RX-8025NB Real Time Clock Module by EPSON
Dependents: TYBLE16_simple_data_logger Check_external_RTC
RX8025NB.cpp
- Committer:
- kenjiArai
- Date:
- 2019-12-17
- Revision:
- 6:414dbeb77add
- Parent:
- 5:e8e8b1b6c103
- Child:
- 7:4793c4817590
File content as of revision 6:414dbeb77add:
/* * mbed library program * Control RX-8025NB Real Time Clock Module * EPSON * * Copyright (c) 2015,'16,'17,'19 Kenji Arai / JH1PJL * http://www.page.sannet.ne.jp/kenjia/index.html * http://mbed.org/users/kenjiArai/ * Created: June 3rd, 2015 * Revised: December 17th, 2019 */ #include "mbed.h" #include "RX8025NB.h" RX8025::RX8025 (PinName p_sda, PinName p_scl) : _i2c_p(new I2C(p_sda, p_scl)), _i2c(*_i2c_p) { RX8025_addr = RX8025ADDR; init(); } RX8025::RX8025 (I2C& p_i2c) : _i2c(p_i2c) { RX8025_addr = RX8025ADDR; init(); } /////////////// Initialize //////////////////////////////// void RX8025::init() { tm t; char dt; _i2c.frequency(400000); // Set 24H dt = read_reg_byte(RX8025_REG_CONTL1); if (dt & 0x20) { // set already ; } else { dt |= 0x20; dt = write_reg_byte(RX8025_REG_CONTL1, dt); } } /////////////// Read RTC data ///////////////////////////// void RX8025::get_time_rtc (tm *t) { read_rtc_std(t); } void RX8025::read_rtc_std (tm *t) { rtc_time time; read_rtc_direct(&time); t->tm_sec = time.rtc_seconds; t->tm_min = time.rtc_minutes; t->tm_hour = time.rtc_hours; t->tm_mday = time.rtc_date; if ( time.rtc_weekday == RTC_Wk_Sunday) { t->tm_wday = 0; // Sun is not 7 but 0 } else { t->tm_wday = time.rtc_weekday; } t->tm_mon = time.rtc_month - 1; t->tm_year = time.rtc_year_raw + 100; t->tm_isdst= 0; } /////////////// Write data to RTC ///////////////////////// void RX8025::set_time_rtc (tm *t) { write_rtc_std(t); } void RX8025::write_rtc_std (tm *t) { rtc_time time; time.rtc_seconds = t->tm_sec; time.rtc_minutes = t->tm_min; time.rtc_hours = t->tm_hour; time.rtc_date = t->tm_mday; if ( t->tm_wday == 0) { time.rtc_weekday = RTC_Wk_Sunday; } else { time.rtc_weekday = t->tm_wday; } time.rtc_month = t->tm_mon + 1; time.rtc_year_raw = t->tm_year - 100; write_rtc_direct(&time); } /////////////// Set Alarm-D / INTA //////////////////////// void RX8025::set_alarmD_reg (uint16_t time) { tm t; char dt; uint8_t m, h; uint16_t set, real; dt = read_reg_byte(RX8025_REG_CONTL1); dt &= ~0x40; // DALE = 0 dt = write_reg_byte(RX8025_REG_CONTL1, dt); read_rtc_std(&t); // read current time real = t.tm_hour * 60 + t.tm_min; set = real + time; m = t.tm_min + (uint8_t)(time % 60); h = t.tm_hour; if (m >= 60) { m -= 60; h += 1; } h += (uint8_t)(time / 60); if (h >= 24) { h -= 24; } rtc_buf[2] = bin2bcd(h); rtc_buf[1] = bin2bcd(m); rtc_buf[0] = RX8025_REG_ALARMD_MIN << 4; _i2c.write(RX8025_addr, rtc_buf, 3, false); dt = read_reg_byte(RX8025_REG_CONTL1); dt |= 0x60; // DALE = 1 dt = write_reg_byte(RX8025_REG_CONTL1, dt); } //bool RX8025::set_next_alarmD_INTA (uint16_t time) void RX8025::set_next_alarmD_INTA (uint16_t time) { uint8_t ret; uint16_t t; if (time < 2) { // Alarm does not check seconds digit. // If 59 to 0 is occured during setting here, 1 minute will have a trouble. t = 2; } else if (time > 1440) { // Less than 24 hours t = 1440; } else { t = time; } set_alarmD_reg(t); } /////////////// Clear Alarm-D / INTA interrupt //////////// void RX8025::clear_alarmD_INTA () { char dt, reg; for (uint32_t i = 0; i < 40; i++) { reg = read_reg_byte(RX8025_REG_CONTL2); if ((reg & 0x01) == 0) { break; } dt = reg & 0xfe; write_reg_byte(RX8025_REG_CONTL1, dt); } } /////////////// Read/Write specific register ////////////// uint8_t RX8025::read_reg_byte(uint8_t reg) { rtc_buf[0] = reg << 4; _i2c.write(RX8025_addr, rtc_buf, 1, true); _i2c.read(RX8025_addr, rtc_buf, 1, false); return rtc_buf[0]; } uint8_t RX8025::write_reg_byte(uint8_t reg, uint8_t data) { rtc_buf[0] = reg << 4; rtc_buf[1] = data; _i2c.write(RX8025_addr, rtc_buf, 2, false); return read_reg_byte(reg); } /////////////// I2C Freq. ///////////////////////////////// void RX8025::frequency(int hz) { _i2c.frequency(hz); } /////////////// Read/Write RTC another format ///////////// void RX8025::read_rtc_direct (rtc_time *tm) { rtc_buf[0] = RX8025_REG_SEC << 4; _i2c.write(RX8025_addr, rtc_buf, 1, true); _i2c.read(RX8025_addr, rtc_buf, 10, false); tm->rtc_seconds = bcd2bin(rtc_buf[RX8025_REG_SEC] & 0x7f); tm->rtc_minutes = bcd2bin(rtc_buf[RX8025_REG_MIN] & 0x7f); tm->rtc_hours = bcd2bin(rtc_buf[RX8025_REG_HOUR] & 0x3f); tm->rtc_date = bcd2bin(rtc_buf[RX8025_REG_DAY] & 0x3f); tm->rtc_weekday = rtc_buf[RX8025_REG_WDAY] & 0x07; tm->rtc_month = bcd2bin(rtc_buf[RX8025_REG_MON] & 0x1f); tm->rtc_year_raw= bcd2bin(rtc_buf[RX8025_REG_YEAR]); tm->rtc_year = tm->rtc_year_raw + 100 + 1900; } void RX8025::write_rtc_direct (rtc_time *tm) { rtc_buf[RX8025_REG_YEAR + 1] = bin2bcd(tm->rtc_year_raw); rtc_buf[RX8025_REG_MON + 1] = bin2bcd(tm->rtc_month); rtc_buf[RX8025_REG_WDAY + 1] = (tm->rtc_weekday & 0x07); rtc_buf[RX8025_REG_DAY + 1] = bin2bcd(tm->rtc_date); rtc_buf[RX8025_REG_HOUR + 1] = bin2bcd(tm->rtc_hours); rtc_buf[RX8025_REG_MIN + 1] = bin2bcd(tm->rtc_minutes); rtc_buf[RX8025_REG_SEC + 1] = bin2bcd(tm->rtc_seconds); rtc_buf[0] = RX8025_REG_SEC << 4; _i2c.write(RX8025_addr, rtc_buf, 8, false); } uint8_t RX8025::bin2bcd (uint8_t dt) { uint8_t bcdhigh = 0; while (dt >= 10) { bcdhigh++; dt -= 10; } return ((uint8_t)(bcdhigh << 4) | dt); } uint8_t RX8025::bcd2bin (uint8_t dt) { uint8_t tmp = 0; tmp = ((uint8_t)(dt & (uint8_t)0xf0) >> (uint8_t)0x4) * 10; return (tmp + (dt & (uint8_t)0x0f)); }