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#include "tusb.h"
#include "tusb_helpers.h" /* for TUD_ENDPOINT_IN */
#include "usb_common.h"
#include "usb_keyboard.h"
/**
* A USB-HID "Report Descriptor" (see USB-HID 1.11 §6.2.2 "Report
* Descriptor") describing a keyboard.
*/
static uint8_t const hid_report_descriptor_keyboard[] = { TUD_HID_REPORT_DESC_KEYBOARD() };
static uint8_t kbd_ifc = 0;
void usb_keyboard_init() {
if (kbd_ifc)
return;
usb_common_init();
kbd_ifc = usb_add_interface(cfgnum_std, TUD_HID_DESC_LEN, (uint8_t[]){
/* USB-HID input-only descriptor for inclusion in the config descriptor; consisting of 3 parts:
* 1. an interface descriptor (USB 2.0 §9.6.5 "Interface"),
* 2. a class-specific (class=HID) descriptor of type HID (USB-HID 1.11 §6.2.1 "HID Descriptor"),
* 3. an endpoint descriptor for inputs (USB 2.0 §9.6.6 "Endpoint").
* The TUD_HID_DESCRIPTOR() macro takes care of this for us. */
TUD_HID_DESCRIPTOR(
0, /* interface : bInterfaceNumber ; Number of this interface (0-indexed) */
STRID_KBD_IFC, /* interface : iInterface ; Index of string descriptor describing this interface */
HID_ITF_PROTOCOL_KEYBOARD, /* interface : bInterfaceProtocol ; see USB-HID 1.11 §4.3 "Protocols" */
sizeof(hid_report_descriptor_keyboard), /* hid : wDescriptorLength ; Total size of report descriptor */
TUD_ENDPOINT_IN | 1, /* endpoint : bEndpointAddress ; Direction | endpoint number (arbitrary?) */
CFG_TUD_HID_EP_BUFSIZE, /* endpoint : wMaxPacketSize ; Maximum packet size this endpoint is capable of sending or receiving */
10), /* endpoint : bInterval ; poll interval (in milliseconds?) */
});
}
#define kbd_buf_cap 1024
static uint32_t kbd_buf[kbd_buf_cap];
static size_t kbd_buf_beg = 0;
static size_t kbd_buf_len = 0;
static uint8_t ascii2keycode[128][2] = { HID_ASCII_TO_KEYCODE };
void usb_keyboard_task(void) {
if (tud_hid_n_ready(kbd_ifc)) {
uint8_t const report_id = 0;
uint8_t modifier = 0;
uint8_t keycodes[6] = {0};
if (kbd_buf_len) {
if (ascii2keycode[kbd_buf[kbd_buf_beg]][0])
modifier = KEYBOARD_MODIFIER_LEFTSHIFT;
keycodes[0] = ascii2keycode[kbd_buf[kbd_buf_beg]][1];
kbd_buf_beg++;
if (kbd_buf_beg == kbd_buf_cap)
kbd_buf_beg = 0;
kbd_buf_len--;
}
tud_hid_n_keyboard_report(kbd_ifc, report_id, modifier, keycodes);
}
}
bool usb_keyboard_send_char(uint32_t ch) {
if (kbd_buf_len == kbd_buf_cap) /* buffer full */
return false;
if (ch > 0x7F) /* not ASCII */
return false;
kbd_buf[(kbd_buf_beg + kbd_buf_len++) % kbd_buf_cap] = ch;
}
bool usb_keyboard_is_flushed(void) {
return kbd_buf_len == 0;
}
/**
* Return a pointer to the HID "Report Descriptor" (see USB-HID 1.11
* §6.2.2 "Report Descriptor") for the given index.
*/
uint8_t const *tud_hid_descriptor_report_cb(uint8_t index) {
static uint8_t const *reports[] = {
hid_report_descriptor_keyboard,
};
if (index >= sizeof reports / sizeof reports[0])
return NULL;
return reports[index];
}
uint16_t tud_hid_get_report_cb(uint8_t instance, uint8_t report_id, hid_report_type_t report_type, uint8_t* buffer, uint16_t reqlen)
{
// TODO not Implemented
(void) instance;
(void) report_id;
(void) report_type;
(void) buffer;
(void) reqlen;
return 0;
}
// Invoked when received SET_REPORT control request or
// received data on OUT endpoint ( Report ID = 0, Type = 0 )
void tud_hid_set_report_cb(uint8_t instance, uint8_t report_id, hid_report_type_t report_type, uint8_t const* buffer, uint16_t bufsize)
{
// TODO not implemented
(void) report_id;
}
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