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This page documents the Linux port to the Nspire calculator. | This page documents the Linux port to the Nspire calculator. There are currently two versions available on the TI-Nspire. All new development will occur on the new kernel however, the legacy kernel is easier to get going. | ||
== | ==Booting== | ||
To have something useful running using Linux on the calculator, a bootloader, kernel and rootfs is needed. | |||
===Bootloader=== | |||
Source code: [https://github.com/tangrs/nspire-linux-loader2 On github] | |||
Nightly builds: None. | |||
Binary: [http://tiplanet.org/nspire-linux-builds/linuxloader2.tns TI-Planet] | |||
The bootloader is run from the Nspire OS to load everything into memory and execute the kernel. | |||
Usage instructions can be found in the [https://github.com/tangrs/nspire-linux-loader2/blob/master/README.md readme] | |||
Copy linuxloader.tns to your calculator and run it. | |||
Valid commands are: | |||
kernel <filename>: Loads a kernel image into memory | |||
initrd <filename>: Loads a ramdisk into memory | |||
dtb <filename>: Loads a DTB image into memory | |||
dump: Prints out the current internal state of the bootloader. Useful for | |||
debugging. | |||
free: Prints out the total amount of memory provided to the bootloader by | |||
the Nspire OS and amounts used by the kernel and ramdisks. | |||
cmdline [str]: Get/set the kernel command line parameters. | |||
mach [id]: Get/set the machine ID that will be provided to Linux upon | |||
booting. Useful for overriding the builtin default value without having to | |||
recompile. | |||
phys [<start> <size>]: Get/set the address and size of physical memory. | |||
Useful for overriding the builtin default value without having to recompile. | |||
rdsize [size]: Get/set the size of the ramdisk that Linux should create on | |||
boot. Leave at 0x0 for the kernel default. | |||
probemem: If this is run on an calculator model that isn't directly | |||
supported by the bootloader, you can use this to try and guess how much memory | |||
the system has. | |||
poke <addr> <value>: Write a word to an arbitrary location in the memory | |||
address space. | |||
peek <addr>: Read a word from an arbitrary location in the memory address | |||
space. | |||
boot: Boot kernel. | |||
The bootloader is also scriptable. Create a text file containing a list of | |||
commands to be executed and change the extension to .ll2.tns, and add the | |||
following line to your /documents/ndless/ndless.cfg.tns file. | |||
ext.ll2=linuxloader2 | |||
Then simply open your script file and the loader will execute all the commands | |||
in it. A sample one could look like this: | |||
kernel linux/zImage.tns | |||
initrd linux/initrd.tns | |||
cmdline root=/dev/ram | |||
boot | |||
This should save a lot of typing everytime you need to boot Linux. | |||
To boot the device tree (newer) kernel, ensure you add a dtb command to load the correct device tree prior to booting. | |||
kernel linux/zImage.tns | |||
initrd linux/initrd.tns | |||
dtb linux/dtb.tns | |||
cmdline root=/dev/ram | |||
boot | |||
====UART==== | |||
You can get serial output on the UART. Remember to add <tt>,115200n8</tt> to the end of your <tt>console=</tt> command line options to keep the baud rate the same as the Nspire OS. | |||
===Kernel=== | |||
Source code: see sections below | |||
Nightly builds: [http://tiplanet.org/nspire-linux-builds/kernel.html TI-Planet] | |||
Please see below sections for the differences between the legacy and newer kernels. | |||
To compile the legacy kernel with default options, first clone the github repo then run: | |||
export ARCH=arm | |||
make nspire_defconfig | |||
make -j4 | |||
cp -v arch/arm/boot/zImage /path/to/folder/zImage.tns | |||
Unfortunately, the newer kernel does not have a defconfig at the moment. You have to enable options manually. Check the nightly builds for example configs you can use. | |||
export ARCH=arm | |||
make menuconfig | |||
make -j4 | |||
make dtbs | |||
cp -v arch/arm/boot/zImage /path/to/folder/zImage.tns | |||
cp -v arch/arm/boot/dts/nspire-*.dtb /path/to/folder/ | |||
===Rootfs=== | |||
Nightly builds: [http://tiplanet.org/nspire-linux-builds/buildroot.html TI-Planet] (WIP) | |||
To have programs actually run on the kernel, you need a root filesystem of some sort containing the userspace programs. | |||
