Difference between revisions of "Porting Theora to 353 cameras"

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(Compressor)
 
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Dealing with the last solution seems to be a good start for this project as the other features mentioned can be added later. In all cases, both FPGA code and software code will need to be adapted.
 
Dealing with the last solution seems to be a good start for this project as the other features mentioned can be added later. In all cases, both FPGA code and software code will need to be adapted.
  
 
+
The source code of this project is available at [http://elphel.cvs.sourceforge.net/elphel/fpga/theora_353/ http://elphel.cvs.sourceforge.net/elphel/fpga/theora_353/]
 
== Hardware updates ==
 
== Hardware updates ==
  
 
=== Compressor ===
 
=== Compressor ===
 +
[[Image:Schematic.png|frame|[[Media:Schematic.png|333 Theora design with the 2 stage compressor and the 8-channel memory controller]]]]
 
Replace the MJPEG compressor in the 353 with the 333 Theora compressor ([http://elphel.cvs.sourceforge.net/elphel/camera333/fpga/x333 333 Theora FPGA code]). Maybe some adaptations need to be done within the Theora compressor itself. However, assuming that the compressor worked in 333 cameras a simple instantiation should suffice.
 
Replace the MJPEG compressor in the 353 with the 333 Theora compressor ([http://elphel.cvs.sourceforge.net/elphel/camera333/fpga/x333 333 Theora FPGA code]). Maybe some adaptations need to be done within the Theora compressor itself. However, assuming that the compressor worked in 333 cameras a simple instantiation should suffice.
  
 
=== Memory controller ===
 
=== Memory controller ===
Replace the 4-channel memory controller with an 8-channel memory interface as in the 333 model in order to handle Theora specific data.
+
Replace the 4-channel memory controller with an 8 channel memory interface as in the 333 model in order to handle Theora specific data.
  
 
{|border="1" cellpadding="2"
 
{|border="1" cellpadding="2"
Line 506: Line 507:
 
== 353 Theora new design ==
 
== 353 Theora new design ==
 
=== Compressor ===
 
=== Compressor ===
 +
 +
Writing tables in compressor (and mcontr8ch) is the same than the 333 design :
 +
* ia = 0x2d and idi = table address (X313_WA_COMP_TA=0x2d)
 +
then
 +
* ia = 0x2c and idi = table data (X313_WA_COMP_TD=0x2c)
 +
 +
Example : Writing zerobin and quantization tables in 353 Theora design
 +
 +
[[Image:Writetabs.jpg]]
  
 
=== Sensorpix ===
 
=== Sensorpix ===
  
Some changes have to be done in this block to interface the sensor and the memory controller (ch0 and 1).
+
Most of the 353 design was used for the new design. Writing procedure for gamma tables in sensorpix block is the same than in 353 (ie with ta bus and twr_gamma signal).
 +
 
 +
*  ia = 0x0e and idi = table address
 +
 
 +
then
  
 +
* ia = 0x0f and idi = table data
 +
 +
Table address is not autoincremented within the sensorpix block but is fed externally with the ta bus.
 +
 +
[[Image:Gammatab.jpg]]
  
 
=== Memory controller ===
 
=== Memory controller ===
Line 557: Line 576:
 
|-
 
|-
 
| '''0x0a''' || da_framesync_dly || write frame sync interrupt delay (in scan lines)
 
| '''0x0a''' || da_framesync_dly || write frame sync interrupt delay (in scan lines)
 +
|-
 +
| '''0x0e''' || da_table_a0 || write gamma table address
 +
|-
 +
| '''0x0f''' || twr0 || write gamma table data
 
|-
 
|-
 
| '''0x10''' ||  || Status register
 
| '''0x10''' ||  || Status register
Line 760: Line 783:
 
== See also ==
 
== See also ==
  
 +
*[http://elphel.cvs.sourceforge.net/elphel/fpga/theora_353/ 353 Theora CVS]
 
*[[Theora]]
 
*[[Theora]]
 
*[[FPGA_Development_in_Elphel_cameras|FPGA Development in Elphel cameras]]
 
*[[FPGA_Development_in_Elphel_cameras|FPGA Development in Elphel cameras]]
 
*[[Design Ideas|FPGA Theora Encoder for Videoconferencing]]
 
*[[Design Ideas|FPGA Theora Encoder for Videoconferencing]]
 
*[[10353]]
 
*[[10353]]

Latest revision as of 07:16, 16 April 2008

Elphel model 333 cameras were able to encode and stream Ogg Theora with 6.3.9 firmware. However, this model is no longer produced by Elphel. The goal of this project is to use the full potential of 353 cameras (larger FPGA, faster CPU) in order to port the Ogg Theora feature on the new hardware. First, the camera should be able to upload small Theora clips via FTP.

