6db4831e98
Android 14
349 lines
10 KiB
ReStructuredText
349 lines
10 KiB
ReStructuredText
.. _joystick-api:
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=====================
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Programming Interface
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=====================
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:Author: Ragnar Hojland Espinosa <ragnar@macula.net> - 7 Aug 1998
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Introduction
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============
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.. important::
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This document describes legacy ``js`` interface. Newer clients are
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encouraged to switch to the generic event (``evdev``) interface.
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The 1.0 driver uses a new, event based approach to the joystick driver.
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Instead of the user program polling for the joystick values, the joystick
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driver now reports only any changes of its state. See joystick-api.txt,
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joystick.h and jstest.c included in the joystick package for more
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information. The joystick device can be used in either blocking or
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nonblocking mode, and supports select() calls.
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For backward compatibility the old (v0.x) interface is still included.
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Any call to the joystick driver using the old interface will return values
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that are compatible to the old interface. This interface is still limited
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to 2 axes, and applications using it usually decode only 2 buttons, although
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the driver provides up to 32.
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Initialization
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==============
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Open the joystick device following the usual semantics (that is, with open).
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Since the driver now reports events instead of polling for changes,
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immediately after the open it will issue a series of synthetic events
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(JS_EVENT_INIT) that you can read to obtain the initial state of the
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joystick.
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By default, the device is opened in blocking mode::
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int fd = open ("/dev/input/js0", O_RDONLY);
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Event Reading
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=============
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::
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struct js_event e;
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read (fd, &e, sizeof(e));
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where js_event is defined as::
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struct js_event {
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__u32 time; /* event timestamp in milliseconds */
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__s16 value; /* value */
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__u8 type; /* event type */
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__u8 number; /* axis/button number */
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};
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If the read is successful, it will return sizeof(e), unless you wanted to read
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more than one event per read as described in section 3.1.
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js_event.type
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-------------
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The possible values of ``type`` are::
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#define JS_EVENT_BUTTON 0x01 /* button pressed/released */
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#define JS_EVENT_AXIS 0x02 /* joystick moved */
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#define JS_EVENT_INIT 0x80 /* initial state of device */
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As mentioned above, the driver will issue synthetic JS_EVENT_INIT ORed
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events on open. That is, if it's issuing a INIT BUTTON event, the
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current type value will be::
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int type = JS_EVENT_BUTTON | JS_EVENT_INIT; /* 0x81 */
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If you choose not to differentiate between synthetic or real events
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you can turn off the JS_EVENT_INIT bits::
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type &= ~JS_EVENT_INIT; /* 0x01 */
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js_event.number
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---------------
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The values of ``number`` correspond to the axis or button that
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generated the event. Note that they carry separate numeration (that
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is, you have both an axis 0 and a button 0). Generally,
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=============== =======
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Axis number
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=============== =======
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1st Axis X 0
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1st Axis Y 1
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2nd Axis X 2
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2nd Axis Y 3
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...and so on
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=============== =======
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Hats vary from one joystick type to another. Some can be moved in 8
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directions, some only in 4, The driver, however, always reports a hat as two
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independent axis, even if the hardware doesn't allow independent movement.
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js_event.value
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--------------
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For an axis, ``value`` is a signed integer between -32767 and +32767
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representing the position of the joystick along that axis. If you
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don't read a 0 when the joystick is ``dead``, or if it doesn't span the
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full range, you should recalibrate it (with, for example, jscal).
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For a button, ``value`` for a press button event is 1 and for a release
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button event is 0.
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Though this::
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if (js_event.type == JS_EVENT_BUTTON) {
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buttons_state ^= (1 << js_event.number);
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}
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may work well if you handle JS_EVENT_INIT events separately,
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::
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if ((js_event.type & ~JS_EVENT_INIT) == JS_EVENT_BUTTON) {
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if (js_event.value)
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buttons_state |= (1 << js_event.number);
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else
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buttons_state &= ~(1 << js_event.number);
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}
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is much safer since it can't lose sync with the driver. As you would
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have to write a separate handler for JS_EVENT_INIT events in the first
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snippet, this ends up being shorter.
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js_event.time
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-------------
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The time an event was generated is stored in ``js_event.time``. It's a time
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in milliseconds since ... well, since sometime in the past. This eases the
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task of detecting double clicks, figuring out if movement of axis and button
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presses happened at the same time, and similar.
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Reading
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=======
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If you open the device in blocking mode, a read will block (that is,
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wait) forever until an event is generated and effectively read. There
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are two alternatives if you can't afford to wait forever (which is,
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admittedly, a long time;)
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a) use select to wait until there's data to be read on fd, or
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until it timeouts. There's a good example on the select(2)
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man page.
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b) open the device in non-blocking mode (O_NONBLOCK)
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O_NONBLOCK
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----------
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If read returns -1 when reading in O_NONBLOCK mode, this isn't
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necessarily a "real" error (check errno(3)); it can just mean there
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are no events pending to be read on the driver queue. You should read
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all events on the queue (that is, until you get a -1).
