mirror of
https://github.com/Ninjdai1/pokeemerald.git
synced 2024-11-18 20:47:40 +01:00
433 lines
8.7 KiB
C
433 lines
8.7 KiB
C
// Ruby/Sapphire/Emerald cartridges contain a Seiko Instruments Inc. (SII)
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// S-3511A real-time clock (RTC). This library ("SIIRTC_V001") is for
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// communicating with the RTC.
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#include "gba/gba.h"
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#include "siirtc.h"
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#define STATUS_INTFE 0x02 // frequency interrupt enable
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#define STATUS_INTME 0x08 // per-minute interrupt enable
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#define STATUS_INTAE 0x20 // alarm interrupt enable
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#define STATUS_24HOUR 0x40 // 0: 12-hour mode, 1: 24-hour mode
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#define STATUS_POWER 0x80 // power on or power failure occurred
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#define TEST_MODE 0x80 // flag in the "second" byte
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#define ALARM_AM 0x00
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#define ALARM_PM 0x80
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#define OFFSET_YEAR offsetof(struct SiiRtcInfo, year)
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#define OFFSET_MONTH offsetof(struct SiiRtcInfo, month)
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#define OFFSET_DAY offsetof(struct SiiRtcInfo, day)
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#define OFFSET_DAY_OF_WEEK offsetof(struct SiiRtcInfo, dayOfWeek)
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#define OFFSET_HOUR offsetof(struct SiiRtcInfo, hour)
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#define OFFSET_MINUTE offsetof(struct SiiRtcInfo, minute)
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#define OFFSET_SECOND offsetof(struct SiiRtcInfo, second)
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#define OFFSET_STATUS offsetof(struct SiiRtcInfo, status)
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#define OFFSET_ALARM_HOUR offsetof(struct SiiRtcInfo, alarmHour)
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#define OFFSET_ALARM_MINUTE offsetof(struct SiiRtcInfo, alarmMinute)
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#define INFO_BUF(info, index) (*((u8 *)(info) + (index)))
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#define DATETIME_BUF(info, index) INFO_BUF(info, OFFSET_YEAR + index)
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#define DATETIME_BUF_LEN (OFFSET_SECOND - OFFSET_YEAR + 1)
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#define TIME_BUF(info, index) INFO_BUF(info, OFFSET_HOUR + index)
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#define TIME_BUF_LEN (OFFSET_SECOND - OFFSET_HOUR + 1)
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#define WR 0 // command for writing data
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#define RD 1 // command for reading data
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#define CMD(n) (0x60 | (n << 1))
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#define CMD_RESET CMD(0)
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#define CMD_STATUS CMD(1)
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#define CMD_DATETIME CMD(2)
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#define CMD_TIME CMD(3)
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#define CMD_ALARM CMD(4)
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#define GPIO_PORT_DATA (*(vu16 *)0x80000C4)
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#define GPIO_PORT_DIRECTION (*(vu16 *)0x80000C6)
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#define GPIO_PORT_READ_ENABLE (*(vu16 *)0x80000C8)
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extern vu16 GPIOPortDirection;
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static u16 sDummy; // unused variable
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static bool8 sLocked;
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static int WriteCommand(u8 value);
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static int WriteData(u8 value);
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static u8 ReadData();
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static void EnableGpioPortRead();
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static void DisableGpioPortRead();
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static const char AgbLibRtcVersion[] = "SIIRTC_V001";
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void SiiRtcUnprotect()
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{
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EnableGpioPortRead();
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sLocked = FALSE;
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}
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void SiiRtcProtect()
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{
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DisableGpioPortRead();
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sLocked = TRUE;
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}
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u8 SiiRtcProbe()
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{
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u8 errorCode;
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struct SiiRtcInfo rtc;
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if (!SiiRtcGetStatus(&rtc))
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return 0;
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errorCode = 0;
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if ((rtc.status & (SIIRTCINFO_POWER | SIIRTCINFO_24HOUR)) == SIIRTCINFO_POWER
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|| (rtc.status & (SIIRTCINFO_POWER | SIIRTCINFO_24HOUR)) == 0)
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{
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// The RTC is in 12-hour mode. Reset it and switch to 24-hour mode.
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// Note that the conditions are redundant and equivalent to simply
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// "(rtc.status & SIIRTCINFO_24HOUR) == 0". It's possible that this
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// was also intended to handle resetting the clock after power failure
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// but a mistake was made.
