/* Copyright 2016-2022 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 "DSi.h" #include "DSi_Camera.h" #include "Platform.h" namespace DSi_CamModule { Camera* Camera0; // 78 / facing outside Camera* Camera1; // 7A / selfie cam u16 ModuleCnt; u16 Cnt; u32 CropStart, CropEnd; // pixel data buffer holds a maximum of 512 words, regardless of how long scanlines are u32 DataBuffer[512]; u32 BufferReadPos, BufferWritePos; u32 BufferNumLines; Camera* CurCamera; // note on camera data/etc intervals // on hardware those are likely affected by several factors // namely, how long cameras take to process frames // camera IRQ is fired at roughly 15FPS with default config const u32 kIRQInterval = 1120000; // ~30 FPS const u32 kTransferStart = 60000; bool Init() { Camera0 = new Camera(0); Camera1 = new Camera(1); return true; } void DeInit() { delete Camera0; delete Camera1; } void Reset() { Camera0->Reset(); Camera1->Reset(); ModuleCnt = 0; // CHECKME Cnt = 0; CropStart = 0; CropEnd = 0; memset(DataBuffer, 0, 512*sizeof(u32)); BufferReadPos = 0; BufferWritePos = 0; BufferNumLines = 0; CurCamera = nullptr; NDS::ScheduleEvent(NDS::Event_DSi_CamIRQ, true, kIRQInterval, IRQ, 0); } void Stop() { Camera0->Stop(); Camera1->Stop(); } void DoSavestate(Savestate* file) { file->Section("CAMi"); file->Var16(&ModuleCnt); file->Var16(&Cnt); /*file->VarArray(FrameBuffer, sizeof(FrameBuffer)); file->Var32(&TransferPos); file->Var32(&FrameLength);*/ Camera0->DoSavestate(file); Camera1->DoSavestate(file); } void IRQ(u32 param) { Camera* activecam = nullptr; // TODO: cameras don't have any priority! // activating both together will jumble the image data together if (Camera0->IsActivated()) activecam = Camera0; else if (Camera1->IsActivated()) activecam = Camera1; if (activecam) { activecam->StartTransfer(); if (Cnt & (1<<11)) NDS::SetIRQ(0, NDS::IRQ_DSi_Camera); if (Cnt & (1<<15)) { BufferReadPos = 0; BufferWritePos = 0; BufferNumLines = 0; CurCamera = activecam; NDS::ScheduleEvent(NDS::Event_DSi_CamTransfer, false, kTransferStart, TransferScanline, 0); } } NDS::ScheduleEvent(NDS::Event_DSi_CamIRQ, true, kIRQInterval, IRQ, 0); } void TransferScanline(u32 line) { u32* dstbuf = &DataBuffer[BufferWritePos]; int maxlen = 512 - BufferWritePos; u32 tmpbuf[512]; int datalen = CurCamera->TransferScanline(tmpbuf, 512); // TODO: must be tweaked such that each block has enough time to transfer u32 delay = datalen*4 + 16; int copystart = 0; int copylen = datalen; if (Cnt & (1<<14)) { // crop picture int ystart = (CropStart >> 16) & 0x1FF; int yend = (CropEnd >> 16) & 0x1FF; if (line < ystart || line > yend) { if (!CurCamera->TransferDone()) NDS::ScheduleEvent(NDS::Event_DSi_CamTransfer, false, delay, TransferScanline, line+1); return; } int xstart = (CropStart >> 1) & 0x1FF; int xend = (CropEnd >> 1) & 0x1FF; copystart = xstart; copylen = xend+1 - xstart; if ((copystart + copylen) > datalen) copylen = datalen - copystart; if (copylen < 0) copylen = 0; } if (copylen > maxlen) { copylen = maxlen; Cnt |= (1<<4); } if (Cnt & (1<<13)) { // convert to RGB for (u32 i = 0; i < copylen; i++) { u32 val = tmpbuf[copystart + i]; int y1 = val & 0xFF; int u = (val >> 8) & 0xFF; int y2 = (val >> 16) & 0xFF; int v = (val >> 24) & 0xFF; u -= 128; v -= 128; int r1 = y1 + ((v * 91881) >> 16); int g1 = y1 - ((v * 46793) >> 16) - ((u * 22544) >> 16); int b1 = y1 + ((u * 116129) >> 16); int r2 = y2 + ((v * 91881) >> 16); int g2 = y2 - ((v * 46793) >> 16) - ((u * 22544) >> 16); int b2 = y2 + ((u * 