We assume that an LED is connected to port B bit 0. If you connect it to a
different port or bit, change the macros below:
*/
-#define LED_PORT_DDR DDRB
-#define LED_PORT_OUTPUT PORTB
-#define R_BIT 4
-#define G_BIT 3
-#define B_BIT 1
#define BUTTON_PIN 4
+#define SIMPLE_COUNTER 1
+
#include <stdint.h>
#include <string.h>
#include <stdbool.h>
#include "usbdrv.h"
#include "oddebug.h" /* This is also an example for using debug macros */
#include "requests.h" /* The custom request numbers we use */
-#include "special_functions.h"
#include "hotp.h"
+#if !SIMPLE_COUNTER
#include "percnt2.h"
+#endif
+#include "usb_keyboard_codes.h"
/* ------------------------------------------------------------------------- */
/* ----------------------------- USB interface ----------------------------- */
/* ------------------------------------------------------------------------- */
+
+#define STATE_WAIT 0
+#define STATE_SEND_KEY 1
+#define STATE_RELEASE_KEY 2
+#define STATE_NEXT 3
+
PROGMEM const char usbHidReportDescriptor[USB_CFG_HID_REPORT_DESCRIPTOR_LENGTH] = {
0x05, 0x01, // USAGE_PAGE (Generic Desktop)
0x09, 0x06, // USAGE (Keyboard)
0xc0 // END_COLLECTION
};
-uint16_t secret_length_ee EEMEM = 0;
-uint8_t secret_ee[32] EEMEM;
-uint8_t reset_counter_ee EEMEM = 0;
-uint8_t digits_ee EEMEM = 8;
+static uint16_t secret_length_ee EEMEM = 0;
+static uint8_t secret_ee[32] EEMEM;
+static uint8_t reset_counter_ee EEMEM = 0;
+static uint8_t digits_ee EEMEM = 8;
-/* Keyboard usage values, see usb.org's HID-usage-tables document, chapter
- * 10 Keyboard/Keypad Page for more codes.
- */
-#define MOD_CONTROL_LEFT (1<<0)
-#define MOD_SHIFT_LEFT (1<<1)
-#define MOD_ALT_LEFT (1<<2)
-#define MOD_GUI_LEFT (1<<3)
-#define MOD_CONTROL_RIGHT (1<<4)
-#define MOD_SHIFT_RIGHT (1<<5)
-#define MOD_ALT_RIGHT (1<<6)
-#define MOD_GUI_RIGHT (1<<7)
-
-#define KEY_A 4
-#define KEY_B 5
-#define KEY_C 6
-#define KEY_D 7
-#define KEY_E 8
-#define KEY_F 9
-#define KEY_G 10
-#define KEY_H 11
-#define KEY_I 12
-#define KEY_J 13
-#define KEY_K 14
-#define KEY_L 15
-#define KEY_M 16
-#define KEY_N 17
-#define KEY_O 18
-#define KEY_P 19
-#define KEY_Q 20
-#define KEY_R 21
-#define KEY_S 22
-#define KEY_T 23
-#define KEY_U 24
-#define KEY_V 25
-#define KEY_W 26
-#define KEY_X 27
-#define KEY_Y 28
-#define KEY_Z 29
-#define KEY_1 30
-#define KEY_2 31
-#define KEY_3 32
-#define KEY_4 33
-#define KEY_5 34
-#define KEY_6 35
-#define KEY_7 36
-#define KEY_8 37
-#define KEY_9 38
-#define KEY_0 39
-
-#define KEY_F1 58
-#define KEY_F2 59
-#define KEY_F3 60
-#define KEY_F4 61
-#define KEY_F5 62
-#define KEY_F6 63
-#define KEY_F7 64
-#define KEY_F8 65
-#define KEY_F9 66
-#define KEY_F10 67
-#define KEY_F11 68
-#define KEY_F12 69
-
-#define NUM_LOCK 1
-#define CAPS_LOCK 2
-#define SCROLL_LOCK 4
+#if SIMPLE_COUNTER
+static uint32_t counter_ee EEMEM = 0;
+#endif
static uint8_t dbg_buffer[8];
-
static uint8_t secret[32];
static uint16_t secret_length_b;
static char token[10];
+#define UNI_BUFFER_SIZE 16
-#define UNI_BUFFER_SIZE 36
-
-static union {
+static union __attribute__((packed)) {
uint8_t w8[UNI_BUFFER_SIZE];
uint16_t w16[UNI_BUFFER_SIZE/2];
uint32_t w32[UNI_BUFFER_SIZE/4];
uint8_t keycode[6];
} keyboard_report_t;
-#define STATE_WAIT 0
-#define STATE_SEND_KEY 1
-#define STATE_RELEASE_KEY 2
-#define STATE_NEXT 3
-
-
-static keyboard_report_t keyboard_report; // sent to PC
-static uchar idleRate; /* in 4 ms units */
