Mesen-SX/Core/TraceLogger.cpp

#include "stdafx.h"
#include <regex>
#include <algorithm>
#include "TraceLogger.h"
#include "DisassemblyInfo.h"
#include "Console.h"
#include "EmuSettings.h"
#include "Debugger.h"
#include "MemoryManager.h"
#include "LabelManager.h"
#include "DebugUtilities.h"
#include "CpuTypes.h"
#include "SpcTypes.h"
#include "NecDspTypes.h"
#include "../Utilities/HexUtilities.h"

string TraceLogger::_executionTrace = "";

TraceLogger::TraceLogger(Debugger* debugger, shared_ptr<Console> console)
{
	_console = console.get();
	_settings = console->GetSettings().get();
	_labelManager = debugger->GetLabelManager().get();
	_memoryDumper = debugger->GetMemoryDumper().get();
	_options = {};
	_currentPos = 0;
	_logCount = 0;
	_logToFile = false;
	_pendingLog = false;

	_stateCache = new DebugState[TraceLogger::ExecutionLogSize];
	_stateCacheCopy = new DebugState[TraceLogger::ExecutionLogSize];
	_disassemblyCache = new DisassemblyInfo[TraceLogger::ExecutionLogSize];
	_disassemblyCacheCopy = new DisassemblyInfo[TraceLogger::ExecutionLogSize];
	_logCpuType = new CpuType[TraceLogger::ExecutionLogSize];
	_logCpuTypeCopy = new CpuType[TraceLogger::ExecutionLogSize];
}

TraceLogger::~TraceLogger()
{
	StopLogging();

	delete[] _stateCache;
	delete[] _stateCacheCopy;
	delete[] _disassemblyCache;
	delete[] _disassemblyCacheCopy;
	delete[] _logCpuType;
	delete[] _logCpuTypeCopy;
}

template <typename T>
void TraceLogger::WriteValue(string& output, T value, RowPart& rowPart)
{
	string str = rowPart.DisplayInHex ? HexUtilities::ToHex(value) : std::to_string(value);
	output += str;
	if (rowPart.MinWidth > (int)str.size())
	{
		output += std::string(rowPart.MinWidth - str.size(), ' ');
	}
}

template <>
void TraceLogger::WriteValue(string& output, string value, RowPart& rowPart)
{
	output += value;
	if (rowPart.MinWidth > (int)value.size())
	{
		output += std::string(rowPart.MinWidth - value.size(), ' ');
	}
}

void TraceLogger::SetOptions(TraceLoggerOptions options)
{
	_options = options;

	_logCpu[(int)CpuType::Cpu] = options.LogCpu;
	_logCpu[(int)CpuType::Spc] = options.LogSpc;
	_logCpu[(int)CpuType::NecDsp] = options.LogNecDsp;
	_logCpu[(int)CpuType::Sa1] = options.LogSa1;
	_logCpu[(int)CpuType::Gsu] = options.LogGsu;
	_logCpu[(int)CpuType::Cx4] = options.LogCx4;
	_logCpu[(int)CpuType::Gameboy] = options.LogGameboy;

	string condition = _options.Condition;
	string format = _options.Format;

	auto lock = _lock.AcquireSafe();
	/*_conditionData = ExpressionData();
	if(!condition.empty()) {
		bool success = false;
		ExpressionData rpnList = _expEvaluator->GetRpnList(condition, success);
		if(success) {
			_conditionData = rpnList;
		}
	}*/

	ParseFormatString(_rowParts, format);
	ParseFormatString(_spcRowParts,
	                  "[PC,4h]   [ByteCode,11h] [Disassembly][EffectiveAddress] [MemoryValue,h][Align,48] A:[A,2h] X:[X,2h] Y:[Y,2h] S:[SP,2h] P:[P,8] H:[Cycle,3] V:[Scanline,3]");
	ParseFormatString(_dspRowParts,
	                  "[PC,4h]   [ByteCode,11h] [Disassembly] [Align,65] [A,2h] S:[SP,2h] H:[Cycle,3] V:[Scanline,3]");
	ParseFormatString(_gsuRowParts,
	                  "[PC,6h]   [ByteCode,11h] [Disassembly] [Align,50] SRC:[X,2] DST:[Y,2] R0:[A,2h] H:[Cycle,3] V:[Scanline,3]");
	ParseFormatString(_cx4RowParts,
	                  "[PC,6h]   [ByteCode,11h] [Disassembly] [Align,45] [A,2h] H:[Cycle,3] V:[Scanline,3]");
	ParseFormatString(_gbRowParts,
	                  "[PC,6h]   [ByteCode,11h] [Disassembly] [Align,45] A:[A,2h] B:[B,2h] C:[C,2h] D:[D,2h] E:[E,2h] HL:[H,2h][L,2h] F:[F,2h] SP:[SP,4h] CYC:[Cycle,3] LY:[Scanline,3]");
}

