#include "gte.h" #include "YBaseLib/Log.h" #include Log_SetChannel(GTE); static inline constexpr u32 CountLeadingBits(u32 value) { u32 count = 0; if ((value & UINT32_C(0x80000000)) != 0) { for (u32 i = 0; i < 32 && ((value & UINT32_C(0x80000000)) != 0); i++) { count++; value <<= 1; } } else { for (u32 i = 0; i < 32 && (value & UINT32_C(0x80000000)) == 0; i++) { count++; value <<= 1; } } return count; } namespace GTE { Core::Core() = default; Core::~Core() = default; void Core::Initialize() {} void Core::Reset() { m_regs = {}; } bool Core::DoState(StateWrapper& sw) { sw.DoPOD(&m_regs); return !sw.HasError(); } u32 Core::ReadDataRegister(u32 index) const { switch (index) { case 15: // SXY3 { // mirror of SXY2 return m_regs.dr32[14]; } case 28: // IRGB case 29: // ORGB { // ORGB register, convert 16-bit to 555 const u8 r = static_cast(std::clamp(m_regs.IR1 / 0x80, 0x00, 0x1F)); const u8 g = static_cast(std::clamp(m_regs.IR2 / 0x80, 0x00, 0x1F)); const u8 b = static_cast(std::clamp(m_regs.IR3 / 0x80, 0x00, 0x1F)); return ZeroExtend32(r) | (ZeroExtend32(g) << 5) | (ZeroExtend32(b) << 10); } case 0: // V0-1 [x,y] case 1: // V0[z] case 2: // V1-2 [x,y] case 3: // V1[z] case 4: // V2-3 [x,y] case 5: // V2[z] case 6: // RGBC case 7: // OTZ case 8: // IR0 case 9: // IR1 case 10: // IR2 case 11: // IR3 case 12: // SXY0 case 13: // SXY1 case 14: // SXY2 case 16: // SZ0 case 17: // SZ1 case 18: // SZ2 case 19: // SZ3 case 20: // RGB0 case 21: // RGB1 case 22: // RGB2 case 23: // RES1 case 24: // MAC0 case 25: // MAC1 case 26: // MAC2 case 27: // MAC3 case 30: // LZCS case 31: // LZCR return m_regs.dr32[index]; default: Panic("Unknown register"); return 0; } } void Core::WriteDataRegister(u32 index, u32 value) { // Log_DebugPrintf("DataReg(%u) <- 0x%08X", index, value); switch (index) { case 1: // V0[z] case 3: // V1[z] case 5: // V2[z] case 8: // IR0 case 9: // IR1 case 10: // IR2 case 11: // IR3 { // sign-extend z component of vector registers m_regs.dr32[index] = SignExtend32(Truncate16(value)); } break; case 7: // OTZ case 16: // SZ0 case 17: // SZ1 case 18: // SZ2 case 19: // SZ3 { // zero-extend unsigned values m_regs.dr32[index] = ZeroExtend32(Truncate16(value)); } break; case 15: // SXY3 { // writing to SXYP pushes to the FIFO m_regs.dr32[12] = m_regs.dr32[13]; // SXY0 <- SXY1 m_regs.dr32[13] = m_regs.dr32[14]; // SXY1 <- SXY2 m_regs.dr32[14] = value; // SXY2 <- SXYP } break; case 28: // IRGB { // IRGB register, convert 555 to 16-bit m_regs.IRGB = value & UINT32_C(0x7FFF); m_regs.dr32[9] = SignExtend32(static_cast(Truncate16((value & UINT32_C(0x1F)) * UINT32_C(0x80)))); m_regs.dr32[10] = SignExtend32(static_cast(Truncate16(((value >> 5) & UINT32_C(0x1F)) * UINT32_C(0x80)))); m_regs.dr32[11] = SignExtend32(static_cast(Truncate16(((value >> 10) & UINT32_C(0x1F)) * UINT32_C(0x80)))); } break; case 30: // LZCS { m_regs.LZCS = static_cast(value); m_regs.LZCR = CountLeadingBits(value); } break; case 29: // ORGB case 31: // LZCR { // read-only registers } break; case 0: // V0-1 [x,y] case 2: // V1-2 [x,y] case 4: // V2-3 [x,y] case 6: // RGBC case 12: // SXY0 case 13: // SXY1 case 14: // SXY2 case 20: // RGB0 case 21: // RGB1 case 22: // RGB2 case 23: // RES1 case 24: // MAC0 case 25: // MAC1 case 26: // MAC2 case 27: // MAC3 m_regs.dr32[index] = value; break; default: Panic("Unknown register"); break; } } u32 Core::ReadControlRegister(u32 index) const { return m_regs.cr32[index]; } void Core::WriteControlRegister(u32 index, u32 value) { // Log_DebugPrintf("ControlReg(%u,%u) <- 0x%08X", index, index + 32, value); switch (index) { case 36 - 32: // RT33 case 44 - 32: // L33 case 52 - 32: // LR33 case 58 - 32: // H - sign-extended on read but zext on use case 59 - 32: // DQA case 61 - 32: // ZSF3 case 62 - 32: // ZSF4 { // MSB of the last matrix element is the last element sign-extended m_regs.cr32[index] = SignExtend32(Truncate16(value)); } break; case 63 - 32: // FLAG { m_regs.FLAG.bits = value & UINT32_C(0x7FFFF000); m_regs.FLAG.UpdateError(); } break; case 32 - 32: // RT11,RT12 case 33 - 32: // RT13,RT21 case 34 - 32: // RT22,RT23 case 35 - 32: // RT31,RT32 case 37 - 32: // TRX case 38 - 32: // TRY case 39 - 32: // TRZ case 40 - 32: // L11,L12 case 41 - 32: // L13,L21 case 42 - 32: // L22,L23 case 43 - 32: // L31,L32 case 45 - 32: // RBK case 46 - 32: // GBK case 47 - 32: // BBK case 48 - 32: // LR11,LR12 case 49 - 32: // LR13,LR21 case 50 - 32: // LR22,LR23 case 51 - 32: // LR31,LR32 case 53 - 32: // RFC case 54 - 32: // GFC case 55 - 32: // BFC case 56 - 32: // OFX case 57 - 32: // OFY case 60 - 32: // DQB { // written as-is, 2x16 or 1x32 bits m_regs.cr32[index] = value; } break; default: Panic("Unknown register"); break; } } void Core::ExecuteInstruction(Instruction inst) { // Panic("GTE instruction"); switch (inst.command) { case 0x01: Execute_RTPS(inst); break; case 0x06: Execute_NCLIP(inst); break; case 0x13: Execute_NCDS(inst); break; case 0x28: Execute_SQR(inst); break; case 0x2D: Execute_AVSZ3(inst); break; case 0x2E: Execute_AVSZ4(inst); break; case 0x30: Execute_RTPT(inst); break; case 0x12: Execute_MVMVA(inst); break; default: Panic("Missing handler"); break; } } void Core::SetMAC(u32 index, s64 value) { if (value < INT64_C(-2147483648)) m_regs.FLAG.SetMACUnderflow(index); else if (value > INT64_C(2147483647)) m_regs.FLAG.SetMACOverflow(index); m_regs.dr32[24 + index] = Truncate32(static_cast(value)); } void Core::SetIR(u32 index, s32 value, bool lm) { if (lm && value < 0) { m_regs.FLAG.SetIRSaturated(index); m_regs.dr32[8 + index] = 0; return; } // saturate to -32768..32767 if (!lm && value < -32768) { m_regs.FLAG.SetIRSaturated(index); m_regs.dr32[8 + index] = static_cast(-1); return; } if (value > 32767) { m_regs.FLAG.SetIRSaturated(index); m_regs.dr32[8 + index] = UINT32_C(0x7FFF); return; } // store the sign extension in the padding bits m_regs.dr32[8 + index] = value; } void Core::SetIR0(s32 value) { if (value < 0) { m_regs.FLAG.SetIRSaturated(0); m_regs.dr32[8] = 0; return; } if (value > 0x1000) { m_regs.FLAG.SetIRSaturated(0); m_regs.dr32[8] = UINT32_C(0x1000); return; } // store the sign extension in the padding bits m_regs.dr32[8] = static_cast(value); } void Core::SetOTZ(s32 value) { if (value < 0) { m_regs.FLAG.sz1_otz_saturated = true; value = 0; } else if (value > 0xFFFF) { m_regs.FLAG.sz1_otz_saturated = true; value = 0xFFFF; } m_regs.dr32[7] = static_cast(value); } void Core::PushSXY(s32 x, s32 y) { if (x < -1024) { m_regs.FLAG.sx2_saturated = true; x = -1024; } else if (x > 32767) { m_regs.FLAG.sx2_saturated = true; x = 32767; } if (y < -1024) { m_regs.FLAG.sy2_saturated = true; y = -1024; } else if (x > 32767) { m_regs.FLAG.sy2_saturated = true; y = 32767; } m_regs.dr32[12] = m_regs.dr32[13]; // SXY0 <- SXY1 m_regs.dr32[13] = m_regs.dr32[14]; // SXY1 <- SXY2 m_regs.SXY2[0] = static_cast(x); m_regs.SXY2[1] = static_cast(y); } void Core::PushSZ(s32 value) { if (value < 0) { m_regs.FLAG.sz1_otz_saturated = true; value = 0; } else if (value > 0xFFFF) { m_regs.FLAG.sz1_otz_saturated = true; value = 0xFFFF; } m_regs.dr32[16] = m_regs.dr32[17]; // SZ0 <- SZ1 m_regs.dr32[17] = m_regs.dr32[18]; // SZ1 <- SZ2 m_regs.dr32[18] = m_regs.dr32[19]; // SZ2 <- SZ3 m_regs.dr32[19] = static_cast(value); // SZ3 <- value } void Core::PushRGB(u8 r, u8 g, u8 b, u8 c) { m_regs.RGB0 = m_regs.RGB1; m_regs.RGB1 = m_regs.RGB2; m_regs.RGB2 = ZeroExtend32(r) | (ZeroExtend32(g) << 8) | (ZeroExtend32(b) << 16) | (ZeroExtend32(c) << 24); } s32 Core::Divide(s32 dividend, s32 divisor) { DebugAssert(divisor != 0); const s32 res = dividend / divisor; if (res > 0x1FFFF) { m_regs.FLAG.divide_overflow = true; return 0x1FFFF; } return res; } s32 Core::SaturateDivide(s32 result) { if (result > 0x1FFFF) { m_regs.FLAG.divide_overflow = true; return 0x1FFFF; } return result; } void Core::RTPS(const s16 V[3], bool sf) { const u8 shift = sf ? 