update jumper overview of helios64 boot modes, hardware page

adding gpio page to helios64
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nurix87 2020-02-19 17:08:58 +07:00
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docs/helios64/gpio.md Normal file
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## User Accessible GPIOs (J12)
Helios4 provides 12 GPIOs on header J12 which can be used for user application. Those GPIOs are provided via an 16-bit IO Expander [PCA9655E](http://www.onsemi.com/PowerSolutions/product.do?id=PCA9655E) connected to I2C bus 0.
![J12 Pinout](/helios4/img/gpio/gpio_pinout_j12.png)
### Pinout Table
| Pin | Port | Remarks |
|------------|----------|---------|
| 1 | - | 3.3V supply |
| 2 | IO0_2 | |
| 3 | IO0_3 | |
| 4 | IO0_4 | |
| 5 | IO0_7 | |
| 6 | IO1_0 | |
| 7 | IO1_1 | |
| 8 | IO1_2 | |
| 9 | IO1_3 | |
| 10 | IO1_4 | |
| 11 | IO1_5 | |
| 12 | IO1_6 | |
| 13 | IO1_7 | |
| 14 | - | GND |
!!! warning
Ports **IO0_0**, **IO0_1**, **IO0_5**, and **IO0_6** are reserved for system use.
!!! important
It is not advisable to access the I2C IO Expander directly using I2C utilities.
## Accessing GPIOs under Linux
If the kernel supports debugfs (*CONFIG_DEBUG_FS=y*), list of GPIOs can be retrieved with the following command
```bash
sudo cat /sys/kernel/debug/gpio
```
Look for the **gpiochip2: GPIOs XXX-YYY** section, whereas **XXX** is first GPIO number and **YYY** is last GPIO number of IO expander.
```
gpiochip2: GPIOs 496-511, parent: i2c/0-0020, pca9555, can sleep:
gpio-496 ( |board-rev-0 ) in lo
gpio-497 ( |board-rev-1 ) in lo
gpio-498 ( |(null) ) out hi
gpio-499 ( |(null) ) in hi
gpio-500 ( |(null) ) in hi
gpio-501 ( |usb-overcurrent-stat) in hi
gpio-502 ( |USB-PWR ) out hi
gpio-503 ( |(null) ) in hi
gpio-504 ( |(null) ) in hi
gpio-505 ( |(null) ) in hi
gpio-506 ( |(null) ) in hi
gpio-507 ( |(null) ) in hi
gpio-508 ( |(null) ) in hi
gpio-509 ( |(null) ) in hi
gpio-510 ( |(null) ) in hi
gpio-511 ( |(null) ) in hi
```
Another way to get first GPIO number of the IO expander
```
cat /sys/bus/i2c/devices/0-0020/gpio/gpiochip*/base
```
Therefore the mapping between header J12 Pins and Sysfs GPIO numbers will be as described in the following table
### GPIO Table
| Pin | Sysfs GPIO number | Remarks |
|----|-----|---------|
| 1 | - | 3.3V supply |
| 2 | 498 | |
| 3 | 499 | |
| 4 | 500 | |
| 5 | 503 | |
| 6 | 504 | |
| 7 | 505 | |
| 8 | 506 | |
| 9 | 507 | |
| 10 | 508 | |
| 11 | 509 | |
| 12 | 510 | |
| 13 | 511 | |
| 14 | - | GND |
!!! note
The mapping table is unlikely to change between Kernel version.
### GPIO Control
**1.** Export the GPIO number you want to use
```
echo N | sudo tee -a /sys/class/gpio/export
```
**2.** Set the direction, "out" for Output or "in" for Input
```
echo DIRECTION | sudo tee -a /sys/class/gpio/gpioN/direction
```
**3.** Now you can read or change the GPIO value
To read GPIO value
```
cat /sys/class/gpio/gpioN/value
```
To change GPIO value (only if GPIO set as Output)
```
echo VALUE | sudo tee -a /sys/class/gpio/gpioN/value
```
!!! notes
Pay attention to the path, /sys/class/gpio/gpio**N**/ where **N** is the GPIO number.
#### Example
Set IO1_7 (pin 13) output as high
```
echo 511 | sudo tee -a /sys/class/gpio/export
echo "out" | sudo tee -a /sys/class/gpio/gpio511/direction
echo 1 | sudo tee -a /sys/class/gpio/gpio511/value
```
## Use GPIO with Device Tree Overlay
!!! info
Device Tree Compiler (dtc) from OS package manager usually is too old, use the one from kernel source or download binary version for Arm [here](/helios4/files/dt-overlay/dtc).