For testing and mucking around, a initrd should be enough. It is possible to build one using [http://buildroot.uclibc.org/ Buildroot]. Otherwise, there are a few on the nightly builds page and the Omnimaga thread. | |||
For a larger root filesystem, you could put a filesystem on a USB drive and add <tt>root=/dev/sdaX</tt> to your kernel command line. You may also need to add <tt>rootdelay=10</tt> to give the USB drive time to initialize. There have also been successes running Arch Linux for ARM and Debian. | |||
==Device tree kernel== | |||
The newer version is a total rewrite of the original code to switch to device trees and has slightly less hardware support (but better USB support). All development in this kernel will go directly to the mainland kernel. The source code can be found at [http://kernel.org kernel.org]. | |||
People interested in using this branch also have to compile the device tree blobs in addition to the kernel by running: | |||
make dtbs | |||
and include it in their bootscripts with: | |||
dtb linux/devicetree.tns | |||
Ensure you are using a version of linuxloader2 with a build date after May 11 2013 (or commits later than 0503ca6) for stable device tree support. If your linuxloader2 does not report a build date on startup, you need to upgrade your copy. You can get an updated copy from the TI-Planet nightly builds site. | |||
===Hardware support=== | |||
===Classic=== | {| | ||
|- | |||
! Hardware !! Classic !! CX !! In mainline !! Notes | |||
|- | |||
| CPU || style="background: green; color: white" | Yes || style="background: green; color: white" | Yes || style="background: green; color: white" | Yes || | |||
|- | |||
| SRAM || style="background: green; color: white" | Yes || style="background: green; color: white" | Yes || style="background: yellow" | No || Matter of adding a few lines to the device tree | |||
|- | |||
| GPIO || style="background: green; color: white" | Yes || style="background: green; color: white" | Yes || style="background: green; color: white" | Yes || | |||
|- | |||
| UART1 || style="background: green; color: white" | Yes || style="background: green; color: white" | Yes || style="background: green; color: white" | Yes || | |||
|- | |||
| I2C || style="background: green; color: white" | Yes || style="background: green; color: white" | Yes || style="background: green; color: white" | WIP || Waiting to be accepted into mainline. Have not received extensive testing. | |||
|- | |||
| Watchdog timer || style="background: yellow" colspan="2" | Yes || style="background: yellow" | Yes || Have not tested. Just enable support for SP805 in the config | |||
|- | |||
| RTC || style="background: yellow" | No || style="background: yellow" | No || style="background: yellow" | No || Should be a matter of adding a few lines to the device tree | |||
|- | |||
| Power management || style="background: red; color: white" | No || style="background: red; color: white" | No || style="background: red; color: white" | No || Difficult to cleanly implement | |||
|- | |||
| Timer 1 || style="background: green; color: white" | Yes || style="background: green; color: white" | Yes || style="background: green; color: white" | Yes || | |||
|- | |||
| Timer 2 || style="background: green; color: white" | Yes || style="background: green; color: white" | Yes || style="background: green; color: white" | Yes || | |||
|- | |||
| Keypad || style="background: green; color: white" colspan="2" | Yes || style="background: green; color: white" | Yes || | |||
|- | |||
| Touchpad || style="background: green; color: white" colspan="2" | Yes || style="background: green; color: white" | WIP || Waiting to be accepted into mainline. Have not received extensive testing. | |||
|- | |||
| LCD Contrast/Backlight || style="background: yellow" | No || style="background: yellow" | No || style="background: yellow" | No || Should be a matter of adding a few lines to the device tree | |||
|- | |||
| LED || style="background: yellow" colspan="2" | WIP || style="background: yellow" | No || Unlocking the LED is already possible | |||
|- | |||
| USB OTG || style="background: green; color: white" colspan="2" | Yes || style="background: green; color: white" | Yes || Everything working include seamless switching between USB host and USB device mode. | |||
|- | |||
| NAND || style="background: yellow" | WIP || style="background: yellow" | WIP || style="background: yellow" | No || Dammit, why does the TI-Nspire have such weird NAND controllers to work with? | |||
|- | |||