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For example,
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::
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while (1) {
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while (read (fd, &e, sizeof(e)) > 0) {
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process_event (e);
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}
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/* EAGAIN is returned when the queue is empty */
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if (errno != EAGAIN) {
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/* error */
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}
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/* do something interesting with processed events */
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}
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One reason for emptying the queue is that if it gets full you'll start
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missing events since the queue is finite, and older events will get
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overwritten.
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The other reason is that you want to know all what happened, and not
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delay the processing till later.
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Why can get the queue full? Because you don't empty the queue as
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mentioned, or because too much time elapses from one read to another
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and too many events to store in the queue get generated. Note that
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high system load may contribute to space those reads even more.
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If time between reads is enough to fill the queue and lose an event,
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the driver will switch to startup mode and next time you read it,
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synthetic events (JS_EVENT_INIT) will be generated to inform you of
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the actual state of the joystick.
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.. note::
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As of version 1.2.8, the queue is circular and able to hold 64
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events. You can increment this size bumping up JS_BUFF_SIZE in
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joystick.h and recompiling the driver.
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In the above code, you might as well want to read more than one event
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at a time using the typical read(2) functionality. For that, you would
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replace the read above with something like::
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struct js_event mybuffer[0xff];
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int i = read (fd, mybuffer, sizeof(mybuffer));
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In this case, read would return -1 if the queue was empty, or some
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other value in which the number of events read would be i /
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sizeof(js_event) Again, if the buffer was full, it's a good idea to
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process the events and keep reading it until you empty the driver queue.
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IOCTLs
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======
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The joystick driver defines the following ioctl(2) operations::
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/* function 3rd arg */
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#define JSIOCGAXES /* get number of axes char */
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#define JSIOCGBUTTONS /* get number of buttons char */
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#define JSIOCGVERSION /* get driver version int */
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#define JSIOCGNAME(len) /* get identifier string char */
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#define JSIOCSCORR /* set correction values &js_corr */
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#define JSIOCGCORR /* get correction values &js_corr */
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For example, to read the number of axes::
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char number_of_axes;
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ioctl (fd, JSIOCGAXES, &number_of_axes);
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JSIOGCVERSION
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-------------
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JSIOGCVERSION is a good way to check in run-time whether the running
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driver is 1.0+ and supports the event interface. If it is not, the
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IOCTL will fail. For a compile-time decision, you can test the
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JS_VERSION symbol::
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#ifdef JS_VERSION
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#if JS_VERSION > 0xsomething
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JSIOCGNAME
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----------
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JSIOCGNAME(len) allows you to get the name string of the joystick - the same
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as is being printed at boot time. The 'len' argument is the length of the
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buffer provided by the application asking for the name. It is used to avoid
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possible overrun should the name be too long::
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char name[128];
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if (ioctl(fd, JSIOCGNAME(sizeof(name)), name) < 0)
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strncpy(name, "Unknown", sizeof(name));
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printf("Name: %s\n", name);
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JSIOC[SG]CORR
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-------------
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For usage on JSIOC[SG]CORR I suggest you to look into jscal.c They are
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not needed in a normal program, only in joystick calibration software
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such as jscal or kcmjoy. These IOCTLs and data types aren't considered
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to be in the stable part of the API, and therefore may change without
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warning in following releases of the driver.
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Both JSIOCSCORR and JSIOCGCORR expect &js_corr to be able to hold
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information for all axis. That is, struct js_corr corr[MAX_AXIS];
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struct js_corr is defined as::
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struct js_corr {
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__s32 coef[8];
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__u16 prec;
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__u16 type;
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};
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and ``type``::
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#define JS_CORR_NONE 0x00 /* returns raw values */
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#define JS_CORR_BROKEN 0x01 /* broken line */
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Backward compatibility
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======================
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The 0.x joystick driver API is quite limited and its usage is deprecated.
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The driver offers backward compatibility, though. Here's a quick summary::
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struct JS_DATA_TYPE js;
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while (1) {
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if (read (fd, &js, JS_RETURN) != JS_RETURN) {
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/* error */
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}
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usleep (1000);
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}
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As you can figure out from the example, the read returns immediately,
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with the actual state of the joystick::
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struct JS_DATA_TYPE {
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int buttons; /* immediate button state */
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int x; /* immediate x axis value */
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int y; /* immediate y axis value */
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};
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and JS_RETURN is defined as::
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#define JS_RETURN sizeof(struct JS_DATA_TYPE)
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To test the state of the buttons,
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::
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first_button_state = js.buttons & 1;
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second_button_state = js.buttons & 2;
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The axis values do not have a defined range in the original 0.x driver,
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except for that the values are non-negative. The 1.2.8+ drivers use a
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fixed range for reporting the values, 1 being the minimum, 128 the
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center, and 255 maximum value.
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The v0.8.0.2 driver also had an interface for 'digital joysticks', (now
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called Multisystem joysticks in this driver), under /dev/djsX. This driver
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doesn't try to be compatible with that interface.
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Final Notes
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===========
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::
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____/| Comments, additions, and specially corrections are welcome.
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\ o.O| Documentation valid for at least version 1.2.8 of the joystick
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=(_)= driver and as usual, the ultimate source for documentation is
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U to "Use The Source Luke" or, at your convenience, Vojtech ;)
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