The IGEP X-loader
From IGEP - ISEE Wiki
Contents
- 1 Summary
- 2 Why IGEP-Xloader
- 3 Features and Limitations
- 4 Pre-Compiled Binaries
- 5 Build Procedure
- 6 BOOT
- 7 FAQ
- 7.1 How I can boot from NFS?
- 7.2 How I can change the assigned kernel memory?
- 7.3 How I can add more kernel variables?
- 7.4 How I can modify my MAC address?
- 7.5 How I can boot my board using ubi root filesystem?
- 7.6 How I can boot my board using a RAM disk?
- 7.7 Can I change the Processor frecuency?
- 7.8 How I can boot downloading the kernel using wget?
- 7.9 My board not boot and I don't know what to do ...
- 7.10 How I can upgrade my old kernel?
- 8 6 Contribution & Support & Bugs Report
Summary
X-Loader, an initial program loader for Embedded boards based on OMAP processors.
Access to the latest version (release 2.5.0-2) here and read the ISEE_Readme.txt for get the latest release information.
Why IGEP-Xloader
Some important reasons exist for using this bootloader on IGEP boards.
Security
This is one of the most important reasons why we develop this new IGEP X-loader. you will Probably know that flash devices get new bad memory blocks with normal usage that can make unusable or can damange the software residing inside the flash (ex: upgrading the software, copying a new kernel ... ), in these cases your board won't be usable anymore if you don't use a right nand filesystem that insures data integrity. Using the old schema we've 4 important partitions on flash without any protection, x-loader, u-boot, u-boot enviroment and kernel.
IGEP X-loader resolves this situation as the configuration and kernel files reside inside a jffs2 partition.
Maintenance
With the old schema 3 different software existed (x-loader, u-boot, kernel) that did exactly the same job, so you had to reconfigure the board, increasing the complexity of maintenance for the board system and provide a major bug source because we had to assure that all software was aligned with all changes. Also, from a second point of view, we did the job three times so the boot process was more complex and slow.
Easy to use
With this new approach use the software it's more easy to use, if you've the boot information stored inside a jffs2 partition you can use the linux kernel to access it directly without the use of any flash tool to modify the software (ex: using nandwrite it's to risky due to its inability to guarantee data integrity over the Nand Flash memory).
Upgrade faster and easy
Upgradint to a new kernel it's easier and faster, you only need to copy the new kernel inside the boot partition, copy your new igep.ini inside and reboot the board with all security.
Features and Limitations
Improvements & Modifications
- Added malloc/free functionality.
- Added mtd framework and onenand support, removed the old onenand drivers.
- Added fs jffs2 support using mtd & onenand support (Read Only).
- Added crc32 and zlib.
- Jffs2 zlib compression support (Read Only).
- Dual boot mmc & onenand with mmc highest priority.
- Added Linux kernel boot directly (Support for 2.6.22 and highest version kernels)
- Linux kernel supported images: vmlinuz, bzImage and zImage.
- Support for loading Linux Ram disk (EXPERIMENTAL)
- Added "ini" files parser.
- The configuration resides in a plain txt (ini format file).
- Support Windows & Linux formating ini files.
- boot from mmc, onenand, or mix with mmc highest priority.
- Added codeblocks project and compilation rules.
- Added support for vfat32 extra names.
- Configure TPS65950 voltage to 1.35V if it's used a DM3730 processor.
- Added new parameter MachineID in kernel tag file, with it you can
- - configure the kernel board ID setup
- Added new parameter buddy for kernels 2.6.35.y and 2.6.37.y
- Optimize some LPDDR Memory configuration values
- Removed some OneNand Debug information
- Removed some FAT incorrect warnings
- Added Support Initial Ram disk
- Reconfigure Makefile options
- Support Kernels 2.6.35, 2.6.37, 3.6.4
- Added support for boot ARM binary files (such u-boot or QNX kernel)
- Support for Numonyx, Micron and hynix POP Memories.
- Memory autodetection.
- Added GPTimer functionality.
