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The other required set of changes

Browse Source 
As per the PR, the changes still holding it up.
Add onekey for testing.
Fix ARM builds.
Fix device descriptor when either axes or buttons is zero.
Add compile-time check for at least one axis or button.
Move definition to try to fix conflict.
PR review comments.
qmk cformat
This commit is contained in:
Nick Brassel
2020-01-10 06:29:34 +11:00
committed by a-chol
parent d88bdc6a1b
commit 801be60473
18 changed files with 455 additions and 458 deletions
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32
docs/feature_joystick.md
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@ -1,6 +1,6 @@
## Joystick HID Device
The keyboard can be made to be recognized as a joystick HID device by the Operating System.
The keyboard can be made to be recognized as a joystick HID device by the Operating System.
This is enabled by adding the following to `rules.mk`
@ -8,24 +8,26 @@ This is enabled by adding the following to `rules.mk`
JOYSTICK_ENABLE = yes
```
The joystick feature provides two services :
The joystick feature provides two services :
* reading an analog input device
* sending gamepad HID reports
Both services can be used without the other, depending on wether you just want to read a device but not send gamepad reports (for volume control for instance)
Both services can be used without the other, depending on whether you just want to read a device but not send gamepad reports (for volume control for instance)
or send gamepad reports based on values computed by the keyboard.
!> Reading analog axes is not currently functional on ARM MCUs.
### Analog circuit
An analog device such as a potentiometer found on a gamepad's analog axes is based on a [voltage divider](https://en.wikipedia.org/wiki/Voltage_divider).
It is composed of three connectors linked to the ground, the power input and power output (usually the middle one). The power output holds the voltage that varies based on the position of the cursor,
which value will be read using your MCU's [ADC](https://en.wikipedia.org/wiki/Analog-to-digital_converter).
Depending on what pins are already used by your keyboard's matrix, the rest of the circuit can get a little bit more complicated,
It is composed of three connectors linked to the ground, the power input and power output (usually the middle one). The power output holds the voltage that varies based on the position of the cursor,
which value will be read using your MCU's [ADC](https://en.wikipedia.org/wiki/Analog-to-digital_converter).
Depending on what pins are already used by your keyboard's matrix, the rest of the circuit can get a little bit more complicated,
feeding the power input and ground connection through pins and using diodes to avoid bad interactions with the matrix scanning procedures.
### Configuring the joystick
The default joystick has 2 axes and and 8 buttons. This can be changed from the config.h file :
The default joystick has 2 axes and and 8 buttons. This can be changed from the config.h file :
```
//max 32 for JOYSTICK_BUTTON_COUNT
@ -38,22 +40,22 @@ When defining axes for your joystick, you have to provide a definition array. Yo
A joystick will either be read from an input pin that allows the use of the ADC, or can be virtual, so that its value is provided by your code.
You have to define an array of type ''joystick_config_t'' and of proper size.
There are three ways for your circuit to work with the ADC, that relies on the use of 1, 2 or 3 pins of the MCU:
There are three ways for your circuit to work with the ADC, that relies on the use of 1, 2 or 3 pins of the MCU:
* 1 pin : your analog device is directly connected to your device Ground and Vcc. The only pin used is the ADC pin of your choice.
* 2 pins : your analog device is powered through a pin that allows toggling it on or off. The other pin is used to read the input value through the ADC
* 3 pins : both the power input and ground are connected to pins that must be set to a proper state before reading and restored afterwards.
The configuration of each axis is performed using one of four macros:
* JOYSTICK_AXIS_VIRTUAL : no ADC reading must be performed, that value will be provided by keyboard/keymap-level code
* JOYSTICK_AXIS_IN (INPUT_PIN, LOW, REST, HIGH) : a voltage will be read on the provided pin, which must be an ADC-capable pin.
* JOYSTICK_AXIS_IN_OUT (INPUT_PIN, OUTPUT_PIN, LOW, REST, HIGH) : the provided OUTPUT_PIN will be set high before INPUT_PIN is read.
* JOYSTICK_AXIS_IN_OUT_GROUND(INPUT_PIN, OUTPUT_PIN, GROUND_PIN, LOW, REST, HIGH) : the OUTPUT_PIN will be set high and GROUND_PIN will be set low before reading from INPUT_PIN
In any case where an ADC reading takes place (when INPUT_PIN is provided), additional LOW, REST and HIGH parameters are used.
In any case where an ADC reading takes place (when INPUT_PIN is provided), additional LOW, REST and HIGH parameters are used.
They implement the calibration of the analog device by defining the range of read values that will be mapped to the lowest, resting position and highest possible value for the axis (-127 to 127).
In practice, you have to provide the lowest/highest raw adc reading, and the raw reading at resting position, when no deflection is applied. You can provide inverted LOW and HIGH to invert the axis.
For instance, an axes configuration can be defined in the following way :
For instance, an axes configuration can be defined in the following way :
```
//joystick config
@ -65,12 +67,12 @@ joystick_config_t joystick_axes[JOYSTICK_AXES_COUNT] = {
When the ADC reads 900 or higher, the returned axis value will be -127, whereas it will be 127 when the ADC reads 285 or lower. Zero is returned when 575 is read.
In this example, the first axis will be read from the A4 pin while B0 is set high and A7 is set low, using an analogRead, whereas the second axis will not be read.
In this example, the first axis will be read from the A4 pin while B0 is set high and A7 is set low, using an analogRead, whereas the second axis will not be read.
In order to give a value to the second axis, you can do so in any customizable entry point of quantum : as an action, in process_record_user or in matrix_scan_user, or even in joystick_task(void) which is called even when no key has been pressed.
You assign a value by writing to joystick_status.axes[axis_index] a signed 8bit value (ranging from -127 to 127). Then it is necessary to assign the flag JS_UPDATED to joystick_status.status in order for an updated HID report to be sent.
