i.MX Processors Knowledge Base

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i.MX Processors Knowledge Base

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GmSSL is an open source cryptographic toolbox that supports SM2 / SM3 / SM4 / SM9 and other national secret (national commercial password) algorithm, SM2 digital certificate and SM2 certificate based on SSL / TLS secure communication protocol to support the national security hardware password device , To provide in line with the national standard programming interface and command line tools, can be used to build PKI / CA, secure communication, data encryption and other standards in line with national security applications. For more information, please access GmSSL official website http://gmssl.org/english.html.   Software environments as the belows: Linux kernel: imx_4.14.98_2.0.0_ga cryptodev: 1.9 HW platform: i.MX6UL, i.MX7D/S, i.MX8M/MM, i.MX8QM/QXP. The patches include the following features: 1, Support SM2/SM9   encryption/decryption/sign/verify/ key exchange ,   RSA  encryption/decryption, DSA/ECDSA sign/verify, DH/ECDH key agreement, ECC & DLC & RSA key generation and big number  operation and   e lliptic  c urve   m ath by CAAM hardware   accelerating . 2, run "git apply 0001-Enhance-cryptodev-and-its-engine-in-GmSSL-by-CAAM-s-.patch" under folder sources/poky, and "git apply 0001-Add-public-key-cryptography-operations-in-CAAM-drive.patch"   under folder   sources/meta-fsl-bsp-release for patch these codes. 3, GmSSL Build command: $ tar zxvf GmSSL-master-iMX.tgz $  cd  GmSSL-master-iMX (For i.MX8M/MM, i.MX8QM/QXP) $  source /opt/arm-arch64/environment-setup-aarch64-poky-linux  $  ./Configure -DHAVE_CRYPTODEV -DUSE_CRYPTODEV_DIGESTS -DHW_ENDIAN_SWAP  --prefix= ~/install64   --openssldir=/etc/gmssl --libdir=/usr/lib no-saf no-sdf no-skf no-sof no-zuc -no-ssl3 shared linux-aarch64 $  make  $  make install                              /*image and config file will be installed to folder   ~ /install64   */   (For  i.MX6UL, i.MX7D/S ) $   source /opt/arm-arch32/environment-setup-cortexa7hf-neon-poky-linux-gnueabi $   ./Configure -DHAVE_CRYPTODEV -DUSE_CRYPTODEV_DIGESTS --prefix= ~ /install32   --openssldir=/etc/gmssl --libdir=/usr/lib no-saf no-sdf no-skf no-sof no-zuc -no-ssl3 shared linux-armv4 $  make  $  make install                             /*image and config file will be installed to folder   ~ /install32   */   4, How to use GmSSL: copy image gmssl to /usr/bin on i.MX board;  copy  gmssl libcrypto.so.1.1 and libssl.so.1.1 to /usr/lib  on i.MX board; copy folder etc/ gmssl to /etc/ on i.MX board. copy test examples (dhtest, dsatest, rsa_test, ecdhtest, ecdsatest, eciestest, sm3test, sms4test, sm2test, sm9test) under GmSSL-master-iMX/test  to U disk for running. You can run test examples by the following commands: #insmod /lib/modules/4.14.98-imx_4.14.98_2.0.0_ga+g5d6cbeafb80c/extra/cryptodev.ko #/run/media/sda1/dhtest #/run/media/sda1/dsatest #/run/media/sda1/rsa_test #/run/media/sda1/ecdhtest #/run/media/sda1/ecdsatest #/run/media/sda1/eciestest #/run/media/sda1/sm3test #/run/media/sda1/sms4test #/run/media/sda1/sm2test #/run/media/sda1/sm9test and speed test commands: #gmssl speed sm2 #gmssl genrsa -rand -f4 512 #gmssl speed dsa #gmssl genrsa -rand -f4 1024 #gmssl speed rsa #gmssl genrsa -rand -f4 2048 #gmssl speed ecdsa #gmssl genrsa -rand -f4 3072 #gmssl speed ecdh #gmssl genrsa -rand -f4 4096   ++++++++++++++++++++++++++++     updating at 2019-09-10    +++++++++++++++++++++++++++++++++++++++++++++ 0001-fix-the-bug-which-hash-and-cipher-key-don-t-use-DMA-.patch fix the issue which   dismatching on key buffer between crytodev and caam driver. Crytodev uses stack's buffer for key storage and caam driver use it to dma map which cause flush cache failure. The patch need to apply on cryptodev-module in Yocto build.   ++++++++++++++++++++++++++++     updating at 2019-10-14   +++++++++++++++++++++++++++++++++++++++++++++ This updating is for China C-V2X application. The package meta-cv2x_4.14.98_2.0.0_ga.tgz is Yocto layer which bases on GmSSL and Cryptodev. I add HW SM2 verification by dedicated CAAM job descriptor and enhanced SW  SM2 verification by precomputed multiples of generator and ARMv8 assembler language to accelerate point  operation.  Software environments as the belows: Linux kernel: imx_4.14.98_2.0.0_ga cryptodev: 1.9 HW platform: i.MX8M/MM/MN, i.MX8QM/QXP. How to build: 1, decompress  meta-cv2x_4.14.98_2.0.0_ga.tgz and copy meta-cv2x to folder (Yocto 4.14.98_2.0.0_ga dir)/sources/ 2, Run DISTRO=fsl-imx-wayland MACHINE=imx8qxpmek source fsl-setup-release.sh -b build-cv2x and add BBLAYERS += " ${BSPDIR}/sources/meta-cv2x " into ( Yocto 4.14.98_2.0.0_ga dir ) /build-cv2x/conf/bblayers.conf and  IMAGE_INSTALL_append += " gmssl-bin "  into local.conf 3, Run bitbake fsl-image-validation-imx. 4, You can find  cv2x-verify.c under (build dir)/tmp/work/aarch64-poky-linux/cryptodev-tests/1.9-r0/git/tests. It is example for using CAAM cryptdev interface to do C-V2X verification (includes SM2 p256, NIST p256 and brainpoolP256r1).   cv2x_benchmark.c   under ( build dir )/tmp/work/aarch64-poky-linux/gmssl/1.0-r0/gmssl-1.0/test is the benchmark test program of C-V2X verifying. It includes HW, SW and HW+SW(one CPU) verifying for  SM2 p256, NIST p256 and brainpoolP256r1. 5, Run the below command on your i.MX8QXP MEK board. modprobe cryptodev ./cv2x_benchmark Note: the udpated GmSSL also support projective coordinates and affine coordinates (CAAM only support affine  coordinates ). Affine  coordinates is used  by default. You can call EC_GROUP_set_coordinates() and EC_GROUP_restore_coordinates() to change coordinates and restore default. When you hope to use some EC APIs under expected coordinates, you need to call EC_GROUP_set_coordinates() before EC APIs and  EC_GROUP_restore_coordinates()  after them. Like the below example: orig_coordinate = EC_GROUP_set_coordinates(EC_PROJECTIVE_COORDINATES); group = EC_GROUP_new_by_curve_name(NID_sm2p256v1); EC_GROUP_restore_coordinates(orig_coordinate);   ++++++++++++++++++++++++++++     updating at 2020-11-09   +++++++++++++++++++++++++++++++++++++++++++++ This updating is for Yocto release of Linux 5.4.47_2.2.0​​. The package meta-gmcrypto_L5.4.47-2.2.0.tgz is Yocto layer which also support c-v2x feature in previous release .  