void TraceLogger::ParseFormatString(vector<RowPart>& rowParts, string format)
{
	rowParts.clear();

	std::regex formatRegex = std::regex("(\\[\\s*([^[]*?)\\s*(,\\s*([\\d]*)\\s*(h){0,1}){0,1}\\s*\\])|([^[]*)",
	                                    std::regex_constants::icase);
	std::sregex_iterator start = std::sregex_iterator(format.cbegin(), format.cend(), formatRegex);
	std::sregex_iterator end = std::sregex_iterator();

	for (std::sregex_iterator it = start; it != end; it++)
	{
		const std::smatch& match = *it;

		if (match.str(1) == "")
		{
			RowPart part = {};
			part.DataType = RowDataType::Text;
			part.Text = match.str(6);
			rowParts.push_back(part);
		}
		else
		{
			RowPart part = {};

			string dataType = match.str(2);
			if (dataType == "ByteCode")
			{
				part.DataType = RowDataType::ByteCode;
			}
			else if (dataType == "Disassembly")
			{
				part.DataType = RowDataType::Disassembly;
			}
			else if (dataType == "EffectiveAddress")
			{
				part.DataType = RowDataType::EffectiveAddress;
			}
			else if (dataType == "MemoryValue")
			{
				part.DataType = RowDataType::MemoryValue;
			}
			else if (dataType == "Align")
			{
				part.DataType = RowDataType::Align;
			}
			else if (dataType == "PC")
			{
				part.DataType = RowDataType::PC;
			}
			else if (dataType == "A")
			{
				part.DataType = RowDataType::A;
			}
			else if (dataType == "B")
			{
				part.DataType = RowDataType::B;
			}
			else if (dataType == "C")
			{
				part.DataType = RowDataType::C;
			}
			else if (dataType == "D")
			{
				part.DataType = RowDataType::D;
			}
			else if (dataType == "E")
			{
				part.DataType = RowDataType::E;
			}
			else if (dataType == "F")
			{
				part.DataType = RowDataType::F;
			}
			else if (dataType == "H")
			{
				part.DataType = RowDataType::H;
			}
			else if (dataType == "L")
			{
				part.DataType = RowDataType::L;
			}
			else if (dataType == "X")
			{
				part.DataType = RowDataType::X;
			}
			else if (dataType == "Y")
			{
				part.DataType = RowDataType::Y;
			}
			else if (dataType == "D")
			{
				part.DataType = RowDataType::D;
			}
			else if (dataType == "DB")
			{
				part.DataType = RowDataType::DB;
			}
			else if (dataType == "P")
			{
				part.DataType = RowDataType::PS;
			}
			else if (dataType == "SP")
			{
				part.DataType = RowDataType::SP;
			}
			else if (dataType == "Cycle")
			{
				part.DataType = RowDataType::Cycle;
			}
			else if (dataType == "HClock")
			{
				part.DataType = RowDataType::HClock;
			}
			else if (dataType == "Scanline")
			{
				part.DataType = RowDataType::Scanline;
			}
			else if (dataType == "FrameCount")
			{
				part.DataType = RowDataType::FrameCount;
			}
			else if (dataType == "CycleCount")
			{
				part.DataType = RowDataType::CycleCount;
			}
			else
			{
				part.DataType = RowDataType::Text;
				part.Text = "[Invalid tag]";
			}

			if (!match.str(4).empty())
			{
				try
				{
					part.MinWidth = std::stoi(match.str(4));
				}
				catch (std::exception&)
				{
				}
			}
			part.DisplayInHex = match.str(5) == "h";

			rowParts.push_back(part);
		}
	}
}

void TraceLogger::StartLogging(string filename)
{
	_outputBuffer.clear();
	_outputFile.open(filename, ios::out | ios::binary);
	_logToFile = true;
}

void TraceLogger::StopLogging()
{
	if (_logToFile)
	{
		_logToFile = false;
		if (_outputFile)
		{
			if (!_outputBuffer.empty())
			{
				_outputFile << _outputBuffer;
			}
			_outputFile.close();
		}
	}
}

