 - Tint MSB and DV, SS, SO.
reg5 - Tint LSB 0x169*0.0625 = 22.5 degC
reg6 - V1 or V1-V2 MSB 0x83, bit 0x80 is DV, bit 0x40 is sign
reg7 - V1 or V1-V2 LSB 0xf2, V1-V2 = 0x3f2*19.42/1000000 = 0.0196142 V (correct, compare with V1 and V2 measured above)
reg8 - V2 or V1-V2 MSB
reg9 - V2 or V1-V2 LSB
regA - V3 MSB or TR2 MSB 0x83, 0x80=DV, 0x40=SS, 0x20=SO
regB - V3 LSB or TR2 LSB 0x3a. TR2 = 0x33a*0.0625 = 51.625 degC (wrong, thermistor Q5 is next to U23, should read same as Tint)
regC - V4 MSB or TR2 MSB
regD - V4 LSB or TR2 LSB
regE - VCC MSB 0xa0, bit 0x80 is DV, 0x40 is sign
regF - VCC LSB 0x44, VCC = 2.5+0x2044*305.18/1000000 = 5.021 V (correct, VCC is +5V)

3V3_SW current is (V2-V1)/0.020 = 0.9807 A (about right?)

SFP

root@cdm0:~# i2cdump 0 0x50
     0  1  2  3  4  5  6  7  8  9  a  b  c  d  e  f    0123456789abcdef
00: 03 04 07 00 00 00 00 40 40 0c 00 01 3d 00 00 00    ???....@@?.?=...
10: 0c 02 00 1e 46 49 4e 49 53 41 52 20 43 4f 52 50    ??.?FINISAR CORP
20: 2e 20 20 20 00 00 90 65 46 54 4c 46 38 35 32 36    .   ..?eFTLF8526
30: 50 33 42 4e 4c 20 20 20 41 20 20 20 03 52 00 9d    P3BNL   A   ?R.?
40: 00 1a 00 00 4e 33 41 42 34 4c 56 20 20 20 20 20    .?..N3AB4LV     
50: 20 20 20 20 32 30 30 33 31 39 20 20 68 f0 03 de        200319  h???
60: 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00    ................
70: 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00    ................
80: 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00    ................
90: 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00    ................
a0: 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00    ................
b0: 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00    ................
c0: 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00    ................
d0: 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00    ................
e0: 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00    ................
f0: 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00    ................
root@cdm0:~# 
root@cdm0:~# i2cdump 0 0x51
     0  1  2  3  4  5  6  7  8  9  a  b  c  d  e  f    0123456789abcdef
00: 5a 00 d8 00 55 00 e2 00 90 88 71 48 8c a0 75 30    Z.?.U.?.??qH??u0
10: 21 34 01 f4 1b 58 03 e8 31 2d 04 eb 1f 07 06 31    !4???X??1-?????1
20: 31 2d 00 64 27 10 00 9e 00 00 00 00 00 00 00 00    1-.d'?.?........
30: 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00    ................
40: 00 00 00 00 3f 80 00 00 00 00 00 00 01 00 00 00    ....??......?...
50: 01 00 00 00 01 00 00 00 01 00 00 00 00 00 00 b7    ?...?...?......?
60: 19 9f 80 c5 0e 17 12 c4 1f 99 00 00 00 00 30 00    ??????????....0.
70: 00 00 00 00 00 00 00 00 ff ff ff ff ff ff ff 01    ...............?
80: 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00    ................
90: 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00    ................
a0: 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00    ................
b0: 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00    ................
c0: 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00    ................
d0: 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00    ................
e0: 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00    ................
f0: 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00    ................
root@cdm0:~# 

QSFP

QSFP i2c enable lines, active low:

QSFP0_SEL - JENC-A 82 - PS-MIO40 - linux gpio 378
QSFP1_SEL - JENC-A 84 - PS-MIO41 - linux gpio 379
QSFP2_SEL - JENC-A 100 - PS-MIO44 - linux gpio 382
QSFP3_SEL - JENC-A 106 - PS-MIO43 - linux gpio 381 (notice 2 and 3 are out of order)
# cat /sys/kernel/debug/gpio
gpiochip0: GPIOs 338-511, parent: platform/ff0a0000.gpio, zynqmp_gpio:
# echo 378 >> /sys/class/gpio/export ### SEL0 338+40
# echo 379 >> /sys/class/gpio/export ### SEL1 338+41
# echo 381 >> /sys/class/gpio/export ### SEL3 338+43
# echo 382 >> /sys/class/gpio/export ### SEL2 338+44
# cat /sys/kernel/debug/gpio
gpiochip0: GPIOs 338-511, parent: platform/ff0a0000.gpio, zynqmp_gpio:
 gpio-378 (                    |sysfs               ) in  hi 
 gpio-379 (                    |sysfs               ) in  hi 
 gpio-381 (                    |sysfs               ) in  hi 
 gpio-382 (                    |sysfs               ) in  hi 
root@gdm0:~# echo out >> /sys/class/gpio/gpio381/direction
root@gdm0:~# echo out >> /sys/class/gpio/gpio382/direction
root@gdm0:~# echo out >> /sys/class/gpio/gpio378/direction
root@gdm0:~# echo out >> /sys/class/gpio/gpio379/direction
root@gdm0:~# 
root@gdm0:~# cat /sys/kernel/debug/gpio
gpiochip0: GPIOs 338-511, parent: platform/ff0a0000.gpio, zynqmp_gpio:
 gpio-378 (                    |sysfs               ) out lo 
 gpio-379 (                    |sysfs               ) out lo 
 gpio-381 (                    |sysfs               ) out lo 
 gpio-382 (                    |sysfs               ) out lo 
root@gdm0:~#
echo 1 >> /sys/class/gpio/gpio381/value
echo 1 >> /sys/class/gpio/gpio382/value
echo 1 >> /sys/class/gpio/gpio378/value
echo 1 >> /sys/class/gpio/gpio379/value
cat /sys/kernel/debug/gpio
root@gdm0:~# cat /sys/kernel/debug/gpio
gpiochip0: GPIOs 338-511, parent: platform/ff0a0000.gpio, zynqmp_gpio:
 gpio-378 (                    |sysfs               ) out hi 
 gpio-379 (                    |sysfs               ) out hi 
 gpio-381 (                    |sysfs               ) out hi 
 gpio-382 (                    |sysfs               ) out hi 
root@gdm0:~# 
root@gdm0:~# i2cdetect -y -r 0
     0  1  2  3  4  5  6  7  8  9  a  b  c  d  e  f
00:                         -- -- -- -- -- -- -- -- 
10: -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- 
20: -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- 
30: -- -- -- 33 -- -- -- -- -- -- -- -- -- -- -- -- 
40: -- -- -- -- -- -- -- -- -- -- -- -- -- -- 4e -- 
50: -- -- -- 53 -- -- -- -- -- -- -- 5b -- -- -- -- 
60: -- -- -- -- -- -- -- -- -- -- -- 6b -- -- -- -- 
70: -- -- -- -- -- -- -- --                         
root@gdm0:~# 

NOTICE NOTHING AT ADDRESS 0x50
ENABLE QSFP0, OBSERVE IT IS AT ADDRESS 0x50

root@gdm0:~# echo 0 >> /sys/class/gpio/gpio378/value
root@gdm0:~# i2cdetect -y -r 0
     0  1  2  3  4  5  6  7  8  9  a  b  c  d  e  f
00:                         -- -- -- -- -- -- -- -- 
10: -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- 
20: -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- 
30: -- -- -- 33 -- -- -- -- -- -- -- -- -- -- -- -- 
40: -- -- -- -- -- -- -- -- -- -- -- -- -- -- 4e -- 
50: 50 -- -- 53 -- -- -- -- -- -- -- 5b -- -- -- -- 
60: -- -- -- -- -- -- -- -- -- -- -- 6b -- -- -- -- 
70: -- -- -- -- -- -- -- --                         
root@gdm0:~# 
root@gdm0:~# i2cdump -y 0 0x50
No size specified (using byte-data access)
     0  1  2  3  4  5  6  7  8  9  a  b  c  d  e  f    0123456789abcdef
00: 0d 00 02 8e 00 00 01 00 00 05 55 00 05 00 00 00    ?.??..?..?U.?...
10: 00 00 00 00 00 00 1e b8 00 00 81 a0 00 00 00 00    ......??..??....
20: 00 00 12 12 00 01 00 01 00 01 0e e0 0f 20 0e e0    ..??.?.?.???? ??
30: 00 00 1f a0 1e 3b 1f 72 00 01 00 00 00 00 00 00    ..???;?r.?......
40: 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00    ................
50: 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00    ................
60: 00 00 00 00 00 00 00 00 00 00 1f 00 00 00 08 00    ..........?...?.
70: 00 00 00 00 00 00 00 ff ff ff ff ff ff ff ff 00    ................
80: 0d 00 0c 04 00 00 00 40 40 02 d5 05 67 00 00 96    ?.??...@@???g..?
90: 00 00 c8 00 46 49 4e 49 53 41 52 20 43 4f 52 50    ..?.FINISAR CORP
a0: 20 20 20 20 07 00 90 65 46 54 4c 34 31 30 51 44        ?.?eFTL410QD
b0: 34 43 20 20 20 20 20 20 41 20 42 68 07 d0 00 43    4C      A Bh??.C
c0: 00 07 0f de 58 37 39 41 43 30 52 20 20 20 20 20    .???X79AC0R     
d0: 20 20 20 20 32 32 30 33 30 39 20 20 3c 10 00 9e        220309  <?.?
e0: 20 20 20 20 20 20 20 20 20 20 20 20 20 20 20 20                    
f0: 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00    ................
root@gdm0:~# 

ethernet mac eeprom

  • correct chip with 84-bit ethernet mac address
root@cdm1:~# i2cdump 0 0x53
     0  1  2  3  4  5  6  7  8  9  a  b  c  d  e  f    0123456789abcdef
00: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
10: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
20: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
30: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
40: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
50: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
60: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
70: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
80: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
90: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
a0: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
b0: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
c0: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
d0: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
e0: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
f0: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
root@cdm1:~# 

root@cdm1:~# i2cdump 0 0x5b
     0  1  2  3  4  5  6  7  8  9  a  b  c  d  e  f    0123456789abcdef
00: XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX    XXXXXXXXXXXXXXXX
10: XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX    XXXXXXXXXXXXXXXX
20: XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX    XXXXXXXXXXXXXXXX
30: XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX    XXXXXXXXXXXXXXXX
40: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
50: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
60: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
70: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
80: 0a 80 c2 04 34 10 08 32 a8 4b a0 00 a0 00 00 00    ????4??2?K?.?...
90: 00 00 00 00 00 00 00 00 00 00 fc c2 3d 1a 51 3c    ..........??=?Q<
a0: 0a 80 c2 04 34 10 08 32 a8 4b a0 00 a0 00 00 00    ????4??2?K?.?...
b0: 00 00 00 00 00 00 00 00 00 00 fc c2 3d 1a 51 3c    ..........??=?Q<
c0: XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX    XXXXXXXXXXXXXXXX
d0: XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX    XXXXXXXXXXXXXXXX
e0: XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX    XXXXXXXXXXXXXXXX
f0: XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX    XXXXXXXXXXXXXXXX
root@cdm1:~# 
  • wrong "602" chip with 64-bit IPv6 address
root@cdm0:~# i2cdump 0 0x53
     0  1  2  3  4  5  6  7  8  9  a  b  c  d  e  f    0123456789abcdef
00: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
10: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
20: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
30: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
40: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
50: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
60: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
70: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
80: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
90: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
a0: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
b0: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
c0: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
d0: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
e0: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
f0: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
root@cdm0:~# i2cdump 0 0x5b
     0  1  2  3  4  5  6  7  8  9  a  b  c  d  e  f    0123456789abcdef
00: XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX    XXXXXXXXXXXXXXXX
10: XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX    XXXXXXXXXXXXXXXX
20: XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX    XXXXXXXXXXXXXXXX
30: XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX    XXXXXXXXXXXXXXXX
40: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
50: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
60: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
70: ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff ff    ................
80: 0a 90 85 04 94 10 08 51 10 5b a0 00 a0 00 00 00    ???????Q?[?.?...
90: 00 00 00 00 00 00 00 00 fc c2 3d 00 00 12 1a 2e    ........??=..??.
a0: 0a 90 85 04 94 10 08 51 10 5b a0 00 a0 00 00 00    ???????Q?[?.?...
b0: 00 00 00 00 00 00 00 00 fc c2 3d 00 00 12 1a 2e    ........??=..??.
c0: XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX    XXXXXXXXXXXXXXXX
d0: XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX    XXXXXXXXXXXXXXXX
e0: XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX    XXXXXXXXXXXXXXXX
f0: XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX    XXXXXXXXXXXXXXXX
root@cdm0:~# 

read ethernet mac address from i2c

(this code is copied from uboot command line i2c code)

in uboot sources board/xilinx/common/board.c replace original function with this:

// special code to read ethernet MAC address from the DS-DM-Rev0 board. K.O. Sep-2022

int zynq_board_read_rom_ethaddr(unsigned char *ethaddr)
{
        struct udevice *bus;
	int ret;
        int busnum = 0;

	ret = uclass_get_device_by_seq(UCLASS_I2C, busnum, &bus);
	if (ret) {
           printf("%s: No bus %d\n", __func__, busnum);
           return ret;
	}

        int chip_addr = 0x5B;

        struct udevice *dev;

        ret = i2c_get_chip(bus, chip_addr, 1, &dev);
	if (ret) {
           printf("%s: Bus %d no chip 0x%02x\n", __func__, busnum, chip_addr);
           return ret;
	}

        int dev_addr = 0x98;

        unsigned char data[8];
           
        ret = dm_i2c_read(dev, dev_addr, data, 8);

	if (ret) {
           printf("%s: Bus %d chip 0x%02x read error %d\n", __func__, busnum, chip_addr, ret);
           return ret;
	}

        printf("%s: Bus %d chip 0x%02x addr 0x%02x read: 0x %02x %02x %02x %02x %02x %02x %02x %02x\n", __func__, busnum, chip_addr, dev_addr, data[0], data[1], data[2], data[3], data[4], data[5], data[6], data[7]);

        // see Atmel-8807-SEEPROM-AT24MAC402-602-Datasheet.pdf

        if (data[0] == 0) {
           // eiu-48 chip
           ethaddr[0] = data[2];
           ethaddr[1] = data[3];
           ethaddr[2] = data[4];
           ethaddr[3] = data[5];
           ethaddr[4] = data[6];
           ethaddr[5] = data[7];
        } else {
           // eiu-64 chip
           ethaddr[0] = data[0];
           ethaddr[1] = data[1];
           ethaddr[2] = data[2];
           ethaddr[3] = data[5];
           ethaddr[4] = data[6];
           ethaddr[5] = data[7];
        }

        printf("%s: ethaddr %02x:%02x:%02x:%02x:%02x:%02x\n", __func__, ethaddr[0], ethaddr[1], ethaddr[2], ethaddr[3], ethaddr[4], ethaddr[5]);

        return ret;
}

also this should have worked if i2c_xxx() functions were enabled in uboot:

i2c_set_bus_num(0);
i2c_probe(0x5b);
i2c_read(0x5b, 0x9a, ethaddr, 6);

read ethernet mac address from i2c (SHOULD WORK)

from: https://stackoverflow.com/questions/43637540/is-there-linux-or-u-boot-support-to-read-a-mac-address-from-a-chip-at-startup

#ethernet related setup
setup_eth=run readmac buildmac
#read mac address from eeprom
readmac=i2c dev 0; i2c read 50 FA.1 6 $loadaddr
#build the ethaddr variable
#not very nice, but does the job
buildmac=\
e=" "; sep=" " \
for i in 0 1 2 3 4 5 ; do\
setexpr x $loadaddr + $i\
setexpr.b b *$x\
e="$e$sep$b"\
sep=":"\
done &&\
setenv ethaddr $e

read ethernet mac address from i2c (DOES NOT WORK)

this method does not work: inside board/xilinx/common/board.c:int zynq_board_read_rom_ethaddr(unsigned char *ethaddr), uclass_get_device_by_ofnode(UCLASS_I2C_EEPROM, eeprom, &dev) returns ENODEV and read from i2c does not happen. K.O. Sep-2022

Read:

Note:

  • 0x5B is the i2c chip address
  • 0x9A is the data offset inside the chip, see datasheet or i2c read dump above.

Edit:

  • emacs -nw PetaLinux_GDM_CDM/project-spec/meta-user/recipes-bsp/u-boot/files/platform-top.h
#include <configs/xilinx_zynqmp.h>
#include <configs/platform-auto.h>
//#define CONFIG_I2C_EEPROM                                                                                                                                                                   
//#define CONFIG_SYS_I2C_EEPROM_ADDR 0x5b                                                                                                                                                     
//#define CONFIG_SYS_I2C_EEPROM_ADDR_OVERFLOW 0x0                                                                                                                                             
#define CONFIG_ZYNQ_GEM_I2C_MAC_OFFSET 0x9A
#error HERE!
  • emacs -nw PetaLinux_GDM_CDM/project-spec/meta-user/recipes-bsp/device-tree/files/system-user.dtsi
/include/ "system-conf.dtsi"
/ {
chosen {
   xlnx,eeprom = &eeprom;
};
};

&i2c0 {
eeprom: eeprom@5b { /* u88 */
compatible = "atmel,24mac402";
reg = <0x5b>;
};
};
  • components/yocto/workspace/sources/u-boot-xlnx/configs/xilinx_zynqmp_virt_defconfig
CONFIG_ZYNQ_GEM_I2C_MAC_OFFSET=0x9A

RTC chip

  • DS3231 RTC chip
  • FPGA connections:
I2C SCL <- J-ENC A85 <- FPGA E17 <- XDC TP_S <- VHDL TP_S is output
I2C SDA <-> J-ENC A87 <-> FPGA D17 <-> XDC TP_S <- VHDL TP_S is output
1pps -> J-ENC B129 -> FPGA AE3 -> XDC "free pin"
1pps -> J-ENC C160 -> FPGA AH12 -> XDC "slow_io"

enable VX clock

devmem 0x80010010 32 0x8; sleep 1;  devmem 0x80010010 32 0x0;
si5394-i2c-file /media/sd-mmcblk1p1/00_freerun.txt 0 0x6b

clock chip configuration

file CDM_v3.0_IN1_fixed_and_IN2_RX_Recovered_VX_62.5MHz_Si5394-RevA-Registers.txt:

  • VCO is 14 GHz
  • Tvco is 71.43 ps
  • N0 divider is 14, frequency is 1000 MHz
  • out0 from N0 divider 0x3 is (3+1)*2 = 8, freq 125 MHz
  • out1 from N0 divider 0x7 is (7+1)*2 = 16, freq 62.5 MHz
  • out2 from N0 divider 0x7 is (7+1)*2 = 16, freq 62.5 MHz
  • out3 from N0 divider 0x3 is (3+1)*2 = 8, freq 125 MHz is the feedback for zero delay

clock chip monitoring

from si5395-94-92-family.pdf:

  • reg 0x1: page select, set to 0 or set to 5 to read 0x53F
  • reg 0x2: 0x94
  • reg 0x3: 0x53 -> device is a si5394
  • reg 0xC: LOSXAXB
  • reg 0xD: LOS and OOF for the 4 clock inputs
  • reg 0xE: LOL and HOLD
  • reg 0xF: CAL_PLL
  • reg 0x11: sticky bits for reg 0xC
  • reg 0x12: sticky bits for reg 0xD
  • reg 0x13: sticky bits for reg 0xE
  • reg 0x14: sticky bits for reg 0xF
  • reg 0x1C: device reset
  • reg 0x1E: low power, hard reset, SYNC
  • reg 0x507: currently selected input clock
  • reg 0x52A: input clock select
  • reg 0x535: FORCE_HOLD
  • reg 0x53F: HOLD_HIST_VALID and FASTLOCK_STATUS

arm and linux benchmark

memory benchmark:

daq13$ arm-linux-gnueabi-gcc -o memcpy.armv7 memcpy.cc -march=armv7 -static -O2
scp memcpy.armv7 to ...
root@gdm-cdm:~# ./memcpy.armv7 
memcpy       1 KiBytes:   1288 MB/sec
memcpy       2 KiBytes:   1924 MB/sec
memcpy       4 KiBytes:   2554 MB/sec
memcpy       8 KiBytes:   3054 MB/sec
memcpy      16 KiBytes:   3262 MB/sec
memcpy      32 KiBytes:   3250 MB/sec
memcpy      64 KiBytes:   3456 MB/sec
memcpy     128 KiBytes:   3556 MB/sec
memcpy     256 KiBytes:   3780 MB/sec
memcpy     512 KiBytes:   3795 MB/sec
memcpy    1024 KiBytes:   3789 MB/sec
memcpy    2048 KiBytes:   3729 MB/sec
memcpy    4096 KiBytes:   3717 MB/sec
memcpy    8192 KiBytes:   3687 MB/sec
memcpy   16384 KiBytes:   3632 MB/sec
memcpy   32768 KiBytes:   3529 MB/sec
memcpy   65536 KiBytes:   3318 MB/sec
memcpy  131072 KiBytes:   2893 MB/sec
root@gdm-cdm:~# 

ethernet receive:

daq13:bin$ ./ttcp -t -s -n 100000 10.0.0.24
ttcp-t: buflen=8192, nbuf=100000, align=16384/0, port=5001  tcp  -> 10.0.0.24
ttcp-t: socket
ttcp-t: connect
ttcp-t: 819200000 bytes in 7.25 real seconds = 110358.39 KB/sec +++
ttcp-t: 100000 I/O calls, msec/call = 0.07, calls/sec = 13794.80
ttcp-t: 0.0user 0.2sys 0:07real 3% 0i+0d 760maxrss 0+2pf 1461+31csw
daq13:bin$ 

root@gdm-cdm:~# ./ttcp.armv7 -r -s
ttcp-r: buflen=8192, nbuf=2048, align=16384/0, port=5001  tcp
ttcp-r: socket
ttcp-r: accept from 10.0.0.25
ttcp-r: 819200000 bytes in 7.27 real seconds = 110098.22 KB/sec +++
ttcp-r: 212040 I/O calls, msec/call = 0.04, calls/sec = 29181.53
ttcp-r: 0.1user 5.7sys 0:07real 81% 0i+0d 584maxrss 0+2pf 125601+2699csw
root@gdm-cdm:~# 

ethernet transmit:

root@gdm-cdm:~# ./ttcp.armv7 -t -s -n 100000 10.0.0.25
ttcp-t: buflen=8192, nbuf=100000, align=16384/0, port=5001  tcp  -> 10.0.0.25
ttcp-t: socket
ttcp-t: connect
ttcp-t: 819200000 bytes in 6.95 real seconds = 115078.69 KB/sec +++
ttcp-t: 100000 I/O calls, msec/call = 0.07, calls/sec = 14384.84
ttcp-t: 0.0user 0.7sys 0:06real 11% 0i+0d 584maxrss 0+2pf 1162+1017csw
root@gdm-cdm:~# 

daq13:bin$ ./ttcp -r -s
ttcp-r: buflen=8192, nbuf=2048, align=16384/0, port=5001  tcp
ttcp-r: socket
ttcp-r: accept from 10.0.0.24
ttcp-r: 819200000 bytes in 6.97 real seconds = 114841.84 KB/sec +++
ttcp-r: 161335 I/O calls, msec/call = 0.04, calls/sec = 23160.01
ttcp-r: 0.0user 1.9sys 0:06real 28% 0i+0d 760maxrss 0+2pf 80646+51csw
daq13:bin$ 