| LCD || style="background: green; color: white" colspan="2" | Yes || style="background: green; color: white" | Yes || | |||
|- | |||
| ADC || style="background: yellow" | No || style="background: yellow" | No || style="background: yellow" | No || | |||
|- | |||
| DES encryption/SHA generator || style="background: yellow" | No || style="background: yellow" | No || style="background: yellow" | No || | |||
|- | |||
| Interrupt controller || style="background: green; color: white" | Yes || style="background: green; color: white" | Yes || style="background: green; color: white" | Yes || | |||
|} | |||
===Notes=== | |||
====Enabling USB OTG support==== | |||
USB OTG with seamless switching relies on a few different options in the kernel. Ensure you’ve enabled the following: | |||
* Zevio GPIO driver - CONFIG_GPIO_ZEVIO | |||
* USB NOP transceiver - CONFIG_NOP_USB_XCEIV | |||
* Fixed voltage regulator driver - CONFIG_REGULATOR_FIXED_VOLTAGE | |||
The NOP transceiver is passed onto the Chipidea driver because the TI-Nspire doesn’t need/have a PHY. | |||
The fixed voltage regulator driver is the bridge between the GPIO and Chipidea. It controls 5V output to the USB port. | |||
==Legacy kernel== | |||
This kernel is not being maintained any more. All new development will occur on the new kernel. This kernel is the initial port of Linux. | |||
===Hardware support=== | |||
====Classic==== | |||
{| | {| | ||
|- | |- | ||
Line 38: | Line 223: | ||
| TI-84 Link port || style="background: yellow" | Unknown || style="background: red; color: white" | No || Do we really need this? | | TI-84 Link port || style="background: yellow" | Unknown || style="background: red; color: white" | No || Do we really need this? | ||
|- | |- | ||
| LED || style="background: | | LED || style="background: green; color: white" | Yes || style="background: red; color: white" | No || | ||
|- | |- | ||
| SPI || style="background: green; color: white" | Yes || style="background: red; color: white" | No || | | SPI || style="background: green; color: white" | Yes || style="background: red; color: white" | No || | ||
Line 57: | Line 242: | ||
|} | |} | ||
===CX=== | ====CX==== | ||
{| | {| | ||
Line 93: | Line 278: | ||
| TI-84 Link port || style="background: yellow" | Unknown || style="background: red; color: white" | No || Do we really need this? | | TI-84 Link port || style="background: yellow" | Unknown || style="background: red; color: white" | No || Do we really need this? | ||
|- | |- | ||
| LED || style="background: | | LED || style="background: green; color: white" | Yes || style="background: red; color: white" | No || | ||
|- | |- | ||
| SPI || style="background: green; color: white" | Yes || style="background: red; color: white" | No || | | SPI || style="background: green; color: white" | Yes || style="background: red; color: white" | No || | ||
Line 101: | Line 286: | ||
| USB Host || style="background: green; color: white" | Yes || style="background: yellow" | USB 1.1 || Uses a workaround but limits speed to USB 1.1 | | USB Host || style="background: green; color: white" | Yes || style="background: yellow" | USB 1.1 || Uses a workaround but limits speed to USB 1.1 | ||
|- | |- | ||
| NAND || style="background: green; color: white" | Yes || style="background: yellow" | WIP || Needs a lot of testing. Unstable. | | NAND || style="background: green; color: white" | Yes || style="background: yellow" | WIP || Needs a lot of testing. Unstable. Note - driver for a similar chip is available [https://github.com/Xilinx/linux-xlnx/blob/master/drivers/mtd/nand/zynq_nand.c here] | ||
|- | |- | ||
| LCD || style="background: green; color: white" | Yes || style="background: green; color: white" | Yes || | | LCD || style="background: green; color: white" | Yes || style="background: green; color: white" | Yes || | ||
Line 112: | Line 297: | ||
|} | |} | ||
== | ===Quirks and technical details=== | ||
====SRAM==== | |||
== | |||
When needing to allocate memory from SRAM when developing for the kernel, use the following functions: | When needing to allocate memory from SRAM when developing for the kernel, use the following functions: | ||
Line 203: | Line 306: | ||
void sram_free(dma_addr_t addr, unsigned int size) | void sram_free(dma_addr_t addr, unsigned int size) | ||
=== | ====Keypad==== | ||
The keymaps can be found in <tt>arch/arm/mach-nspire/keypad.c</tt>. Each array element represents one bit in [[Keypads]]. | The keymaps can be found in <tt>arch/arm/mach-nspire/keypad.c</tt>. Each array element represents one bit in [[Keypads]]. | ||