void TraceLogger::LogExtraInfo(const char* log, uint32_t cycleCount)
{
	if (_logToFile && _options.ShowExtraInfo)
	{
		//Flush current buffer
		_outputFile << _outputBuffer;
		_outputBuffer.clear();
		_outputFile << "[" << log << " - Cycle: " << std::to_string(cycleCount) << "]" << (
			_options.UseWindowsEol ? "\r\n" : "\n");
	}
}

template <CpuType cpuType>
void TraceLogger::GetStatusFlag(string& output, uint8_t ps, RowPart& part)
{
	constexpr char cpuActiveStatusLetters[8] = {'N', 'V', 'M', 'X', 'D', 'I', 'Z', 'C'};
	constexpr char cpuInactiveStatusLetters[8] = {'n', 'v', 'm', 'x', 'd', 'i', 'z', 'c'};

	constexpr char spcActiveStatusLetters[8] = {'N', 'V', 'P', 'B', 'H', 'I', 'Z', 'C'};
	constexpr char spcInactiveStatusLetters[8] = {'n', 'v', 'p', 'b', 'h', 'i', 'z', 'c'};

	const char* activeStatusLetters = cpuType == CpuType::Cpu ? cpuActiveStatusLetters : spcActiveStatusLetters;
	const char* inactiveStatusLetters = cpuType == CpuType::Cpu ? cpuInactiveStatusLetters : spcInactiveStatusLetters;

	if (part.DisplayInHex)
	{
		WriteValue(output, ps, part);
	}
	else
	{
		string flags;
		for (int i = 0; i < 8; i++)
		{
			if (ps & 0x80)
			{
				flags += activeStatusLetters[i];
			}
			else if (part.MinWidth >= 8)
			{
				flags += inactiveStatusLetters[i];
			}
			ps <<= 1;
		}
		WriteValue(output, flags, part);
	}
}

void TraceLogger::WriteByteCode(DisassemblyInfo& info, RowPart& rowPart, string& output)
{
	string byteCode;
	info.GetByteCode(byteCode);
	if (!rowPart.DisplayInHex)
	{
		//Remove $ marks if not in "hex" mode (but still display the bytes as hex)
		byteCode.erase(std::remove(byteCode.begin(), byteCode.end(), '$'), byteCode.end());
	}
	WriteValue(output, byteCode, rowPart);
}

void TraceLogger::WriteDisassembly(DisassemblyInfo& info, RowPart& rowPart, uint8_t sp, uint32_t pc, string& output)
{
	int indentLevel = 0;
	string code;

	if (_options.IndentCode)
	{
		indentLevel = 0xFF - (sp & 0xFF);
		code = std::string(indentLevel, ' ');
	}

	LabelManager* labelManager = _options.UseLabels ? _labelManager : nullptr;
	info.GetDisassembly(code, pc, labelManager, _settings);
	WriteValue(output, code, rowPart);
}

void TraceLogger::WriteEffectiveAddress(DisassemblyInfo& info, RowPart& rowPart, void* cpuState, string& output,
                                        SnesMemoryType cpuMemoryType, CpuType cpuType)
{
	int32_t effectiveAddress = info.GetEffectiveAddress(_console, cpuState, cpuType);
	if (effectiveAddress >= 0)
	{
		if (_options.UseLabels)
		{
			AddressInfo addr{effectiveAddress, cpuMemoryType};
			string label = _labelManager->GetLabel(addr);
			if (!label.empty())
			{
				WriteValue(output, " [" + label + "]", rowPart);
				return;
			}
		}
		WriteValue(output, " [" + HexUtilities::ToHex24(effectiveAddress) + "]", rowPart);
	}
}

void TraceLogger::WriteMemoryValue(DisassemblyInfo& info, RowPart& rowPart, void* cpuState, string& output,
                                   SnesMemoryType memType, CpuType cpuType)
{
	int32_t address = info.GetEffectiveAddress(_console, cpuState, cpuType);
	if (address >= 0)
	{
		uint8_t valueSize;
		uint16_t value = info.GetMemoryValue(address, _memoryDumper, memType, valueSize);
		if (rowPart.DisplayInHex)
		{
			output += "= $";
			if (valueSize == 2)
			{
				WriteValue(output, (uint16_t)value, rowPart);
			}
			else
			{
				WriteValue(output, (uint8_t)value, rowPart);
			}
		}
		else
		{
			output += "= ";
		}
	}
}

