/* Copyright 2016-2023 melonDS team 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 "DSi.h" #include "DSi_I2C.h" #include "DSi_Camera.h" #include "ARM.h" #include "SPI.h" #include "Platform.h" namespace melonDS { using Platform::Log; using Platform::LogLevel; // TODO: These are purely approximations const double DSi_BPTWL::PowerButtonShutdownTime = 0.5; const double DSi_BPTWL::PowerButtonForcedShutdownTime = 5.0; const double DSi_BPTWL::VolumeSwitchRepeatStart = 0.5; const double DSi_BPTWL::VolumeSwitchRepeatRate = 1.0 / 6; // Could not find a pattern or a decent formula for these, // regardless, they're only 64 bytes in size const u8 DSi_BPTWL::VolumeDownTable[32] = { 0x00, 0x00, 0x00, 0x00, 0x00, 0x02, 0x02, 0x03, 0x04, 0x05, 0x06, 0x06, 0x07, 0x08, 0x09, 0x0A, 0x0B, 0x0C, 0x0D, 0x0E, 0x0F, 0x10, 0x11, 0x12, 0x13, 0x14, 0x15, 0x16, 0x17, 0x18, 0x19, 0x1A, }; const u8 DSi_BPTWL::VolumeUpTable[32] = { 0x02, 0x03, 0x06, 0x07, 0x08, 0x0A, 0x0B, 0x0C, 0x0D, 0x0E, 0x0F, 0x10, 0x11, 0x12, 0x13, 0x14, 0x15, 0x16, 0x17, 0x18, 0x19, 0x1A, 0x1B, 0x1C, 0x1D, 0x1E, 0x1F, 0x1F, 0x1F, 0x1F, 0x1F, 0x1F, }; DSi_BPTWL::DSi_BPTWL(melonDS::DSi& dsi, DSi_I2CHost* host) : DSi_I2CDevice(dsi, host) { } DSi_BPTWL::~DSi_BPTWL() { } void DSi_BPTWL::Reset() { CurPos = -1; memset(Registers, 0x5A, 0x100); Registers[0x00] = 0x33; // TODO: support others?? Registers[0x01] = 0x00; Registers[0x02] = 0x50; Registers[0x10] = 0x00; // irq flag Registers[0x11] = 0x00; // reset Registers[0x12] = 0x00; // irq mode Registers[0x20] = 0x8F; // battery Registers[0x21] = 0x07; Registers[0x30] = 0x13; Registers[0x31] = 0x00; // camera power Registers[0x40] = 0x1F; // volume Registers[0x41] = 0x04; // backlight Registers[0x60] = 0x00; Registers[0x61] = 0x01; Registers[0x62] = 0x50; Registers[0x63] = 0x00; Registers[0x70] = 0x00; // boot flag Registers[0x71] = 0x00; Registers[0x72] = 0x00; Registers[0x73] = 0x00; Registers[0x74] = 0x00; Registers[0x75] = 0x00; Registers[0x76] = 0x00; Registers[0x77] = 0x00; Registers[0x80] = 0x10; Registers[0x81] = 0x64; // Ideally these should be replaced by a proper BPTWL core emulator PowerButtonTime = 0.0; PowerButtonDownFlag = false; PowerButtonShutdownFlag = false; VolumeSwitchTime = 0.0; VolumeSwitchRepeatTime = 0.0; VolumeSwitchKeysDown = 0; VolumeSwitchDownFlag = false; } void DSi_BPTWL::DoSavestate(Savestate* file) { file->Section("I2BP"); file->VarArray(Registers, 0x100); file->Var32(&CurPos); } // TODO: Needs more investigation on the other bits inline bool DSi_BPTWL::GetIRQMode() const { return Registers[0x12] & 0x01; } u8 DSi_BPTWL::GetBootFlag() const { return Registers[0x70]; } bool DSi_BPTWL::GetBatteryCharging() const { return Registers[0x20] >> 7; } void DSi_BPTWL::SetBatteryCharging(bool charging) { Registers[0x20] = (((charging ? 0x8 : 0x0) << 4) | (Registers[0x20] & 0x0F)); } u8 DSi_BPTWL::GetBatteryLevel() const { return Registers[0x20] & 0xF; } void DSi_BPTWL::SetBatteryLevel(u8 batteryLevel) { Registers[0x20] = ((Registers[0x20] & 0xF0) | (batteryLevel & 0x0F)); //SPI_Powerman::SetBatteryLevelOkay(batteryLevel > batteryLevel_Low ? true : false); if (batteryLevel <= 1) { SetIRQ(batteryLevel ? IRQ_BatteryLow : IRQ_BatteryEmpty); } } u8 DSi_BPTWL::GetVolumeLevel() const { return Registers[0x40]; } void DSi_BPTWL::SetVolumeLevel(u8 volume) { Registers[0x40] = volume & 0x1F; } u8 DSi_BPTWL::GetBacklightLevel() const { return Registers[0x41]; } void DSi_BPTWL::SetBacklightLevel(u8 backlight) { Registers[0x41] = backlight > 4 ? 