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Sometime need standalone compile device tree. Only Linux headers and device tree directory are needed.         
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This article is rather short that only mentions the script that is needed to make an iMX93EVK act as a USB mass storage device so that whenever you connect your iMX device to a windows/linux system via USB, it should get enumerated something like a usb drive.  The storage that is used in this example is mmc so the expectation is that you have inserted a mmc card in the slot. Below is the script:- #!/bin/sh   # This composite gadget include function: # - MASS STORAGE     # # Exit status is 0 for PASS, nonzero for FAIL # STATUS=0   # Check if there is udc available, if not, return fail UDC_DIR=/sys/class/udc if test "$(ls -A "$UDC_DIR")"; then echo "The available udc:" for entry in "$UDC_DIR"/* do echo "$entry" done else STATUS=1 echo "No udc available!" exit $STATUS; fi   id=1; udc_name=ci_hdrc.0 #back_file=/dev/mmcblk1 back_file=/tmp/lun0.img   mkdir /sys/kernel/config/usb_gadget/g$id cd /sys/kernel/config/usb_gadget/g$id   # Use NXP VID, i.MX8QXP PID echo 0x1fc9 > idVendor echo 0x12cf > idProduct   mkdir strings/0x409 echo 123456ABCDEF > strings/0x409/serialnumber echo NXP > strings/0x409/manufacturer echo "NXP iMX USB Composite Gadget" > strings/0x409/product   mkdir configs/c.1 mkdir configs/c.1/strings/0x409   echo 5 > configs/c.1/MaxPower echo 0xc0 > configs/c.1/bmAttributes   mkdir functions/mass_storage.1 echo $back_file > functions/mass_storage.1/lun.0/file ln -s functions/mass_storage.1 configs/c.1/   echo $udc_name > UDC First execute the script. After that insert the g_mass_storage module in the kernel by executing :- modprobe g_mass_storage file=/dev/mmcblk1 removable=1 In the dmesg output, you will see something like below:-   After that you can connect a C type USB cable to the USB1 port of imx93evk and the other end to any USB ports of a laptop. The moment it is connected, you would be able to see a USB drive similar to what you get when we connect a pen-drive. 
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Design Check Lists: HW Design Checking List for i.MX6DQSDL HW Design Checking List for i.Mx53 Hardware Design Checklist for i.MX28 HW_Design_Checking_List_for_i.MX6SoloX i.MX6UL Hardware design checklist   DDR Design Tool: I.MX53 DDR3 Script Aid imx53 DDR stress tester V0.042 i.Mx6DQSDL DDR3 Script Aid MX6DQP DDR3 Script Aid i.Mx6DQSDL LPDDR2 Script Aid i.Mx6SL LPDDR2 Script Aid i.MX6SX DDR3 Script Aid I.MX6UL DDR3 Script Aid i.MX6UL_LPDDR2_Script_Aid i.MX6ULL_DDR3_Script_Aid  i.MX6ULL_LPDDR2_Script_Aid  MX6SLL_LPDDR2_Script_Aid  MX6SLL_LPDDR3_Script_Aid  i.MX6 DDR Stress Test Tool V1.0.3 i.MX6/7 DDR Stress Test Tool V3.00 i.MX8MSCALE DDR Tool Release  i.MX8M DDR3L register programming aid  i.MX 8/8X Family DDR Tools Release   Application Notes: MX_Design_Validation_Guide I.MX6 series USB Certification Guides
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Important: If you have any questions or would like to report any issues with the DDR tools or supporting documents please create a support ticket in the i.MX community. Please note that any private messages or direct emails are not monitored and will not receive a response.   These are the detailed programming aids for the registers associated with MMDC DDR3 and LPDDR2 initialization for the MX6DQ SoC. The last sheet formats the register settings for use with ARM RealView ICE. It can also be used with the windows executable for the DDR Stress Test. This programming aid was used for internal NXP boards.  
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    Xenomai is real-time framework, which can run seamlessly side-by-side Linux as a co-kernel system, or natively over mainline Linux kernels (with or without PREEMPT-RT patch). The dual kernel nicknamed Cobalt, is a significant rework of the Xenomai 2.x system. Cobalt implements the RTDM specification for interfacing with real-time device drivers. The native linux version, an enhanced implementation of the experimental Xenomai/SOLO work, is called Mercury. In this environment, only a standalone implementation of the RTDM specification in a kernel module is required, for interfacing the RTDM-compliant device drivers with the native kernel. You can get more detailed information from Home · Wiki · xenomai / xenomai · GitLab       I have ported xenomai 3.1 to i.MX Yocto 4.19.35-1.1.0, and currently support ARMv7 and tested on imx6ulevk/imx6ull14x14evk/imx6qpsabresd/imx6dlsabresd/imx6sxsabresdimx6slevk boards. I also did stress test by tool stress-ng on some boards.      You need to git clone https://gitee.com/zxd2021-imx/xenomai-arm.git, and git checkout Linux-4.19.35-1.1.0. (which inlcudes all patches and bb file) and add the following variable in conf/local.conf before build xenomai by command bitake xenomai.  XENOMAI_KERNEL_MODE = "cobalt"  PREFERRED_VERSION_linux-imx = "4.19-${XENOMAI_KERNEL_MODE}" IMAGE_INSTALL_append += " xenomai" DISTRO_FEATURES_remove = "optee" or XENOMAI_KERNEL_MODE = "mercury" PREFERRED_VERSION_linux-imx = "4.19-${XENOMAI_KERNEL_MODE}" IMAGE_INSTALL_append += " xenomai" DISTRO_FEATURES_remove = "optee" If XENOMAI_KERNEL_MODE = "cobalt", you can build dual kernel version. And If XENOMAI_KERNEL_MODE = "mercury", it is single kernel with PREEMPT-RT patch. The following is test result by the command (/usr/xenomai/demo/cyclictest -p 50 -t 5 -m -n -i 1000 😞 //Mecury on 6ULL with stress-ng --cpu 4 --io 2 --vm 1 --vm-bytes 128M --metrics-brief policy: fifo: loadavg: 6.08 2.17 0.81 8/101 534 T: 0 (  530) P:99 I:1000 C:  74474 Min:     23 Act:  235 Avg:   77 Max:    8278 T: 1 (  531) P:99 I:1500 C:  49482 Min:     24 Act:   32 Avg:   56 Max:    8277 T: 2 (  532) P:99 I:2000 C:  36805 Min:     24 Act:   38 Avg:   79 Max:    8170 T: 3 (  533) P:99 I:2500 C:  29333 Min:     25 Act:   41 Avg:   54 Max:    7069 T: 4 (  534) P:99 I:3000 C:  24344 Min:     24 Act:   51 Avg:   60 Max:    7193   //Cobalt on 6ULL with stress-ng --cpu 4 --io 2 --vm 1 --vm-bytes 128M --metrics-brief policy: fifo: loadavg: 7.02 6.50 4.01 8/100 660 T: 0 (  652) P:50 I:1000 C: 560348 Min:      1 Act:   10 Avg:   15 Max:      71 T: 1 (  653) P:50 I:1500 C: 373556 Min:      1 Act:    9 Avg:   17 Max:      78 T: 2 (  654) P:50 I:2000 C: 280157 Min:      2 Act:   14 Avg:   20 Max:      64 T: 3 (  655) P:50 I:2500 C: 224120 Min:      1 Act:   12 Avg:   15 Max:      57 T: 4 (  656) P:50 I:3000 C: 186765 Min:      1 Act:   31 Avg:   19 Max:      53   //Cobalt on 6qp with stress-ng --cpu 4 --io 2 --vm 1 --vm-bytes 512M --metrics-brief policy: fifo: loadavg: 8.11 7.44 4.45 8/156 1057 T: 0 (  917) P:50 I:1000 C: 686106 Min:      0 Act:    3 Avg:    5 Max:      53 T: 1 (  918) P:50 I:1500 C: 457395 Min:      0 Act:    3 Avg:    5 Max:      49 T: 2 (  919) P:50 I:2000 C: 342866 Min:      0 Act:    2 Avg:    4 Max:      43 T: 3 (  920) P:50 I:2500 C: 274425 Min:      0 Act:    3 Avg:    5 Max:      58 T: 4 (  921) P:50 I:3000 C: 228682 Min:      0 Act:    2 Avg:    6 Max:      46   //Cobalt on 6dl with stress-ng --cpu 2 --io 2 --vm 1 --vm-bytes 256M --metrics-brief policy: fifo: loadavg: 3.35 4.15 2.47 1/122 850 T: 0 (  729) P:50 I:1000 C: 608088 Min:      0 Act:    1 Avg:    3 Max:      34 T: 1 (  730) P:50 I:1500 C: 405389 Min:      0 Act:    0 Avg:    4 Max:      38 T: 2 (  731) P:50 I:2000 C: 304039 Min:      0 Act:    1 Avg:    4 Max:      45 T: 3 (  732) P:50 I:2500 C: 243225 Min:      0 Act:    0 Avg:    4 Max:      49 T: 4 (  733) P:50 I:3000 C: 202683 Min:      0 Act:    0 Avg:    5 Max:      38   //Cobalt on 6SX stress-ng --cpu 4 --io 2 --vm 1 --vm-bytes 512M  --metrics-brief policy: fifo: loadavg: 7.51 7.19 6.66 8/123 670 T: 0 (  598) P:50 I:1000 C:2314339 Min:      0 Act:    3 Avg:    8 Max:      60 T: 1 (  599) P:50 I:1500 C:1542873 Min:      0 Act:   15 Avg:    8 Max:      72 T: 2 (  600) P:50 I:2000 C:1157152 Min:      0 Act:    4 Avg:    9 Max:      55 T: 3 (  601) P:50 I:2500 C: 925721 Min:      0 Act:    5 Avg:    9 Max:      57 T: 4 (  602) P:50 I:3000 C: 771434 Min:      0 Act:    6 Avg:    6 Max:      41   //Cobalt on 6Solo lite stress-ng --cpu 4 --io 2 --vm 1 --vm-bytes 512M  --metrics-brief policy: fifo: loadavg: 7.01 7.04 6.93 8/104 598 T: 0 (  571) P:50 I:1000 C:3639967 Min:      0 Act:    9 Avg:    7 Max:      60 T: 1 (  572) P:50 I:1500 C:2426642 Min:      0 Act:    9 Avg:   11 Max:      66 T: 2 (  573) P:50 I:2000 C:1819980 Min:      0 Act:   11 Avg:   10 Max:      57 T: 3 (  574) P:50 I:2500 C:1455983 Min:      0 Act:   12 Avg:   10 Max:      56 T: 4 (  575) P:50 I:3000 C:1213316 Min:      0 Act:    7 Avg:    9 Max:      43   //Cobalt on 7d with stress-ng --cpu 2 --io 2 --vm 1 --vm-bytes 