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if (!SiiRtcReset())
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return 0;
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errorCode++;
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}
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SiiRtcGetTime(&rtc);
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if (rtc.second & TEST_MODE)
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{
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// The RTC is in test mode. Reset it to leave test mode.
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if (!SiiRtcReset())
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return (errorCode << 4) & 0xF0;
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errorCode++;
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}
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return (errorCode << 4) | 1;
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}
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bool8 SiiRtcReset()
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{
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u8 result;
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struct SiiRtcInfo rtc;
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if (sLocked == TRUE)
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return FALSE;
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sLocked = TRUE;
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GPIO_PORT_DATA = 1;
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GPIO_PORT_DATA = 5;
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GPIO_PORT_DIRECTION = 7;
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WriteCommand(CMD_RESET | WR);
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GPIO_PORT_DATA = 1;
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GPIO_PORT_DATA = 1;
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sLocked = FALSE;
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rtc.status = SIIRTCINFO_24HOUR;
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result = SiiRtcSetStatus(&rtc);
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return result;
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}
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bool8 SiiRtcGetStatus(struct SiiRtcInfo *rtc)
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{
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u8 statusData;
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if (sLocked == TRUE)
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return FALSE;
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sLocked = TRUE;
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GPIO_PORT_DATA = 1;
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GPIO_PORT_DATA = 5;
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GPIO_PORT_DIRECTION = 7;
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WriteCommand(CMD_STATUS | RD);
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GPIO_PORT_DIRECTION = 5;
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statusData = ReadData();
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rtc->status = (statusData & (STATUS_POWER | STATUS_24HOUR))
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| ((statusData & STATUS_INTAE) >> 3)
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| ((statusData & STATUS_INTME) >> 2)
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| ((statusData & STATUS_INTFE) >> 1);
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GPIO_PORT_DATA = 1;
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GPIO_PORT_DATA = 1;
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sLocked = FALSE;
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return TRUE;
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}
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bool8 SiiRtcSetStatus(struct SiiRtcInfo *rtc)
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{
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u8 statusData;
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if (sLocked == TRUE)
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return FALSE;
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sLocked = TRUE;
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GPIO_PORT_DATA = 1;
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GPIO_PORT_DATA = 5;
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statusData = STATUS_24HOUR
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| ((rtc->status & SIIRTCINFO_INTAE) << 3)
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| ((rtc->status & SIIRTCINFO_INTME) << 2)
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| ((rtc->status & SIIRTCINFO_INTFE) << 1);
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GPIO_PORT_DIRECTION = 7;
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WriteCommand(CMD_STATUS | WR);
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WriteData(statusData);
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GPIO_PORT_DATA = 1;
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GPIO_PORT_DATA = 1;
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sLocked = FALSE;
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return TRUE;
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}
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bool8 SiiRtcGetDateTime(struct SiiRtcInfo *rtc)
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{
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u8 i;
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if (sLocked == TRUE)
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return FALSE;
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sLocked = TRUE;
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GPIO_PORT_DATA = 1;
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GPIO_PORT_DATA = 5;
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GPIO_PORT_DIRECTION = 7;
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WriteCommand(CMD_DATETIME | RD);
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GPIO_PORT_DIRECTION = 5;
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for (i = 0; i < DATETIME_BUF_LEN; i++)
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DATETIME_BUF(rtc, i) = ReadData();
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INFO_BUF(rtc, OFFSET_HOUR) &= 0x7F;
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GPIO_PORT_DATA = 1;
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GPIO_PORT_DATA = 1;
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sLocked = FALSE;
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return TRUE;
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}
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bool8 SiiRtcSetDateTime(struct SiiRtcInfo *rtc)
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{
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u8 i;
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if (sLocked == TRUE)
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return FALSE;
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sLocked = TRUE;
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GPIO_PORT_DATA = 1;
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GPIO_PORT_DATA = 5;
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GPIO_PORT_DIRECTION = 7;
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WriteCommand(CMD_DATETIME | WR);
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for (i = 0; i < DATETIME_BUF_LEN; i++)
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WriteData(DATETIME_BUF(rtc, i));
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GPIO_PORT_DATA = 1;
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GPIO_PORT_DATA = 1;
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sLocked = FALSE;
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return TRUE;
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}
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bool8 SiiRtcGetTime(struct SiiRtcInfo *rtc)
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{
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u8 i;
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if (sLocked == TRUE)
