4. PSDK QNX Components

4.1. QNX BSP release

The QNX BSP package must be downloaded from QNX Software Center.

Note

Refer Release Notes software dependencies section for more information.

For the purposes of creating a consolidated build process and in turn allowing for support of scripts to create SD content, the BSP needs to be extracted to the folder within the PSDK QNX build environment as show below.

For QNX SDP 7.0:

# Unzip the BSP
mkdir -p ${PSDK_RTOS_PATH}/psdkqa/qnx/bsp
cd ${PSDK_RTOS_PATH}/psdkqa/qnx/bsp
unzip ${QNX_BASE}/bsp/BSP_ti-j721e-am752x-evm_br-700_be-700_<version>.zip

For QNX SDP 7.1:

# Unzip the BSP
mkdir -p ${PSDK_RTOS_PATH}/psdkqa/qnx/bsp
cd ${PSDK_RTOS_PATH}/psdkqa/qnx/bsp
unzip ${QNX_BASE}/bsp/BSP_ti-j721e-am752x-evm_br-mainline_be-710_<version>.zip

4.1.1. TI Modifications to the BSP

Memory Carveout

Memory sections with pre-defined physical addresses must be set aside in the QNX BSP IFS build file so that the memory is not given to other programs and can be used solely by the remote cores

Specify a section to be set aside by modifying the startup line to use the “-r” option. For example, to reserve 0x5C000000 bytes, at physical address 0xA0000000, on J7 QNX BSP, the build file the arguments would be (highlighted below):

+keeplinked] startup-j721e-evm -v -r0xA0000000,0x5C000000,1

R5 Display support

For R5 Display support, the Startup need to be provided with -d option to specify not to configure the DSS and eDP.

[+keeplinked] startup-j721e-evm -v -r0xA0000000,0x5C000000,1 -d

Reference TI build file

The reference TI build file is provide in the qnx/scripts/bsp directory.

# Copy in TI specific build scripts and settings to allow building of a QNX-IFS which supports
# vision_apps demos
cp ${PSDK_RTOS_PATH}/psdkqa/qnx/scripts/bsp/j721e-evm-ti.build ${PSDK_RTOS_PATH}/psdkqa/qnx/bsp/images/

4.2. QNX Screen release

The QNX Screen package must be downloaded from QNX Software Center.

The QNX Screen package must be installed and running for GPU support.

The QNX Screen package can optionally control the DSS (Display) from the A72, the PSDK QNX package default is R5 control of the DSS.

Note

Refer Release Notes software dependencies section for more information.

4.2.1. Enabling R5 Control Of DSS

By default the PSDK QNX delivery will default to eDP display, controlled from the R5. The items that must be addressed for the system to run with R5 Controlled Display, and are set by default are:

  • The libWFDdummy.so must be used by the QNX graphics.conf file Reference ${PSDK_QNX_PATH}/qnx/scripts/user__dss_on_r5.sh.
  • The QNX BSP startup command line option in the QNX BSP build file, must have the “-d” option specified
  • ENABLE_DSS flag must be defined, please reference Vision Apps User Guide, see section on “Build Instructions”:
Vision Apps User Guide
  - Build And Run
      - Build Instructions

4.2.2. Enabling A72 Control of DSS

To disable the R5 control of the display, and enable A72 control of the display, the items that must be addressed are:

  • The libWFDdummy.so must be used by the QNX graphics.conf file. Reference ${PSDK_QNX_PATH}/qnx/scripts/user__dss_on_a72.sh
  • The QNX BSP startup command line option in the QNX BSP build file must not have the “-d” option specified
  • The ENABLE_DSS flag must be undefined, please reference Vision Apps User Guide, see section on “Build Instructions”:
Vision Apps User Guide
  - Build And Run
 . - Build Instructions

4.3. QNX USB and Networking Packages

The QNX USB and Networking packages must be downloaded from QNX Software Center.

Note

Refer Release Notes software dependencies section for more information.

4.4. SCI Client Resource Manager

The SCI Client Resource Manager (tisci-mgr) provides support for multiple users to make use of the sciclient library from PSDRKA without interfering with each other requests. It provides a mechanism to serialize the transactions to the DMSC.

Note

The tisci-mgr logs the SYSFW information to the slogger.

Note

Refer PSDK RTOS Components for more information about each individual component.

4.5. IPC Resource Manager

4.5.1. Overview

The IPC resource manager (tiipc-mgr) provides a processor-agnostic API which can be used for communication between processors in a multi-processor environment.