256M --metrics-brief policy: fifo: loadavg: 5.03 5.11 5.15 6/107 683 T: 0 (  626) P:50 I:1000 C:6842938 Min:      0 Act:    1 Avg:    2 Max:      63 T: 1 (  627) P:50 I:1500 C:4561953 Min:      0 Act:    4 Avg:    2 Max:      66 T: 2 (  628) P:50 I:2000 C:3421461 Min:      0 Act:    0 Avg:    2 Max:      69 T: 3 (  629) P:50 I:2500 C:2737166 Min:      0 Act:    3 Avg:    2 Max:      71 T: 4 (  630) P:50 I:3000 C:2280969 Min:      0 Act:    2 Avg:    1 Max:      33   //////////////////////////////////////// Update for Yocto L5.10.52 2.1.0  /////////////////////////////////////////////////////////// New release for Yocto release L5.10.52 2.1.0. You need to git clone https://gitee.com/zxd2021-imx/xenomai-arm and git checkout xenomai-5.10.52-2.1.0. Updating: 1, Upgrade Xenomai to v3.2 2, Enable Dovetail instead of ipipe. Copy xenomai-arm to <Yocto folder>/sources/meta-imx/meta-bsp/recipes-kernel, and add the following variable in conf/local.conf before build Image with xenomai enable by command bitake imx-image-multimedia. XENOMAI_KERNEL_MODE = "cobalt" IMAGE_INSTALL_append += " xenomai" or XENOMAI_KERNEL_MODE = "mercury" IMAGE_INSTALL_append += " xenomai" Notice: If XENOMAI_KERNEL_MODE = "cobalt", you can build dual kernel version. And If XENOMAI_KERNEL_MODE = "mercury", it is single kernel with PREEMPT-RT patch. //////////////////////////////////////// Update for Yocto L5.15.71 2.2.0  /////////////////////////////////////////////////////////// New release for Yocto release L5.15.71 2.2.0. You need to git clone https://gitee.com/zxd2021-imx/xenomai-arm and git checkout xenomai-5.15.71-2.2.0. Updating: 1, Upgrade Xenomai to v3.2.2 Copy xenomai-arm to <Yocto folder>/sources/meta-imx/meta-bsp/recipes-kernel, and add the following variable in conf/local.conf before build Image with xenomai enable by command bitake imx-image-multimedia. XENOMAI_KERNEL_MODE = "cobalt" IMAGE_INSTALL:append += " xenomai" or XENOMAI_KERNEL_MODE = "mercury" IMAGE_INSTALL:append += " xenomai" Notice: If XENOMAI_KERNEL_MODE = "cobalt", you can build dual kernel version. And If XENOMAI_KERNEL_MODE = "mercury", it is single kernel with PREEMPT-RT patch.   ///////// Later update for Later Yocto release, please refer to the following community post //////////// 移植实时Linux方案Xenomai到i.MX ARM64平台 (Enable real-time Linux Xenomai on i.MX ARM64 Platform)   
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Symptoms   Trying to initialize a repo, for example:  $repo init -u https://github.com/nxp-imx/imx-manifest -b imx-linux-mickledore -m imx-6.1.36-2.1.0.xml we have the below log: File "/home/username/bin/repo", line 51 def print(self, *args, **kwargs): ^ SyntaxError: invalid syntax   Workaround (1)   The first workaround consist in change the python alternatives (caused when you have installed two or more python versions). NOTE: in my case, the python version that i want to change as first priority is python3.8 $sudo update-alternatives --install /usr/bin/python python /usr/bin/python3.8 1   Then we run: $sudo update-alternatives --config python    To verify if your python priority was changed successfully try: $python --version   You should see the version configured as priority number 1.     Workaround (2)   The workaround is very simple, only we need modify the repo file $ nano ~/bin/repo   and we will change the python interpreter in the first line (from python to python3): ORIGINAL FILE   EDITED FILE   After to do this change, repo will works fine again.     I hope this can helps to you!   Best regards.
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Hello there. Here is a good way to use U-boot in an efficient way with custom scripts. The bootscript is an script that is automatically executed when the boot loader starts, and before the OS auto boot process. The bootscript allows the user to execute a set of predefined U-Boot commands automatically before proceeding with normal OS boot. This is especially useful for production environments and targets which don’t have an available serial port for showing the U-Boot monitor. This information can be find in U-Boot Reference Manual.   I will take the example load a binary file in CORTEX M4 of IMX8MM-EVK. In my case, I have the binary file in MMC 2:1 called gpio.bin and I will skip those steps because that is not the goal.   First, you need the u-boot-tools installed in your Linux machine: sudo apt install u-boot-tools   That package provide to us the tool mkimage to convert a text file (.src, .txt) file to a bootscript file for U-Boot.   Now, create your custom script, in this case a simple script for load binary file in Cortex M4: nano mycustomscript.scr  and write your U-Boot commands: fatload mmc 2:1 0x80000000 gpio.bin cp.b 0x80000000 0x7e0000 0x10000 bootaux 0x7e0000   Now we can convert the text file to bootscript with mkimage. Syntax: mkimage -T script -n "Bootscript" -C none -d <input_file> <output_file> mkimage -T script -n "Bootscript" -C none -d mycustomscript.scr LCM4-bootscript   This will create a file called LCM4-bootscript (Or as your called it).   A way to load this bootscript file to U-Boot is using the UUU tool, in U-Boot set the device in fastboot with command: u-boot=> fastboot 0 Then in linux with the board connected through USB to PC run the command: sudo uuu -b fat_write LCM4-bootscript mmc 2:1 LCM4-bootscript   Now we have our bootscript in U-Boot in MMC 2:1.   Finally, we can run the bootscript in U-Boot: u-boot=> load mmc 2:1 ${loadaddr} LCM4-bootscript 158 bytes read in 2 ms (77.1 KiB/s) u-boot=> source ${loadaddr} ## Executing script at 40400000 6656 bytes read in 5 ms (1.3 MiB/s) ## No elf image at address 0x007e0000 ## Starting auxiliary core stack = 0x20020000, pc = 0x1FFE02CD...   And the Cortex M4 booted successfully:    I hope this can helps to you.   Best regards.   Salas.  
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What is a device tree? The device tree is a data structure that is passed to the Linux kernel to describe the physical devices in a system. Before device trees came into use, the bootloader (for example, U-Boot) had to tell the kernel what machine type it was booting. Moreover, it had to pass other information such as memory size and location, kernel command line, etc. Sometimes, the device tree is confused with the Linux Kernel configuration, but the device tree specifies what devices are available and how they are accessed, not whether the hardware is used. The device tree is a structure composed of nodes and properties: Nodes: The node name is a label used to identify the node. Properties: A node may contain multiple properties arranged with a name and a value. Phandle: Property in one node that contains a pointer to another node. Aliases: The aliases node is an index of other nodes. A device tree is defined in a human-readable device tree syntax text file such as .dts or .dtsi. The machine has one or several .dts files that correspond to different hardware configurations. With these .dts files we can compile them into a device tree binary (.dtb) blobs that can either be attached to the kernel binary (for legacy compatibility) or, as is more commonly done, passed to the kernel by a bootloader like U-Boot. What is Devshell? The Devshell is a terminal shell that runs in the same context as the BitBake task engine. It is possible to run Devshell directly or it may spawn automatically. The advantage of this tool is that is automatically included when you configure and build a platform project so, you can start using it by installing the packages and following the setup of i.MX Yocto Project User's Guide on section 3 “Host Setup”. Steps: Now, let’s see how to compile your device tree files of i.MX devices using Devshell. On host machine. Modify or make your device tree on the next path: - 64 bits. ~/imx-yocto-bsp/<build directory>/tmp/work-shared/<machine>/kernel-source/arch/arm64/boot/dts/freescale - 32 bits. ~/imx-yocto-bsp/<build directory>/tmp/work-shared/<machine>/kernel-source/arch/arm/boot/dts To compile, it is needed to prepare the environment as is mentioned on i.MX Yocto Project User's Guide on section 5.1 “Build Configurations”. $ cd ~/imx-yocto-bsp $ DISTRO=fsl-imx-xwayland MACHINE=<machine> source imx-setup-release.sh -b <build directory> $ bitbake -c devshell virtual/kernel (it will open a new window) On Devshell window. $ make dtbs (after finished, close the Devshell window) On host machine. $ bitbake -c compile -f virtual/kernel $ bitbake -c deploy -f virtual/kernel This process will compile all the device tree files linked to the machine declared on setup environment and your device tree files will be deployed on the next path: ~/imx-yocto-bsp/<build directory>/tmp/deploy/images/<machine> I hope this article will be helpful. Best regards. Jorge.