Install Xilinx tools

  • install Vivado 2020.2
login at https://www.xilinx.com/myprofile.html
go to "Downloads"
go to archive,
find 2020.2
download Xilinx_Unified_2020.2_1118_1232_Lin64.bin
sh ./Xilinx_Unified_2020.2_1118_1232_Lin64.bin
banner window should open with spinner "downloading installation data"
"a newer version is available" -> say "continue"
next
"select install type" window:
provide email and password,
select "download image"
select directory /home/olchansk/Xilinx/Downloads/2020.2\
select "linux" and "full image"
next
download summary: space required 38.52 Gbytes
download
installation progress
downloading spinner, 16 M/s 47 minutes...
"download image has been created successfully". Ok.
check contents of /home/olchansk/Xilinx/Downloads/2020.2
ls -l /home/olchansk/Xilinx/Downloads/2020.2
total 67
drwxr-xr-x 2 olchansk users    9 Sep  1 16:22 bin
drwxr-xr-x 3 olchansk users   15 Sep  1 16:23 data
drwxr-xr-x 4 olchansk users    4 Sep  1 16:22 lib
drwxr-xr-x 2 olchansk users  644 Sep  1 16:22 payload
drwxr-xr-x 2 olchansk users    7 Sep  1 16:22 scripts
drwxr-xr-x 4 olchansk users    4 Sep  1 16:22 tps
-rwxr-xr-x 1 olchansk users 3256 Nov 18  2020 xsetup
daq13:2020.2$ 
./xsetup
spinned loading installation data
xilinx design tools 2022.1 now available -> say continue
"welcome" -> next
"select product" -> vivado -> next -> vivado hl system edition -> next
select devices: only zynq ultrascale+ mpsoc -> next
select destination: /opt/Xilinx (as root, mkdir /opt/Xilinx, chmod olchansk.users /opt/Xilinx)
install ...
complete
move /home/olchansk/Xilinx/Downloads/2020.2 to /daq/daqstore/olchansk/Xilinx/Downloads/
  • install petalinux 2020.2
./xsetup
"a newer version is available" -> say "continue"
next
"select product to install" -> select Petalinux (Linux only) -> next
"select destination directory" -> select "/opt/Xilinx" (disk space required 2.64 GB) -> next
"summary" -> install ...
error about missing /tmp/tmp-something files
"installation completed successfully" (hard to dismiss, "ok" button is partially cut-off)
done?
I think it failed, /opt/Xilinx/PetaLinux/2020.2/bin is empty except for petalinux-v2020.2-final-installer.run
try to run it by hand, same error about /tmp/tmp-something files. strange...
notice it complains about "truncate", which truncate finds ~/bin/truncate, get rid of it,
try again
now complains about missing texinfo and zlib1g:i386
apt install texinfo -> ok
apt install zlib1g:i386 -> installs bunch of gcc stuff -> ok
try again
reports "already installed" -> delete /opt/Xilinx/.xinstall/PetaLinux_2020.2/, delete entries in ~/.Xilinx/registry/installedSW.xml
try again
success
  • install vivado 2022.1 and petalinux 2022.1 - everything is pretty much the same

Petalinux

  • cd PetaLinux_GDM_CDM
  • petalinux-config
  • enable i2c MAC address and DHCP
git clone https://bitbucket.org:/team-ds-dm/ds-dm-u-boot-xlnx.git
cd ds-dm-u-boot-xlnx
git checkout ds-dm-u-boot-xlnx

linux-components ->
uboot -> ext-local-src
external u-boot local source -> ds-dm-u-boot-xlnx (path to the customized uboot git repository)
  • enable DHCP
Subsystem AUTO Hardware Settings -> Ethernet Settings
randomize MAC address -> NO
ethernet mac address -> leave empty
obtain ip address automatically -> YES
  • set hostname and product names
Firmware Version Configuration ->
Host name -> "ds-dm"
Product name -> "Petalinux_GDM_CDM"
  • configure linux kernel
petalinux-config -c kernel
  • enable NFS-Root
petalinux-config
Image Packaging Configuration > Root File System Type -> set to NFS
Location of NFS root directory set to "/nfsroot"

petalinux-config -c kernel
Networking support > IP: kernel level configuration
enable DHCP, BOOTP, RARP
File systems > Network file systems > Root file systems on NFS
  • manually fix linux kernel command line:
grep nfsroot PetaLinux_GDM_CDM/project-spec/configs/config
edit CONFIG_SUBSYSTEM_BOOTARGS_GENERATED to read
earlycon console=ttyPS0,115200 clk_ignore_unused panic=60 root=/dev/nfs nfsroot=/nfsroot/%s ip=dhcp rw
  • check configuration in
    • PetaLinux_GDM_CDM/project-spec/configs/config
    • PetaLinux_GDM_CDM/project-spec/configs/rootfs_config
    • PetaLinux_GDM_CDM/components/plnx_workspace/device-tree/device-tree/system-conf.dtsi

JTAG server

localhost:3121

ds20k block

module ds20k
  (
   //    CLOCK INPUTs
   input wire clk,
   input reset, // pulse for power-up reset
   input wire pll_is_locked, // clock cleaner PLL is locked to selected input clock

   //    REGISTER_DATA
   
   input wire [255:0] [31:0] register_data_in,
   output reg [255:0] [31:0] register_data_out,
   input wire register_write_strobe, // pulse when AXI write transaction puts new data in register_data_in
   input wire register_read_ack, // pulse after AXI read transaction captures data from register_data_out, used to read from FIFO
   
   //    GDM QSFP FIBER LINKS
   output reg [11:0] [15:0] qsfp_tx_data,
   output reg [11:0] [1:0]  qsfp_tx_ctrl,
   input wire [11:0] [15:0] qsfp_rx_data_error, // not sure what this is.
   input wire [11:0] [15:0] qsfp_rx_data,
   input wire [11:0] [1:0]  qsfp_rx_ctrl,
   input wire [11:0] qsfp_rx_is_good, // single bit indicating that RX link is up and data is good.

   // CDM SFP FIBER LINKS
   output reg [15:0] sfp_tx_data,
   output reg [1:0]  sfp_tx_ctrl,
   input wire [15:0] sfp_rx_data,
   input wire [1:0]  sfp_rx_ctrl,
   input wire        sfp_rx_is_good, // single bit indicating that RX link is up and data is good.
      
   //    VX_RXs
   input wire [3:0] vx1_rx,
   input wire [3:0] vx2_rx,  
   input wire [3:0] vx3_rx,  
   input wire [3:0] vx4_rx,  
   input wire [3:0] vx5_rx,  
   input wire [3:0] vx6_rx,  
   input wire [3:0] vx7_rx,  
   input wire [3:0] vx8_rx,
   input wire [3:0] vx9_rx,  
   input wire [3:0] vx10_rx,    
   input wire [3:0] vx11_rx,
   input wire [3:0] vx12_rx,
   
   //    VX_TXs
   output reg [2:0] vx1_tx_out,
   output reg [2:0] vx2_tx_out,
   output reg [2:0] vx3_tx_out,
   output reg [2:0] vx4_tx_out,
   output reg [2:0] vx5_tx_out,
   output reg [2:0] vx6_tx_out,
   output reg [2:0] vx7_tx_out,
   output reg [2:0] vx8_tx_out,
   output reg [2:0] vx9_tx_out,
   output reg [2:0] vx10_tx_out,
   output reg [2:0] vx11_tx_out,
   output reg [2:0] vx12_tx_out,

   // remove input wire gdm_trg,
   // remove input wire gdm_tsm,
   
   //    LEMO INPUTs
   input wire [4:1] ext_in_lv_async, // direct connection to LEMO connectors, not clocked
    
   //    LEMO OUTPUTs
   output reg [2:1] ext_out, // direct connection to LEMO connectors, not clocked
    
   //    FRONT PANEL LEDs
   output reg [3:0] fp_led_out, // direct connection to LEMO connectors, not clocked

   //    trigger and tsm output
   // remove output reg trg_out,
   // remove output reg tsm_out
   );

world view

Note:

  • red lines: clocks
  • green lines: AXI/Avalon packet streams
  • blue lines: serial data

GDM-CDM-VX.drawio.svg

description

same thing, in words:

detector
digitizer, 125 MHz
digital filter
digital discriminator
hit map, 64 bits at 125 MHz (could be 250 MHz, filter and discriminator clock)
packetizer, 64 bits -> id, timestamp, 8x 8-bit words, eop
8/10 serializer, 12.5 MHz parallel in, 125 MHz serial out
lvds line to CDM vx_rx
BBB: also VX busy to lvds line to CDM vx_rx, do not want to depend on serial comm for vx busy, do not want to inject async data into the hit map packet stream
--- CDM
lvds line capture in IBUF register, vxN_rx clock, 125 MHz clock, from PLL with adjustable phase, scan phase to find sweet spot
vx rx 10/8 deserializer, vxN_rx clock, stobes out parallel data every 10 clocks at 12.5 MHz
vx rx phase transfer from vxN_rx clock to main CDM clock, have 10 clocks for transfer to happen
from here everything is on the CDM main clock
vx rx packet adapter, 12.5 MHz 8-bit packets to 125 MHz 16-bit packets, internal FIFO to avoid data overrun
sfp tx mux, all VX packet streams into one CDM sfp tx packet stream
BBB: capture VX RX busy to CDM main clock (IBUF register), grand-or becomes vx_rx_busy
sfp tx packetizer (data,eop,vx_rx_busy -> data,k)
sfp tx 16/20 serializer, 16 bit at 125 MHz in, 2500 MHz serial out (20 bits at 125 MHz)
sfp tx fiber link to GDM, 2 Gigabits/sec
--- GDM
qsfp rx deserializer, 16 bit at 125 MHz output on main GDM clock
qsfp rx depacketizer (data,k -> packet data,eop; qsfp_rx_busy)
qsfp rx demux, hit map packets routed to GDM trigger logic block
GDM trigger logic block looks at hit map, generates yes/no trigger decision, encodes it as a trigger packet
TSM generator encodes GPS time data as a TSM packet
qsfp tx mux - trigger packets, tsm packets, etc to qsfp tx packet stream
qsfp tx packetizer (data,eop;trg,tsm,bsy -> data,k)
NB: the same tx data is sent to all 12 qsfp tx ports, to make sure we do not accidentally desync the CDMs.
qsfp tx 16/20 serializer, 16-bit at 125 MHz to 20-bit at 250 MHz to 2500 MHz serial out
qsfp tx fiber link to CDM, 2 Gigabits/sec
--- CDM
sfp rx 20/16 deserializer, 16-bit at 125 MHz
sfp rx depacketizer, (data,k -> data,eop;trg_in,tsm_in,bsy_in)
sfp rx demux (in reality, noop, all packets go to same place, vx tx)
vx tx mux (packets from GDM, packets with simulated waveforms from CDM midas frontend via AXI FIFO)
vx tx packet adapter 16-bit at 125 MHz to 8-bit at 12.5 MHz strobed every 10 clocks. NB: most important, this 10-clock strobe runs in sync between all CDMs!
vx tx phase transfer from main CDM clock to vxN_tx clock, have 10 clocks for transfer to happen
from here we run on the vxN_tx clock
vx txN serializer, 8-bit at 12.5 MHz to 125 MHz serial
vx_txN OBUF register, vxN_rx clock, 125 MHz clock, from PLL with adjustable phase, scan phase to find sweet spot
lvds line to vx
BBB: bsy_in from GDM is converted from pulse to level, goes out lvds line to vx, sync to vxN_tx clock
TTT: trg_in from GDM is a pulse, does out lvds line to vx, sync to vxN_tx clock.
NB: tsm is always a packet, bsy is always a signal (no packet), trg can be a packet or signal.
--- VX
lvds data captured by 125 MHz ADC sampling clock (CAEN base firmware logic)
lvds data connected to Yair's block
10/8 deserializer
depacketizer (data,k -> data,eop) to avoid accidental desync, we do not send any no trg, no tsm, no bsy K-codes.
demux
trigger packets go their way (4x 64 bit words of data go to event header: timestamps, hitmap data)
tsm packets go their way (4x 64 bit words of data go to tsm event header: timestamps, GPS time data)
BBB: bsy from lvds line stops waveform acquisition
TTT: trg from lvds line cause waveform acquisition, same as trg packet, but has no timestamp and other data attached to it.

Firmware registers

Block 0

0 | ALL | ALL | RO | USR_ACCESSE2 see https://docs.xilinx.com/r/en-US/ug974-vivado-ultrascale-libraries/USR_ACCESSE2

Block 1

Block 2

Block 3

DS20k block register map

  • busybox devmem 0x80013000 32

Note: R=readable, W=writable, L=latched by CMD_LATCH, B=reset on begin of run

reg | version    | xDM | xx | description
  0 | 0x20230731 | ALL | RO | ds20k version
  0 | 0x20240118 | ALL | RW | ds20k version and command
  1 | 0x20230731 | ALL | RW | scratch read/write register
  2 | 0x20230731 | ALL | RW | configure inputs and outputs
  3 | 0x20230731 | ALL | RW | FP_LED mux
  4 | 0x20230731 | ALL | RW | EXT_OUT mux
  5 | 0x20230731 | ALL | RO | VX_RX state
  6 | 0x20230731 | ALL | RO | VX_RX, LEMO_IN, VX_TX, FP_LED, EXT_OUT state
  7 | 0x20230731 | ALL | RW | LED_OUT, EXT_OUT, VX_TX outputs
  8 | 0x20230731 | ALL | RW | VX_TX mux and config
  9 | 0x20230731 | ALL | RW | trigger config
 10 | 0x20231013 | ALL | RO | status register
 11 | 0x20230731 | ALL | RO | trigger counter
 12 | 0x20230731 | ALL | RO | time slice marker counter
 13 | 0x20240814 | ALL | RO | GPS 1pps period, 125 MHz
 14 | 0x20240814 | ALL | RO | Ru clock 1pps period, 125 MHz
 15 | 0x20230811 | CDM | RO | SFP RX status
 16 | 0x20230811 | CDM | RW | SFP TX control
 17 | 0x20230811 | GDM | RO | QSFP RX data 0, 1
 18 |            |.    |.   | 2, 3
 19 |            |.    |.   | 4, 5
 20 |            |.    |.   | 6, 7
 21 |            |     |.   | 8, 9
 22 |            |.    |.   | 10, 11
 23 | 0x20230811 | GDM | RW | QSFP TX control
 24 | 0x20231013 | ALL | RW | trigger pulser period
 25 | 0x20231013 | ALL | RW | trigger pulser burst control
 26 | 0x20231013 | ALL | RW | tsm pulser period
 27 | 0x20231204 | ALL | RW | data fifo CPU to FPGA
 28 | 0x20231204 | ALL | RW | packet loopback control
 28 | 0x20240118 | ALL | RW | data fifo FPGA to CPU
 29 | 0x20231208 | GDM | RW | bitmap of active qsfp ports
 29 | 0x20240118 | ALL | RW | packet loopback control
 29 | 0x20240510 | ALL | RW | packet routing
 30 | 0x20231208 | GDM | RO | qsfp link status ports 0..7
 31 | 0x20231208 | GDM | RO | qsfp link status ports 8..11
 32 | 0x20240118 | GDM | RW | enabled QSFP ports
 33 | 0x20240118 | CDM | RW | enabled VX ports
 34,35 | 0x20240118 | ALL | RO | time stamp 64 bits
 36,37 | 0x20240118 | ALL | RO | old time stamp
 38,39,40 | 0x20240118 | CDM | RO | VX busy counters
 41,42,43 | 0x20240118 | GDM | RO | QSFP busy counters
 44 | 0x20240118 | CDM | RO | cdm_bsy_up_counter and cdm_bsy_pulse_counter
 45 | 0x20240118 | CDM | RO | cdm_veto_pulse_counter and cdm_veto_up_counter
 46 | 0x20240118 | GDM | RO | gdm_bsy_pulse_counter and gdm_bsy_up_counter
 47 | 0x20240118 | GDM | RO | gdm_bsy_refresh_counter
 48 | 0x20240118 | GDM | RO |  gdm_veto_up_counter and gdm_veto_pulse_counter
 49,50,51 | 0x20240424 | CDM | RO | VX RX serial data monitor, 8 bits per VX port
 52,53    | 0x20240424 | CDM | RO | VX serial link status, 4 bits per VX port
 54 | 0x20240424 | CDM | RO | VX TX serial data monitor
 55 | 0x20240430 | ALL | RO | QSFP, SFP and VX link loss counters
 56 | 0x20240510 | ALL | RO | sfp_rx_packet_counter
 57 | same       | ALL | RO | sfp_tx_packet_counter
 58 | same       | ALL | RO | qsfp_rx_packet_counter[0]
 59 | same       | ALL | RO | qsfp_tx_packet_counter
 60 | same       | ALL | RO | vx_rx_packet_counter[0]
 61 | same       | ALL | RO | vx_tx_packet_counter
 62 | 0x20240719 | CDM | RO | cdm_hitmap_period, ports 0, 1
 63 | same       | CDM | RO | ports 2, 3
 64 | same       | CDM | RO | ports 4, 5
 65 | same       | CDM | RO | ports 6, 7
 66 | same       | CDM | RO | ports 8, 9
 67 | same       | CDM | RO | ports 10, 11
 68 | 0x20240814 | ALL | RW | GPS control and status
 69 | 0x20241104 | CDM | RO | vx_tx_trg_packet_counter, counter of TRG packets CDM->VX
 70 | 0x20241104 | CDM | RO | vx_tx_tsm_packet_counter, counter of TSM packets CDM->VX
 71 | 0x20241104 | ALL | RO | packet error bits
 72,73 | 0x20241104 | CDM | ROL | vx_tx_trg_data_latched[63:0] trigger packet data
 74,75 | 0x20241104 | CDM | ROL | vx_tx_tsm_data_latched[63:0] tsm packet data (truncated to 64 bits)
 76 | 0x20241104 | CDM | ROL | cdm_hitmap_trigger_counter_latched, counter of hitmap triggers generated in the CDM
 77,78,79 | 0x20241104 | CDM | ROL | vx_rx_hitmap_data_latched | VX_RX 80 bits of HITMAP packet from VX

Register 0 0x80013000 ds20k version

on read: ds20k version 0xYYYYMMDD

on write:

  • 0 - noop - as of version 0x20240118, write a zero after writing a command
  • 1 - cmd_reset - reset logic to good state
  • 2 - cmd_arm_ts - arm timestamp reset
  • 3 - cmd_trg - issue a trigger
  • 4 - cmd_tsm - issue a tsm
  • 5 - cmd_vx_rx_reset - reset the VX receive path
  • 6 - cmd_vx_tx_reset - reset the VX transmit path
  • 7 - cmd_hitmap_trg - generate a hitmap trigger and data packet
  • 8 - cmd_trg_pulser_reset - reset the trigger pulser
  • 9 - cmd_tsm_pulser_reset - reset the tsm pulser
  • 10 - cmd_bor_start - start begin-of-run trigger sequence
  • 11 - cmd_bor_clear - after run has started, clear begin-of-run status bits
  • 12 - cmd_latch - latch counters & etc into AXI registers for coherent readout

Register 1 0x80013004 scratch

scratch read-write register

Register 2 0x80013008 input and output config

bit | version | fpga name       | description
  0 | ALL     | lemo_enable     | enable LEMO input 1
  1 |         |                 | 2
  2 |         |                 | 3
  3 |         |                 | 4
  4 | ALL     | lemo_invert     | invert LEMO input 1
  5 |         |                 | 2
  6 |         |                 | 3
  7 |         |                 | 4
  9 | ALL     | ext_out_disable | disable LEMO output 1
 10 |         |                 | 2
 11 | ALL     | ext_out_invert  | invert LEMO output 1
 12 |         |                 | 2

Register 3 0x8001300C FP_LED control

wire [15:0] led_out_mux_sel  = register_data_in[3][15:0];
wire [3:0]  led_out_invert   = register_data_in[3][19:16];
led_out_mux_sel is 4 groups (one per LED) of 4 bits (choice 0..15):
mux | version    | fpga name       | description
  0 | ALL        |                 | power on default
  1 | ALL        | led_out_reg     | register 7 bits
  2 | 0x20231013 | pll_locked      | clock chip PLL is locked
  3 | 0x20231013 | sfp_link_status | SFP link is good
  3 | 0x20240118 | sfp_link_status or qsfp_tx_link_rx_status | SFP/QSFP link is good
  4 | ALL        | lemo_in_sync[1] | LEMO input 1
  5 | ALL        | lemo_in_sync[2] | LEMO input 2
  6 | ALL        | lemo_in_sync[3] | LEMO input 3
  7 | ALL        | lemo_in_sync[4] | LEMO input 4
  8 | ALL        | ext_out[1]      | LEMO output 1
  9 | ALL        | ext_out[2]      | LEMO output 2
  A | 0x20231013 | trg_in          | trigger
  B | 0x20231013 | tsm_in          | time slice marker
  C | 0x20240118 | gdm_bsy         | GDM busy: OR of all CDM busy
  D | 0x20240118 | cdm_bsy         | CDM busy: OR of all VX busy
  E | 0x20240118 | cdm_veto        | GDM busy -> GDM veto -> CDM veto -> VX trigger veto
  F | ALL        |                 | fixed logic level 1

Register 4 0x80013010 LEMO OUT control

wire [7:0] ext_out_mux_sel = register_data_in[4][7:0];
ext_out_mux_sel is 2 groups (one per LEMO) of 4 bits (choice 0..15):

mux | version    | fpga name       | description
  0 | ALL        |                 | power on default
  1 | ALL        | ext_out_reg     | register 7
  2 | ALL        | trg_pulser      | pulser trigger
  3 | 0x20240724 | vx1_tx_out[2]   | vx1 serial data out
  4 | 0x20240724 | vx1_rx[1]       | vx1 serial data in
  5 | 0x20240724 | vx_rx_iob[0]    | vx1 serial data in captured by IOB register
  6 | ALL        | lemo_in_async[1]| test synchronizer
  7 | ALL        | lemo_in_sync[1] | test synchronizer
  8 | 0x20240724 | trg_in_pulse    | trigger signal
  9 | 0x20240724 | tsm_in_pulse    | time slice marker signal
  A | 0x20240118 | cdm_bsy         | CDM busy from VX
  B | 0x20240118 | gdm_bsy         | GDM busy from CDM
  C | 0x20240118 | cdm_veto        | veto from GDM to CDM to VX
  D | 0x20240118 | vx1_rx[1]       | serial data VX to CDM
  E | not used (sink)
  F | ALL        | 1               | fixed logic level 1