The IPC resource manager provides a user library (tiipc-usr) that exposes the IPC LLD API to QNX applications for communication through the IPC resource manager. The IPC LLD API is described in detail in the PDK documentation.

4.5.2. Example Application

An IPC example application (ipc_test) is provided with the release as well. To use this application, the appropriate remote core binaries need to be built and placed on the target filesystem. The following remote core applications are needed:

Firmware Name Core(s)
ex02_bios_multicore_echo_testb use for mcu1_0
ex02_bios_multicore_echo_test use for all other cores

For remote core firmware build instructions, please refer to the IPC LLD PDK documentation.

Once the remote core firmware is built, copy the images to the target filesystem in the rootfs partition. Existing firmware binaries should be backed up as required. The ex02* firmware binaries should be renamed to the firmware name expected by the bootloader. For example:

cp ex02_bios_multicore_echo_test_c7x_1_release.xe71 ${ROOTFS}/lib/firmware/j7-c71_0-fw
cp ex02_bios_multicore_echo_test_c66xdsp_1_release.xe66 ${ROOTFS}/lib/firmware/j7-c66_1-fw
cp ex02_bios_multicore_echo_test_c66xdsp_2_release.xe66 ${ROOTFS}/lib/firmware/j7-c66_0-fw
cp ex02_bios_multicore_echo_test_mcu3_1_release.xer5f ${ROOTFS}/lib/firmware/j7-main-r5f1_1-fw
cp ex02_bios_multicore_echo_test_mcu3_0_release.xer5f ${ROOTFS}/lib/firmware/j7-main-r5f1_0-fw
cp ex02_bios_multicore_echo_test_mcu2_1_release.xer5f ${ROOTFS}/lib/firmware/j7-main-r5f0_1-fw
cp ex02_bios_multicore_echo_test_mcu2_0_release.xer5f ${ROOTFS}/lib/firmware/j7-main-r5f0_0-fw
cp ex02_bios_multicore_echo_test_mcu1_1_release.xer5f ${ROOTFS}/lib/firmware/j7-mcu-r5f0_1-fw
cp ex02_bios_multicore_echo_testb_mcu1_0_release.xer5f ${ROOTFS}/lib/firmware/j7-mcu-r5f0_0-fw

After copying the firmware and booting the target, the ipc_test can be run from the command line (example output given below):

J7EVM@QNX:/# /sd/tibin/ipc_test
Running Ipc_echo_test
IPC_echo_test (core : mpu1_0) ....
IPC init done
This example application will not exit
SendTask9: mpu1_0 <--> C7X_1, Ping- 10, pong - 10 completed
SendTask8: mpu1_0 <--> C66X_2, Ping- 10, pong - 10 completed
SendTask7: mpu1_0 <--> C66X_1, Ping- 10, pong - 10 completed
...

Make sure that the tiipc-mgr is running before executing the ipc_test. Note that the test app will not exit.

Note

Refer PSDK RTOS Components for more information about each individual component.

4.6. UDMA Resource Manager

The UDMA resource manager (tiudma-mgr) provides support for multiple users to make use of the UDMA functionlity without interfering with each other requests.

Note

Refer PSDK RTOS Components for more information about each individual component.

4.7. Shared Memory Allocator

The Shared Memory Allocator resource manager (shmemallocator) provides support for multiple users to allocate memory from the shared memory region. This shared memory region is carvedout of the QNX memory as part of the QNX Startup parameters.

4.8. CPSW2G DEVNP driver

4.8.1. Overview

The CPSW2G DEVNP network driver can be viewed as the “glue” between the underlying cpsw2g lowlevel driver, and the software infrastructure of io-pkt, the protocol stack above it. The “bottom half” of the driver is coded specifically to interact with the PDK’s cpsw & udma low-level drivers, and the “top half” of the driver is coded specifically for io-pkt.

Note

The J721E CPSW2G DEVNP network driver has support for SMMU. Refer FAQ & App Notes for more information on how to enable this feature.

Note

Refer PSDK RTOS Components for more information about each individual component.

4.8.2. Running

Boot the board with the SDcard. At the QNX prompt, run below, to mount the SD card and then launch the executable:

tisci-mgr
tiudma-mgr
io-pkt-v6-hc -d cpsw2g verbose=0xff
dhclient -nw am0

The cpsw2g driver configures all the driver created threads to have the runmask as 0x1. This is to make sure all the threads run on Core 0 of A72. Hence it is optional to specify the command prefix “on -C 0” when starting the io-pkt-v6-hc with the cpsw2g driver.