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In some cases, such as mass production or preparing a demo. We need u-boot environment stored in demo sdcard mirror image.  Here is a way: HW:  i.MX8MP evk SW:  LF_v5.15.52-2.1.0_images_IMX8MPEVK.zip The idea is to use fw_setenv to set the sdcard mirror as the operation on a real emmc/sdcard. Add test=ABCD in u-boot-initial-env for test purpose. And use fw_printenv to check and use hexdump to double confirm it. The uboot env is already written into sdcard mirror(imx-image-multimedia-imx8mpevk.wic). All those operations are on the host x86/x64 PC. ./fw_setenv -c fw_env.config -f u-boot-initial-env Environment WRONG, copy 0 Cannot read environment, using default ./fw_printenv -c fw_env.config Environment OK, copy 0 jh_root_dtb=imx8mp-evk-root.dtb loadbootscript=fatload mmc ${mmcdev}:${mmcpart} ${loadaddr} ${bsp_script}; mmc_boot=if mmc dev ${devnum}; then devtype=mmc; run scan_dev_for_boot_part; fi arch=arm baudrate=115200 ...... ...... ...... splashimage=0x50000000 test=ABCD usb_boot=usb start; if usb dev ${devnum}; then devtype=usb; run scan_dev_for_boot_part; fi vendor=freescale hexdump -s 0x400000 -n 2000 -C imx-image-multimedia-imx8mpevk.wic 00400000 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 |................| hexdump -s 0x400000 -n 10000 -C imx-image-multimedia-imx8mpevk.wic 00400000 5f a4 9b 97 20 6a 68 5f 72 6f 6f 74 5f 64 74 62 |_... jh_root_dtb| 00400010 3d 69 6d 78 38 6d 70 2d 65 76 6b 2d 72 6f 6f 74 |=imx8mp-evk-root| 00400020 2e 64 74 62 00 20 6c 6f 61 64 62 6f 6f 74 73 63 |.dtb. loadbootsc| 00400030 72 69 70 74 3d 66 61 74 6c 6f 61 64 20 6d 6d 63 |ript=fatload mmc| 00400040 20 24 7b 6d 6d 63 64 65 76 7d 3a 24 7b 6d 6d 63 | ${mmcdev}:${mmc| 00400050 70 61 72 74 7d 20 24 7b 6c 6f 61 64 61 64 64 72 |part} ${loadaddr| 00400060 7d 20 24 7b 62 73 70 5f 73 63 72 69 70 74 7d 3b |} ${bsp_script};| 00400070 00 20 6d 6d 63 5f 62 6f 6f 74 3d 69 66 20 6d 6d |. mmc_boot=if mm| ...... ...... ...... 00401390 76 3d 31 00 73 6f 63 3d 69 6d 78 38 6d 00 73 70 |v=1.soc=imx8m.sp| 004013a0 6c 61 73 68 69 6d 61 67 65 3d 30 78 35 30 30 30 |lashimage=0x5000| 004013b0 30 30 30 30 00 74 65 73 74 3d 41 42 43 44 00 75 |0000.test=ABCD.u| 004013c0 73 62 5f 62 6f 6f 74 3d 75 73 62 20 73 74 61 72 |sb_boot=usb star| 004013d0 74 3b 20 69 66 20 75 73 62 20 64 65 76 20 24 7b |t; if usb dev ${| 004013e0 64 65 76 6e 75 6d 7d 3b 20 74 68 65 6e 20 64 65 |devnum}; then de| flash the sdcard mirror into i.MX8MP evk board emmc to check uuu -b emmc_all imx-boot-imx8mp-lpddr4-evk-sd.bin-flash_evk imx-image-multimedia-imx8mpevk.wic  The first time boot, the enviroment is already there.  How to achieve that: a. fw_setenv/fw_printenv: https://github.com/sbabic/libubootenv.git Note: Please do not use uboot fw_setenv/fw_printenv Compile it on the host x86/x64 PC. It is used on host. b. u-boot-initial-env Under uboot, make u-boot-initial-env Note: Yocto deploys u-boot-initial-env by default c. fw_env.config  imx-image-multimedia-imx8mpevk.wic 0x400000 0x4000 0x400000 0x4000 are from uboot-imx\configs\imx8mp_evk_defconfig CONFIG_ENV_SIZE=0x4000 CONFIG_ENV_OFFSET=0x400000 Now, you can run  ./fw_setenv -c fw_env.config -f u-boot-initial-env
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Issue description: ZQ calibration issue with LPDDR2 memory with two chip selects    Micron has verified it on my customer's board with i.MX6Q. (ECT-SYT-1163 for FIC.pdf) The patch is made based on lp 5.1, see attachment.
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Hello everyone, We have recently migrated our Source code from CAF (Codeaurora) to Github, so i.MX NXP old recipes/manifest that point to Codeaurora eventually will be modified so it points correctly to Github to avoid any issues while fetching using Yocto. Also, all repo init commands for old releases should be changed from: $ repo init -u https://source.codeaurora.org/external/imx/imx-manifest -b <branch name> [ -m <release manifest>] To: $ repo init -u https://github.com/nxp-imx/imx-manifest -b <branch name> [ -m <release manifest>] This will also apply to all source code that was stored in Codeaurora, the new repository for all i.MX NXP source code is: https://github.com/nxp-imx For any issues regarding this, please create a community thread and/or a support ticket. Regards, Aldo.
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    OpenSSL is popular software library for applications that secure communications over computer networks against eavesdropping or need to identify the party at the other end. It is widely used in internet web servers, serving a majority of all web sites. OpenSSL contains an open-source implementation of the Transport Layer Security (TLS) and Secure Sockets Layer (SSL) protocols, it is a robust, commercial-grade, and full-featured toolkit for the SSL and TLS protocols. OpenSSL is also a general-purpose cryptography library. Its core library, written in the C programming language, implements basic cryptographic functions and provides various utility functions. Wrappers allowing the use of the OpenSSL library in a variety of computer languages are available. More and more embeded systems, like IoT gateway, ePOS, based on i.MX use OpenSSL for their secure communications and cryptographic operations. But it's cryptography library is pure software implementation which need to occupy lots of CPU resouce and the perfermance is very weak than dedicated hardware IP (like CAAM).    CAAM is the i.MX's cryptographic acceleration and assurance module, which serves as NXP's latest cryptographic acceleration and offloading hardware. It combines functions previously implemented in separate modules to create a modular and scalable acceleration and assurance engine. It also implements block encryption algorithms, stream cipher algorithms, hashing algorithms, public key algorithms (i.MX6UL/i.MX7D/S), and a hardware random number generator.   The official Yocto release (L4.1.15_2.0.0-ga) of the i.MX only enable cryptodev for accelerating symmetric algorithms and hashing algorithms, not support asymmetric algorithms(RSA, ECC). And its engine in OpenSSL(version 1.0.2h) also miss some features which is used to support symmetric algorithms and hashing algorithms, for example, AES ECB, SHA224/256, etc. These patches in the post will close the above gaps for i.MX Linux system. The software environments as the belows: Linux kernel: imx_4.1.15_2.0.0_ga cryptodev: 1.8 OpenSSL: 1.0.2h The patches include the following key features: 1, Add public key cryptography part in CAAM driver, through protocol commands, to implement a number of public (and private) key functions. These are DSA and ECDSA sign/verify, Diffie-Hellman (DH) and ECDH key agreement, ECC key generation, DLC key generation, RSA encryption/decryption, RSA key-generation finalization. 2, Add big number operation and elliptic curve math in CAAM driver to implement addition, subtraction, multiplication, exponentiation, reduction, inversion, greatest common divisor, prime testing and point add, point double, point multiply. 3, Add API in cryptodev to support RSA encryption/decryption, DSA/ECDSA sign/verify, DH/ECDH key agreement, ECC & DLC & RSA key generation and big number operation and elliptic curve math. 4, Add public key cryptography functions, hardware rng, and missing hash symmetric algorithms in OpenSSL crytodev engine. Note: 1, You can refer to ecdhtest.c, ecdsatest.c, dhtest.c, dsatest.c, rsa_test.c for how to use crytodev engine in your applications based on libcryto.so. You can also find their executable programs in folder openssl-1.0.2h/test after compiling. 2, If you want to call crytodev API directly to accelerate public key cryptography operations, please refer to asymmetric_cipher.c in cryptodev-linux-1.8/tests. Current Limitation: 1, CAAM driver don't support AES GCM/CCM but hardware supporting. I plan to add the feature next version. 2, ECDSA sign/verify will fail on some binary curves (sect163r1, sect163r2, sect193r1, sect193r2, sect233r1, sect283r1, sect409r1, sect571r1 and X9.62 binary curves). I will try to find the root cause and fix it.   ==================================== for  some binary curves (sect163r1, sect163r2, sect193r1, sect193r2, sect233r1, sect283r1, sect409r1, sect571r1 and X9.62 binary curves)  are rarely used, so i will try to find the root cause when i'm free.  +++++++++++++++++++++++    updating for Linux-4.14.78-1.1.10 ++++++++++++++++++++++++++++ This updating is for Yocto release of Linux -4.14.78-1.1.10. The new software environments as the belows: Linux kernel: imx_4.14.78_1.1.10 cryptodev: 1.9 OpenSSL: 1.0.2p HW platform: i.MX6UL, i.MX7D/S, i.MX8M/8M Mini, i.MX8/8X. The patches include the following new features: 1, support  RSA key generation but defaultly use openssl build-in function (BN_generate_prime_ex) to create prime p, q for higher security. If need to use CAAM accelerating,  please comment Macro USE_BUILTIN_PRIME_GENERATION, but don't confirm its security. 2, Add Manufacturing-protection feature, and you can refer to manufacturing_protection_test function in asymmetric_cipher.c. 3, Support AES GCM in cryptodev. 