void TraceLogger::WriteAlign(int originalSize, RowPart& rowPart, string& output)
{
	if ((int)output.size() - originalSize < rowPart.MinWidth)
	{
		output += std::string(rowPart.MinWidth - (output.size() - originalSize), ' ');
	}
}

void TraceLogger::GetTraceRow(string& output, CpuState& cpuState, PpuState& ppuState, DisassemblyInfo& disassemblyInfo,
                              SnesMemoryType memType, CpuType cpuType)
{
	int originalSize = (int)output.size();
	uint32_t pcAddress = (cpuState.K << 16) | cpuState.PC;
	for (RowPart& rowPart : _rowParts)
	{
		switch (rowPart.DataType)
		{
		case RowDataType::Text: output += rowPart.Text;
			break;
		case RowDataType::ByteCode: WriteByteCode(disassemblyInfo, rowPart, output);
			break;
		case RowDataType::Disassembly:
			WriteDisassembly(disassemblyInfo, rowPart, (uint8_t)cpuState.SP, pcAddress, output);
			break;
		case RowDataType::EffectiveAddress: WriteEffectiveAddress(disassemblyInfo, rowPart, &cpuState, output, memType,
		                                                          cpuType);
			break;
		case RowDataType::MemoryValue: WriteMemoryValue(disassemblyInfo, rowPart, &cpuState, output, memType, cpuType);
			break;
		case RowDataType::Align: WriteAlign(originalSize, rowPart, output);
			break;

		case RowDataType::PC: WriteValue(output, HexUtilities::ToHex24(pcAddress), rowPart);
			break;
		case RowDataType::A: WriteValue(output, cpuState.A, rowPart);
			break;
		case RowDataType::X: WriteValue(output, cpuState.X, rowPart);
			break;
		case RowDataType::Y: WriteValue(output, cpuState.Y, rowPart);
			break;
		case RowDataType::D: WriteValue(output, cpuState.D, rowPart);
			break;
		case RowDataType::DB: WriteValue(output, cpuState.DBR, rowPart);
			break;
		case RowDataType::SP: WriteValue(output, cpuState.SP, rowPart);
			break;
		case RowDataType::PS: GetStatusFlag<CpuType::Cpu>(output, cpuState.PS, rowPart);
			break;
		case RowDataType::Cycle: WriteValue(output, ppuState.Cycle, rowPart);
			break;
		case RowDataType::Scanline: WriteValue(output, ppuState.Scanline, rowPart);
			break;
		case RowDataType::HClock: WriteValue(output, ppuState.HClock, rowPart);
			break;
		case RowDataType::FrameCount: WriteValue(output, ppuState.FrameCount, rowPart);
			break;
		case RowDataType::CycleCount: WriteValue(output, (uint32_t)cpuState.CycleCount, rowPart);
			break;
		default: break;
		}
	}
	output += _options.UseWindowsEol ? "\r\n" : "\n";
}

void TraceLogger::GetTraceRow(string& output, SpcState& cpuState, PpuState& ppuState, DisassemblyInfo& disassemblyInfo)
{
	int originalSize = (int)output.size();
	uint32_t pcAddress = cpuState.PC;
	for (RowPart& rowPart : _spcRowParts)
	{
		switch (rowPart.DataType)
		{
		case RowDataType::Text: output += rowPart.Text;
			break;
		case RowDataType::ByteCode: WriteByteCode(disassemblyInfo, rowPart, output);
			break;
		case RowDataType::Disassembly: WriteDisassembly(disassemblyInfo, rowPart, cpuState.SP, pcAddress, output);
			break;
		case RowDataType::EffectiveAddress: WriteEffectiveAddress(disassemblyInfo, rowPart, &cpuState, output,
		                                                          SnesMemoryType::SpcMemory, CpuType::Spc);
			break;
		case RowDataType::MemoryValue: WriteMemoryValue(disassemblyInfo, rowPart, &cpuState, output,
		                                                SnesMemoryType::SpcMemory, CpuType::Spc);
			break;
		case RowDataType::Align: WriteAlign(originalSize, rowPart, output);
			break;