===Touchpad=== | ====Touchpad==== | ||
There are some weird issues with the Touchpad. After booting Linux, the Touchpad doesn't function correctly under Nspire OS and requires entering diags or a few hard resets to get it back to normal. The exact cause is unknown but it is possible that this behavior is caused by the bootloader not correctly resetting Touchpad controller when the device boots up again so the Nspire OS is still using a Linux-configured Touchpad controller. | There are some weird issues with the Touchpad. After booting Linux, the Touchpad doesn't function correctly under Nspire OS and requires entering diags or a few hard resets to get it back to normal. The exact cause is unknown but it is possible that this behavior is caused by the bootloader not correctly resetting Touchpad controller when the device boots up again so the Nspire OS is still using a Linux-configured Touchpad controller. | ||
Line 217: | Line 316: | ||
It has been half solved by having the Touchpad driver reset the controller on a soft reboot. However, this doesn't happen on hard reboots and will still cause the Nspire OS to not function correctly. Whenever possible, perform a soft reboot in Nspire Linux by using Ctrl+Alt(Var)+Delete(Scratchpad) or using the reboot command. | It has been half solved by having the Touchpad driver reset the controller on a soft reboot. However, this doesn't happen on hard reboots and will still cause the Nspire OS to not function correctly. Whenever possible, perform a soft reboot in Nspire Linux by using Ctrl+Alt(Var)+Delete(Scratchpad) or using the reboot command. | ||
===LCD contrast/backlight=== | ====LCD contrast/backlight==== | ||
At the moment, contrast settings can be found at <tt>/proc/contrast</tt> for classic calculators though this will be deprecated soon. The CX already has a working driver for backlight control. | At the moment, contrast settings can be found at <tt>/proc/contrast</tt> for classic calculators though this will be deprecated soon. The CX already has a working driver for backlight control. | ||
=== | ====USB==== | ||
== | |||
USB support is mostly working. The only thing missing is a USB PHY driver. The USB controller driver in this kernel is currently unable to switch seamlessly between USB host and USB device mode because of this. | |||
To work around this, we get the Nspire OS to set the right modes | To work around this, we get the Nspire OS to set the right modes before booting Linux. | ||
For USB Host mode: insert a USB OTG cable's A end or a USB device into the calculator while still inside the Nspire OS before running the bootloader. | For USB Host mode: insert a USB OTG cable's A end or a USB device into the calculator while still inside the Nspire OS before running the bootloader. | ||
Line 243: | Line 336: | ||
Both OTG and USB host work on the CX but since it needs a workaround that can't be integrated into the OTG driver, only one will work at a time. To maintain compatibility, the default is to use the USB host only driver. If you wish to use USB OTG on the CX, simply add <tt>cx_usb_otg</tt> to your kernel command line arguments. | Both OTG and USB host work on the CX but since it needs a workaround that can't be integrated into the OTG driver, only one will work at a time. To maintain compatibility, the default is to use the USB host only driver. If you wish to use USB OTG on the CX, simply add <tt>cx_usb_otg</tt> to your kernel command line arguments. | ||
==== | ====ADC==== | ||
ADC values can be read at <tt>/sys/bus/iio/devices/iio:device0</tt> (310 = 1V). | ADC values can be read at <tt>/sys/bus/iio/devices/iio:device0</tt> (310 = 1V). | ||
Line 253: | Line 342: | ||
==More information== | ==More information== | ||
[http://www.omnimaga.org/ | * [http://www.omnimaga.org/ti-nspire-projects/calling-all-linux-kernel-developers! Omnimaga thread] | ||
[http://www.omnimaga.org/ | * [http://www.omnimaga.org/ti-nspire-projects/calling-all-linux-kernel-developers!/msg323459/#msg323459 FAQ] | ||
* [http://tiplanet.org/nspire-linux-builds/ TI-Planet nightly builds] | |||
* [https://github.com/Vogtinator/nspire-linux-configs Linux configs] |
Latest revision as of 10:33, 31 May 2015
This page documents the Linux port to the Nspire calculator. There are currently two versions available on the TI-Nspire. All new development will occur on the new kernel however, the legacy kernel is easier to get going.