4, git clone https://gitee.com/zxd2021-imx/meta-openssl-caam.git, git checkout Linux-4.14.78-1.1.10 and copy meta-openssl-caam to folder <Yocto 4.14.78-1.1.10 dir>/sources/ 5, Run DISTRO=fsl-imx-wayland MACHINE=imx6ulevk source fsl-setup-release.sh -b build-imx6ulevk and add BBLAYERS += " ${BSPDIR}/sources/meta-openssl-caam " into /build-imx6ulevk/conf/bblayers.conf 6, bitbake fsl-image-validation-imx 7, Run the below command on your i.MX6UL EVK board. modprobe cryptodev openssl genrsa -f4 -engine cryptodev 512 -elapsed openssl speed dsa -engine cryptodev -elapsed openssl genrsa -f4 -engine cryptodev 1024 -elapsed openssl speed rsa -engine cryptodev -elapsed openssl genrsa -f4 -engine cryptodev 2048 -elapsed openssl speed ecdsa -engine cryptodev -elapsed openssl genrsa -f4 -engine cryptodev 3072 -elapsed openssl speed ecdh -engine cryptodev -elapsed openssl genrsa -f4 -engine cryptodev 4096 -elapsed openssl speed -evp sha256 -engine cryptodev -elapsed openssl speed -evp aes-128-cbc -engine cryptodev -elapsed openssl speed -evp aes-128-ecb -engine cryptodev -elapsed openssl speed -evp aes-128-cfb -engine cryptodev -elapsed openssl speed -evp aes-128-ofb -engine cryptodev -elapsed openssl speed -evp des-ede3 -engine cryptodev -elapsed openssl speed -evp des-cbc -engine cryptodev -elapsed openssl speed -evp des-ede3-cfb -engine cryptodev -elapsed +++++++++++++++++++++++    updating for Linux-4.14.98-2.3.3 ++++++++++++++++++++++++++++ This updating is for Yocto release of Linux -4.14.98-2.3.3. The new software environments as the belows: Linux kernel: imx_4.14.98-2.3.3 cryptodev: 1.9 OpenSSL: 1.0.2p HW platform: i.MX6UL, i.MX7D/S, i.MX8M/8M Mini/8M Nano, i.MX8/8X. The patches include the following new features: 1, git clone https://gitee.com/zxd2021-imx/meta-openssl-caam.git, git checkout Linux-4.14.98-2.3.3 and copy meta-openssl-caam to folder <Yocto 4.14.98-2.3.3 dir>/sources/ 2, Run DISTRO=fsl-imx-wayland MACHINE=imx8mmevk source fsl-setup-release.sh -b build-imx8mmevk and add BBLAYERS += " ${BSPDIR}/sources/meta-openssl-caam " into /build-imx8mmevk/conf/bblayers.conf 3, bitbake fsl-image-validation-imx 4, Run the below command on your i.MX8M Mini EVK board. modprobe cryptodev openssl genrsa -f4 -engine cryptodev 512 -elapsed openssl speed dsa -engine cryptodev -elapsed openssl genrsa -f4 -engine cryptodev 1024 -elapsed openssl speed rsa -engine cryptodev -elapsed openssl genrsa -f4 -engine cryptodev 2048 -elapsed openssl speed ecdsa -engine cryptodev -elapsed openssl genrsa -f4 -engine cryptodev 3072 -elapsed openssl speed ecdh -engine cryptodev -elapsed openssl genrsa -f4 -engine cryptodev 4096 -elapsed openssl speed -evp sha256 -engine cryptodev -elapsed openssl speed -evp aes-128-cbc -engine cryptodev -elapsed openssl speed -evp aes-128-ecb -engine cryptodev -elapsed openssl speed -evp aes-128-cfb -engine cryptodev -elapsed openssl speed -evp aes-128-ofb -engine cryptodev -elapsed openssl speed -evp des-ede3 -engine cryptodev -elapsed openssl speed -evp des-cbc -engine cryptodev -elapsed openssl speed -evp des-ede3-cfb -engine cryptodev -elapsed +++++++++++++++++++++++    updating for Linux-4.19.35-1.1.2 ++++++++++++++++++++++++++++ This updating is for Yocto release of Linux 4.19.35-1.1.2​​.  Software environments as the belows: Linux kernel: imx_4.19.35-1.1.2 cryptodev: 1.10 OpenSSL: 1.1.1l HW platform: i.MX6UL, i.MX7D/S, i.MX8M/8M Mini/8M Nano, i.MX8/8X. How to build: 1, git clone https://gitee.com/zxd2021-imx/meta-openssl-caam.git, git checkout Linux-4.19.35-1.1.2 and copy meta-openssl-caam to folder <Yocto 4.19.35-1.1.2 dir>/sources/ 2, Run DISTRO=fsl-imx-wayland MACHINE=imx8mmevk source imx-setup-release.sh -b build-imx8mmevk and add BBLAYERS += " ${BSPDIR}/sources/meta-openssl-caam " into <Yocto 4.19.35-1.1.2 dir>/build-imx8mmevk/conf/bblayers.conf. 3, Run bitbake fsl-image-validation-imx. 4, Run the below command on your i.MX8M Mini EVK board. modprobe cryptodev openssl speed dsa openssl speed rsa openssl speed ecdsa openssl speed ecdh openssl genrsa -f4 -engine devcrypto 512 openssl genrsa -f4 -engine devcrypto 1024 openssl genrsa -f4 -engine devcrypto 2048 openssl genrsa -f4 -engine devcrypto 3072 openssl genrsa -f4 -engine devcrypto 4096 openssl speed -evp sha256 -engine devcrypto -elapsed openssl speed -evp aes-128-cbc -engine devcrypto -elapsed openssl speed -evp aes-128-ecb -engine devcrypto -elapsed openssl speed -evp aes-128-cfb -engine devcrypto -elapsed openssl speed -evp aes-128-ofb -engine devcrypto -elapsed openssl speed -evp des-ede3 -engine devcrypto -elapsed openssl speed -evp des-cbc -engine devcrypto -elapsed openssl speed -evp des-ede3-cfb -engine devcrypto -elapsed +++++++++++++++++++++++    updating for Linux-5.4.70-2.3.4 ++++++++++++++++++++++++++++ This updating is for Yocto release of Linux 5.4.70_2.3.4​​.  Software environments as the belows: Linux kernel: imx_5.4.70_2.3.4 cryptodev: 1.10 OpenSSL: 1.1.1l HW platform: i.MX6UL, i.MX7D/S, i.MX8M/8M Mini/8M Nano/8M Plus, i.MX8/8X. How to build: 1, git clone https://gitee.com/zxd2021-imx/meta-openssl-caam.git, git checkout Linux-5.4.70-2.3.4  and copy meta-openssl-caam to folder <Yocto 5.4.70_2.3.4 dir>/sources/ 2, Run DISTRO=fsl-imx-wayland MACHINE=imx8mmevk source imx-setup-release.sh -b build-imx8mmevk and add BBLAYERS += " ${BSPDIR}/sources/meta-openssl-caam " into <Yocto 5.4.70_2.3.4 dir>/build-imx8mmevk/conf/bblayers.conf. 3, Run bitbake imx-image-multimedia. 4, Run the below command on your i.MX8M Mini EVK board. modprobe cryptodev openssl speed dsa openssl speed rsa openssl speed ecdsa openssl speed ecdh openssl genrsa -f4 -engine devcrypto 512 openssl genrsa -f4 -engine devcrypto 1024 openssl genrsa -f4 -engine devcrypto 2048 openssl genrsa -f4 -engine devcrypto 3072 openssl genrsa -f4 -engine devcrypto 4096 openssl speed -evp sha256 -engine devcrypto -elapsed openssl speed -evp aes-128-cbc -engine devcrypto -elapsed openssl speed -evp aes-128-ecb -engine devcrypto -elapsed openssl speed -evp aes-128-cfb -engine devcrypto -elapsed openssl speed -evp aes-128-ofb -engine devcrypto -elapsed openssl speed -evp des-ede3 -engine devcrypto -elapsed openssl speed -evp des-cbc -engine devcrypto -elapsed openssl speed -evp des-ede3-cfb -engine devcrypto -elapsed     +++++++++++++++++++++++    updating for Linux-5.10.52-2.1.0 ++++++++++++++++++++++++++++ This updating is for Yocto release of Linux 5.10.52_2.1.0​​.  Software environments as the belows: Linux kernel: lf-5.10.y cryptodev: 1.12 OpenSSL: 1.1.1l HW platform: i.MX6UL, i.MX7D/S, i.MX8M/8M Mini/8M Nano/8M Plus, i.MX8/8X. How to build: 1, git clone https://gitee.com/zxd2021-imx/meta-openssl-caam.git, git checkout Linux-5.10.52-2.1.0 and copy meta-openssl-caam to folder <Yocto 5.10.52_2.1.0 dir>/sources/ 2, Run DISTRO=fsl-imx-xwayland MACHINE=imx8mmevk source imx-setup-release.sh -b build-imx8mmevk and add BBLAYERS += " ${BSPDIR}/sources/meta-openssl-caam " into <Yocto 5.10.52_2.1.0 dir>/build-imx8mmevk/conf/bblayers.conf. 3, Run bitbake imx-image-multimedia. 4, Run the below command on your i.MX8M Mini EVK board. modprobe cryptodev openssl speed dsa openssl speed rsa openssl speed ecdsa openssl speed ecdh openssl genrsa -f4 -engine devcrypto 512 openssl genrsa -f4 -engine devcrypto 1024 openssl genrsa -f4 -engine devcrypto 2048 openssl genrsa -f4 -engine devcrypto 3072 openssl genrsa -f4 -engine devcrypto 4096 openssl speed -evp sha256 -engine devcrypto -elapsed openssl speed -evp aes-128-cbc -engine devcrypto -elapsed openssl speed -evp aes-128-ecb -engine devcrypto -elapsed openssl speed -evp aes-128-cfb -engine devcrypto -elapsed openssl speed -evp aes-128-ofb -engine devcrypto -elapsed openssl speed -evp des-ede3 -engine devcrypto -elapsed openssl speed -evp des-cbc -engine devcrypto -elapsed openssl speed -evp des-ede3-cfb -engine devcrypto -elapsed   +++++++++++++++++++++++    updating for Linux-5.15.71-2.2.0 ++++++++++++++++++++++++++++ This updating is for Yocto release of Linux 5.15.71-2.2.0​​.  Software environments as the belows: Linux kernel: lf-5.15.71-2.2.0 cryptodev: 1.12 OpenSSL: 3.1.0 HW platform: i.MX6UL, i.MX7D/S, i.MX8M/8M Mini/8M Nano/8M Plus, i.MX8/8X. How to build: 1, git clone https://gitee.com/zxd2021-imx/meta-openssl-caam.git, git checkout Linux-5.15.71-2.2.0 and copy meta-openssl-caam to folder <Yocto 5.15.71_2.2.0 dir>/sources/ 2, Run DISTRO=fsl-imx-xwayland MACHINE=imx8mmevk source imx-setup-release.sh -b build-imx8mmevk and add BBLAYERS += " ${BSPDIR}/sources/meta-openssl-caam " into <Yocto 5.15.71_2.2.0 dir>/build-imx8mmevk/conf/bblayers.conf. 3, Run bitbake imx-image-multimedia. 4, Run the below command on your i.MX8M Mini EVK board. modprobe cryptodev openssl speed sm2 openssl speed dsa openssl speed rsa openssl speed ecdsa openssl speed ecdh openssl genrsa -f4 -engine devcrypto 512 openssl genrsa -f4 -engine devcrypto 1024 openssl genrsa -f4 -engine devcrypto 2048 openssl genrsa -f4 -engine devcrypto 3072 openssl genrsa -f4 -engine devcrypto 4096 openssl speed -evp sha256 -engine devcrypto -elapsed openssl speed -evp aes-128-cbc -engine devcrypto -elapsed openssl speed -evp aes-128-ecb -engine devcrypto -elapsed openssl speed -evp aes-128-cfb -engine devcrypto -elapsed openssl speed -evp aes-128-ofb -engine devcrypto -elapsed openssl speed -evp des-ede3 -engine devcrypto -elapsed openssl speed -evp des-cbc -engine devcrypto -elapsed openssl speed -evp des-ede3-cfb -engine devcrypto -elapsed    
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We will build a remote debug environmet of Qt Creator in this user guide.   Contents 1 Change local.conf file in Yocto 2 2 Build and deploy Yocto SDK 2 2.1 Build full image SDK . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2 2.2 Deploy SDK . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2 3 Configure QT Kit 2 3.1 Setup device . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2 3.2 Configure QT version . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3 3.3 Configure gcc and g++ manually . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4 3.4 Configure gdb manually . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5 3.5 Configure Kit . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5 3.6 Very important thing!! . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5 4 Test result