Different solutions are possible as previously mentioned in the Theora page :

  • Instantiate both the Theora compressor and the MJPEG compressor in the FPGA since the new Spartan 3E seems to be large enough to handle the two features.
  • Replace the existing MJPEG compressor with the Theora compressor and implement software Theora to JPEG conversion if JPEG is needed.
  • Replace the existing MJPEG compressor in the 353 camera with the Theora compressor and keep two configuration files on the camera filesystem (one for Theora the other for MJPEG). FPGA code could be changed at run-time according to the needs.

Dealing with the last solution seems to be a good start for this project as the other features mentioned can be added later. In all cases, both FPGA code and software code will need to be adapted.

The source code of this project is available at http://elphel.cvs.sourceforge.net/elphel/fpga/theora_353/

Hardware updates

Compressor

Replace the MJPEG compressor in the 353 with the 333 Theora compressor (333 Theora FPGA code). Maybe some adaptations need to be done within the Theora compressor itself. However, assuming that the compressor worked in 333 cameras a simple instantiation should suffice.

Memory controller

Replace the 4-channel memory controller with an 8 channel memory interface as in the 333 model in order to handle Theora specific data.

Channel 333 Theora 353
0 8/16 bit data from sensor to SDRAM Data from the sensor (it can be combined with FPN correction data) to the SDRAM in either 8-bit mode or 16-bit
1 16 bit data from SDRAM to FPN correction module Reads FPN data from SDRAM (8bit - subtract, 8 bit - scale) and feeds it to FPGA for FPN correction of the data on the way from sensor to SDRAM (through channel 0)
2 20x20 tiles of raw data from SDRAM to the color space converter and compressor Provides data to JPEG encoder in 16x16x8bit MCUs. It can also provide data directly to CPU through DMA bypassing any compression
3 PIO read/write of SDRAM data Provides bidirectional access from CPU through 8x32 bit window.
4 Writing current (restored) frame as YCbCr 4:2:0 data to SDRAM
5 Reading previous frame as YCbCr 4:2:0 data from SDRAM
6 Writing 12-bit pre-tokens to SDRAM (in macroblock-scan order, starting with AC[63]
7 reading 12-bit pre-tokens from SDRAM in indexed coded order

Sensor interface

sensorpix block must be adapted in order to provide a coherent interface between the memory controller and the sensor (channels 0 and 1)


System Interface

Adapt the system interface to assure communication between FPGA and its environment.

A feature of the system interface is to establish communication between the system CPU and the different blocks within the FPGA (compressor, memory controller etc). This is done by selecting a block with the address bus a[12:0] connected to the internal address bus ial[7:0]:

x353.v
always @ (posedge cwr) begin
   a0[7:0]<=ial[7:0];  // may want to change to just ia if ia will be late enough;
   wnr0                <= ~irnw;
   da_ctl0             <= (ial[7:0]==8'h00);  // 0x00 WE to control 32-bit register (1 loc)
   da_dmamode0         <= (ial[7:0]==8'h01);  // 0x01 select writing to dma_cntr/dma_raw (1 loc)
   da_sensormode0      <= (ial[7:0]==8'h02);  // 0x02 select writing to sensorpix (1 loc)
   ...
   da_compressor0      <= (ial[7:1]==7'h06);  // 0x0c..0x0d - will be farther decoded in the compressor module
   ...

Since memory controller and compressor are to be replaced these addresses have to be adapted.