4 : backlight; } void DSi_BPTWL::ResetButtonState() { PowerButtonTime = 0.0; PowerButtonDownFlag = false; PowerButtonShutdownFlag = false; VolumeSwitchKeysDown = 0; VolumeSwitchDownFlag = false; VolumeSwitchTime = 0.0; VolumeSwitchRepeatTime = 0.0; } void DSi_BPTWL::DoHardwareReset(bool direct) { ResetButtonState(); Log(LogLevel::Debug, "BPTWL: soft-reset\n"); if (direct) { // TODO: This doesn't seem to stop the SPU DSi.SoftReset(); return; } // TODO: soft-reset might need to be scheduled later! // TODO: this has been moved for the JIT to work, nothing is confirmed here DSi.ARM7.Halt(4); } void DSi_BPTWL::DoShutdown() { ResetButtonState(); DSi.Stop(Platform::StopReason::PowerOff); } void DSi_BPTWL::SetPowerButtonHeld(double time) { if (!PowerButtonDownFlag) { PowerButtonDownFlag = true; PowerButtonTime = time; DoPowerButtonPress(); return; } double elapsed = time - PowerButtonTime; if (elapsed < 0) return; if (elapsed >= PowerButtonForcedShutdownTime) { Log(LogLevel::Debug, "Force power off via DSi power button\n"); DoPowerButtonForceShutdown(); return; } if (elapsed >= PowerButtonShutdownTime) { DoPowerButtonShutdown(); } } void DSi_BPTWL::SetPowerButtonReleased(double time) { double elapsed = time - PowerButtonTime; if (elapsed >= 0 && elapsed < PowerButtonShutdownTime) { DoPowerButtonReset(); } PowerButtonTime = 0.0; PowerButtonDownFlag = false; PowerButtonShutdownFlag = false; } void DSi_BPTWL::SetVolumeSwitchHeld(u32 key) { VolumeSwitchKeysDown |= (1 << key); } void DSi_BPTWL::SetVolumeSwitchReleased(u32 key) { VolumeSwitchKeysDown &= ~(1 << key); VolumeSwitchDownFlag = false; VolumeSwitchTime = 0.0; VolumeSwitchRepeatTime = 0.0; } inline bool DSi_BPTWL::CheckVolumeSwitchKeysValid() const { bool up = VolumeSwitchKeysDown & (1 << volumeKey_Up); bool down = VolumeSwitchKeysDown & (1 << volumeKey_Down); return up != down; } s32 DSi_BPTWL::ProcessVolumeSwitchInput(double time) { if (!CheckVolumeSwitchKeysValid()) return -1; s32 key = VolumeSwitchKeysDown & (1 << volumeKey_Up) ? volumeKey_Up : volumeKey_Down; // Always fire an IRQ when first pressed if (!VolumeSwitchDownFlag) { VolumeSwitchDownFlag = true; VolumeSwitchTime = time; DoVolumeSwitchPress(key); return key; } // Handle key repetition mechanic if (VolumeSwitchRepeatTime == 0) { double elapsed = time - VolumeSwitchTime; if (elapsed < VolumeSwitchRepeatStart) return -1; VolumeSwitchRepeatTime = time; DoVolumeSwitchPress(key); return key; } double elapsed = time - VolumeSwitchRepeatTime; if (elapsed < VolumeSwitchRepeatRate) return -1; double rem = fmod(elapsed, VolumeSwitchRepeatRate); VolumeSwitchRepeatTime = time - rem; DoVolumeSwitchPress(key); return key; } void DSi_BPTWL::DoPowerButtonPress() { // Set button pressed IRQ SetIRQ(IRQ_PowerButtonPressed); // There is no default hardware behavior for pressing the power button } void DSi_BPTWL::DoPowerButtonReset() { // Reset via IRQ, handled by software SetIRQ(IRQ_PowerButtonReset); // Reset automatically via hardware if (!GetIRQMode()) { // Assumes this isn't called during normal CPU execution DoHardwareReset(true); } } void DSi_BPTWL::DoPowerButtonShutdown() { // Shutdown via IRQ, handled by software if (!PowerButtonShutdownFlag) { SetIRQ(IRQ_PowerButtonShutdown); } PowerButtonShutdownFlag = true; // Shutdown automatically via hardware if (!GetIRQMode()) { DoShutdown(); } // The IRQ is only fired once (hence the need for an if guard), // but the hardware shutdown is continuously triggered. // That way when switching the IRQ mode while holding // down the power button, the DSi will still shut down } void DSi_BPTWL::DoPowerButtonForceShutdown() { DoShutdown(); } void DSi_BPTWL::DoVolumeSwitchPress(u32 