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|
/***************************************************************************
* __________ __ ___.
* Open \______ \ ____ ____ | | _\_ |__ _______ ___
* Source | _// _ \_/ ___\| |/ /| __ \ / _ \ \/ /
* Jukebox | | ( <_> ) \___| < | \_\ ( <_> > < <
* Firmware |____|_ /\____/ \___ >__|_ \|___ /\____/__/\_ \
* \/ \/ \/ \/ \/
* $Id: $
*
* Copyright (C) 2011-2021 by Tomasz Moń
*
* This program is free software; you can redistribute it and/or
* modify it under the terms of the GNU General Public License
* as published by the Free Software Foundation; either version 2
* of the License, or (at your option) any later version.
*
* This software is distributed on an "AS IS" basis, WITHOUT WARRANTY OF ANY
* KIND, either express or implied.
*
****************************************************************************/
#include <stdio.h>
#include "config.h"
#include "file.h"
#include "system.h"
#include "time.h"
#include "power.h"
#include "kernel.h"
#include "panic.h"
/*#define LOGF_ENABLE*/
#include "logf.h"
#include "avr-sansaconnect.h"
#include "uart-target.h"
#include "usb.h"
#include "button.h"
#include "backlight.h"
#include "powermgmt.h"
#include "aic3x.h"
//#define BUTTON_DEBUG
#ifdef BUTTON_DEBUG
#include "lcd-target.h"
#include "lcd.h"
#include "font.h"
#include "common.h"
#endif
#ifdef BUTTON_DEBUG
#define dbgprintf DEBUGF
#else
#define dbgprintf(...)
#endif
#define AVR_DELAY_US 200
#define AVR_MAX_RETRIES 10
#define CMD_SYNC 0xAA
#define CMD_CLOSE 0xCC
#define CMD_FILL 0xFF
/* Actual command opcodes handled by AVR */
#define CMD_STATE 0xBB
#define CMD_VER 0xBC
#define CMD_MONOTIME 0xBD
#define CMD_PGMWAKE 0xBF
#define CMD_HDQ_READ 0xC0
#define CMD_HDQ_WRITE 0xC1
#define CMD_HDQ_STATUS 0xC2
#define CMD_GET_LAST_RESET_TYPE 0xC4
#define CMD_UNKNOWN_C5 0xC5
#define CMD_GET_BATTERY_TEMP 0xC8
#define CMD_LCM_POWER 0xC9
#define CMD_AMP_ENABLE 0xCA
#define CMD_WHEEL_EN 0xD0
#define CMD_SET_INTCHRG 0xD1
#define CMD_GET_INTCHRG 0xD2
#define CMD_WIFI_PD 0xD3
#define CMD_UNKNOWN_D4 0xD4
#define CMD_UNKNOWN_D5 0xD5
#define CMD_UNKNOWN_D6 0xD6
#define CMD_CODEC_RESET 0xD7
#define CMD_ADC_START 0xD8
#define CMD_ADC_RESULT 0xD9
#define CMD_SYS_CTRL 0xDA
#define CMD_SET_USBCHRG 0xE2
#define CMD_GET_USBCHRG 0xE3
#define CMD_MONORSTCNT 0xE4
/* CMD_LCM_POWER parameters */
#define LCM_POWER_OFF 0x00
#define LCM_POWER_ON 0x01
#define LCM_POWER_SLEEP 0x02
#define LCM_POWER_WAKE 0x03
#define LCM_REPOWER_ON 0x04
/* CMD_SYS_CTRL parameters */
#define SYS_CTRL_POWEROFF 0x00
#define SYS_CTRL_RESET 0x01
#define SYS_CTRL_SLEEP 0x02
#define SYS_CTRL_DISABLE_WD 0x03
#define SYS_CTRL_KICK_WD 0x04
#define SYS_CTRL_EN_HDQ_THERM 0x05
#define SYS_CTRL_EN_TS_THERM 0x06
#define SYS_CTRL_FRESET 0x80
/* HDQ status codes */
#define HDQ_STATUS_OK 0x00
#define HDQ_STATUS_NOT_READY 0x01
#define HDQ_STATUS_TIMEOUT 0x02
/* protects spi avr commands from concurrent access */
static struct mutex avr_mtx;
/* serializes hdq read/write and status retrieval */
static struct mutex hdq_mtx;
/* AVR thread events */
#define INPUT_INTERRUPT 1
#define MONOTIME_OFFSET_UPDATE 2
#define POWER_OFF_REQUEST 3
static int btn = 0;
static bool hold_switch;
static bool input_interrupt_pending;
/* AVR implements 32-bit counter incremented every second.