Booting
To have something useful running using Linux on the calculator, a bootloader, kernel and rootfs is needed.
Bootloader
Source code: On github
Nightly builds: None.
Binary: TI-Planet
The bootloader is run from the Nspire OS to load everything into memory and execute the kernel.
Usage instructions can be found in the readme
Copy linuxloader.tns to your calculator and run it. Valid commands are: kernel <filename>: Loads a kernel image into memory initrd <filename>: Loads a ramdisk into memory dtb <filename>: Loads a DTB image into memory dump: Prints out the current internal state of the bootloader. Useful for debugging. free: Prints out the total amount of memory provided to the bootloader by the Nspire OS and amounts used by the kernel and ramdisks. cmdline [str]: Get/set the kernel command line parameters. mach [id]: Get/set the machine ID that will be provided to Linux upon booting. Useful for overriding the builtin default value without having to recompile. phys [<start> <size>]: Get/set the address and size of physical memory. Useful for overriding the builtin default value without having to recompile. rdsize [size]: Get/set the size of the ramdisk that Linux should create on boot. Leave at 0x0 for the kernel default. probemem: If this is run on an calculator model that isn't directly supported by the bootloader, you can use this to try and guess how much memory the system has. poke <addr> <value>: Write a word to an arbitrary location in the memory address space. peek <addr>: Read a word from an arbitrary location in the memory address space. boot: Boot kernel. The bootloader is also scriptable. Create a text file containing a list of commands to be executed and change the extension to .ll2.tns, and add the following line to your /documents/ndless/ndless.cfg.tns file. ext.ll2=linuxloader2 Then simply open your script file and the loader will execute all the commands in it. A sample one could look like this: kernel linux/zImage.tns initrd linux/initrd.tns cmdline root=/dev/ram boot This should save a lot of typing everytime you need to boot Linux.
To boot the device tree (newer) kernel, ensure you add a dtb command to load the correct device tree prior to booting.
kernel linux/zImage.tns initrd linux/initrd.tns dtb linux/dtb.tns cmdline root=/dev/ram boot
UART
You can get serial output on the UART. Remember to add ,115200n8 to the end of your console= command line options to keep the baud rate the same as the Nspire OS.
Kernel
Source code: see sections below
Nightly builds: TI-Planet
Please see below sections for the differences between the legacy and newer kernels.
To compile the legacy kernel with default options, first clone the github repo then run:
export ARCH=arm make nspire_defconfig make -j4 cp -v arch/arm/boot/zImage /path/to/folder/zImage.tns
Unfortunately, the newer kernel does not have a defconfig at the moment. You have to enable options manually. Check the nightly builds for example configs you can use.
export ARCH=arm make menuconfig make -j4 make dtbs cp -v arch/arm/boot/zImage /path/to/folder/zImage.tns cp -v arch/arm/boot/dts/nspire-*.dtb /path/to/folder/
Rootfs
Nightly builds: TI-Planet (WIP)
To have programs actually run on the kernel, you need a root filesystem of some sort containing the userspace programs.