- Support Numonyx, Micron and hynix memories.
- DMA Copy support
- Omtimized memcpy and memset functions.
- DSS Video driver.
- Support ISEE toolchain yocto 1.2 based.
Limitations
- The ini configuration file it's limited to max size: 16 KiB
- Kernel Command line parameters it's limited to: 4 KiB
- Malloc it's hardcode limited to 32 MiB.
- Video is limited to 1024 x 768 x 16 bits.
- Video Memory is limited to 1280 x 720 x 32 bits.
TODO
- Remove compilation warnings.
- System Rescue.
- Improve boot selection and priority.
- Remove unused code.
STATUS
- Support:
- IGEPv2 DM3730
- IGEPv2 OMAP3530
- IGEP COM MODULE DM3730
- IGEP COM PROTON DM3730
- IGEP COM MODULE AM3703
VERSION CHANGES
[2.1.0-1] This version only can be build with gcc linaro 4.5.2 other compilers be not supported.
[2.1.0-1] Removed some uncontrolled "printf" with incorrect information.
[2.1.0-1] Modified some code under __DEBUG__ option.
[2.1.0-1] Added Support for TPS65950-A3 initialization at 1.35V
[2.1.0-1] Added support for IGEP Module 0030
[2.1.0-1] Added support dynamic Machine ID selection (same xloader boot IGEPv2 & IGEP Module)
[2.1.0-2] ARM Compilation bug resolved
[2.1.0-3] Update SDRAM structure initialization
[2.1.0-3] Added support for Initial RAM disk
[2.1.0-3] Updated Initial RAM disk destination address
[2.2.0-1] Update Makefile structure
[2.2.0-1] Downgrade the boot processor speed
[2.3.0-1] Add NAND flash devices and Micron MT29CXGXXMAXX memories support
[2.3.0-2] Add Hynix NAND memorie and IGEP0032 support
[2.3.0-2] Added lzo compression schema.
[2.3.0-3] Add Support for execute ARM binaries [2.3.0-3] Bug Fixes related to I and D Cache
[2.4.0-1] Added Memory test feature
[2.4.0-1] Added some boot information
[2.4.0-1] New read_nand_cache function optimized for load from NAND
[2.4.0-1] BUG resolved: Refresh Setup in Micron & Hynix Memories
[2.4.0-1] BUG resolved: Reset Memory controller after initialize Malloc function
[2.4.0-1] BUG resolved: Resolve problems updating the flash content under jffs2
[2.4.0-2] Resolved Memory Autodetection
[2.4.0-2] Better hang board led control
[2.4.0-2] New read_nand_cache function optimized for load from OneNand
[2.4.0-2] Added Hw GPtimer functionality
[2.5.0-1] Added System DMA driver.
[2.5.0-1] Added optimized memcpy & memset functions.
[2.5.0-1] Improved boot speed.
[2.5.0-1] Improve NAND driver support.
[2.5.0-1] Auto x-loader.bin.ift and MLO generation.
[2.5.0-1] Added DSS video support.
[2.5.0-2] Fixed System DMA misconfiguration.
[2.5.0-2] Improve GPMC timming setup.
[2.5.0-2] Added DSS igep.ini variables.
[2.5.0-2] Added Support for new memory capacities.
[2.5.0-2] Auto x-loader.bin.ift and MLO generation.
[2.5.0-2] Minor bug fixes.
[2.5.0-3] platform.S: downgrade MPU boot clock from 1GHz to 800 MHz
Pre-Compiled Binaries
Release | Download link | Support |
---|---|---|
2.5.0-2 | igep-x-loader-2.5.0-2.tar.bz2 | All Boards |
2.4.0-2 | igep-x-loader-2.4.0-2.tar.bz2 | All Boards except IGEP COM MODULE AM3703 |
2.1.0-2 | igep-x-loader-2.1.0-2.tar.bz2 | All Boards except IGEP COM MODULE AM3703 |
2.1.0-3 | igep-x-loader-2.1.0-3.tar.bz2 | All Boards except IGEP COM MODULE AM3703 |
2.2.0-1 | igep-x-loader-2.2.0-1.tar.bz2 | All Boards except IGEP COM MODULE AM3703 |
Build Procedure
Build with ISEE SDK Yocto Toolchain 1.2
Download and Install the cross compiler if you not do it before.