+static keyboard_report_t keyboard_report; /* report sent to the host */
+static uchar idleRate; /* in 4 ms units */
static uchar key_state = STATE_WAIT;
-volatile static uchar LED_state = 0xff; // received from PC
+volatile static uchar LED_state = 0xff;
/* ------------------------------------------------------------------------- */
+static
void memory_clean(void) {
memset(secret, 0, 32);
secret_length_b = 0;
}
+#define NO_CHECK 1
+
+static
uint8_t secret_set(void){
+#if !NO_CHECK
uint8_t r;
union {
uint8_t w8[32];
uint16_t w16[16];
} read_back;
+#endif
const uint8_t length_B = (secret_length_b + 7) / 8;
eeprom_busy_wait();
eeprom_write_block(secret, secret_ee, length_B);
+#if !NO_CHECK
eeprom_busy_wait();
eeprom_read_block(read_back.w8, secret_ee, length_B);
r = memcmp(secret, read_back.w8, length_B);
if (r) {
return 1;
}
+#endif
eeprom_busy_wait();
eeprom_write_word(&secret_length_ee, secret_length_b);
+#if !NO_CHECK
eeprom_busy_wait();
r = eeprom_read_word(&secret_length_ee) == secret_length_b;
memory_clean();
if (!r) {
return 1;
}
+#else
+ memory_clean();
+#endif
+
return 0;
}
-void token_generate(void) {
- percnt_inc(0);
+static
+void counter_inc(void){
+#if SIMPLE_COUNTER
+ uint32_t t;
eeprom_busy_wait();
- eeprom_read_block(secret, secret_ee, 32);
+ t = eeprom_read_dword(&counter_ee);
eeprom_busy_wait();
- hotp(token, secret, eeprom_read_word(&secret_length_ee), percnt_get(0), eeprom_read_byte(&digits_ee));
- memory_clean();
+ eeprom_write_dword(&counter_ee, t + 1);
+#else
+ percnt_inc(0);
+#endif
}
+static
void counter_reset(void) {
uint8_t reset_counter;
eeprom_busy_wait();
reset_counter = eeprom_read_byte(&reset_counter_ee);
+#if SIMPLE_COUNTER
+ eeprom_busy_wait();
+ eeprom_write_dword(&counter_ee, 0);
+#else
percnt_reset(0);
+#endif
eeprom_busy_wait();
eeprom_write_byte(&reset_counter_ee, reset_counter + 1);
}
+static
void counter_init(void) {
+#if !SIMPLE_COUNTER
eeprom_busy_wait();
if (eeprom_read_byte(&reset_counter_ee) == 0) {
counter_reset();
}
percnt_init(0);
+#endif
+}
+
+static
+void token_generate(void) {
+ counter_inc();
+ eeprom_busy_wait();
+ eeprom_read_block(secret, secret_ee, 32);
+ eeprom_busy_wait();
+#if SIMPLE_COUNTER
+ hotp(token, secret, eeprom_read_word(&secret_length_ee), eeprom_read_dword(&counter_ee), eeprom_read_byte(&digits_ee));
+#else
+ hotp(token, secret, eeprom_read_word(&secret_length_ee), percnt_get(0), eeprom_read_byte(&digits_ee));
+#endif
+ memory_clean();
}
+
+static
void buildReport(uchar send_key) {
keyboard_report.modifier = 0;
}
}
-uint8_t read_button(void){
- uint8_t t,v=0;
- t = DDRB;
- DDRB &= ~(1<<BUTTON_PIN);
- PORTB |= 1<<BUTTON_PIN;
- PORTB &= ~(1<<BUTTON_PIN);
- v |= PINB;
- DDRB |= t&(1<<BUTTON_PIN);
- PORTB &= ~(t&(1<<BUTTON_PIN));
- v >>= BUTTON_PIN;
- v &= 1;
- v ^= 1;
- return v;
-}
-
-void init_temperature_sensor(void){
- ADMUX = 0x8F;
- ADCSRA = 0x87;
-}
-
-uint16_t read_temperture_sensor(void){
- ADCSRA |= 0x40;
- while(ADCSRA & 0x40)
- ;
- return ADC;
+static
+int8_t button_get_debounced(volatile uint8_t debounce_count) {
+ uint8_t v;
+ v = PINB & _BV(BUTTON_PIN);
+ while (debounce_count-- && v == (PINB & _BV(BUTTON_PIN))) {
+ ;
+ }
+ if (debounce_count) {
+ return -1;
+ }
+ return v ? 0 : 1;
}
usbMsgLen_t usbFunctionSetup(uchar data[8])
uni_buffer.w8[0] = 0;
return USB_NO_MSG;
case CUSTOM_RQ_INC_COUNTER:
- percnt_inc(0);
+ counter_inc();
return 0;
case CUSTOM_RQ_GET_COUNTER:
+#if SIMPLE_COUNTER
+ eeprom_busy_wait();
+ uni_buffer.w32[0] = eeprom_read_dword(&counter_ee);