Software environments as the belows: Linux kernel: imx_5.4.47_2.2.0 cryptodev: 1.10 HW platform: i.MX6UL, i.MX7D/S, i.MX8M/8M Mini/8M Nano/8M Plus, i.MX8/8X. How to build: 1, decompress meta-gmcrypto_L5.4.47-2.2.0.tgz and copy meta-gmcrypto to folder (Yocto 5.4.47_2.2.0 dir)/sources/ 2, Run DISTRO=fsl-imx-wayland MACHINE=imx8mmevk source imx-setup-release.sh -b build-imx8mmevk and add BBLAYERS += " ${BSPDIR}/sources/meta-gmcrypto " into ( Yocto 5.4.47_2.2.0 dir ) /build-imx8mmevk/conf/bblayers.conf and  IMAGE_INSTALL_append += " gmssl-bin "  into local.conf 3, Run bitbake fsl-image-validation-imx. 4, You can find  cv2x-verify.c under (build dir)/tmp/work/aarch64-poky-linux/cryptodev-tests/1.10caam-r0/git/tests. It is example for using CAAM cryptdev interface to do C-V2X verification (includes SM2 p256, NIST p256 and brainpoolP256r1).   cv2x_benchmark.c   under ( build dir )/tmp/work/aarch64-poky-linux/gmssl/1.0-r0/gmssl-1.0/test is the benchmark test program of C-V2X verifying. It includes HW, SW and HW+SW(one CPU) verifying for  SM2 p256, NIST p256 and brainpoolP256r1. 5, Run the below command on your i.MX8M Mini evk board. modprobe cryptodev ./cv2x_benchmark gmssl speed sm2 gmssl speed dsa gmssl speed rsa gmssl speed ecdsa gmssl speed ecdh gmssl genrsa -rand -f4 -engine cryptodev 4096 Note: 1, the udpated GmSSL also support projective coordinates and affine coordinates (CAAM only support affine  coordinates ). Affine  coordinates is used  by default. You can call EC_GROUP_set_coordinates() and EC_GROUP_restore_coordinates() to change coordinates and restore default. When you hope to use some EC APIs under expected coordinates, you need to call EC_GROUP_set_coordinates() before EC APIs and  EC_GROUP_restore_coordinates() after them. Like the below example: orig_coordinate = EC_GROUP_set_coordinates(EC_PROJECTIVE_COORDINATES); group = EC_GROUP_new_by_curve_name(NID_sm2p256v1); EC_GROUP_restore_coordinates(orig_coordinate); 2, Yocto Zeus integrates openssl 1.1.1g, so I change library name of gmssl from libcrypto to libgmcrypto and from libssl to libgmssl to avoid name confliction with openssl 1.1.1g (lib name are also libcrypto.so.1.1 and libssl.so.1.1). You should use -lgmcrypto and -lgmssl when you link gmssl library instead of -lcrypto and -lssl.
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i.MX evaluation board can be a simple solution to program i.MX boards in a factory for instance. i.MX evaluation board are not for industrial usage, but you can find plenty of cheap i.MX insdustrial boards on the web. Here I am using an i.MX8QXP rev B0 MEK board and I will program an i.MX6Q SABRE SD board. The first step is to generate your image. Follow the documentation steps to generate the "validation" image. You will have to customize a little bit the local.conf file (in conf/local.conf) to have git, cmake, gcc and other missing package. edit local.conf and add the following lines at the end of the file: IMAGE_INSTALL_append = " git cmake htop packagegroup-core-buildessential xz p7zip rsync" ‍‍‍‍ ‍ I have added rsync package in local, it can replace cp (copy) but with the --progress option you can see the copy progression. P7zip replace unzip for our images archives avaialable on nxp.com as unzip as issues with big files. then rebake your image: bitbake - k fsl - image - validation - imx‍‍‍‍ ‍ When it is done, go in tmp/deploy/image/<your image generated> and use uuu to program your board (I use a sd card; thus I can increase the partition esily): sudo . / uuu - b sd_all imx - boot - imx8qxpmek - sd . bin - flash fsl - image - validation - imx - imx8qxpmek . sdcard . bz2 / * ‍‍‍‍ ‍ As the rootfs can be too small, use gparted under Linux for instance to increase the size of the partition. Put the SD card and start your board. Here here the dirty part... You may know archlinux|ARM websitesite (Arch Linux ARM ), you have a lots of precompiled packages. Thus on the board you can download it, and copy the file in /usr folder (you can use it to have the latest openSSL for  instance!). Plug an ethernet cable on the board and check if it is up: ifconfig - a ifconfig eth0 up‍‍‍‍‍‍‍‍ ‍ ‍ Now you should have access to the internet. On uuu webpage you can find all the packages you need (here I am using a 4.14.98_2.0.0 Linux): mkdir missinglibs cd missinglibs wget http : / / mirror . archlinuxarm . org / aarch64 / core / bzip2 -1.0 . 8 - 2 - aarch64 . pkg . tar . xz wget http : / / mirror . archlinuxarm . org / aarch64 / core / nettle -3.5 . 1 - 1 - aarch64 . pkg . tar . xz wget http : / / mirror . archlinuxarm . org / aarch64 / core / libusb -1.0 . 22 - 1 - aarch64 . pkg . tar . xz wget http : / / mirror . archlinuxarm . org / aarch64 / extra / libzip -1.5 . 2 - 2 - aarch64 . pkg . tar . xz wget http : / / mirror . archlinuxarm . org / aarch64 / core / zlib -1 : 1.2 . 11 - 3 - aarch64 . pkg . tar . xz wget http : / / mirror . archlinuxarm . org / aarch64 / extra / p7zip -16.02 - 5 - aarch64 . pkg . tar . xz cd . . ‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ Wait all the archives are downloaded (otherwise you'll decompress before the archive is downloaded) as wget is running in background! Now untar the archives and copy it in the rootfs (dirty): tar - xJf libzip -1.5 . 2 - 2 - aarch64 . pkg . tar . xz tar - xJf libusb -1.0 . 22 - 1 - aarch64 . pkg . tar . xz tar - xJf nettle -3.5 . 1 - 1 - aarch64 . pkg . tar . xz tar - xJf bzip2 -1.0 . 8 - 2 - aarch64 . pkg . tar . xz cp zlib -1 : 1.2 . 11 - 3 - aarch64 . pkg . tar . xz zlib tar - xJf zlib tar - xJf p7zip -16.02 - 5 - aarch64 . pkg . tar . xz cd usr sudo cp - R . / usr cd . . / . . / ‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ Download and compile uuu: git clone git : / / github . com / NXPmicro / mfgtools . git cd mfgtools / cmake . make‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍ ‍ ‍ ‍ ‍ Download an image on nxp.com for instance. I have downloaded on the i.MX6 4.14.98_2.0.0 image and put it on a usb key. then unzip it in the uuu folder: 7z e L4 .14 . 98_2 .0 . 0_ga_images_MX6QPDLSOLOX . zip‍‍‍ ‍ As mentionned before unzip cannot hadle big files... so use 7z as me plug the i.MX6Q SABRE SD to the i.MX8X and program your i.MX6 board: . / uuu uuu . auto - imx6qsabresd‍ uuu ( Universal Update Utility ) for nxp imx chips -- libuuu_1 .3 . 74 - 0 - g64eeca1 Success 1 Failure 0 ‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍ ‍ ‍ ‍ ‍