Download the toolchain from this link and uncompress it as root in your / directory.
Hint: Remember setup the enviroment before build the source: source /opt/poky/1.2/environment-setup-armv7a-vfp-neon-poky-linux-gnueabi
Download the sources from our git repository
$ git clone git://git.isee.biz/pub/scm/igep-x-loader.git
Get your desired tag / release
git checkout <your_desired_release> -b <your_name_release>
$ git checkout release-2.5.0-2 -b release-2.5.0-2-local
Setup the board build setup
make igep00x0_config
Build the software
make
Sign the binary x-loader (Only versions prior to 2.5.0-x)
You should execute contrib/signGP for sign the xloader.
contrib/signGP x-load.bin The signed x-loader it's named: x-load.bin.ift
Build Native
Download from git repository
$ git clone git://git.isee.biz/pub/scm/igep-x-loader.git
git checkout <your_desired_release> -b <your_name_release>
$ git checkout release-2.5.0-2 -b release-2.5.0-2-local
Configure the board settings
make igep00x0_config
Edit the variable CFLAGS and add the option: -fno-stack-protector CFLAGS := $(CPPFLAGS) -Wall -Wstrict-prototypes -fno-stack-protector
Build
make CROSS_COMPILE=arm-none-linux-gnueabi-
Sign the binary x-loader
You should execute contrib/signGP for sign the xloader.
contrib/signGP x-load.bin The signed x-loader it's named: x-load.bin.ift
BOOT
The IGEP X-Loader must reside in the microSD card or in the Nand Memory.
MMC Boot
Prepare the microsd card
You can follow this howto about how prepare the microsd card or How to boot from MicroSD Card
Get a new microsd card and create two partitions, the first one must be fat16/32 and the second one can be formated in any format type supported by linux kernel.
Copy the files in the first (FAT) partition
In the first partition you must copy in this order:
- x-loader.bin.ift (you must rename this file to MLO before copy it) / This is a signed image using contrib/signGP tool
- x-loader configuration file igep.ini also you can change the configuration file name editing the file: igep00x0.h (#define IGEP_BOOT_CFG_INI_FILE "igep.ini")
- Your desired kernel image.
Load Order:
48 /* Linux Images */ 49 const char* LinuxImageNames [] = { 50 "kparam" /* Use kparam first */ 51 "zImage", /* jffs2 it's case sensitive */ 52 "zimage", /* fat name it's not case sentitive */ 53 "vmlinuz", 54 "bzImage", 55 "bzimage", 56 0, 57 }; or you can set the name for your kernel in the configuration file using the tag: kImageName
Don't use a uImage kernel format (from uboot), only standard kernel formats be supported.
kernel build command example:
$make ARCH=arm CROSS_COMPILE=arm-poky-linux-gnueabi- zImage modules
Second Partition
Copy all your rootfs in this second partition.
Also you can use the linaro 10.11 minimal image download the image and untar (as root) in your microsd card second partition.
Remember install the kernel modules in this partition.
Example:
sudo make ARCH=arm CROSS_COMPILE=arm-poky-linux-gnueabi- modules_install INSTALL_MOD_PATH=[path to your target rootfs]
Nand Boot
Nand Partitions
We've defined 3 partitions on the Nand Memory.
MTD partitions on "omap2-onenand": (a) 0x000000000000-0x000000080000 : "X-Loader" (b) 0x000000080000-0x000000c80000 : "Boot" (c) 0x000000c80000-0x000020000000 : "File System"
X-Loader Partition
- Not fs formated (onenand raw)
- Size: 0x80000 (512 KiB)
- The xloader must be signed before copy it into the flash memory.