+#else
uni_buffer.w32[0] = percnt_get(0);
+#endif
usbMsgPtr = (usbMsgPtr_t)uni_buffer.w32;
return 4;
case CUSTOM_RQ_RESET_COUNTER:
return 1;
case CUSTOM_RQ_GET_TOKEN:
token_generate();
- usbMsgPtr = token;
+ usbMsgPtr = (usbMsgPtr_t)token;
return strlen(token);
case CUSTOM_RQ_PRESS_BUTTON:
usbMsgPtr = dbg_buffer;
return len;
}
- case CUSTOM_RQ_READ_MEM:
- usbMsgPtr = (uchar*)rq->wValue.word;
- return rq->wLength.word;
- case CUSTOM_RQ_WRITE_MEM:
- case CUSTOM_RQ_EXEC_SPM:
-/* uni_buffer_fill = 4;
- uni_buffer.w16[0] = rq->wValue.word;
- uni_buffer.w16[1] = rq->wLength.word;
- return USB_NO_MSG;
-*/ case CUSTOM_RQ_READ_FLASH:
- uni_buffer.w16[0] = rq->wValue.word;
- uni_buffer.w16[1] = rq->wLength.word;
- uni_buffer_fill = 4;
- return USB_NO_MSG;
case CUSTOM_RQ_RESET:
soft_reset((uint8_t)(rq->wValue.word));
break;
case CUSTOM_RQ_READ_BUTTON:
- uni_buffer.w8[0] = read_button();
+ uni_buffer.w8[0] = button_get_debounced(25);
usbMsgPtr = uni_buffer.w8;
return 1;
- case CUSTOM_RQ_READ_TMPSENS:
- uni_buffer.w16[0] = read_temperture_sensor();
- usbMsgPtr = uni_buffer.w8;
- return 2;
}
}
}
memcpy(dbg_buffer, data, len);
return 1;
- case CUSTOM_RQ_WRITE_MEM:
- memcpy(uni_buffer.ptr[0], data, len);
- uni_buffer.w16[0] += len;
- return !(uni_buffer.w16[1] -= len);
- case CUSTOM_RQ_EXEC_SPM:
- if(uni_buffer_fill < 8){
- uint8_t l = 8 - uni_buffer_fill;
- if(len<l){
- len = l;
- }
- memcpy(&(uni_buffer.w8[uni_buffer_fill]), data, len);
- uni_buffer_fill += len;
- return 0;
- }
- uni_buffer.w16[1] -= len;
- if (uni_buffer.w16[1] > 8) {
- memcpy(uni_buffer.ptr[0], data, len);
- uni_buffer.w16[0] += len;
- return 0;
- } else {
- memcpy(&(uni_buffer.w8[uni_buffer_fill]), data, len);
- exec_spm(uni_buffer.w16[2], uni_buffer.w16[3], uni_buffer.ptr[0], data, len);
- return 1;
- }
default:
return 1;
}
return 0;
}
uchar usbFunctionRead(uchar *data, uchar len){
- uchar ret = len;
- switch(current_command){
- case CUSTOM_RQ_READ_FLASH:
- while(len--){
- *data++ = pgm_read_byte((uni_buffer.w16[0])++);
- }
- return ret;
- default:
- break;
- }
return 0;
}
/* ------------------------------------------------------------------------- */
-char key_seq[] = "Hello World";
-
int main(void)
{
- uchar i;
size_t idx = 0;
+ int8_t i = 0, last_stable_button_state = 0;
wdt_enable(WDTO_1S);
/* Even if you don't use the watchdog, turn it off here. On newer devices,
* additional hardware initialization.
*/
- init_temperature_sensor();
+ DDRB &= ~_BV(BUTTON_PIN); /* make button pin input */
+ PORTB |= _BV(BUTTON_PIN); /* turn on pull-up resistor */
+ counter_init();
usbInit();
usbDeviceDisconnect(); /* enforce re-enumeration, do this while interrupts are disabled! */
- i = 0;
while(--i){ /* fake USB disconnect for ~512 ms */
wdt_reset();
_delay_ms(2);
}
usbDeviceConnect();
- LED_PORT_DDR |= _BV(R_BIT) | _BV(G_BIT) | _BV(B_BIT); /* make the LED bit an output */
-
sei();
wdt_reset();
usbPoll();
+ i = button_get_debounced(25);
+ if (i != -1) {
+ if (last_stable_button_state == 0 && i == 1) {
+ key_state = STATE_SEND_KEY;
+ }
+ last_stable_button_state = i;
+ }
+
if(usbInterruptIsReady() && key_state != STATE_WAIT){
switch(key_state) {
case STATE_SEND_KEY:
- buildReport(key_seq[idx]);
+ buildReport(token[idx]);
key_state = STATE_RELEASE_KEY; // release next
break;
case STATE_RELEASE_KEY:
buildReport(0);
++idx;
- if (key_seq[idx] == '\0') {
+ if (token[idx] == '\0') {
idx = 0;
key_state = STATE_WAIT;
} else {