116129) >> 16); r1 = std::clamp(r1, 0, 255); g1 = std::clamp(g1, 0, 255); b1 = std::clamp(b1, 0, 255); r2 = std::clamp(r2, 0, 255); g2 = std::clamp(g2, 0, 255); b2 = std::clamp(b2, 0, 255); u32 col1 = (r1 >> 3) | ((g1 >> 3) << 5) | ((b1 >> 3) << 10) | 0x8000; u32 col2 = (r2 >> 3) | ((g2 >> 3) << 5) | ((b2 >> 3) << 10) | 0x8000; dstbuf[i] = col1 | (col2 << 16); } } else { // return raw data memcpy(dstbuf, &tmpbuf[copystart], copylen*sizeof(u32)); } u32 numscan = Cnt & 0x000F; if (BufferNumLines >= numscan) { BufferReadPos = 0; // checkme BufferWritePos = 0; BufferNumLines = 0; DSi::CheckNDMAs(0, 0x0B); } else { BufferWritePos += copylen; if (BufferWritePos > 512) BufferWritePos = 512; BufferNumLines++; } if (CurCamera->TransferDone()) return; NDS::ScheduleEvent(NDS::Event_DSi_CamTransfer, false, delay, TransferScanline, line+1); } u8 Read8(u32 addr) { // printf("unknown DSi cam read8 %08X\n", addr); return 0; } u16 Read16(u32 addr) { switch (addr) { case 0x04004200: return ModuleCnt; case 0x04004202: return Cnt; } printf("unknown DSi cam read16 %08X\n", addr); return 0; } u32 Read32(u32 addr) { switch (addr) { case 0x04004204: { u32 ret = DataBuffer[BufferReadPos]; if (Cnt & (1<<15)) { if (BufferReadPos < 511) BufferReadPos++; // CHECKME!!!! // also presumably we should set bit4 in Cnt if there's no new data to be read } return ret; } case 0x04004210: return CropStart; case 0x04004214: return CropEnd; } printf("unknown DSi cam read32 %08X\n", addr); return 0; } void Write8(u32 addr, u8 val) { // printf("unknown DSi cam write8 %08X %02X\n", addr, val); } void Write16(u32 addr, u16 val) { switch (addr) { case 0x04004200: { u16 oldcnt = ModuleCnt; ModuleCnt = val; if ((ModuleCnt & (1<<1)) && !(oldcnt & (1<<1))) { // reset shit to zero // CHECKME Cnt = 0; } if ((ModuleCnt & (1<<5)) && !(oldcnt & (1<<5))) { // TODO: reset I2C?? } } return; case 0x04004202: { // TODO: during a transfer, clearing bit15 does not reflect immediately // maybe it needs to finish the trasnfer or atleast the current block // checkme u16 oldmask; if (Cnt & 0x8000) { val &= 0x8F20; oldmask = 0x601F; } else { val &= 0xEF2F; oldmask = 0x0010; } Cnt = (Cnt & oldmask) | (val & ~0x0020); if (val & (1<<5)) { Cnt &= ~(1<<4); BufferReadPos = 0; BufferWritePos = 0; } if ((val & (1<<15)) && !(Cnt & (1<<15))) { // start transfer //DSi::CheckNDMAs(0, 0x0B); } } return; case 0x04004210: if (Cnt & (1<<15)) return; CropStart = (CropStart & 0x01FF0000) | (val & 0x03FE); return; case 0x04004212: if (Cnt & (1<<15)) return; CropStart = (CropStart & 0x03FE) | ((val & 0x01FF) << 16); return; case 0x04004214: if (Cnt & (1<<15)) return; CropEnd = (CropEnd & 0x01FF0000) | (val & 0x03FE); return; case 0x04004216: if (Cnt & (1<<15)) return; CropEnd = (CropEnd & 0x03FE) | ((val & 0x01FF) << 16); return; } printf("unknown DSi cam write16 %08X %04X\n", addr, val); } void Write32(u32 addr, u32 val) { switch (addr) { case 0x04004210: if (Cnt & (1<<15)) return; CropStart = val & 0x01FF03FE; return; case 0x04004214: if (Cnt & (1<<15)) return; CropEnd = val & 0x01FF03FE; return; } printf("unknown DSi cam write32 %08X %08X\n", addr, val); } Camera::Camera(u32 num) { Num = num; } Camera::~Camera() { } void Camera::DoSavestate(Savestate* file) { char magic[5] = "CAMx"; magic[3] = '0' + Num; file->Section(magic); file->Var32(&DataPos); file->Var32(&RegAddr); file->Var16(&RegData); file->Var16(&PLLDiv); file->Var16(&PLLPDiv); file->Var16(&PLLCnt); file->Var16(&ClocksCnt); file->Var16(&StandbyCnt); file->Var16(&MiscCnt); file->Var16(&MCUAddr); file->VarArray(MCURegs, 