353 system interface address table

Address da signal Comments
0x00 da_ctl0 WE to control 32-bit register (1 loc)
0x01 da_dmamode0 select writing to dma_cntr/dma_raw (1 loc)
0x02 da_sensormode0 select writing to sensorpix (1 loc)
0x03 da_virttrig0 write virtual trigger threshold
0x04 da_sensortrig0 select writing to sensorpix (1 loc)
0x05 da_sensortrig_lines0 write number of lines to be transferred in a frame (or after trigger)
0x07 da_sens_dc0 write to sensor DCDC converter frequency divider
0x08 da_dcm0 tune SDRAM clock phase
0x09 da_saturation0 write color saturation values
0x0a da_framesync_dly0 write frame sync interrupt delay (in scan lines)
0x0c..0x0d da_compressor0 will be farther decoded in the compressor module
0x0e da_table_a0 write tables address
0x0f twr0 write tables data
0x10 Status register
0x1b dcmrst async signal to restart DCMs (if irnw=0)
0x1c..0x1f da_interrupts0 interrupt control
0x20..0x2f da_dswe0 select reading/writing to mcontr (16 locations)
0x30 da_mem0 read/write to SDRAM buffer, autoincrement address
0x40..0x43 da_hist0 write/read histogram related data/registers
0x44..0x47 da_rtc0 real time clock
0x48 da_timestamp0 write timestamp mode
0x74 da_xjtag0 write to external (sensor board) JTAG
0x78..0x7b da_extsync0 control of external sync module 0x78 - 0x7b


333 system interface address table

Address da signal Comments
0x00 da_ctl0 WE to control 32-bit register (1 loc)
0x01 da_dmamode0 select writing to dma_cntr/dma_raw (1 loc)
0x02 da_sensormode0 select writing to sensorpix (1 loc)
0x03 da_virttrig0 write virtual trigger threshold
0x04 da_sensortrig0 select writing to sensorpix (1 loc)
0x05 da_sensortrig_lines0 write number of lines to be transferred in a frame (or aftre trigger)
0x06 da_interrupts0 interrupt mask
0x07 da_sens_dc0 write to sensor DCDC converter frequency divider
0x08 da_dcm0 tune SDRAM clock phase
0x10 da_debug write 0x10 any - load debug shift, read (through cs4) -shift
0x20..0x27 da_mcontr0 select reading/writing to mcontr (8 locations)
0x28..0x2f da_compressor0 will be farther decoded in the compressor module
0x2c..0x2d da_table0 write gamma tables address (same as in compressor)
0x30 da_mem0 read/write to SDRAM buffer, autoincrement address

Addresses 0x01,2,3,4,5,6,8 and 0x30 can be kept in the 353 system interface. The interrupt mask address 0x06 in the 333 sys interface is no longer used (353 uses interrupt vectors). The Theora compressor and the new memory controller addresses have to be mapped again in the new design (addresses 0x0c..0x0d and 0x20 to 0x2f in the 353 sys interface).

Interrupts

Adapt the Theora compressor interrupts to the 353 interrupt vector .

The 353 interrupt vector can handle up to 16 different irq. However, only irq 0 to 7 are used :

x353.v

assign irq_in= {8'b0,                    // extra
               compressor_done_compress, // 7 - will go high after all data is sent out (reset by compressor)
               compressor_done_input,    // 6 - will go high after EOT and persist until DCT is enabled (reset by compressor)
               dcc_rdy,                  // 5 - obsolete in 333 - channel3 has 128 more dc coefficients (or some if the compression is finished)
               compressor_eot,           // 4 - compressor read in the last MCU (predictable time to end of transfer)
               sr_sensortrig[2],         // 3 - (sync to pclk) - level, reset by writing to sensor triggering command register
               xfer_over_irq,            // 2 - (sync to pclk) - frame acquisition over
               trig_irq,                 // 1 - (sync to pclk) - external trigger
               vacts};                   // 0 - (sync to pclk) - frame sync

353 MJPEG compressor triggers irqs 4, 6 and 7. 333 Theora compressor is the source of two irqs :

compressor_all.v

done,           // single-cycle pulse when the compressed frame is sent out (IRQ source).
reset_compress, // reset compressor done interrupt (writing any compressor command)

Adaptation should consist of assigning Theora compressor irq sources to vectors 6 and 7 for example if the MJPEG compressor is to be replaced.

DMA FIFOs

353 design uses 2 DMA FIFOs between the compressor and the system interface instead of one for the 333 Theora compressor. The two DMA FIFOs have also slight differences between the two design. Maybe a single 333 FIFO should be kept for the final design (?)