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return FALSE;
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sLocked = TRUE;
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GPIO_PORT_DATA = 1;
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GPIO_PORT_DATA = 5;
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GPIO_PORT_DIRECTION = 7;
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WriteCommand(CMD_TIME | RD);
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GPIO_PORT_DIRECTION = 5;
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for (i = 0; i < TIME_BUF_LEN; i++)
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TIME_BUF(rtc, i) = ReadData();
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INFO_BUF(rtc, OFFSET_HOUR) &= 0x7F;
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GPIO_PORT_DATA = 1;
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GPIO_PORT_DATA = 1;
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sLocked = FALSE;
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return TRUE;
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}
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bool8 SiiRtcSetTime(struct SiiRtcInfo *rtc)
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{
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u8 i;
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if (sLocked == TRUE)
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return FALSE;
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sLocked = TRUE;
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GPIO_PORT_DATA = 1;
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GPIO_PORT_DATA = 5;
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GPIO_PORT_DIRECTION = 7;
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WriteCommand(CMD_TIME | WR);
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for (i = 0; i < TIME_BUF_LEN; i++)
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WriteData(TIME_BUF(rtc, i));
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GPIO_PORT_DATA = 1;
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GPIO_PORT_DATA = 1;
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sLocked = FALSE;
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return TRUE;
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}
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bool8 SiiRtcSetAlarm(struct SiiRtcInfo *rtc)
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{
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u8 i;
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u8 alarmData[2];
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if (sLocked == TRUE)
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return FALSE;
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sLocked = TRUE;
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// Decode BCD.
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alarmData[0] = (rtc->alarmHour & 0xF) + 10 * ((rtc->alarmHour >> 4) & 0xF);
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// The AM/PM flag must be set correctly even in 24-hour mode.
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if (alarmData[0] < 12)
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alarmData[0] = rtc->alarmHour | ALARM_AM;
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else
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alarmData[0] = rtc->alarmHour | ALARM_PM;
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alarmData[1] = rtc->alarmMinute;
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GPIO_PORT_DATA = 1;
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GPIO_PORT_DATA = 5;
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GPIOPortDirection = 7; // Why is this the only instance that uses a symbol?
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WriteCommand(CMD_ALARM | WR);
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for (i = 0; i < 2; i++)
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WriteData(alarmData[i]);
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GPIO_PORT_DATA = 1;
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GPIO_PORT_DATA = 1;
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sLocked = FALSE;
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return TRUE;
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}
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static int WriteCommand(u8 value)
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{
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u8 i;
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u8 temp;
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for (i = 0; i < 8; i++)
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{
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temp = ((value >> (7 - i)) & 1);
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GPIO_PORT_DATA = (temp << 1) | 4;
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GPIO_PORT_DATA = (temp << 1) | 4;
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GPIO_PORT_DATA = (temp << 1) | 4;
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GPIO_PORT_DATA = (temp << 1) | 5;
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}
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// control reaches end of non-void function
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}
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static int WriteData(u8 value)
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{
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u8 i;
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u8 temp;
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for (i = 0; i < 8; i++)
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{
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temp = ((value >> i) & 1);
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GPIO_PORT_DATA = (temp << 1) | 4;
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GPIO_PORT_DATA = (temp << 1) | 4;
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GPIO_PORT_DATA = (temp << 1) | 4;
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GPIO_PORT_DATA = (temp << 1) | 5;
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}
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// control reaches end of non-void function
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}
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static u8 ReadData()
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{
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u8 i;
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u8 temp;
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u8 value;
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for (i = 0; i < 8; i++)
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{
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GPIO_PORT_DATA = 4;
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GPIO_PORT_DATA = 4;
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GPIO_PORT_DATA = 4;
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GPIO_PORT_DATA = 4;
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GPIO_PORT_DATA = 4;
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GPIO_PORT_DATA = 5;
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temp = ((GPIO_PORT_DATA & 2) >> 1);
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value = (value >> 1) | (temp << 7); // UB: accessing uninitialized var
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}
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return value;
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}
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static void EnableGpioPortRead()
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{
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GPIO_PORT_READ_ENABLE = 1;
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}
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static void DisableGpioPortRead()
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{
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GPIO_PORT_READ_ENABLE = 0;
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}
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