12 : 0; // IR1 = MAC1 = (TRX*1000h + RT11*VX0 + RT12*VY0 + RT13*VZ0) SAR (sf*12) // IR2 = MAC2 = (TRY*1000h + RT21*VX0 + RT22*VY0 + RT23*VZ0) SAR (sf*12) // IR3 = MAC3 = (TRZ*1000h + RT31*VX0 + RT32*VY0 + RT33*VZ0) SAR (sf*12) #define T(i) \ (((s64(m_regs.TR[i]) * 0x1000) + (s64(m_regs.RT[i][0]) * V[0]) + (s64(m_regs.RT[i][1]) * V[1]) + \ (s64(m_regs.RT[i][2]) * V[2])) >> \ shift) const s64 Rx = T(0); const s64 Ry = T(1); const s64 Rz = T(2); #undef T SetMAC(1, Rx); SetMAC(2, Ry); SetMAC(3, Rz); SetIR(1, m_regs.MAC1, false); SetIR(2, m_regs.MAC2, false); SetIR(3, m_regs.MAC3, false); // SZ3 = MAC3 SAR ((1-sf)*12) ;ScreenZ FIFO 0..+FFFFh const s32 SZ3 = sf ? m_regs.MAC3 : (m_regs.MAC3 >> 12); PushSZ(SZ3); // MAC0=(((H*20000h/SZ3)+1)/2)*IR1+OFX, SX2=MAC0/10000h ;ScrX FIFO -400h..+3FFh // MAC0=(((H*20000h/SZ3)+1)/2)*IR2+OFY, SY2=MAC0/10000h ;ScrY FIFO -400h..+3FFh // MAC0=(((H*20000h/SZ3)+1)/2)*DQA+DQB, IR0=MAC0/1000h ;Depth cueing 0..+1000h s32 result; if (m_regs.SZ3 == 0) { // divide by zero result = 0x1FFFF; } else { result = SaturateDivide(Truncate32(((ZeroExtend64(m_regs.H) * 0x20000) / SZ3) + 1) / 2); } // MAC0=(((H*20000h/SZ3)+1)/2)*IR1+OFX, SX2=MAC0/10000h ;ScrX FIFO -400h..+3FFh const s32 MAC0_x = result * m_regs.IR1 + m_regs.OFX; const s32 MAC0_y = result * m_regs.IR2 + m_regs.OFY; const s32 MAC0_z = result * m_regs.DQA + m_regs.DQB; PushSXY(MAC0_x / 0x10000, MAC0_y / 0x10000); SetIR0(MAC0_z / 0x1000); } void Core::Execute_RTPS(Instruction inst) { m_regs.FLAG.Clear(); RTPS(m_regs.V0, inst.sf); m_regs.FLAG.UpdateError(); } void Core::Execute_RTPT(Instruction inst) { m_regs.FLAG.Clear(); const bool sf = inst.sf; RTPS(m_regs.V0, sf); RTPS(m_regs.V1, sf); RTPS(m_regs.V2, sf); m_regs.FLAG.UpdateError(); } void Core::Execute_NCLIP(Instruction inst) { // MAC0 = SX0*SY1 + SX1*SY2 + SX2*SY0 - SX0*SY2 - SX1*SY0 - SX2*SY1 m_regs.FLAG.Clear(); const s64 MAC0x = s64(m_regs.SXY0[0]) * s64(m_regs.SXY1[1]) + s64(m_regs.SXY1[0]) * s64(m_regs.SXY2[1]) + s64(m_regs.SXY2[0]) * s64(m_regs.SXY0[1]) - s64(m_regs.SXY0[0]) * s64(m_regs.SXY2[1]) - s64(m_regs.SXY1[0]) * s64(m_regs.SXY0[1]) - s64(m_regs.SXY2[0]) * s64(m_regs.SXY1[1]); SetMAC(0, MAC0x); m_regs.FLAG.UpdateError(); } void Core::Execute_SQR(Instruction inst) { m_regs.FLAG.Clear(); const u8 shift = inst.sf ? 