FPGA -> CPU data out MUX

The purpose of this MUX is to route data out from the different FPGA blocks to the system interface and then to the data bus to the CPU. The selection is made with the internal address bus ia.

                                  _
                               --| \
                               --|  |
                               --|  |
                               --|  |--- iod[31:0] -> to system interface
                               --|  |
                               --|  |
                                 |_/
from system interface -> ia[7:0]__|


333 MUX

Adress range ia(5) ia(4) iod[31:0] Comments
0x0.. 0 0 dma_d[31:0] DMA data
0x1.. 0 1 rd_regs[31:0] Data from internal registers
0x2.. 1 0 {8'h0,xfer_bytes[23:0]} Frame length (in bytes)
0x3.. 1 1 bdo[31:0] 32-bit data from SDRAM channel 3


353 MUX

Address ia(6) ia(5) ia(4) ia(2) ia(0) iod[31:0] Comments
0x0.. (even) 0 0 0 X 0 dma_d0[31:0] DMA 0 data
0x0.. (odd) 0 0 0 X 1 dma_d1[31:0] DMA 1 data
0x1.. 0 0 1 X X rd_regs[31:0] Data from internal registers
0x2.. 0 1 0 X X dsdo[31:0] Data out from descriptor memory
0x3.. 0 1 1 X X bdo[31:0] 32-bit data from SDRAM channel3
0x40..0x43 1 0 X 0 X hist_do[31:0] Histogram data out, actully only [17:0]
0x44 1 0 X 1 0 {12'h0,pio_usec[19:0]} usec output from RTC
0x45 1 0 X 1 1 pio_sec[31:0] sec output from RTC
0x6.. 1 1 0 X X 32'h0 0x0000
0x7.. 1 1 1 X X {14'b0,xfpgatdo,xfpgastat,4'b0,io_pins[11:0]} TDO read from an external FPGA / Multiplexed read data from xjtag / Status of 12 i/o pins

Internal registers MUX and status register

333 MUX

Address ia(1) ia(0) rd_regs[31:0] Comments
0x10 0 0 Status register See below
0x11 0 1 {24'b0,irqr[7:0]} Interrupts
0x12 1 0 {5'b0,trig_v[10:0],4'b0,trig_h[11:0]} Trigger phase
0x13 1 1 MODELREV Model revision

353 MUX

Address ia(2) ia(1) ia(0) rd_regs[31:0] Comments
0x10 0 0 0 Status register See below
0x11 0 0 1 irqr[31:0] Interrupts
0x12 0 1 0 {5'b0,trig_v[10:0],4'b0,trig_h[11:0]} Trigger phase
0x13 0 1 1 MODELREV Model revision
0x14 1 X 0 {8'h0,imgptr[23:0]} Image pointer in 32-byte chunks
0x15 1 X 1 hifreq[31:0] Accumulated high-freq components


333 status register

Bit # Signal Comments
0 sr_sda0 I2C to sensor
1 sr_scl0 I2C clock0
2 sr_sda1 I2C
3 sr_scl1 I2C clock1
4..12 rq_busy[8:0] Request or busy - per mcontr channel
13..15 sr_sensortrig[2:0] x00 - idle, x01 - waiting vacts to start, x10 - waiting for trigger, x11 - frame over ,1xx - frame done (reset by writing command to sensor_trig
16 sr_memrdy Ready to r/w next 8x32 page (channel 3) CPU<->SDRAM
17 sr_wrempty CPU write buffer empty (valid only in write mode)
18 1'b0 0x0
19 dma_empty dma output buffer empty and dma is enabled (pessimistic - with delay)
20 itrig TRIG input
21..22 dcm_err[1:0] 00 - no data (SDRAM reads) since last change (wclk*wcmd)

, 01 - clock is too late , 10 - clock is too early , 11 - OK (some measurements show too late, some - too early)

23 dcm_done
24 sr_pipe_rdy Will go active with delay to overlap with DMA busy (external)
25 sr_pipe_nempty Compressor pipe not empty (updated with done -> IRQ)
26 sr_pipe_full Compressor pipe has 3 frame compress commands in the input queue/in progress
27 en_refresh Status bit to find out if SDRAM is programmed
28 tok_frame_num_wr Odd/even frame of tokens written
29 1'b0 0x0
30 debug_out Debug shift register output
31 'b0 0x0

