Mesen/Core/HdPackLoader.cpp

678 lines
23 KiB
C++

#include "stdafx.h"
#include <algorithm>
#include <unordered_map>
#include "../Utilities/ZipReader.h"
#include "../Utilities/FolderUtilities.h"
#include "../Utilities/StringUtilities.h"
#include "../Utilities/HexUtilities.h"
#include "../Utilities/PNGHelper.h"
#include "Console.h"
#include "HdPackLoader.h"
#include "HdPackConditions.h"
#include "HdNesPack.h"
#define checkConstraint(x, y) if(!(x)) { MessageManager::Log(y); return; }
HdPackLoader::HdPackLoader()
{
}
bool HdPackLoader::InitializeLoader(VirtualFile &romFile, HdPackData *data)
{
_data = data;
string romName = FolderUtilities::GetFilename(romFile.GetFileName(), false);
string hdPackFolder = FolderUtilities::GetHdPackFolder();
string zipName = romName + ".hdn";
string definitionPath = FolderUtilities::CombinePath(romName, "hires.txt");
string legacyPath = FolderUtilities::CombinePath(hdPackFolder, definitionPath);
if(ifstream(legacyPath)) {
_loadFromZip = false;
_hdPackFolder = FolderUtilities::GetFolderName(legacyPath);
return true;
} else {
vector<string> hdnPackages = FolderUtilities::GetFilesInFolder(romFile.GetFolderPath(), { ".hdn" }, false);
vector<string> more = FolderUtilities::GetFilesInFolder(hdPackFolder, { ".hdn", ".zip" }, false);
hdnPackages.insert(hdnPackages.end(), more.begin(), more.end());
string sha1Hash = romFile.GetSha1Hash();
for(string path : hdnPackages) {
_reader.LoadArchive(path);
vector<uint8_t> hdDefinition;
if(_reader.ExtractFile("hires.txt", hdDefinition)) {
if(FolderUtilities::GetFilename(path, false) == romName) {
_loadFromZip = true;
_hdPackFolder = path;
return true;
} else {
for(string line : StringUtilities::Split(string(hdDefinition.data(), hdDefinition.data() + hdDefinition.size()), '\n')) {
std::transform(line.begin(), line.end(), line.begin(), ::tolower);
if(line.find("<supportedrom>") != string::npos && line.find(sha1Hash) != string::npos) {
_loadFromZip = true;
_hdPackFolder = path;
return true;
}
}
}
}
}
}
return false;
}
bool HdPackLoader::LoadHdNesPack(string definitionFile, HdPackData &outData)
{
HdPackLoader loader;
if(ifstream(definitionFile)) {
loader._data = &outData;
loader._loadFromZip = false;
loader._hdPackFolder = FolderUtilities::GetFolderName(definitionFile);
return loader.LoadPack();
}
return false;
}
bool HdPackLoader::LoadHdNesPack(VirtualFile &romFile, HdPackData &outData)
{
HdPackLoader loader;
if(loader.InitializeLoader(romFile, &outData)) {
return loader.LoadPack();
}
return false;
}
bool HdPackLoader::CheckFile(string filename)
{
if(_loadFromZip) {
return _reader.CheckFile(filename);
} else {
ifstream file(FolderUtilities::CombinePath(_hdPackFolder, filename), ios::in | ios::binary);
if(file.good()) {
return true;
}
}
return false;
}
bool HdPackLoader::LoadFile(string filename, vector<uint8_t> &fileData)
{
fileData.clear();
if(_loadFromZip) {
if(_reader.ExtractFile(filename, fileData)) {
return true;
}
} else {
ifstream file(FolderUtilities::CombinePath(_hdPackFolder, filename), ios::in | ios::binary);
if(file.good()) {
file.seekg(0, ios::end);
uint32_t fileSize = (uint32_t)file.tellg();
file.seekg(0, ios::beg);
fileData = vector<uint8_t>(fileSize, 0);
file.read((char*)fileData.data(), fileSize);
return true;
}
}
return false;
}
bool HdPackLoader::LoadPack()
{
string currentLine;
try {
vector<uint8_t> hdDefinition;
if(!LoadFile("hires.txt", hdDefinition)) {
return false;
}
InitializeGlobalConditions();
for(string lineContent : StringUtilities::Split(string(hdDefinition.data(), hdDefinition.data() + hdDefinition.size()), '\n')) {
if(lineContent.empty()) {
continue;
}
if(lineContent[lineContent.size() - 1] == '\r') {
lineContent = lineContent.substr(0, lineContent.size() - 1);
}
currentLine = lineContent;
vector<HdPackCondition*> conditions;
if(lineContent.substr(0, 1) == "[") {