* The counter value cannot be modified to arbitrary value,
* so the epoch offset needs to be stored in a file.
*/
#define MONOTIME_OFFSET_FILE ROCKBOX_DIR "/monotime_offset.dat"
static uint32_t monotime_offset;
/* Buffer last read monotime value. Reading monotime takes
* atleast 1400 us so the tick counter is used together with
* last read monotime value to return current time.
*/
static bool monotime_available;
static uint32_t monotime_value;
static unsigned long monotime_value_tick;
static long avr_stack[DEFAULT_STACK_SIZE/sizeof(long)];
static const char avr_thread_name[] = "avr";
static struct event_queue avr_queue;
/* OF bootloader will refuse to start software if low power is set
* Bits 3, 4, 5, 6 and 7 are unknown.
*/
#define BATTERY_STATUS_LOW_POWER (1 << 2)
#define BATTERY_STATUS_CHARGER_CONNECTED (1 << 1)
#define BATTERY_STATUS_CHARGING (1 << 0)
static uint8_t avr_battery_status;
#define BATTERY_LEVEL_NOT_DETECTED (1 << 7)
#define BATTERY_LEVEL_PERCENTAGE_MASK 0x7F
static uint8_t avr_battery_level = 100;
static inline uint16_t be2short(uint8_t *buf)
{
return (uint16_t)((buf[0] << 8) | buf[1]);
}
#define BUTTON_DIRECT_MASK (BUTTON_LEFT | BUTTON_UP | BUTTON_RIGHT | BUTTON_DOWN | BUTTON_SELECT | BUTTON_VOL_UP | BUTTON_VOL_DOWN | BUTTON_NEXT | BUTTON_PREV)
static void handle_wheel(uint8_t wheel)
{
static int key = 0;
static uint8_t velocity = 0;
static uint32_t wheel_delta = 1ul << 24;
static uint8_t wheel_prev = 0;
static unsigned long nextbacklight_hw_on = 0;
static int prev_key = -1;
static int prev_key_post = 0;
if (TIME_AFTER(current_tick, nextbacklight_hw_on))
{
backlight_on();
reset_poweroff_timer();
nextbacklight_hw_on = current_tick + HZ/4;
}
if (wheel_prev < wheel)
{
key = BUTTON_SCROLL_FWD;
velocity = wheel - wheel_prev;
}
else if (wheel_prev > wheel)
{
key = BUTTON_SCROLL_BACK;
velocity = wheel_prev - wheel;
}
if (prev_key != key && velocity < 2 /* filter "rewinds" */)
{
/* direction reversal */
prev_key = key;
wheel_delta = 1ul << 24;
return;
}
/* TODO: take velocity into account */
if (button_queue_empty())
{
if (prev_key_post == key)
{
key |= BUTTON_REPEAT;
}
/* Post directly, don't update btn as avr doesn't give
interrupt on scroll stop */
button_queue_post(key, wheel_delta);
wheel_delta = 1ul << 24;
prev_key_post = key;
}
else
{
/* skipped post - increment delta and limit to 7 bits */
wheel_delta += 1ul << 24;
if (wheel_delta > (0x7ful << 24))
wheel_delta = 0x7ful << 24;
}
wheel_prev = wheel;
prev_key = key;
}
/* buf must be 8-byte state array (reply from avr_hid_get_state() */
static void parse_button_state(uint8_t *state)
{
uint16_t main_btns_state = be2short(&state[2]);
#ifdef BUTTON_DEBUG