The following example writes two axes based on keypad presses, with KP_5 as a precision modifier :
The following example writes two axes based on keypad presses, with KP_5 as a precision modifier :
```
#ifdef JOYSTICK_ENABLE
@ -133,7 +135,7 @@ bool process_record_user(uint16_t keycode, keyrecord_t *record) {
break;
#endif
}
return true;
}
```

8
drivers/avr/analog.c
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@ -129,9 +129,9 @@ int16_t adc_read(uint8_t mux) {
low = ADCL;
// Must read MSB only once!
low |= (ADCH << 8);
//turn off the ADC
ADCSRA &= ~(1<<ADEN);
// turn off the ADC
ADCSRA &= ~(1 << ADEN);
return low;
}

3
keyboards/handwired/onekey/keymaps/joystick/config.h Normal file
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@ -0,0 +1,3 @@
#pragma once
#define JOYSTICK_AXES_COUNT 0
#define JOYSTICK_BUTTON_COUNT 1

5
keyboards/handwired/onekey/keymaps/joystick/keymap.c Normal file
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@ -0,0 +1,5 @@
#include QMK_KEYBOARD_H
const uint16_t PROGMEM keymaps[][MATRIX_ROWS][MATRIX_COLS] = {
LAYOUT( JS_BUTTON0 )
};

1
keyboards/handwired/onekey/keymaps/joystick/rules.mk Normal file
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@ -0,0 +1 @@
JOYSTICK_ENABLE = yes

20
quantum/joystick.c
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@ -1,15 +1,13 @@
#include "joystick.h"
joystick_t joystick_status = {
.buttons = {0},
.axes = {
#if JOYSTICK_AXES_COUNT>0
0
joystick_t joystick_status = {.buttons = {0},
.axes =
{
#if JOYSTICK_AXES_COUNT > 0
0
#endif
},
.status = 0
};
},
.status = 0};
//array defining the reading of analog values for each axis
__attribute__ ((weak))
joystick_config_t joystick_axes[JOYSTICK_AXES_COUNT] = {};
// array defining the reading of analog values for each axis
__attribute__((weak)) joystick_config_t joystick_axes[JOYSTICK_AXES_COUNT] = {};

55
quantum/joystick.h
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@ -1,55 +1,52 @@
#ifndef JOYSTICK_H
#define JOYSTICK_H
#pragma once
#ifndef JOYSTICK_BUTTON_COUNT
#define JOYSTICK_BUTTON_COUNT 8
# define JOYSTICK_BUTTON_COUNT 8
#endif
#ifndef JOYSTICK_AXES_COUNT
#define JOYSTICK_AXES_COUNT 4
# define JOYSTICK_AXES_COUNT 4
#endif
#include <stdint.h>
//configure on input_pin of the joystick_axes array entry to JS_VIRTUAL_AXIS
// configure on input_pin of the joystick_axes array entry to JS_VIRTUAL_AXIS
// to prevent it from being read from the ADC. This allows outputing forged axis value.
//
#define JS_VIRTUAL_AXIS 0xFF
#define JOYSTICK_AXIS_VIRTUAL {JS_VIRTUAL_AXIS,JS_VIRTUAL_AXIS,JS_VIRTUAL_AXIS,0 ,1023}
#define JOYSTICK_AXIS_IN(INPUT_PIN, LOW, REST, HIGH) {JS_VIRTUAL_AXIS,INPUT_PIN ,JS_VIRTUAL_AXIS,LOW,REST,HIGH}
#define JOYSTICK_AXIS_IN_OUT(INPUT_PIN, OUTPUT_PIN, LOW, REST, HIGH) {OUTPUT_PIN ,INPUT_PIN ,JS_VIRTUAL_AXIS,LOW,REST,HIGH}
#define JOYSTICK_AXIS_IN_OUT_GROUND(INPUT_PIN, OUTPUT_PIN, GROUND_PIN, LOW, REST, HIGH) {OUTPUT_PIN ,INPUT_PIN ,GROUND_PIN ,LOW,REST,HIGH}
#define JOYSTICK_AXIS_VIRTUAL \
{ JS_VIRTUAL_AXIS, JS_VIRTUAL_AXIS, JS_VIRTUAL_AXIS, 0, 1023 }
#define JOYSTICK_AXIS_IN(INPUT_PIN, LOW, REST, HIGH) \
{ JS_VIRTUAL_AXIS, INPUT_PIN, JS_VIRTUAL_AXIS, LOW, REST, HIGH }
#define JOYSTICK_AXIS_IN_OUT(INPUT_PIN, OUTPUT_PIN, LOW, REST, HIGH) \
{ OUTPUT_PIN, INPUT_PIN, JS_VIRTUAL_AXIS, LOW, REST, HIGH }
#define JOYSTICK_AXIS_IN_OUT_GROUND(INPUT_PIN, OUTPUT_PIN, GROUND_PIN, LOW, REST, HIGH) \
{ OUTPUT_PIN, INPUT_PIN, GROUND_PIN, LOW, REST, HIGH }
typedef struct {
uint8_t output_pin;
uint8_t input_pin;
uint8_t ground_pin;
//the AVR ADC offers 10 bit precision, with significant bits on the higher part
uint16_t min_digit;
uint16_t mid_digit;
uint16_t max_digit;
uint8_t output_pin;
uint8_t input_pin;
uint8_t ground_pin;
// the AVR ADC offers 10 bit precision, with significant bits on the higher part
uint16_t min_digit;
uint16_t mid_digit;
uint16_t max_digit;
} joystick_config_t;
extern joystick_config_t joystick_axes[JOYSTICK_AXES_COUNT];
enum joystick_status{
JS_INITIALIZED = 1,
JS_UPDATED = 2
};
enum joystick_status { JS_INITIALIZED = 1, JS_UPDATED = 2 };
typedef struct {
uint8_t buttons[JOYSTICK_BUTTON_COUNT/8+1];
int16_t axes[JOYSTICK_AXES_COUNT];
uint8_t status:2;
uint8_t buttons[JOYSTICK_BUTTON_COUNT / 8 + 1];
int16_t axes[JOYSTICK_AXES_COUNT];
uint8_t status : 2;
} joystick_t;
extern joystick_t joystick_status;
//to be implemented in the hid protocol library
// to be implemented in the hid protocol library
void send_joystick_packet(joystick_t* joystick);
#endif //JOYSTICK_H

244
quantum/process_keycode/process_joystick.c
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@ -1,159 +1,145 @@
#include "joystick.h"
#include "process_joystick.h"
#include <quantum/joystick.h>
#include <quantum/quantum_keycodes.h>
#include <quantum/config_common.h>
#ifdef __AVR__
# include <drivers/avr/analog.h>
# include "analog.h"
#endif
#include <string.h>
#include <math.h>
bool process_joystick_buttons(uint16_t keycode, keyrecord_t *record);