Register 5 0x80013014 VX_RX status

assign register_data_out[5] = {
                vx8_rx[3], vx8_rx[2], vx8_rx[1], vx8_rx[0],
                vx7_rx[3], vx7_rx[2], vx7_rx[1], vx7_rx[0],
                vx6_rx[3], vx6_rx[2], vx6_rx[1], vx6_rx[0],
                vx5_rx[3], vx5_rx[2], vx5_rx[1], vx5_rx[0],
                vx4_rx[3], vx4_rx[2], vx4_rx[1], vx4_rx[0],
                vx3_rx[3], vx3_rx[2], vx3_rx[1], vx3_rx[0],
                vx2_rx[3], vx2_rx[2], vx2_rx[1], vx2_rx[0],
                vx1_rx[3], vx1_rx[2], vx1_rx[1], vx1_rx[0]
                };

Register 6 0x80013018 VX_RX, LEMO_IN, VX_TX, FP_LED, EXT_OUT state

assign register_data_out[6] = {
                vx2_tx_out[2], vx2_tx_out[1], vx2_tx_out[0], vx1_tx_out[2],
                vx1_tx_out[1], vx1_tx_out[0], ext_out[2], ext_out[1],
                fp_led_out[3], fp_led_out[2], fp_led_out[1], fp_led_out[0],
                ext_in_lv[4], ext_in_lv[3], ext_in_lv[2], ext_in_lv[1],
                vx12_rx[3], vx12_rx[2], vx12_rx[1], vx12_rx[0],
                vx11_rx[3], vx11_rx[2], vx11_rx[1], vx11_rx[0],
                vx10_rx[3], vx10_rx[2], vx10_rx[1], vx10_rx[0],
                vx9_rx[3], vx9_rx[2], vx9_rx[1], vx9_rx[0]
                };
bit | version | fpga name       | description
  0 | ALL     | vx9_rx          | VX_RX
  1 |         |                 | 
  2 |         |                 | 
  3 |         |                 | 
  4 | ALL     | vx10_rx         | VX_RX
  5 |         |                 | 
  6 |         |                 | 
  7 |         |                 | 
  8 | ALL     | vx11_rx         | VX_RX
  9 |         |                 | 
 10 |         |                 | 
 11 |         |                 | 
 12 | ALL     | vx12_rx         | VX_RX
 13 |         |                 | 
 14 |         |                 | 
 15 |         |                 | 
 16 | ALL     | ext_in_lv       | LEMO inputs
 17 |         |                 | 
 18 |         |                 | 
 19 |         |                 | 
 20 | ALL     | FP_LED          | FP_LEDs
 21 |         |                 | 
 22 |         |                 | 
 23 |         |                 | 
 24 | ALL     | ext_out[1]      | LEMO outputs
 25 |         | ext_out[2]      | 
 26 | ALL     | vx1_tx          | VX1_TX
 27 |         |                 | 
 28 |         |                 |
 29 | ALL     | vx2_tx          | VX2_TX 
 30 |         |                 | 
 31 |         |                 | 

Register 7 0x8001301C LED_OUT, EXT_OUT, VX_TX outputs

   wire [3:0] led_out_reg = register_data_in[7][3:0];
   wire [2:1] ext_out_reg = register_data_in[7][5:4];
   // register_data_in[7][6];
   // register_data_in[7][7];
   wire [7:0] vx_tx_out_reg = register_data_in[7][15:8];
bit | version | fpga name       | description
  0 | ALL     | led_out_reg     | FP_LED 1
  1 |         |                 | 2
  2 |         |                 | 3
  3 |         |                 | 4
  4 | ALL     | ext_out_reg     | LEMO OUT 1
  5 |         |                 | 2
  6 | -       |                 | 
  7 | -       |                 | 
  8 | ALL     | vx_tx_out_reg   | VX1_TX 0
  9 |         |                 | 1
 10 |         |                 | 2
 11 |         |                 | -
 12 | ALL     |                 | VX2_TX 0
 13 |         |                 | 1
 14 |         |                 | 2
 15 |         |                 | -
 16 | -       |                 |
 17 |         |                 | 
 18 |         |                 | 
 19 |         |                 | 
 20 |         |                 |
 21 |         |                 | 
 22 |         |                 | 
 23 |         |                 | 
 24 |         |                 |
 25 |         |                 | 
 26 |         |                 |
 27 |         |                 | 
 28 |         |                 |
 29 |         |                 | 
 30 |         |                 | 
 31 |         |                 | 

Register 8 0x80013020 VX_TX config

wire [3:0] vx_tx_mux_sel = register_data_in[8][3:0];
vx_tx_loopback           = register_data_in[8][31];
vx_tx_mux_sel is 4 bits (choice 0..15):
0 - power on default, control by vx_tx_out_reg
1 - GDM
2 - CDM
3 - pulser loopback test
4 - pulser loopback test
5 - 62.5 MHz output
6 - 125 MHz output
7 - trg, tsm, serial
8 - trg, tsm, lvds serial rx to serial tx loopback
9 - GPS box control (ds20k rev 0x20240814)
10
11
12
13
14
15 - production config: trg, veto, serial

Register 9 trg and tsm source

from version 0x20240724

   wire [15:0] trg_src_mask      = register_data_in[9][15:0];
   wire [31:16] tsm_src_mask      = register_data_in[9][31:16];
   wire [15:0]      trg_src_bits =
                    {
                     1'b0,            // 15
                     1'b0,            // 14
                     vx_tx_tsm_done,  // 13
                     vx_tx_trg_done,  // 12

                     1'b0, // gdm_hitmap_trigger, // 11
                     cdm_hitmap_trigger, // 10
                     sfp_rx_tsm,      // 9
                     sfp_rx_trg,      // 8

                     sfp_rx_data[1],  // 7
                     sfp_rx_data[0],  // 6
                     tsm_pulser,      // 5
                     trg_pulser,      // 4

                     lemo_in_sync[4], // 3
                     lemo_in_sync[3], // 2
                     lemo_in_sync[2], // 1
                     lemo_in_sync[1]  // 0
                     };
   
   wire [15:0]      trg_bits = trg_src_bits & trg_src_mask;
   wire [15:0]      tsm_bits = trg_src_bits & tsm_src_mask;

before that:

   wire [7:0] trg_src_mask      = register_data_in[9][7:0];
   wire [7:0] tsm_src_mask      = register_data_in[9][15:8];
   wire       trg_pulser_enable = register_data_in[9][16];
   wire       tsm_pulser_enable = register_data_in[9][17];
   wire       trg_software      = register_data_in[9][18];
   wire       tsm_software      = register_data_in[9][19];
   // bits 20:31 not used
wire [7:0]       xxx_src_bits =
                    {
                     sfp_rx_data[1],
                     sfp_rx_data[0],
                     tsm_pulser & tsm_pulser_enable,
                     trg_pulser & trg_pulser_enable,
                     lemo_in_sync[4],
                     lemo_in_sync[3],
                     lemo_in_sync[2],
                     lemo_in_sync[1]
                     };
trg_src_mask and tsm_src_mask bits:
0 - LEMO IN 1
1 - LEMO IN 2
2 - LEMO IN 3
3 - LEMO IN 4
4 - trg_pulser
5 - tsm_pulser
6 - sfp_rx_data[0] // to become sfp_trg_in, selected from sfp_rx_data[0], cdm_rx trg_out and gdm trigger packet
7 - sfp_rx_data[1] // to become sfp_tsm_in, selected from sfp_rx_data[1], cdm_rx tsm_out and gdm tsm packet

Register 10 0x80013028 status register

bit | version    | fpga name       | description
  0 | 0x20231013 | pll_locked      | clock chip PLL is locked
  1 | 0x20240118 | ts_reset_armed  | timestamp reset is armed
  2 | 0x20240118 | qsfp_tx_link_rx_status | QSFP link status is good for all enabled ports
  3 | 0x20240424 | vx_tx_link_rx_status   | VX link status is good for all enabled ports
  4 | 0x20240118 | cdm_bsy         | VX busy grand-or
  5 | 0x20240118 | gdm_bsy         | QSFP busy grand-or 
  6 | 0x20240118 | gdm_veto        | gdm_veto = gdm_busy 
  7 | 0x20240118 | cdm_veto        | CDM veto from GDM to VX 
  8 | 0x20240725 | bor_started     | begin-of-run sequence started
  9 | 0x20240725 | bor_finished    | begin-of-run sequence fininished, see commands 10 and 11 
 10 |         |                 | 
 11 |         |                 | 
 12 |         |                 | 
 13 |         |                 | 
 14 |         |                 | 
 15 |         |                 | 
 16 |         |                 | 
 17 |         |                 | 
 18 |         |                 | 
 19 |         |                 | 
 20 |         |                 | 
 21 |         |                 | 
 22 |         |                 | 
 23 |         |                 | 
 24 |         |                 | 
 25 |         |                 | 
 26 |         |                 | 
 27 |         |                 | 
 28 |         |                 |
 29 |         |                 | 
 30 |         |                 | 
 31 |         |                 | 

Register 11 0x8001302C trg_counter

trigger counter

Register 12 0x80013030 tsm_counter

time slice marker counter

Register 13 0x80013034 GPS 1pps period

GPS 1pps period in 8 ns clocks

Register 14 0x80013038 Rb clock 1pps period

PRS-10 Rb clock 1pps output period in 8 ns clocks

Register 15 0x8001303C SFP RX status

bit | ds20k version | fpga signal name | description
  0 | ALL        | sfp_rx_data[15:0]   | cdm sfp received data
 16 | same       | sfp_rx_data_is_k[0] | 
 17 | same       | sfp_rx_data_is_k[1] | 
 18 |            | 0                   | 
 19 | 0x20231204 | sfp_rx_sel_lpb      | sfp tx->rx loopback
 20 | 0x20231013 | sfp_link_status     | sfp link connected, exchanging data
 21 | same       | sfp_link_rx_status  | sfp link receiving correct idle pattern from GDM TX
 22 | same       | sfp_link_error      | sfp link receiver error (badk or overflow)
 23 | same       | sfp_rx_data_error   | sfp transceiver state machine is in error state
 24 |            |                     | 
 25 |            |                     | 
 26 |            |                     | 
 27 |            |                     | 
 28 |            |                     |
 29 |            |                     | 
 30 |            |                     | 
 31 |            |                     | 

Register 16 SFP TX control

   wire [15:0] sfp_tx_data_reg = register_data_in[16][15:0];
   wire [1:0]  sfp_tx_ctrl_reg = register_data_in[16][17:16];
   // 18
   // 19
   // 20:23
   wire qsfp_tx_enable_trg     = register_data_in[23][24]; // enable QSFP TX trg_in_pulse k-code
   wire qsfp_tx_enable_tsm     = register_data_in[23][25]; // enable QSFP TX tsm_in_pulse k-code
   // 26
   // 27
   //wire sfp_rx_sel_loopback    = register_data_in[16][28]; // TX->RX serial loopback
   wire sfp_tx_sel_loopback    = register_data_in[16][29]; // RX->TX serial loopback
   wire sfp_tx_sel_trg         = register_data_in[16][30]; // 16 individual bits
   wire sfp_tx_sel_reg         = register_data_in[16][31]; // from register

Register 17-22 QSFP RX data

QSFP RX data links 0..11

Register 23 QSFP TX control

   wire [15:0] qsfp_tx_data_reg = register_data_in[23][15:0];
   wire [1:0]  qsfp_tx_ctrl_reg = register_data_in[23][17:16];
   wire qsfp_rx_sel_lpb         = register_data_in[23][28]; // TX->RX loopback
   wire qsfp_tx_sel_lpb         = register_data_in[23][29]; // RX->TX loopback
   wire qsfp_tx_sel_trg         = register_data_in[23][30]; // 16 individual bits
   wire qsfp_tx_sel_reg         = register_data_in[23][31]; // data from register

Register 24 0x80013060 trigger pulser period

trigger pulser period in units of 8 ns (125 MHz clock)

Register 25 0x80013064 trigger burst pulser

   wire [7:0]         conf_burst_count  = conf_pulser_burst_ctrl[31:24];
   wire [23:0]        conf_burst_period = conf_pulser_burst_ctrl[23:0];

Register 26 0x80013068 tsm pulser period

time slice marker period in units of 8 ns (125 MHz clock)

Register 27 0x8001306C data write fifo

   wire        fifo_reset = register_data_in[27][31];
   wire        fifo_to_fpga_wr1 = register_data_in[27][27];
   wire        fifo_to_fpga_wr2 = register_data_in[27][26];
   wire [16:0] fifo_to_fpga_din = register_data_in[27][16:0];
   assign register_data_out[27][31:24] = register_data_in[27][31:24]; // echo write bits
   assign register_data_out[27][23] = fifo_to_fpga_full;
   assign register_data_out[27][22] = fifo_to_fpga_empty;

Register 28 0x80013070 data read fifo

   wire        fifo_reset = register_data_in[28][31];
   wire        fifo_from_fpga_rd1 = register_data_in[28][25];
   wire        fifo_from_fpga_rd2 = register_data_in[28][24];
   assign register_data_out[28][31:24] = register_data_in[28][31:24]; // echo write bits
   assign register_data_out[28][21] = fifo_from_fpga_full;
   assign register_data_out[28][20] = fifo_from_fpga_empty;
   assign register_data_out[28][16:0] = fifo_from_fpga_dout;

Register 29 0x80013074 packet routing

Control packet routing and loopbacks:

   wire [3:0]  dn_route_ctrl             = register_data_in[29][3:0];
   wire [3:0]  up_route_ctrl             = register_data_in[29][7:4];
   wire [3:0]  fifo_to_fpga_route_ctrl   = register_data_in[29][11:8];
   //wire [3:0]  spare_route_ctrl        = register_data_in[29][15:12];

   wire        dn_mux_trg_enable         = register_data_in[29][16];
   wire        dn_mux_tsm_enable         = register_data_in[29][17];
   wire        dn_mux_sfp_rx_fifo_enable = register_data_in[29][18];
   // 19
   // 20..23

   wire        up_mux_vx_rx_enable       = register_data_in[29][24];
   // 25
   // 26
   // 27
   wire        fifo_from_fpga_hitmap_enable       = register_data_in[29][28];
   // 29..31

fifo_to_fpga output routing:

  • 0 - to down packet mux
  • 1 - to up packet mux
  • 2 - to fifo_from_fpga mux
  • 3 - not used

down packet mux inputs:

  • fifo_to_fpga_0
  • trg_pkt16 enabled by dn_mux_trg_enable
  • tsm_pkt16 enabled by dn_mux_tsm_enable
  • sfp_rx_fifo_pkt16 enabled by dn_mux_sfp_rx_fifo_enable
  • up_pkt16_2 loopback from up packet mux

down packet mux output routing:

  • 0 - to vx_tx_pkt16 to VX TX (vx_link_tx and vx_ser_tx)
  • 1 - to fifo_from_fpga mux
  • 2 - to up packet mux loopback
  • 3 - to qsfp_tx_pkt16 to GDM QSFP TX (cdm_link_tx)

up packet mux inputs:

  • vx_rx_pkt16 enabled by up_mux_vx_rx_enable data from 12 VX RX links
  • fifo_to_fpga_1
  • dn_pkt16_2 loopback from down packet mux

up packet mux output routing:

  • 0 - to sfp_tx_pkt16 to CDM SFP TX (VX data to GDM)
  • 1 - to fifo_from_fpga mux
  • 2 - to down packet mux loop loopback
  • 3 - not used

fifo_from_fpga mux inputs:

  • fifo_to_fpga_2
  • dn_pkt16_1 from down packet mux
  • up_pkt16_1 from up packet mux
  • qsfp_tx_pkt16 from GDM QSFP link 0 (there is no GDM QSFP 12-to-1 mux)
  • hitmap_pkt16 enabled by fifo_from_fpga_hitmap_enable in register 29

Register 30 0x80013078 qsfp link status ports 0..7

assign register_data_out[30] = 
     {
       qsfp_rx_data_error[7], qsfp_link_error[7], qsfp_link_status[7], qsfp_link_rx_status[7], // 7
       qsfp_rx_data_error[6], qsfp_link_error[6], qsfp_link_status[6], qsfp_link_rx_status[6], // 6
       qsfp_rx_data_error[5], qsfp_link_error[5], qsfp_link_status[5], qsfp_link_rx_status[5], // 5
       qsfp_rx_data_error[4], qsfp_link_error[4], qsfp_link_status[4], qsfp_link_rx_status[4], // 4
       qsfp_rx_data_error[3], qsfp_link_error[3], qsfp_link_status[3], qsfp_link_rx_status[3], // 3
       qsfp_rx_data_error[2], qsfp_link_error[2], qsfp_link_status[2], qsfp_link_rx_status[2], // 2
       qsfp_rx_data_error[1], qsfp_link_error[1], qsfp_link_status[1], qsfp_link_rx_status[1], // 1
       qsfp_rx_data_error[0], qsfp_link_error[0], qsfp_link_status[0], qsfp_link_rx_status[0]  // 0
      };

Register 31 0x8001307C qsfp link status ports 8..11

assign register_data_out[31] = 
     {
       4'b0000,
       4'b0000,
       4'b0000,
       4'b0000,
       qsfp_rx_data_error[11], qsfp_link_error[11], qsfp_link_status[11], qsfp_link_rx_status[11], // 11
       qsfp_rx_data_error[10], qsfp_link_error[10], qsfp_link_status[10], qsfp_link_rx_status[10], // 10
       qsfp_rx_data_error[9],  qsfp_link_error[9],  qsfp_link_status[9],  qsfp_link_rx_status[9],  // 9
       qsfp_rx_data_error[8],  qsfp_link_error[8],  qsfp_link_status[8],  qsfp_link_rx_status[8]   // 8
      };

Register 32 0x80013080 bitmap of enabled qsfp ports

   wire [11:0]  qsfp_mask       = register_data_in[32][11:0];
   wire         qsfp_bsy_force  = register_data_in[32][12];
   // not used                  = register_data_in[32][15:13];
   wire [15:0]  gdm_veto_extend = register_data_in[32][31:16];

On the GDM:

qsfp_rx_bsy[11..0] are pulses received from the CDMs

qsfp_rx_bsy_or is the grand-or of qsfp_rx_bsy masked by qsfp_mask

if qsfp_rx_bsy_or is high, gdm_bsy goes up and stays up for vx_bsy_extend*2 clocks

gdm_veto = gdm_bsy (bsy of any one VX causes trigger veto to all of them)

gdm_veto transition 0->1 causes gdm_veto_pulse. as long as gdm_veto is high, gdm_veto_pulse is generated every gdm_veto_extend clocks

gdm_veto_pulse is sent to all CDMs.

For this to work right, cdm_bsy_extend should not be bigger than gdm_veto_extend.

Register 33 0x80013084 bitmap of enabled VX ports

   wire [11:0]  vx_mask       = register_data_in[33][11:0];
   wire         vx_bsy_force  = register_data_in[33][12];
   // not used                = register_data_in[33][15:13];
   wire [15:0]  vx_bsy_extend = register_data_in[33][31:16];

On the CDM:

cdm_bsy is a grand-or of all vx_bsy masked by vx_mask (list of active VXes).

vx_bsy_extend controls how often state of cdm_bsy is sent to the GDM. when cdm_bsy goes 0->1, we send a cdm_bsy_pulse and keep resending it every vx_bsy_extend clocks as long as cdm_bsy stays high.

cdm_bsy_pulse is sent to the GDM.

sfp_rx_veto is the received from the GDM

if sfp_rx_veto goes up, cdm_veto goes up and stays up for gdm_veto_extend clocks.

for this to work right, CDM gdm_veto_extend must be bigger than GDM gdm_veto_extend.

cdm_veto goes to VXes on v1_tx_out[1] which is LVDS input 13.

Register 34, 35 0x80013088, 8C current timestamp

current 64-bit timestamp, 125 MHz

Register 36, 37 0x80013090, 94 old timestamp

old 64-bit timestamp, 125 MHz. timestamp saved at run start when it is reset to 0.

Register 38, 39, 40 0x80013098, 9C, A0 VX busy counters

8 bits per VX port, counters overflow to 255, reset at run start.

Register 41, 42, 43 0x800130A4, A8, AC QSFP busy counters

8 bits per QSFP port, counters overflow to 255, reset at run start.

Register 44, 45, 46, 47, 48 0x800130B0, B4, B8, BC, C0 CDM and GDM busy and veto counters

  • cdm_busy = grand-or of all VX busy for enabled VXes
  • gdm_busy = grand-or of all CDM busy for enabled CDMs
  • gdm_veto = gdm_busy
 44 | lo 16 bits | cdm_bsy_up_counter      | CDM busy, increments when cdm_busy goes 0->1
 44 | hi 16 bits | cdm_bsy_pulse_counter   | CDM busy to GDM, increments for each cdm_bsy_pulse sent to the GDM

 45 | lo 16 bits | cdm_veto_pulse_counter  | CDM veto from GDM, increments for each sfp_rx_veto received from the GDM
 45 | hi 16 bits | cdm_veto_up_counter     | CDM veto to VX, increments each time cdm_veto is set to 1.