You should copy the x-loader in the firsts 4 blocks (first 512 KiB), this is not a formated partition due the ROM not permits boot from a formated partition in flash, you should use flash_eraseall and writeloader for copy x-loader in the first blocks.
Suggested procedure: Sign the x-loader before write it on the flash or microsd card. Sign x-loader: You should execute contrib/signGP for sign the xloader that resides inside the flash memory. contrib/signGP x-load.bin The signed x-loader it's named: x-load.bin.ift Erase and copy the x-loader into the first flash partition (mtd0): $nand_eraseall /dev/mtd0 $writeloader -i <x-loader.bin.ift> -o /dev/mtd0
Boot Partition
- filesystem used jffs2 zlib/lzo compressed filesystem.
- Suggested size: 0xC00000 (12 MiB).
X-Loader only support jffs2 partitions for boot partition.
Create the boot partition:
Suggested procedure: Erase all mtd1 content: $flash_eraseall /dev/mtd1 Create your partition: $mount -t jffs2 /dev/mtdblock1 /mnt
Next uses:
You can mount the partition over your boot directory in the rootfs
$mount -t jffs2 /dev/mtdblock1 /boot
You can use the cp command for copy your kernel and igep.ini configuration file.
$cp igep.ini /boot $cp zImage /boot
Rootfs Partition
- fs (your prefered fs supported by linux, maybe a good choice it should be ubifs)
- Size, all or you can create more partitions if you wish ...
Boot Priority
XLoader first try load from mmc and if it fails then try from OneNand.
MLO (x-loader), igep.ini, zImage from MMC
If all it's present in the mmc it don't try to boot from Onenand.
MLO (x-loader) in MMC, igep.ini and zImage in Onenand.
If only MLO it's provided this one try to load the other information from the Onenand.
It means that XLoader always try to load the information from MMC and if it fails then try to load from OneNand.
Configuration file: igep.ini
This entry in wikipedia can help you how a ini file it's structured.
Inside the sources/scripts directory you can found a igep.ini example file.
The actual XLoader can handle two kind tags:
[kernel] Used for internal XLoader setup.
[kparams] Used for pass the linux kernel parameters.
TAG: [kernel]
1 [kernel] 2 kaddress=0x80008000 3 rdaddress=0x81600000 4 serial.low=00000001 5 serial.high=00000000 6 revision=0001 7 kImageName=zImage-test 8 kRdImageName=rdImage-test 9 MachineID=xxxx Where Machine ID = 2344 for IGEPv2, ID = 2717 for IGEP COM Module, ID = 3203 for IGEP COM PROTON 10 Mode=<kernel> or <binary> 11 dss=<0 or 1> Enable or Disable Video Output 12 dss_color=<0x00FF8000> Write your desired color in hex value 13 dss_bitmap=<filename> Raw display image
Parameter Name | Description | Default Value | Comments |
kaddress | Kernel copy address | 0x80008000 | hex memory address |
rdaddress | Ram Disk location address | 0x81600000 | hex memory address |
serial.low | Serial number (low part) | 0 - 99999999 | numeric |
serial.high | Serial number (high part) | 0 - 99999999 | numeric |
revision | Revision ID | 0 - 9999 | numeric |
kImageName | Kernel, binary image name | N/A | Kernel or binary image name |
kRdImageName | Ramdisk | N/A | Ram Disk image name |
MachineID | Machine ID (kernel ID) | 2717 | 2717 (IGEP COM Module) | 2344 IGEPv2 | 3203 (IGEP COM PROTON) |
Mode | Boot Mode | kernel | kernel=linux kernel / binary=boot binary image |
dss | Enable Video | 0 | 0 = Disable, 1 Enable Video Output |
dss_color | Video Color | 0x00FF8000 | Solid Color |
dss_bitmap | Video Bitmap Image | string | filename with desired image |
TAG: [kparams]
In this tag you can add all kernel parameters that you need, this is only an example:
10 [kparams] 11 console=ttyS2,115200n8 12 ;earlyprintk=serial,ttyS2,115200 13 mem=512M 14 boot_delay=0 15 ;mpurate=800 16 ;loglevel=7 17 omapfb.mode=dvi:1024x768MR-16@60\r 18 smsc911x.mac=0xb2,0xb0,0x14,0xb5,0xcd,0xde\r 19 ;ubi.mtd=2 20 ;root=ubi0:igep0020-rootfs 21 ;rootfstype=ubifs 22 root=/dev/mmcblk0p2 rw rootwait Also remember you can comment any line using ';' or '#' characters.