Another way to use the GPIO is by using device tree. In device tree the user accessible
GPIO is labelled as [expander0](https://git.kernel.org/pub/scm/linux/kernel/git/stable/linux.git/tree/arch/arm/boot/dts/armada-388-helios4.dts#n155).
Instead of directly modifying the Helios4 device tree source (*armada-388-helios4.dts*) and recompiling,
Linux and U-Boot provide a mechanism called device tree overlay. With overlay, user just needs
to create simple device tree that would be overlay'd on top of base device tree.
For example, to use **IO0_2** as power off button input, create following device tree source
and save it as power-button.dts
```
/dts-v1/;
/plugin/;
/ {
fragment@0 {
target-path = "/gpio-keys";
__overlay__ {
power-button {
label = "Soft Power Off";
linux,code = <116>;
gpios = <&expander0 2 1>;
};
};
};
};
```
Download dtc and compile device tree with this command
```
wget https://wiki.kobol.io/helios4/files/dt-overlay/dtc
chmod 755 dtc
./dtc -I dts -O dtb -o power-button.dtbo power-button.dts
```
***Button Wiring***
![button wiring](/helios4/img/gpio/power_button_sch.png)
The GPIO has internal pull up resistor, when the button is not pressed the input read as High and when the button is pressed the input read as Low, therefore we use active low flag.
----
In the above example you will find the 2 following lines
```
linux,code = <116>;
gpios = <&expander0 2 1>;
```
For **linux,code** property, you can use one of the following values. For complete even code list refer to [input-event-codes.h](https://git.kernel.org/pub/scm/linux/kernel/git/stable/linux.git/plain/include/uapi/linux/input-event-codes.h).
| Event Code Name | Event Code | Description |
|-------------|-------|---------------|
| KEY_POWER | 116 | Power Button |
| KEY_SLEEP | 142 | Sleep Button |
| KEY_WAKEUP | 116 | Power Button |
| BTN_0 | 0x100 | User Button 0 |
| BTN_1 | 0x101 | User Button 1 |
| BTN_2 | 0x102 | User Button 2 |
| BTN_3 | 0x103 | User Button 3 |
| BTN_4 | 0x104 | User Button 4 |
| BTN_5 | 0x105 | User Button 5 |
| BTN_6 | 0x106 | User Button 6 |
| BTN_7 | 0x107 | User Button 7 |
| BTN_8 | 0x108 | User Button 8 |
| BTN_9 | 0x109 | User Button 9 |
For **gpios** properties, the syntax is as follow
`<&expander0 index flag>`
Where *index* is one of the following values
| Port Number | Index |
|-------|----|
| IO0_2 | 2 |
| IO0_3 | 3 |
| IO0_4 | 4 |
| IO0_7 | 7 |
| IO1_0 | 8 |
| IO1_1 | 9 |
| IO1_2 | 10 |
| IO1_3 | 11 |
| IO1_4 | 12 |
| IO1_5 | 13 |
| IO1_6 | 14 |
| IO1_7 | 15 |
And *flag* is one of the following values
| Flag | Property |
|------|-----------|
| 0 | GPIO line is active high |
| 1 | GPIO line is active low |
For more info please refer to
[gpio-keys binding](https://git.kernel.org/pub/scm/linux/kernel/git/stable/linux.git/plain/Documentation/devicetree/bindings/input/gpio-keys.txt).
### Device Tree Overlay under Armbian
!!! info
Armbian older than version 5.98 is still not compiled with overlay support. Refer to instruction to [Compile Helios4 DTB with Symbol Support](#compile-helios4-dtb-with-symbol-support) or use precompiled binary.
Armbian Default (Stretch, Linux Kernel 4.14):
`wget https://wiki.kobol.io/files/dt-overlay/lk4.14_armada-388-helios4.dtb`
`sudo cp lk4.14_armada-388-helios4.dtb /boot/dtb/armada-388-helios4.dtb`
Armbian Next (Buster, Linux Kernel 4.19):
`wget https://wiki.kobol.io/files/dt-overlay/lk4.19_armada-388-helios4.dtb`
`sudo cp lk4.19_armada-388-helios4.dtb /boot/dtb/armada-388-helios4.dtb`
Create */boot/overlay-user/* to store the overlay and copy the overlay to the folder
```
sudo mkdir -p /boot/overlay-user
sudo cp power-button.dtbo /boot/overlay-user/
```
Then edit */boot/armbianEnv.txt* and append the overlay filename (without dtbo extension) to *user_overlays*
`user_overlays=power-button`
Reboot the system to load the overlay.