uint16_t main_btns_changed = be2short(&state[4]);
#endif
/* make sure other bits doesn't conflict with our "free bits" buttons */
main_btns_state &= BUTTON_DIRECT_MASK;
if (state[1] & 0x01) /* is power button pressed? */
{
main_btns_state |= BUTTON_POWER;
}
btn = main_btns_state;
/* check if stored hold_switch state changed (prevents lost changes) */
if ((state[1] & 0x20) /* hold change notification */ ||
(hold_switch != ((state[1] & 0x02) >> 1)))
{
hold_switch = (state[1] & 0x02) >> 1;
#ifdef BUTTON_DEBUG
dbgprintf("HOLD changed (%d)", hold_switch);
#endif
#ifndef BOOTLOADER
backlight_hold_changed(hold_switch);
#endif
}
if ((hold_switch == false) && (state[1] & 0x80)) /* scrollwheel change */
{
handle_wheel(state[0]);
}
#ifdef BUTTON_DEBUG
if (state[1] & 0x10) /* power button change */
{
/* power button state has changed */
main_btns_changed |= BUTTON_POWER;
}
if (btn & BUTTON_LEFT) dbgprintf("LEFT");
if (btn & BUTTON_UP) dbgprintf("UP");
if (btn & BUTTON_RIGHT) dbgprintf("RIGHT");
if (btn & BUTTON_DOWN) dbgprintf("DOWN");
if (btn & BUTTON_SELECT) dbgprintf("SELECT");
if (btn & BUTTON_VOL_UP) dbgprintf("VOL UP");
if (btn & BUTTON_VOL_DOWN) dbgprintf("VOL DOWN");
if (btn & BUTTON_NEXT) dbgprintf("NEXT");
if (btn & BUTTON_PREV) dbgprintf("PREV");
if (btn & BUTTON_POWER) dbgprintf("POWER");
if (btn & BUTTON_HOLD) dbgprintf("HOLD");
if (btn & BUTTON_SCROLL_FWD) dbgprintf("SCROLL FWD");
if (btn & BUTTON_SCROLL_BACK) dbgprintf("SCROLL BACK");
#endif
}
static bool avr_command_reads_data(uint8_t opcode)
{
switch (opcode)
{
case CMD_STATE:
case CMD_VER:
case CMD_GET_LAST_RESET_TYPE:
case CMD_GET_INTCHRG:
case CMD_MONOTIME:
case CMD_UNKNOWN_C5:
case CMD_MONORSTCNT:
case CMD_HDQ_STATUS:
case CMD_GET_BATTERY_TEMP:
case CMD_GET_USBCHRG:
case CMD_ADC_RESULT:
return true;
default:
return false;
}
}
static size_t avr_command_data_size(uint8_t opcode)
{
switch (opcode)
{
case CMD_STATE: return 8;
case CMD_VER: return 1;
case CMD_MONOTIME: return 4;
case CMD_PGMWAKE: return 4;
case CMD_HDQ_READ: return 1;
case CMD_HDQ_WRITE: return 2;
case CMD_HDQ_STATUS: return 2;
case CMD_GET_LAST_RESET_TYPE: return 1;
case CMD_UNKNOWN_C5: return 1;
case CMD_GET_BATTERY_TEMP: return 2;
case CMD_LCM_POWER: return 1;
case CMD_AMP_ENABLE: return 1;
case CMD_WHEEL_EN: return 1;
case CMD_SET_INTCHRG: return 1;
case CMD_GET_INTCHRG: return 1;
case CMD_WIFI_PD: return 1;
case CMD_UNKNOWN_D4: return 1;
case CMD_UNKNOWN_D5: return 2;
case CMD_UNKNOWN_D6: return 2;
case CMD_CODEC_RESET: return 0;
case CMD_ADC_START: return 1;
case CMD_ADC_RESULT: return 2;
case CMD_SYS_CTRL: return 1;
case CMD_SET_USBCHRG: return 1;
case CMD_GET_USBCHRG: return 1;
case CMD_MONORSTCNT: return 2;
default:
panicf("Invalid AVR opcode %02X", opcode);
return 0;
}
}
static uint8_t spi_read_byte(void)
{
uint16_t rxdata;
do
{
rxdata = IO_SERIAL1_RX_DATA;
}
while (rxdata & (1<<8));
return rxdata & 0xFF;
}
static void avr_hid_select(void)
{
/* Drive GIO29 (AVR SS) low */
IO_GIO_BITCLR1 = (1 << 13);
}
static void avr_hid_release(void)
{
/* Drive GIO29 (AVR SS) high */
IO_GIO_BITSET1 = (1 << 13);
}
static bool avr_run_command(uint8_t opcode, uint8_t *data, size_t data_length)
{
bool success = true;
const bool is_read = avr_command_reads_data(opcode);
size_t i;
uint8_t rx;
/* Verify command data size and also make sure command is valid */
if (avr_command_data_size(opcode) != data_length)
{
panicf("AVR %02x invalid data length", opcode);
}
mutex_lock(&avr_mtx);
bitset16(&IO_CLK_MOD2, CLK_MOD2_SIF1);
IO_SERIAL1_TX_ENABLE = 0x0001;
avr_hid_select();
udelay(10);
IO_SERIAL1_TX_DATA = CMD_SYNC;
spi_read_byte();
/* Allow AVR to process CMD_SYNC */
udelay(AVR_DELAY_US);
IO_SERIAL1_TX_DATA = opcode;
rx = spi_read_byte();
if (rx != CMD_SYNC)
{
/* AVR failed to register CMD_SYNC */
success = false;
}
/* Allow AVR to process opcode */
udelay(AVR_DELAY_US);
if (is_read)
{
for (i = 0; i < data_length; i++)
{
IO_SERIAL1_TX_DATA = CMD_FILL;
data[i] = spi_read_byte();
udelay(AVR_DELAY_US);
}
}
else
{
for (i = 0; i < data_length; i++)
{
IO_SERIAL1_TX_DATA = data[i];
spi_read_byte();
udelay(AVR_DELAY_US);
}
}
IO_SERIAL1_TX_DATA = CMD_CLOSE;
rx = spi_read_byte();
udelay(AVR_DELAY_US);
if (is_read)
{
success = success && (rx == CMD_CLOSE);
}
avr_hid_release();
IO_SERIAL1_TX_ENABLE = 0;
bitclr16(&IO_CLK_MOD2, CLK_MOD2_SIF1);
mutex_unlock(&avr_mtx);
return success;
}
static bool avr_hid_get_state(void)
{
uint8_t state[8];
if (avr_run_command(CMD_STATE, state, sizeof(state)))
{
avr_battery_status = state[6];
avr_battery_level = state[7];
parse_button_state(state);
return true;
}
return false;
}
static bool avr_hid_sync(void)
{
int retry;
for (retry = 0; retry < AVR_MAX_RETRIES; retry++)
{
if (avr_hid_get_state())
{
return true;
}
mdelay(100);
}
/* TODO: Program HID as it appears to be not programmed.
* To do so, unfortunately, AVR firmware would have to be written
* from scratch as OF blob cannot be used due to licensing.
*/
return false;
}
static bool avr_execute_command(uint8_t opcode, uint8_t *data, size_t data_length)
{
int retry;
for (retry = 0; retry < AVR_MAX_RETRIES; retry++)
{
if (avr_run_command(opcode, data, data_length))
{
return true;
}
/* Resync and try again */
avr_hid_sync();
}
return false;
}
void avr_hid_init(void)
{
/*
setup alternate GIO functions:
GIO30 - SIF1 Clock
GIO31 - SIF1 Data In
GIO32 - SIF1 Data Out
Manually drive GIO29 output (directly connected to AVR's SS).