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Important: If you have any questions or would like to report any issues with the DDR tools or supporting documents please create a support ticket in the i.MX community. Please note that any private messages or direct emails are not monitored and will not receive a response. i.MX 6/7 Family DDR Stress Test  The i.MX6/7 DDR Stress Test Tool is a PC-based software to fine-tune DDR parameters and verify the DDR performance on a non-OS, single-task environment(it is a light-weight test tool to test DDR performance). It performs write leveling, DQS gating and read/write delay calibration features. The tool described on this page cover the following i.MX 6/7 series SoCs: i.MX 6DQP (Dual/Quad Plus) i.MX 6DQ (Dual/Quad) i.MX 6DL/S (Dual Lite/Solo) i.MX 6SoloX i.MX 6SL i.MX 6SLL i.MX 6UL i.MX 6ULL/ULZ i.MX 7D/S i.MX 7ULP Note that the DDR Stress test tool supports the all of the above i.MX SoCs, however, some of the supported i.MX SoCs named in the tool support multiple i.MX SoCs as follows: MX6DQ – when selected, this supports both i.MX 6DQ and i.MX 6DQP (Plus) MX6DL – when selected, this supports both i.MX 6DL and i.MX 6S (i.MX 6DLS family) MX6ULL – when selected, this supports both i.MX 6ULL and i.MX6 ULZ MX7D – when selected, this supports both i.MX 7D and i.MX 7S The purpose of the i.MX 6/7 series DDR Tools is to enable users to generate and test a custom DRAM initialization based on their device configuration (density, number of chip selects, etc.) and board layout (data bus bit swizzling, etc.). This process equips the user to then proceed with the bring-up of a boot loader and an OS. Once the OS is brought up, it is recommended to run an OS-based memory test (like Linux memtester) to further verify and test the DDR memory interface. The i.MX 6/7 series DDR Tools consist of: DDR Register Programming Aid (RPA): i.MX 6/7 Series DDR Tool Release DDR Stress test: Described below There are three options to run the DDR Stress test. Each of these options are provided in the attached zip files. The following is a high-level overview of each option along with the naming convention of the associated zip file: Option 1 GUI based: Run the GUI executable and connect your board to the host PC via USB Archive file: ddr_stress_tester_vX.xx.zip The tool will first need to run a DDR initialization script for the specified i.MX SoC (refer to Load Init Script in the GUI tool).  Example initialization scripts based on NXP's development boards can be found in this zip file under the script folder.  Note, these scripts may need to be modified for your custom board and memory.   Option 2 DDR Stress Tester: JTAG Interface A hardware debugger connected to the board via the JTAG interface is used to download an elf file into the i.MX SoC OCRAM (internal RAM) and then begin execution. Results are shown on the UART serial port (115200-8-n-1). Archive file: ddr_stress_tester_jtag_vX.xx.zip As with the GUI tool, the JTAG/debugger option will first need to run a DDR initialization script for the specified i.MX SoC. Refer to the GUI tool description above for the location of the example scripts (which are found in the ddr_stress_tester_vX.xx.zip file). Note that the scripts are available either in the RealView ICE format (.inc file) or the DS-5 DSTERAM format (.ds). For other debuggers, the user will have to modify the script's command syntax for their specific debugger. This is also true if converting from a RealView Ice (.inc) format to a DS-5 DSTREAM (.ds) format and vice versa. The DDR Stress Tester executable (starting with V2.20) has an auto UART detection feature. If a different UART port for the serial console has been chosen than used on the NXP development tool (EVK, SABRE) specific commands can be added to the DDR initialization script that allows you to configure for the specific UART and then load and run the elf executable. Refer to the FAQ section of this community post and the txt file found in the JTAG archive file for instructions.   Option 3 U-Boot: The boot loader u-boot is running and commands in u-boot are used to download the bin file into SoC OCRAM and begin execution. Results are shown on the UART serial port (115200-8-n-1) Archive file: ddr_stress_tester_uboot_vX.xx.zip When downloading the DDR Stress Tool by u-boot, please copy the ddr-test-uboot-jtag-mxxxx.bin to SD card and load it to IRAM using the 'fatload' u-boot command (see notes below when using newer versions of u-boot). For i.MX6, please load the binary to 0x00907000. For i.MX7D, please load the binary to 0x00910000.  It is imperative to first disable the I and D cache in u-boot as shown below as the DDR Stress Test re-configures and re-enables the cache and MMU page table. While this option allows the user to load and run the DDR stress test from u-boot, NXP highly recommends executing the GUI based version for system testing and debugging. The u-boot version is considered a “last resort” for systems in production which may not have USB or JTAG connectivity. The reasons behind this stance are: In the GUI version, the system starts “clean” and uninitialized, whereas u-boot initializes many SoC features outside the knowledge of the DDR stress test and may conflict with the stress test operation When running the u-boot version, the test will overwrite the contents of u-boot residing in DDR, hence the test will overwrite any data in DDR. Once the stress test is loaded and executed, u-boot itself will no longer be accessible. To return to the functionality of u-boot, a system re-boot is required. Newer versions on u-boot do not allow a direct loading of the DDR stress test code from the SD card (boot media) directly to the SoC internal OCRAM (aka IRAM). Hence, the procedure is updated to first load the DDR stress test code into DDR and then copy into OCRAM, as shown in the procedure below: u-boot> dcache off;icache off;fatload mmc 2:1 0x12000000 ddr-test-uboot-jtag-mx6dq.bin;cp.b 0x12000000 0x00907000 0x20000;go 0x00907000 As u-boot initializes many peripherals that may conflict with the operation of the DDR stress test, it is necessary to clock gate these peripherals prior to running the DDR stress test. Hence, it is highly recommended to augment the procedure above as follows: u-boot> dcache off;icache off;fatload mmc 2:1 0x12000000 ddr-test-uboot-jtag-mx6dq.bin;cp.b 0x12000000 0x00907000 0x20000; u-boot> mw 0x020c4068 0x00C0000F; u-boot> mw 0x020c406c 0x00000000; u-boot> mw 0x020c4074 0x3F300000; u-boot> mw 0x020c4078 0x0000F300; u-boot> mw 0x020c407c 0x0F000003; u-boot> mw 0x020c4080 0x000003FC; u-boot> go 0x00907000 Note, in the above procedure, it is recommended to write to each clock gate register in separate commands (refer to commands starting with “mw”). The SoC requires a finite amount of time to gate each clock hence performing this sequence with a new command line write ensures the SoC has time to gate the intended clocks.   Stress Test Revision Features Comments 3.00 Add i.MX 7ULP support in the GUI version Known issues: USB connection is unstable when under USB HUB or some PC environments 2.92 Minor correction with write leveling calibration code error check to avoid a corner case of flagging an error when none have occurred.    2.91 Resolved issue with write leveling calibration code where a race condition in the code may result in the calibration routine not being able to find any delay values.   Only applies to MX6 series SoCs that support DDR3.  2.90 Reserve write delay line register (MMDC_MPWRDLCTL) configuration as DDR script does when do write calibration. In previous releases, MMDC_MPWRDLCTL would be changed to 0x40404040 by default.      * Further details available in the release notes  _________________________________________________________________________________________________________________________________________    FAQ   Q. I see an error message that states "ERROR: DCD addr is out of valid range.", why is this and how do I resolve?   A. Sometimes, when using the register programming aid, there are registers writes that are not supported in the DCD range.  Try looking for the following items and comment them out from the DDR initialization script: wait = on setmem /16 0x020bc000 = 0x30 // disable watchdog (note the address for this may be different between i.MX6x devices)  Q. How do I select the "DDR Density" pull-down menu and what is the purpose of this?   A. The DDR Density pull-down menu gives the user the option of testing a DDR density smaller than what they actually have on their board.  The advantage of doing this is to speed up test time to allow the user to perform a "quick test" of their system.  IMPORTANT: it is imperative that the user not set this value higher than the supported density on their board, doing so will cause the stress test to fail and/or lock up. The DDR Density has a different meaning depending on the memory type being tested (DDR3 or LPDDR2): For DDR3, this is the density per CHIP SELECT.  So if your board has two chip selects, and each chip select has 512MB, you would simply select 512MB or lower.  The default setting will simply set this to the detected density per chip select. For LPDDR2, this is the density per CHANNEL.  This is only relevant for MX6 devices that support 2 channel LPDDR2 memories (MX6DQ, MX6DL).  For other MX6 devices that support only one LPDDR2 channel, then this is the total density (for the maximum setting) for that channel. Note that for LPDDR2, the number of chip selects (per channel) is irrelevant when selecting the density to test as the stress test combines both chip-selects into one combined density per channel.  For example, lets say you have a 2GB LPDDR2 device, which 2 channels and 2 chip-selects per channel.  That means you have 512MB per chip select, per channel.  Or, it also means you have 1GB per channel when combining both chip selects per channel.  