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This document explains how to bring-up u-boot & Linux via JTAG This procedure has been tested on: i.MX6 Solo X Sabre SD i.MX6UL EVK Prerequistes: Get the latest BSP for your board. This procedure was tested with L4.1.15. Build the 'core-image-minimal' image to bring-up your board (Detailed steps here) Optional- Build a meta-toolchain for your device 1.- Set board to boot from Serial dowloader mode or set it to boot from the SD card and remove the sd card We basically want the board to stall in boot ROM to attach to the target. 2.- Connect JTAG probe and turn on the board The device should stall trying to establish a connection to download an image, this will allow us to attach to the target. 3.- Load Device Configuration Data In 'normal' boot sequence the boot ROM takes care of reading the DCD and configuring the device accordingly, but in this case we are skipping this sequence and we need to configure the device manually. The script used by Lauterbach to parse and configure the device is called dcd_interpreter.cmm and can be found here. Search for the package for your specific device. The DCD configuration for your board should be on your u-boot directory: yocto_build_dir/tmp/work/<your board>imx6ulevk/u-boot-imx/<u-boot_version>2016.03-r0/git under board/freescale/<name of your board>mx6ul_14x14_evk/imximage.cfg This file (imximage.cfg) contains all the data to bring up DRAM among other early configuration options. 4.- Load U-boot If an SREC file of U-boot is not present build it (meta-toolchain installed required) the SREC file contains all the information required by the probe to load it and makes this process easier. To build the SREC simply type: make <your board defconfig>mx6ul_14x14_evk_defconfig  (all supported boards are found under u-boot_dir/configs) make If you cannot build an SREC or do not want to, you can use the u-boot.imx (located under yocto_build_dir/tmp/deploy/images/<your board name>/) or u-boot.bin files but you will need to figure out the start address and load address for these files, this can be done by examining the IVT on u-boot.imx (here is a useful document explaining the structure of the IVT). Let U-boot run and you should see its output on the console I will try to boot from several sources but it will fail and show you the prompt. 5.- Create RAMDisk After building the core-image-minimal you will have all the required files under yocto_build_dir/tmp/deploy/images/<your board name>/ You will need: zImage.bin - zImage--<Linux Version>--<your board>.bin Device tree blob - zImage--<Linux Version>--<your board>.dtb Root file system - core-image-minimal-<your board>.rootfs.ext4 We need to create a RAMDisk out of the root file system we now have, these are the steps to do so: Compress current Root file system using gzip: gzip core-image-minimal-<your board>.rootfs.ext4 If you want to keep the original file use: gzip -c core-image-minimal-<your board>.rootfs.ext4 > core-image-minimal-<your board>.rootfs.ext4.gz Create RAMDisk using mkimage: mkimage -A arm -O linux -T ramdisk -C gzip -n core-image-minimal -d core-image-minimal-<your board>.rootfs.ext4.gz core-image-minimal-RAMDISK.rootfs.ext4.gz.u-boot Output: Image Name: core-image-minimal Created: Tue May 23 11:28:55 2017 Image Type: ARM Linux RAMDisk Image (gzip compressed) Data Size: 3017939 Bytes = 2947.21 kB = 2.88 MB Load Address: 00000000 Entry Point: 00000000 Here are some details on mkimage usage Usage: mkimage -l image -l ==> list image header information mkimage [-x] -A arch -O os -T type -C comp -a addr -e ep -n name -d data_file[:data_file...] image -A ==> set architecture to 'arch' -O ==> set operating system to 'os' -T ==> set image type to 'type' -C ==> set compression type 'comp' -a ==> set load address to 'addr' (hex) -e ==> set entry point to 'ep' (hex) -n ==> set image name to 'name' -d ==> use image data from 'datafile' -x ==> set XIP (execute in place) mkimage [-D dtc_options] [-f fit-image.its|-F] fit-image -D => set options for device tree compiler -f => input filename for FIT source Signing / verified boot not supported (CONFIG_FIT_SIGNATURE undefined) mkimage -V ==> print version information and exit 6.- Modify U-boot's environment variables Now we need to modify U-boot's bootargs as follows: setenv bootargs console=${console},${baudrate} root=/dev/ram rw We need to find out the addresses where u-boot will expect the zImage, the device tree and the initial RAMDisk, we can do it as follows: => printenv fdt_addr fdt_addr=0x83000000 => printenv initrd_addr initrd_addr=0x83800000 => printenv loadaddr loadaddr=0x80800000 Where: fdt_addr -> Device tree blob load address initrd_addr -> RAMDisk load address loadaddr -> zImage load address 7.- Load zImage, DTB and RAMDisk Now we know where to load our zImage, device tree blob and RAMDisk, on Lauterbach this can be achieved by running the following commands: Stop the target and execute: data.load.binary zImage.bin 0x80800000 data.load.binary Your_device.dtb 0x83000000 data.load.binary  core-image-minimal-RAMDISK.rootfs.ext4.gz.u-boot 0x83800000 Let the device run again and deattach from the device in lauterbach this is achieved by: go SYStem.mode.NoDebug start the boot process on u-boot as follows: bootz ${loadaddr} ${initrd_addr} ${fdt_addr} You should now see the Linux kernel boot process on your terminal: After the kernel boots you should see its prompt on your terminal: Since we are running out of RAM there is no way for us to save u-boot's environment variables, but you can modify the source and compile u-boot with the new bootargs, by doing so you can create a Load script that loads all the binaries hits go and the boot process will continue automatically. One way to achieve this is to modify the configuration file under U-boot_dir/include/configs/<your board>.h find the mfgtool_args and modify accordingly. The images attached to this thread have been modified as mentioned.