!!! notes
If there is more than one overlay file, separate it by space. For example
`user_overlays=power-button sleep-button`
----
***Additional Steps for U-Boot 2018.11 (Armbian Default)***
Bootscript (**boot.scr**) used in Armbian Default does not have routine to automatically load overlay from */boot/overlay-user* therefore **/boot/boot.cmd** need to be modified.
Append the following block
```
fdt addr ${fdt_addr}
fdt resize 65536
for overlay_file in ${user_overlays}; do
if load ${boot_interface} 0:1 ${loadaddr} ${prefix}overlay-user/${overlay_file}.dtbo; then
echo "Applying user provided DT overlay ${overlay_file}.dtbo"
fdt apply ${loadaddr} || setenv overlay_error "true"
fi
done
if test "${overlay_error}" = "true"; then
echo "Error applying DT overlays, restoring original DT"
load ${boot_interface} 0:1 ${fdt_addr} ${prefix}dtb/${fdtfile}
fi
```
before
`bootz ${kernel_addr_r} ${ramdisk_addr_r} ${fdt_addr}`
so it become
```
fdt addr ${fdt_addr}
fdt resize 65536
for overlay_file in ${user_overlays}; do
if load ${boot_interface} 0:1 ${loadaddr} ${prefix}overlay-user/${overlay_file}.dtbo; then
echo "Applying user provided DT overlay ${overlay_file}.dtbo"
fdt apply ${loadaddr} || setenv overlay_error "true"
fi
done
if test "${overlay_error}" = "true"; then
echo "Error applying DT overlays, restoring original DT"
load ${boot_interface} 0:1 ${fdt_addr} ${prefix}dtb/${fdtfile}
fi
bootz ${kernel_addr_r} ${ramdisk_addr_r} ${fdt_addr}
```
Recompile with
`mkimage -C none -A arm -T script -d /boot/boot.cmd /boot/boot.scr`
----
### Device Tree Overlay under Other Distro
#### Compile Helios4 DTB with Symbol Support
Download Linux Kernel source code and extract it to *~/src/linux*. Change directory to *~/src/linux*
Download and apply kernel patch for
- Linux Kernel 4.14
```
wget https://wiki.kobol.io/helios4/files/dt-overlay/compile-dtb-lk-4.14.patch
git apply --apply compile-dtb-lk-4.14.patch
```
- Linux Kernel 4.19
```
wget https://wiki.kobol.io/helios4/files/dt-overlay/compile-dtb-lk-4.19.patch
git apply --apply compile-dtb-lk-4.19.patch
```
Compile Helios4 device tree
`make armada-388-helios4.dtb`
Copy the dtb to boot folder (eg. /boot/dtb/)
`sudo cp arch/arm/boot/dts/armada-388-helios4.dtb /boot/dtb/`
Copy the overlay also to the same folder.