 46 | lo 16 bits | gdm_bsy_pulse_counter   | GDM busy from CDM, increments for each qsfp_rx_busy received from CDMs (unless they overlap)
 46 | hi 16 bits | gdm_bsy_up_counter      | GDM busy, increments each time gdm_bsy goes 0->1

 47 | lo 16 bits | gdm_bsy_refresh_counter | GDM busy, increments each time gdm_bsy is extended by new qsfp_rx_busy
 47 | hi 16 bits | spare                   |

 48 | lo 16 bits | gdm_veto_up_counter     | GDM veto, increments each time gdm_veto goes 0->1
 48 | hi 16 bits | gdm_veto_pulse_counter  | GDM veto to CDM, increments for each gdm_veto_pulse sent to the CDM

Register 49, 50, 51 0x800130xx VX RX serial data monitor

VX RX data, 8-bit per VX channel. k-bit is omitted.

   assign register_data_out[49][7:0]   = vx_rx_data[0]; // vx1
   assign register_data_out[49][15:8]  = vx_rx_data[1]; // vx2
   assign register_data_out[49][23:16] = vx_rx_data[2]; // vx3
   assign register_data_out[49][31:24] = vx_rx_data[3]; // vx4

   assign register_data_out[50][7:0]   = vx_rx_data[4]; // vx5
   assign register_data_out[50][15:8]  = vx_rx_data[5]; // vx6
   assign register_data_out[50][23:16] = vx_rx_data[6]; // vx7
   assign register_data_out[50][31:24] = vx_rx_data[7]; // vx8

   assign register_data_out[51][7:0]   = vx_rx_data[8]; // vx9
   assign register_data_out[51][15:8]  = vx_rx_data[9]; // vx10
   assign register_data_out[51][23:16] = vx_rx_data[10]; // vx11
   assign register_data_out[51][31:24] = vx_rx_data[11]; // vx12

Register 52, 53 VX link status

   assign register_data_out[52] = 
     {
       vx_rx_error[7], vx_link_error[7], vx_link_status[7], vx_link_rx_status[7], // 7
       vx_rx_error[6], vx_link_error[6], vx_link_status[6], vx_link_rx_status[6], // 6
       vx_rx_error[5], vx_link_error[5], vx_link_status[5], vx_link_rx_status[5], // 5
       vx_rx_error[4], vx_link_error[4], vx_link_status[4], vx_link_rx_status[4], // 4
       vx_rx_error[3], vx_link_error[3], vx_link_status[3], vx_link_rx_status[3], // 3
       vx_rx_error[2], vx_link_error[2], vx_link_status[2], vx_link_rx_status[2], // 2
       vx_rx_error[1], vx_link_error[1], vx_link_status[1], vx_link_rx_status[1], // 1
       vx_rx_error[0], vx_link_error[0], vx_link_status[0], vx_link_rx_status[0]  // 0
      };

   assign register_data_out[53] = 
     {
       //4'b0000,
       1'b0, ~vx_rx_deser_rdy[0], vx_rx_code_err[0], vx_rx_disp_err[0],
       //4'b0000,
       //4'b0000,
       //4'b0000,
       vx_rx_monitor[0],
       vx_rx_error[11], vx_link_error[11], vx_link_status[11], vx_link_rx_status[11], // 11
       vx_rx_error[10], vx_link_error[10], vx_link_status[10], vx_link_rx_status[10], // 10
       vx_rx_error[9],  vx_link_error[9],  vx_link_status[9],  vx_link_rx_status[9],  //  9
       vx_rx_error[8],  vx_link_error[8],  vx_link_status[8],  vx_link_rx_status[8]   //  8
      };

vx_rx_monitor (12-bit) is from deserializer_10b.sv:

   assign monitor_out[9:0] = lastByte[9:0];
   assign monitor_out[10]  = comma;
   assign monitor_out[11]  = ready;

Register 54 VX TX serial data monitor

  • contents of vx_tx_monitor from vx_ser_tx.sv:
   assign monitor_out[8:0]   = data_to_encoder; // 8-bit + k
   assign monitor_out[9]     = valid;
   assign monitor_out[15:10] = 0;
   assign monitor_out[25:16] = encoded_data; // 10-bit
   assign monitor_out[26]    = encoded_valid;
   assign monitor_out[27]    = 0;
   assign monitor_out[31:28] = 0;

Register 55 QSFP, SFP, VX link loss counters

assign register_data_out[55] = {
  vx_rx_error_counter,
  qsfp_link_rx_status_drop_counter,
  sfp_link_rx_status_drop_counter,
  vx_link_rx_status_drop_counter
};
24..31 - CDM VX RX error counters, count any errors in the VX RX data path (bad serial data, fifo overflow, etc)
16..23 - GDM QSFP link loss counter, increments on qsfp_tx_link_rx_status 1->0 (reg10)
 8..15 - CDM SFP  link loss counter, increments on sfp_link_rx_status     1->0 (reg15)
 0...7 - CDM VX   link loss counter, increments on vx_tx_link_rx_status   1->0 (reg10)

Register 68 GPS control and status

assign register_data_out[68] =
     {
      8'b00000000,      // 23+8
      rb_1pps_counter,  // 16+8 bits
      gps_1pps_counter, // 8+8 bits
      1'b0,
      1'b0,
      rb_ser_in,   // 5
      gps_data_in, // 4
      gps_aux_out, // 3
      gps_aux_in,  // 2
      rb_1pps_in,  // 1
      gps_1pps_in  // 0
      };

Register 71 packet error bits

assign register_data_out[71] =
     {
      8'b00000000,  // 23+8 bits
      8'b00000000,  // 16+8 bits
      8'b00000000,  //  8+8 bits
      1'b0, // 7
      1'b0, // 6
      1'b0, // 5
      1'b0, // 4
      cdm_hitmap_encode_error_latch, // 3
      cdm_hitmap_pkt16_error_latch,  // 2
      vx_tx_tsm_pkt8_error_latch,    // 1
      vx_tx_trg_pkt8_error_latch     // 0
      };

Firmware registers branch develop_ko

Register map

  0 | ALL | ALL | RO | USR_ACCESSE2 see https://docs.xilinx.com/r/en-US/ug974-vivado-ultrascale-libraries/USR_ACCESSE2
  1 | ALL | ALL | RW | read write scratch register
  2 | ALL | CDM | ?? | MGT not used
  3 | ALL | CDM | RO | MGT debug_data
  4 | ALL | CDM | RW | clk_config_vec
  5 | ALL | CDM | ?? | not used
  6 | ALL | CDM | RO | CDM_link_data_processing:o_error_time
  7 | ALL | CDM | RO | CDM_link_data_processing:o_error_count

register 0 0x80010000

GDM:

0 - gdm_link_interface:i_mgt_rst
2 - gdm_link_interface:i_link_down_latched_rst
8 - GDM_link_data_processing:i_rst
10..9 - GDM_link_data_processing:i_data_mode

CDM:

0 - cdm_link_interface:i_mgt_rst
2 - cdm_link_interface:i_link_down_latched_rst
8 - CDM_link_data_processing:i_rst
10..9 - CDM_link_data_processing:i_data_mode

register 1 0x80010004

GDM:

nlinks-1..0 - gdm_link_interface:i_rx_slide_trigger

CDM:

nlinks-1..0 - cdm_link_interface:i_rx_slide_trigger

register 2 0x80010008

GDM:

nlinks-1..0 - gdm_link_interface:o_link_power_good
nlinks+15..16 - gdm_link_interface:o_link_status

CDM:

nlinks-1..0 - cdm_link_interface:o_link_power_good
nlinks+15..16 - cdm_link_interface:o_link_status

register 3 0x8001000c

GDM: simple loopback register

CDM:

31..0 - debug_data - cdm_link_interface:o_debug

o_debug:

rx_link_rst & rx_error & rx_link_up & rx_receiving_data &
std_logic_vector(rx_state_count) & tx_state_count_on_rx_clk & i_rx_ctrl3(0) &
i_rx_ctrl1(1 downto 0) & i_rx_ctrl0(1 downto 0) &
rx_data_is_k28p1_k28p5 &
i_rx_data;

register 4 0x80010010

GDM write:

0 - clk_config_vec(0) - CLK_IN_SEL_LS(0)
1 - clk_config_vec(1) - CLK_IN_SEL_LS(1)
2 - clk_config_vec(2) - CLK_EXT_SEL_LS
3 - clk_config_vec(3) - CLK_RSTn_LS

GDM read:

0 - clk_config_vec(0) - CLK_IN_SEL_LS(0)
1 - clk_config_vec(1) - CLK_IN_SEL_LS(1)
2 - clk_config_vec(2) - CLK_EXT_SEL_LS
3 - clk_config_vec(3) - CLK_RSTn_LS
4 - clk_config_vec(4) - CLK_LOSXTn_LS
5 - clk_config_vec(5) - CLK_LOLn_LS
6 - clk_config_vec(6) - CLK_INTn_LS
7 - constant 1
31..8 - constant 0

register 5 0x80010014

not used

register 6 0x80010018

GDM:

3..0 - GDM_link_data_processing:i_status_select

CDM:

31..0 - CDM_link_data_processing:o_error_count

register 7 0x8001001c

GDM:

31..0 - GDM_link_data_processing:o_status_vector

CDM:

31..0 - CDM_link_data_processing:o_error_count

GDM, CDM, VX packet communications

  • timestamp math
1 clock is 8 ns is 125 MHz
8 bits of clocks is 256 clocks is 2048 ns is ~2 usec
16 bits of clocks is ~500 usec is 0.5 msec
24 bits of clocks is ~134 msec
32 bits of clocks is ~34 sec
40 bits of clocks is ~8.7 ksec is 2.4 hours
48 bits of clocks is ~625 hours is ~26 days
56 bits of clocks is ~6.6 kdays is ~18 kyears
62 bits of clocks is ~10 Mhours is 427 kdays is ~1.1 kyears
64 bits of clocks is ~4.4 kyears
  • 0x02 - TRG packet, 8 bytes, 80 adc clocks, 640 ns on lvds link
0 - 0x02
1 - trg_counter[7:0]
2 - ts64 low byte 0
3 - ts64 byte 1
4 - ts64 byte 2
5 - ts64 high byte 3
6 - trg_in_latch[7:0]
7 - trg_in_latch[15:8]
  • 0x03 - HITMAP_TRG packet, 12 bytes, 120 adc clocks, 960 ns on lvds link
0 - 0x03
1 - trg_counter[7:0]
2 - ts64 low byte 0
3 - ts64 byte 1
4 - ts64 byte 2
5 - ts64 high byte 3
6 - vx_bitmap[7:0]
7 - vx_bitmap[15:8]
8 - vx_bitmap[23:16]
9 - vx_bitmap[31:24]
10 - vx_bitmap[39:32]
11 - vx_bitmap[47:40]
  • 0x10 - TSM packet, 26 bytes, 260 adc clocks, 2080 ns on lvds link
0 - 0x10
1 - tsm_counter[7:0]
2 - gdm_ts64 low byte 0
3 - 1
4 - 2
5 - 3
6 - 4
7 - 5
8 - 6
9 - gdm_ts64 high byte 7
10 - gps_ts64 low byte 0
11 - 1
12 - 2
13 - 3
14 - 4
15 - 5
16 - 6
17 - gps_ts64 high byte 7
18 - gps_data64 low byte 0
19 - 1
20 - 2
21 - 3
22 - 4
23 - 5
24 - 6
25 - gps_data64 high byte 7
  • 0x81 - VX hitmap packet, 10 bytes, 100 adc clocks, 800 ns on lvds link, 48 ns on fiber link
0 - 0x81
1 - VX ID
2 - hitmap low byte, nits 7:0
3 - 15:8
4 - 23:16
5 - 31:24
6 - ...:32
7 - ...
8 - ...
9 - hitmap low byte, bits 63:...
  • 0x82 - CDM hitmap packet, 108 bytes, not sent on lvds link, not sent on fiber link
0 - 0x82
1 - cdm_hitmap_trigger_counter[7:0]
2 - ts64 byte 0
3 - ts64 byte 1
4 - ts64 byte 2
5 - ts64 byte 3
6 - ts64 byte 4
7 - ts64 byte 5
8 - ts64 byte 6
9 - ts64 byte 7
10 - cdm_hitmap_or12 byte 0 (7:0)
11 - cdm_hitmap_or12 byte 1 (11:8) plus 4 bits: 12=0, 13=0, 14=0, 15=cdm_hitmap_grand_or
12 - cdm_hitmap_data, low byte, 12*64 bits = 768 bits = 48 words = 96 bytes
...
107 - cdm_hitmap_data, high byte

AXI bus timing

  • AXI 100 MHz clock, 10 ns, 32-bit data
  • AXI single-dword read: 36 clock repeat rate, 360 ns is 2.777 MHz, 4 bytes per transfer is 11.11 Mbytes/sec
  • AXI single-qword read: 13 clock repeat rate, 130 ns is 7.7 MHz, 4 bytes per transfer is 30 Mbytes/sec, not accounting for the gap
  • AXI memcpy read: 4 transfers at 13 clocks, gap, 4 transfers at 13 clocks, gap, etc. below 30 Mbytes/sec.

Ds-dm-axi-read.png Ds-dm-axi-read-64.png Ds-dm-axi-read-memcpy.png

  • AXI single-dword write: 20 clocks repeat rate, 200 ns is 5 MHz, 4 bytes per transfer is 20 Mbytes/sec
  • AXI single-qword write: 13+20 clocks repeat rate, 330 ns is 3 MHz, 16 bytes per burst is 48 Mbytes/sec

Ds-dm-axi-write.png Ds-dm-axi-write-64.png

AXI bus addresses

  • see AXI/AMBA addresses assigned inthe FPGA project: (s_axi/reg0 is the DS-DM AXI registers)
daq00:ds-dm-gcdm$ grep assign_bd_address scripts/GDM_CDM_XU8_bd.tcl
  assign_bd_address -offset 0x80010000 -range 0x00004000 -target_address_space [get_bd_addr_spaces zynq_ultra_ps_e/Data] [get_bd_addr_segs axi_register_interfa_0/s_axi/reg0] -force
  assign_bd_address -offset 0x000400000000 -range 0x40000000 -target_address_space [get_bd_addr_spaces zynq_ultra_ps_e/Data] [get_bd_addr_segs ddr4/C0_DDR4_MEMORY_MAP/C0_DDR4_ADDRESS_BLOCK] -force
  assign_bd_address -offset 0x80000000 -range 0x00010000 -target_address_space [get_bd_addr_spaces zynq_ultra_ps_e/Data] [get_bd_addr_segs system_management_wiz/S_AXI_LITE/Reg] -force
daq00:ds-dm-gcdm$ 
  • see AXI/AMBA addresses exported from FPGA project to Linux kernel: (uio for debug bridge should say "debug bridge")
root@gdm0:~# cat /sys/class/uio/uio*/name
axi-pmon
axi-pmon
axi-pmon
axi-pmon
root@gdm0:~# 
root@gdm0:~# ls -l /sys/class/uio/
total 0
lrwxrwxrwx 1 root root 0 Oct 18 01:36 uio0 -> ../../devices/platform/amba/ffa00000.perf-monitor/uio/uio0
lrwxrwxrwx 1 root root 0 Oct 18 01:36 uio1 -> ../../devices/platform/amba/fd0b0000.perf-monitor/uio/uio1
lrwxrwxrwx 1 root root 0 Oct 18 01:36 uio2 -> ../../devices/platform/amba/fd490000.perf-monitor/uio/uio2
lrwxrwxrwx 1 root root 0 Oct 18 01:36 uio3 -> ../../devices/platform/amba/ffa10000.perf-monitor/uio/uio3
root@gdm0:~# ls -l /sys/class/uio/../../devices/platform/amba/
total 0
-rw-r--r-- 1 root root 4096 Oct 18 19:37 driver_override
drwxr-xr-x 3 root root    0 Oct 18 01:36 fd070000.memory-controller
drwxr-xr-x 4 root root    0 Oct 18 01:36 fd0b0000.perf-monitor
drwxr-xr-x 4 root root    0 Oct 18 01:36 fd400000.zynqmp_phy
drwxr-xr-x 4 root root    0 Oct 18 01:36 fd490000.perf-monitor
drwxr-xr-x 4 root root    0 Oct 18 01:36 fd500000.dma
drwxr-xr-x 4 root root    0 Oct 18 01:36 fd510000.dma
drwxr-xr-x 4 root root    0 Oct 18 01:36 fd520000.dma
drwxr-xr-x 4 root root    0 Oct 18 01:36 fd530000.dma
drwxr-xr-x 4 root root    0 Oct 18 01:36 fd540000.dma
drwxr-xr-x 4 root root    0 Oct 18 01:36 fd550000.dma
drwxr-xr-x 4 root root    0 Oct 18 01:36 fd560000.dma
drwxr-xr-x 4 root root    0 Oct 18 01:36 fd570000.dma
drwxr-xr-x 4 root root    0 Oct 18 01:36 fd6e0000.cci
drwxr-xr-x 5 root root    0 Oct 18 01:36 ff000000.serial
drwxr-xr-x 4 root root    0 Oct 18 01:36 ff020000.i2c
drwxr-xr-x 6 root root    0 Oct 18 01:36 ff0a0000.gpio
drwxr-xr-x 4 root root    0 Oct 18 01:36 ff0b0000.ethernet
drwxr-xr-x 4 root root    0 Oct 18 01:36 ff0e0000.ethernet
drwxr-xr-x 4 root root    0 Oct 18 01:36 ff0f0000.spi
drwxr-xr-x 5 root root    0 Oct 18 01:36 ff160000.mmc
drwxr-xr-x 5 root root    0 Oct 18 01:36 ff170000.mmc
drwxr-xr-x 3 root root    0 Oct 18 01:36 ff960000.memory-controller
drwxr-xr-x 4 root root    0 Oct 18 01:36 ff9d0000.usb0
drwxr-xr-x 4 root root    0 Oct 18 01:36 ffa00000.perf-monitor
drwxr-xr-x 4 root root    0 Oct 18 01:36 ffa10000.perf-monitor
drwxr-xr-x 4 root root    0 Oct 18 01:36 ffa50000.ams
drwxr-xr-x 5 root root    0 Oct 18 01:36 ffa60000.rtc
drwxr-xr-x 4 root root    0 Oct 18 01:36 ffa80000.dma
drwxr-xr-x 4 root root    0 Oct 18 01:36 ffa90000.dma
drwxr-xr-x 4 root root    0 Oct 18 01:36 ffaa0000.dma
drwxr-xr-x 4 root root    0 Oct 18 01:36 ffab0000.dma
drwxr-xr-x 4 root root    0 Oct 18 01:36 ffac0000.dma
drwxr-xr-x 4 root root    0 Oct 18 01:36 ffad0000.dma
drwxr-xr-x 4 root root    0 Oct 18 01:36 ffae0000.dma
drwxr-xr-x 4 root root    0 Oct 18 01:36 ffaf0000.dma
-r--r--r-- 1 root root 4096 Oct 18 19:37 modalias
lrwxrwxrwx 1 root root    0 Oct 18 19:37 of_node -> ../../../firmware/devicetree/base/amba
drwxr-xr-x 2 root root    0 Oct 18 19:37 power
lrwxrwxrwx 1 root root    0 Oct 18 01:36 subsystem -> ../../../bus/platform
-rw-r--r-- 1 root root 4096 Oct 18 01:36 uevent
root@gdm0:~# 

Build firmware

Build from git clone

THESE ARE K.O.'s NOTES FOR CREATING THE PETALINUX DIRECTORY.

THEY DO NOT WORK!

COPY PETALINUX FROM A WORKING PROJECT AND USE "make gdm" and "make cdm" AS DESCRIBED BELOW.

  • git clone git@edev-group.triumf.ca:fw/exp/darkside/gcdm.git
  • #Makefile change VIVADO_SETTINGS_SCRIPT := /opt/Xilinx/Vivado/2022.1/settings64.sh
  • #. /opt/Xilinx/Vivado/2022.1/settings64.sh
  • . /opt/Xilinx/Vivado/2020.2/settings64.sh
  • make clean
  • make all_from_scratch
  • . /opt/Xilinx/PetaLinux/2020.2/tool/settings.sh
  • make petalinux_create
  • make petalinux_rebuild_new_hw_des
  • bomb out: The TMPDIR: /home/olchansk/git/ds-dm-gcdm/PetaLinux_GDM_CDM/build/tmp can't be located on nfs.
  • mkdir /tmp/build_tmp
  • rm -rf /home/olchansk/git/ds-dm-gcdm/PetaLinux_GDM_CDM/build/tmp/
  • ln -s /tmp/build_tmp /home/olchansk/git/ds-dm-gcdm/PetaLinux_GDM_CDM/build/tmp
  • try again
  • grinds, loads a whole bunch of packages...
  • finishes with desire to copy things to /tftpboot
  • make sdcard_cp_to wants to copy files from PetaLinux_GDM_CDM/images/linux/ to SD card

Build firmware

NOTE: directory Petalinux_GDM_CDM should already exist!

