/* Copyright 2016-2020 Arisotura This file is part of melonDS. melonDS 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 3 of the License, or (at your option) any later version. melonDS is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with melonDS. If not, see http://www.gnu.org/licenses/. */ #include #include #include #include "RTC.h" namespace RTC { u16 IO; u8 Input; u32 InputBit; u32 InputPos; u8 Output[8]; u32 OutputBit; u32 OutputPos; u8 CurCmd; u8 StatusReg1; u8 StatusReg2; u8 Alarm1[3]; u8 Alarm2[3]; u8 ClockAdjust; u8 FreeReg; bool Init() { return true; } void DeInit() { } void Reset() { Input = 0; InputBit = 0; InputPos = 0; memset(Output, 0, sizeof(Output)); OutputPos = 0; CurCmd = 0; StatusReg1 = 0; StatusReg2 = 0; memset(Alarm1, 0, sizeof(Alarm1)); memset(Alarm2, 0, sizeof(Alarm2)); ClockAdjust = 0; FreeReg = 0; } void DoSavestate(Savestate* file) { file->Section("RTC."); file->Var16(&IO); file->Var8(&Input); file->Var32(&InputBit); file->Var32(&InputPos); file->VarArray(Output, sizeof(Output)); file->Var32(&OutputBit); file->Var32(&OutputPos); file->Var8(&CurCmd); file->Var8(&StatusReg1); file->Var8(&StatusReg2); file->VarArray(Alarm1, sizeof(Alarm1)); file->VarArray(Alarm2, sizeof(Alarm2)); file->Var8(&ClockAdjust); file->Var8(&FreeReg); } u8 BCD(u8 val) { return (val % 10) | ((val / 10) << 4); } void ByteIn(u8 val) { //printf("RTC IN: %02X\n", val); if (InputPos == 0) { if ((val & 0xF0) == 0x60) { u8 rev[16] = {0x06, 0x86, 0x46, 0xC6, 0x26, 0xA6, 0x66, 0xE6, 0x16, 0x96, 0x56, 0xD6, 0x36, 0xB6, 0x76, 0xF6}; CurCmd = rev[val & 0xF]; } else CurCmd = val; if (CurCmd & 0x80) { switch (CurCmd & 0x70) { case 0x00: Output[0] = StatusReg1; break; case 0x40: Output[0] = StatusReg2; break; case 0x20: { time_t timestamp; struct tm* timedata; time(×tamp); timedata = localtime(×tamp); Output[0] = BCD(timedata->tm_year - 100); Output[1] = BCD(timedata->tm_mon + 1); Output[2] = BCD(timedata->tm_mday); Output[3] = BCD(timedata->tm_wday); Output[4] = BCD(timedata->tm_hour); Output[5] = BCD(timedata->tm_min); Output[6] = BCD(timedata->tm_sec); } break; case 0x60: { time_t timestamp; struct tm* timedata; time(×tamp); timedata = localtime(×tamp); Output[0] = BCD(timedata->tm_hour); Output[1] = BCD(timedata->tm_min); Output[2] = BCD(timedata->tm_sec); } break; case 0x10: if (StatusReg2 & 0x04) { Output[0] = Alarm1[0]; Output[1] = Alarm1[1]; Output[2] = Alarm1[2]; } else Output[0] = Alarm1[2]; break; case 0x50: Output[0] = Alarm2[0]; Output[1] = Alarm2[1]; Output[2] = Alarm2[2]; break; case 0x30: Output[0] = ClockAdjust; break; case 0x70: Output[0] = FreeReg; break; } } InputPos++; return; } switch (CurCmd & 0x70) { case 0x00: if (InputPos == 1) StatusReg1 = val & 0x0E; break; case 0x40: if (InputPos == 1) StatusReg2 = val; if (StatusReg2 & 0x4F) printf("RTC INTERRUPT ON: %02X\n", StatusReg2); break; case 0x20: // TODO: set time somehow?? break; case 0x60: // same shit break; case 0x10: if (StatusReg2 & 0x04) { if (InputPos <= 3) Alarm1[InputPos-1] = val; } else { if (InputPos == 1) Alarm1[2] = val; } break; case 0x50: if (InputPos <= 3) Alarm2[InputPos-1] = val; break; case 0x30: if (InputPos == 1) ClockAdjust = val; break; case 0x70: if (InputPos == 1) FreeReg = val; break; } InputPos++; } u16 Read() { //printf("RTC READ %04X\n", IO); return IO; } void Write(u16 val, bool byte) { if (byte) val |= (IO & 0xFF00); //printf("RTC WRITE %04X\n", val); if (val & 0x0004) { if (!(IO & 0x0004)) { // start transfer Input = 0; InputBit = 0; InputPos = 0; memset(Output, 0, sizeof(Output)); OutputBit = 0; OutputPos = 0; } else { if (!(val & 0x0002)) // clock low { if (val & 0x0010) { // write if (val & 0x0001) Input |= (1<= 8) { InputBit = 0; ByteIn(Input); Input = 0; InputPos++; } } else { // read if (Output[OutputPos] & (1<= 8) { OutputBit = 0; if (OutputPos < 7) OutputPos++; } } } } } if (val & 0x0010) IO = val; else IO = (IO & 0x0001) | (val & 0xFFFE); } }