bool process_joystick(uint16_t keycode, keyrecord_t *record){
if (process_joystick_buttons(keycode, record)
&& (joystick_status.status & JS_UPDATED)>0){
send_joystick_packet(&joystick_status);
joystick_status.status &= ~JS_UPDATED;
}
return true;
}
bool process_joystick(uint16_t keycode, keyrecord_t *record) {
if (process_joystick_buttons(keycode, record) && (joystick_status.status & JS_UPDATED) > 0) {
send_joystick_packet(&joystick_status);
joystick_status.status &= ~JS_UPDATED;
}
__attribute__ ((weak))
void joystick_task(void){
if (process_joystick_analogread() && (joystick_status.status & JS_UPDATED)){
send_joystick_packet(&joystick_status);
joystick_status.status &= ~JS_UPDATED;
}
}
bool process_joystick_buttons(uint16_t keycode, keyrecord_t *record){
if (keycode < JS_BUTTON0 || keycode > JS_BUTTON_MAX){
return true;
} else {
if (record->event.pressed){
joystick_status.buttons[(keycode-JS_BUTTON0)/8] |= 1<<(keycode%8);
}
void joystick_task(void) {
if (process_joystick_analogread() && (joystick_status.status & JS_UPDATED)) {
send_joystick_packet(&joystick_status);
joystick_status.status &= ~JS_UPDATED;
}
}
bool process_joystick_buttons(uint16_t keycode, keyrecord_t *record) {
if (keycode < JS_BUTTON0 || keycode > JS_BUTTON_MAX) {
return true;
} else {
joystick_status.buttons[(keycode-JS_BUTTON0)/8] &= ~(1<<(keycode%8));
if (record->event.pressed) {
joystick_status.buttons[(keycode - JS_BUTTON0) / 8] |= 1 << (keycode % 8);
} else {
joystick_status.buttons[(keycode - JS_BUTTON0) / 8] &= ~(1 << (keycode % 8));
}
joystick_status.status |= JS_UPDATED;
}
joystick_status.status |= JS_UPDATED;
}
return true;
return true;
}
uint8_t savePinState(uint8_t pin){
uint8_t savePinState(uint8_t pin) {
#ifdef __AVR__
uint8_t pinNumber = pin & 0xF;
return ((PORTx_ADDRESS(pin) >> pinNumber) & 0x1) << 1
| ((DDRx_ADDRESS(pin) >> pinNumber) & 0x1) ;
uint8_t pinNumber = pin & 0xF;
return ((PORTx_ADDRESS(pin) >> pinNumber) & 0x1) << 1 | ((DDRx_ADDRESS(pin) >> pinNumber) & 0x1);
#else
return 0;
return 0;
#endif
}
void restorePinState(uint8_t pin, uint8_t restoreState){
void restorePinState(uint8_t pin, uint8_t restoreState) {
#ifdef __AVR__
uint8_t pinNumber = pin & 0xF;
PORTx_ADDRESS(pin) = (PORTx_ADDRESS(pin) & ~_BV(pinNumber)) | (((restoreState >> 1) & 0x1) << pinNumber);
DDRx_ADDRESS(pin) = (DDRx_ADDRESS(pin) & ~_BV(pinNumber)) | ((restoreState & 0x1) << pinNumber);
uint8_t pinNumber = pin & 0xF;
PORTx_ADDRESS(pin) = (PORTx_ADDRESS(pin) & ~_BV(pinNumber)) | (((restoreState >> 1) & 0x1) << pinNumber);
DDRx_ADDRESS(pin) = (DDRx_ADDRESS(pin) & ~_BV(pinNumber)) | ((restoreState & 0x1) << pinNumber);
#else
return;
return;
#endif
}
__attribute__ ((weak))
bool process_joystick_analogread(){
return process_joystick_analogread_quantum();
}
bool process_joystick_analogread_quantum(){
__attribute__((weak)) bool process_joystick_analogread() { return process_joystick_analogread_quantum(); }
bool process_joystick_analogread_quantum() {
#if JOYSTICK_AXES_COUNT > 0
for (int axis_index=0 ; axis_index<JOYSTICK_AXES_COUNT ; ++axis_index){
if (joystick_axes[axis_index].input_pin==JS_VIRTUAL_AXIS){
continue;
for (int axis_index = 0; axis_index < JOYSTICK_AXES_COUNT; ++axis_index) {
if (joystick_axes[axis_index].input_pin == JS_VIRTUAL_AXIS) {
continue;
}
// save previous input pin status as well
uint8_t inputSavedState = savePinState(joystick_axes[axis_index].input_pin);
// disable pull-up resistor
writePinLow(joystick_axes[axis_index].input_pin);
// if pin was a pull-up input, we need to uncharge it by turning it low
// before making it a low input
setPinOutput(joystick_axes[axis_index].input_pin);
wait_us(10);
// save and apply output pin status
uint8_t outputSavedState = 0;
if (joystick_axes[axis_index].output_pin != JS_VIRTUAL_AXIS) {
// save previous output pin status
outputSavedState = savePinState(joystick_axes[axis_index].output_pin);
setPinOutput(joystick_axes[axis_index].output_pin);
writePinHigh(joystick_axes[axis_index].output_pin);
}
uint8_t groundSavedState = 0;
if (joystick_axes[axis_index].ground_pin != JS_VIRTUAL_AXIS) {
// save previous output pin status
groundSavedState = savePinState(joystick_axes[axis_index].ground_pin);
setPinOutput(joystick_axes[axis_index].ground_pin);
writePinLow(joystick_axes[axis_index].ground_pin);
}
wait_us(10);
setPinInput(joystick_axes[axis_index].input_pin);
wait_us(10);
# ifdef __AVR__
int16_t axis_val = analogReadPin(joystick_axes[axis_index].input_pin);
# else
// default to resting position
int16_t axis_val = joystick_axes[axis_index].mid_digit;
# endif
// test the converted value against the lower range
uint16_t ref = joystick_axes[axis_index].mid_digit;
uint16_t range = joystick_axes[axis_index].min_digit;
int16_t ranged_val = -127 * fminf(1.f, (axis_val - (float)(ref)) / (range - (float)ref));
if (ranged_val > 0) {
// the value is in the higher range
range = joystick_axes[axis_index].max_digit;
