/*************************************************************************** * __________ __ ___. * Open \______ \ ____ ____ | | _\_ |__ _______ ___ * Source | _// _ \_/ ___\| |/ /| __ \ / _ \ \/ / * Jukebox | | ( <_> ) \___| < | \_\ ( <_> > < < * Firmware |____|_ /\____/ \___ >__|_ \|___ /\____/__/\_ \ * \/ \/ \/ \/ \/ * $Id$ * * Copyright (C) 2002 by Linus Nielsen Feltzing, Uwe Freese, Laurent Baum * * All files in this archive are subject to the GNU General Public License. * See the file COPYING in the source tree root for full license agreement. * * This software is distributed on an "AS IS" basis, WITHOUT WARRANTY OF ANY * KIND, either express or implied. * ****************************************************************************/ #include "config.h" #ifdef CONFIG_RTC #include "i2c.h" #include "rtc.h" #include "kernel.h" #include "system.h" #include "pcf50606.h" #include "pcf50605.h" #if CONFIG_RTC == RTC_E8564 #include "i2c-pp5020.h" #endif /*CONFIG_RTC == RTC_E8564*/ #include #define RTC_ADR 0xd0 #define RTC_DEV_WRITE (RTC_ADR | 0x00) #define RTC_DEV_READ (RTC_ADR | 0x01) #if CONFIG_RTC == RTC_E8564 void rtc_init(void) { } int rtc_read_datetime(unsigned char* buf) { unsigned char tmp; int read; /*RTC_E8564's slave address is 0x51*/ read = i2c_readbytes(0x51,0x02,7,buf); /* swap wday and mday to be compatible with * get_time() from firmware/common/timefuncs.c */ tmp=buf[3]; buf[3]=buf[4]; buf[4]=tmp; return read; } int rtc_write_datetime(unsigned char* buf) { int i; unsigned char tmp; /* swap wday and mday to be compatible with * set_time() in firmware/common/timefuncs.c */ tmp=buf[3]; buf[3]=buf[4]; buf[4]=tmp; for (i=0;i<7;i++){ ipod_i2c_send(0x51, 0x02+i,buf[i]); } return 1; } #elif CONFIG_RTC == RTC_PCF50605 void rtc_init(void) { } int rtc_read_datetime(unsigned char* buf) { return pcf50605_read_multiple(0x0a, buf, 7); } int rtc_write_datetime(unsigned char* buf) { int i; for (i=0;i<7;i++) { pcf50605_write(0x0a+i, buf[i]); } return 1; } #elif CONFIG_RTC == RTC_PCF50606 void rtc_init(void) { } int rtc_read_datetime(unsigned char* buf) { int rc; int oldlevel = set_irq_level(HIGHEST_IRQ_LEVEL); rc = pcf50606_read_multiple(0x0a, buf, 7); set_irq_level(oldlevel); return rc; } int rtc_write_datetime(unsigned char* buf) { int rc; int oldlevel = set_irq_level(HIGHEST_IRQ_LEVEL); rc = pcf50606_write_multiple(0x0a, buf, 7); set_irq_level(oldlevel); return rc; } #else void rtc_init(void) { unsigned char data; #ifdef HAVE_ALARM_MOD /* Check + save alarm bit first, before the power thread starts watching */ rtc_check_alarm_started(false); #endif rtc_write(0x13, 0x10); /* 32 kHz square wave */ /* Clear the Stop bit if it is set */ data = rtc_read(0x01); if(data & 0x80) rtc_write(0x01, 0x00); /* Clear the HT bit if it is set */ data = rtc_read(0x0c); if(data & 0x40) { data &= ~0x40; rtc_write(0x0c,data); } #ifdef HAVE_ALARM_MOD /* Clear Trec bit, write-protecting the RTC for 200ms when shutting off */ /* without this, the alarm won't work! */ data = rtc_read(0x04); if (data & 0x80) { data &= ~0x80; rtc_write(0x04, data); } /* Also, make sure that the OUT bit in register 8 is 1, otherwise the player can't be turned off. */ rtc_write(8, rtc_read(8) | 0x80); #endif } #ifdef HAVE_ALARM_MOD /* check whether the unit has been started by the RTC alarm function */ /* (check for AF, which => started using wakeup alarm) */ bool rtc_check_alarm_started(bool release_alarm) { static bool alarm_state, run_before; bool rc; if (run_before) { rc = alarm_state; alarm_state &= ~release_alarm; } else { /* This call resets AF, so we store the state for later recall */ rc = alarm_state = rtc_check_alarm_flag(); run_before = true; } return