		case RowDataType::PC: WriteValue(output, HexUtilities::ToHex((uint16_t)pcAddress), rowPart);
			break;
		case RowDataType::A: WriteValue(output, cpuState.A, rowPart);
			break;
		case RowDataType::X: WriteValue(output, cpuState.X, rowPart);
			break;
		case RowDataType::Y: WriteValue(output, cpuState.Y, rowPart);
			break;
		case RowDataType::SP: WriteValue(output, cpuState.SP, rowPart);
			break;
		case RowDataType::PS: GetStatusFlag<CpuType::Spc>(output, cpuState.PS, rowPart);
			break;
		case RowDataType::Cycle: WriteValue(output, ppuState.Cycle, rowPart);
			break;
		case RowDataType::Scanline: WriteValue(output, ppuState.Scanline, rowPart);
			break;
		case RowDataType::HClock: WriteValue(output, ppuState.HClock, rowPart);
			break;
		case RowDataType::FrameCount: WriteValue(output, ppuState.FrameCount, rowPart);
			break;

		default: break;
		}
	}
	output += _options.UseWindowsEol ? "\r\n" : "\n";
}

void TraceLogger::GetTraceRow(string& output, NecDspState& cpuState, PpuState& ppuState,
                              DisassemblyInfo& disassemblyInfo)
{
	int originalSize = (int)output.size();
	uint32_t pcAddress = cpuState.PC;
	for (RowPart& rowPart : _dspRowParts)
	{
		switch (rowPart.DataType)
		{
		case RowDataType::Text: output += rowPart.Text;
			break;
		case RowDataType::ByteCode: WriteByteCode(disassemblyInfo, rowPart, output);
			break;
		case RowDataType::Disassembly: WriteDisassembly(disassemblyInfo, rowPart, cpuState.SP, pcAddress, output);
			break;
		case RowDataType::Align: WriteAlign(originalSize, rowPart, output);
			break;

		case RowDataType::PC: WriteValue(output, HexUtilities::ToHex((uint16_t)pcAddress), rowPart);
			break;
		case RowDataType::A:
			output += "A:" + HexUtilities::ToHex(cpuState.A);
			output += " B:" + HexUtilities::ToHex(cpuState.B);
			output += " DR:" + HexUtilities::ToHex(cpuState.DR);
			output += " DP:" + HexUtilities::ToHex(cpuState.DP);
			output += " SR:" + HexUtilities::ToHex(cpuState.SR);
			output += " K:" + HexUtilities::ToHex(cpuState.K);
			output += " L:" + HexUtilities::ToHex(cpuState.L);
			output += " M:" + HexUtilities::ToHex(cpuState.M);
			output += " N:" + HexUtilities::ToHex(cpuState.N);
			output += " RP:" + HexUtilities::ToHex(cpuState.RP);
			output += " TR:" + HexUtilities::ToHex(cpuState.TR);
			output += " TRB:" + HexUtilities::ToHex(cpuState.TRB) + " ";
			//output += "FA=" + HexUtilities::ToHex(cpuState.FlagsA);
			//output += "FB=" + HexUtilities::ToHex(cpuState.FlagsB);
			WriteValue(output, cpuState.A, rowPart);
			break;
		case RowDataType::SP: WriteValue(output, cpuState.SP, rowPart);
			break;
		case RowDataType::Cycle: WriteValue(output, ppuState.Cycle, rowPart);
			break;
		case RowDataType::Scanline: WriteValue(output, ppuState.Scanline, rowPart);
			break;
		case RowDataType::HClock: WriteValue(output, ppuState.HClock, rowPart);
			break;
		case RowDataType::FrameCount: WriteValue(output, ppuState.FrameCount, rowPart);
			break;
		default: break;
		}
	}
	output += _options.UseWindowsEol ? "\r\n" : "\n";
}

void TraceLogger::GetTraceRow(string& output, GsuState& gsuState, PpuState& ppuState, DisassemblyInfo& disassemblyInfo)
{
	int originalSize = (int)output.size();
	uint32_t pcAddress = (gsuState.ProgramBank << 16) | gsuState.R[15];
	for (RowPart& rowPart : _gsuRowParts)
	{
		switch (rowPart.DataType)
		{
		case RowDataType::Text: output += rowPart.Text;
			break;
		case RowDataType::ByteCode: WriteByteCode(disassemblyInfo, rowPart, output);
			break;
		case RowDataType::Disassembly: WriteDisassembly(disassemblyInfo, rowPart, 0, pcAddress, output);
			break;
		case RowDataType::Align: WriteAlign(originalSize, rowPart, output);
			break;

