Kernel documentation for the SPI framework can be found in the Documentation directory of your linux source tree or here Documentation/spi/spi-summary.
Linux SPI drivers are broken into two parts. A controller driver that handles direct communication with the hardware and a protocol driver to handle the details of the data for a particular device. The interface defined in spi.c/spi.h is the bridge between the two.
For the OMAP3's, the controller driver is omap2_mcspi.c. The OMAP3's have 4 SPI busses which the omap2_mcspi driver handles. The kernel config option to include the omap2_mcspi driver is CONFIG_SPI_OMAP24XX and is already built into standard Gumstix Overo kernels.
The OMAP3 SPI controller has the ability to act as either a SPI master or SPI slave, but the current kernel code only supports the SPI master configuration.
Gumstix brings out SPI bus 1 chip select pins 0 and 1 on most of the Overo expansion boards.
A protocol driver is what you need if you want to use the SPI system.
There are a couple of steps every SPI protocol driver needs to follow.
- Slave devices must be registered for each SPI bus and chip select position used.
- The SPI protocol driver needs to be registered with the system using the same name as the devices it will be handling so the kernel can link the two.
It doesn't matter which order these steps are performed. Most existing SPI drivers do the device registration completely outside the driver code in a board file. If you are writing your own driver, it is probably more convenient to do it in the driver code itself. When both device and driver registration are completed, the probe() function for the driver will be called and SPI communications can start.
SPI data communication happens using I/O queues. One or more SPI transfers are bundled up into SPI messages in the protocol driver. The protocol driver then submits the SPI messages to the controller driver's I/O queue with calls to spi_async(). These messages are processed in FIFO order asynchronously by the controller driver. As each message finishes, the controller notifies the protocol driver via 'completion' callbacks. The protocol driver can then process the raw data as necessary.
There are some simple synchronous functions exposed by the spi.h/spi.c interface to simplify the asynchronous behaviour of the Linux SPI system for protocol drivers.
Spidev is a standard Linux module that implements a generic SPI protocol driver while exposing a char device interface to userland via sysfs.
The documentation for spidev can be found here - Documentation/spi/spidev.
The spidev driver does not register devices so a board file patch like this one spidev-enable.patch is required to use spidev with the Overos. You should customize that patch for the particular device you are using. Things you might want to change are the bus speed and the mode.
The spidev driver is built in to the standard Overo kernels. If you are using OE, apply the board patch by copying it to the org.openembedded.dev/recipes/linux/linux-omap3-2.6.xx/ directory and then adding a line to include the patch in your kernel recipe org.openembedded.dev/recipes/linux/linux-omap3_2.6.xx.bb
As you can see from the patch, the standard Overo kernels already occupy the SPI bus 1 chip select lines 0 and 1 if either the ADS7846 touchscreen controller (CS0) or the LGPHILIPS LB035Q02 display driver (CS1) are enabled. You will have to disable these drivers in your kernel config if you want to connect your device to either of these lines. Only one protocol driver at a time can manage a particular CS line on a given SPI bus.
Here's one Gumstix mailing list thread posted on 7/21/09, where some users have successfully used spidev with the Overos.
You can also search the Gumstix mailing list archives for spidev
Here is an article that can get you started writing your own custom SPI driver for Linux using Gumstix Overos as the example board - Writing a Linux SPI driver
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