Forth Lesson 22

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Mitch Bradley's Forth and
Open Firmware Lessons:

Using Forth Under Linux

You can run Forth under Linux and use it to inspect I/O devices.

On XO-1.75 and XO-4

On OLPC OS builds, /runin/sdkit-arm contains Open Firmware built for use within Linux.

 $ su
 # cd /runin/sdkit-arm
 # RUNIN_PATH=/runin ./sdkit.sh
 ok 

Or download http://dev.laptop.org/~wmb/sdkit-arm.tgz . Unpack it into your home directory on an XO-1.75 .

 $ tar xfz sdkit-arm.tgz

Then:

 $ cd sdkit-arm
 $ su
 # ./sdkit.sh
 ok

sdkit comes up in hex mode, so you can enter and display numbers in hex without additional qualifiers. To enter a decimal number, precede it with "d# ", e.g. "d# 123"

GPIO Access

Command Stack Description Example
gpio-pin@ ( gpio# -- flag ) Flag is true if GPIO pin is high d# 108 gpio-pin@ .
gpio-out? ( gpio# -- flag ) Flag is true if GPIO is an output d# 108 gpio-out? .
gpio-set ( gpio# -- ) Drives GPIO high d# 108 gpio-set
gpio-clr ( gpio# -- ) Drives GPIO low d# 108 gpio-clr
gpio-rise@ ( gpio# -- flag ) Flag is true if rising edge detected d# 108 gpio-rise@ .
gpio-fall@ ( gpio# -- flag ) Flag is true if falling edge detected d# 108 gpio-fall@ .
gpio-edge@ ( gpio# -- flag ) Flag is true if edge detected d# 108 gpio-edge@ .
gpio-clr-edge ( gpio# -- ) Clears GPIO edge detector d# 108 gpio-clr-edge
gpio-dir-out ( gpio# -- ) Sets GPIO direction to output d# 108 gpio-dir-out
gpio-dir-in ( gpio# -- ) Sets GPIO direction to input d# 108 gpio-dir-out
gpio-set-rer ( gpio# -- ) Enables rising edge detection d# 108 gpio-set-rer
gpio-clr-rer ( gpio# -- ) Disables rising edge detection d# 108 gpio-set-rer
gpio-set-fer ( gpio# -- ) Enables falling edge detection d# 108 gpio-set-fer
gpio-clr-fer ( gpio# -- ) Disables falling edge detection d# 108 gpio-set-fer

Multi-Function Pin Register Access

The Multi-Function Pin Registers (MFPRs) control the assignment of chip pins to internal functions, and also control characteristics of those pins, such as drive strength, pull up/down resistors, etc. Since each multi-function pins can be used as a GPIO, we use the GPIO number to designate which pin we are interested in.

Command Stack Description Example
af@ ( gpio# -- function ) Returns the MFPR setting for gpio# d# 108 af@ .
af! ( function gpio# -- ) Sets the MFPR for gpio# h# a0c0 d# 108 af!
dump-mfprs ( -- ) Displays a table of all MFPR settings dump-mfprs
gpio>mfpr ( gpio# -- address ) Returns the address of the MFPR register for gpio# d# 108 gpio>mfpr .

Camera Test

The camera test turns on the camera chip and lets you access internal camera chip registers via its I2C bus interface.

Command Stack Description Example
test-camera-i2c ( -- ) Turns on the camera and dumps its internal registers test-camera-i2c
start-camera ( -- ) Sets up the camera clocks and pads, powers on and resets the camera sensor chip start-camera
ov@ ( reg# -- value ) Reads an internal camera register via I2C 5 ov@ .
ov! ( value reg# -- ) Writes an internal camera register via I2C 4 12 ov!
ov-dump ( -- ) Displays a bunch of camera registers ov-dump

Accelerometer

Command Stack Description Example
select /accelerometer ( -- ) Activate accelerometer device driver select /accelerometer
acceleration@ ( -- x y z ) Read acceleration values acceleration@ .d .d .d

acceleration@ .d .d .d cr many

unselect ( -- ) Deactivate the current device driver unselect

Two-Wire Serial Interface (I2C/SMBUS) Hardware

Command Stack Description Example
set-twsi-target ( slave channel -- ) Select a TWSI channel and slave address for subsequent access h# 3a 6 set-twsi-target
twsi-b@ ( reg -- byte ) Read a byte h# 20 twsi-b@ .
twsi-b! ( byte reg -- byte ) Write a byte h# 47 h# 20 twsi-b!
twsi-write ( byte_n-1 .. byte0 n -- ) Write n bytes from the stack 33 22 11 00 4 twsi-write
twsi-get ( reg#_n-1 .. reg#0 #reg-bytes #data-bytes -- data_n-1 .. data0 ) Send #reg-bytes register address bytes from the stack, then read #data-bytes onto the stack. h# 23 h# 01 2 4 twsi-get . . . .


Accessing Arbitrary Devices

In addition to the "canned" access words for specific devices, you can manually access any device you wish, using the "mmap" command to assign a virtual address to the I/O device's physical address.

Command Stack Description Example
mmap ( phys-addr size -- virt-addr ) Assigns a page-aligned virtual address to a physical device address range d4050000 1000 mmap constant clock-unit-base
unaligned-mmap ( phys-addr -- virt-addr ) Assigns a possibly-unaligned virtual address to a physical device address d4033800 unaligned-mmap constant twsi5-base

For mmap, the physical address and size must both be multiples of 0x1000 (the CPU page size), i.e. their low three hex digits must be 0.

For unaligned-mmap, the physical address need not be page-aligned. Unaligned-mmap calls mmap with a page-aligned address (mapping a single page) and then adds the offset into the virtual address.

You can add offsets to the virtual address to access registers within the range {virtual-address .. virtual-address+size-1}. For example:

 ok d4050000 1000 mmap  constant clock-unit
 ok clock-unit 24 + l@ .

You could use unaligned-mmap to get an address that points to an individual register within a register block, but it's usually better to map the base address of the register block and then apply small offsets to the virtual address to access individual registers.

Recipes

Storage LED

Useful for checking that sdkit-arm is functioning.

 ok d# 10 gpio-set  \ turn on the LED
 ok d# 10 gpio-clr  \ turn off the LED
 ok d# 10 0 do d# 10 gpio-set d# 100 ms d# 10 gpio-clr d# 400 ms loop  \ blink the LED ten times
Thermal Sensor

Obtains the temperature from the CPU, until <trac>10954</trac> is fixed.

 d4013200 unaligned-mmap constant thermal-base
 : cpu-temperature  ( -- celcius )
    0                     ( acc )
    d# 100 0  do          ( acc )  \ Accumulate 100 samples
       thermal-base @     ( acc reg )
       h# 3ff and         ( acc val )
       +                  ( acc' )
    loop                  ( acc )
    d# 52940 -  d# 196 /  ( convert to celcius )
 ;
 cpu-temperature .d

Thus endeth the lesson.