key) { u8 volume = Registers[0x40]; switch (key) { case volumeKey_Up: volume = VolumeUpTable[volume]; break; case volumeKey_Down: volume = VolumeDownTable[volume]; break; } Registers[0x40] = volume; SetIRQ(IRQ_VolumeSwitchPressed); } void DSi_BPTWL::SetIRQ(u8 irqFlag) { Registers[0x10] |= irqFlag & IRQ_ValidMask; if (GetIRQMode()) { DSi.SetIRQ2(IRQ2_DSi_BPTWL); } } void DSi_BPTWL::Acquire() { //printf("BPTWL: start\n"); } u8 DSi_BPTWL::Read(bool last) { //printf("BPTWL: read %02X -> %02X @ %08X\n", CurPos, Registers[CurPos], NDS::GetPC(1)); u8 ret = Registers[CurPos]; // IRQ flags are automatically cleared upon read if (CurPos == 0x10) { Registers[0x10] = 0; } CurPos++; if (last) { CurPos = -1; } return ret; } void DSi_BPTWL::Write(u8 val, bool last) { if (last) { CurPos = -1; return; } if (CurPos == 0xFFFFFFFF) { CurPos = val; //printf("BPTWL: reg=%02X\n", val); return; } if (CurPos == 0x11 && val == 0x01) { // Assumes this is called during normal CPU execution DoHardwareReset(false); val = 0; // checkme CurPos = -1; return; } // Mask volume level if (CurPos == 0x40) { val &= 0x1F; } // Clamp backlight level if (CurPos == 0x41) { val = val > 4 ? 4 : val; } if (CurPos == 0x11 || CurPos == 0x12 || CurPos == 0x21 || CurPos == 0x30 || CurPos == 0x31 || CurPos == 0x40 || CurPos == 0x41 || CurPos == 0x60 || CurPos == 0x63 || (CurPos >= 0x70 && CurPos <= 0x77) || CurPos == 0x80 || CurPos == 0x81) { Registers[CurPos] = val; } //printf("BPTWL: write %02X -> %02X\n", CurPos, val); CurPos++; // CHECKME } DSi_I2CHost::DSi_I2CHost(melonDS::DSi& dsi) : DSi(dsi) { BPTWL = new DSi_BPTWL(dsi, this); Camera0 = new DSi_Camera(dsi, this, 0); Camera1 = new DSi_Camera(dsi, this, 1); } DSi_I2CHost::~DSi_I2CHost() { delete BPTWL; BPTWL = nullptr; delete Camera0; Camera0 = nullptr; delete Camera1; Camera1 = nullptr; } void DSi_I2CHost::Reset() { Cnt = 0; Data = 0; CurDeviceID = 0; CurDevice = nullptr; BPTWL->Reset(); Camera0->Reset(); Camera1->Reset(); } void DSi_I2CHost::DoSavestate(Savestate* file) { file->Section("I2Ci"); file->Var8(&Cnt); file->Var8(&Data); file->Var8(&CurDeviceID); if (!file->Saving) { GetCurDevice(); } BPTWL->DoSavestate(file); Camera0->DoSavestate(file); Camera1->DoSavestate(file); } void DSi_I2CHost::GetCurDevice() { switch (CurDeviceID) { case 0x4A: CurDevice = BPTWL; break; case 0x78: CurDevice = Camera0; break; case 0x7A: CurDevice = Camera1; break; case 0xA0: case 0xE0: CurDevice = nullptr; break; default: Log(LogLevel::Warn, "I2C: unknown device %02X\n", CurDeviceID); CurDevice = nullptr; break; } } void DSi_I2CHost::WriteCnt(u8 val) { //printf("I2C: write CNT %02X, %02X, %08X\n", val, Data, NDS::GetPC(1)); // TODO: check ACK flag // TODO: transfer delay // TODO: IRQ // TODO: check read/write direction if (val & (1<<7)) { bool islast = val & (1<<0); if (val & (1<<5)) { // read val &= 0xF7; if (CurDevice) { Data = CurDevice->Read(islast); } else { Data = 0xFF; } //printf("I2C read, device=%02X, cnt=%02X, data=%02X, last=%d\n", Device, val, Data, islast); } else { // write val &= 0xE7; bool ack = true; if (val & (1<<1)) { CurDeviceID = Data & 0xFE; //printf("I2C: %s start, device=%02X\n", (Data&0x01)?"read":"write", Device); GetCurDevice(); if (CurDevice) { CurDevice->Acquire(); } else { ack = false; } } else { //printf("I2C write, device=%02X, cnt=%02X, data=%02X, last=%d\n", Device, val, Data, islast); if (CurDevice) { CurDevice->Write(Data, islast); } else { ack = false; } } if (ack) val |= (1<<4); } val &= 0x7F; } Cnt = val; } u8 DSi_I2CHost::ReadData() { return Data; } void DSi_I2CHost::WriteData(u8 val) { Data = val; } }