size_t endOfCondition = lineContent.find_first_of(']', 1);
conditions = ParseConditionString(lineContent.substr(1, endOfCondition - 1), _data->Conditions);
lineContent = lineContent.substr(endOfCondition + 1);
}
vector<string> tokens;
if(lineContent.substr(0, 5) == "<ver>") {
_data->Version = stoi(lineContent.substr(5));
if(_data->Version > HdNesPack::CurrentVersion) {
MessageManager::Log("[HDPack] This HD Pack was built with a more recent version of Mesen - update Mesen to the latest version and try again.");
return false;
}
} else if(lineContent.substr(0, 7) == "<scale>") {
lineContent = lineContent.substr(7);
_data->Scale = std::stoi(lineContent);
} else if(lineContent.substr(0, 10) == "<overscan>") {
tokens = StringUtilities::Split(lineContent.substr(10), ',');
ProcessOverscanTag(tokens);
} else if(lineContent.substr(0, 5) == "<img>") {
lineContent = lineContent.substr(5);
if(!ProcessImgTag(lineContent)) {
return false;
}
} else if(lineContent.substr(0, 7) == "<patch>") {
tokens = StringUtilities::Split(lineContent.substr(7), ',');
ProcessPatchTag(tokens);
} else if(lineContent.substr(0, 12) == "<background>") {
tokens = StringUtilities::Split(lineContent.substr(12), ',');
ProcessBackgroundTag(tokens, conditions);
} else if(lineContent.substr(0, 11) == "<condition>") {
tokens = StringUtilities::Split(lineContent.substr(11), ',');
ProcessConditionTag(tokens, false);
ProcessConditionTag(tokens, true);
} else if(lineContent.substr(0, 6) == "<tile>") {
tokens = StringUtilities::Split(lineContent.substr(6), ',');
ProcessTileTag(tokens, conditions);
} else if(lineContent.substr(0, 9) == "<options>") {
tokens = StringUtilities::Split(lineContent.substr(9), ',');
ProcessOptionTag(tokens);
} else if(lineContent.substr(0, 5) == "<bgm>") {
tokens = StringUtilities::Split(lineContent.substr(5), ',');
ProcessBgmTag(tokens);
} else if(lineContent.substr(0, 5) == "<sfx>") {
tokens = StringUtilities::Split(lineContent.substr(5), ',');
ProcessSfxTag(tokens);
}
}
LoadCustomPalette();
InitializeHdPack();
return true;
} catch(std::exception ex) {
MessageManager::Log(string("[HDPack] Error loading HDPack: ") + ex.what() + " on line: " + currentLine);
return false;
}
}
bool HdPackLoader::ProcessImgTag(string src)
{
HdPackBitmapInfo bitmapInfo;
vector<uint8_t> fileData;
vector<uint8_t> pixelData;
LoadFile(src, fileData);
if(PNGHelper::ReadPNG(fileData, pixelData, bitmapInfo.Width, bitmapInfo.Height)) {
bitmapInfo.PixelData.resize(pixelData.size() / 4);
memcpy(bitmapInfo.PixelData.data(), pixelData.data(), bitmapInfo.PixelData.size() * sizeof(bitmapInfo.PixelData[0]));
_hdNesBitmaps.push_back(bitmapInfo);
return true;
} else {
MessageManager::Log("[HDPack] Error loading HDPack: PNG file " + src + " could not be read.");
return false;
}
}
void HdPackLoader::InitializeGlobalConditions()
{
HdPackCondition* hmirror = new HdPackHorizontalMirroringCondition();
hmirror->Name = "hmirror";
_data->Conditions.push_back(unique_ptr<HdPackCondition>(hmirror));
HdPackCondition* invHmirror = new HdPackHorizontalMirroringCondition();
invHmirror->Name = "!hmirror";
_data->Conditions.push_back(unique_ptr<HdPackCondition>(invHmirror));
HdPackCondition* vmirror = new HdPackVerticalMirroringCondition();
vmirror->Name = "vmirror";
_data->Conditions.push_back(unique_ptr<HdPackCondition>(vmirror));
HdPackCondition* invVmirror = new HdPackVerticalMirroringCondition();
invVmirror->Name = "!vmirror";
_data->Conditions.push_back(unique_ptr<HdPackCondition>(invVmirror));
HdPackCondition* bgpriority = new HdPackBgPriorityCondition();
bgpriority->Name = "bgpriority";
_data->Conditions.push_back(unique_ptr<HdPackCondition>(bgpriority));
HdPackCondition* invBgpriority = new HdPackBgPriorityCondition();
invBgpriority->Name = "!bgpriority";
_data->Conditions.push_back(unique_ptr<HdPackCondition>(invBgpriority));
}
void HdPackLoader::ProcessOverscanTag(vector<string> &tokens)