0x8000); } void Camera::Reset() { Platform::Camera_Stop(Num); DataPos = 0; RegAddr = 0; RegData = 0; PLLDiv = 0x0366; PLLPDiv = 0x00F5; PLLCnt = 0x21F9; ClocksCnt = 0; StandbyCnt = 0x4029; // checkme MiscCnt = 0; MCUAddr = 0; memset(MCURegs, 0, 0x8000); // default state is preview mode (checkme) MCURegs[0x2104] = 3; TransferY = 0; memset(FrameBuffer, 0, (640*480/2)*sizeof(u32)); } void Camera::Stop() { Platform::Camera_Stop(Num); } bool Camera::IsActivated() { if (StandbyCnt & (1<<14)) return false; // standby if (!(MiscCnt & (1<<9))) return false; // data transfer not enabled return true; } void Camera::StartTransfer() { TransferY = 0; u8 state = MCURegs[0x2104]; if (state == 3) // preview { FrameWidth = *(u16*)&MCURegs[0x2703]; FrameHeight = *(u16*)&MCURegs[0x2705]; FrameReadMode = *(u16*)&MCURegs[0x2717]; FrameFormat = *(u16*)&MCURegs[0x2755]; } else if (state == 7) // capture { FrameWidth = *(u16*)&MCURegs[0x2707]; FrameHeight = *(u16*)&MCURegs[0x2709]; FrameReadMode = *(u16*)&MCURegs[0x272D]; FrameFormat = *(u16*)&MCURegs[0x2757]; } else { FrameWidth = 0; FrameHeight = 0; FrameReadMode = 0; FrameFormat = 0; } Platform::Camera_CaptureFrame(Num, FrameBuffer, 640, 480, true); } bool Camera::TransferDone() { return TransferY >= FrameHeight; } int Camera::TransferScanline(u32* buffer, int maxlen) { if (TransferY >= FrameHeight) return 0; if (FrameWidth > 640 || FrameHeight > 480 || FrameWidth < 2 || FrameHeight < 2 || (FrameWidth & 1)) { // TODO work out something for these cases? printf("CAM%d: invalid resolution %dx%d\n", Num, FrameWidth, FrameHeight); //memset(buffer, 0, width*height*sizeof(u16)); return 0; } // TODO: non-YUV pixel formats and all int retlen = FrameWidth >> 1; int sy = (TransferY * 480) / FrameHeight; if (FrameReadMode & (1<<1)) sy = 479 - sy; if (FrameReadMode & (1<<0)) { for (int dx = 0; dx < retlen; dx++) { if (dx >= maxlen) break; int sx = (dx * 640) / FrameWidth; u32 val = FrameBuffer[sy*320 + sx]; buffer[dx] = val; } } else { for (int dx = 0; dx < retlen; dx++) { if (dx >= maxlen) break; int sx = 319 - ((dx * 640) / FrameWidth); u32 val = FrameBuffer[sy*320 + sx]; buffer[dx] = (val & 0xFF00FF00) | ((val >> 16) & 0xFF) | ((val & 0xFF) << 16); } } TransferY++; return retlen; } void Camera::I2C_Start() { DataPos = 0; } u8 Camera::I2C_Read(bool last) { u8 ret; if (DataPos & 0x1) { ret = RegData & 0xFF; RegAddr += 2; // checkme } else { RegData = I2C_ReadReg(RegAddr); ret = RegData >> 8; } if (last) DataPos = 0; else DataPos++; return ret; } void Camera::I2C_Write(u8 val, bool last) { if (DataPos < 2) { if (DataPos == 0) RegAddr = val << 8; else RegAddr |= val; if (RegAddr & 0x1) printf("DSi_Camera: !! UNALIGNED REG ADDRESS %04X\n", RegAddr); } else { if (DataPos & 0x1) { RegData |= val; I2C_WriteReg(RegAddr, RegData); RegAddr += 2; // checkme } else { RegData = val << 8; } } if (last) DataPos = 0; else DataPos++; } u16 Camera::I2C_ReadReg(u16 addr) { switch (addr) { case 0x0000: return 0x2280; // chip ID case 0x0010: return PLLDiv; case 0x0012: return PLLPDiv; case 0x0014: return PLLCnt; case 0x0016: return ClocksCnt; case 0x0018: return StandbyCnt; case 0x001A: return MiscCnt; case 0x098C: return MCUAddr; case 0x0990: case 0x0992: case 0x0994: case 0x0996: case 0x0998: case 0x099A: case 0x099C: case 0x099E: { addr -= 0x0990; u16 ret = MCU_Read((MCUAddr & 0x7FFF) + addr); if (!