Zynq UltraScale+ MPSoC VCU TRD 2018.3 - 10G HDMI Video Capture and HDMI Display

Zynq UltraScale+ MPSoC VCU TRD 2018.3 - 10G HDMI Video Capture and HDMI 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. 10G will give sufficient bandwidth for the streaming protocol to play video pipeline smoothly.

This design supports the following video interfaces:

Sources:

  • HDMI-Rx capture pipeline implemented in the PL.
  • File source (SD card, USB storage, SATA hard disk).
  • Stream-In from network or internet.

Sinks:

  • HDMI-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:

  • 10G Ethernet on PL 
  • 1G Ethernet on PS


10G Deliverables:

Pipeline

Input source

Output Type

Resolution

Video encode/Decoder type

Deliverables

Record/Stream-Out pipeline

HDMI-Rx

File Sink/ Stream-Out

4K/1080p

HEVC/AVC

HDMI Rx Video encodes with VCU and stores it in a container format.

Playback pipeline

File Source/ Stream-In

HDMI –Tx

4K/1080p

HEVC/AVC

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

Capture--> Display

HDMI-Rx

HDMI -Tx

4K/1080p

HEVC/AVC

HDMI Rx Video passes to HDMI-Tx without VCU.

Capture--> Encode--> Decode--> Display

HDMI-Rx

HDMI -Tx

4K/1080p

HEVC/AVC

HDMI Rx raw video passes through  VCU elements encoder and decoder and finally displays on HDMI-Tx.


Supported Resolution:

The table below provides the supported resolution in this design.

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


√ - Supported
NA – Not applicable
x – Not supported


The below figure shows the TRD block diagram.

The below sections describe the 10G HDMI Video Capture and HDMI Display design. It is VCU TRD design supporting 10G HDMI-Rx and HDMI-Tx. For the overview, software tools, system requirements and design files follow the link below:

The below figure shows the 10G HDMI Video Capture and HDMI Display design hardware block diagram.

The below figure shows the 10G HDMI Video Capture and HDMI 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 are placed in the following directory structure. The user needs to copy all the files from the $TRD_HOME/images/vcu_10g/ to FAT32 formatted SD card directory.


TRD package contents specific to 10G HDMI Video Capture and HDMI Display design are placed in the following directory structure.


configuration files(input.cfg) for various Resolutions are placed in the following directory structure in /media/card.

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:


Example:

4kp60 HEVC_HIGH Display Pipeline execution

4kp60 HEVC_HIGH Record Pipeline execution

4kp60 HEVC_HIGH Stream-out Pipeline execution

4kp60 HEVC_HIGH Stream-in Pipeline execution

NOTE: Make sure HDMI-Rx should be configured to 4kp60 mode.

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

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

2.3 Optimum VCU Encoder parameters for use-cases:

Video streaming:

  • Video streaming use-case requires very stable bitrate graph for all pictures.
  • It is good to avoid periodic large Intra pictures during the encoding session
  • Low-latency rate control (hardware RC) is the preferred control-rate for video streaming, it tries to maintain equal amount frame sizes for all pictures.
  • Good to avoid periodic Intra frames instead use low-delay-p (IPPPPP…)
  • VBR is not a preferred mode of streaming.

Performance: AVC Encoder settings:

  • It is preferred to use 8 or higher slices for better AVC encoder performance.
  • AVC standard does not support Tile mode processing which results in processing of MB rows sequentially for entropy coding.

Quality: Low bitrate AVC encoding:

  • Enable profile=high and use qp-mode=auto for low-bitrate encoding use-cases.
  • The high profile enables 8x8 transform which results in better video quality at low bitrates.



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: HDMI or DP

Out Type:
Options: display, record, and stream

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: HDMI, 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.
NOTE: For 10G HDMI Options: file:///media/usb/abc.ts (for file path), udp://192.168.26.89:5004/ (for Network streaming, Here 192.168.26.89 is 10G IP address and 5004 is port no) 
            For 1G HDMI Options: file:///media/usb/abc.ts (for file path), udp://192.168.25.89:5004/ (for Network streaming, Here 192.168.25.89 is 1G 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.

Encoder Configuration:
It is the starting point of encoder configuration.

Encoder Num:
Starting Nth encoder configuration.
Options: 1

Encoder Name:
Name of the encoder.
Options: AVC, HEVC

Profile:
Name of the profile.
Options: baseline, main or high for AVC. Main for HEVC.

Rate Control:
Rate control options.
Options: CBR, VBR, and low-latency.