{
OverscanDimensions overscan;
overscan.Top = std::stoi(tokens[0]);
overscan.Right = std::stoi(tokens[1]);
overscan.Bottom = std::stoi(tokens[2]);
overscan.Left = std::stoi(tokens[3]);
_data->HasOverscanConfig = true;
_data->Overscan = overscan;
}
void HdPackLoader::ProcessPatchTag(vector<string> &tokens)
{
checkConstraint(tokens.size() >= 2, "[HDPack] Patch tag requires more parameters");
checkConstraint(tokens[1].size() == 40, string("[HDPack] Invalid SHA1 hash for patch (" + tokens[0] + "): " + tokens[1]));
vector<uint8_t> fileData;
if(!LoadFile(tokens[0], fileData)) {
MessageManager::Log(string("[HDPack] Patch file not found: " + tokens[1]));
return;
}
std::transform(tokens[1].begin(), tokens[1].end(), tokens[1].begin(), ::toupper);
if(_loadFromZip) {
_data->PatchesByHash[tokens[1]] = VirtualFile(_hdPackFolder, tokens[0]);
} else {
_data->PatchesByHash[tokens[1]] = FolderUtilities::CombinePath(_hdPackFolder, tokens[0]);
}
}
void HdPackLoader::ProcessTileTag(vector<string> &tokens, vector<HdPackCondition*> conditions)
{
HdPackTileInfo *tileInfo = new HdPackTileInfo();
size_t index = 0;
if(_data->Version < 100) {
tileInfo->TileIndex = std::stoi(tokens[index++]);
tileInfo->BitmapIndex = std::stoi(tokens[index++]);
tileInfo->PaletteColors = std::stoi(tokens[index + 2]) | (std::stoi(tokens[index + 1]) << 8) | (std::stoi(tokens[index]) << 16);
index += 3;
} else {
tileInfo->BitmapIndex = std::stoi(tokens[index++]);
string tileData = tokens[index++];
if(tileData.size() >= 32) {
//CHR RAM tile, read the tile data
for(int i = 0; i < 16; i++) {
tileInfo->TileData[i] = HexUtilities::FromHex(tileData.substr(i * 2, 2));
}
tileInfo->IsChrRamTile = true;
tileInfo->TileIndex = -1;
} else {
tileInfo->TileIndex = std::stoi(tileData);
tileInfo->IsChrRamTile = false;
}
tileInfo->PaletteColors = HexUtilities::FromHex(tokens[index++]);
}
tileInfo->X = std::stoi(tokens[index++]);
tileInfo->Y = std::stoi(tokens[index++]);
tileInfo->Conditions = conditions;
tileInfo->ForceDisableCache = false;
for(HdPackCondition* condition : conditions) {
if(dynamic_cast<HdPackSpriteNearbyCondition*>(condition)) {
tileInfo->ForceDisableCache = true;
break;
} else if(dynamic_cast<HdPackTileNearbyCondition*>(condition)) {
HdPackTileNearbyCondition* tileNearby = dynamic_cast<HdPackTileNearbyCondition*>(condition);
if(tileNearby->TileX % 8 > 0 || tileNearby->TileY % 8 > 0) {
tileInfo->ForceDisableCache = true;
break;
}
}
}
if(_data->Version > 0) {
tileInfo->Brightness = (uint8_t)(std::stof(tokens[index++]) * 255);
} else {
tileInfo->Brightness = 255;
}
tileInfo->DefaultTile = (tokens[index++] == "Y");
//For CHR ROM tiles, the ID is just the bank number in chr rom (4k banks)
tileInfo->ChrBankId = tileInfo->TileIndex / 256;
if(_data->Version < 100) {
if(tokens.size() >= 24) {
//CHR RAM tile, read the tile data
for(int i = 0; i < 16; i++) {
tileInfo->TileData[i] = std::stoi(tokens[index++]);
}
tileInfo->IsChrRamTile = true;
} else {
tileInfo->IsChrRamTile = false;
}
} else {
if(tileInfo->IsChrRamTile && tokens.size() > index) {
tileInfo->ChrBankId = std::stoul(tokens[index++]);
}
if(tileInfo->IsChrRamTile && tokens.size() > index) {
tileInfo->TileIndex = std::stoi(tokens[index++]);
}
}
checkConstraint(tileInfo->BitmapIndex < _hdNesBitmaps.size(), "[HDPack] Invalid bitmap index: " + std::to_string(tileInfo->BitmapIndex));
HdPackBitmapInfo &bitmapInfo = _hdNesBitmaps[tileInfo->BitmapIndex];
uint32_t bitmapOffset = tileInfo->Y * bitmapInfo.Width + tileInfo->X;
uint32_t* pngData = (uint32_t*)bitmapInfo.PixelData.data();
tileInfo->HdTileData.resize(64 * _data->Scale * _data->Scale);
for(uint32_t y = 0; y < 8 * _data->Scale; y++) {
memcpy(tileInfo->HdTileData.data() + (y * 8 * _data->Scale), pngData + bitmapOffset, 8 * _data->Scale * sizeof(uint32_t));
bitmapOffset += bitmapInfo.Width;
}