#. /opt/Xilinx/Vivado/2020.2/settings64.sh
. /opt/Xilinx/Vivado/2022.2/settings64.sh
. /opt/Xilinx/PetaLinux/2020.2/tool/settings.sh
make clean_gdm   # remove gdm build tree
make gdm         # build or rebuild GDM
make copy_gdm    # copy to gdm0
make clean_cdm   # remove cdm build tree
make cdm         # build or rebuild CDM
make copy_cdm    # copy to cdm0 and cdm1

copy to SD card:

open a root shell
format 16 GB Sd card per above
cd .../ds-dm-gcdm
make copy

build times

CDM 12-june-2023 69aabc1c25130d970bc375aca684bd68849e6685
daq13 AMD-5700G 1688.61user 399.33system 23:28.84elapsed 148%CPU
dsdaqgw AMD-7700 1090.55user 247.34system 16:03.55elapsed 138%CPU
dsdaqgw AMD-7700 CDM incremental 196.68user 67.62system 7:35.42elapsed 58%CPU
dsdaqgw AMD-7700 CDM incremental 684.72user 94.17system 7:30.17elapsed 173%CPU
dsdaqgw AMD-7700 GDM incremental 849.84user 99.79system 9:04.56elapsed 174%CPU

prepare bootable sd card

format the sd card

this only needs to be done once

  • become root
  • cd ~olchansk/git/ds-dm-gcdm
  • use "lsblk" to identify the SD card (should show as 8/16/32 GB block device)/ /dev/sdd in this case
  • make sdcard_format SDCARD_DEVICE=/dev/sdd
  • disconnect sd card, reconnect the sd card (to detect new partition tables, etc)

copy CDM boot files

cd /home/dsdmdev/git/ds-dm-gcdm
make copy

copy boot files to the sd card

  • as root: identify partition labels, run "blkid", should say "BOOT", "rootfs" and "data"
  • mount
mkdir /media/olchansk/BOOT
mkdir /media/olchansk/rootfs
mkdir /media/olchansk/data
mount -L BOOT /media/olchansk/BOOT
mount -L rootfs /media/olchansk/rootfs
mount -L data /media/olchansk/data
cp PetaLinux_GDM_CDM/images/linux/BOOT.BIN /media/olchansk/BOOT/
cp PetaLinux_GDM_CDM/images/linux/boot.scr /media/olchansk/BOOT/
cp PetaLinux_GDM_CDM/images/linux/image.ub /media/olchansk/BOOT/
umount /media/olchansk/BOOT
umount /media/olchansk/rootfs
umount /media/olchansk/data
eject /dev/sdd

boot messages

Xilinx Zynq MP First Stage Boot Loader 
Release 2020.2   Sep 24 2022  -  13:29:15
NOTICE:  ATF running on XCZU4CG/silicon v4/RTL5.1 at 0xfffea000
NOTICE:  BL31: v2.2(release):xlnx_rebase_v2.2_2020.3
NOTICE:  BL31: Built : 18:02:46, Sep 28 2022


U-Boot 2020.01 (Sep 28 2022 - 18:03:39 +0000)

Model: DarkSide 20k DM
Board: Xilinx ZynqMP
DRAM:  2 GiB
usb dr_mode not found
PMUFW:  v1.1
EL Level:       EL2
Chip ID:        zu4
NAND:  0 MiB
MMC:   mmc@ff160000: 0, mmc@ff170000: 1
In:    serial@ff000000
Out:   serial@ff000000
Err:   serial@ff000000
Bootmode: SD_MODE1
Reset reason:   SOFT 
Net:   
ZYNQ GEM: ff0b0000, mdio bus ff0b0000, phyaddr -1, interface rgmii-id

Warning: ethernet@ff0b0000 (eth0) using random MAC address - d6:62:5f:13:00:44
eth0: ethernet@ff0b0000
ZYNQ GEM: ff0e0000, mdio bus ff0e0000, phyaddr -1, interface rgmii-id
Could not get PHY for eth1: addr -1

Hit any key to stop autoboot:  0 
ZynqMP> 
CTRL-A Z for help | 115200 8N1 | NOR | Minicom 2.7.1 | VT102 | Online 122:2 | ttyACM0                                       

load FPGA from u-boot

ZynqMP> fpga info
Xilinx Device
Descriptor @ 0x000000007fddb2c0
Family:         ZynqMP PL
Interface type: csu_dma configuration interface (ZynqMP)
Device Size:    1 bytes
Cookie:         0x0 (0)
Device name:    zu4
Device Function Table @ 0x000000007fda5fe8
PCAP status     0xa0002fde
ZynqMP> 
  • cp CDM_XU8_top.bit /tftpboot/fpga.bit
dhcp
tftpb 0x10000000 fpga.bit
fpga loadb 0 0x10000000 ${filesize}
ZynqMP> dhcp
BOOTP broadcast 1
DHCP client bound to address 192.168.0.100 (1 ms)
*** Warning: no boot file name; using 'C0A80064.img'
Using ethernet@ff0b0000 device
TFTP from server 192.168.0.1; our IP address is 192.168.0.100
Filename 'C0A80064.img'.
Load address: 0x8000000
Loading: *
TFTP error: 'file /tftpboot/C0A80064.img not found for 192.168.0.100' (1)
Not retrying...
ZynqMP> tftpb 0x10000000 fpga.bit
Using ethernet@ff0b0000 device
TFTP from server 192.168.0.1; our IP address is 192.168.0.100
Filename 'fpga.bit'.
Load address: 0x10000000
Loading: #################################################################
         #################################################################
         #################################################################
         #################################################################
         #################################################################
         #################################################################
         #################################################################
         #################################################################
         ############
         6.2 MiB/s
done
Bytes transferred = 7797807 (76fc2f hex)
ZynqMP> fpga loadb 0 0x10000000 ${filesize}
  design filename = "CDM_XU8_top;UserID=0XFFFFFFFF;Version=2022.2"
  part number = "xczu4cg-fbvb900-1-e"
  date = "2024/08/14"
  time = "14:18:22"
  bytes in bitstream = 7797692
zynqmp_align_dma_buffer: Align buffer at 0000000010000073 to 000000000fffff80(swap 0)
ZynqMP> 

load FPGA from Linux

this will reset the CPU

cp fpga.bit /lib/firmware/
echo fpga.bit > /sys/class/fpga_manager/fpga0/firmware
  • make .bin file:
bootgen -image CDM_XU8_top.bif -arch zynqmp -o ./fpga.bin -w
  • cat CDM_XU8_top.bif
dsdaqgw:ds-dm-gcdm$ cat CDM_XU8_top.bif
all:
{
        [destination_device = pl] ./Vivado_CDM_XU8/CDM_XU8.runs/impl_1/CDM_XU8_top.bit
}
dsdaqgw:ds-dm-gcdm$ 

this will reset the CPU

cp fpga.bin /lib/firmware/
echo fpga.bin > /sys/class/fpga_manager/fpga0/firmware

this will reset the CPU

root@dsdm:~# ./fpgautil -b fpga.bin -f Full

this will reset the CPU

DTSO file from here: https://xilinx-wiki.atlassian.net/wiki/spaces/A/pages/18841847/Solution+ZynqMP+PL+Programming
echo 0 > /sys/class/fpga_manager/fpga0/flags
mount -t configfs configfs /configfs
root@dsdm:~# dtc -O dtb -o fpga.dtbo -b 0 -@ fpga.dtso
root@dsdm:~# cp fpga.dtbo /lib/firmware/
root@dsdm:~# cp fpga.bit /lib/firmware/
root@dsdm:~# rmdir /configfs/device-tree/overlays/fpga
root@dsdm:~# mkdir /configfs/device-tree/overlays/fpga
root@dsdm:~# echo -n "fpga.dtbo" > /configfs/device-tree/overlays/fpga/path 

fpgautil

git clone https://github.com/Xilinx/meta-xilinx.git
cd meta-xilinx/meta-xilinx-core/recipes-bsp/fpga-manager-script/files/
scp fpgautil.c root@dsdm:
ssh root@dsdm
make fpgautil
ls -l ./fpgautil
root@dsdm:~# ls -l ./fpgautil
-rwxr-xr-x 1 root root 72256 Aug 16 00:15 ./fpgautil
root@dsdm:~# ./fpgautil 

fpgautil: FPGA Utility for Loading/reading PL Configuration

Usage:	fpgautil -b <bin file path> -o <dtbo file path>

Options: -b <binfile>		(Bin file path)
         -o <dtbofile>		(DTBO file path)
         -f <flags>		Optional: <Bitstream type flags>
				   f := <Full | Partial > 
         -n <Fpga region info>  FPGA Regions represent FPGA's
                                and partial reconfiguration
                                regions of FPGA's in the
                                Device Tree
				Default: <full>
	  -s <secure flags>	Optional: <Secure flags>
				   s := <AuthDDR | AuthOCM | EnUsrKey | EnDevKey | AuthEnUsrKeyDDR | AuthEnUsrKeyOCM | AuthEnDevKeyDDR | AuthEnDevKeyOCM>
	  -k <AesKey>		Optional: <AES User Key>
	  -r <Readback> 	Optional: <file name>
				Default: By default Read back contents will be stored in readback.bin file
	  -t			Optional: <Readback Type>
				   0 - Configuration Register readback
				   1 - Configuration Data Frames readback
				Default: 0 (Configuration register readback)
	  -R 			Optional: Remove overlay from a live tree
 
Examples:
(Load Full bitstream using Overlay)
fpgautil -b top.bit.bin -o can.dtbo -f Full -n full 
(Load Partial bitstream using Overlay)
fpgautil -b rm0.bit.bin -o rm0.dtbo -f Partial -n PR0
(Load Full bitstream using sysfs interface)
fpgautil -b top.bit.bin -f Full
(Load Partial bitstream using sysfs interface)
fpgautil -b rm0.bit.bin -f Partial
(Load Authenticated bitstream through the sysfs interface)
fpgautil -b top.bit.bin -f Full -s AuthDDR 
(Load Parital Encrypted Userkey bitstream using Overlay)
fpgautil -b top.bit.bin -o pl.dtbo -f Partial -s EnUsrKey -k <32byte key value>
(Read PL Configuration Registers)
fpgautil -b top.bit.bin -r
(Remove Partial Overlay)
fpgautil -R -n PR0
(Remove Full Overlay)
fpgautil -R -n full
Note: fpgautil -R is responsible for only removing the dtbo file from the livetree. it will not remove the PL logic from the FPGA region.
 
root@dsdm:~# 

fw_printenv

to access u-boot environment from Linux:

  • apt install -y libubootenv-tool
  • create /etc/fw_env.config
/media/BOOT/uboot.env 0 0x40000
/media/BOOT/uboot-redund.env 0 0x40000
  • if uboot.env files do not exist, run "saveenv" from u-boot command prompt
  • fw_printenv and fw_setenv should work

Boot from network

u-boot

ZynqMP> setenv bootcmd run bootcmd_dhcp
ZynqMP> saveenv
ZynqMP> reset

boot.scr

# boot.scr
# mkimage -C none -A arm -T script -d boot.scr boot.scr.uimg
echo Loading FPGA!
#tftpb 0x10000000 fpga.bit
tftpb 0x10000000 {ipaddr}.bit
fpga loadb 0 0x10000000 ${filesize}
echo Booting Linux!
run bootcmd_pxe
echo Done!
mkimage -C none -A arm -T script -d boot.scr boot.scr.uimg

tftpboot

cp /home/olchansk/git/ds-dm-gcdm/boot.scr.uimg /tftpboot
ln -s /home/olchansk/git/ds-dm-gcdm/PetaLinux_GDM_CDM/images/linux /tftpboot/xilinx-dsdm
mkdir /tftpboot/pxelinux.cfg
cat > /tftpboot/pxelinux.cfg/default-arm-zynqmp <<EOF
LABEL Linux
   KERNEL xilinx-dsdm/Image
   FDT xilinx-dsdm/system.dtb
   #INITRD rootfs.cpio.gz.u-boot
EOF

boot sequence

  • xilinx magic load BOOT.BIN from SD card
  • load FPGA form BOOT.BIN
  • load and run u-boot from BOOT.BIN or from image.ub
  • u-boot load environment from ??? probably SD card uboot-redund.env, this includes our bootcmd
  • run bootcmd which run bootcmd_dhcp which does:
  • from /tftpboot:
  • load and run boot.scr.uimg which does:
  • load FPGA image xilinx-dsdm/${ipaddr}.bit
  • run bootcmd_pxe which does:
  • load pxelinux.cfg/default-arm-zynqmp which does:
  • load xilinx-dsdm/Image ### this is the linux kernel
  • load xilinx-dsdm/system.dtb ### this is the device tree
  • start linux kernel
  • linux kernel does dhcp
  • linux kernel does nfs mount /nfsroot/%s,vers=3,tcp ### %s is replaced by the hostname supplied by DHCP
  • userland starts and runs to console and ssh login.

Xilinx ILA

References:

Build xvcserver_cdm.exe: (it is built as a static executable, can be copied and run anywhere)

ssh dsdaq@gdm0
cd /home/dsdaq/online/ds-dm-software
git pull ### get latest version
make xvcserver_cdm.exe
ssh root@gdm0
/home/dsdaq/online/ds-dm-software/xvcserver_cdm.exe
INFO: To connect to this xvcServer instance, use url: TCP:gdm0:2542

To activate and use the vivado logic analyzer:

  • data path: vivado -> hw_server -> xvcserver -> mmap axi bus -> debug bridge -> jtag -> ILA
  • define ILAs in the code
  • instantiate the xilinx debug bridge at AXI bus address 0x80020000 (FIXME!!! this collides with Ian's AXI addresses)
  • build and boot the new FPGA firmware. updating the linux kernel is not necessary.
  • login root@gdm0, run: /home/dsdaq/online/ds-dm-software/xvcserver_cdm.exe -v ### with "-v" for the first time to see that vivado does connect to it, without "-v", normally.
  • login dsdaqgw, run: hw_server -s tcp:localhost:3121 -e "set auto-open-servers xilinx-xvc:gdm0:2542" ### tells us to connect to port localhost:3121
  • login dsdaqgw, run vivado, open project, open hardware manager, open target, open new target, "connect to remote server", hostname "localhost", port "3121", next (bombs, try again, 3 times), popup add virtual cable, enter hostname "gdm0" port "2542", "ok", it shows in "hardware targets", "next", "finish", error popup "[Common 17-163] Missing value for option 'objects', please type 'set_property -help' for usage info", ignore it, in "hardware", right click the "gdm0" one, open target, under "hardware" and "debug bridge" we should see all the ILAs, under "hardware device properties", the "probes file" should have the ".ltx" file generated by vivado "Vivado_GDM_XU8/GDM_XU8.runs/impl_1/debug_nets.ltx", click on an ILA, a waveform should open.

Software

test_cdm.exe

CDM SFP status

# /home/dsdaq/online/ds-dm-software/test_cdm.exe --sfp
DS-DM mapping /dev/mem at 0x80010000
DS-DM FPGA firmware revision 0xbb2f0ae7
CDM firmware 0xbb2f0ae7
arg 1: [--sfp]
Polling SFP status...
identifier 0x03
connector  0x07
encoding   0x01
wavelength 0x0352 (850 nm)
vendor_name [FINISAR CORP.   ]
vendor_pn   [FTLF8526P3BNL   ]
vendor_rev  [A   ]
vendor_sn   [N3AB9M8         ]
vendor_date [200319  ]
dm_type    0x68
temp 29.0 C
vcc  3.323 V
tx_bias  7.250 mA
tx_power 478.4 uW
rx_power 2.3 uW
SFP good 1, status: temp 30.6 C, tx_bias 7.4 mA, tx_power 476 uW, rx_power 818 uW
...

GDM QSFP status

root@gdm0:~# /home/dsdaq/online/ds-dm-software/test_cdm.exe --qsfp3 --qsfp
DS-DM mapping /dev/mem at 0x80010000
DS-DM FPGA firmware revision 0x53aee418
CDM firmware 0x53aee418
arg 1: [--qsfp3]
gpiochip0: GPIOs 338-511, parent: platform/ff0a0000.gpio, zynqmp_gpio:
 gpio-378 (                    |sysfs               ) out hi 
 gpio-379 (                    |sysfs               ) out hi 
 gpio-381 (                    |sysfs               ) out lo 
 gpio-382 (                    |sysfs               ) out hi 
arg 2: [--qsfp]
Polling QSFP status...
identifier 0x0d
status     0x02
los        0x8f
temp       28.2 C
vcc        3.323 V
rx_power     0.1   0.1   0.1   0.1 uW
tx_bias      7.6   7.6   7.6   0.0 mA
tx_power   792.2 773.8 823.0   0.1 uW
vendor_name [FINISAR CORP    ]
vendor_pn   [FTL410QD4C      ]
vendor_rev  [A ]
wavelength  850
max_temp    70 C
vendor_sn   [X79AC0R         ]
vendor_date [220309  ]
QSFP good 1, status: temp 27.7 C, los 0x8b, tx_bias 7.5 7.6 7.6 0.0 mA, tx_power 792 772 821   0 uW, rx_power   0   0 466   0 uW

GDM clock status

/home/dsdaq/online/ds-dm-software/test_cdm.exe --cc
/home/dsdaq/online/ds-dm-software/test_cdm.exe --gdm-clocks
  • clock chip not loaded, not running:
root@gdm0:~# /home/dsdaq/online/ds-dm-software/test_cdm.exe --cc
DS-DM mapping /dev/mem at 0x80010000
DS-DM FPGA firmware revision 0x6d2ebce6
CDM firmware 0x6d2ebce6
Polling CC status...
Clock chip registers: 0x06 0x00 0x94 0x53 0x00 0x00 0x0f 0x16 0x04 0x00 0x01 0x68 0x09 0x00 0x02 0xf2 0x00 0x1f 0xf0 0x22 0xf2, 0x507: 0x00, 0x52A: 0x00, 0x53F: 0x04
Clock chip state 0, status:  SYSINCAL XAXB_ERR LOL CAL_PLL IN0 IN_SEL_0 FASTLOCK_STATUS

root@gdm0:~# /home/dsdaq/online/ds-dm-software/test_cdm.exe --gdm-clocks
DS-DM mapping /dev/mem at 0x80010000
DS-DM FPGA firmware revision 0x6d2ebce6
CDM firmware 0x6d2ebce6
GDM clock frequency counters:
0x1030 mgt_rx_ref_clk_raw: 0x1f7caf52 (528265042) should be ~125 MHz
0x1034 rx_clk:             0x00000000 (0) should be ~125 MHz
0x1038 mgt_tx_ref_clk_raw: 0x1f7caf52 (528265042) should be ~125 MHz
0x103C tx_clk:             0x00000000 (0) should be ~125 MHz
0x1040 clk_50MHz:          0x02faf080 (50000000) should be 50 MHz exactly
0x1044 Block1_clk:         0x05f5e100 (100000000) should be 100 MHz exactly
  • clock chip good (IN0 - external 10 MHz clock)
root@gdm0:~# /home/dsdaq/online/ds-dm-software/test_cdm.exe --cc
DS-DM mapping /dev/mem at 0x80010000
DS-DM FPGA firmware revision 0x6d2ebce6
CDM firmware 0x6d2ebce6
Polling CC status...
Clock chip registers: 0x06 0x00 0x94 0x53 0x00 0x00 0x00 0x00 0x00 0x00 0x01 0x68 0x00 0x44 0x00 0xd0 0x01 0x1f 0xff 0x22 0xf2, 0x507: 0x3f, 0x52A: 0x01, 0x53F: 0x00
Clock chip state 1, status:  LOS_IN2 OOF_IN2 IN0 IN_SEL_REGCTRL IN_SEL_0

root@gdm0:~# /home/dsdaq/online/ds-dm-software/test_cdm.exe --gdm-clocks
DS-DM mapping /dev/mem at 0x80010000
DS-DM FPGA firmware revision 0x6d2ebce6
CDM firmware 0x6d2ebce6
GDM clock frequency counters:
0x1030 mgt_rx_ref_clk_raw: 0x07735a3b (125000251) should be ~125 MHz
0x1034 rx_clk:             0x07735a3c (125000252) should be ~125 MHz
0x1038 mgt_tx_ref_clk_raw: 0x07735a3b (125000251) should be ~125 MHz
0x103C tx_clk:             0x07735a3c (125000252) should be ~125 MHz
0x1040 clk_50MHz:          0x02faf080 (50000000) should be 50 MHz exactly
0x1044 Block1_clk:         0x05f5e100 (100000000) should be 100 MHz exactly

CDM clock status

/home/dsdaq/online/ds-dm-software/test_cdm.exe --cc
/home/dsdaq/online/ds-dm-software/test_cdm.exe --cdm-clocks
  • clock chip not loaded, not running:
root@cdm1:~# /home/dsdaq/online/ds-dm-software/test_cdm.exe --cc
DS-DM mapping /dev/mem at 0x80010000
DS-DM FPGA firmware revision 0x6d2ebec9
CDM firmware 0x6d2ebec9
Polling CC status...
Clock chip registers: 0x06 0x00 0x94 0x53 0x00 0x00 0x0f 0x16 0x04 0x00 0x01 0x68 0x19 0x00 0x02 0xf2 0x00 0x1f 0xf0 0x22 0xf2, 0x507: 0x00, 0x52A: 0x00, 0x53F: 0x04
Clock chip state 0, status:  SYSINCAL XAXB_ERR LOL CAL_PLL IN0 IN_SEL_0 FASTLOCK_STATUS

root@cdm1:~# /home/dsdaq/online/ds-dm-software/test_cdm.exe --cdm-clocks
DS-DM mapping /dev/mem at 0x80010000
DS-DM FPGA firmware revision 0x6d2ebec9
CDM firmware 0x6d2ebec9
CDM clock frequency counters:
0x1030 mgt_rx_ref_clk_raw: 0x07735851 (124999761) should be ~125 MHz
0x1034 rx_clk:             0x00000000 (0) should be ~125 MHz
0x1038 mgt_tx_ref_clk_raw: 0x0127fefa (19398394) should be ~125 MHz
0x103C tx_clk:             0x00000000 (0) should be ~125 MHz
0x1040 clk_50MHz:          0x02faf080 (50000000) should be 50 MHz exactly
0x1044 Block1_clk:         0x05f5e100 (100000000) should be 100 MHz exactly
  • clock chip uses internal clock (IN1 - internal oscillator), observe rx_clk frequency is not same as others
root@cdm1:~# /home/dsdaq/online/ds-dm-software/test_cdm.exe --cc
DS-DM mapping /dev/mem at 0x80010000
DS-DM FPGA firmware revision 0x6d2ebec9
CDM firmware 0x6d2ebec9
Polling CC status...
Clock chip registers: 0x06 0x00 0x94 0x53 0x00 0x00 0x00 0x00 0x00 0x00 0x01 0x68 0x00 0x00 0x00 0xd0 0x01 0x1f 0xfe 0x22 0xf2, 0x507: 0x7f, 0x52A: 0x02, 0x53F: 0x02
Clock chip state 1, status:  IN1 IN_SEL_1 HOLD_HIST_VALID

root@cdm1:~# /home/dsdaq/online/ds-dm-software/test_cdm.exe --cdm-clocks
DS-DM mapping /dev/mem at 0x80010000
DS-DM FPGA firmware revision 0x6d2ebec9
CDM firmware 0x6d2ebec9
CDM clock frequency counters:
0x1030 mgt_rx_ref_clk_raw: 0x07735853 (124999763) should be ~125 MHz
0x1034 rx_clk:             0x07735b0a (125000458) should be ~125 MHz
0x1038 mgt_tx_ref_clk_raw: 0x07735853 (124999763) should be ~125 MHz
0x103C tx_clk:             0x07735852 (124999762) should be ~125 MHz
0x1040 clk_50MHz:          0x02faf080 (50000000) should be 50 MHz exactly
0x1044 Block1_clk:         0x05f5e100 (100000000) should be 100 MHz exactly
  • clock chip uses SFP recovered clock (IN2 - sfp rx recovered clock), observe mgt_rx_ref_clk_raw (CDM 125 MHz oscillator) is different from others (SFP RX recovered clock)
root@cdm1:~# /home/dsdaq/online/ds-dm-software/test_cdm.exe --cc
DS-DM mapping /dev/mem at 0x80010000
DS-DM FPGA firmware revision 0x6d2ef81a
CDM firmware 0x6d2ef81a
Polling CC status...
Clock chip registers: 0x06 0x00 0x94 0x53 0x00 0x00 0x00 0x00 0x00 0x00 0x01 0x68 0x00 0x00 0x00 0xd0 0x01 0x1f 0xfe 0x22 0xf2, 0x507: 0xbf, 0x52A: 0x02, 0x53F: 0x02
Clock chip state 1, status:  IN2 IN_SEL_1 HOLD_HIST_VALID
^C
root@cdm1:~# /home/dsdaq/online/ds-dm-software/test_cdm.exe --cdm-clocks
DS-DM mapping /dev/mem at 0x80010000
DS-DM FPGA firmware revision 0x6d2ef81a
CDM firmware 0x6d2ef81a
CDM clock frequency counters:
0x1030 mgt_rx_ref_clk_raw: 0x0773581b (124999707) should be ~125 MHz
0x1034 rx_clk:             0x07735ad6 (125000406) should be ~125 MHz
0x1038 mgt_tx_ref_clk_raw: 0x07735ad7 (125000407) should be ~125 MHz
0x103C tx_clk:             0x07735ad6 (125000406) should be ~125 MHz
0x1040 clk_50MHz:          0x02faf080 (50000000) should be 50 MHz exactly
0x1044 Block1_clk:         0x05f5e100 (100000000) should be 100 MHz exactly
^C