		case RowDataType::PC: WriteValue(output, HexUtilities::ToHex24(pcAddress), rowPart);
			break;
		case RowDataType::A:
			WriteValue(output, gsuState.R[0], rowPart);
			for (int i = 1; i < 16; i++)
			{
				output += " R" + std::to_string(i) + ":" + HexUtilities::ToHex(gsuState.R[i]);
			}
			break;
		case RowDataType::X: WriteValue(output, gsuState.SrcReg, rowPart);
			break;
		case RowDataType::Y: WriteValue(output, gsuState.DestReg, rowPart);
			break;

		case RowDataType::Cycle: WriteValue(output, ppuState.Cycle, rowPart);
			break;
		case RowDataType::Scanline: WriteValue(output, ppuState.Scanline, rowPart);
			break;
		case RowDataType::HClock: WriteValue(output, ppuState.HClock, rowPart);
			break;
		case RowDataType::FrameCount: WriteValue(output, ppuState.FrameCount, rowPart);
			break;
		default: break;
		}
	}
	output += _options.UseWindowsEol ? "\r\n" : "\n";
}


void TraceLogger::GetTraceRow(string& output, Cx4State& cx4State, PpuState& ppuState, DisassemblyInfo& disassemblyInfo)
{
	int originalSize = (int)output.size();
	uint32_t pcAddress = (cx4State.Cache.Address[cx4State.Cache.Page] + (cx4State.PC * 2)) & 0xFFFFFF;
	for (RowPart& rowPart : _cx4RowParts)
	{
		switch (rowPart.DataType)
		{
		case RowDataType::Text: output += rowPart.Text;
			break;
		case RowDataType::ByteCode: WriteByteCode(disassemblyInfo, rowPart, output);
			break;
		case RowDataType::Disassembly: WriteDisassembly(disassemblyInfo, rowPart, 0, pcAddress, output);
			break;
		case RowDataType::Align: WriteAlign(originalSize, rowPart, output);
			break;

		case RowDataType::PC: WriteValue(output, HexUtilities::ToHex24(pcAddress), rowPart);
			break;
		case RowDataType::A:
			output += " A:" + HexUtilities::ToHex24(cx4State.A);
			output += string(" ") + (cx4State.Carry ? "C" : "c") + (cx4State.Zero ? "Z" : "z") + (
				cx4State.Overflow ? "V" : "v") + (cx4State.Negative ? "N" : "n");

			output += " PC:" + HexUtilities::ToHex(cx4State.PC);
			output += " MAR:" + HexUtilities::ToHex24(cx4State.MemoryAddressReg);
			output += " MDR:" + HexUtilities::ToHex24(cx4State.MemoryDataReg);
			output += " DPR:" + HexUtilities::ToHex24(cx4State.DataPointerReg);
			output += " ML:" + HexUtilities::ToHex24((uint32_t)cx4State.Mult & 0xFFFFFF);
			output += " MH:" + HexUtilities::ToHex24((uint32_t)(cx4State.Mult >> 24) & 0xFFFFFF);
			for (int i = 0; i < 16; i++)
			{
				output += " R" + std::to_string(i) + ":" + HexUtilities::ToHex24(cx4State.Regs[i]);
			}
			break;

		case RowDataType::Cycle: WriteValue(output, ppuState.Cycle, rowPart);
			break;
		case RowDataType::Scanline: WriteValue(output, ppuState.Scanline, rowPart);
			break;
		case RowDataType::HClock: WriteValue(output, ppuState.HClock, rowPart);
			break;
		case RowDataType::FrameCount: WriteValue(output, ppuState.FrameCount, rowPart);
			break;
		default: break;
		}
	}
	output += _options.UseWindowsEol ? "\r\n" : "\n";
}

void TraceLogger::GetTraceRow(string& output, GbCpuState& cpuState, GbPpuState& ppuState,
                              DisassemblyInfo& disassemblyInfo)
{
	int originalSize = (int)output.size();
	uint32_t pcAddress = cpuState.PC;
	for (RowPart& rowPart : _gbRowParts)
	{
		switch (rowPart.DataType)
		{
		case RowDataType::Text: output += rowPart.Text;
			break;
		case RowDataType::ByteCode: WriteByteCode(disassemblyInfo, rowPart, output);
			break;
		case RowDataType::Disassembly:
			WriteDisassembly(disassemblyInfo, rowPart, (uint8_t)cpuState.SP, pcAddress, output);
			break;
		case RowDataType::EffectiveAddress: WriteEffectiveAddress(disassemblyInfo, rowPart, &cpuState, output,
		                                                          SnesMemoryType::GameboyMemory, CpuType::Gameboy);
			break;
		case RowDataType::MemoryValue: WriteMemoryValue(disassemblyInfo, rowPart, &cpuState, output,
		                                                SnesMemoryType::GameboyMemory, CpuType::Gameboy);
			break;
		case RowDataType::Align: WriteAlign(originalSize, rowPart, output);
			break;