*/
IO_GIO_FSEL2 = (IO_GIO_FSEL2 & 0x00FF) | 0xA800;
/* GIO29, GIO30 - outputs, GIO31 - input */
IO_GIO_DIR1 = (IO_GIO_DIR1 & ~((1 << 13) | (1 << 14))) | (1 << 15);
/* GIO32 - output */
bitclr16(&IO_GIO_DIR2, (1 << 0));
avr_hid_release();
/* Master, MSB first, RATE = 219 (Bit rate = ARM clock / 2*(RATE + 1)))
* Boosted 148.5 MHz / 440 = 337.5 kHz
* Default 74.25 MHz / 440 = 168.75 kHz
*/
IO_SERIAL1_MODE = 0x6DB;
mutex_init(&avr_mtx);
mutex_init(&hdq_mtx);
}
int _battery_level(void)
{
/* OF still plays music when level is at 0 */
if (avr_battery_level & BATTERY_LEVEL_NOT_DETECTED)
{
return 0;
}
return avr_battery_level & BATTERY_LEVEL_PERCENTAGE_MASK;
}
int _battery_voltage(void)
{
return avr_hid_hdq_read_short(HDQ_REG_VOLT);
}
int _battery_time(void)
{
/* HDQ_REG_TTE reads as 65535 when charging */
return avr_hid_hdq_read_short(HDQ_REG_TTE);
}
unsigned int power_input_status(void)
{
if (avr_battery_status & BATTERY_STATUS_CHARGER_CONNECTED)
{
return POWER_INPUT_USB_CHARGER;
}
return POWER_INPUT_NONE;
}
bool charging_state(void)
{
return (avr_battery_status & BATTERY_STATUS_CHARGING) != 0;
}
static int avr_hid_hdq_read_byte_internal(uint8_t address)
{
uint8_t result[2];
if (!avr_execute_command(CMD_HDQ_READ, &address, sizeof(address)))
{
return -1;
}
do
{
mdelay(10);
if (!avr_execute_command(CMD_HDQ_STATUS, result, sizeof(result)))
{
return -1;
}
}
while (result[0] == HDQ_STATUS_NOT_READY);
if (result[0] != HDQ_STATUS_OK)
{
logf("HDQ read %d status %d", address, result[0]);
return -1;
}
return result[1];
}
int avr_hid_hdq_read_byte(uint8_t address)
{
int retry;
int value = -1;
for (retry = 0; (retry < 3) && (value < 0); retry++)
{
mutex_lock(&hdq_mtx);
value = avr_hid_hdq_read_byte_internal(address);
mutex_unlock(&hdq_mtx);
}
return value;
}
int avr_hid_hdq_read_short(uint8_t address)
{
int old_hi = -1, old_lo = -1, hi = -2, lo = -2;
/* Keep reading until we read the same value twice.
* There's no atomic 16-bit value retrieval, so keep reading
* until we read the same value twice. HDQ registers update
* no more than once per 2.56 seconds so usually there will
* be 4 reads and sometimes 6 reads.
*/
while ((old_hi != hi) || (old_lo != lo))
{
old_hi = hi;
old_lo = lo;
hi = avr_hid_hdq_read_byte(address + 1);
lo = avr_hid_hdq_read_byte(address);
}
if ((hi < 0) || (lo < 0))
{
return -1;
}
return (hi << 8) | lo;
}
static void avr_hid_enable_wheel(void)
{
uint8_t enable = 0x01;
avr_execute_command(CMD_WHEEL_EN, &enable, sizeof(enable));
}
/* command that is sent by "hidtool -J 1" issued on every OF boot */
void avr_hid_enable_charger(void)
{
uint8_t enable = 0x01;
avr_execute_command(CMD_SET_INTCHRG, &enable, sizeof(enable));
}
void avr_hid_wifi_pd(int high)
{
uint8_t state = high ? 0x01 : 0x00;
avr_execute_command(CMD_WIFI_PD, &state, sizeof(state));
}
static void avr_hid_lcm_power(uint8_t parameter)
{
avr_execute_command(CMD_LCM_POWER, ¶meter, sizeof(parameter));
}
void avr_hid_lcm_sleep(void)
{
avr_hid_lcm_power(LCM_POWER_SLEEP);
}
void avr_hid_lcm_wake(void)
{
avr_hid_lcm_power(LCM_POWER_WAKE);
}
void avr_hid_lcm_power_on(void)
{
avr_hid_lcm_power(LCM_POWER_ON);
}
void avr_hid_lcm_power_off(void)
{
avr_hid_lcm_power(LCM_POWER_OFF);
}
void avr_hid_reset_codec(void)
{
avr_execute_command(CMD_CODEC_RESET, NULL, 0);
}
void avr_hid_set_amp_enable(uint8_t enable)
{
avr_execute_command(CMD_AMP_ENABLE, &enable, sizeof(enable));
}
static void avr_hid_sys_ctrl(uint8_t parameter)
{
avr_execute_command(CMD_SYS_CTRL, ¶meter, sizeof(parameter));
}
void avr_hid_power_off(void)
{
/* Do not execute command directly here because we can get called inside
* tick task context that must not acquire mutex.