CDM link status, PRBS test mode

# /home/dsdaq/online/ds-dm-software/test_cdm.exe --cdm-link
# /home/dsdaq/online/ds-dm-software/test_cdm.exe --link-test2
  • fiber disconnected, no link:
CDM firmware:    0xbb2f0ae7
0x1000 SFP c.c. status: 0x00000031
    CLK_IN_SEL_LS   0x1
    CLK_EXT_SEL_LS  0
    CLK_CLK_RSTn_LS 0
    CLK_LOSXTn_LS   1
    CLK_LOLn_LS     1
    CLK_INTn_LS     0
0x1008 SFP link reset:  0x00000000
0x1010 SFP link status: 0x00000025
    sfp_mod_absent_N       1
    sfp_rx_los_N           0
    link_power_good        1
    rx_link_up             0
    rx_receiving_data      0
    rx_error               1
    rx_lnk_up_and_running  0
    tx_link_up             0
    tx_sending_data        0
    tx_link_up_and_running 0
    link_up_and_running    0
0x1014 SFP link data:   0x466a8187
    rx_data     0x8187
    k28p1_k28p5 0
    rx_ctrl0    0x1
    rx_ctrl1    0x1
    rx_ctrl3    0x1
    tx_state    0x1
    rx_state    0x6
    rx_receiving_data 0
    rx_link_up        0
    rx_error          1
    rx_link_rst       0
0x2000 link test mode: 0x00000200, seconds: 0x00079093, errors: 0xffffffff
  • fiber connected, good link:
CDM firmware:    0xbb2f0ae7
0x1000 SFP c.c. status: 0x000000b2
    CLK_IN_SEL_LS   0x2
    CLK_EXT_SEL_LS  0
    CLK_CLK_RSTn_LS 0
    CLK_LOSXTn_LS   1
    CLK_LOLn_LS     1
    CLK_INTn_LS     0
0x1008 SFP link reset:  0x00000000
0x1010 SFP link status: 0x000007dc
    sfp_mod_absent_N       0
    sfp_rx_los_N           0
    link_power_good        1
    rx_link_up             1
    rx_receiving_data      1
    rx_error               0
    rx_lnk_up_and_running  1
    tx_link_up             1
    tx_sending_data        1
    tx_link_up_and_running 1
    link_up_and_running    1
0x1014 SFP link data:   0x35c02774
    rx_data     0x2774
    k28p1_k28p5 0
    rx_ctrl0    0x0
    rx_ctrl1    0x0
    rx_ctrl3    0x0
    tx_state    0x3
    rx_state    0x5
    rx_receiving_data 1
    rx_link_up        1
    rx_error          0
    rx_link_rst       0
0x2000 link test mode: 0x00000200, seconds: 0x00078a8c, errors: 0x00000000

GDM link status, PRBS test mode

1 link connected, no errors:
# /home/dsdaq/online/ds-dm-software/test_cdm.exe --gdm-link
# /home/dsdaq/online/ds-dm-software/test_cdm.exe --link-test2
GDM firmware:    0x6b2ee010
0x1014: 0x00000008, 18: 0x00000008, 1C: 0x00000000, 24: 0x00000fff
0x2000: 0x00000200, time: 0x00078aa4, errors:
0xffffffff 0xffffffff 0xffffffff
0x00000000 0xffffffff 0xffffffff
0xffffffff 0xffffffff 0xffffffff
0xffffffff 0xffffffff 0xffffffff

CDM link status

root@cdm1:~# /home/dsdaq/online/ds-dm-software/test_cdm.exe --link-test0

root@cdm1:~# /home/dsdaq/online/ds-dm-software/test_cdm.exe --cc
DS-DM mapping /dev/mem at 0x80010000
DS-DM FPGA firmware revision 0x6d2ef81a
CDM firmware 0x6d2ef81a
Polling CC status...
Clock chip registers: 0x06 0x00 0x94 0x53 0x00 0x00 0x00 0x00 0x00 0x00 0x01 0x68 0x00 0x00 0x00 0xd0 0x01 0x1f 0xfe 0x22 0xf2, 0x507: 0xbf, 0x52A: 0x02, 0x53F: 0x02
Clock chip state 1, status:  IN2 IN_SEL_1 HOLD_HIST_VALID

root@cdm1:~# /home/dsdaq/online/ds-dm-software/test_cdm.exe --cdm-clocks
DS-DM mapping /dev/mem at 0x80010000
DS-DM FPGA firmware revision 0x6d2ef81a
CDM firmware 0x6d2ef81a
CDM clock frequency counters:
0x1030 mgt_rx_ref_clk_raw: 0x077357a0 (124999584) should be ~125 MHz
0x1034 rx_clk:             0x07735a5c (125000284) should be ~125 MHz
0x1038 mgt_tx_ref_clk_raw: 0x07735a5b (125000283) should be ~125 MHz
0x103C tx_clk:             0x07735a5b (125000283) should be ~125 MHz
0x1040 clk_50MHz:          0x02faf080 (50000000) should be 50 MHz exactly
0x1044 Block1_clk:         0x05f5e100 (100000000) should be 100 MHz exactly

root@cdm1:~# /home/dsdaq/online/ds-dm-software/test_cdm.exe --cdm-link
DS-DM mapping /dev/mem at 0x80010000
DS-DM FPGA firmware revision 0x6d2ef81a
CDM firmware 0x6d2ef81a
CDM firmware:    0x6d2ef81a
0x1000 SFP c.c. status: 0x000000b2
    CLK_IN_SEL_LS   0x2
    CLK_EXT_SEL_LS  0
    CLK_CLK_RSTn_LS 0
    CLK_LOSXTn_LS   1
    CLK_LOLn_LS     1
    CLK_INTn_LS     0
0x1008 SFP link reset:  0x00000000
0x1010 SFP link status: 0x000007dc
    sfp_mod_absent_N       0
    sfp_rx_los_N           0
    link_power_good        1
    rx_link_up             1
    rx_receiving_data      1
    rx_error               0
    rx_lnk_up_and_running  1
    tx_link_up             1
    tx_sending_data        1
    tx_link_up_and_running 1
    link_up_and_running    1
0x1014 SFP link data:   0x35c6bcbc
    rx_data     0xbcbc
    k28p1_k28p5 0
    rx_ctrl0    0x3
    rx_ctrl1    0x0
    rx_ctrl3    0x0
    tx_state    0x3
    rx_state    0x5
    rx_receiving_data 1
    rx_link_up        1
    rx_error          0
    rx_link_rst       0
0x2000 link test mode: 0x00000000, seconds: 0x00001671, errors: 0xffffffff

root@cdm1:~# /home/dsdaq/online/ds-dm-software/test_cdm.exe 15
DS-DM mapping /dev/mem at 0x80010000
DS-DM FPGA firmware revision 0x6d2ef81a
CDM firmware 0x6d2ef81a
reg[15] is 0x0033bcbc (3390652)

GDM link status

root@gdm0:~# /home/dsdaq/online/ds-dm-software/test_cdm.exe --link-test0

root@gdm0:~# /home/dsdaq/online/ds-dm-software/test_cdm.exe --cc
DS-DM mapping /dev/mem at 0x80010000
DS-DM FPGA firmware revision 0x6d2ebce6
CDM firmware 0x6d2ebce6
Polling CC status...
Clock chip registers: 0x06 0x00 0x94 0x53 0x00 0x00 0x00 0x00 0x00 0x00 0x01 0x68 0x00 0x44 0x00 0xd0 0x01 0x1f 0xff 0x22 0xf2, 0x507: 0x3f, 0x52A: 0x01, 0x53F: 0x02
Clock chip state 1, status:  LOS_IN2 OOF_IN2 IN0 IN_SEL_REGCTRL IN_SEL_0 HOLD_HIST_VALID

root@gdm0:~# /home/dsdaq/online/ds-dm-software/test_cdm.exe --gdm-clocks
DS-DM mapping /dev/mem at 0x80010000
DS-DM FPGA firmware revision 0x6d2ebce6
CDM firmware 0x6d2ebce6
GDM clock frequency counters:
0x1030 mgt_rx_ref_clk_raw: 0x07735a0a (125000202) should be ~125 MHz
0x1034 rx_clk:             0x07735a0a (125000202) should be ~125 MHz
0x1038 mgt_tx_ref_clk_raw: 0x07735a0a (125000202) should be ~125 MHz
0x103C tx_clk:             0x07735a0a (125000202) should be ~125 MHz
0x1040 clk_50MHz:          0x02faf080 (50000000) should be 50 MHz exactly
0x1044 Block1_clk:         0x05f5e100 (100000000) should be 100 MHz exactly

register 0x1018 bit 0x800

root@gdm0:~# /home/dsdaq/online/ds-dm-software/test_cdm.exe --gdm-link
DS-DM mapping /dev/mem at 0x80010000
DS-DM FPGA firmware revision 0x6d2ebce6
CDM firmware 0x6d2ebce6
GDM firmware:    0x6d2ebce6
0x1014: 0x00000800, 18: 0x00000800, 1C: 0x00000000, 24: 0x00000fff
0x2000: 0x00000000, time: 0x00003d2f, errors:
0xffffffff 0xffffffff 0xffffffff
0xffffffff 0xffffffff 0xffffffff
0xffffffff 0xffffffff 0xffffffff
0xffffffff 0xffffffff 0xffffffff

link data alternates 0xbcbc and 0x1cbc

root@gdm0:~# /home/dsdaq/online/ds-dm-software/test_cdm.exe 22
DS-DM mapping /dev/mem at 0x80010000
DS-DM FPGA firmware revision 0x6d2ebce6
CDM firmware 0x6d2ebce6
reg[22] is 0xbcbc93ab (-1128492117)

root@gdm0:~# /home/dsdaq/online/ds-dm-software/test_cdm.exe 22
DS-DM mapping /dev/mem at 0x80010000
DS-DM FPGA firmware revision 0x6d2ebce6
CDM firmware 0x6d2ebce6
reg[22] is 0x1cbc1aaf (482089647)
root@gdm0:~# 

Run trg and tsm

on the GDM:

ssh root@gdm00
./test_cdm.exe --gdm-clocks
./test_cdm.exe --load-cc
./test_cdm.exe --cc
./test_cdm.exe --reset-mgt
./test_cdm.exe --gdm-clocks
./test_cdm.exe --writereg 2 0xff # enable LEMO NIM inputs
./test_cdm.exe --writereg 3 0xba54 # LEDs: lemo1, lemo2, trg, tsm
./test_cdm.exe --writereg 4 0x99 $ # LEMO out is trg_in_pulse
./test_cdm.exe --writereg 9 0x32010 # trg and tsm from trg_pulser and tsm_pulse
./test_cdm.exe --writereg 24 1250000 # trg pulser 100 Hz
./test_cdm.exe --writereg 26 125000000 # tsm pulser 1 Hz
./test_cdm.exe --writereg 23 0x40000000 # route trg_in and tsm_in to qsfp tx bits 0 and 1
./test_cdm.exe --counters # observe counters are counting at 100 Hz and 1 Hz

on the CDM:

ssh root@cdm01
./test_cdm.exe --cdm-clocks
./test_cdm.exe --load-cc
./test_cdm.exe --reset-mgt
./test_cdm.exe --cdm-clocks
./test_cdm.exe --cdm-link # issue --reset-mgt on CDM and GDM until link is good
./test_cdm.exe --writereg 2 0xff # enable LEMO NIM inputs
./test_cdm.exe --writereg 3 0xba54 # enable LEDs: lemo1, lemo2, trg, tsm
./test_cdm.exe --writereg 4 0x99 # enable LEMO output trg_in
./test_cdm.exe --writereg 9 0x8040 # enable trg_in and tsm_in from sfp rx bits 0 and 1
./test_cdm.exe --writereg 7 0xff00 # drive VX LVDS lines to logic level 0
./test_cdm.exe --writereg 8 0x2 # VX LVDS with trg and tsm, misrouted in second VX
#./test_cdm.exe --writereg 8 0x7 # VX LVDS with tsm
./test_cdm.exe --counters # observe counters are counting at 100 Hz and 1 Hz

switch GDM and CDM to packetizer trg and tsm:

on the GDM:

/home/dsdaq/online/ds-dm-software/test_cdm.exe --writereg 23 0x00000000

on the CDM:

/home/dsdaq/online/ds-dm-software/test_cdm.exe --writereg 9 0x0804
/home/dsdaq/online/ds-dm-software/test_cdm.exe --counters # observe counters are counting at 100 Hz and 1 Hz

Run packet loopback

GDM CPU -> fifo_to_fpga -> GDM QSFP -> CDM SFP -> fifo_from_fpga -> CDM CPU

On the GDM: (CDM is connected to first QSFP port)

/home/dsdaq/online/ds-dm-software/test_cdm.exe --load-cc
/home/dsdaq/online/ds-dm-software/test_cdm.exe --reset-mgt
/home/dsdaq/online/ds-dm-software/test_cdm.exe --gdm-link
/home/dsdaq/online/ds-dm-software/test_cdm.exe --writereg 32 1 ### tell GDM to use first QSFP port
/home/dsdaq/online/ds-dm-software/test_cdm.exe --gdm-link ### confirm link status is "3"
/home/dsdaq/online/ds-dm-software/test_cdm.exe --writereg 29 2 ### enable GDM packet data injection
/home/dsdaq/online/ds-dm-software/test_cdm.exe --test-fifo-write-loop

One the CDM:

/home/dsdaq/online/ds-dm-software/test_cdm.exe --load-cc
/home/dsdaq/online/ds-dm-software/test_cdm.exe --reset-mgt
/home/dsdaq/online/ds-dm-software/test_cdm.exe --cdm-link
/home/dsdaq/online/ds-dm-software/test_cdm.exe --writereg 29 3 ### enable CDM packet data injection
/home/dsdaq/online/ds-dm-software/test_cdm.exe --test-fifo-read

dsvslice integration

VX setup

  • general
    • Start acq from user code = y, all others = n (as of Mar 2023: will start when first trigger received)
    • Use NIM IO = y
    • Use external clock = y
    • LVDS quartet is input = n, y, n, y
    • LVDS quartet mode = User, User, User, User
  • trigger from front panel NIM:
    • Trigger on external signal = y, all others = n
    • connect CDM EXT_OUT(2) to VX "TrigIn"
  • trigger from LVDS "Sync" mode
    • Trigger on LVDS Sync signal = y, all others = n
    • LVDS quartet mode = User, Sync, User, User
  • trigger from LVDS "User" mode
    • Trigger on LVDS pair 12 signal = y, all others = n
    • LVDS quartet is input = n, y, n, y
    • LVDS quartet mode = User, User, User, User

GDM setup

  • GDM is gdm0
  • set inputs to NIM mode
  • set outputs to TTL mode (this GDM has wrong NIM output circuit)
  • use top QSFP slot, connect split cable 1 into CDM01, cable 2 into CDM02
  • connect non-inverted NIM trigger signal to top-LEMO-left EXT_IN_LV(1)
  • connect non-inverted NIM TSM signal to top-LEME-right EXT_IN_LV(2)
  • GDM LEDs: TRIG, TSM, trigger enabled, trigger_out
  • GDM LEMO_OUT: trigger, trigger

CDM setup

  • set CDM LEMO inputs to NIM
  • set CDM LEMO outputs to NIM
  • CDM01 is cdm0
  • CDM02 is cdm1
  • connect GDM fiber links to SFP port
  • connect 1st VX port of CDM01 to VX1
  • connect 1st VX port of CDM02 to VX2
  • connect LEMO EXT_OUT(2) to VX "TrigIn", CDM01 to VX1, CDM02 to VX2
  • power up
  • CDM LEDs: GDM TRIG, GDM TSM, trigger enabled, trigger out
  • CDM LEMO_OUT: gdm_trg, trigger

After power up

  • start the CDM frontend from the MIDAS "Programs" page. To start manually, see the Start Command on the Programs page.
  • CDM frontend should enable the VX clock, disable the trigger
  • from the MIDAS status page, goto the CDM page
  • outdated: in the CDMx data tables, the 2nd number should read 0x35c08008, if it does not and the last 4 digits randomly change, reset the GDM links
  • if the FEs complain - do in order: for GDM, CDM01, CDM02, ..., press "reset mgt" of each board, then press "unreset mgt", if it does not help, STOP HERE
  • start a run
  • CDM frontend will enable the trigger
  • GDM frontend will enable the trigger
  • LEDs on the GDM should flash, LEDs on the CDM should flash, TrigIn and TrigOut of the VX should flash
  • stop a run
  • GDM frontend will disable the trigger
  • CDM frontend will disable the trigger

Phase measurement

daq00:PhaseMeasurement$ python3 ./phaseMeasurement.py --help
usage: phaseMeasurement.py [-h] fileName numberEvents numberVX sizeEvents stopEvent minHist maxHist numberBin writeToTXT saveAsPDF

Read data from midas file (in .lz4 format) to calculate phase between the clock of VX1 and VX2

positional arguments:
  fileName      Name of the file we want to read data from (Example: run00389.mid.lz4)
  numberEvents  Number of events recorded in the file
  numberVX      Number of VX used in this run (usually 2...)
  sizeEvents    Number of points per event
  stopEvent     Number of events you want to go through to calculate phase
  minHist       Minimal value for the x axis of the phase measurement histogram (in ns)
  maxHist       Maximal value for the x axis of the phase measurement histogram (in ns)
  numberBin     Number of bins wanted for the generated histogram
  writeToTXT    Write argument as yes to generate text file with results of calculation
  saveAsPDF     Save generated plots to PDF files

optional arguments:
  -h, --help    show this help message and exit
daq00:PhaseMeasurement$ 
  • try an old file with
  • python3 ./phaseMeasurement.py run00877.mid.lz4 10000 2 10000 500 -20 20 81 yes yes
bin size = 0.494 ns
num_events =  347
mean = -1.705 ns
rms = 3.087 ns
mean_error = 0.166 ns
centroid = -1.706 ns.
width (sigma) = 0.363 ns.
error on the centroid = 0.016558 ns.
  • ls -l *.txt *.pdf
dsdaq@dsvslice:~/online/PhaseMeasurement$ ls -l *.txt *.pdf
-rw-rw-r-- 1 dsdaq dsdaq 64728 Dec 14 16:56 run00877.mid.lz4_Plots.pdf
-rw-rw-r-- 1 dsdaq dsdaq   274 Dec 14 16:56 run00877.mid.lz4.txt
dsdaq@dsvslice:~/online/PhaseMeasurement$ 
  • scope settings (from email message)
From fcote-lortie@triumf.ca  Thu Dec 15 17:11:46 2022
From: Francis Cote-Lortie <fcote-lortie@triumf.ca>
To: Konstantin Olchanski <olchansk@triumf.ca>
Subject: Re: How to use scope as a waveform generator
Date: Fri, 16 Dec 2022 01:11:44 +0000

  1.  Turn the power on (bottom left of the scope)
  2.  Access the waveform generator display by pressing the Gen button (bottom right of the scope)
  3.  The waveform generator display allows you to choose wave type (sine, square, etc.), frequency, amplitude, offset, etc. The display is a touch screen. Make the
waveform you want by using the different options.
  4.  Turn the output on (first option on the display) by pressing on the button. It will go from 0 to 1.

     The settings that we are using right now are:
      Type of waveform: Sine wave
      Offset: 0 V
      Amplitude: 1 Vpp
      Frequency: 50 kHz
      Noise: 0 V
________________________________
From: Francis Cote-Lortie <fcote-lortie@triumf.ca>
Sent: Thursday, December 15, 2022 4:58 PM
To: Konstantin Olchanski <olchansk@triumf.ca>
Subject: Re: How to use scope as a waveform generator


  1.  Turn the power on (bottom left of the scope)
  2.  Access the waveform generator display by pressing the Gen button (bottom right of the scope)
  3.  The waveform generator display allows you to choose wave type (sine, square, etc.), frequency, amplitude, offset, etc. The display is a touch screen. Make the
waveform you want by using the different options.
  4.  Turn the output on (first option on the display)

     The settings that we are using right now are:
      Type of waveform: Sine wave
      Offset: 0 V
      Amplitude: 1 Vpp
      Frequency: 50 kHz
      Noise: 0 V
________________________________
From: Francis Cote-Lortie
Sent: Thursday, December 15, 2022 4:54 PM
To: Konstantin Olchanski <olchansk@triumf.ca>
Subject: How to use scope as a waveform generator


  1.  Turn the power on (bottom left of the scope)
  2.  Access the waveform generator display by pressing the Gen button (bottom right of the scope)
  3.  The waveform generator display allows you to choose wave type (sine, square, etc.), frequency, amplitude, offset, etc. The display is a touch screen. Make the
waveform you want by using the different options.
  4.  Turn the output on (first option on the display)

Standalone link test

CDM: program clock chip
busybox devmem 0x80011000 32 0x8
busybox devmem 0x80011000 32 0x0
/home/dsdaq/si5394-i2c-file CDM_v3.0_IN1_fixed_and_IN2_RX_Recovered_VX_62.5MHz_Si5394-RevA-Registers.txt  0 0x6b

GDM, CDM: link reset
busybox devmem 0x80011008 32 1

GDM, CDM: release reset
busybox devmem 0x80011008 32 0

CDM: link status (NOTE: SFP LOS and mod_absent are swapped!!!)
busybox devmem 0x80011010 32
0x00000024 <- fiber plugged
0x00000025 <- fiber unplugged
0x00000027 <- SFP unplugged
0x000007DC <- successful link with GDM

CDM: link state machine and data
busybox devmem 0x80011014 32
0x35C06FF6

CDM: set link to counting mode
busybox devmem 0x80012000 32 0x101
busybox devmem 0x80012000 32 0x100

CDM: time counter and error counter
root@cdm1:~# busybox devmem 0x80012000 32
0x00000100 <--- link mode
root@cdm1:~# busybox devmem 0x80012004 32
0x0000058C <--- seconds counter
root@cdm1:~# busybox devmem 0x80012004 32
0x0000058D
root@cdm1:~# busybox devmem 0x80012008 32
0x00000000 <--- error counter

GDM: no link
root@gdm0:~# busybox devmem 0x80011014 32
0x00000000
root@gdm0:~# busybox devmem 0x80011018 32
0x00000000
root@gdm0:~# busybox devmem 0x8001101c 32
0x00000000
root@gdm0:~# busybox devmem 0x80011024 32
0x00000FFF
root@gdm0:~# 