#### Apply overlay on U-Boot
To apply overlay to base dtb, the procedure is
1. Load Helios4 dtb to memory
2. Set fdt address to dtb address
3. Resize the fdt
4. Load overlay to memory
5. Apply from overlay address
6. Boot the kernel
Example command
```
load mmc 0:1 ${ramdisk_addr_r} /boot/uInitrd
load mmc 0:1 ${kernel_addr_r} /boot/zImage
load mmc 0:1 ${fdt_addr_r} /boot/dtb/${fdtfile}
fdt addr ${fdt_addr_r}
fdt resize 65536
load mmc 0:1 0x300000 /boot/dtb/power-button.dtbo
fdt apply 0x300000
bootz ${kernel_addr_r} ${ramdisk_addr_r} ${fdt_addr_r}
```

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Name |Peripheral Type|Connector Type|Details Name |Peripheral Type|Connector Type|Details
-----|---------------|--------------|------- -----|---------------|--------------|-------
P10|eMMC|2x1 Pin Male Header|Disable eMMC boot P8|SATA Cont. Mem. Flash Enable Jumper|2x1 Pin Header|Sata Controller Flash Memory Enable
P11|SPI Flash|2x1 Pin Male Header|Disable SPI Flash P9|eFuse Dis. Jumper|Not Populated|**TBD** eFuse Power Supply
P13|HS Select|2x1 Pin Male Header|USB-C HS Select (Close = Type C HS, Open = Console) P10|eMMC Dis. Jumper|2x1 Pin Male Header|Disable eMMC boot
J1|USB3|USB 3.0| USB 3.0 Port Header P11|SPI Flash Dis. Jumper|2x1 Pin Male Header|Disable SPI Flash
P13|HS Select Jumper|2x1 Pin Male Header|USB-C HS Select (Close = Type C HS, Open = Console)
J1|USB3 Host|USB 3.0 Host| USB 3.0 Port Header
J3|SATA|SATA 3.0|Port 0 (SATA1) J3|SATA|SATA 3.0|Port 0 (SATA1)
J4|SATA|SATA 3.0|Port 1 (SATA2) J4|SATA|SATA 3.0|Port 1 (SATA2)
J5|SATA|SATA 3.0|Port 2 (SATA3) J5|SATA|SATA 3.0|Port 2 (SATA3)
J6|SATA|SATA 3.0|Port 3 (SATA4) J6|SATA|SATA 3.0|Port 3 (SATA4)
J7|HDD Power|8 Pin ATX 12V|Rated for 5x HDD
J8|SATA|SATA 3.0|Port 4 (SATA5) J8|SATA|SATA 3.0|Port 4 (SATA5)
J9|Battery Power|6 Pin ATX 12V|Battery Backup J7|HDD Power Conn.|8 Pin ATX 12V|Rated for 5x HDD
J10|ATX Power Supply|4 Pin ATX 12V|4 Pin ATX Power Connector J9|Battery Power Conn.|6 Pin ATX 12V|Battery Backup
J10|ATX Power Supply Conn.|4 Pin ATX 12V|4 Pin ATX Power Connector
J11|LAN1|RJ45|Gigabit Ethernet J11|LAN1|RJ45|Gigabit Ethernet
J12|LAN2|RJ45|2.5 Gigabit Ethernet J12|LAN2|RJ45|2.5 Gigabit Ethernet
J13|USB 3.0|Dual Port USB3.0|Type A J13|USB 3.0 Host|Dual Port USB3.0|Type A
J14|microSD|Push-Push card connector|Support SDHC and SDXC J14|microSD|Push-Push card connector|Support SDHC and SDXC
J15|Serial port|Micro-USB Connector|Via onboard FTDI USB-to-UART0 bridge J15|USB Type-C Dual Role|USB Type-C Connector|Via onboard FTDI USB-to-UART0 bridge
J16|DC connector|Kycon 4-Pin Mini-DIN|DC input 12V / 8A J16|DC Connector|Kycon 4-Pin Mini-DIN|DC input 12V / 8A
FAN1|Fan|4x1 Pin Male Header|PWM and RPM support FAN1|Fan Connector|4x1 Pin Male Header|PWM and RPM support
FAN2|Fan|4x1 Pin Male Header|PWM and RPM support FAN2|Fan Connector|4x1 Pin Male Header|PWM and RPM support
P1|I2C|4x1 Pin Male Header|I2C Bus 1 P1|I2C Header|4x1 Pin Male Header|I2C Bus 1
P2|UEXT|2x5 Pin Male Header|Universal EXTension Support [2] P2|UEXT Header|2x5 Pin Male Header|Universal EXTension Support [2]
P3|Front Panel|12x1 Pin Male Header|PWM and RPM support P3|Front Panel Header|12x1 Pin Male Header|PWM and RPM support
P4|Buzzer|2x1 Pin Header|Buzzer Speaker Support P4|Buzzer Header|2x1 Pin Header|Buzzer Speaker Support
P5|GPIO|7x2 Pin Male Header|GPIO configurable as input or output<br>Via IO Expander on I2C Bus 0 P5|GPIO Pin Header|7x2 Pin Male Header|GPIO configurable as input or output<br>Via IO Expander on I2C Bus 0
SW1|Power|Push Button|Power Button SW1|Power Button|Push Button|Power Button
SW2|Boot Mode|Push Button|Boot mode selector :<br> SPI,MMC,UART,SATA SW2|Recovery Button|Push Button|Boot mode selector :<br> SPI,MMC,UART,SATA
SW3|Reset|Push Button|Reset Button SW3|Reset Button|Push Button|Reset Button
## Boot Modes ## Boot Modes
Helios64 supports at least **3 (TBD)** boot modes that can be chosen by using the jumper configuration. Helios64 supports at least **3 (TBD)** boot modes that can be chosen by using the jumper configuration.