rc; } /* * Checks the AL register. This call resets AL once read. * * We're only interested if ABE is set. AL is still raised regardless * even if the unit is off when the alarm occurs. */ bool rtc_check_alarm_flag(void) { return ( ( (rtc_read(0x0f) & 0x40) != 0) && (rtc_read(0x0a) & 0x20) ); } /* set alarm time registers to the given time (repeat once per day) */ void rtc_set_alarm(int h, int m) { unsigned char data; /* for daily alarm, RPT5=RPT4=on, RPT1=RPT2=RPT3=off */ rtc_write(0x0e, 0x00); /* seconds 0 and RTP1 */ rtc_write(0x0d, ((m / 10) << 4) | (m % 10)); /* minutes and RPT2 */ rtc_write(0x0c, ((h / 10) << 4) | (h % 10)); /* hour and RPT3 */ rtc_write(0x0b, 0xc1); /* set date 01 and RPT4 and RTP5 */ /* set month to 1, if it's invalid, the rtc does an alarm every second instead */ data = rtc_read(0x0a); data &= 0xe0; data |= 0x01; rtc_write(0x0a, data); } /* read out the current alarm time */ void rtc_get_alarm(int *h, int *m) { unsigned char data; data = rtc_read(0x0c); *h = ((data & 0x30) >> 4) * 10 + (data & 0x0f); data = rtc_read(0x0d); *m = ((data & 0x70) >> 4) * 10 + (data & 0x0f); } /* turn alarm on or off by setting the alarm flag enable */ /* the alarm is automatically disabled when the RTC gets Vcc power at startup */ /* avoid that an alarm occurs when the device is on because this locks the ON key forever */ /* returns false if alarm was set and alarm flag (output) is off */ /* returns true if alarm flag went on, which would lock the device, so the alarm was disabled again */ bool rtc_enable_alarm(bool enable) { unsigned char data = rtc_read(0x0a); if (enable) { data |= 0xa0; /* turn bit d7=AFE and d5=ABE on */ } else data &= 0x5f; /* turn bit d7=AFE and d5=ABE off */ rtc_write(0x0a, data); /* check if alarm flag AF is off (as it should be) */ /* in some cases enabling the alarm results in an activated AF flag */ /* this should not happen, but it does */ /* if you know why, tell me! */ /* for now, we try again forever in this case */ while (rtc_check_alarm_flag()) /* on */ { data &= 0x5f; /* turn bit d7=AFE and d5=ABE off */ rtc_write(0x0a, data); sleep(HZ / 10); rtc_check_alarm_flag(); data |= 0xa0; /* turn bit d7=AFE and d5=ABE on */ rtc_write(0x0a, data); } return false; /* all ok */ } #endif /* HAVE_ALARM_MOD */ int rtc_write(unsigned char address, unsigned char value) { int ret = 0; unsigned char buf[2]; i2c_begin(); buf[0] = address; buf[1] = value; /* send run command */ if (i2c_write(RTC_DEV_WRITE,buf,2)) { ret = -1; } i2c_end(); return ret; } int rtc_read(unsigned char address) { int value = -1; unsigned char buf[1]; i2c_begin(); buf[0] = address; /* send read command */ if (i2c_write(RTC_DEV_READ,buf,1) >= 0) { i2c_start(); i2c_outb(RTC_DEV_READ); if (i2c_getack()) { value = i2c_inb(1); } } i2c_stop(); i2c_end(); return value; } int rtc_read_multiple(unsigned char address, unsigned char *buf, int numbytes) { int ret = 0; unsigned char obuf[1]; int i; i2c_begin(); obuf[0] = address; /* send read command */ if (i2c_write(RTC_DEV_READ, obuf, 1) >= 0) { i2c_start(); i2c_outb(RTC_DEV_READ); if (i2c_getack()) { for(i = 0;i < numbytes-1;i++) buf[i] = i2c_inb(0); buf[i] = i2c_inb(1); } else { ret = -1; } } i2c_stop(); i2c_end(); return ret; } int rtc_read_datetime(unsigned char* buf) { int rc; rc = rtc_read_multiple(1, buf, 7); /* Adjust weekday */ if(buf[3] == 7) buf[3]=0; return rc; } int rtc_write_datetime(unsigned char* buf) { int i; int rc = 0; /* Adjust weekday */ if(buf[3] == 0) buf[3] = 7; for (i = 0; i < 7 ; i++) { rc |= rtc_write(i+1, buf[i]); } rc |= rtc_write(8, 0x80); /* Out=1, calibration = 0 */ return rc; } #endif /* CONFIG_RTC == RTC_PCF50606 */ #endif /* CONFIG_RTC */