In this case, you would choose (a maximum setting of) 1GB in the DDR Density drop down menu.  However, this is also the same setting as the default setting (which you are welcome to still choose 1GB to convince yourself that 1GB per channel is indeed being tested). Now let's assume you have only one channel (LPDDR2) and one chip select, with a density of 128MB; in this case, the maximum DDR Density you can select is 128MB. Let's assume you have one channel and two chip selects, each chip select is 128MB;  in this case, the maximum DDR Density you can select is 256MB (a combination of both chip selects).   Note, for the MX7D, an actual density needs to be entered. For the MX6x series, simply leaving this field as Default will cause the DDR stress test to ascertain the supported density from the DDR init script. As the MX7D DDR controller is different, this feature is not supported, hence it is required for the user to enter an actual density (for more details regarding MX7D usage of density and number of chip-selects, see the next FAQ on the DDR CS setting).   Q.  What is the purpose of the "DDR CS" pull-down option?   A.  The answer depends on which processor you are testing:   For the i.MX 6x series: This pull down menu gives you the option of testing one chip select (CS0) or ALL (both) chip selects *IF* you have a two-chip select configuration.  If you have a two-chip select configuration, then this allows you to test only one chip select for faster test time; else you can choose to test both chip selects.  Note that if you have a one-chip select configuration and you choose "ALL", the stress test will return an error.   For the iMX 7D: Because the MX7D DDR controller is different, the DDR stress test will need the user to supply the entire supported density found on their board. The chip select field should be left as is (0) as the test will naturally test one chip select to the next. For example, let’s assume you are using two chip selects, with each chip select being 512MB. In this case, you would enter 1GB for the DDR Density field ensuring that both chip selects will be tested. The user is allowed to enter a density less than the density found on their board (for quicker testing), but keeping in mind both chip selects may not be tested in this case.   Q. I run DDR calibration using the DDR Stress Test Tool to obtain the calibration results.  Are these calibration parameters are written to the uboot flash_header.S automatically or manually?   A. The calibration values obtained from the DDR Stress Test Tool will need to be manually updated in the flash_header.S file or any other DDR initialization script.   Q. When running the DDR stress test on MX7D and I try to perform calibration, I get an error stating that calibration is not supported, is this expected?   A. Yes, calibration is not supported or needed when using MX7.  The reason is, MX7 uses a different memory controller than the MX6 series.  The MX6 series memory controller has built-in support for calibration where the MX7 memory controller does not.   Q. When running the GUI version of the DDR stress test, on MX7 and I leave DDR Density as default, I get an error in the tool stating I must supply a density.  Why is this?   A. This is due to the fact that MX7 uses a different memory controller than the MX6 series.  In the MX6 series, it was possible to calculate the memory density from the memory controller register settings.  The MX7 memory controller is different and does not lend itself to easily calculate the supported density based on the register settings.  Instead, the user should verify the density on their board and selected this value in the DDR Density pull-down menu.    Q. I noticed that when I run write-leveling calibration I sometimes see a note that due to the write-leveling calibration value being greater than 1/8 clock cycle that WALAT must be set to 1.  What does this mean?   A. In the MMDC chapter of the reference manual for the specific i.MX 6 device, the need to set WALAT is described in the MDMISC register as follows: "The purpose of WALAT is to add time delay at the end of a burst write operation to ensure that the JEDEC time specification for Write Post Amble Delay (tWPST) is met (DQS strobe is held low at the end of a write burst for > 30% a clock cycle before it is released). If the value of any of the WL_DL_ABS_OFFSETn register fields are greater than ‘1F’, WALAT should be set to ‘1’ (cycle additional delay). WALAT should be further increased for any full-cycle delays added by the WL_CYC_DELn register fields." Therefore, if the write-leveling calibration routine detects any write-leveling delay value greater than 0x1F, it will note to the user that WALAT must be set and the user should update their DDR3 init script to ensure WALAT is set.  Sometimes, a user may find that the write-leveling delay value may fluctuate from one run to the next, which is quite normal.  If it is found that this delay is "borderline" meaning sometimes it is greater than 0x1F and sometimes it might be slightly less, then it is ok to go ahead and set WALAT permanently in your init script as there is no harm in doing so and will ensure you will stay within JEDEC's tWPST.   Q. I sometimes see that after running write-leveling calibration that delay values being reported back are zero'd out (0x00), and then at times I see a non-zero value being reported, why is this? A. It is quite normal to see slight variations in the delay value between write-leveling calibration runs.  The write-leveling calibration routine assumes a majority of users have designed their board such that the DDR3 memories are placed close to the i.MX 6 SoC. There’s a mechanism in NXP’s DDR Stress test write leveling calibration code that checks the returned write leveling value. If the write-leveling calibration routine detects that the returned delay value is greater than ¾ of a clock cycle, it will "zero out" the delay value. It does this because it assumes that such a large delay result is due to the fact that the DQS signal is already delayed relative to the SDCLK, and to align DQS with SDCLK requires the calibration routine to delay DQS even further to align it to the next SDCLK edge, something we ideally would like to avoid.  JEDEC specs that the DQS edge must be within 25% of a SDCLK cycle with respect to the SDCLK edge, so having DQS initially slightly delayed from SDCLK is actually ok, hence why the calibration routine “zero’s” this out when the returned value exceeds ¾ of a clock cycle.  In cases like this, the DQS edge and SDCLK edge are so close together that in some calibration runs, the DQS edge may slightly precede SDCLK (resulting in a very small write-leveling delay value) and other runs, it may be slightly delayed relative to the SDCLK (resulting in a very large write-leveling delay value that will try to align DQS to the next SDCLK edge, hence needs to be zero’d out).   Q. When using the JTAG version of the DDR stress test, how can I select a different UART port for my serial port?   A. Under the folder ddr_stress_tester_jtag_v2.52, there's a text file that describes how to add a different UART port by adding a few additional commands to your DDR init script.  The following is an outline of these commands: 1. Ungate UART module clocks (most NXP scripts ungate all of the peripheral clocks at the beginning of the script, so this part is already done) 2. Configure the IOMUX options for the pins you wish the UART to use (normally an IOMUX option for UART_TX and UART_RX, and a daisy chain option for the UART_RX input) 3. Enable the desired UART module via the register UCR1, bit UART_EN 4. Disable other UART modules (UCR1[UART_EN] = 0).  Normally disabling UART1 should be sufficient, but it doesn't hurt to disable all of the other un-used UART options for the purpose of the stress test.   Here's an example in the .ds file vernacular of a set up as follows: MX6DQ, UART4 on KEY_COL0 and KEY_ROW0 (assume clock is ungated to all peripherals): mem set 0x020E01F8 32 0x00000004   #// config_pad_mode(KEY_COL0, ALT4) mem set 0x020E01FC 32 0x00000004   #// config_pad_mode(KEY_ROW0, ALT4); mem set 0x020E0938 32 0x00000001   #// Pad KEY_ROW0 is involved in Daisy Chain. mem set 0x02020080 32 0x00000000   #//disable UART1 in UART1_UCR1 (Note, you can disable other UART modules as well) mem set 0x021F0080 32 0x00000001   #//enable UART4 in UART4_UCR1   Here's another example in the .inc file vernacular of a set up as follows: MX6SX, UART5 on SD4_DATA4 abd SD4_DATA5 (assume clock is ungated to all peripherals): setmem /32 0x020E0294 = 0x2 //IOMUXC_SW_MUX_CTL_PAD_SD4_DATA5, ALT2; UART5_TX_DATA setmem /32 0x020E0290 = 0x2 //IOMUXC_SW_MUX_CTL_PAD_SD4_DATA4, ALT2; UART5_RX_DATA setmem /32 0x020E0850 = 0x00000000 // IOMUXC_UART5_IPP_UART_RXD_MUX_SELECT_INPUT, daisy chain for UART5_RX input to use SD4_DATA4 setmem /32 0x021F4080 = 0x00000001 // Enable UART_EN in UCR1 of UART5 // Disable UART_EN in UCR1 of UART1, UART2, UART3, and UART4 setmem /32 0x02020080 = 0x00000000 // UART1 setmem /32 0x021F0080 = 0x00000000 // UART2 setmem /32 0x021EC080 = 0x00000000 // UART3 setmem /32 0x021E8080 = 0x00000000 // UART4     Related Resources Links: iMX 8M Mini Register Programming Aid DRAM PLL setting  i.MX 8/8X Series DDR Tool Release  i.MX 8M Family DDR Tool Release 
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This is a quick article focused on how to add the support of SFTP on the i.MX devices using Yocto to add that packages.   Refer to the pdf attached.
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This is a quick article focused on how to add the support of the ssh on the i.MX devices using Yocto to add that packages.   Refer to the pdf attached.