Filler Data:
Filler Data NAL units for CBR rate control.
Options: True, False

QP:
QP control mode used by the VCU encoder.
Options: Uniform, Auto

L2 Cache:
Enable or Disable L2Cache buffer in encoding process.
Options: True, False

Latency Mode:
Encoder latency mode.
Options: normal, sub_frame

Low Bandwidth:
If enabled, decrease the vertical search range used for P-frame motion estimation to reduce the bandwidth.
Options: True, False

Gop Mode:
Group of Pictures mode.
Options: Basic, low_delay_p, low_delay_b

Bitrate:
Target bitrate in Kbps
Options: 1-60000

B Frames:
Number of B-frames between two consecutive P-frames
Options: 0-4

Slice:
The number of slices produced for each frame. Each slice contains one or more complete macroblock/CTU row(s). Slices are distributed over the frame as regularly as possible. If slice-size is defined as well more slices may be produced to fit the slice-size requirement.
Options:
4-22 4kp resolution with HEVC codec
4-32 4kp resolution with AVC codec
4-32 1080p resolution with HEVC codec
4-32 1080p resolution with AVC codec

GoP Length:
The distance between two consecutive I frames
Options: 1-1000

Format:
The format of input data.
Options: NV12

Preset:
Options: HEVC_HIGH, HEVC_MEDIUM, HEVC_LOW, AVC_HIGH, AVC_MEDIUM, AVC_LOW, Custom

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

Record Configuration:
It is the starting point of record configuration.

Record Num:
Starting Nth record configuration.
Options: 1

Out-File Name:
Record file path.
Options: /media/usb/abc.ts

Duration:
Duration in minutes.
Options: 1-3

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

Streaming Configuration:
It is the starting point of streaming configuration.

Streaming Num:
Starting Nth Streaming configuration.
Options: 1.

Host IP:
The host to send the packets to
Note: For 10G- Options: 192.168.26.89 or Windows PC IP 
Note: For 1G- Options: 192.168.25.89 or Windows PC IP 


Port:
The port to send the packets to
Options: 5004,5008,5012 and 5016.

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

  • To check the link status, resolution and video node of HDMI input source, run below xmedia-ctl command.

When HDMI source is connected to 4KP60 resolution, it shows:

NOTE: Check resolution and frame-rate of "dv.detect" under "v_hdmi_rx_ss" node.

When HDMI source is not connected, it shows:

NOTE: Here "dv.query:no-link" under "v_hdmi_rx_ss" node shows HDMI-Rx source is not connected or HDMI-Rx source is not active(Try waking up the device by pressing key on remote).

  • Follow below steps to switch the HDMI-Rx resolution from 1080p60 to 4kp60.
    • Check current HDMI Input Source Resolution (1080p60) by following the above-mentioned steps.
    • Run vcu_gst_app for current HDMI resolution (1080p60) by executing the following command.

Below configurations needs to be set in input.cfg for HDMI-1080p60.

    • Change Resolution of HDMI Input Source from 1080p60 to 4kp60 by following below steps.
      • Set the HDMI source resolution to 4kp60 (Home page → settings → display & Sound → Resolution → change to 4kp60).
      • Save the configuration to take place the change.
    • Verify the desired HDMI Input Source Resolution (4kp60) by following the above-mentioned steps.
  • If HDMI Tx link-up issue is observed after Linux booting, use the following command:
  • Run the following gst-launch-1.0 command to display raw HDMI video using GStreamer pipeline.
  • Run the following gst-launch-1.0 command to display processed(capture → encode → decode → display) HDMI video using GStreamer pipeline.
  • Run the following gst-launch-1.0 command to record HDMI video using GStreamer pipeline.

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

  • Run the following gst-launch-1.0 command to play the recorded file using the GStreamer pipeline.

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

  • Run the following gst-launch-1.0 command to stream-out HDMI video using Gstreamer pipeline.

NOTE: Here 192.168.25.89 is host/client IP address and 5004 is port no.

  • Run the following gst-launch-1.0 command to display stream-in video using Gstreamer pipeline where 5004 is port no.

Notes for gst-launch-1.0 commands:

  • Make sure HDMI-Rx media pipeline is configured for 4kp60 resolution and source/sink have the same colour format. Run below xmedia-ctl commands to set resolution and format of HDMI scaler node.

When HDMI Input Source is NVIDIA SHIELD

NOTE: Make sure NVIDIA SHIELD is configured for 4kp resolution and RGB888 color format.

When HDMI Input Source is ABOX

NOTE: Make sure ABOX is configured for 4kp resolution and VYYUYY8 colour format.