GDM: good link channel 10, counting mode
root@gdm0:~# busybox devmem 0x80012000 32 0x101
root@gdm0:~# busybox devmem 0x80012000 32 0x100
root@gdm0:~# busybox devmem 0x80012008 32
0x3A8B68C2
root@gdm0:~# busybox devmem 0x80012008 32
0x42E03BEF
root@gdm0:~# busybox devmem 0x8001200c 32
0xDA090972
root@gdm0:~# busybox devmem 0x8001200c 32
0xDE6F22E9
root@gdm0:~# busybox devmem 0x80012019 32
Bus error
root@gdm0:~# busybox devmem 0x80012010 32
0xFFFFFFFF
root@gdm0:~# busybox devmem 0x80012014 32
0xFFFFFFFF
root@gdm0:~# busybox devmem 0x80012018 32
0xFFFFFFFF
root@gdm0:~# busybox devmem 0x8001201c 32
0xFFFFFFFF
root@gdm0:~# busybox devmem 0x80012020 32
0xFFFFFFFF
root@gdm0:~# busybox devmem 0x80012024 32
0xFFFFFFFF
root@gdm0:~# busybox devmem 0x80012028 32
0x00000000
root@gdm0:~# busybox devmem 0x8001202c 32
0xFFFFFFFF
root@gdm0:~# busybox devmem 0x80012030 32
0xFFFFFFFF
root@gdm0:~# busybox devmem 0x80012034 32
0xFFFFFFFF
root@gdm0:~# 

mapping of link channels:

qsfp0 lane0 - 0x0100 - link 8
qsfp0 lane1 - 0x0200 - link 9
qsfp0 lane2 - 0x0400 - link 10
qsfp0 lane3 - n/c
qsfp1 lane0 - 0x0800 - link 11
qsfp1 lane1 - 0x0010 - link 4
qsfp1 lane2 - 0x0020 - link 5
qsfp1 lane3 - n/c
qsfp2 lane0 - 0x0040 - link 6
qsfp2 lane1 - 0x0080 - link 7
qsfp2 lane2 - 0x0001 - link 0
qsfp2 lane3 - n/c
qsfp3 lane0 - 0x0002 - link 1
qsfp3 lane1 - 0x0004 - link 2
qsfp3 lane2 - 0x0008 - link 3
qsfp3 lane3 - n/c

script to start the test with 2 CDMs:

ssh dsdaq@dsvslice
ssh root@gdm0 busybox devmem 0x80011008 32 1
ssh root@cdm0 busybox devmem 0x80011008 32 1
ssh root@cdm1 busybox devmem 0x80011008 32 1
ssh root@gdm0 busybox devmem 0x80011008 32 0
ssh root@cdm1 busybox devmem 0x80011008 32 0
ssh root@cdm0 busybox devmem 0x80011008 32 0
ssh root@gdm0 /home/dsdaq/online/ds-dm-software/test_cdm.exe --link-test2
ssh root@cdm0 /home/dsdaq/online/ds-dm-software/test_cdm.exe --link-test2
ssh root@cdm1 /home/dsdaq/online/ds-dm-software/test_cdm.exe --link-test2

LEMO trigger GDM to CDM to VX

on the GDM:

/home/dsdaq/si5394-i2c-file /home/dsdaq/GDM_v1.0_IN0_EXT1_and_IN1_fixed_Si5394-RevA-Registers.txt 0 0x6b
busybox devmem 0x80011008 32 0x1
busybox devmem 0x80011008 32 0x0
/home/dsdaq/online/ds-dm-software/test_cdm.exe --writereg 23 0x80001230 # QSFP TX fixed pattern
/home/dsdaq/online/ds-dm-software/test_cdm.exe --writereg 2 0xff # enable LEMO inputs
/home/dsdaq/online/ds-dm-software/test_cdm.exe --writereg 3 0x7654 # enable LED, one per LEMO input
/home/dsdaq/online/ds-dm-software/test_cdm.exe --writereg 9 0x0F0F # enable LEMO to trg_in and tsm_in
/home/dsdaq/online/ds-dm-software/test_cdm.exe --writereg 23 0x40001230 # enable trg_in and tsm_in output to QSFP

on the CDM:

/home/dsdaq/si5394-i2c-file /home/dsdaq/CDM_v3.0_IN1_fixed_and_IN2_RX_Recovered_VX_62.5MHz_Si5394-RevA-Registers.txt 0 0x6b
/home/dsdaq/online/ds-dm-software/test_cdm.exe --cdm-clocks
/home/dsdaq/online/ds-dm-software/test_cdm.exe --sfp
busybox devmem 0x80011008 32 1
busybox devmem 0x80011008 32 0
/home/dsdaq/online/ds-dm-software/test_cdm.exe --cdm-link
/home/dsdaq/online/ds-dm-software/test_cdm.exe --writereg 9 0x8040 # trg_in from sfp[0], tsm_in form sfp[1]
/home/dsdaq/online/ds-dm-software/test_cdm.exe 11 # trg_in counter
/home/dsdaq/online/ds-dm-software/test_cdm.exe 12 # tsm_in counter

GPS receiver VCL-2705

gnss-help
gnss-showver -> F/W: Ver 1.7 Feb 17 2020 16:20:43

gnss-showselftest -> no antenna connected
Overall   : FAIL
EPROM Test: PASS
Antenna   : NOT DETECTED
GNSS      : COMMUNICATION OK

gnss-showsettings
GNSS NMEA BAUDRATE        :115200
GNSS ANTENNA LENGTH       :30 meters
GNSS USER CONFIGURED DELAY:-65 nanoseconds
GNSS 1PPS PULSE WIDTH     :200 milliseconds
GNSS MODE                 :GPS
GNSS STATUS               :STATIONARY

GNSSAUX> gnss-showserial
SERIAL :2704H01V17MAX310

GNSSAUX> gnss-showmode
GNSS MODE : GPS

GNSSAUX> gnss-showstatus
GNSS STATUS: STATIONARY

GNSSAUX> gnss-showalarms
CURRENT ALARMS GNSS
ANTENNA   : NOT DETECTED

GNSSAUX> gnss-showerrors
CURRENT ALARMS GNSS
ANTENNA : **NOT DETECTED
ERROR STATISTICS GNSS
RMC GOOD DURATION  : Secs 0
RMC BAD DURATION   : Secs 0
LOCK GOOD SECS DURATION  : Secs 0
LOCK BAD SECS DURATION   : Secs 0
SATINFO GOOD ITERATIONS   :0
SATINFO REJECT ITERATIONS :0
SATINFO NOTALKER ITERATIONS   :0
CURRENT MONITOR STATE GNSS
STATE :Phase-1 HUNTING ANTENNA DETECT

GNSSAUX> gnss-showsatinfo
GNSS RECEIVER ANTENNA Not Detected !

GNSSAUX> gnss-showsats
Total Sats: 0

GNSSAUX> gnss-showmyloc
GNSS RECEIVER ANTENNA Not Detected !

GNSSAUX> gnss-show1ppsstate 
GNSS RECEIVER ANTENNA Not Detected !

GNSSAUX> gnss-showjamstatus
Not Available !

GNSSAUX> gnss-showspoofstatus
Not Available !

--- antenna connected, can see the sky ---

GNSSAUX> gnss-showselftest
Overall   : PASS
EPROM Test: PASS
Antenna   : DETECTED
GNSS      : COMMUNICATION OK

GNSSAUX> gnss-showalarms
CURRENT ALARMS GNSS
ANTENNA   : DETECTED
GNSS LOCK : AVAILABLE

GNSSAUX> gnss-showerrors
CURRENT ALARMS GNSS
ANTENNA : DETECTED
GNSS LOCK : AVAILABLE
ERROR STATISTICS GNSS
RMC GOOD DURATION  : Mins 1,Secs 34
RMC BAD DURATION   : Secs 55
LOCK GOOD SECS DURATION  : Mins 1,Secs 34
LOCK BAD SECS DURATION   : Secs 55
SATINFO GOOD ITERATIONS   :3
SATINFO REJECT ITERATIONS :0
SATINFO NOTALKER ITERATIONS   :0
CURRENT MONITOR STATE GNSS
STATE :Phase-4 NORMAL OPERATION, Monitoring GNSSLOCK

GNSSAUX> gnss-showsatinfo
GNSS MODE :GPS
SATELLITE INFORMATION  TALKER:GPS
NMEA ID : 01-32
NO OF SATELLITES IN VIEW: 08
NO OF XXGSV MSGS        : 03
SatNo   PRN NO (SV ID)      ELEVATION (degs)    AZIMUTH (degs)      C/No (SNR)
1       0                   0                   0                   0                   
2       0                   0                   0                   0                   
3       0                   0                   0                   0                   
4       0                   0                   0                   0                   
5       0                   0                   0                   0                   
6       0                   0                   0                   0                   
7       0                   0                   0                   0                   
8       0                   0                   0                   0                   
<<<<<< End of Sat Info >>>>>>

GNSSAUX> gnss-showsats
Total Sats: 8

GNSSAUX> gnss-showmyloc
GNSS RECEIVER LOCATION:
Latitude : 4914.81911
Longitude: 12313.69595

GNSSAUX> gnss-show1ppsstate
GPS 1PPS STATE: LOCKED

GNSSAUX> gnss-showmyloc        

GNSS RECEIVER LOCATION:
Latitude : 4914.80688
Longitude: 12313.69531

enter into google maps search box as: 49 14.80688, -123 13.69531, observe the space, the moved dot and the minus.

GNSSAUX> gnss-resetgnss

Executing....Please Wait....
$$$$$END
  • 1PPS BNC output: period 1 sec, pulse width 200 ms, 3.3V into 1MOhm, 1.38V into 50Ohm.
  • IRIG-B BNC output: 5.6V into 1MOhm, 2.4V into 50Ohm.
  • IRIG-B format selector: default is all up.

Rb clock PRS10

  • https://www.thinksrs.com/products/prs10.html
  • 10 MHz output is sine wave around 5V peak to peak
  • 1PPS BNC output is 10 usec pulse, 5V into 1MHohm.
  • RS232 connection: minicom -D /dev/ttyUSB0 -b 9600
  • ser2net config: localhost,3001:raw:600:usb-5-2-1.0:9600 -XONXOFF -RTSCTS LOCAL
  • ssh daq13, cd /home/olchansk/git/ser2net, ./ser2net -c ~/daq/ds/ser2net.conf -d
  • ssh daq13, cd ~/daq/ds, python3 prs10.py
  • RS232 commands:
ID?
PRS10_3.56_SN_105719
VB1
SN?
RS1 -- reset
ST? -- status
FC? -- 10MHz OCXO drive voltage DAC settings
DS? -- "detected signals"
GA? -- gain of frequency lock loop between ovenized oscillator and Rb cell, 0=use ovenized oscillator only
MO? -- magnetic offset of the Rb cell, range 2300..3600, if out of range, unit must be set to different operating mode, see prs10m.pdf
MR? -- magnetic read
TT? -- time-tag, time in ns between 1PPS out and 1PPS in
TS? -- time slope, ???
TO? -- time offset, ???
PS? -- pulse slope, ???
PL? -- 0=phase lock off, 1=phase lock on, lock to 1PPS input
PT? -- phase lock integrator time constant, PT8 is integrator time constant 18.2 hours, natural time constant 2.25 hours
PF? -- phase lock stability factor, PF2 is "1"
PI? -- phase lock integrator

Analog to digital 12 bit ADC, values 0.000 to 4.998

AD0? -- Spare (J204)
AD1? -- +24V(heater supply) divided by 10.
AD2? -- +24V(electronics supply) divided by 10
AD3? -- Drain voltage to lamp FET divided by 10
AD4? -- Gate voltage to lamp FET divided by 10
AD5? -- Crystal heater control voltage
AD6? -- Resonance cell heater control voltage
AD7? -- Discharge lamp heater control voltage
AD8? -- Amplified ac photosignal
AD9? -- Photocell’s I/V converter voltage divided by 4
AD10? -- Case temperature (10 mV/°C)
AD11? -- Crystal thermistors
AD12? -- Cell thermistors
AD13? -- Lamp thermistors
AD14? -- Frequency calibration pot / external calibration voltage
AD15? -- Analog ground

A/D via CPU E-port:

AD16? -- Varactor voltage for 22.48 MHz VCXO (inside RF synthesizer) / 4
AD17? -- Varactor voltage for 360 MHz VCO (output of RF synthesizer) / 4
AD18? -- Gain control voltage for amplifier which drives frequency multiplier / 4
AD19? -- RF synthesizer’s lock indicator voltage (nominally 4.8 V when locked )

ST?

ST1 : Power supplies and Discharge Lamp
ST1 bit, Condition which sets bit, Corrective Action
0 -- +24 for electronic < +22 Vdc
1 -- +24 for electronics > +30 Vdc
2 -- +24 for heaters <+22 Vdc
3 -- +24 for heaters > +30 Vdc
4 -- Lamp light level too low
5 -- Lamp light level too high
6 -- Gate voltage too low
7 -- Gate voltage too high

ST2: RF Synthesizer
ST2 bit, Condition which sets bit, Corrective Action
0 -- RF synthesizer PLL unlocked
1 -- RF crystal varactor too low
2 -- RF crystal varactor too high
3 -- RF VCO control too low
4 -- RF VCO control too high
5 -- RF AGC control too low
6 -- RF AGC control too high
7 -- Bad PLL parameter

ST3: Temperature Controllers
ST3 bit, Condition which sets bit
0 -- Lamp temp below set point
1 -- Lamp temp above set point
2 -- Crystal temp below set point
3 -- Crystal temp above set point
4 -- Cell temp below set point
5 -- Cell temp above set point
6 -- Case temperature too low
7 -- Case temperature too high

ST4: Frequency Lock-Loop Control
ST4 bit, Condition which sets bit
0 -- Frequency lock control is off
1 -- Frequency lock is disabled
2 -- 10 MHz EFC is too high
3 -- 10 MHz EFC is too low
4 -- Analog cal voltage > 4.9 V
5 -- Analog cal voltage < 0.1
6 -- not used
7 -- not used

ST5: Frequency Lock to External 1pps
ST5 bit, Condition which sets bit
0 -- PLL disabled
1 -- < 256 good 1pps inputs
2 -- PLL active
3 -- > 256 bad 1pps inputs
4 -- Excessive time interval
5 -- PLL restarted
6 -- f control saturated
7 -- No 1pps input

ST6: System Level Events
ST6 bit and Condition which sets bit
0 Lamp restart
1 Watchdog time-out and reset
2 Bad interrupt vector
3 EEPROM write failure
4 EEPROM data corruption
5 Bad command syntax
6 Bad command parameter
7 Unit has been reset
  • ST? on warm start
received:  PRS_10
received:  255,255,255,243,34,255
received:  0,0,0,1,34,0
...
received:  0,0,0,1,34,0
received:  0,0,0,0,2,0
...
received:  0,0,0,0,2,0
received:  0,0,0,0,4,0
  • ST? on loss of external 1PPS
...
received:  0,0,0,0,4,0
disconnect 1PPS input
received:  0,0,0,0,132,0
...
reconnect 1PPS input
received:  0,0,0,0,132,0
received:  0,0,0,0,4,0
...
  • ST? on coldish start
daq13:ds$ python3 prs10.py
Connected
received [  ] old [ b'' ] counter:  0
received [ PRS_10 ] old [  ] counter:  0
received [ 255,255,255,243,34,255 ] old [ PRS_10 ] counter:  0
received [ 80,0,0,1,34,1 ] old [ 255,255,255,243,34,255 ] counter:  0
received [ 0,0,1,1,34,0 ] old [ 80,0,0,1,34,1 ] counter:  0
received [ 0,0,0,1,34,0 ] old [ 0,0,1,1,34,0 ] counter:  0
received [ 0,0,16,1,34,0 ] old [ 0,0,0,1,34,0 ] counter:  6
received [ 0,0,20,1,34,0 ] old [ 0,0,16,1,34,0 ] counter:  5
received [ 0,0,4,1,34,0 ] old [ 0,0,20,1,34,0 ] counter:  8
received [ 0,0,0,1,34,0 ] old [ 0,0,4,1,34,0 ] counter:  3
received [ 0,0,0,0,2,0 ] old [ 0,0,0,1,34,0 ] counter:  49
received [ 0,0,0,0,4,0 ] old [ 0,0,0,0,2,0 ] counter:  250
...
  • ST? on cold start, note: no bump in the 10MHz clock as reported by DS-DM clock chip
Connected
received [  ] old [ b'' ] counter:  0
received [ PRS_10 ] old [  ] counter:  0
received [ 255,255,255,243,34,255 ] old [ PRS_10 ] counter:  0
received [ 80,0,21,1,34,1 ] old [ 255,255,255,243,34,255 ] counter:  0
received [ 64,0,21,1,34,0 ] old [ 80,0,21,1,34,1 ] counter:  0
received [ 0,0,21,1,34,0 ] old [ 64,0,21,1,34,0 ] counter:  0
received [ 0,0,20,1,34,0 ] old [ 0,0,21,1,34,0 ] counter:  158
received [ 0,0,4,1,34,0 ] old [ 0,0,20,1,34,0 ] counter:  23
received [ 0,0,0,1,34,0 ] old [ 0,0,4,1,34,0 ] counter:  47
received [ 0,0,0,0,2,0 ] old [ 0,0,0,1,34,0 ] counter:  40
received [ 0,0,0,0,4,0 ] old [ 0,0,0,0,2,0 ] counter:  249

det fac integration test

Connections:

  • GPS receiver "IRIG-B SEL" both switches "up" - both "on", IRIG-B format B004
  • GPS receiver USB-B -> long cable -> daq13 USB-A
  • GPS receiver "1PPS out" -> long BNC cable -> BNC-T -> scope (5V, no 50ohm) and Rb clock BNC "1PPS in"
  • GPS receiver "IRIG-B 50ohms" -> long BNC cable -> BNC-T -> scope (5V, no 50ohm) and DS-DM LEMO input 1 (TTL mode)
  • Rb clock RS232 -> RS232 straight cable -> RS232-to-USB adapter -> daq13 USB-A
  • Rb clock "1PPS out" BNC -> scope (5V, no 50ohm, trig threshold rising edge 2V)
  • Rb clock "10MHz output 50 Ohm" BNC -> lemo -> lemo-T -> scope (sine wave, 5V, no 50ohm) and DS-DM clock input.

Programs to run:

  • on daq13: cd /home/olchansk/git/ser2net, ./ser2net -c ~/daq/ds/ser2net.conf -d
localhost,3001:raw:600:usb-5-2-1.0:9600  -XONXOFF -RTSCTS LOCAL
  • on daq13: cd /home/olchansk/daq/ds, python3 prs10.py ### connects to ser2net
daq13:ds$ python3 prs10.py
Connected
received [  ] old [ b'' ] counter:  0
received [ PRS_10 ] old [  ] counter:  0
received [ 255,255,255,243,34,255 ] old [ PRS_10 ] counter:  0
received [ 80,0,21,1,34,1 ] old [ 255,255,255,243,34,255 ] counter:  0
received [ 64,0,21,1,34,0 ] old [ 80,0,21,1,34,1 ] counter:  0
received [ 0,0,21,1,34,0 ] old [ 64,0,21,1,34,0 ] counter:  0
received [ 0,0,20,1,34,0 ] old [ 0,0,21,1,34,0 ] counter:  158
received [ 0,0,4,1,34,0 ] old [ 0,0,20,1,34,0 ] counter:  23
received [ 0,0,0,1,34,0 ] old [ 0,0,4,1,34,0 ] counter:  47
received [ 0,0,0,0,2,0 ] old [ 0,0,0,1,34,0 ] counter:  40
received [ 0,0,0,0,4,0 ] old [ 0,0,0,0,2,0 ] counter:  249
received [ 0,0,0,0,132,0 ] old [ 0,0,0,0,4,0 ] counter:  12096
received [ 0,0,0,0,20,0 ] old [ 0,0,0,0,132,0 ] counter:  2
received [ 0,0,0,0,148,0 ] old [ 0,0,0,0,20,0 ] counter:  0
received [ 0,0,0,0,4,0 ] old [ 0,0,0,0,148,0 ] counter:  575
received [ 0,0,0,0,132,0 ] old [ 0,0,0,0,4,0 ] counter:  11449
received [ 0,0,0,0,4,0 ] old [ 0,0,0,0,132,0 ] counter:  0
received [ 0,0,0,0,132,0 ] old [ 0,0,0,0,4,0 ] counter:  2755
received [ 0,0,0,0,4,0 ] old [ 0,0,0,0,132,0 ] counter:  0
received [ 0,0,0,0,132,0 ] old [ 0,0,0,0,4,0 ] counter:  34386
received [ 0,0,0,0,4,0 ] old [ 0,0,0,0,132,0 ] counter:  0
received [ 0,0,0,0,132,0 ] old [ 0,0,0,0,4,0 ] counter:  41035
received [ 0,0,0,0,4,0 ] old [ 0,0,0,0,132,0 ] counter:  0
received [ 0,0,0,0,132,0 ] old [ 0,0,0,0,4,0 ] counter:  113401
received [ 0,0,0,0,4,0 ] old [ 0,0,0,0,132,0 ] counter:  0
received [ 0,0,0,0,132,0 ] old [ 0,0,0,0,4,0 ] counter:  33375
received [ 0,0,0,0,4,0 ] old [ 0,0,0,0,132,0 ] counter:  0
received [ 0,0,0,0,132,0 ] old [ 0,0,0,0,4,0 ] counter:  54767
received [ 0,0,0,0,4,0 ] old [ 0,0,0,0,132,0 ] counter:  0
received [ 0,0,0,0,132,0 ] old [ 0,0,0,0,4,0 ] counter:  85059
received [ 0,0,0,0,4,0 ] old [ 0,0,0,0,132,0 ] counter:  0
received [ 0,0,0,0,132,0 ] old [ 0,0,0,0,4,0 ] counter:  33222
received [ 0,0,0,0,4,0 ] old [ 0,0,0,0,132,0 ] counter:  0
received [ 0,0,0,0,132,0 ] old [ 0,0,0,0,4,0 ] counter:  119234
received [ 0,0,0,0,4,0 ] old [ 0,0,0,0,132,0 ] counter:  0
received [ 0,0,0,0,132,0 ] old [ 0,0,0,0,4,0 ] counter:  121990
received [ 0,0,0,0,4,0 ] old [ 0,0,0,0,132,0 ] counter:  0
received [ 0,0,0,0,132,0 ] old [ 0,0,0,0,4,0 ] counter:  128184
received [ 0,0,0,0,4,0 ] old [ 0,0,0,0,132,0 ] counter:  0
received [ 0,0,0,0,132,0 ] old [ 0,0,0,0,4,0 ] counter:  56002
received [ 0,0,0,0,4,0 ] old [ 0,0,0,0,132,0 ] counter:  0
received [ 0,0,0,0,132,0 ] old [ 0,0,0,0,4,0 ] counter:  428237
received [ 0,0,0,0,4,0 ] old [ 0,0,0,0,132,0 ] counter:  0
received [ 0,0,0,0,132,0 ] old [ 0,0,0,0,4,0 ] counter:  8250
received [ 0,0,0,0,4,0 ] old [ 0,0,0,0,132,0 ] counter:  0
received [ 0,0,0,0,132,0 ] old [ 0,0,0,0,4,0 ] counter:  1388
received [ 0,0,0,0,4,0 ] old [ 0,0,0,0,132,0 ] counter:  0
received [ 0,0,0,0,132,0 ] old [ 0,0,0,0,4,0 ] counter:  30506
received [ 0,0,0,0,4,0 ] old [ 0,0,0,0,132,0 ] counter:  0
received [ 0,0,0,0,132,0 ] old [ 0,0,0,0,4,0 ] counter:  142704
received [ 0,0,0,0,4,0 ] old [ 0,0,0,0,132,0 ] counter:  0
received [ 0,0,0,0,132,0 ] old [ 0,0,0,0,4,0 ] counter:  179451
received [ 0,0,0,0,4,0 ] old [ 0,0,0,0,132,0 ] counter:  0
received [ 0,0,0,0,132,0 ] old [ 0,0,0,0,4,0 ] counter:  106182
received [ 0,0,0,0,4,0 ] old [ 0,0,0,0,132,0 ] counter:  0
received [ 0,0,0,0,132,0 ] old [ 0,0,0,0,4,0 ] counter:  68747
received [ 0,0,0,0,4,0 ] old [ 0,0,0,0,132,0 ] counter:  0
received [ 0,0,0,0,132,0 ] old [ 0,0,0,0,4,0 ] counter:  65424
received [ 0,0,0,0,4,0 ] old [ 0,0,0,0,132,0 ] counter:  0
received [ 0,0,0,0,132,0 ] old [ 0,0,0,0,4,0 ] counter:  157587
received [ 0,0,0,0,4,0 ] old [ 0,0,0,0,132,0 ] counter:  0
received [ 0,0,0,0,132,0 ] old [ 0,0,0,0,4,0 ] counter:  6932
received [ 0,0,0,0,4,0 ] old [ 0,0,0,0,132,0 ] counter:  0
received [ 0,0,0,0,132,0 ] old [ 0,0,0,0,4,0 ] counter:  1388
received [ 0,0,0,0,4,0 ] old [ 0,0,0,0,132,0 ] counter:  0
received [ 0,0,0,0,132,0 ] old [ 0,0,0,0,4,0 ] counter:  20255
received [ 0,0,0,0,4,0 ] old [ 0,0,0,0,132,0 ] counter:  0
received [ 0,0,0,0,132,0 ] old [ 0,0,0,0,4,0 ] counter:  4
received [ 0,0,0,0,4,0 ] old [ 0,0,0,0,132,0 ] counter:  0
received [ 0,0,0,0,132,0 ] old [ 0,0,0,0,4,0 ] counter:  225941
received [ 0,0,0,0,4,0 ] old [ 0,0,0,0,132,0 ] counter:  0
received [ 0,0,0,0,132,0 ] old [ 0,0,0,0,4,0 ] counter:  72183
received [ 0,0,0,0,4,0 ] old [ 0,0,0,0,132,0 ] counter:  0
received [ 0,0,0,0,132,0 ] old [ 0,0,0,0,4,0 ] counter:  26970
received [ 0,0,0,0,4,0 ] old [ 0,0,0,0,132,0 ] counter:  1
39287
  • on ds-dm: ./test_cdm.exe --irigb ### note sbs mismatch is because I should wrap around at 16 bits
dataframe: S00000000S100001010S...S001010101S000001000S, sec: 00, min: 51, hrs: 22, day of year: 300, year: 2023, date: 27 oct, sbs: 16724 should be 82260
dataframe: S10000000S100001010S...S101010101S000001000S, sec: 01, min: 51, hrs: 22, day of year: 300, year: 2023, date: 27 oct, sbs: 16725 should be 82261
dataframe: S01000000S100001010S...S011010101S000001000S, sec: 02, min: 51, hrs: 22, day of year: 300, year: 2023, date: 27 oct, sbs: 16726 should be 82262
dataframe: S11000000S100001010S...S111010101S000001000S, sec: 03, min: 51, hrs: 22, day of year: 300, year: 2023, date: 27 oct, sbs: 16727 should be 82263
dataframe: S00100000S100001010S...S000110101S000001000S, sec: 04, min: 51, hrs: 22, day of year: 300, year: 2023, date: 27 oct, sbs: 16728 should be 82264
dataframe: S10100000S100001010S...S100110101S000001000S, sec: 05, min: 51, hrs: 22, day of year: 300, year: 2023, date: 27 oct, sbs: 16729 should be 82265