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A new version of the Pins Tool for i.MX Application Processors has been released and is available for download as desktop tool from Pins Tool for i.MX Application Processors|NXP. The pins Tool for i.MX Application Processors is used for pin routing configuration, validation and code generation, including pin functional/electrical properties, power rails, run-time configurations, with the following main features: Desktop application Muxing and pin configuration with consistency checking Multicore support ANSI-C initialization code Graphical processor package view Multiple configuration blocks/functions Easy-to-use device configuration Selection of Pins and Peripherals Package with IP blocks Routed pins with electrical characteristics Registers with configured and reset values Power Groups with assigned voltage levels Source code for C/C++ applications Documented and easy to understand source code CSV Report and Device Tree File Localized for English and Simplified Chinese Mostly Connected: On-Demand device data download Integrates with any compiler and IDE What's New Added Label support to give signals a name Added ‘Log’ and ‘Problems’ view to report conflicts between settings Added support for templates to store user configurations as starting point for new configurations Added ability to download and share data for devices, especially for off-network host machines i. MX header files are now automatically part of the device data Import of legacy Processor Expert .pe files Export of register defines Various bug fixes and documentation improvements The release notes of the desktop application are attached to this article. Import Processor Expert Files A new importer has been added to import legacy Processor Expert for i.MX files: Labels Signals can now have user defined labels: Templates, Kits, Boards and Processors When creating a new configuration, it offers Templates, Boards and Processors. Custom configurations can be stored as templates and then used for new configurations. Board Specific Functions With the provided board and kit configurations, there are now pre-configured initialization functions for major blocks on the board: Export Data To simplify downloading the device specific data for the desktop tool, the 'Export' function can be used to download and export the data. The data can be copied that way to another machine or all data for a set of devices can be loaded. Export Registers With the Export command the registers can be exported as text/source: This is used to store the register values: /*FUNCTION********************************************************************** * * Function Name : init_audmux_pins * Description   : Configures pin routing and optionally pin electrical features. * *END**************************************************************************/ #define INIT_AUDMUX_PINS_IOMUXC_AUD5_INPUT_DA_AMX_SELECT_INPUT_VALUE            0x00000000   /*!< Register name: IOMUXC_AUD5_INPUT_DA_AMX_SELECT_INPUT */ #define INIT_AUDMUX_PINS_IOMUXC_AUD5_INPUT_TXCLK_AMX_SELECT_INPUT_VALUE         0x00000000   /*!< Register name: IOMUXC_AUD5_INPUT_TXCLK_AMX_SELECT_INPUT */ #define INIT_AUDMUX_PINS_IOMUXC_AUD5_INPUT_TXFS_AMX_SELECT_INPUT_VALUE          0x00000000   /*!< Register name: IOMUXC_AUD5_INPUT_TXFS_AMX_SELECT_INPUT */ #define INIT_AUDMUX_PINS_IOMUXC_SW_MUX_CTL_PAD_DI0_PIN02_VALUE                  0x00000002   /*!< Register name: IOMUXC_SW_MUX_CTL_PAD_DI0_PIN02 */ #define INIT_AUDMUX_PINS_IOMUXC_SW_MUX_CTL_PAD_DI0_PIN03_VALUE                  0x00000002   /*!< Register name: IOMUXC_SW_MUX_CTL_PAD_DI0_PIN03 */ #define INIT_AUDMUX_PINS_IOMUXC_SW_MUX_CTL_PAD_DI0_PIN04_VALUE                  0x00000002   /*!< Register name: IOMUXC_SW_MUX_CTL_PAD_DI0_PIN04 */ #define INIT_AUDMUX_PINS_IOMUXC_SW_MUX_CTL_PAD_DI0_PIN15_VALUE                  0x00000002   /*!< Register name: IOMUXC_SW_MUX_CTL_PAD_DI0_PIN15 */ #define INIT_AUDMUX_PINS_IOMUXC_SW_MUX_CTL_PAD_DISP0_DATA16_VALUE               0x00000003   /*!< Register name: IOMUXC_SW_MUX_CTL_PAD_DISP0_DATA16 */ #define INIT_AUDMUX_PINS_IOMUXC_SW_MUX_CTL_PAD_DISP0_DATA18_VALUE               0x00000003   /*!< Register name: IOMUXC_SW_MUX_CTL_PAD_DISP0_DATA18 */ #define INIT_AUDMUX_PINS_IOMUXC_SW_MUX_CTL_PAD_DISP0_DATA19_VALUE               0x00000003   /*!< Register name: IOMUXC_SW_MUX_CTL_PAD_DISP0_DATA19 */ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ We hope you will find this new release useful. Thanks for designing with NXP! 
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1.- Set SW602 Boot mode pin settings to Serial Downloader mode 2.-Connect JTAG debug probe and turn on the board 3.-Run script to bring-up DRAM In Lauterbach this script is called 'mcimx6ul_sieve_dram.cmm' under the mcimx6ul folder, the scripts can be found here and are also attached (download the imx6ultralite package). If you are not using Lauterbach please ask your probe vendor for a similar script. NOTE: this u-boot image has been built to run off DRAM if your bootloader runs from OCRAM you might not need a script. While running the script you might be prompted with and error telling you there is a syntax error in the script system.cpu IMX6ULL simply edit the script and change the CPU name to IMX6ULTRALITE 4.- Load u-boot.srec to DRAM and start executing it The srec is being used in this case because it contains the addresses where the binary needs to be loaded and the entry point for the application is automatically recognised and set by Lauterbach. To load it simply issue 'data.load.S3record u-boot.srec' and then click on go to let it run. You should now be able to see the output from u-boot on the console hit any key on the console to stop the boot process. 5.- Load QuadSPI configuration to DRAM and flash it to the memory The Boot ROM on the i.MX6UL requires the configuration data for the QuadSPI memory to be stored at address 0x400 of the QuadSPI memory, the length of this configuration data is 512 bytes. Attached is a configuration binary that can be used for the NOR flash memory used in the i.MX6UL EVK. For more details on the configuration parameters please refer to chapter '8.6.3 QuadSPI Configuration Parameters' of the i.MX6UL Reference Manual. Stop the execution on T32 (Lauterbach's environment) and load the configuration to DRAM by issuing 'data.load.binary QSPI_cfg2.bin 0x90000000' and resume execution. On u-boot execute the 'sf probe' command (sf stands for Serial Flash) to detect the memory. You should see an output like the following: => sf probe SF: Detected N25Q256 with page size 256 Bytes, erase size 4 KiB, total 32 MiB Now issue the sf erase command to erase the first sector (remember our erase size is of 4KiB): => sf erase 0x0 0x1000 SF: 4096 bytes @ 0x0 Erased: OK Now we are ready to write our configuration to address 0x400 => sf write 0x90000000 0x400 0x200 SF: 512 bytes @ 0x400 Written: OK 6.- Load u-boot.imx to DRAM and download it to memory. We will follow the same procedure to download the u-boot image to the memory. Stop execution on Lauterbach and load u-boot.imx to DRAM using 'data.load.binary u-boot_SPI.imx 0x90000000' and resume execution (u-boot.imx contains the IVT header which basically stores all the information the device needs to boot u-boot.bin and u-boot.imx). The boot ROM expects to find the IVT header at address 0x1000 of the SPI NOR Flash memory. We will load u-boot.imx to this address by issuing ' sf update 0x90000000 0x1000 0x57830 '(the size of u-boot.imx is 358448 bytes) this will erase and write the memory. => sf update 0x90000000 0x1000 0x57830 358448 bytes written, 0 bytes skipped in 23.741s, speed 15458 B/s If you want to verify that the image was flashed correctly you can read from QuadSPI to DRAM by issuing 'sf read 0x90000000 0x1000 0x57830 ' and verify the data. 7.- Now we can end our debug session and turn off our board Set SW602 to Internal boot mode (ON/OFF) and SW601 to select boot from QuadSPI (all OFF) Turn on the board again and you should be able to see u-boot's output on your terminal. This procedure can be used with other boards/i.MX6 derivatives, I am just posting the setup in which I tested it.