353 status register

Bit # Signal Comments
0 sr_sda0 I2C to sensor
1 sr_scl0 I2C clock
2 sr_ch0rdy Ready to write next page (channel 0) SENSOR->SDRAM
3 sr_ch1rdy Ready to read next page (channel 1) SDRAM->FPN(SENSOR)
4 sr_ch2rdy Ready to read next page (channel 2) SDRAM->DMA
5 sr_memrdy Ready to r/w next 8x32 page (channel 3) CPU<->SDRAM
6 sr_wrempty CPU write buffer empty (valid only in write mode). May reprogram channel3.
7..10 sr_nextFrame[3:0] (level) generated before actual block is filled - needed to be combined with the pulse from buffer control
11..13 sr_sensortrig[2:0] x00 - idle, x01 - waiting vacts to start, x10 - waiting for trigger, x11 - frame over ,1xx - frame done (reset by writing command to sensor_trig
14 dcc_rdy 128 of DC components from JPEG encoder are available (same as interrupt)
15 compressor_done_input will go high after EOT and persist until DCT is enabled
16 compressor_done_compress will go high after all data is sent out
17 dma_empty dma output buffer empty and dma is enabled (pessimistic - with delay)
19..18 dcm_err[1:0] SDRAM DCM phase error
20 dcm_done SDRAM DCM cmd (inc/dec) done
21 dcm_locked SDRAM DCM overflow
22 dcm_status[0] SDRAM DCM overflow
24..23 sens_ph_err[1:0] Sensor DCM phase error
25 sens_dcm_done Sensor DCM cmd (inc/dec/reset) done
26 sens_dcm_locked Sensor DCM overflow
27 sens_dcm_status[0] Sensor DCM overflow
28 clockios_locked dcm locked
29..30 clockios_status[1:0] dcm status (bit 1 - dcm clkin stopped)
31 1'b0 0x0

Control register

The dcr[31:0] bus is used to control the different blocks according to the control register values. The control register can be directly written by the CPU at the address 0x00.


333 control register

bit # destination block Comments
0..2 Not used
3 sensorpads Inverts idclk phase
4 sensorpads fillfactory sensor mode
5 sensorpads delay hact pulse by 1
6 sensorpads cb_zoran
7 sensorpads skip first scan line from the sensor
8 sensortrig external trigger polarity (0: 1->0, 1: 0->1)
9 sensorpads iarst
10 sensorpads iaro
11 iobuf EXPS (output pin)
12 iobuf EXPS (output pin)
13 sensorpads imrst
14 iobuf XRST (output pin)
15 i2cpads scl0 out
16 i2cpads scl0 enable
17 i2cpads sda0 out
18 i2cpads sda0 enable
19 i2cpads scl1 out
20 i2cpads scl1 enable
21 i2cpads sda1 out
22 i2cpads sda1 enable
23 Not used
24..27 clock_pclk pclk source
28..30 Not used
31 clock_pclk clk enable


353 control register

bit # destination block Comments
0 Not used
1..2 compressor, sensorpix, histogram
3 sensorpads Inverts idclk phase
4 sensorpads fillfactory sensor mode
5 sensorpads delay hact pulse by 1
6 sensorpads cb_zoran
7 sensorpads skip first scan line from the sensor
8 sensortrig external trigger polarity (0: 1->0, 1: 0->1)
9 sensorpads iarst
10 sensorpads iaro
11 sensorpads 0 - use 12-bit sensor data, 1 - use converter output pins
12 sensorpads sensor trigger
13 sensorpads imrst
14 iobuf XRST (output pin)
15 i2cpads scl0 out
16 i2cpads scl0 enable
17 i2cpads sda0 out
18 i2cpads sda0 enable
19 sensorpads dclkmode
20 sensorpads use {vact,hact} as 2 LSB in 14-bit data
21..22 sensorpads register hact, vact, bpf N/4 Tpclk later than data
23 Not used
24..25 BUFGMUX pclk source
28..30 compressor
31 clock_pclk

Others

  • Looks like Theora compressor requires 90° phase clock that was abandoned in the 353 design.