ranged_val = 127 * fminf(1.f, (axis_val - (float)(ref)) / (range - (float)ref));
}
if (ranged_val != joystick_status.axes[axis_index]) {
joystick_status.axes[axis_index] = ranged_val;
joystick_status.status |= JS_UPDATED;
}
// restore output, ground and input status
if (joystick_axes[axis_index].output_pin != JS_VIRTUAL_AXIS) {
restorePinState(joystick_axes[axis_index].output_pin, outputSavedState);
}
if (joystick_axes[axis_index].ground_pin != JS_VIRTUAL_AXIS) {
restorePinState(joystick_axes[axis_index].ground_pin, groundSavedState);
}
restorePinState(joystick_axes[axis_index].input_pin, inputSavedState);
}
//save previous input pin status as well
uint8_t inputSavedState = savePinState(joystick_axes[axis_index].input_pin);
//disable pull-up resistor
writePinLow(joystick_axes[axis_index].input_pin);
//if pin was a pull-up input, we need to uncharge it by turning it low
// before making it a low input
setPinOutput(joystick_axes[axis_index].input_pin);
wait_us(10);
//save and apply output pin status
uint8_t outputSavedState = 0;
if (joystick_axes[axis_index].output_pin!=JS_VIRTUAL_AXIS) {
//save previous output pin status
outputSavedState = savePinState(joystick_axes[axis_index].output_pin);
setPinOutput(joystick_axes[axis_index].output_pin);
writePinHigh(joystick_axes[axis_index].output_pin);
}
uint8_t groundSavedState = 0;
if (joystick_axes[axis_index].ground_pin!=JS_VIRTUAL_AXIS) {
//save previous output pin status
groundSavedState = savePinState(joystick_axes[axis_index].ground_pin);
setPinOutput(joystick_axes[axis_index].ground_pin);
writePinLow(joystick_axes[axis_index].ground_pin);
}
wait_us(10);
setPinInput(joystick_axes[axis_index].input_pin);
wait_us(10);
#ifdef __AVR__
int16_t axis_val = analogReadPin(joystick_axes[axis_index].input_pin);
#else
//default to resting position
int16_t axis_val = joystick_axes[axis_index].mid_digit;
#endif
//test the converted value against the lower range
uint16_t ref = joystick_axes[axis_index].mid_digit;
uint16_t range = joystick_axes[axis_index].min_digit;
int16_t ranged_val = -127*fminf(1.f, (axis_val - (float)(ref)) /(range - (float)ref));
if (ranged_val > 0){
//the value is in the higher range
range = joystick_axes[axis_index].max_digit;
ranged_val = 127*fminf(1.f, (axis_val - (float)(ref)) /(range - (float)ref));
}
if (ranged_val!=joystick_status.axes[axis_index]){
joystick_status.axes[axis_index] = ranged_val;
joystick_status.status |= JS_UPDATED;
}
//restore output, ground and input status
if (joystick_axes[axis_index].output_pin!=JS_VIRTUAL_AXIS) {
restorePinState(joystick_axes[axis_index].output_pin, outputSavedState);
}
if (joystick_axes[axis_index].ground_pin!=JS_VIRTUAL_AXIS) {
restorePinState(joystick_axes[axis_index].ground_pin, groundSavedState);
}
restorePinState(joystick_axes[axis_index].input_pin, inputSavedState);
}
#endif
return true;
return true;
}

5
quantum/process_keycode/process_joystick.h
View File

@ -1,5 +1,4 @@
#ifndef PROCESS_JOYSTICK_H
#define PROCESS_JOYSTICK_H
#pragma once
#include <stdint.h>
#include "quantum.h"
@ -10,5 +9,3 @@ void joystick_task(void);
bool process_joystick_analogread(void);
bool process_joystick_analogread_quantum(void);
#endif //PROCESS_JOYSTICK_H

4
quantum/quantum.c
View File

@ -63,10 +63,6 @@ float bell_song[][2] = SONG(TERMINAL_SOUND);
# endif
#endif
#ifdef JOYSTICK_ENABLE
#include <process_keycode/process_joystick.h>
#endif //JOYSTICK_ENABLE
static void do_code16(uint16_t code, void (*f)(uint8_t)) {
switch (code) {
case QK_MODS ... QK_MODS_MAX:

4
quantum/quantum.h
View File

@ -142,6 +142,10 @@ extern layer_state_t layer_state;
# include "process_magic.h"
#endif
#ifdef JOYSTICK_ENABLE
# include "process_joystick.h"
#endif
#ifdef GRAVE_ESC_ENABLE
# include "process_grave_esc.h"
#endif

2
tmk_core/common/keyboard.c
View File

@ -72,7 +72,7 @@ along with this program. If not, see <http://www.gnu.org/licenses/>.
# include "process_midi.h"
#endif
#ifdef JOYSTICK_ENABLE
# include "process_joystick.h"
# include "process_joystick.h"
#endif
#ifdef HD44780_ENABLE
# include "hd44780.h"

10
tmk_core/common/report.h
View File

@ -185,6 +185,16 @@ typedef struct {
int8_t h;
} __attribute__((packed)) report_mouse_t;
typedef struct {
#if JOYSTICK_AXES_COUNT > 0
int8_t axes[JOYSTICK_AXES_COUNT];
#endif
#if JOYSTICK_BUTTON_COUNT > 0
uint8_t buttons[(JOYSTICK_BUTTON_COUNT - 1) / 8 + 1];
#endif
} __attribute__((packed)) joystick_report_t;
/* keycode to system usage */
static inline uint16_t KEYCODE2SYSTEM(uint8_t key) {
switch (key) {

108
tmk_core/protocol/chibios/usb_main.c
View File

@ -48,7 +48,7 @@ extern keymap_config_t keymap_config;
#endif
#ifdef JOYSTICK_ENABLE
# include <quantum/joystick.h>
# include "joystick.h"
#endif
/* ---------------------------------------------------------
@ -292,11 +292,11 @@ static usb_driver_configs_t drivers = {
#endif
#ifdef JOYSTICK_ENABLE
#define JOYSTICK_IN_CAPACITY 4
#define JOYSTICK_OUT_CAPACITY 4