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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   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.   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. 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. The following is an example of downloading and running the DDR stress test from u-boot: u-boot> dcache off u-boot> icache off u-boot> fatload mmc 0:1 0x00907000 ddr-test-uboot-jtag-mx6ul.bin u-boot> go 0x00907000   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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NOTE: Always de-power the target board and the aggregator when plugging or unplugging smart sensors from the aggregator. NOTE: See this link to instrument a board with a Smart Sensor. This page documents the triple-range "smart" current sensor that's part of a larger system for profiling power on application boards. The smart sensor features a Kinetis KL05Z with three current sense amplifiers. It allows measurement currents in three ranges. Four assembly options allow measurement of rail voltages 0-3.3V (two overall current ranges), 0-6.6V, and 12V. It connects to an aggregator, which powers, controls and aggregates data from a number of smart sensor boards. One of the biggest improvements over the older dual-range measurement system is that the on-sensor microcontroller allows near-simultaneous measurement of all instrumented rails on a board. The dual range profiler can only make one measurement at a time.  These are intended to be used with a microncontroller board to act as a trigger and data aggregator. This aggregator could also be used to reprogram the sensors.  The series resistance added by the smart sensor when in run mode (highest current range) is under 11 milliOhms as measured with 4-point probes and a Keysight B2902B SMU.  A "power oscilloscope" can be made by triggering measurements at regular intervals and presenting the results graphically.... Schematic: Board Layout, Top: Board Layout, Bottom: Here's a photo of two with a nickel is included to show scale. The board measures about 0.5 by 1.3 inches. Connections: The smart sensor header connections are: 5V: powers the 3.3V regulator, which in turn powers everything else on the sensor board 12V: all the gates of all the switching FETs are pulled pulled up to 12V GND: ground connection SCL/TX: I2C clock line  SDA/RX:  I2C data line  SWD_CLK:  line for triggering smart sensors to make measurements RESET_B:  line for resetting the smart sensor board SWD_IO: select line for the smart sensor Theory of operation: Three shunts and current sense amplifiers are used to measure current in three ranges. One shunt/sense amp pair has a 0.002 Ω shunt integrated into the IC package (U1, INA250). The other two sense amps (U2 and U3, INA212) require an external shunt.  FETs Q1, Q2,  and Q3 are used to switch the two lower range shunt/sense amp pairs in and out of circuit. In normal run operation (highest current range), Q1 (FDMC012N03, with Rds(on) under 1.5m Ω ) is turned on, which shorts leaves only U1 in circuit. FETs Q4, Q5 and Q6 translate the voltages to 3.3V so that GPIO on U4 (MCU KL05Z) can control them.  Rail voltage measurement is facilitated via resistors R3, R4, and R12 and Q7. Not all of these are populated in every assembly option. For measuring rail voltages 0-3.3V, R12 is populated. To measure 0-6.6V, R3, R4,and Q7 are populated. When turned on Q7 enables the voltage divider. All of the assembly option population info can be found in the schematic (attached). Regulator U5 (AP2210N) provides the 3.3V supply for all of the components on the board. This 1% tolerance regulator is used to provide a good reference for the ADC in U4.  Microcontroller U4 detects the assembly population option of the board via resistors R9, R10, and R11 so that the same application code can be used across all variations of the sensor boards. GPIO control the FETs and four ADC channels are used to measure the sense amplifier outputs and the rail voltage. Having a microcontroller on the sensor board allows the user to do extra credit things like count coulombs as well as allowing all similarly instrumented rails to measure at the same time via trigger line SWD_CLK. Data communication can be via I2C or UART, since these two pins can do both.  But if multiple sensor boards are to be used with an aggregator, communication needs to be over I2C. Application Code: The latest application code for the KL05Z on the smart sensor resides here: https://os.mbed.com/users/r14793/code/30847-SMRTSNSR-KL05Z/. The latest binary is attached below. In order to re-flash a smart sensor, the modification detailed in the aggregator page needs to be made. Once the modification is completed, leave the aggregator unpowered while pluging the SWD debugger into J5 and the smart sensor to be programmed into JP15. Very old UART-based application code for the KL05Z, built in the on-line MBED compiler (note that it requires the modified mbed library for internal oscillator). This code was used while testing the first smart sensor prototypes. It has since been abandoned. It's published here in the event that a user wants to use a single sensor plugged into JP15 with UART breakout connector J6. /****************************************************************************** * * MIT License (https://spdx.org/licenses/MIT.html) * Copyright 2017-2018 NXP * * MBED code for KL05Z-based "smart" current sensor board, basic testing * of functions via UART (connected via FRDM board and OpenSDA USB virtual * COM port). * * Eventual goal is to have each smart sensor communicate over I2C to an * aggregator board (FRDM board with a custom shield), allowing 1-10 power * supply rails to be instrumented. Extra credit effort is to support * sensors and aggregator with sigrok... * * Because there is no crystal on the board, need to edit source mbed-dev library * to use internal oscillator with pound-define: * change to "#define CLOCK_SETUP 0" in file: * mbed-dev/targets/TARGET_Freescale/TARGET_KLXX/TARGET_KL05Z/device/system_MKL05Z4.c * ******************************************************************************/ #include "mbed.h" // These will be GPIO for programming I2C address... // not yet implemented, using as test pins... DigitalOut addr0 ( PTA3 ) ; DigitalOut addr1 ( PTA4 ) ; DigitalOut addr2 ( PTA5 ) ; DigitalOut addr3 ( PTA6 ) ; // configure pins for measurements... // analog inputs from sense amps and rail voltage divider... AnalogIn HIGH_ADC ( PTB10 ) ; AnalogIn VRAIL_ADC ( PTB11 ) ; AnalogIn LOW1_ADC ( PTA9 ) ; AnalogIn LOW2_ADC ( PTA8 ) ; // outputs which control switching FETs... DigitalOut VRAIL_MEAS ( PTA7 ) ; // turns on Q7, connecting voltage divider DigitalOut LOW_ENABLE ( PTB0 ) ; // turns on Q4, turning off Q1, enabling low measurement DigitalOut LOW1 ( PTB2 ) ; // turns on