Using different phases reduces AC component of the current through the power/ground lines of the FPGA by spreading register transitions. Theora has larger core so it may help spreading phases.--Andrey.filippov 13:45, 25 February 2008 (CST)

  • ...?

Software updates

  • Adapt FPGA definitions (x353.h) and most likely some other FPGA drivers.
  • ...?

These lists of update are obviously incomplete. They need to be more detailed in order to make an exhaustive list of the changes that have to be done.

353 Theora new design

Compressor

Writing tables in compressor (and mcontr8ch) is the same than the 333 design :

  • ia = 0x2d and idi = table address (X313_WA_COMP_TA=0x2d)

then

  • ia = 0x2c and idi = table data (X313_WA_COMP_TD=0x2c)

Example : Writing zerobin and quantization tables in 353 Theora design

Writetabs.jpg

Sensorpix

Most of the 353 design was used for the new design. Writing procedure for gamma tables in sensorpix block is the same than in 353 (ie with ta bus and twr_gamma signal).

  • ia = 0x0e and idi = table address

then

  • ia = 0x0f and idi = table data

Table address is not autoincremented within the sensorpix block but is fed externally with the ta bus.

Gammatab.jpg

Memory controller

Channel Description
0 8/16 bit data from sensor to SDRAM
1 16 bit data from SDRAM to FPN correction module
2 20x20 tiles of raw data from SDRAM to the color space converter and compressor
3 PIO read/write of SDRAM data
4 Writing current (restored) frame as YCbCr 4:2:0 data to SDRAM
5 Reading previous frame as YCbCr 4:2:0 data from SDRAM
6 Writing 12-bit pre-tokens to SDRAM (in macroblock-scan order, starting with AC[63]
7 Reading 12-bit pre-tokens from SDRAM in indexed coded order

System interface

Address da signal Comments
0x00 da_ctl WE to control 32-bit register (1 loc)
0x01 da_dmamode select writing to dma_cntr/dma_raw (1 loc)
0x02 da_sensormode select writing to sensorpix (1 loc)
0x03 da_virttrig write virtual trigger threshold
0x04 da_sensortrig select writing to sensorpix (1 loc)
0x05 da_sensortrig_lines write number of lines to be transferred in a frame (or after trigger)
0x07 da_sens_dc write to sensor DCDC converter frequency divider
0x08 da_dcm tune SDRAM clock phase
0x0a da_framesync_dly write frame sync interrupt delay (in scan lines)
0x0e da_table_a0 write gamma table address
0x0f twr0 write gamma table data
0x10 Status register
0x1b dcmrst async signal to restart DCMs (if irnw=0)
0x1c..0x1f da_interrupts interrupt control
0x20..0x27 da_mcontr select reading/writing to mcontr (8 locations)
0x28..0x2f da_compressor will be farther decoded in the compressor module
0x2c..0x2d da_table write gamma tables address (same as in compressor)
0x30 da_mem read/write to SDRAM buffer, autoincrement address
0x40..0x43 da_hist write/read histogram related data/registers
0x44..0x47 da_rtc real time clock
0x48 da_timestamp write timestamp mode
0x74 da_xjta0 write to external (sensor board) JTAG
0x78..0x7b da_extsync control of external sync module 0x78 - 0x7b

Interrupts

irq_in Signal Comments
15..8 GND Extra
7 compressor_done_compress single-cycle pulse when the compressed frame is sent out
6 compressor_reset_compress reset compressor done interrupt (writing any compressor command)
5 GND dcc_rdy was tied to GND in the 333 design
4 GND eot irq was tied to GND in the 333 design
3 sr_sensortrig[2] (sync to pclk) - level, reset by writing to sensor triggering command register
2 xfer_over_irq (sync to pclk) - frame acquisition over
1 trig_irq (sync to pclk) - external trigger
0 vacts (sync to pclk) - frame sync

DMA FIFOs

A single DMA FIFO from the 333 design will be instanciated.