Please see above figure for the connector/interface list. The default Boot device order for Helios64 is the SPI Flash Memory, eMMC, then micro-SD Card.
The SoC will access this order sequentially to find the bootloader in all possible storage medium.
To change the boot order if the bootloader are present in all possible volatile storage, we can use the combination of P10 and P11 jumpers.
(Please see above figure for the connector/interface list.)
Following jumper are available in the Helios64 board to configure the boot modes: Following jumper are available in the Helios64 board to configure the boot modes:
- P10 jumper to disable eMMC, when this jumper close it means disable the eMMC device (open = enable eMMC), - P11 jumper can be used disable SPI Flash, when this jumper is shorted/close it means disable boot from the SPI Flash, and the board will search the next boot device (which is eMMC).
- P11 jumper to disable SPI Flash, when this jumper is shorted/close it means disable the SPI Flash (open = enable SPI Flash), - P10 jumper is available to disable eMMC boot, when this jumper is closed Helios64 wil skip looking for bootloader from the eMMC and will continue with the micro-SD card,
- P13 jumper is the HS select, when this jumper closed the High Speed (USB 2.0) connection to the SoC will be establised, so you can use flashing technology such as rockusb and marskom.
So you can select to search for bootloader starting from the SPI Flash Storage, eMMC, untill micro-SD card.
Following table may simplified boot ordering by jumper config by assuming the bootloaders are present in every storage device:
P11 State|P10 State|Boot Order|Notes
-----|---------------|--------------|-------
0|0|SPI Flash|-
1|0|eMMC|-
1|1|micro-SD Card|-
!!! note
Please note, in case of bootloader is not present in the storage devices. The SoC will search to the next possible boot device.
## Jumpers
- P13 jumper is the HS select, when this jumper closed the High Speed USB (USB 2.0) connection to the SoC will be establised, while the serial console is disconnected, so you can use flashing technology such as rockusb and maskrom in the USB type-C port.
[comment]: <> (its also called as HS select, when this jumper is closed the micro USB-C connector become type-C HS (open = console), your USB-C cable will connected to the serial console of the Helios64 board by default. By closing this connection the USB-C connection will become the HS mode, the eMMC will be detected as the USB Mass storage in your PC, in this configuration can directly flash the Armbian image to it.) [comment]: <> (its also called as HS select, when this jumper is closed the micro USB-C connector become type-C HS (open = console), your USB-C cable will connected to the serial console of the Helios64 board by default. By closing this connection the USB-C connection will become the HS mode, the eMMC will be detected as the USB Mass storage in your PC, in this configuration can directly flash the Armbian image to it.)
@ -69,30 +89,23 @@ Please refer to [U-boot](/helios4/uboot) section to know how to use the other mo
LED Name|Color|Description LED Name|Color|Description
---|---|--- ---|---|---
LED1|red/blue|SATA1 activity LED1|green|SYS power
LED2|red/blue|SATA2 activity LED2|green|Peripheral power
LED3|red/blue|SATA3 activity LED3|green|HDD power
LED4|red/blue|SATA4 activity LED4|blue|System ON
LED5|red/blue|SATA5 activity LED5|bule|HDD activity
LED6|blue|USB activity LED6|green|System Status
LED7|blue|Network activity LED7|red|System Error
LED8|red/blue|System status/activity LED8|orange|Battery Charge
LED9|green|SYS power
LED10|green|HDD power
LED11|green|USB power
LED12|orange|Battery Charge
## Reset Button ## Reset Button
Helios64 board provides a RESET push button (RST BTN) to hard reset the SoC (System-On-Chip). Helios64 board provides a RESET push button (RST BTN) to hard reset the board.
!!! Important
This button only resets the SoC and not the overall board. For instance it won't reset the HDD.
## I2C Interface ## I2C Interface
Helios64 board exposes the SoC I2C Bus 1, on header P1. Below is the header pin-out, the little arrow on the PCB indicates the ground pin. Helios64 board exposes the SoC I2C Bus 1, on header **P1**. Below is the header pin-out.
![I2C Pinout](/helios64/img/hardware/i2c_pinout.png) ![I2C Pinout](/helios64/img/hardware/i2c_pinout.png)