12 : 0; SetMAC(1, (s32(m_regs.IR1) * s32(m_regs.IR1)) >> shift); SetMAC(2, (s32(m_regs.IR2) * s32(m_regs.IR2)) >> shift); SetMAC(3, (s32(m_regs.IR3) * s32(m_regs.IR3)) >> shift); const bool lm = inst.lm; SetIR(1, m_regs.MAC1, lm); SetIR(2, m_regs.MAC2, lm); SetIR(3, m_regs.MAC3, lm); m_regs.FLAG.UpdateError(); } void Core::Execute_AVSZ3(Instruction inst) { m_regs.FLAG.Clear(); const s64 MAC0 = static_cast(m_regs.ZSF3) * static_cast(ZeroExtend32(m_regs.SZ1) + ZeroExtend32(m_regs.SZ2) + ZeroExtend32(m_regs.SZ3)); SetMAC(0, MAC0); SetOTZ(static_cast(MAC0 / 0x1000)); m_regs.FLAG.UpdateError(); } void Core::Execute_AVSZ4(Instruction inst) { m_regs.FLAG.Clear(); const s64 MAC0 = static_cast(m_regs.ZSF4) * static_cast(ZeroExtend32(m_regs.SZ0) + ZeroExtend32(m_regs.SZ1) + ZeroExtend32(m_regs.SZ2) + ZeroExtend32(m_regs.SZ3)); SetMAC(0, MAC0); SetOTZ(static_cast(MAC0 / 0x1000)); m_regs.FLAG.UpdateError(); } s64 Core::VecDot(const s16 A[3], const s16 B[3]) { return s64(s32(A[0]) * s32(B[0])) + s64(s32(A[1]) * s32(B[1])) + s64(s32(A[2]) * s32(B[2])); } s64 Core::VecDot(const s16 A[3], s16 B_x, s16 B_y, s16 B_z) { return s64(s32(A[0]) * s32(B_x)) + s64(s32(A[1]) * s32(B_y)) + s64(s32(A[2]) * s32(B_z)); } void Core::MulMatVec(const s16 M[3][3], const s16 Vx, const s16 Vy, const s16 Vz, bool sf, bool lm) { #define dot3(i) \ TruncateAndSetMAC( \ TruncateMAC(TruncateMAC(s64(s32(M[i][0]) * s32(Vx))) + s64(s32(M[i][1]) * s32(Vy))) + \ s64(s32(M[i][2]) * s32(Vz)), \ sf) dot3(0); dot3(1); dot3(2); #undef dot3 TruncateAndSetIR<1>(m_regs.MAC1, lm); TruncateAndSetIR<2>(m_regs.MAC2, lm); TruncateAndSetIR<3>(m_regs.MAC3, lm); } void Core::MulMatVec(const s16 M[3][3], const s32 T[3], const s16 Vx, const s16 Vy, const s16 Vz, bool sf, bool lm) { #define dot3(i) \ TruncateAndSetMAC(s64(T[i] << 12) + \ TruncateMAC(TruncateMAC(TruncateMAC(s64(s32(M[i][0]) * s32(Vx))) + \ s64(s32(M[i][1]) * s32(Vy))) + \ s64(s32(M[i][2]) * s32(Vz))), \ sf) dot3(0); dot3(1); dot3(2); #undef dot3 TruncateAndSetIR<1>(m_regs.MAC1, lm); TruncateAndSetIR<2>(m_regs.MAC2, lm); TruncateAndSetIR<3>(m_regs.MAC3, lm); } void Core::NCDS(const s16 V[3], bool sf, bool lm) { const u8 shift = sf ? 12 : 0; // [IR1,IR2,IR3] = [MAC1,MAC2,MAC3] = (LLM*V0) SAR (sf*12) MulMatVec(m_regs.LLM, V[0], V[1], V[2], sf, lm); // [IR1,IR2,IR3] = [MAC1,MAC2,MAC3] = (BK*1000h + LCM*IR) SAR (sf*12) MulMatVec(m_regs.LCM, m_regs.BK, m_regs.IR1, m_regs.IR2, m_regs.IR3, sf, lm); // [MAC1,MAC2,MAC3] = [R*IR1,G*IR2,B*IR3] SHL 4 ;<--- for NCDx/NCCx TruncateAndSetMAC<1>((s64(ZeroExtend64(m_regs.RGBC[0])) << 