FPGA -> CPU data out MUX

Address ia(6) ia(5) ia(4) ia(2) ia(0) iod[31:0] Comments
0x0.. 0 0 0 x 0 dma_d[31:0] DMA data
0x1.. 0 0 1 x x rd_regs[31:0] Data from internal registers
0x2.. 0 1 0 x x {8'h0,xfer_bytes[23:0]} Frame length (in bytes)
0x3.. 0 0 1 x x bdo[31:0] 32-bit data from SDRAM channel 3
0x40..0x43 1 0 x 0 x hist_do[31:0] Histogram data out, actully only [17:0]
0x44 1 0 x 1 0 {12'h0,pio_usec[19:0]} usec output from RTC
0x45 1 0 x 1 1 pio_sec[31:0] sec output from RTC
0x6.. 1 1 0 x x 32'h0 0x0000
0x7.. 1 1 1 x x {14'b0,xfpgatdo,xfpgastat,4'b0,io_pins[11:0]} TDO read from an external FPGA / Multiplexed read data from xjtag / Status of 12 i/o pins

Internal registers MUX and status register

Address ia(1) ia(0) rd_regs[31:0] Comments
0x10 0 0 Status register See below
0x11 0 1 irqr[31:0] Interrupts
0x12 1 0 {5'b0,trig_v[10:0],4'b0,trig_h[11:0]} Trigger phase
0x13 1 1 MODELREV Model revision

Status register

Bit # Signal Comments
0 sr_sda0 I2C data
1 sr_scl0 I2C clock
2..10 rq_busy[8:0] Request or busy - per mcontr channel
11 sr_memrdy Ready to r/w next 8x32 page (channel 3) CPU<->SDRAM
12 sr_wrempty CPU write buffer empty (valid only in write mode)
13..15 sr_sensortrig[2:0] x00 - idle, x01 - waiting vacts to start, x10 - waiting for trigger, x11 - frame over ,1xx - frame done (reset by writing command to sensor_trig
16 dma_empty dma output buffer empty and dma is enabled (pessimistic - with delay)
17..18 dcm_err[1:0] 00 - no data (SDRAM reads) since last change (wclk*wcmd)

, 01 - clock is too late , 10 - clock is too early , 11 - OK (some measurements show too late, some - too early)

19 dcm_done SDRAM DCM cmd (inc/dec) done
20 dcm_locked SDRAM DCM overflow
21..22 sens_ph_err[1:0] Sensor DCM phase error
23 sens_dcm_done Sensor DCM cmd (inc/dec/reset) done
24 sens_dcm_locked Sensor DCM overflow
25 clockios_locked dcm locked
26 clockios_status[1] dcm status (bit 1 - dcm clkin stopped)
27 sr_pipe_rdy Will go active with delay to overlap with DMA busy (external)
28 sr_pipe_nempty Compressor pipe not empty (updated with done -> IRQ)
29 sr_pipe_full Compressor pipe has 3 frame compress commands in the input queue/in progress
30 en_refresh Status bit to find out if SDRAM is programmed
31 took_frame_num_wr Odd/even frame of tokens written

Control register

bit # Signal Destination block Comments
0 Not used
1..2 cb_bayer_phase compressor, sensorpix, histogram
3 sensorpads Inverts idclk phase (Not used)
4 cb_fillfactory sensorpads fillfactory sensor mode
5 cb_dlyhact sensorpads delay hact pulse by 1
6 cb_zoran sensorpads cb_zoran
7 cb_skipline sensorpads skip first scan line from the sensor
8 cb_xt_pol sensortrig external trigger polarity (0: 1->0, 1: 0->1)
9 iarst sensorpads iarst
10 iaro sensorpads iaro
11 cb_encnvclk sensorpads 0 - use 12-bit sensor data, 1 - use converter output pins
12 cb_sensor_trigger sensorpads sensor trigger
13 imrst sensorpads imrst
14 cb_scl0_o iobuf XRST (output pin)
15 cb_scl0_o i2cpads scl0 out
16 cb_scl0_en i2cpads scl0 enable
17 cb_sda0_o i2cpads sda0 out
18 cb_sda0_en i2cpads sda0 enable
19 cb_dclkmode sensorpads dclkmode
20 cb_pxd14 sensorpads use {vact,hact} as 2 LSB in 14-bit data
21..22 cb_latehact sensorpads register hact, vact, bpf N/4 Tpclk later than data
23 Not used
24..25 cb_pclksrc BUFGMUX pclk source
28..30 Not used
31 Not used

Others

See also