#define JOYSTICK_IN_MODE USB_EP_MODE_TYPE_BULK
#define JOYSTICK_OUT_MODE USB_EP_MODE_TYPE_BULK
.joystick_driver = QMK_USB_DRIVER_CONFIG(JOYSTICK, 0, false),
# define JOYSTICK_IN_CAPACITY 4
# define JOYSTICK_OUT_CAPACITY 4
# define JOYSTICK_IN_MODE USB_EP_MODE_TYPE_BULK
# define JOYSTICK_OUT_MODE USB_EP_MODE_TYPE_BULK
.joystick_driver = QMK_USB_DRIVER_CONFIG(JOYSTICK, 0, false),
#endif
};
@ -888,58 +888,54 @@ void virtser_task(void) {
#ifdef JOYSTICK_ENABLE
typedef struct {
#if JOYSTICK_AXES_COUNT>0
int8_t axes[JOYSTICK_AXES_COUNT];
#endif
#if JOYSTICK_BUTTON_COUNT>0
uint8_t buttons[(JOYSTICK_BUTTON_COUNT-1)/8+1];
#endif
} __attribute__ ((packed)) joystick_report_t;
void send_joystick_packet(joystick_t* joystick) {
void send_joystick_packet(joystick_t *joystick) {
joystick_report_t rep = {
#if JOYSTICK_AXES_COUNT>0
.axes = {
joystick->axes[0]
# if JOYSTICK_AXES_COUNT > 0
.axes = {joystick->axes[0]
#if JOYSTICK_AXES_COUNT >= 2
,joystick->axes[1]
#endif
#if JOYSTICK_AXES_COUNT >= 3
,joystick->axes[2]
#endif
#if JOYSTICK_AXES_COUNT >= 4
,joystick->axes[3]
#endif
#if JOYSTICK_AXES_COUNT >= 5
,joystick->axes[4]
#endif
#if JOYSTICK_AXES_COUNT >= 6
,joystick->axes[5]
#endif
},
#endif //JOYSTICK_AXES_COUNT>0
#if JOYSTICK_BUTTON_COUNT>0
.buttons = {
joystick->buttons[0]
#if JOYSTICK_BUTTON_COUNT>8
,joystick->buttons[1]
#endif
#if JOYSTICK_BUTTON_COUNT>16
,joystick->buttons[2]
#endif
#if JOYSTICK_BUTTON_COUNT>24
,joystick->buttons[3]
#endif
}
#endif //JOYSTICK_BUTTON_COUNT>0
};
chnWrite(&drivers.joystick_driver.driver, (uint8_t*)&rep, sizeof(rep));
# if JOYSTICK_AXES_COUNT >= 2
,
joystick->axes[1]
# endif
# if JOYSTICK_AXES_COUNT >= 3
,
joystick->axes[2]
# endif
# if JOYSTICK_AXES_COUNT >= 4
,
joystick->axes[3]
# endif
# if JOYSTICK_AXES_COUNT >= 5
,
joystick->axes[4]
# endif
# if JOYSTICK_AXES_COUNT >= 6
,
joystick->axes[5]
# endif
},
# endif // JOYSTICK_AXES_COUNT>0
# if JOYSTICK_BUTTON_COUNT > 0
.buttons = {joystick->buttons[0]
# if JOYSTICK_BUTTON_COUNT > 8
,
joystick->buttons[1]
# endif
# if JOYSTICK_BUTTON_COUNT > 16
,
joystick->buttons[2]
# endif
# if JOYSTICK_BUTTON_COUNT > 24
,
joystick->buttons[3]
# endif
}
# endif // JOYSTICK_BUTTON_COUNT>0
};
chnWrite(&drivers.joystick_driver.driver, (uint8_t *)&rep, sizeof(rep));
}
#endif

107
tmk_core/protocol/lufa/lufa.c
View File

@ -86,7 +86,7 @@ extern keymap_config_t keymap_config;
#endif
#ifdef JOYSTICK_ENABLE
#include "joystick.h"
# include "joystick.h"
#endif
uint8_t keyboard_idle = 0;
@ -271,64 +271,58 @@ static void Console_Task(void) {
* Joystick
******************************************************************************/
#ifdef JOYSTICK_ENABLE
typedef struct {
#if JOYSTICK_AXES_COUNT>0
int8_t axes[JOYSTICK_AXES_COUNT];
#endif
#if JOYSTICK_BUTTON_COUNT>0
uint8_t buttons[(JOYSTICK_BUTTON_COUNT-1)/8+1];
#endif
} __attribute__ ((packed)) joystick_report_t;
void send_joystick_packet(joystick_t* joystick){
void send_joystick_packet(joystick_t *joystick) {
uint8_t timeout = 255;
uint8_t where = where_to_send();
if (where != OUTPUT_USB && where != OUTPUT_USB_AND_BT) {
return;
}
joystick_report_t r = {
#if JOYSTICK_AXES_COUNT>0
.axes = {
joystick->axes[0]
uint8_t where = where_to_send();
#if JOYSTICK_AXES_COUNT >= 2
,joystick->axes[1]
#endif
#if JOYSTICK_AXES_COUNT >= 3
,joystick->axes[2]
#endif
#if JOYSTICK_AXES_COUNT >= 4
,joystick->axes[3]
#endif
#if JOYSTICK_AXES_COUNT >= 5
,joystick->axes[4]
#endif
#if JOYSTICK_AXES_COUNT >= 6
,joystick->axes[5]
#endif
if (where != OUTPUT_USB && where != OUTPUT_USB_AND_BT) {
return;
}
joystick_report_t r = {
# if JOYSTICK_AXES_COUNT > 0
.axes = {joystick->axes[0]
# if JOYSTICK_AXES_COUNT >= 2
,
joystick->axes[1]
# endif
# if JOYSTICK_AXES_COUNT >= 3
,
joystick->axes[2]
# endif
# if JOYSTICK_AXES_COUNT >= 4
,
joystick->axes[3]
# endif
# if JOYSTICK_AXES_COUNT >= 5
,
joystick->axes[4]
# endif
# if JOYSTICK_AXES_COUNT >= 6
,
joystick->axes[5]
# endif
},
#endif //JOYSTICK_AXES_COUNT>0
#if JOYSTICK_BUTTON_COUNT>0
.buttons = {
joystick->buttons[0]
#if JOYSTICK_BUTTON_COUNT>8
,joystick->buttons[1]
#endif
#if JOYSTICK_BUTTON_COUNT>16
,joystick->buttons[2]
#endif
#if JOYSTICK_BUTTON_COUNT>24
,joystick->buttons[3]
#endif
# endif // JOYSTICK_AXES_COUNT>0
# if JOYSTICK_BUTTON_COUNT > 0
.buttons = {joystick->buttons[0]
# if JOYSTICK_BUTTON_COUNT > 8
,
joystick->buttons[1]
# endif
# if JOYSTICK_BUTTON_COUNT > 16
,
joystick->buttons[2]
# endif
# if JOYSTICK_BUTTON_COUNT > 24
,
joystick->buttons[3]
# endif
}
#endif //JOYSTICK_BUTTON_COUNT>0
# endif // JOYSTICK_BUTTON_COUNT>0
};
/* Select the Joystick Report Endpoint */
@ -494,8 +488,7 @@ void EVENT_USB_Device_ConfigurationChanged(void) {
ConfigSuccess &= Endpoint_ConfigureEndpoint(CDC_IN_EPADDR, EP_TYPE_BULK, CDC_EPSIZE, ENDPOINT_BANK_SINGLE);
#endif
#ifdef JOYSTICK_ENABLE
ConfigSuccess &= ENDPOINT_CONFIG(JOYSTICK_IN_EPNUM, EP_TYPE_INTERRUPT, ENDPOINT_DIR_IN,
JOYSTICK_EPSIZE, ENDPOINT_BANK_SINGLE);