Q5, turning off Q2, disconnecting shunt R1 DigitalOut LOW2 ( PTB1 ) ; // turns on Q6, turning off Q3, disconnecting shunt R2 // input used for triggering measurement... // will eventually need to be set up as an interrupt so it minimizes delay before measurement InterruptIn trigger ( PTA0 ) ; // use as a trigger to make measurement... // PTB3/4 can be used as UART or I2C... // For easier development with one smart sensor, we are using UART here... Serial uart ( PTB3 , PTB4 ) ; // tx, rx long int count = 0 ; int n = 25 ; // global number of averages for each measurement int i , temp ; bool repeat = true ; // flag indicating whether measurements should repeat or not const float vref = 3.3 ; // set vref for use in calculations... float delay = 0.25 ; // default delay between measurement bool gui = false ; // flag for controlling human vs machine readable output bool statistics = false ; // flag for outputting min and max along with average (GUI mode only) void enableHighRange ( ) { LOW_ENABLE = 0 ; // short both low current shunts, close Q1 wait_us ( 5 ) ; // delay for FET to settle... (make before break) LOW1 = 0 ; LOW2 = 0 ; // connect both shunts to make lower series resistance VRAIL_MEAS = 0 ; // disconnect rail voltage divider wait_us ( 250 ) ; // wait for B2902A settling... } void enableLow1Range ( ) { LOW1 = 0 ; LOW2 = 1 ; // disconnect LOW2 shunt so LOW1 can measure wait_us ( 5 ) ; // delay for FET to settle... (make before break) LOW_ENABLE = 1 ; // unshort low current shunts, open Q1 VRAIL_MEAS = 0 ; // disconnect rail voltage divider wait_us ( 250 ) ; // wait for B2902A settling... } void enableLow2Range ( ) { LOW1 = 1 ; LOW2 = 0 ; // disconnect LOW1 shunt so LOW2 can measure wait_us ( 5 ) ; // delay for FET to settle... (make before break) LOW_ENABLE = 1 ; // unshort low current shunts, open Q1 VRAIL_MEAS = 0 ; // disconnect rail voltage divider wait_us ( 500 ) ; // wait for B2902A settling... } void enableRailV ( ) { VRAIL_MEAS = 1 ; // turn on Q7, to enable R3-R4 voltage divider wait_us ( 125 ) ; // wait for divider to settle... // Compensation cap can be used to make // voltage at ADC a "square wave" but it is // rail voltage and FET dependent. Cap will // need tuning if this wait time is to be // removed/reduced. // // So, as it turns out, this settling time and // compensation capacitance are voltage dependent // because of the depletion region changes in the // FET. Reminiscent of grad school and DLTS. // Gotta love device physics... } void disableRailV ( ) { VRAIL_MEAS = 0 ; // turn off Q7, disabling R3-R4 voltage divider } // this function measures current, autoranging as necessary // to get the best measurement... void measureAuto ( ) { Timer t ; float itemp ; float tempI = 0 ; float imin = 1.0 ; // used to keep track of the minimum... float imax = 0 ; // used to keep track of the maximum... t . start ( ) ; // use timer to see how long things take... enableHighRange ( ) ; // this should already be the case, but do it anyway... for ( i = 0 ; i < n ; i ++ ) { itemp = HIGH_ADC ; // read HIGH range sense amp output if ( statistics && itemp > imax ) imax = itemp ; // update max if necessary if ( statistics && itemp < imin ) imin = itemp ; // update min if necessary tempI + = itemp ; // add current sample to running sum } tempI = tempI / n * vref / 0.8 ; // compute average we just took... if ( gui ) uart . printf ( "=> %5.3f " , tempI ) ; if ( statistics && gui ) uart . printf ( "[%5.3f/%5.3f] " , imin * vref / 0.8 , imax * vref / 0.8 ) ; // if current is below this threshold, use LOW1 to measure... if ( tempI < 0.060 ) { if ( ! gui ) uart . printf ( "... too Low: %f A, switching to low1 ==>\r\n" , tempI ) ; tempI = 0 ; enableLow1Range ( ) ; // change FETs to enable LOW1 measurement... imin = 1.0 ; imax = 0 ; for ( i = 0 ; i < n ; i ++ ) { itemp = LOW1_ADC ; // read LOW1 sense amp output if ( statistics && itemp > imax ) imax = itemp ; // update max if necessary if ( statistics && itemp < imin ) imin = itemp ; // update min if necessary tempI + = itemp ; // add current sample to running sum } tempI = tempI / n * vref / 0.05 / 1000 ; // compute average we just took... if ( gui ) uart . printf ( "%6.4f " , tempI ) ; if ( statistics && gui ) uart . printf ( "[%6.4f/%6.4f] " , imin * vref / 0.05 / 1000 , imax * vref / 0.05 / 1000 ) ; // if current is below this threshold, use LOW2 to measure... if ( tempI < 0.0009 ) { if ( ! gui ) uart . printf ( "... too Low: %f A, switching to low2 ==>\r\n" , tempI ) ; tempI = 0 ; enableLow2Range ( ) ; // change FETs to enable LOW1 measurement... imin = 1.0 ; imax = 0 ; for ( i = 0 ; i < n ; i ++ ) { itemp = LOW2_ADC ; // read LOW2 sense amp output if ( statistics && itemp > imax ) imax = itemp ; // update max if necessary if ( statistics && itemp < imin ) imin = itemp ; // update min if necessary tempI + = itemp ; // add current sample to running sum } tempI = tempI / n * vref / 2 / 1000 ; // compute average we just took... if ( gui ) uart . printf ( "%8.6f " , tempI ) ; if ( statistics && gui ) uart . printf ( "[%8.6f/%8.6f] " , imin * vref / 2 / 1000 , imax * vref / 2 / 1000 ) ; } } t . stop ( ) ; // stop the timer to see how long it took do do this... enableHighRange ( ) ; if ( ! gui ) uart . printf ( "\r\nCurrent = %f A Current Measure Time = %f sec\r\n" , tempI , t . read ( ) ) ; } // the autoranging should really be done with functions that return values, as should the // functions below... This would make for shorter and more elegant code, but the author // is a bit of a pasta programmer... void measureHigh ( ) { float highI = 0 ; enableHighRange ( ) ; for ( i = 0 ; i < n ; i ++ ) { highI + = HIGH_ADC ; } highI = highI / n ; uart . printf ( "HIghI = %f A\r\n" , vref * highI / 0.8 ) ; } void measureLow1 ( ) { float low1I = 0 ; enableLow1Range ( ) ; for ( i = 0 ; i < n ; i ++ ) { low1I + = LOW1_ADC ; } enableHighRange ( ) ; low1I = low1I / n ; uart . printf ( "low1I = %f A\r\n" , vref * low1I / 0.05 / 1000 ) ; } void measureLow2 ( ) { float low2I = 0 ; enableLow2Range ( ) ; for ( i = 0 ; i < n ; i ++ ) { low2I + = LOW2_ADC ; } enableHighRange ( ) ; low2I = low2I / n ; uart . printf ( "low2I = %f A\r\n" , vref * low2I / 2 / 1000 ) ; } // measure the rail voltage, default being with // a divide by 2 resistor divider // It has to be switched out when not in use or it will // add to the measured current, at least in the low ranges... void measureRailV ( ) { float railv = 0 ; float mult = vref * 2 ; // since divide by 2, we can measure up to 6.6V... float vmin = 5 ; float vmax = 0 ; float vtemp ; enableRailV ( ) ; // switch FETs so divider is connected... for ( i = 0 ; i < n ; i ++ ) { vtemp = VRAIL_ADC ; // read voltage at divider output... if ( statistics && vtemp > vmax ) vmax = vtemp ; // update max if necessary if ( statistics && vtemp < vmin ) vmin = vtemp ; // update min if necessary railv + = vtemp ; // add current sample to running sum } disableRailV ( ) ; // now disconnect the voltage divider railv = railv / n ; // compute average (note this is in normalized ADC [0..1]) // Convert to voltage by multiplying by "mult" if ( ! gui ) uart . printf ( "RailV = %5.3f V " , mult * railv ) ; if ( gui ) uart . printf ( "%5.3f " , mult * railv ) ; if ( statistics && gui ) uart . printf ( "[%5.3f/%5.3f] " , mult * vmin , mult * vmax ) ; uart . printf ( "\r\n" ) ; } // not sure how useful this function is... void measureAll ( ) { measureHigh ( ) ; measureLow1 ( ) ; measureLow2 ( ) ; measureRailV ( ) ; } // test function to see if trigger pin is being hit... // intended for use later to do timed triggering of measurements... void triggerIn ( ) { uart . printf ( "You're triggering me! \r\n" ) ; measureAll ( ) ; } // main... int main ( ) { // set up basic conditions... Timer m ; uart . baud ( 115200 ) ; enableHighRange ( ) ; // default state - only HIGH sense amp in circuit, no divider // signal that we're alive... uart . printf ( "Hello World!