FAQ
How I can boot from NFS?
Yes, you should add below parameters in the kparams tag:
#smsc911x.mac fix your mac address smsc911x.mac=0xb2,0xb0,0x14,0xb5,0xcd,0xde # IP set you IP settings <local_ip>:<server_ip>:<gateway>:<network_mask>::<interface>: ip=192.168.2.123:192.168.2.105:192.168.2.1:255.255.255.0::eth0: # Set root as nfs root=/dev/nfs # Set your NFS root path as <server_ip>:<rootfs_path> nfsroot=192.168.2.105:/srv/nfs/linaro_minimal
How I can change the assigned kernel memory?
You can use the mem kernel variable as assign your desired kernel memory as:
[kparams] mem=430M
How I can add more kernel variables?
You can add more variables creating a new variable - value pair under kparams tag as:
boot_delay=0
How I can modify my MAC address?
You can assign your desired mac address using the variable smsc911x.mac as:
smsc911x.mac=0xb2,0xb0,0x14,0xb5,0xcd,0xde
How I can boot my board using ubi root filesystem?
You should use these parameters:
ubi.mtd=2 root=ubi0:igep0020-rootfs rootfstype=ubifs
How I can boot my board using a RAM disk?
Use a RAMdisk it's fully supported.
[kernel] rdaddress=0x81600000 kRdImageName=ramdisk.bin [kparams] root=/dev/ram0 rw
Can I change the Processor frecuency?
Yes you can, IGEP X-loader configures the processor to boot at 600 Mhz you can select a different boot speed using the variable mpurate as:
mpurate=800
If you don't force any frequency the linux kernel will put your processor at the maximum speed (ex: DM3730 will run at 1 Ghz)
How I can boot downloading the kernel using wget?
The way for do that it's using one minimal kernel and RAMdisk (ex: using image-core-minimal from poky), the procedure can be more or less:
a) Copy your minimal kernel and your Ramdisk inside the boot partition.
b) Boot Normally from this kernel and Ramdisk, create one script your your desired command such wget http://192.168.15.22/mykernel.bin
c) Execute the script when boot (you can do that adding the script to the init enviroment)
d) if the downloading it's ok then execute the kexec call, first load the kernel and then pass to it your desired parameters.
e) finally boot the new kernel with kexec.
My board not boot and I don't know what to do ...
When you test your IGEP X-loader, igep.ini file and kernel we suggest use a microsd card in front of use directly the flash nand, if your flash not boot copy all files in one microsd card and boot from there. You can check what happens removing some files from your microsd card for example if you wish test if your flashed kernel it's loaded in a right way then remove the kernel from your microsd card (note: use the same kernel name), IGEP X-loader first try load the file from your microsd card but if it's not found then it try to find the file in the flash.
How I can upgrade my old kernel?
Just copy the new one, the most secure way it's copy the new one and at end replace the igep.ini file with your new one.
$ mount -t jffs2 /dev/mtdblock1 /boot $ cp newkernel.bin /boot $ cp igep.ini /boot
Use a different kernel name and you always can boot from your old one.
6 Contribution & Support & Bugs Report
Contributions to this project be welcome and you can send your patches to support@iseebcn.com or you can use the igep forum for it.
You can access to IGEP-x-Loader repository using our git at git.isee.biz
IGEP IRC Channel: http://webchat.freenode.net/?channels=igep
If you have any question, don't ask to ask at the IGEP Community Forum or the IGEP Community Chat |