ConfigSuccess &= ENDPOINT_CONFIG(JOYSTICK_IN_EPNUM, EP_TYPE_INTERRUPT, ENDPOINT_DIR_IN, JOYSTICK_EPSIZE, ENDPOINT_BANK_SINGLE);
#endif
}

76
tmk_core/protocol/usb_descriptor.c
View File

@ -279,51 +279,58 @@ const USB_Descriptor_HIDReport_Datatype_t PROGMEM ConsoleReport[] = {
#endif
#ifdef JOYSTICK_ENABLE
#if JOYSTICK_AXES_COUNT == 0 && JOYSTICK_BUTTON_COUNT == 0
#error Need at least one axis or button for joystick
#endif
const USB_Descriptor_HIDReport_Datatype_t PROGMEM JoystickReport[] =
{
HID_RI_USAGE_PAGE(8, 0x01), /* Generic Desktop */
HID_RI_USAGE(8, 0x04), /* Joystick */
HID_RI_COLLECTION(8, 0x01), /* Application */
HID_RI_COLLECTION(8, 0x00), /* Physical */
HID_RI_USAGE_PAGE(8, 0x01), /* Generic Desktop */
#if JOYSTICK_AXES_COUNT >= 1
HID_RI_USAGE_PAGE(8, 0x01), /* Generic Desktop */
#if JOYSTICK_AXES_COUNT >= 1
HID_RI_USAGE(8, 0x30), // USAGE (X)
#endif
#if JOYSTICK_AXES_COUNT >= 2
#if JOYSTICK_AXES_COUNT >= 2
HID_RI_USAGE(8, 0x31), // USAGE (Y)
#endif
#if JOYSTICK_AXES_COUNT >= 3
#if JOYSTICK_AXES_COUNT >= 3
HID_RI_USAGE(8, 0x32), // USAGE (Z)
#endif
#if JOYSTICK_AXES_COUNT >= 4
#if JOYSTICK_AXES_COUNT >= 4
HID_RI_USAGE(8, 0x33), // USAGE (RX)
#endif
#if JOYSTICK_AXES_COUNT >= 5
#if JOYSTICK_AXES_COUNT >= 5
HID_RI_USAGE(8, 0x34), // USAGE (RY)
#endif
#if JOYSTICK_AXES_COUNT >= 6
#if JOYSTICK_AXES_COUNT >= 6
HID_RI_USAGE(8, 0x35), // USAGE (RZ)
#endif
HID_RI_LOGICAL_MINIMUM(8, -127),
HID_RI_LOGICAL_MAXIMUM(8, 127),
HID_RI_REPORT_COUNT(8, JOYSTICK_AXES_COUNT),
HID_RI_REPORT_SIZE(8, 0x08),
HID_RI_INPUT(8, HID_IOF_DATA | HID_IOF_VARIABLE | HID_IOF_ABSOLUTE),
#if JOYSTICK_AXES_COUNT >= 1
HID_RI_LOGICAL_MINIMUM(8, -127),
HID_RI_LOGICAL_MAXIMUM(8, 127),
HID_RI_REPORT_COUNT(8, JOYSTICK_AXES_COUNT),
HID_RI_REPORT_SIZE(8, 0x08),
HID_RI_INPUT(8, HID_IOF_DATA | HID_IOF_VARIABLE | HID_IOF_ABSOLUTE),
#endif
HID_RI_USAGE_PAGE(8, 0x09), /* Button */
HID_RI_USAGE_MINIMUM(8, 0x01), /* Button 1 */
HID_RI_USAGE_MAXIMUM(8, JOYSTICK_BUTTON_COUNT), /* Button 5 */
HID_RI_LOGICAL_MINIMUM(8, 0x00),
HID_RI_LOGICAL_MAXIMUM(8, 0x01),
HID_RI_REPORT_COUNT(8, JOYSTICK_BUTTON_COUNT),
HID_RI_REPORT_SIZE(8, 0x01),
HID_RI_INPUT(8, HID_IOF_DATA | HID_IOF_VARIABLE | HID_IOF_ABSOLUTE),
#if JOYSTICK_BUTTON_COUNT >= 1
HID_RI_USAGE_PAGE(8, 0x09), /* Button */
HID_RI_USAGE_MINIMUM(8, 0x01), /* Button 1 */
HID_RI_USAGE_MAXIMUM(8, JOYSTICK_BUTTON_COUNT), /* Button max */
HID_RI_LOGICAL_MINIMUM(8, 0x00),
HID_RI_LOGICAL_MAXIMUM(8, 0x01),
HID_RI_REPORT_COUNT(8, JOYSTICK_BUTTON_COUNT),
HID_RI_REPORT_SIZE(8, 0x01),
HID_RI_INPUT(8, HID_IOF_DATA | HID_IOF_VARIABLE | HID_IOF_ABSOLUTE),
#if (JOYSTICK_BUTTON_COUNT % 8) != 0
HID_RI_REPORT_SIZE(8, 0x01),
HID_RI_REPORT_COUNT(8, 8 - (JOYSTICK_BUTTON_COUNT % 8)),
HID_RI_INPUT(8, HID_IOF_CONSTANT),
#endif
#if (JOYSTICK_BUTTON_COUNT % 8) != 0
HID_RI_REPORT_SIZE(8, 0x01),
HID_RI_REPORT_COUNT(8, 8 - (JOYSTICK_BUTTON_COUNT % 8)),
HID_RI_INPUT(8, HID_IOF_CONSTANT),
#endif
#endif
HID_RI_END_COLLECTION(0),
HID_RI_END_COLLECTION(0),
};
@ -863,7 +870,6 @@ const USB_Descriptor_Configuration_t PROGMEM ConfigurationDescriptor = {
},
#endif
/*
* Joystick
*/
@ -902,7 +908,7 @@ const USB_Descriptor_Configuration_t PROGMEM ConfigurationDescriptor = {
.EndpointAddress = (ENDPOINT_DIR_IN | JOYSTICK_IN_EPNUM),
.Attributes = (EP_TYPE_INTERRUPT | ENDPOINT_ATTR_NO_SYNC | ENDPOINT_USAGE_DATA),
.EndpointSize = JOYSTICK_EPSIZE,
.PollingIntervalMS = 0x0A
.PollingIntervalMS = USB_POLLING_INTERVAL_MS
},
#endif
};
@ -1038,10 +1044,10 @@ uint16_t get_usb_descriptor(const uint16_t wValue, const uint16_t wIndex, const
break;
#endif
#ifdef JOYSTICK_ENABLE
case JOYSTICK_INTERFACE:
Address = &ConfigurationDescriptor.Joystick_HID;
Size = sizeof(USB_HID_Descriptor_HID_t);
break;
case JOYSTICK_INTERFACE:
Address = &ConfigurationDescriptor.Joystick_HID;
Size = sizeof(USB_HID_Descriptor_HID_t);
break;
#endif
}
@ -1088,10 +1094,10 @@ uint16_t get_usb_descriptor(const uint16_t wValue, const uint16_t wIndex, const
break;
#endif
#ifdef JOYSTICK_ENABLE
case JOYSTICK_INTERFACE:
Address = &JoystickReport;
Size = sizeof(JoystickReport);
break;
case JOYSTICK_INTERFACE:
Address = &JoystickReport;
Size = sizeof(JoystickReport);
break;
#endif
}

8
tmk_core/protocol/usb_descriptor.h
View File

@ -126,9 +126,9 @@ typedef struct {
#ifdef JOYSTICK_ENABLE
// Joystick HID Interface
USB_Descriptor_Interface_t Joystick_Interface;
USB_HID_Descriptor_HID_t Joystick_HID;
USB_Descriptor_Endpoint_t Joystick_INEndpoint;
USB_Descriptor_Interface_t Joystick_Interface;
USB_HID_Descriptor_HID_t Joystick_HID;
USB_Descriptor_Endpoint_t Joystick_INEndpoint;
#endif
} USB_Descriptor_Configuration_t;
@ -235,7 +235,7 @@ enum usb_endpoints {
# define CDC_OUT_EPADDR (ENDPOINT_DIR_OUT | CDC_OUT_EPNUM)
#endif
#ifdef JOYSTICK_ENABLE
JOYSTICK_IN_EPNUM = NEXT_EPNUM,
JOYSTICK_IN_EPNUM = NEXT_EPNUM,
JOYSTICK_OUT_EPNUM = NEXT_EPNUM,
#endif
};

221
tmk_core/protocol/vusb/vusb.c
View File

@ -27,7 +27,6 @@ along with this program. If not, see <http://www.gnu.org/licenses/>.