(MCUAddr & (1<<15))) ret |= (MCU_Read((MCUAddr & 0x7FFF) + addr+1) << 8); return ret; } case 0x301A: return ((~StandbyCnt) & 0x4000) >> 12; } if(Num==1)printf("DSi_Camera%d: unknown read %04X\n", Num, addr); return 0; } void Camera::I2C_WriteReg(u16 addr, u16 val) { switch (addr) { case 0x0010: PLLDiv = val & 0x3FFF; return; case 0x0012: PLLPDiv = val & 0xBFFF; return; case 0x0014: // shouldn't be instant either? val &= 0x7FFF; val |= ((val & 0x0002) << 14); PLLCnt = val; return; case 0x0016: ClocksCnt = val; //printf("ClocksCnt=%04X\n", val); return; case 0x0018: { bool wasactive = IsActivated(); // TODO: this shouldn't be instant, but uh val &= 0x003F; val |= ((val & 0x0001) << 14); StandbyCnt = val; //printf("CAM%d STBCNT=%04X (%04X)\n", Num, StandbyCnt, val); bool isactive = IsActivated(); if (isactive && !wasactive) Platform::Camera_Start(Num); else if (wasactive && !isactive) Platform::Camera_Stop(Num); } return; case 0x001A: { bool wasactive = IsActivated(); MiscCnt = val & 0x0B7B; //printf("CAM%d MISCCNT=%04X (%04X)\n", Num, MiscCnt, val); bool isactive = IsActivated(); if (isactive && !wasactive) Platform::Camera_Start(Num); else if (wasactive && !isactive) Platform::Camera_Stop(Num); } return; case 0x098C: MCUAddr = val; return; case 0x0990: case 0x0992: case 0x0994: case 0x0996: case 0x0998: case 0x099A: case 0x099C: case 0x099E: addr -= 0x0990; MCU_Write((MCUAddr & 0x7FFF) + addr, val&0xFF); if (!(MCUAddr & (1<<15))) MCU_Write((MCUAddr & 0x7FFF) + addr+1, val>>8); return; } if(Num==1)printf("DSi_Camera%d: unknown write %04X %04X\n", Num, addr, val); } // TODO: not sure at all what is the accessible range // or if there is any overlap in the address range u8 Camera::MCU_Read(u16 addr) { addr &= 0x7FFF; return MCURegs[addr]; } void Camera::MCU_Write(u16 addr, u8 val) { addr &= 0x7FFF; switch (addr) { case 0x2103: // SEQ_CMD MCURegs[addr] = 0; if (val == 2) MCURegs[0x2104] = 7; // capture mode else if (val == 1) MCURegs[0x2104] = 3; // preview mode else if (val != 5 && val != 6) printf("CAM%d: atypical SEQ_CMD %04X\n", Num, val); return; case 0x2104: // SEQ_STATE, read-only return; } MCURegs[addr] = val; } void Camera::InputFrame(u32* data, int width, int height, bool rgb) { // TODO: double-buffering? if (width == 640 && height == 480 && !rgb) { memcpy(FrameBuffer, data, (640*480/2)*sizeof(u32)); return; } if (rgb) { for (int dy = 0; dy < 480; dy++) { int sy = (dy * height) / 480; for (int dx = 0; dx < 640; dx+=2) { int sx; sx = (dx * width) / 640; u32 pixel1 = data[sy*width + sx]; sx = ((dx+1) * width) / 640; u32 pixel2 = data[sy*width + sx]; int r1 = (pixel1 >> 16) & 0xFF; int g1 = (pixel1 >> 8) & 0xFF; int b1 = pixel1 & 0xFF; int r2 = (pixel2 >> 16) & 0xFF; int g2 = (pixel2 >> 8) & 0xFF; int b2 = pixel2 & 0xFF; int y1 = ((r1 * 19595) + (g1 * 38470) + (b1 * 7471)) >> 16; int u1 = ((b1 - y1) * 32244) >> 16; int v1 = ((r1 - y1) * 57475) >> 16; int y2 = ((r2 * 19595) + (g2 * 38470) + (b2 * 7471)) >> 16; int u2 = ((b2 - y2) * 32244) >> 16; int v2 = ((r2 - y2) * 57475) >> 16; u1 += 128; v1 += 128; u2 += 128; v2 += 128; y1 = std::clamp(y1, 0, 255); u1 = std::clamp(u1, 0, 255); v1 = std::clamp(v1, 0, 255); y2 = std::clamp(y2, 0, 255); u2 = std::clamp(u2, 0, 255); v2 = std::clamp(v2, 0, 255); // huh u1 = (u1 + u2) >> 1; v1 = (v1 + v2) >> 1; FrameBuffer[(dy*640 + dx) / 2] = y1 | (u1 << 8) | (y2 << 16) | (v1 << 24); } } } else { for (int dy = 0; dy < 480; dy++) { int sy = (dy * height) / 480; for (int dx = 0; dx < 640; dx+=2) { int sx = (dx * width) / 640; FrameBuffer[(dy*640 + dx) / 2] = data[(sy*width + sx) / 2]; } } } } }