For debug traces, run the below command before starting the DEVNP driver and start the driver with increased verbose parameter (ex: verbose=0x3ff) this will show all the drivers slog messages

slog2info –c
slog2info -w &

4.8.3. Additonal steps

  • Run “if_up -p am0” to check if the interface is ready
  • Run “ifconfig am0 up” to bring UP the link.
  • Run “dhclient -nw am0” for DHCP server provide the IP address
  • Run “ifconfig -v” to check the assigned IP address and status
  • Run “tcpdump -e” to look at the tcp traffic

4.8.4. Starting driver with other options

We can run the below command to get the usage of the DEVNP driver

use devnp-cpsw2g.so

To run the cpsw2g devnp driver with PHY:

io-pkt-v6-hc –d cpsw2g verbose=0x0

To run the cpsw2g devnp driver in mac-to-mac mode with 1Gbps:

io-pkt-v6-hc –d cpsw2g verbose=0x0,mac-to-mac=1,speed=1000

To run the cpsw2g devnp driver in mac-to-mac mode with 1Gbps with gPTP:

io-pkt-v6-hc –d cpsw2g verbose=0x0,ptp=1,mac-to-mac=1,speed=1000

To get a dynamic IP address for the cpsw2g port:

dhclient -nw am0

To get a static Ip address for the cpsw2g port:

ifconfig am0 up
ifconfig am0 <static_ip_address>

4.9. CPSW9G DEVNP driver

4.9.1. Overview

The CPSW9G DEVNP network driver implemented as “virtual” driver that communicates with the Ethernet Firware Switch firmware running on the R5 core. The control message transfer is done via IPC. The RX and TX data packets are passed to the CPSW9G port using the UDMA.

CPSW9G Firmware on MCU2_0 implemented TimeSync Module utilizing CPTS timer for PTP support to sync with Master clock on the network. TimeSync module configured PTP stack with the following default properties.

  • Ordinary Clock
  • IEEE 802.3 Transport
  • Peer Delay Mechanism (P2P)

For TimeSync Module design, please refer to EthFW documentation for details. CPSW9G DEVNP driver has included an option to return CPTS timer timestamp via devctl() with PTP_GET_TIME command. Please refer to the example, ptp_test, to see how to use PTP_GET_TIME command to get CPTS timer timestamp from cpsw9g devnp driver.

Note

Refer PSDK RTOS Components for more information about EthFW component.

4.9.2. Running

Boot the board with the SDcard. At the QNX prompt, run below, to mount the SD card and then launch the executable:

tisci-mgr
tiipc-mgr
tiudma-mgr
io-pkt-v6-hc -d cpsw9g verbose=0xff
dhclient -nw an0

The cpsw9g driver configures all the driver created threads to have the runmask as 0x1. This is to make sure all the threads run on Core 0 of A72. Hence it is optional to specify the command prefix “on -C 0” when starting the io-pkt-v6-hc with the cpsw9g driver.

For debug traces, run the below command before starting the DEVNP driver and start the driver with increased verbose parameter (ex: verbose=0x3ff) this will show all the drivers slog messages

slog2info –c
slog2info -w &

4.9.3. Additonal steps

  • Run “if_up -p an0” to check if the interface is ready
  • Run “ifconfig an0 up” to bring UP the link.
  • Run “dhclient -nw an0” for DHCP server provide the IP address
  • Run “ifconfig -v” to check the assigned IP address and status
  • Run “tcpdump -e” to look at the tcp traffic

4.9.4. Starting driver with other options

We can run the below command to get the usage of the DEVNP driver

use devnp-cpsw9g.so

To run the cpsw9g devnp driver with gPTP:

io-pkt-v6-hc –d cpsw9g ptp=1

4.10. K3conf QNX utility

K3CONF is a QNX port of the Linux user-space based standalone application designed to provide a quick’n easy way to dynamically diagnose Texas Instruments’ K3 architecture based processors. K3CONF is intended to provide similar experience to that of OMAPCONF that runs on legacy TI platforms.

Note

WARNING: This is work in progress! Please don’t expect things to be complete in any dimension. Use at your own risk. And keep the reset button in reach.

To get more details on how to use k3conf utility, run below:

k3conf --help