For testing and mucking around, a initrd should be enough. It is possible to build one using Buildroot. Otherwise, there are a few on the nightly builds page and the Omnimaga thread.
For a larger root filesystem, you could put a filesystem on a USB drive and add root=/dev/sdaX to your kernel command line. You may also need to add rootdelay=10 to give the USB drive time to initialize. There have also been successes running Arch Linux for ARM and Debian.
Device tree kernel
The newer version is a total rewrite of the original code to switch to device trees and has slightly less hardware support (but better USB support). All development in this kernel will go directly to the mainland kernel. The source code can be found at kernel.org.
People interested in using this branch also have to compile the device tree blobs in addition to the kernel by running:
make dtbs
and include it in their bootscripts with:
dtb linux/devicetree.tns
Ensure you are using a version of linuxloader2 with a build date after May 11 2013 (or commits later than 0503ca6) for stable device tree support. If your linuxloader2 does not report a build date on startup, you need to upgrade your copy. You can get an updated copy from the TI-Planet nightly builds site.
Hardware support
Hardware | Classic | CX | In mainline | Notes |
---|---|---|---|---|
CPU | Yes | Yes | Yes | |
SRAM | Yes | Yes | No | Matter of adding a few lines to the device tree |
GPIO | Yes | Yes | Yes | |
UART1 | Yes | Yes | Yes | |
I2C | Yes | Yes | WIP | Waiting to be accepted into mainline. Have not received extensive testing. |
Watchdog timer | Yes | Yes | Have not tested. Just enable support for SP805 in the config | |
RTC | No | No | No | Should be a matter of adding a few lines to the device tree |
Power management | No | No | No | Difficult to cleanly implement |
Timer 1 | Yes | Yes | Yes | |
Timer 2 | Yes | Yes | Yes | |
Keypad | Yes | Yes | ||
Touchpad | Yes | WIP | Waiting to be accepted into mainline. Have not received extensive testing. | |
LCD Contrast/Backlight | No | No | No | Should be a matter of adding a few lines to the device tree |
LED | WIP | No | Unlocking the LED is already possible | |
USB OTG | Yes | Yes | Everything working include seamless switching between USB host and USB device mode. | |
NAND | WIP | WIP | No | Dammit, why does the TI-Nspire have such weird NAND controllers to work with? |
LCD | Yes | Yes | ||
ADC | No | No | No | |
DES encryption/SHA generator | No | No | No | |
Interrupt controller | Yes | Yes | Yes |
Notes
Enabling USB OTG support
USB OTG with seamless switching relies on a few different options in the kernel. Ensure you’ve enabled the following:
- Zevio GPIO driver - CONFIG_GPIO_ZEVIO
- USB NOP transceiver - CONFIG_NOP_USB_XCEIV
- Fixed voltage regulator driver - CONFIG_REGULATOR_FIXED_VOLTAGE
The NOP transceiver is passed onto the Chipidea driver because the TI-Nspire doesn’t need/have a PHY.
The fixed voltage regulator driver is the bridge between the GPIO and Chipidea. It controls 5V output to the USB port.
Legacy kernel
This kernel is not being maintained any more. All new development will occur on the new kernel. This kernel is the initial port of Linux.