*/
queue_post(&avr_queue, POWER_OFF_REQUEST, 0);
}
static bool avr_state_changed(void)
{
return (IO_GIO_BITSET0 & 0x1) ? false : true;
}
static bool headphones_inserted(void)
{
return (IO_GIO_BITSET0 & 0x04) ? false : true;
}
static void set_audio_output(bool headphones)
{
#ifdef BOOTLOADER
(void)headphones;
#else
if (headphones)
{
/* Stereo output on headphones */
avr_hid_set_amp_enable(0);
aic3x_switch_output(true);
}
else
{
/* Mono output on built-in speaker */
aic3x_switch_output(false);
avr_hid_set_amp_enable(1);
}
#endif
}
static void read_monotime_offset(void)
{
int fd = open(MONOTIME_OFFSET_FILE, O_RDONLY);
if (fd >= 0)
{
uint32_t offset;
if (sizeof(offset) == read(fd, &offset, sizeof(offset)))
{
monotime_offset = offset;
}
close(fd);
}
}
static bool write_monotime_offset(void)
{
bool success = false;
int fd = open(MONOTIME_OFFSET_FILE, O_WRONLY | O_CREAT | O_TRUNC, 0666);
if (fd >= 0)
{
uint32_t offset = monotime_offset;
if (sizeof(monotime_offset) == write(fd, &offset, sizeof(offset)))
{
success = true;
}
close(fd);
}
return success;
}
static void read_monotime(void)
{
uint8_t tmp[4];
uint32_t t1, t2;
if (!avr_execute_command(CMD_MONOTIME, tmp, sizeof(tmp)))
{
return;
}
t1 = (tmp[0]) | (tmp[1] << 8) | (tmp[2] << 16) | (tmp[3] << 24);
if (!avr_execute_command(CMD_MONOTIME, tmp, sizeof(tmp)))
{
return;
}
t2 = (tmp[0]) | (tmp[1] << 8) | (tmp[2] << 16) | (tmp[3] << 24);
if ((t1 == t2) || (t1 + 1 == t2))
{
int flags = disable_irq_save();
monotime_value = t2;
monotime_value_tick = current_tick;
restore_irq(flags);
monotime_available = true;
}
}
static time_t get_timestamp(void)
{
time_t timestamp;
if (!monotime_available)
{
read_monotime();
}
if (monotime_available)
{
int flags = disable_irq_save();
timestamp = monotime_value;
timestamp += monotime_offset;
timestamp += ((current_tick - monotime_value_tick) / HZ);
restore_irq(flags);
return timestamp;
}
return 0;
}
void rtc_init(void)
{
/* This is called before disk is mounted */
}
int rtc_read_datetime(struct tm *tm)
{
time_t time = get_timestamp();
gmtime_r(&time, tm);
return 1;
}
int rtc_write_datetime(const struct tm *tm)
{
time_t offset = mktime((struct tm *)tm);
int flags = disable_irq_save();
offset -= monotime_value;
offset -= ((current_tick - monotime_value_tick) / HZ);
monotime_offset = offset;
restore_irq(flags);
queue_post(&avr_queue, MONOTIME_OFFSET_UPDATE, 0);
return 1;
}
void avr_thread(void)
{
struct queue_event ev;
bool headphones_active_state = headphones_inserted();
bool headphones_state;
bool disk_access_available = true;
bool monotime_offset_update_pending = false;
set_audio_output(headphones_active_state);
read_monotime_offset();
read_monotime();
while (1)
{
if (avr_state_changed())
{
/* We have to read AVR state, simply check if there's any event
* pending but do not block. It is possible that AVR interrupt
* line is held active even though we read the state (change
* occured during read).