\r\n" ) ; // configure the trigger interrupt... trigger . rise ( & triggerIn ) ; while ( true ) { count ++ ; wait ( delay ) ; if ( repeat ) { // if repeat flag is set, keep making measurements... m . reset ( ) ; // reset and start timer... m . start ( ) ; measureAuto ( ) ; // measuring current using auto-ranging... measureRailV ( ) ; // measure rail voltage... m . stop ( ) ; // stop the timer. if ( ! gui ) uart . printf ( " Total Measure Time = %f sec" , m . read ( ) ) ; if ( ! gui ) uart . printf ( "\r\n\r\n" ) ; } // see if there are any characters in the receive buffer... // this is how we change things on the fly... // Commands (single keystroke... it's easier) // t = one shot automeasure // v = measure volt // h = one shot high measure // k = one shot LOW1 measure // l = one shot LOW2 measure (letter l) // r = toggle repeat // R = turn off repeat // + = faster repeat rate // - = slower repeat rate // = = set repeat rate to 0.25 sec // g = use human readable text output // G = use compressed text format for GUI // s = turn statistics output off // S = turn statistics output on (only in GUI mode) // n = decrease number of averages for each measurement // N = increase number of averages for each measurement // // these were for testing FET switching... // 1 = LOW_ENABLE = 0 (the number 1) // 2 = LOW1 = 0 // 3 = LOW2 = 0 // 4 = VRAIL_MEAS = 0 // ! = LOW_ENABLE = 1 // @ = LOW1 = 1 // # = LOW2 = 1 // $ = VRAIL_MEAS = 1 if ( uart . readable ( ) ) { temp = uart . getc ( ) ; if ( temp == ( int ) 't' ) { if ( ! gui ) uart . printf ( "Keyboard trigger: " ) ; measureAuto ( ) ; measureRailV ( ) ; //measureAll(); } if ( temp == ( int ) 'v' ) { uart . printf ( "Keyboard trigger: " ) ; measureRailV ( ) ; } if ( temp == ( int ) 'h' ) { uart . printf ( "Keyboard trigger: " ) ; measureHigh ( ) ; } if ( temp == ( int ) 'k' ) { uart . printf ( "Keyboard trigger: " ) ; measureLow1 ( ) ; } if ( temp == ( int ) 'l' ) { uart . printf ( "Keyboard trigger: " ) ; measureLow2 ( ) ; } if ( temp == ( int ) '1' ) { LOW_ENABLE = 0 ; uart . printf ( "Keyboard trigger: LowEnable = %d\r\n" , 0 ) ; } if ( temp == ( int ) '2' ) { LOW1 = 0 ; uart . printf ( "Keyboard trigger: LOW1 = %d\r\n" , 0 ) ; } if ( temp == ( int ) '3' ) { LOW2 = 0 ; uart . printf ( "Keyboard trigger: LOW2 = %d\r\n" , 0 ) ; } if ( temp == ( int ) '4' ) { VRAIL_MEAS = 0 ; uart . printf ( "Keyboard trigger: VRAILMEAS = %d\r\n" , 0 ) ; } if ( temp == ( int ) '!' ) { LOW_ENABLE = 1 ; uart . printf ( "Keyboard trigger: LowEnable = %d\r\n" , 1 ) ; } if ( temp == ( int ) '@' ) { LOW1 = 1 ; uart . printf ( "Keyboard trigger: LOW1 = %d\r\n" , 1 ) ; } if ( temp == ( int ) '#' ) { LOW2 = 1 ; uart . printf ( "Keyboard trigger: LOW2 = %d\r\n" , 1 ) ; } if ( temp == ( int ) '$' ) { VRAIL_MEAS = 1 ; uart . printf ( "Keyboard trigger: VRAILMEAS = %d\r\n" , 1 ) ; } if ( temp == ( int ) 'r' ) { repeat = ! repeat ; uart . printf ( "Keyboard trigger: repeat toggle: %s \r\n" , repeat ? "true" : "false" ) ; } if ( temp == ( int ) 'R' ) repeat = false ; if ( temp == ( int ) '+' ) { delay - = 0.05 ; if ( delay < 0.05 ) delay = 0.05 ; } if ( temp == ( int ) '-' ) { delay + = 0.05 ; if ( delay > 1 ) delay = 1 ; } if ( temp == ( int ) '=' ) delay = 0.25 ; if ( temp == ( int ) 'g' ) gui = false ; if ( temp == ( int ) 'G' ) gui = true ; if ( temp == ( int ) 's' ) statistics = false ; if ( temp == ( int ) 'S' ) statistics = true ; if ( temp == ( int ) 'n' ) { n - = 25 ; if ( n < 25 ) n = 25 ; } if ( temp == ( int ) 'N' ) { n + = 25 ; if ( n > 1000 ) n = 1000 ; } if ( temp == ( int ) 'N' || temp == ( int ) 'n' ) uart . printf ( "/r/n/r/n Averages = %d \r\n\r\b" , n ) ; } } } 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‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍ ‍
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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 attached file xenomai-4.14.35-1.1.0-arm-20200818.tgz (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
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[中文翻译版] 见附件   原文链接: https://community.nxp.com/docs/DOC-344336 
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[中文翻译版] 见附件   原文链接: https://community.nxp.com/docs/DOC-344462 
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i.MX6UL/ULL extend uart port and integrate SIP I2C device. Contents 1 硬件设计说明 ............................................................. 2 硬件框图 ........................................................................ 2 硬件模块设计 ................................................................. 4 IOMUX 表 ....................................................................... 8 2 编译环境搭建 ............................................................. 8 编译环境文档及镜像下载。 ............................................ 8 编译环境搭建 ............................................................... 11 3 移植BSP 到扩展串口板 ........................................... 15 Uboot 中支持新的DTB ................................................ 15 Uboot 中调试串口改成UART6 ..................................... 16 去除掉无用的驱动及其IOMUX .................................... 18 增加i.MX6UL/ULL 本身串口支持 ................................. 18 增加GPIO 输出支持(GPIO_LED) ............................ 26 增加GPIO 输入支持(GPIO_KEY) ........................... 30 增加PWM支持 ............................................................ 34 增加i.MX6UL 本身ADC 支持 ....................................... 38 修改网口驱动仅支持一个网口 ...................................... 41 增加NXP PCF8591 I2C 转ADC 芯片支持 ................... 44 增加NXP PCA9555A I2C 转GPIO 芯片支持(rework 支持) 47 增加NXP PCT2075 I2C 温度传感器芯片支持(rework 支持) 55 增加NXP PCF8563 I2C RTC 支持(rework 支持) ......... 58 增加NXP PCA9632 I2C LED控制器芯片支持(rework 支持) 65 增加CH438 EIM 转串口芯片支持(delay) ..................... 70