		case RowDataType::PC: WriteValue(output, HexUtilities::ToHex((uint16_t)pcAddress), rowPart);
			break;
		case RowDataType::A: WriteValue(output, cpuState.A, rowPart);
			break;
		case RowDataType::B: WriteValue(output, cpuState.B, rowPart);
			break;
		case RowDataType::C: WriteValue(output, cpuState.C, rowPart);
			break;
		case RowDataType::D: WriteValue(output, cpuState.D, rowPart);
			break;
		case RowDataType::E: WriteValue(output, cpuState.E, rowPart);
			break;
		case RowDataType::F: WriteValue(output, cpuState.Flags, rowPart);
			break;
		case RowDataType::H: WriteValue(output, cpuState.H, rowPart);
			break;
		case RowDataType::L: WriteValue(output, cpuState.L, rowPart);
			break;
		case RowDataType::SP: WriteValue(output, cpuState.SP, rowPart);
			break;
		case RowDataType::Cycle: WriteValue(output, ppuState.Cycle, rowPart);
			break;
		case RowDataType::Scanline: WriteValue(output, ppuState.Scanline, rowPart);
			break;
		case RowDataType::FrameCount: WriteValue(output, ppuState.FrameCount, rowPart);
			break;

		default: break;
		}
	}
	output += _options.UseWindowsEol ? "\r\n" : "\n";
}

/*
bool TraceLogger::ConditionMatches(DebugState &state, DisassemblyInfo &disassemblyInfo, OperationInfo &operationInfo)
{
	if(!_conditionData.RpnQueue.empty()) {
		EvalResultType type;
		if(!_expEvaluator->Evaluate(_conditionData, state, type, operationInfo)) {
			if(operationInfo.OperationType == MemoryOperationType::ExecOpCode) {
				//Condition did not match, keep state/disassembly info for instruction's subsequent cycles
				_lastState = state;
				_lastDisassemblyInfo = disassemblyInfo;
				_pendingLog = true;
			}
			return false;
		}
	}
	return true;
}
*/

void TraceLogger::GetTraceRow(string& output, CpuType cpuType, DisassemblyInfo& disassemblyInfo, DebugState& state)
{
	switch (cpuType)
	{
	case CpuType::Cpu: GetTraceRow(output, state.Cpu, state.Ppu, disassemblyInfo, SnesMemoryType::CpuMemory, cpuType);
		break;
	case CpuType::Spc: GetTraceRow(output, state.Spc, state.Ppu, disassemblyInfo);
		break;
	case CpuType::NecDsp: GetTraceRow(output, state.NecDsp, state.Ppu, disassemblyInfo);
		break;
	case CpuType::Sa1: GetTraceRow(output, state.Sa1.Cpu, state.Ppu, disassemblyInfo, SnesMemoryType::Sa1Memory,
	                               cpuType);
		break;
	case CpuType::Gsu: GetTraceRow(output, state.Gsu, state.Ppu, disassemblyInfo);
		break;
	case CpuType::Cx4: GetTraceRow(output, state.Cx4, state.Ppu, disassemblyInfo);
		break;
	case CpuType::Gameboy: GetTraceRow(output, state.Gameboy.Cpu, state.Gameboy.Ppu, disassemblyInfo);
		break;
	}
}

void TraceLogger::AddRow(CpuType cpuType, DisassemblyInfo& disassemblyInfo, DebugState& state)
{
	_logCpuType[_currentPos] = cpuType;
	_disassemblyCache[_currentPos] = disassemblyInfo;
	_stateCache[_currentPos] = state;
	_pendingLog = false;

	if (_logCount < ExecutionLogSize)
	{
		_logCount++;
	}

	if (_logToFile)
	{
		GetTraceRow(_outputBuffer, cpuType, _disassemblyCache[_currentPos], _stateCache[_currentPos]);
		if (_outputBuffer.size() > 32768)
		{
			_outputFile << _outputBuffer;
			_outputBuffer.clear();
		}
	}