DS-IOGC GPS interface board

Changes Rev0 to Rev1

From: Peter Margetak <pmargetak@triumf.ca>
Subject: IOGC REV1 review
Date: Wed, 4 Sep 2024 07:31:19 +0000

Hi Konstantin,
Pls have a look at SCH for new rev. I'd like to send it to mfr next week so if you can comment by early next week. Meanwhile I work on layout and other stuff.

Changes:

New ICs - all powered +5V
U20 - inverters for  RUclk RX/TX
U21 - non inverting line driver for RU-1pps-out (so you don't have to route if via GDM to see it on scope)
U22 - non inverting buffer for ext 1pps input

All Lemo connectors have the same position but they are double lemos now => new panel needed
@Marek Walczak<mailto:mwalczak@triumf.ca> you can print it ahead once pcb is done + update IOGC docs and panel description

J2A/B - Test ports for RU-1pps in and out
J5A/B - inputs for external GPS data and External source of 1pps
J6A/B  - aux in/out for GDM

SW1 - no change - select RX/TX  USB/GDM
SW2 - select latch sensitivity for rising/falling edge
SW3 - select source of GPS data (opto or ext)  AND select source of 1pps input (latch or ext)

p.

PRS-10 Rb clock device

The Rb clock PRS-10 device provides these connections:

RS232 RX input - serial communication, non-standard RS232
RS232 TX output - serial communication, non-standard RS232
10 MHz clock output - coax 50 Ohm high resolution 10 MHz clock
1pps output - 1 Hz clock corresponding to the 10 MHz clock
1pps input - 1pps signal from GPS receiver

Mode of operation:

  • 10 MHz clock is always running
  • 1pps output is always running
  • if 1pps input from GPS received is present, after 256 pulses PRS-10 will sync it's 1pps output with the 1pps input by adjusting the frequency of the 10 MHz clock
  • when unlocked: 1pps output and 1pps input unrelated
  • when locked to GPS: 1pps output and 1pps input always go up and down at the same time

Theory of operation:

  • 10 MHz clock is produced by a high-quality crystal (stable on the scale of seconds)
  • crystal oscillator is synchronized to a Rb cell (stable on the scale of hours and days)
  • Rb cell resonant frequency is synchronized to the GPS 1pps signal (stable on the scale of months and years)

Rev1 connections

  • LEMO connectors (front panel)
LEMO J2A output - Rb clock 1pps in monitor
LEMO J2B output - Rb clock 1pps out monitor
LEMO J5A input  - GPS IRIG-B from GPS receiver to FPGA (VCL-2705)
LEMO J5B input  - GPS 1pps from GPS receiver to PRS-10 (VCL-2705)
LEMO J6A output - AUX-OUT from FPGA (dual-LEMO PCB-side)
LEMO J6B input  - AUX-IN to FPGA (dual-LEMO away-from -PCB)
  • SMB connectors (back)
SMB J3 output - GPS 1pps loopback to LNGS
SMB J4 input - LNGS GPS data input
  • LEDs
D1 - same as LEMO J2A out (Rb clock 1pps in)
D2 - same as SMB J3 out (GPS 1pps from LNGS or from a GPS receiver)
D5 - controlled by FPGA-OUT-LED1
D6 - controlled by FPGA-OUT-LED2
D7 - PRS-10 24V power ok
  • switches
SW1A and SW1B - route PRS-10 RS232 to USB or to FPGA
SW2A - route PRS-10 1pps input from SMB J4 (LNGS) or from LEMO J5B (GPS receiver 1pps)
SW2B - route FPGA-IN-GPSDATA input from SMB J4 (LNGS) or from LEMO J5A (GPS receiver IRIG-B data)
SW3 - LNGS 1pps from rising edge or from falling edge of SMB J4 (LNGS)

Rb clock cable

Rb clock ----- DS-IOGC side, pin numbers are as labeled on the cable connectors

1 - 1pps out - 8 - 1pps out                    --- correct
2 - nc
3 - nc
4 - TXD      - 3  - RU-DATA-OUT - USB-RX input --- correct
5 - 1pps in  - 2  - 1pps in                    --- correct
6 - +24V     - 10 - +24V                       --- should by pin 1 to use both +24V pins?
7 - RXD      - 15 - RU-DATA-IN - USB-TX output --- correct
8 - nc
9 - +24V     - 10 - +24V --- correct
10 - GND     - 9  - GND  --- correct

VX connections

VXA_TX0 - FPGA-OUT-LED2 - D6 LED ("10 MHz clock")
VXA_TX1 - FPGA-OUT-LED1 - D5 LED ("GPS DATA")
VXA_TX2 - FPGA-OUT-RU1PPS-EN - enable 1pps to Rb clock
VXA_TX3 - not used (62.5 Hz clock)

VXB_TX0 - FPGA-TX - PRS-10 RS-232 out
VXB_TX1 - FPGA-OUT-AUX - 5V TTL J5 LEMO out
VXB_TX2 - FPGA-OUT-OPTO1PPS-EN - PRS-10 power enable
VXB_TX3 - not used (62.5 MHz clock)

VXA_RX0 - FPGA-IN-OPTO1PPS - 1pps from GPS
VXA_RX1 - FPGA-IN-GPSDATA - J4 GPS data
VXA_RX2 - n/c
VXA_RX3 - n/c

VXB_RX0 - n/c
VXB_RX1 - FPGA-IN-AUX - J5 LEMO TTL input
VXB_RX2 - FPGA-RX - PRS-10 RS-232 in
VXB_RX3 - FPGA-IN_RU1PPS - PRS-10 1pps output

test sequence

  • ./test_cdm_local.exe --writereg 7 0 ### clear reg 7
  • ./test_cdm_local.exe --writereg 8 0 ### set vx_tx mux to vx_tx control from reg 7
  • connect blue cable to GDM port 6 (next to the ethernet connector)
  • ./test_cdm_local.exe --writereg 7 0x4000 ### power up
  • test LEDs:
  • ./test_cdm_local.exe --writereg 7 0x4100 ### right LED D6
  • ./test_cdm_local.exe --writereg 7 0x4200 ### left LED D5
  • test AUX-IN and AUX-OUT:
  • ./test_cdm_local.exe --writereg 7 0x6000 ### J6A LEMO (PCB-side) measure +5VDC
  • install LEMO jumper between LEMO J6A and J6B
  • write 0x4000 then ./test_cdm_local.exe 6 ### reads 0x5C, bit 5 0x20 reads 0
  • write 0x6000 then ./test_cdm_local.exe 6 ### reads 0x7C, bit 5 0x20 reads 1
  • write 0x4000 to clear all bits
  • test the 10 MHz clock:
  • init the c.c: ./test_cdm_local.exe --load-cc
  • connect 10 MHz clock output to DS-DM LEMO J6-LEFT (CLK_EXT1)
  • 10 MHz output ok - IN0 is good: ./test_cdm_local.exe --cc
Clock chip state 1, status:  OOF_IN2 IN1 IN_SEL_1 HOLD_HIST_VALID
  • without 10 MHz reports IN0 LOS (no signal) and OOF (wrong frequency)
Clock chip state 1, status:  LOS_IN0 OOF_IN0 OOF_IN2 IN1 IN_SEL_1 HOLD_HIST_VALID
  • test GPS IRIG-B data:
  • connect GPS IRIG-B signal to J6B (dual-LEMO away from PCB)
  • IRIG-B via AUX-IN is ok: ./test_cdm_local.exe --irigb
dataframe: S00100110S111001000S...S011110000S010000000S, sec: 34, min: 17, hrs: 00, day of year: 223, year: 2024, date: 10 aug, sbs:  1054 should be  1054
  • test GPS 1pps signal:
  • connect GPS 1pps to J5B (dual-LEMO away from PCB)
  • ./test_cdm_local.exe --writereg 8 9 ### set vx_tx mux to GPS control, hard enables PRS-10 power and PRS-10 1pps in
  • observe 1pps counters in reg 68 count at 1 Hz: rb_1pps 0x51->0x52, gps_1pps 0xd5->oxd6
root@dsdm:~# ./test_cdm_local.exe 68
ds20k_reg[68] is 0x0051d520 (5362976)
ds20k_reg[68] is 0x0052d624 (5428772)
...
  • observe PRS-10 can see the 1pps signal "130" changes to "2" after 243 seconds to "4"
  • observe period of GPS and PRS-10 1pps is identical (plus/minus 1 clock)
root@dsdm:~# ./test_cdm_local.exe 13 14
ds20k_reg[13] is 0x077356d4 (124999380)
ds20k_reg[14] is 0x077356d4 (124999380)
  • observe GDM/CDM clocks are exactly 125 MHz, we are running on DS-DM internal oscillator
root@dsdm:~# ./test_cdm_local.exe --gdm-clocks
GDM clock frequency counters:
0x1030 mgt_rx_ref_clk_raw: 0x07735943 (125000003) should be ~125 MHz
0x1034 rx_clk:             0x07735943 (125000003) should be ~125 MHz
0x1038 mgt_tx_ref_clk_raw: 0x07735943 (125000003) should be ~125 MHz
0x103C tx_clk:             0x07735943 (125000003) should be ~125 MHz
0x1040 clk_50MHz:          0x02faf080 (50000000) should be 50 MHz exactly
0x1044 Block1_clk:         0x05f5e100 (100000000) should be 100 MHz exactly
  • switch CC to external clock:
root@dsdm:~# ./test_cdm_local.exe --cc-in0
CC use clock input 0: 10 MHz LEMO external clock
root@dsdm:~# ./test_cdm_local.exe --cc
Polling CC status...
Clock chip state 1, status:  IN0 IN_SEL_REGCTRL IN_SEL_0 HOLD_HIST_VALID
  • observe rx_clk and tx_clk are now slightly off: they run from PRS-10 10 MHz clock and are measured against the DS-DM internal oscillator.
root@dsdm:~# ./test_cdm_local.exe --gdm-clocks
DS-DM mapping /dev/mem at 0x80010000
DS-DM FPGA firmware build 0x94b12519, ds20k version 0x20240814
DS-DM firmware build 0x94b12519, ds20k version 0x20240814
GDM clock frequency counters:
0x1030 mgt_rx_ref_clk_raw: 0x077358e1 (124999905) should be ~125 MHz
0x1034 rx_clk:             0x07735b49 (125000521) should be ~125 MHz
0x1038 mgt_tx_ref_clk_raw: 0x07735b49 (125000521) should be ~125 MHz
0x103C tx_clk:             0x07735b49 (125000521) should be ~125 MHz
0x1040 clk_50MHz:          0x02faf080 (50000000) should be 50 MHz exactly
0x1044 Block1_clk:         0x05f5e100 (100000000) should be 100 MHz exactly
  • observe GPS and PRS-10 1pps period is now exactly 125*10^6 of 8ns clocks (equal to 1 second)
root@dsdm:~# ./test_cdm_local.exe 13 14
ds20k_reg[13] is 0x0773593f (124999999)
ds20k_reg[14] is 0x0773593f (124999999)
  • look at them repeatedly, observe reg 13 "GPS 1pps period" has some wobble, reg 14 "Rb clock 1pps period" is steady. this is as expected: if GPS 1pps was steady, we do not need to Rb clock. PRS-10 1pps is derived from the PRS-10 10 MHz clock and is measured against the 125 MHz clock derived from the same 10 MHz clock in the GDM FPGA.

Rev0 Test status:

  • GPS 1pps to SMB-in ok (LED flashes)
  • GPS 1pps to FPGA ok
  • GPS data to FPGA ok
  • GPS 1pps to PRS-10 enabled from FPGA ok
  • PRS-10 Rb clock 1pps out to FPGA ok
  • PRS-10 Rb clock 1pps out to FPGA to LEMO AUX out ok
  • can see GPS 1pps, IRIG-B, PRS-10 1pps out, 10 MHz on the scope, ok
  • PRS-10 syncs on leading edge (0->1) of GPS 1pps signal, ok
  • reg 13 and 14 1pps periods are identical, ok
  • CC locks on PRS-10 10 MHz clock, DS-DM runs on PRS-10 clock, ok
  • NOT TESTED - smb output
  • NOT TESTED - optical converter fiber to SMB
  • NOT TESTED - optical converter SMB to fiber
  • NOT TESTED - SMB loopback
  • NOT TESTED - fiber loopback

Rev1 Test status: (21 Nov 2024)

  • power up ok
  • LEDs ok
  • LEMO AUX-IN, AUX-out ok
  • GPS IRIG-B to FPGA via AUX-IN ok
  • PRS-10 Rb clock 1pps out to FPGA ok
  • PRS-10 Rb clock 10 MHz to C.C. ok
  • PRS-10 RS-232 ok

VX busy logic

DS-20K DAQ

Overview

DS-DM, GDM and CDM are key parts of the DS-20K DAQ system:

  • common clock distribution from external clock (atomic clock, GPS) to GDM to per-quadrant CDMs to VX digitizers
  • common trigger distribution from GDM internal algorithm or external input to all VX digitizers
  • run control: GDM, CDM, VX all start recording data at the same time (clock and timestamp reset)
  • collection of trigger data from VX digitizers to per-quadrant CDMs to GDM

Deliverables

  • hardware and firmware for GDM to CDM clock distribution
  • hardware and firmware for CDM to VX clock distribution
  • hardware and firmware for GDM external clock input (atomic clock or GPS)
  • hardware and firmware for CDM and VX serial communications (VX LVDS I/O connector)
  • firmware for run control (timestamp reset and sync): GDM to CDM to VX
  • firmware for common trigger distribution: GDM to CDM to VX
  • firmware for trigger data flow: VX to CDM to GDM
  • firmware for busy control: VX to CDM to GDM back to CDM to VX
  • firmware for flow control: FEP to GDM MIDAS frontend to GDM to CDM to VX
  • GDM MIDAS frontend: clock selector and monitoring, trigger and run control, busy and flow control, GDM housekeeping
  • CDM MIDAS frontend: clock monitoring, CDM housekeeping

specific performance:

  • GDM external clock: 10 MHz GPS clock
  • GDM to CDM fiber link:
    • clock XXX MHz
    • link data rate: XXX Gbit/sec
    • CDM recovered clock: XXX MHz
    • CDM recovered clock jitter: XXX ns
    • phase alignment between CDMs: XXX ns
    • phase alignment between CDMs persists across reboots, power cycles, firmware updates
    • phase alignment between CDMs should be easy to measure
    • phase alignment between CDMs should be easy to recalibrate if hardware parts are replaced (DS-DM boards, fiber transceivers, fiber cables, etc)
    • data packet bandwidth: XXX Mbytes/sec
    • data packet latency: XXX clocks
    • data packet skew between CDMs: XXX clocks
  • CDM to VX clock:
    • clock: XXX MHz
    • jitter, all CDM clock outputs: XXX MHz
    • phase alignment between all CDM clock outputs: XXX ns
  • CDM to VX trigger:
    • TBD (use the VX "sync" input or VX LVDS I/O line or VX serial link packet)
  • CDM to VX serial link:
    • clock: XXX MHz (TBD: VX external clock, or LVDS I/O line or link recovered clock)
    • bit rate: XXX bits/sec
    • latency: XXX link clocks
    • maximum skew between VXes: XXX ns
  • VX to CDM serial link:
    • clock: XXX MHz (TBD: VX external clock, or LVDS I/O line or link recovered clock)
    • bit rate: XXX bits/sec
    • latency: XXX link clocks
    • maximum skew between VXes: XXX ns
  • timestamp reset:
    • maximum skew between VXes: XXX ns
  • busy round trip time: XXX ns (VX to CDM to GDM back to CDM to VX)
  • flow control latency: XXX ns (FEP software to GDM MIDAS frontend to GDM to CDM to VX)

Technical risk items

this refers to unexpected behaviour and performance of system components, causes big difficulty in implementing the system, prevents delivery of deliverables, and prevents or negatively affects operation of the DS-20K DAQ or of the whole experiment.

(14-sep-2022, list is not sorted by any criterial: severity, probability, ease of investigation)

(stability of course is long term stability, across hours, days, weeks, months, years)

  • stability of Enclustra FPGA modules (crashes/year, failures to boot/year, flash corruption/year)
  • stability of GDM external clock PLL (lock loss/year)
  • stability of CDM recovered clock (lock loss/year, unexpected phase drifts, etc)
  • unexpected failures or bit error rates in GDM-CDM fiber links
  • stability of CDM VX clock outputs (stability of clock cleaner chip)
  • stability of VX internal clock distribution (VX PLL lock loss events)
  • stability of VX CAEN base firmware (different versions of CAEN base firmware have different clock distribution behaviour)
  • strange things in CAEN base firmware (unexpected clocking of LVDS I/O, unexpected phase shifts between clocks, etc)
  • DS-DM and VX hardware problems (incompatible LVSD I/O, incompatible clock signals, etc)

Milestones

(14-sep-2022: at this stage of the project, priority must be given to identifying and retiring (so called) technical risk factors. it is not good to build the complete system only to discover that (for example) some Enclustra FPGA modules require 5 attempts to boot and erase their flash memory contents once a month. Both example are real-life actual problems that caused big difficulties in GRIFFIN/TIGRESS and ALPHA-g experiments).

Development and testing milestones in time reversed order:

  • full DAQ data challenge: all VXes, CDM, GDM, network, FEP, TSP, MIDAS operate as designed
  • one quadrant data challenge: 1 VME crate of VX, CDM, GDM, network, FEP, TSP, MIDAS operate as designed
  • vertical slice data challenge: 1 VME crate, 2 VX, 2 CDM (1 VX per CDM), GDM, etc operate as designed
  • GDM-CDM link finalized (data rate frozen, data packet format frozen, data content permitted to change)
  • CDM-VX serial link finalized (data rate frozen, data packet format frozen, data content permitted to change)
  • run control (timestamp reset) and trigger distribution design agreed upon, frozen (list of possible triggers permitted to change)
  • VX to CDM to GDM data flow design agreed upon, frozen (data contents permitted to change)
  • major technical risk items retired (all hardware and firmware is working as expecred without mysteries and surprises, all problems are identified, investigated, resolved, solutions tested)
  • stable operation of CDM-VX serial links in vertical slice system
  • stable operation of GDM to CDM clock in vertical slice system
  • stable operation of CDM to VX clock in vertical slice system
  • vertical slice system assembled (1 VME crate, 2 VX, 2 CDM, 1 GDM, network, FEP, TSP, MIDAS)

ZZZ

ZZZ