staging:iio:documenation partial update.

More to be added, but this brings the docs in line with
the current code. Now they are hopefully just uninformative
rather than actually incorrect.

Signed-off-by: Jonathan Cameron <jic23@cam.ac.uk>
Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
This commit is contained in:
Jonathan Cameron 2011-05-18 14:42:40 +01:00 committed by Greg Kroah-Hartman
parent 0ed731d234
commit 44d8b3542f
5 changed files with 91 additions and 78 deletions

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@ -8,34 +8,66 @@ The crucial structure for device drivers in iio is iio_dev.
First allocate one using:
struct iio_dev *indio_dev = iio_allocate_device(0);
struct iio_dev *indio_dev = iio_allocate_device(sizeof(struct chip_state));
where chip_state is a structure of local state data for this instance of
the chip.
That data can be accessed using iio_priv(struct iio_dev *)
Then fill in the following:
indio_dev->dev.parent
the struct device associated with the underlying hardware.
- indio_dev->dev.parent
Struct device associated with the underlying hardware.
- indio_dev->name
Name of the device being driven - made available as the name
attribute in sysfs.
indio_dev->num_interrupt_lines
number of event triggering hardware lines the device has.
- indio_dev->info
pointer to a structure with elements that tend to be fixed for
large sets of different parts supported by a given driver.
This contains:
* info->driver_module:
Set to THIS_MODULE. Used to ensure correct ownership
of various resources allocate by the core.
* info->num_interrupt_lines:
Number of event triggering hardware lines the device has.
* info->event_attrs:
Attributes used to enable / disable hardware events.
* info->attrs:
General device attributes. Typically used for the weird
and the wonderful bits not covered by the channel specification.
* info->read_raw:
Raw data reading function. Used for both raw channel access
and for associate parameters such as offsets and scales.
* info->write_raw:
Raw value writing function. Used for writable device values such
as DAC values and caliboffset.
* info->read_event_config:
Typically only set if there are some interrupt lines. This
is used to read if an on sensor event detector is enabled.
* info->write_event_config:
Enable / disable an on sensor event detector.
* info->read_event_value:
Read value associated with on sensor event detectors. Note that
the meaning of the returned value is dependent on the event
type.
* info->write_event_value:
Write the value associated with on sensor event detectors. E.g.
a threshold above which an interrupt occurs. Note that the
meaning of the value to be set is event type dependant.
indio_dev->event_attrs
attributes used to enable / disable hardware events - note the
attributes are embedded in iio_event_attr structures with an
associated iio_event_handler which may or may note be shared.
If num_interrupt_lines = 0, then no need to fill this in.
indio_dev->attrs
general attributes such as polled access to device channels.
indio_dev->dev_data
private device specific data.
indio_dev->driver_module
typically set to THIS_MODULE. Used to specify ownership of some
iio created resources.
indio_dev->modes
whether direct access and / or ring buffer access is supported.
- indio_dev->modes:
Specify whether direct access and / or ring buffer access is supported.
- indio_dev->ring:
An optional associated buffer.
- indio_dev->pollfunc:
Poll function related elements. This controls what occurs when a trigger
to which this device is attached sends and event.
- indio_dev->channels:
Specification of device channels. Most attributes etc are built
form this spec.
- indio_dev->num_channels:
How many channels are there?
Once these are set up, a call to iio_device_register(indio_dev),
will register the device with the iio core.

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@ -3,8 +3,7 @@ Overview of IIO
The Industrial I/O subsystem is intended to provide support for devices
that in some sense are analog to digital converters (ADCs). As many
actual devices combine some ADCs with digital to analog converters
(DACs) the intention is to add that functionality at a future date
(hence the name).
(DACs) that functionality is also supported.
The aim is to fill the gap between the somewhat similar hwmon and
input subsystems. Hwmon is very much directed at low sample rate
@ -31,32 +30,28 @@ event must be accessed via polling.
Note: A given device may have one or more event channel. These events are
turned on or off (if possible) via sysfs interfaces.
* Hardware ring buffer support. Some recent sensors have included
* Hardware buffer support. Some recent sensors have included
fifo / ring buffers on the sensor chip. These greatly reduce the load
on the host CPU by buffering relatively large numbers of data samples
based on an internal sampling clock. Examples include VTI SCA3000
series and Analog Device ADXL345 accelerometers. Each ring buffer
typically has an event chrdev (similar to the more general ones above)
to pass on events such as buffer 50% full and an access chrdev via
which the raw data it self may be read back.
series and Analog Device ADXL345 accelerometers. Each buffer supports
polling to establish when data is available.
* Trigger and software ring buffer support. In many data analysis
* Trigger and software buffer support. In many data analysis
applications it it useful to be able to capture data based on some
external signal (trigger). These triggers might be a data ready
signal, a gpio line connected to some external system or an on
processor periodic interrupt. A single trigger may initialize data
capture or reading from a number of sensors. These triggers are
used in IIO to fill software ring buffers acting in a very similar
used in IIO to fill software buffers acting in a very similar
fashion to the hardware buffers described above.
Other documentation:
userspace.txt - overview of ring buffer reading from userspace.
device.txt - elements of a typical device driver.
trigger.txt - elements of a typical trigger driver.
ring.txt - additional elements required for ring buffer support.
ring.txt - additional elements required for buffer support.
sysfs-bus-iio - abi documentation file.