*/
queue_wait_w_tmo(&avr_queue, &ev, 0);
}
else
{
queue_wait(&avr_queue, &ev);
}
if (ev.id == SYS_USB_CONNECTED)
{
/* Allow USB to gain exclusive storage access */
usb_acknowledge(SYS_USB_CONNECTED_ACK);
disk_access_available = false;
}
else if (ev.id == SYS_USB_DISCONNECTED)
{
disk_access_available = true;
}
else if (ev.id == MONOTIME_OFFSET_UPDATE)
{
monotime_offset_update_pending = true;
}
else if (ev.id == POWER_OFF_REQUEST)
{
avr_hid_reset_codec();
avr_hid_sys_ctrl(SYS_CTRL_POWEROFF);
}
input_interrupt_pending = false;
if (avr_state_changed())
{
/* Read buttons state */
avr_hid_get_state();
}
headphones_state = headphones_inserted();
if (headphones_state != headphones_active_state)
{
set_audio_output(headphones_state);
headphones_active_state = headphones_state;
}
if (disk_access_available)
{
if (monotime_offset_update_pending && write_monotime_offset())
{
monotime_offset_update_pending = false;
}
}
/* Update buffered monotime value every hour */
if (TIME_AFTER(current_tick, monotime_value_tick + 3600 * HZ))
{
read_monotime();
}
}
}
void GIO0(void) __attribute__ ((section(".icode")));
void GIO0(void)
{
/* Clear interrupt */
IO_INTC_IRQ1 = (1 << 5);
if (!input_interrupt_pending)
{
input_interrupt_pending = true;
queue_post(&avr_queue, INPUT_INTERRUPT, 0);
}
}
void GIO2(void) __attribute__ ((section(".icode")));
void GIO2(void)
{
/* Clear interrupt */
IO_INTC_IRQ1 = (1 << 7);
/* Prevent event queue overflow by allowing just one pending event */
if (!input_interrupt_pending)
{
input_interrupt_pending = true;
queue_post(&avr_queue, INPUT_INTERRUPT, 0);
}
}
void button_init_device(void)
{
btn = 0;
hold_switch = false;
queue_init(&avr_queue, true);
input_interrupt_pending = true;
queue_post(&avr_queue, INPUT_INTERRUPT, 0);
create_thread(avr_thread, avr_stack, sizeof(avr_stack), 0,
avr_thread_name IF_PRIO(, PRIORITY_USER_INTERFACE)
IF_COP(, CPU));
IO_GIO_DIR0 |= 0x01; /* Set GIO0 as input */
/* Get in sync with AVR */
avr_hid_sync();
/* Enable wheel */
avr_hid_enable_wheel();
/* Read button status and tell avr we want interrupt on next change */
avr_hid_get_state();
IO_GIO_IRQPORT |= 0x05; /* Enable GIO0/GIO2 external interrupt */
IO_GIO_INV0 &= ~0x05; /* Clear INV for GIO0/GIO2 */
/* falling edge detection on GIO0, any edge on GIO2 */
IO_GIO_IRQEDGE = (IO_GIO_IRQEDGE & ~0x01) | 0x04;
/* Enable GIO0 and GIO2 interrupts */
IO_INTC_EINT1 |= INTR_EINT1_EXT0 | INTR_EINT1_EXT2;
}
int button_read_device(void)
{
if(hold_switch)
return 0;
else
return btn;
}
bool button_hold(void)
{
return hold_switch;
}
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