#include "host_driver.h"
#include "vusb.h"
#include "joystick.h"
#include "joystick.h"
#include <util/delay.h>
static uint8_t vusb_keyboard_leds = 0;
@ -144,64 +143,67 @@ static void send_consumer(uint16_t data) {
typedef struct {
uint8_t report_id;
#if JOYSTICK_AXES_COUNT>0
int8_t axes[JOYSTICK_AXES_COUNT];
#endif
#if JOYSTICK_AXES_COUNT > 0
int8_t axes[JOYSTICK_AXES_COUNT];
#endif
#if JOYSTICK_BUTTON_COUNT>0
uint8_t buttons[(JOYSTICK_BUTTON_COUNT-1)/8+1];
#endif
} __attribute__ ((packed)) vusb_joystick_report_t;
#if JOYSTICK_BUTTON_COUNT > 0
uint8_t buttons[(JOYSTICK_BUTTON_COUNT - 1) / 8 + 1];
#endif
} __attribute__((packed)) vusb_joystick_report_t;
void send_joystick_packet(joystick_t* status)
{
void send_joystick_packet(joystick_t *status) {
vusb_joystick_report_t r = {
.report_id = REPORT_ID_JOYSTICK,
#if JOYSTICK_AXES_COUNT>0
.axes = {
status->axes[0]
#if JOYSTICK_AXES_COUNT > 0
.axes = {status->axes[0]
#if JOYSTICK_AXES_COUNT >= 2
,status->axes[1]
#endif
#if JOYSTICK_AXES_COUNT >= 3
,status->axes[2]
#endif
#if JOYSTICK_AXES_COUNT >= 4
,status->axes[3]
#endif
#if JOYSTICK_AXES_COUNT >= 5
,status->axes[4]
#endif
#if JOYSTICK_AXES_COUNT >= 6
,status->axes[5]
#endif
# if JOYSTICK_AXES_COUNT >= 2
,
status->axes[1]
# endif
# if JOYSTICK_AXES_COUNT >= 3
,
status->axes[2]
# endif
# if JOYSTICK_AXES_COUNT >= 4
,
status->axes[3]
# endif
# if JOYSTICK_AXES_COUNT >= 5
,
status->axes[4]
# endif
# if JOYSTICK_AXES_COUNT >= 6
,
status->axes[5]
# endif
},
#endif //JOYSTICK_AXES_COUNT>0
#endif // JOYSTICK_AXES_COUNT>0
#if JOYSTICK_BUTTON_COUNT>0
.buttons = {
status->buttons[0]
#if JOYSTICK_BUTTON_COUNT > 0
.buttons = {status->buttons[0]
#if JOYSTICK_BUTTON_COUNT>8
,status->buttons[1]
#endif
#if JOYSTICK_BUTTON_COUNT>16
,status->buttons[2]
#endif
#if JOYSTICK_BUTTON_COUNT>24
,status->buttons[3]
#endif
# if JOYSTICK_BUTTON_COUNT > 8
,
status->buttons[1]
# endif
# if JOYSTICK_BUTTON_COUNT > 16
,
status->buttons[2]
# endif
# if JOYSTICK_BUTTON_COUNT > 24
,
status->buttons[3]
# endif
}
#endif //JOYSTICK_BUTTON_COUNT>0
#endif // JOYSTICK_BUTTON_COUNT>0
};
if (usbInterruptIsReady3()) {
usbSetInterrupt3((void *)&r, sizeof(vusb_joystick_report_t));
}
}
/*------------------------------------------------------------------*
* Request from host *
*------------------------------------------------------------------*/
@ -395,57 +397,58 @@ const PROGMEM uchar mouse_extra_hid_report[] = {
0x81, 0x00, // Input (Data, Array, Absolute)
0xC0 // End Collection
# endif
#if JOYSTICK_ENABLE
0x05, 0x01, // USAGE_PAGE (Generic Desktop)
0x09, 0x04, // USAGE (Joystick)
0xa1, 0x01, // COLLECTION (Application)
0x85, REPORT_ID_JOYSTICK, // REPORT_ID (6)
0x09, 0x01, // USAGE (Pointer)
0xa1, 0x00, // COLLECTION (Physical)
#if JOYSTICK_AXES_COUNT > 0
#if JOYSTICK_AXES_COUNT >= 1
0x09, 0x30, // USAGE (X)
#endif
#if JOYSTICK_AXES_COUNT >= 2
0x09, 0x31, // USAGE (Y)
#endif
#if JOYSTICK_AXES_COUNT >= 3
0x09, 0x32, // USAGE (Z)
#endif
#if JOYSTICK_AXES_COUNT >= 4
0x09, 0x33, // USAGE (RX)
#endif
#if JOYSTICK_AXES_COUNT >= 5
0x09, 0x34, // USAGE (RY)
#endif
#if JOYSTICK_AXES_COUNT >= 6
0x09, 0x35, // USAGE (RZ)
#endif
0x15, 0x81, // LOGICAL_MINIMUM (-127)
0x25, 0x7f, // LOGICAL_MAXIMUM (127)
0x75, 0x08, // REPORT_SIZE (8)
0x95, JOYSTICK_AXES_COUNT, // REPORT_COUNT (JOYSTICK_AXES_COUNT)
0x81, 0x02, // INPUT (Data,Var,Abs)
#endif
#if JOYSTICK_BUTTON_COUNT> 0
0x05, 0x09, // USAGE_PAGE (Button)
0x19, 0x01, // USAGE_MINIMUM (Button 1)
0x29, JOYSTICK_BUTTON_COUNT, // USAGE_MAXIMUM
0x15, 0x00, // LOGICAL_MINIMUM (0)
0x25, 0x01, // LOGICAL_MAXIMUM (1)
0x75, 0x01, // REPORT_SIZE (1)
0x95, JOYSTICK_BUTTON_COUNT, // REPORT_COUNT
0x81, 0x02, // INPUT (Data,Var,Abs)
//fill up report to get it byte-aligned
#if (JOYSTICK_BUTTON_COUNT % 8) != 0
0x75, 0x01, // REPORT_SIZE (1)