	_currentPos = (_currentPos + 1) % ExecutionLogSize;
}

/*
void TraceLogger::LogNonExec(OperationInfo& operationInfo)
{
	if(_pendingLog) {
		auto lock = _lock.AcquireSafe();
		if(ConditionMatches(_lastState, _lastDisassemblyInfo, operationInfo)) {
			AddRow(_lastDisassemblyInfo, _lastState);
		}
	}
}*/

void TraceLogger::Log(CpuType cpuType, DebugState& state, DisassemblyInfo& disassemblyInfo)
{
	if (_logCpu[(int)cpuType])
	{
		//For the sake of performance, only log data for the CPUs we're actively displaying/logging
		auto lock = _lock.AcquireSafe();
		//if(ConditionMatches(state, disassemblyInfo, operationInfo)) {
		AddRow(cpuType, disassemblyInfo, state);
		//}
	}
}

void TraceLogger::Clear()
{
	_logCount = 0;
}

const char* TraceLogger::GetExecutionTrace(uint32_t lineCount)
{
	int startPos;

	_executionTrace.clear();
	{
		auto lock = _lock.AcquireSafe();
		lineCount = std::min(lineCount, _logCount);
		memcpy(_stateCacheCopy, _stateCache, sizeof(DebugState) * TraceLogger::ExecutionLogSize);
		memcpy(_disassemblyCacheCopy, _disassemblyCache, sizeof(DisassemblyInfo) * TraceLogger::ExecutionLogSize);
		memcpy(_logCpuTypeCopy, _logCpuType, sizeof(CpuType) * TraceLogger::ExecutionLogSize);
		startPos = (_currentPos > 0 ? _currentPos : TraceLogger::ExecutionLogSize) - 1;
	}

	bool enabled = false;
	for (int i = 0; i <= (int)DebugUtilities::GetLastCpuType(); i++)
	{
		enabled |= _logCpu[i];
	}

	if (enabled && lineCount > 0)
	{
		for (int i = 0; i < TraceLogger::ExecutionLogSize; i++)
		{
			int index = (startPos - i);
			if (index < 0)
			{
				index = TraceLogger::ExecutionLogSize + index;
			}

			if ((i > 0 && startPos == index) || !_disassemblyCacheCopy[index].IsInitialized())
			{
				//If the entire array was checked, or this element is not initialized, stop
				break;
			}

			CpuType cpuType = _logCpuTypeCopy[index];
			if (!_logCpu[(int)cpuType])
			{
				//This line isn't for a CPU currently being logged
				continue;
			}

			DebugState& state = _stateCacheCopy[index];
			switch (cpuType)
			{
			case CpuType::Cpu: _executionTrace += "\x2\x1" + HexUtilities::ToHex24((state.Cpu.K << 16) | state.Cpu.PC) +
					"\x1";
				break;
			case CpuType::Spc: _executionTrace += "\x3\x1" + HexUtilities::ToHex(state.Spc.PC) + "\x1";
				break;
			case CpuType::NecDsp: _executionTrace += "\x4\x1" + HexUtilities::ToHex(state.NecDsp.PC) + "\x1";
				break;
			case CpuType::Sa1: _executionTrace += "\x4\x1" + HexUtilities::ToHex24(
					(state.Sa1.Cpu.K << 16) | state.Sa1.Cpu.PC) + "\x1";
				break;
			case CpuType::Gsu: _executionTrace += "\x4\x1" + HexUtilities::ToHex24(
					(state.Gsu.ProgramBank << 16) | state.Gsu.R[15]) + "\x1";
				break;
			case CpuType::Cx4: _executionTrace += "\x4\x1" + HexUtilities::ToHex24(
					(state.Cx4.Cache.Address[state.Cx4.Cache.Page] + (state.Cx4.PC * 2)) & 0xFFFFFF) + "\x1";
				break;
			case CpuType::Gameboy: _executionTrace += "\x4\x1" + HexUtilities::ToHex(state.Gameboy.Cpu.PC) + "\x1";
				break;
			}

			string byteCode;
			_disassemblyCacheCopy[index].GetByteCode(byteCode);
			_executionTrace += byteCode + "\x1";
			GetTraceRow(_executionTrace, cpuType, _disassemblyCacheCopy[index], _stateCacheCopy[index]);

			lineCount--;
			if (lineCount == 0)
			{
				break;
			}
		}
	}
	return _executionTrace.c_str();
}