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This is based on L5.10.35 BSP where you have to install QT static build: Qt 5.15 static build: Assuming your sysroot is at "/sysroot-cross" and your toolchain is at "/Toolchain" your qt-source is at /Qt-5.15 PATH=/sysroot-cross/bin:/sysroot-cross/sbin:/Toolchain/bin mkdir /Qt-5.15/mkspecs/qws/linux-imx6-g++ create in this dir the textfile "qmake.conf" with this content: ####################### snip qmake.conf ############################## include(../../common/linux.conf) include(../../common/qws.conf) # modifications to g++.conf QMAKE_CC                = arm-linux-gnueabi-gcc QMAKE_CFLAGS            = -pipe -isystem /sysroot-cross/include -isystem /sysroot-cross/usr/include QMAKE_CXX               = arm-linux-gnueabi-g++ QMAKE_CXXFLAGS          = -pipe -isystem /sysroot-cross/include -isystem /sysroot-cross/usr/include QMAKE_INCDIR            = /sysroot-cross/include /sysroot-cross/usr/include QMAKE_LIBDIR            = /sysroot-cross/lib /sysroot-cross/usr/lib QMAKE_LINK              = arm-linux-gnueabi-g++ QMAKE_LINK_SHLIB        = arm-linux-gnueabi-g++ QMAKE_LFLAGS            = -L/sysroot-cross/lib -L/sysroot-cross/usr/lib -Wl,-rpath-link -Wl,/sysroot-cross/lib QMAKE_LFLAGS           += -Wl,-rpath-link -Wl,/sysroot-cross/usr/lib #Opengl QMAKE_INCDIR_OPENGL = /Vivante/include QMAKE_INCDIR_OPENGL += /Vivante/include/GL QMAKE_INCDIR_OPENGL += /Vivante/include/EGL QMAKE_INCDIR_OPENGL += /Vivante/include/GLES2 QMAKE_LIBDIR_OPENGL = /Vivante/lib QMAKE_INCDIR_OPENGL_ES1 = $$QMAKE_INCDIR_OPENGL QMAKE_LIBDIR_OPENGL_ES1 = $$QMAKE_LIBDIR_OPENGL QMAKE_INCDIR_OPENGL_ES1CL = $$QMAKE_INCDIR_OPENGL QMAKE_LIBDIR_OPENGL_ES1CL = $$QMAKE_LIBDIR_OPENGL QMAKE_INCDIR_OPENGL_ES2 = /Vivante/include QMAKE_INCDIR_OPENGL_ES2 += /Vivante/include/EGL QMAKE_INCDIR_OPENGL_ES2 += /Vivante/include/GLES2 QMAKE_LIBDIR_OPENGL_ES2 = $$QMAKE_LIBDIR_OPENGL QMAKE_INCDIR_EGL = $$QMAKE_INCDIR_OPENGL_ES2 QMAKE_LIBDIR_EGL = $$QMAKE_LIBDIR_OPENGL QMAKE_LIBS_EGL = -lEGL -lGAL -lGLESv2 -lGLES_CM QMAKE_LIBS_OPENGL_ES2 = -lEGL -lGAL -lGLESv2 -lGLES_CM QMAKE_LIBS_OPENGL = -lEGL -lGAL -lGLESv2 -lGLES_CM QMAKE_LIBS_OPENGL_QT = -lEGL -lGAL -lGLESv2 -lGLES_CM QMAKE_LIBS_OPENGL_ES1 = QMAKE_LIBS_OPENGL_ES1CL = # modifications to linux.conf QMAKE_AR                = arm-linux-gnueabi-ar cqs QMAKE_OBJCOPY           = arm-linux-gnueabi-objcopy QMAKE_STRIP             = arm-linux-gnueabi-strip QMAKE_CFLAGS_RELEASE   = -pipe -isystem /sysroot-cross/include -isystem /sysroot-cross/usr/include load(qt_config) ####################### snip qmake.conf ############################## create in the same dir the text file "qplatformdefs.h" ####################### snip qplatformdefs.h ############################## #include "../../linux-g++/qplatformdefs.h" ####################### snip qplatformdefs.h ############################## now goto dir /Qt-5.15 cd /Qt-5.15 call configure with ./configure -opensource -confirm-license -release -no-rpath -no-fast \     -no-sql-ibase -no-sql-mysql -no-sql-odbc -no-sql-psql -no-sql-sqlite2 \     -no-qt3support -no-mmx -no-3dnow -no-sse -no-sse2 -no-sse3 -no-ssse3 \     -no-sse4.1 -no-sse4.2 -no-avx -no-optimized-qmake -no-nis -no-cups -pch \     -reduce-relocations -force-pkg-config -prefix /usr -no-armfpa -make libs \     -nomake docs -little-endian -embedded armv6 -qt-decoration-styled \     -depths all -xplatform qws/linux-imx6-g++ -iconv -largefile -qt-gfx-linuxfb \     -qt-gfx-multiscreen -qt-mouse-pc -qt-mouse-linuxinput -qt-libpng \     -plugin-gfx-directfb -system-zlib -no-accessibility -no-gfx-transformed \     -no-gfx-qvfb -no-gfx-vnc -no-kbd-tty -no-kbd-linuxinput -no-kbd-qvfb \     -no-mouse-linuxtp -no-mouse-tslib -no-mouse-qvfb -no-libmng -no-libtiff \     -no-gif -no-libjpeg -no-freetype -no-stl -no-glib -no-openssl -no-egl \     -no-xmlpatterns -no-exceptions -no-multimedia -no-audio-backend -no-phonon \     -no-phonon-backend -no-webkit -no-script -no-scripttools -no-svg -no-script \     -no-declarative -no-sql-sqlite -no-qdbus -no-opengl -static -nomake tools \     -nomake examples -nomake demos when configuring is finished call make after a looong time, when everything goes right, we have a staticly compiled Qt. DO NOT call "make install". We will install manually: copy from /Qt-5.15/bin the files moc, uic, rcc and qmake to somewhere in PATH, eg. /sysroot-cross/bin copy the contents of dir /Qt-5.15/mkspecs to /sysroot-cross/usr/mkspec copy the contents of dir /Qt-5.15/plugins to /sysroot-cross/usr/plugins copy the contents of dir /Qt-5.15/include to /sysroot-cross/usr/include copy the contents of dir /Qt-5.15/lib to /sysroot-cross/usr/lib Test application camtest: if you don't have/want directfb plugin remove from camtest.pro the lines LIBS += -L/sysroot-cross/usr/plugins/gfxdrivers QTPLUGIN += QDirectFBScreen and the lines from main.cpp #include <QtPlugin> Q_IMPORT_PLUGIN(qdirectfbscreen) generate makefile by typing /sysroot-cross/bin/qmake -spec /sysroot-cross/usr/mkspecs/qws/linux-imx6-g++ camtest.pro then make you should set and activate your framebuffers with this script ################# snip ################################ fbset -fb /dev/fb0 -g 1024 768 1024 2304 16 echo -n 0 > /sys/class/graphics/fb0/blank fbset -fb /dev/fb1 -g 1024 768 1024 1536 32 echo -n 0 > /sys/class/graphics/fb1/blank modprobe galcore modprobe uvcvideo modprobe mxc_v4l2_capture ################# snip ################################ if you use directfb then your /etc/directfbrc file should look like this: ######################## snip /etc/directfbrc ############# system=fbdev fbdev=/dev/fb1 mode=1024x768 depth=32 pixelformat=ARGB no-cursor window-surface-policy=systemonly ######################## snip /etc/directfbrc ############# to start the application with directfb: ./camtest -qws -display directfb without directfb using linuxfb: ./camtest -qws -display linuxfb:/dev/fb1 Notes about application: 1. The application shows 2 webcams in background-framebuffer (BG-FB). The foreground-framebuffer (FG-FB) shows the qt-gui. FG-FB is configured to be fully opaque and uses color-keying. On the BG-FB one cam is overlayed on the other cam using IPU. Optimization possibilities: the app copies the frames from the cams with memcpy. This wouldn't be necessary, when the kernel usb-webcam interface (uvc) would support V4L2_MEMORY_USERPTR method. through this way, you could pass the mapped IPU mmapped inbufs directly to v4l2 output buffers. If you get errors like NOSPC (-28) from uvc, this is a limitation of USB. My board is a MX6QSabre, where the two webcams are connected to the same usb-controller. With both webcams I had to limit the frame size to 320x250 and 160x120 at 25Hz. You might try higher res if you have other type of webcams (not usb). Have fun  
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This note show how to use the open source gstreamer1.0-rtsp-server package on i.MX6QDS and i.MX8x to stream video files and camera using RTP protocol.  The i.MX 6ULL and i.MX 7 doesn't have Video Processing Unit (VPU). Real Time protocol is a very common network protocol for delivering media over IP networks. On the board, you will need a GStreamer pipeline that encodes the raw video, adds the RTP payload, and sends over a network sink. A generic pipeline would look as follows: video source ! video encoder ! RTP payload ! network sink Video source: often it is a camera, but it can be a video from a file or a test pattern, for example. Video encoder: a video encoder as H.264, H.265, VP8, JPEG and others. RTP payload: an RTP payload that matches the video encoder. Network sink: a video sync that streams over the network, often via UDP.   Prerequisites: MX6x o MX8x board with the L5.10.35 BSP installed. A host PC with either Gstreamer or VLC player installed. Receiving h.264/h.265 Encoded RTP Video Stream on a Host Machine Using GStreamer GStreamer is a low-latency method for receiving RTP video. On your host machine, install Gstreamer and send the following command: $ gst-launch-1.0 -v udpsrc port=5000 caps = "application/x-rtp, media=(string)video, clock-rate=(int)90000, encoding-name=(string)H264, payload=(int)96" ! rtph264depay ! decodebin ! videoconvert ! autovideosink sync=false   Using Host PC: VLC Player Optionally, you can use VLC player to receive RTP video on a PC. First, in your PC, create a sdp file with the following content:  stream.sdpv=0m=video 5000 RTP/AVP 96c=IN IP4 127.0.0.1a=rtpmap:96 H264/90000 After this, with the GStreamer pipepline on the device running, open this .sdp file with VLC Player on the host PC. Sending h.264 and h.265 Encoded RTP Video Stream GStreamer provides an h.264 encoding element by software named x264enc. Use this plugin if your board does not support h.264 encoding by hardware or if you want to use the same pipeline on different modules. Note that the video performance will be lower compared with the plugins with encoding accelerated by hardware. # gst-launch-1.0 videotestsrc ! videoconvert ! x264enc ! rtph264pay config-interval=1 pt=96 ! udpsink host=<host-machine-ip> port=5000 Note: Replace <host-machine-ip> by the IP of the host machine. In all examples you can replace videotestsrc by v4l2src element to collect a stream from a camera   i.MX8X # gst-launch-1.0 videotestsrc ! videoconvert ! v4l2h264enc ! rtph264pay config-interval=1 pt=96 ! udpsink host=<host-machine-ip> port=5000   i.MX 8M Mini Quad/ 8M Plus # gst-launch-1.0 videotestsrc ! videoconvert ! vpuenc_h264 ! rtph264pay config-interval=1 pt=96 ! udpsink host=<host-machine-ip> port=5000 i.MX6X The i.MX6QDS does not support h.265 so the h.264 can work: # gst-launch-1.0 videotestsrc ! videoconvert ! vpuenc_h264 ! rtph264pay config-interval=1 pt=96 ! udpsink host=<host-machine-ip> port=5000   Using Other Video Encoders While examples of streaming video with other encoders are not provided, you may try it yourself. Use the gst-inspect tool to find available encoders and RTP payloaders on the board: # gst-inspect-1.0 | grep -e "encoder"# gst-inspect-1.0 | grep -e "rtp" -e " payloader" Then browse the results and replace the elements in the original pipelines. On the receiving end, you will have to use a corresponding payload. Inspect the payloader element to find the corresponding values. For example: # gst-inspect-1.0 rtph264pay   Install rtp in your yocto different form L5.10.35 BSP, to install gstreamer1.0-rtsp-server in any Yocto Project image, please follow the steps below: Enable meta-multimedia layer: Add the following on your build/conf/bblayers.conf: BBLAYERS += "$"${BSPDIR}/sources/meta-openembedded/meta-multimedia" Include gstreamer1.0-rtsp-server into the image: Add the following on your build/conf/local.conf: IMAGE_INSTALL_append += "gstreamer1.0-rtsp-server" Run bitbake and mount your sdcard. Copy the binaries: Access the gstreamer1.0-rtsp-server examples folder: $ cd /build/tmp/work/cortexa9hf-vfp-neon-poky-linux-gnueabi/gstreamer1.0-rtsp-server/$version/build/examples/.libs Copy the test-uri and test-launch to the rootfs /usr/bin folder. $ sudo cp test-uri test-launch /media/USER/ROOTFS_PATH/usr/bin Be sure that the IPs are correctly set: SERVER: => ifconfig eth0 $SERVERIP CLIENT: => ifconfig eth0 $CLIENTIP Video file example SERVER: => test-uri file:///home/root/video_file.mp4 CLIENT: => gst-launch-1.0 playbin uri=rtsp://$SERVERIP:8554/test You can try to improve the framerate performance using manual pipelines in the CLIENT with the rtspsrc plugin instead of playbin. Follow an example: => gst-launch-1.0 rtspsrc location=rtsp://$SERVERIP:8554/test caps = 'application/x-rtp'  ! queue max-size-buffers=0 ! rtpjitterbuffer latency=100 ! queue max-size-buffers=0 ! rtph264depay ! queue max-size-buffers=0 ! decodebin ! queue max-size-buffers=0 ! imxv4l2sink sync=false   Camera example SERVER: => test-launch "( imxv4l2src device=/dev/video0 ! capsfilter caps='video/x-raw, width=1280, height=720, framerate=30/1, mapping=/test' ! vpuenc_h264 ! rtph264pay name=pay0 pt=96 )" CLIENT: => gst-launch-1.0 rtspsrc location=rtsp://$SERVERIP:8554/test ! decodebin ! autovideosink sync=false The rtspsrc has two properties very useful for RTSP streaming: Latency: Useful for low-latency RTSP stream playback (default 200 ms); Buffer-mode: Used to control buffer mode. The slave mode is recommended for low-latency communications. Using these properties, the example below gets 29 FPS without a sync=false property in the sink plugin. The key achievement here is the fact that there is no dropped frame: => gst-launch-1.0 rtspsrc location=rtsp://$SERVERIP:8554/test latency=100 buffer-mode=slave ! queue max-size-buffers=0 ! rtph264depay ! vpudec ! imxv4l2sink      
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Important: If you have any questions or would like to report any issues with the DDR tools or supporting documents please create a support ticket in the i.MX community. Please note that any private messages or direct emails are not monitored and will not receive a response. i.MX 6/7 Series Family DDR Tools Overview This page contains the latest releases for the i.MX 6/7 series DDR Tools. The tools described on this page cover the following i.MX 6/7 series SoCs: i.MX 6DQP (Dual/Quad Plus) i.MX 6DQ (Dual/Quad) i.MX 6DL/S (Dual Lite/Solo) i.MX 6SoloX i.MX 6SL i.MX 6SLL i.MX 6UL i.MX 6ULL/ULZ i.MX 7D/S i.MX 7ULP The purpose of the i.MX 6/7 series DDR Tools is to enable users to generate and test a custom DRAM initialization based on their device configuration (density, number of chip selects, etc.) and board layout (data bus bit swizzling, etc.). This process equips the user to then proceed with the bring-up of a boot loader and an OS. Once the OS is brought up, it is recommended to run an OS-based memory test (like Linux memtester) to further verify and test the DDR memory interface. The i.MX 6/7 series DDR Tools consist of: DDR Register Programming Aid (RPA) DDR Stress test _________________________________________________________ i.MX 6/7 Series DDR Stress Test The i.MX 6/7 Series DDR stress test tool is a Windows-based software tool that is used as a mechanism to verify that the DDR initialization is operational prior for use in u-boot and OS bring-up. The DDR Stress Test tool can be found here: i.MX 6/7 DDR Stress Test Tool Note that the DDR Stress test tool supports all of the above i.MX SoCs, however, some of the supported i.MX SoCs named in the tool support multiple i.MX SoCs as follows: MX6DQ – when selected, this supports both i.MX 6DQ and i.MX 6DQP (Plus) MX6DL – when selected, this supports both i.MX 6DL and i.MX 6S (i.MX 6DLS family) MX6ULL – when selected, this supports both i.MX 6ULL and i.MX6 ULZ MX7D – when selected, this supports both i.MX 7D and i.MX 7S _____________________________________________________________________________ i.MX 6/7 Series DDR Register Programming Aid (RPA) The i.MX 6/7 series DDR RPA (or simply RPA) is an Excel spreadsheet tool used to develop DDR initialization for a user’s specific DDR configuration (DDR device type, density, etc.). The RPA generates the DDR initialization script for use with the DDR Stress Test tool. For a history of the previous versions of an RPA, refer to the Revision History tab of the respective RPA. To obtain the latest RPAs, please refer to the following links: i.MX 6DQP i.MX6DQP Register Programming Aids i.MX 6DQ i.MX6DQ Register Programming Aids i.MX 6DL/S i.MX6DL Register Programming Aids i.MX 6SoloX i.MX6SX Register Programming Aids i.MX 6SL i.MX6SL Register Programming Aids  i.MX6SLL i.MX6SLL Register Programming Aids i.MX 6UL/ULL/ULZ i.MX6UL/ULL/ULZ DRAM Register Programming Aids i.MX7D i.MX7D DRAM Register Programming Aids i.MX 7ULP i.MX7ULP DRAM Register Programming Aids _____________________________________________________________________________ DRAM Register Programming Aids FAQ    
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  Question: How can we generate an ARM DS5 DStream format DDR initialization script using the DRAM Register Programming Aid?  Answer: Some RPAs include a  "DStream .ds file" tab for the ARM DS5 debugger specific commands. The i.MX6UL/ULL/ULZ DRAM Register Programming Aids for example already has this supported. However, the user can easily create  the .ds format from the existing .inc format. The basic steps to convert .inc files to .ds format are as follows: 1)  Replace the one instance of setmem /16 with mem set 2)  In that same line, replace 0x020bc000 = with 0x020bc000 16 3)  Use a Replace All command to change setmem /32 with mem set 4)  Use a Replace All command to change = with 32 5)  Use a Replace All command to change // with # 6)  Save as a .ds file.   Question: When using a 528MHz DRAM Controller interface with a DDR memory of a faster speed bin, which speed bin timing options should one use? Answer: For example, let’s assume our MX6DQ design is using a DDR3 memory from a DDR3-1600 speed bin.  However, the maximum speed of the MMDC interface for the MX6DQ using DDR3 is 528MHz.  Should we use the 1600 speed bin (800MHz clock speed) or the 1066 speed bin (533MHz clock speed)?  In short, the user should use the timings rated for the maximum speed (frequency) with which you are running, in this case DDR3-1066 (533MHz).  In some cases, like when using the MX6DL, the maximum DDR frequency is 400MHz.  In this case, you would want to try and use 800 timings found in the AC timing parameters table.  However, most DDR3 devices have speed bin tables that may go only as low as 1066, in which case you would use the closest speed bin to your operational frequency (i.e. the 1066 speed bin table).     Question: Some timing parameters may specify a min and max number, which should I use? Answer: In most cases, you will want to choose the minimum timings.  Some DRAM controllers may have a tRAS_MAX timing parameter, in which case you would obviously use the maximum tRAS parameter given in the DRAM data sheet. Also, for timing parameters tAONPD and tAOFPD, we also want to use the maximum values given in the DDR3 data sheet. These represent the maximum amount of time the DDR3 device takes to turn on or off the RTT (termination), therefore, we should wait at least this amount of time before issuing any commands or accesses.   Question: Some timing parameters state things like “Greater of 3CK or 7.5ns”; which should I use? Answer: This depends on your clock speed.  Say you are running at 533MHz.  At 533MHz, 7.5ns equates to 4CKs.  In this case, 7.5ns at 533MHz is GREATER than 3CK, so we would use the 7.5ns number, or 4CKs. At 400MHz, 7.5ns equates to 3CKs.  In this case, we’d simply use 3CKs.   Question: I have a design that will throttle the DDR frequency (dynamic frequency scaling).  At full speed, I plan to run at 533MHz, and then I plan to throttle down to say 400MHz whenever possible.  Do I need to re-calculate my 400 MHz timing parameters that were initially set for 533MHz? Answer: It is not necessary to re-calculate timing parameters for 400MHz, and you can re-use the ones for 533MHz.  The timings at 533 MHz are much tighter than 400 MHz, and the key here is to NOT violate timings.  Also, it may be a bit of a hassle maintaining two sets of timing parameters, especially if later in the design, you swap DDR vendors that might require you to re-calculate some timing parameters.  It’s easier to do it once and to come up with a combined worse-case timing parameters for 533MHz, which you know will work at 400MHz.  But, if you don’t mind maintaining two sets of timing parameters, and really want to optimize timings down to the last pico-second for 400MHz, then knock yourself out.   Question: Can I use these Register programming aids for both Fly by and T- Topology ? Answer Yes The DDR register programming aid is agnostic to the DDR layout. The same spreadsheet works for both topologies. We recommend running write leveling calibration for both topologies and the values returned by the Write Leveling routine from the Freescale DDR stress test should be incorporated back to the customer specific initialization script. The DDR stress test also has a feature whereby it evaluates the write leveling values returned from calibration and increments WALAT to 1 if the values exceed a defined limit. The DDR stress test informs the user when the Write Additional latency (WALAT) exceeds the limit and should be increased by 1, and reminds the user to add it back in the customer specific initialization script if required.   WALAT - 0 00000000 WALAT: Write Additional latency. Recommend to clear these bits. Proper board design should ensure that the DDR3 devices are placed close enough to the MMDC to ensure the skew between CLK and DQS is less than 1 cycle.     Question: Can I use the DEFAULT Register programming aid values for MDOR when using an Internal OSC instead of the recommended 32.768 KHZ XTAL ? Answer No, NXP recommends reprogramming these values based on the worse case frequency (Max clock) of the internal OSC of the device to guarantee JEDEC timings are met. Please refer to Internal Oscillator Accuracy considerations for the i.MX 6 Series for more details  
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