0x95, 8 - (JOYSTICK_BUTTON_COUNT % 8), // REPORT_COUNT
0x81, 0x01, // INPUT (Data,Var,Abs)
#endif
#endif
0xc0, // END_COLLECTION
0xc0 // END_COLLECTION
#endif //JOYSTICK_ENABLE
# if JOYSTICK_ENABLE
0x05,
0x01, // USAGE_PAGE (Generic Desktop)
0x09, 0x04, // USAGE (Joystick)
0xa1, 0x01, // COLLECTION (Application)
0x85, REPORT_ID_JOYSTICK, // REPORT_ID (6)
0x09, 0x01, // USAGE (Pointer)
0xa1, 0x00, // COLLECTION (Physical)
# if JOYSTICK_AXES_COUNT > 0
# if JOYSTICK_AXES_COUNT >= 1
0x09, 0x30, // USAGE (X)
# endif
# if JOYSTICK_AXES_COUNT >= 2
0x09, 0x31, // USAGE (Y)
# endif
# if JOYSTICK_AXES_COUNT >= 3
0x09, 0x32, // USAGE (Z)
# endif
# if JOYSTICK_AXES_COUNT >= 4
0x09, 0x33, // USAGE (RX)
# endif
# if JOYSTICK_AXES_COUNT >= 5
0x09, 0x34, // USAGE (RY)
# endif
# if JOYSTICK_AXES_COUNT >= 6
0x09, 0x35, // USAGE (RZ)
# endif
0x15, 0x81, // LOGICAL_MINIMUM (-127)
0x25, 0x7f, // LOGICAL_MAXIMUM (127)
0x75, 0x08, // REPORT_SIZE (8)
0x95, JOYSTICK_AXES_COUNT, // REPORT_COUNT (JOYSTICK_AXES_COUNT)
0x81, 0x02, // INPUT (Data,Var,Abs)
# endif
# if JOYSTICK_BUTTON_COUNT > 0
0x05, 0x09, // USAGE_PAGE (Button)
0x19, 0x01, // USAGE_MINIMUM (Button 1)
0x29, JOYSTICK_BUTTON_COUNT, // USAGE_MAXIMUM
0x15, 0x00, // LOGICAL_MINIMUM (0)
0x25, 0x01, // LOGICAL_MAXIMUM (1)
0x75, 0x01, // REPORT_SIZE (1)
0x95, JOYSTICK_BUTTON_COUNT, // REPORT_COUNT
0x81, 0x02, // INPUT (Data,Var,Abs)
// fill up report to get it byte-aligned
# if (JOYSTICK_BUTTON_COUNT % 8) != 0
0x75, 0x01, // REPORT_SIZE (1)
0x95, 8 - (JOYSTICK_BUTTON_COUNT % 8), // REPORT_COUNT
0x81, 0x01, // INPUT (Data,Var,Abs)
# endif
# endif
0xc0, // END_COLLECTION
0xc0 // END_COLLECTION
# endif // JOYSTICK_ENABLE
};
#endif
@ -468,19 +471,19 @@ const PROGMEM char usbDescriptorConfiguration[] = {
/* USB configuration descriptor */
9, /* sizeof(usbDescriptorConfiguration): length of descriptor in bytes */
USBDESCR_CONFIG, /* descriptor type */
# if defined (MOUSE_ENABLE) || defined(EXTRAKEY_ENABLE)
59, // 9 + (9 + 9 + 7) + (9 + 9 + 7)
#else
34, // 9 + (9 + 9 + 7)
# if defined(MOUSE_ENABLE) || defined(EXTRAKEY_ENABLE)
59, // 9 + (9 + 9 + 7) + (9 + 9 + 7)
# else
34, // 9 + (9 + 9 + 7)
# endif
0,
// 18 + 7 * USB_CFG_HAVE_INTRIN_ENDPOINT + 7 * USB_CFG_HAVE_INTRIN_ENDPOINT3 + 9, 0,
/* total length of data returned (including inlined descriptors) */
// 18 + 7 * USB_CFG_HAVE_INTRIN_ENDPOINT + 7 * USB_CFG_HAVE_INTRIN_ENDPOINT3 + 9, 0,
/* total length of data returned (including inlined descriptors) */
# if defined(MOUSE_ENABLE) || defined(EXTRAKEY_ENABLE)
2, /* number of interfaces in this configuration */
# else
1,
#endif
# endif
1, /* index of this configuration */
0, /* configuration name string index */
# if USB_CFG_IS_SELF_POWERED
@ -533,13 +536,13 @@ const PROGMEM char usbDescriptorConfiguration[] = {
0, /* PROTOCOL: none */
0, /* string index for interface */
/* HID descriptor */
9, /* sizeof(usbDescrHID): length of descriptor in bytes */
USBDESCR_HID, /* descriptor type: HID */
0x01, 0x01, /* BCD representation of HID version */
0x00, /* target country code */
0x01, /* number of HID Report (or other HID class) Descriptor infos to follow */
0x22, /* descriptor type: report */
sizeof(mouse_extra_hid_report), 0, /* total length of report descriptor */
9, /* sizeof(usbDescrHID): length of descriptor in bytes */
USBDESCR_HID, /* descriptor type: HID */
0x01, 0x01, /* BCD representation of HID version */
0x00, /* target country code */
0x01, /* number of HID Report (or other HID class) Descriptor infos to follow */
0x22, /* descriptor type: report */
sizeof(mouse_extra_hid_report), 0, /* total length of report descriptor */
# if USB_CFG_HAVE_INTRIN_ENDPOINT3 /* endpoint descriptor for endpoint 3 */
/* Endpoint descriptor */
7, /* sizeof(usbDescrEndpoint) */