Zynq UltraScale+ MPSoC VCU TRD 2018.3 - SDI Video Display

Zynq UltraScale+ MPSoC VCU TRD 2018.3 - SDI Video Display


Table of Contents

1 Overview

  • The primary goal of this Design is to demonstrate the capabilities of VCU hard block present in Zynq UltraScale+ EV devices. The TRD will serve as a platform to tune the performance parameters of VCU and arrive at optimal configurations for encoder and decoder blocks with the streaming use case where bandwidth plays a vital role. 

    This design supports the following video interfaces:

    Sources:

    • File source (SD card, USB storage, SATA hard disk).
    • Stream-In from network or internet.

    Sinks:

    • SDI-Tx display pipeline implemented in the PL.

    VCU Codec:

    • Video Encode/Decode capability using VCU hard block in PL 
      • AVC/HEVC encoding.
      • Encoder/decoder parameter configuration.

    Streaming Interfaces:

    • 1G Ethernet on PS

    Supported Features:

    The table below provides the supported encoder feature in this release.

    Resolution
    Command Line
    Single StreamMulti-stream
    4kp60NA
    4kp30NA
    1080p60NA


    √ - Supported
    NA – Not applicable
    x – Not supported


    Deliverables:

    Pipeline

    Input source

    Output Type

    Resolution

    Video encode/Decoder type

    Deliverables

    Playback pipeline

    File Source/ Stream-In

    SDI-Tx

    4K/1080p

    HEVC/AVC

    Playback of the local-file/stream-in with video decoded using VCU and display on  SDI-Tx.

The below figure shows the SDI Video Display design hardware block diagram.


The below figure shows the SDI Video Display design software block diagram.


1.1 Board Setup

Refer below link for Board Setup


1.2 Run Flow

The TRD package is released with the source code, Vivado project, Petalinux BSP, and SD card image that enables the user to run the demonstration. It also includes the binaries necessary to configure and boot the ZCU106 board. Prior to running the steps mentioned in this wiki page, download the TRD package and extract its contents to a directory referred to as ‘TRD_HOME' which is the home directory.

Refer below link to download all TRD contents.


TRD package contents specific to SDI Video Display design are placed in the following directory structure. The user needs to copy all the files from the $TRD_HOME/images/vcu_sditx/ to FAT32 formatted SD card directory.


└── rdf0428-zcu106-vcu-trd-2018-3
    ├── apu
    │   ├── apps
    │   └── vcu_petalinux_bsp
    ├── documentation
    ├── images
    │   ├── vcu_sditx
    │   │   ├── autostart.sh
    │   │   ├── bin
    │   │   ├── BOOT.BIN
    │   │   ├── config
    │   │   ├── image.ub
    │   │   ├── system.dtb
    │   │   └── vcu
    ├── pl
    │   ├── constrs
    │   ├── pre-built
    │   │   ├── vcu_sditx
    │   ├── Readme.txt
    │   ├── scripts
    │   │   └── vcu_sditx.tcl
    │   └── srcs
    └── README.txt

Configuration files(input.cfg) are placed in the following directory structure in /media/card.

config/
├── Display
├── Stream
└── input.cfg

1.2.1 GStreamer Application (vcu_gst_app)

The vcu_gst_app is a command line multi-threaded Linux application. The command line application requires an input configuration file (input.cfg) to be provided in the plain text.

Execution of the application is shown below:

% vcu_gst_app < path to *.cfg file>


Example:

Display Pipeline execution

% vcu_gst_app /media/card/config/Display/input.cfg

Stream-in Pipeline execution

% vcu_gst_app /media/card/config/Stream/input.cfg

To measure the latency of the pipeline, run the below command. The latency data is huge, so dump it to a file.

% GST_DEBUG="GST_TRACER:7" GST_TRACERS="latency;scheduletime" ./vcu_gst_app ./input.cfg >& dump_log.txt

Refer below link for detailed run flow steps


1.3 Build Flow

Refer below link for Build Flow



2 Other Information

2.1 Known Issues

2.2 Limitations



3 Appendix A - Input Configuration File (input.cfg)


The example configuration files are stored at /media/card/config/ folder.

Common Configuration:
It is the starting point of common configuration.

Num of Input:
Provide the number of input. this is always 1 for this design.

Output:
Select the video interface.
Options: SDI or DP

Out Type:
Options: Display

Display Rate:
Pipeline frame rate.
Options: 30 FPS or 60 FPS for each stream.

Exit:
It indicates to the application that the configuration is over.

Input Configuration:
It is the starting point of input configuration.

Input Num:
Starting Nth input configuration.
Options: 1

Input Type:
Input source type.
Options: File, Stream

Uri:
File path or Network URL. Applicable for file playback and stream-in pipeline only. Supported file formats for playback are ts, mp4 and mkv.
Options: file:///media/usb/abc.ts (for file path), udp://192.168.26.89:5004/ (for Network streaming, Here 192.168.26.89 is IP address and 5004 is port no)

Raw:
To tell pipeline is processed or pass-through.
Options: True, False

Width:
The width of the live source.
Options: 3840, 1920

Height:
The height of the live source.
Options: 2160, 1080

Exit:
It indicates to the application that the configuration is over.

Trace Configuration:
It is the starting point of trace configuration.

FPS Info:
To display fps info on the console.
Options: True, False

APM Info:
To display APM counter number on the console.
Options: True, False

Pipeline Info:
To display pipeline info on console.
Options: True, False

Exit
It indicates to the application that the configuration is over.


4 Appendix B

  • Run the following gst-launch-1.0 command for file playback using Gstreamer pipeline.
$ gst-launch-1.0 uridecodebin uri="file:///media/usb/test.ts" ! queue max-size-bytes=0 ! kmssink bus-id="a0070000.v_mix"

NOTE: File location should be USB-3.0 to avoid the read-write bandwidth issue.

  • Run the following gst-launch-1.0 command to display stream-in video using Gstreamer pipeline where 5004 is port no.
$ gst-launch-1.0 udpsrc port=5004 buffer-size=60000000 caps="application/x-rtp, clock-rate=90000" ! rtpjitterbuffer latency=1000 ! rtpmp2tdepay ! tsparse ! video/mpegts ! tsdemux name=demux ! queue ! h265parse ! omxh265dec internal-entropy-buffers=5 latency-mode=normal ! queue max-size-bytes=0 ! kmssink bus-id="a0070000.v_mix"

Notes for modetest commands:

  • Modetest command for  4kp60
$ modetest -M xlnx -s 36:3840x2160-60@YUYV  -w 36:sdi_mode:5 -w 36:sdi_data_stream:8 -w 36:is_frac:0 &
  • Modetest command for 1080p60
$ modetest -M xlnx -s 36:1920x1080-60@YUYV  -w 36:sdi_mode:3 -w 36:sdi_data_stream:8 -w 36:is_frac:0 &

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