4) * s64(m_regs.MAC1), false); TruncateAndSetMAC<2>((s64(ZeroExtend64(m_regs.RGBC[1])) << 4) * s64(m_regs.MAC2), false); TruncateAndSetMAC<3>((s64(ZeroExtend64(m_regs.RGBC[2])) << 4) * s64(m_regs.MAC3), false); // [MAC1,MAC2,MAC3] = MAC+(FC-MAC)*IR0 ;<--- for NCDx only // [IR1,IR2,IR3] = (([RFC,GFC,BFC] SHL 12) - [MAC1,MAC2,MAC3]) SAR (sf*12) TruncateAndSetIR<1>(s32((s64(m_regs.FC[0]) << 12) - s64(m_regs.MAC1)) >> (sf ? 12 : 0), false); TruncateAndSetIR<2>(s32((s64(m_regs.FC[1]) << 12) - s64(m_regs.MAC2)) >> (sf ? 12 : 0), false); TruncateAndSetIR<3>(s32((s64(m_regs.FC[2]) << 12) - s64(m_regs.MAC3)) >> (sf ? 12 : 0), false); // [MAC1,MAC2,MAC3] = (([IR1,IR2,IR3] * IR0) + [MAC1,MAC2,MAC3]) // [MAC1,MAC2,MAC3] = [MAC1,MAC2,MAC3] SAR (sf*12) ;<--- for NCDx/NCCx TruncateAndSetMAC<1>(s64(s32(m_regs.IR1) * s32(m_regs.IR0)) + s64(m_regs.MAC1), sf); TruncateAndSetMAC<2>(s64(s32(m_regs.IR2) * s32(m_regs.IR0)) + s64(m_regs.MAC2), sf); TruncateAndSetMAC<3>(s64(s32(m_regs.IR3) * s32(m_regs.IR0)) + s64(m_regs.MAC3), sf); // Color FIFO = [MAC1/16,MAC2/16,MAC3/16,CODE], [IR1,IR2,IR3] = [MAC1,MAC2,MAC3] PushRGB(TruncateRGB<0>(m_regs.MAC1 / 16), TruncateRGB<1>(m_regs.MAC2 / 16), TruncateRGB<2>(m_regs.MAC3 / 16), m_regs.RGBC[3]); TruncateAndSetIR<1>(m_regs.MAC1, lm); TruncateAndSetIR<2>(m_regs.MAC2, lm); TruncateAndSetIR<3>(m_regs.MAC3, lm); } void Core::Execute_NCDS(Instruction inst) { m_regs.FLAG.Clear(); NCDS(m_regs.V0, inst.sf, inst.lm); m_regs.FLAG.UpdateError(); } void Core::Execute_MVMVA(Instruction inst) { // TODO: Remove memcpy.. s16 M[3][3]; switch (inst.mvmva_multiply_matrix) { case 0: std::memcpy(M, m_regs.RT, sizeof(s16) * 3 * 3); break; case 1: std::memcpy(M, m_regs.LLM, sizeof(s16) * 3 * 3); break; case 2: std::memcpy(M, m_regs.LCM, sizeof(s16) * 3 * 3); break; default: // buggy Panic("Missing implementation"); return; } s16 Vx, Vy, Vz; switch (inst.mvmva_multiply_vector) { case 0: Vx = m_regs.V0[0]; Vy = m_regs.V0[1]; Vz = m_regs.V0[2]; break; case 1: Vx = m_regs.V1[0]; Vy = m_regs.V1[1]; Vz = m_regs.V1[2]; break; case 2: Vx = m_regs.V2[0]; Vy = m_regs.V2[1]; Vz = m_regs.V2[2]; break; default: Vx = m_regs.IR0; Vy = m_regs.IR1; Vz = m_regs.IR2; break; } s32 T[3]; switch (inst.mvmva_translation_vector) { case 0: std::memcpy(T, m_regs.TR, sizeof(T)); break; case 1: std::memcpy(T, m_regs.BK, sizeof(T)); break; case 2: // buggy std::memcpy(T, m_regs.FC, sizeof(T)); break; case 3: std::fill_n(T, countof(T), s32(0)); break; default: Panic("Missing implementation"); return; } MulMatVec(M, T, Vx, Vy, Vz, inst.sf, inst.lm); } } // namespace GTE