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@ -1,57 +1,55 @@
Ring buffer support within IIO
Buffer support within IIO
This document is intended as a general overview of the functionality
a ring buffer may supply and how it is specified within IIO. For more
specific information on a given ring buffer implementation, see the
comments in the source code. Note that the intention is to allow
some drivers to specify ring buffers choice at probe or runtime, but
for now the selection is hard coded within a given driver.
a buffer may supply and how it is specified within IIO. For more
specific information on a given buffer implementation, see the
comments in the source code. Note that some drivers allow buffer
implementation to be selected at compile time via Kconfig options.
A given ring buffer implementation typically embedded a struct
A given buffer implementation typically embeds a struct
iio_ring_buffer and it is a pointer to this that is provided to the
IIO core. Access to the embedding structure is typically done via
container_of functions.
struct iio_ring_buffer contains 4 function pointers
(preenable, postenable, predisable, postdisable).
These are used to perform implementation specific steps on either side
of the core changing it's current mode to indicate that the ring buffer
struct iio_ring_buffer contains a struct iio_ring_setup_ops *setup_ops
which in turn contains the 4 function pointers
(preenable, postenable, predisable and postdisable).
These are used to perform device specific steps on either side
of the core changing it's current mode to indicate that the buffer
is enabled or disabled (along with enabling triggering etc as appropriate).
Also in struct iio_ring_buffer is a struct iio_ring_access_funcs.
The function pointers within here are used to allow the core to handle
as much ring buffer functionality as possible. Note almost all of these
as much buffer functionality as possible. Note almost all of these
are optional.
mark_in_use, unmark_in_use
Basically indicate that not changes should be made to the ring
buffer state that will effect the form of the data being captures
(e.g. scan elements or length)
Basically indicate that not changes should be made to the buffer state that
will effect the form of the data being captures (e.g. scan elements or length)
store_to
If possible, push data to ring buffer.
If possible, push data to the buffer.
read_last
If possible get the most recent entry from the buffer (without removal).
If possible, get the most recent scan from the buffer (without removal).
This provides polling like functionality whilst the ring buffering is in
use without a separate read from the device.
rip_lots
The primary ring buffer reading function. Note that it may well not return
as much data as requested. The deadoffset is used to indicate that some
initial data in the data array is not guaranteed to be valid.
rip_first_n
The primary buffer reading function. Note that it may well not return
as much data as requested.
mark_param_changed
Used to indicate that something has changed. Used in conjunction with
request_update
If parameters have changed that require reinitialization or configuration of
the ring buffer this will trigger it.
the buffer this will trigger it.
get_bytes_per_datum, set_bytes_per_datum
Get/set the number of bytes for a complete scan. (All samples + timestamp)
get_length / set_length
Get/set the number of sample sets that may be held by the buffer.
Get/set the number of complete scans that may be held by the buffer.
is_enabled
Query if ring buffer is in use

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@ -5,14 +5,11 @@ an IIO device. Whilst this can create device specific complexities
such triggers are registered with the core in the same way as
stand-alone triggers.
struct iio_trig *trig = iio_allocate_trigger();
struct iio_trig *trig = iio_allocate_trigger("<trigger format string>", ...);
allocates a trigger structure. The key elements to then fill in within
a driver are:
trig->control_attrs
Any sysfs attributes needed to control parameters of the trigger
trig->private_data
Device specific private data.
@ -20,8 +17,12 @@ trig->owner
Typically set to THIS_MODULE. Used to ensure correct
ownership of core allocated resources.
trig->name
A unique name for the trigger.
trig->set_trigger_state:
Function that enables / disables the underlying source of the trigger.
There is also a
trig->alloc_list which is useful for drivers that allocate multiple
triggers to keep track of what they have created.
When these have been set call:
@ -30,9 +31,8 @@ iio_trigger_register(trig);
to register the trigger with the core, making it available to trigger
consumers.
Trigger Consumers
Currently triggers are only used for the filling of software ring
Currently triggers are only used for the filling of software
buffers and as such any device supporting INDIO_RING_TRIGGERED has the
consumer interface automatically created.

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@ -1,12 +0,0 @@
Userspace access to IIO
The sysfs attributes are documented in sysfs-bus-iio.
Udev will create the following entries under /dev by default:
device0:buffer0:access0 - ring access chrdev
device0:buffer0:event0 - ring event chrdev
device0:event0 - general event chrdev.
The files, lis3l02dqbuffersimple.c and iio_utils.h in this directory provide an example
of how to use the ring buffer and event interfaces.