Hardware support
Classic
Hardware | Possible? | Implemented? | Notes |
---|---|---|---|
CPU | Yes | Yes | |
SDRAM | Yes | Yes | |
SRAM | Yes | Yes | |
GPIO | Yes | Yes | |
UART1 | Yes | Yes | |
I2C | Yes | Yes | |
Watchdog timer | Yes | Yes | |
RTC | Yes | Yes | |
Power management | Yes | WIP | Basic CPU frequency scaling has been implemented |
Timer 1 | Yes | No | |
Timer 2 | Yes | Yes | |
Keypad | Yes | Yes | |
Touchpad | Yes | Yes | |
LCD Contrast/Backlight | Yes | Basic | |
TI-84 Link port | Unknown | No | Do we really need this? |
LED | Yes | No | |
SPI | Yes | No | |
USB OTG | Yes | Yes | |
USB Host | Yes | Yes | |
NAND | Unknown | No | |
LCD | Yes | Yes | |
ADC | Yes | Yes | |
DES encryption/SHA generator | Yes | No | |
Interrupt controller | Yes | Yes |
CX
Hardware | Possible? | Implemented? | Notes |
---|---|---|---|
CPU | Yes | Yes | |
SDRAM | Yes | Yes | |
SRAM | Yes | Yes | |
GPIO | Yes | Yes | |
UART1 | Yes | Yes | |
I2C | Yes | Yes | |
Watchdog timer | Yes | Yes | |
RTC | Yes | Yes | |
Power management | Yes | WIP | Basic CPU frequency scaling has been implemented |
Timer 1 | Yes | No | |
Timer 2 | Yes | Yes | |
Keypad | Yes | Yes | |
Touchpad | Yes | Yes | |
LCD Contrast/Backlight | Yes | Yes | |
TI-84 Link port | Unknown | No | Do we really need this? |
LED | Yes | No | |
SPI | Yes | No | |
USB OTG | Yes | Yes | Current implementation breaks USB Host (see notes) |
USB Host | Yes | USB 1.1 | Uses a workaround but limits speed to USB 1.1 |
NAND | Yes | WIP | Needs a lot of testing. Unstable. Note - driver for a similar chip is available here |
LCD | Yes | Yes | |
ADC | Yes | Yes | |
DES encryption/SHA generator | Yes | No | |
Interrupt controller | Yes | Yes |
Quirks and technical details
SRAM
When needing to allocate memory from SRAM when developing for the kernel, use the following functions:
void *sram_alloc(unsigned int size, dma_addr_t *dma_addr) void sram_free(dma_addr_t addr, unsigned int size)
Keypad
The keymaps can be found in arch/arm/mach-nspire/keypad.c. Each array element represents one bit in Keypads.
Touchpad
There are some weird issues with the Touchpad. After booting Linux, the Touchpad doesn't function correctly under Nspire OS and requires entering diags or a few hard resets to get it back to normal. The exact cause is unknown but it is possible that this behavior is caused by the bootloader not correctly resetting Touchpad controller when the device boots up again so the Nspire OS is still using a Linux-configured Touchpad controller.
It has been half solved by having the Touchpad driver reset the controller on a soft reboot. However, this doesn't happen on hard reboots and will still cause the Nspire OS to not function correctly. Whenever possible, perform a soft reboot in Nspire Linux by using Ctrl+Alt(Var)+Delete(Scratchpad) or using the reboot command.
LCD contrast/backlight
At the moment, contrast settings can be found at /proc/contrast for classic calculators though this will be deprecated soon. The CX already has a working driver for backlight control.
USB
USB support is mostly working. The only thing missing is a USB PHY driver. The USB controller driver in this kernel is currently unable to switch seamlessly between USB host and USB device mode because of this.
To work around this, we get the Nspire OS to set the right modes before booting Linux.
For USB Host mode: insert a USB OTG cable's A end or a USB device into the calculator while still inside the Nspire OS before running the bootloader.
For USB Device mode: connect the Nspire to a computer while in Nspire OS before running the bootloader.
The USB hardware on the calculators also provide very little power (something in the double digit milliamps). For anything other than a basic USB drive or a keyboard, a powered USB hub might be required to supply enough power.
Extra notes for CX
Both OTG and USB host work on the CX but since it needs a workaround that can't be integrated into the OTG driver, only one will work at a time. To maintain compatibility, the default is to use the USB host only driver. If you wish to use USB OTG on the CX, simply add cx_usb_otg to your kernel command line arguments.
ADC
ADC values can be read at /sys/bus/iio/devices/iio:device0 (310 = 1V).