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In recent months, some i.MX6ULL users try to add google chromium to Linux BSP L4.1.15 managed by yocto project 2.1 (krogoth), but failed.  One of A customers project also encoutered the same issues, their engineers submitted case to us asking for help. Then a compilation test for the customer was done,  there really exist some errors during compilation. The follwing contents show how to compile it and handle issues. ---System Configurations Hardware: notebook, i7 4-cores, 16GB DDR4 Software: windows 7/10, VMware Player 14.0, USB3.1 SSD Step1: # cd ~/fsl-release-bsp # DISTRO=fsl-imx-x11 MACHINE=imx6ull14x14evk source fsl-setup-release.sh -b build-x11 # gedit ./conf/local.conf          Add lines below, just like descriptions of chromium in i.MX_Yocto_User’s_Guide.pdf …… CORE_IMAGE_EXTRA_INSTALL += "chromium libexif" LICENSE_FLAGS_WHITELIST="commercial" …… [Comment] Above methord has been described in i.MX_Yocto_User's_Guide.pdf . # bitbake chromium -c fetch           Begin to download chromium package :                    If you feel it’s the speed of download is too slow, you can copy the following link to explorer, and download the file directly: http://gsdview.appspot.com/chromium-browser-official/chromium-48.0.2548.0.tar.xz Then copy the file to ~/fsl-release-bsp/downloads. And create a.done file by touch command in the directory. # cd ~/fsl-release-bsp/downloads # touch chromium-48.0.2548.0.tar.xz.done          Empty file is OK, not need any contents in the file. Step 2          Begin to compile chromium: # cd ~/fsl-release-bsp/downloads/build-x11 # bitbake chromium -c compile          From the following picture, total tasks are 1636 Errors 1 during compilation Error : ERROR: cups-2.1.3-r0 do_fetch: Fetcher failure: Fetch command failed with exit code 4, output: failed: Connection timed out. Read error (Connection timed out) in headers.   ERROR: cups-2.1.3-r0 do_fetch: Function failed: Fetcher failure for URL: 'https://www.cups.org/software/2.1.3/cups-2.1.3-source.tar.bz2'. Unable to fetch URL from any source. ERROR: Logfile of failure stored in: /home/weidong/fsl-release-bsp-415-200/build-x11/tmp/work/cortexa7hf-neon-poky-linux-gnueabi/cups/2.1.3-r0/temp/log.do_fetch.33362 ERROR: Task 111 (/home/weidong/fsl-release-bsp-415-200/sources/poky/meta/recipes-extended/cups/cups_2.1.3.bb, do_fetch) failed with exit code '1' Handle it: Download the file through explorer: https://www.cups.org/software/2.1.3/cups-2.1.3-source.tar.bz2 Then copy it to ~/fsl-release-bsp/downloads, and create cups-2.1.3-source.tar.bz2.done Continue: # bitbake chromium -c compile Errors 2 during compilation Handle it : copy the fsimx6ul-chromium.patch to your main yocto directory (same directory were you can find yocto-download). Switch to this directory and apply the patch with the following command: patch -p1 < fsimx6ul-chromium.patch Compile your yocto rootfs again [Comment] The solution is from the link: https://forum.fs-net.de/index.php?thread/4352-yocto-build-chromium-browser/ fsimx6ul-chromium.patchis provided by F&S Support Team Continue: # bitbake chromium -c compile Successfully. Step 3 Compiling full image # bitbake fsl-image-gui          When chromium compilation is done, we can begin to comipile rootfs(fsl-image-gui)          Then no errors occurred. Compiled BSP successfully.   Then we check if chromium has been included in rootfs. # cd ~/fsl-release-bsp/build-x11/tmp/deploy/images/imx6ull14x14evk [Comment] (1) fsl-image-gui-imx6ull14x14evk-20200425220751.rootfs.tar.bz2          The file is rootfs without u-boot/device tree/linux kernel. (2) fsl-image-gui-imx6ull14x14evk-20200425220751.rootfs.sdcard          The file is full image including u-boot/device tree/kernel/rootfs Here is the links among files:          Now we check if rootfs have included chromium, create a temp directory in ~/ and copy rootffs to the temp directory # mkdir ~/temp # cp ./fsl-image-gui-imx6ull14x14evk-20200425220751.rootfs.tar.bz2 ~/temp          Then decompress it. # cd ~/temp # tar -jxvf fsl-image-gui-imx6ull14x14evk-20200425220751.rootfs.tar.bz2 # cd usr/bin/chromium/ # ls Successfully. NXP TIC team Weidog Sun 2020/05/01
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[中文翻译版] 见附件   原文链接: https://community.nxp.com/docs/DOC-342877 
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[中文翻译版] 见附件   原文链接: https://community.nxp.com/docs/DOC-342833 
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L5.4.3_1.0.0 release is now available on  IMX_SW  landing page: BSP Updates and Releases -> Linux ->Linux L5.4.3_1.0.0. Documentation -> Linux -> Linux 5.4.3_1.0.0 Documentation Files available: # Name Description 1 imx-yocto-LF_L5.4.3_1.0.0.zip i.MX L5.4.3_1.0.0 for Linux BSP Documentation.  Includes Release Notes, User Guide. 2 LF_v5.4.y-1.0.0_images_MX6QPDLSOLOX.zip i.MX 6QuadPlus, i.MX 6Quad, i.MX 6DualLite, i.MX 6Solox Linux Binary Demo Files 3 LF_v5.4.y-1.0.0_images_MX6SLLEVK.zip i.MX 6SLL EVK Linux Binary Demo Files 4 LF_v5.4.y-1.0.0_images_MX6UL7D.zip i.MX 6UltraLite EVK, 7Dual SABRESD, 6ULL EVK Linux Binary Demo Files 5 LF_v5.4.y-1.0.0_images_MX7ULPEVK.zip i.MX 7ULP EVK Linux Binary Demo Files  6 LF_v5.4.y-1.0.0_images_MX8MMEVK.zip i.MX 8M Mini EVK Linux Binary Demo Files  7 LF_v5.4.y-1.0.0_images_MX8MNEVK.zip i.MX 8M Nano EVK Linux Binary Demo Files  8 LF_v5.4.y-1.0.0_images_MX8MQEVK.zip i.MX 8M Quad EVK Linux Binary Demo files 9 LF_v5.4.y-1.0.0_images_MX8QMMEK.zip i.MX 8QMax MEK Linux Binary Demo files 10 LF_v5.4.y-1.0.0_images_MX8QXPMEK.zip i.MX 8QXPlus MEK Linux Binary Demo files 11 imx-scfw-porting-kit-1.2.10.1.tar.gz System Controller Firmware (SCFW) porting kit v1.2.10.1 for L5.4.3_1.0.0   Target board: MX 8 Series MX 8QuadXPlus MEK Board MX 8QuadMax MEK Board MX 8M Quad EVK Board MX 8M Mini EVK Board MX 8M Nano EVK Board MX 7 Series MX 7Dual SABRE-SD Board MX 7ULP EVK Board MX 6 Series MX 6QuadPlus SABRE-SD and SABRE-AI Boards MX 6Quad SABRE-SD and SABRE-AI Boards MX 6DualLite SDP SABRE-SD and SABRE-AI Boards MX 6SoloX SABRE-SD MX 6UltraLite EVK Board MX 6ULL EVK Board MX 6ULZ EVK Board MX 6SLL EVK Board   What’s New/Features: Please consult the Release Notes.   Known Issues: For known issues and more details please consult the Release Notes.   More information on changes of Yocto, see: README:  https://source.codeaurora.org/external/imx/imx-manifest/tree/README?h=imx-linux-zeus ChangeLog:  https://source.codeaurora.org/external/imx/imx-manifest/tree/ChangeLog?h=imx-linux-zeus      
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[中文翻译版] 见附件   原文链接: i.MX Create Android SDCard Mirror 
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[中文翻译版] 见附件   原文链接: https://community.nxp.com/docs/DOC-343079 
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[中文翻译版] 见附件   原文链接: https://community.nxp.com/docs/DOC-343116 
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[中文翻译版] 见附件   原文链接: https://community.nxp.com/docs/DOC-343344 
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