tileInfo->UpdateFlags();
_data->Tiles.push_back(unique_ptr<HdPackTileInfo>(tileInfo));
}
void HdPackLoader::ProcessOptionTag(vector<string> &tokens)
{
for(string token : tokens) {
if(token == "disableSpriteLimit") {
_data->OptionFlags |= (int)HdPackOptions::NoSpriteLimit;
} else if(token == "alternateRegisterRange") {
_data->OptionFlags |= (int)HdPackOptions::AlternateRegisterRange;
} else if(token == "disableContours") {
_data->OptionFlags |= (int)HdPackOptions::NoContours;
} else if(token == "disableCache") {
_data->OptionFlags |= (int)HdPackOptions::DisableCache;
} else {
MessageManager::Log("[HDPack] Invalid option: " + token);
}
}
}
void HdPackLoader::ProcessConditionTag(vector<string> &tokens, bool createInvertedCondition)
{
checkConstraint(tokens.size() >= 4, "[HDPack] Condition tag should contain at least 4 parameters");
checkConstraint(tokens[0].size() > 0, "[HDPack] Condition name may not be empty");
checkConstraint(tokens[0].find_last_of('!') == string::npos, "[HDPack] Condition name may not contain '!' characters");
unique_ptr<HdPackCondition> condition;
if(tokens[1] == "tileAtPosition") {
condition.reset(new HdPackTileAtPositionCondition());
} else if(tokens[1] == "tileNearby") {
condition.reset(new HdPackTileNearbyCondition());
} else if(tokens[1] == "spriteAtPosition") {
condition.reset(new HdPackSpriteAtPositionCondition());
} else if(tokens[1] == "spriteNearby") {
condition.reset(new HdPackSpriteNearbyCondition());
} else if(tokens[1] == "memoryCheck" || tokens[1] == "ppuMemoryCheck") {
condition.reset(new HdPackMemoryCheckCondition());
} else if(tokens[1] == "memoryCheckConstant" || tokens[1] == "ppuMemoryCheckConstant") {
condition.reset(new HdPackMemoryCheckConstantCondition());
} else if(tokens[1] == "frameRange") {
condition.reset(new HdPackFrameRangeCondition());
} else {
MessageManager::Log("[HDPack] Invalid condition type: " + tokens[1]);
return;
}
tokens[0].erase(tokens[0].find_last_not_of(" \n\r\t") + 1);
condition->Name = tokens[0];
if(createInvertedCondition) {
condition->Name = "!" + condition->Name;
}
int index = 2;
if(dynamic_cast<HdPackBaseTileCondition*>(condition.get())) {
checkConstraint(tokens.size() >= 6, "[HDPack] Condition tag should contain at least 6 parameters");
int x = std::stoi(tokens[index++]);
int y = std::stoi(tokens[index++]);
string token = tokens[index++];
int32_t tileIndex = -1;
string tileData;
if(token.size() == 32) {
tileData = token;
} else {
tileIndex = std::stoi(token);
}
uint32_t palette = HexUtilities::FromHex(tokens[index++]);
((HdPackBaseTileCondition*)condition.get())->Initialize(x, y, palette, tileIndex, tileData);
} else if(dynamic_cast<HdPackBaseMemoryCondition*>(condition.get())) {
checkConstraint(_data->Version >= 101, "[HDPack] This feature requires version 101+ of HD Packs");
checkConstraint(tokens.size() >= 5, "[HDPack] Condition tag should contain at least 5 parameters");
bool usePpuMemory = tokens[1].substr(0, 3) == "ppu";
uint32_t operandA = HexUtilities::FromHex(tokens[index++]);
if(usePpuMemory) {
checkConstraint(operandA >= 0 && operandA <= 0x3FFF, "[HDPack] Out of range memoryCheck operand");
operandA |= HdPackBaseMemoryCondition::PpuMemoryMarker;
} else {
checkConstraint(operandA >= 0 && operandA <= 0xFFFF, "[HDPack] Out of range memoryCheck operand");
}
HdPackConditionOperator op;
string opString = tokens[index++];
if(opString == "==") {
op = HdPackConditionOperator::Equal;
} else if(opString == "!=") {
op = HdPackConditionOperator::NotEqual;
} else if(opString == ">") {
op = HdPackConditionOperator::GreaterThan;
} else if(opString == "<") {
op = HdPackConditionOperator::LowerThan;
} else if(opString == "<=") {
op = HdPackConditionOperator::LowerThanOrEqual;
} else if(opString == ">=") {
op = HdPackConditionOperator::GreaterThanOrEqual;
} else {
checkConstraint(false, "[HDPack] Invalid operator.");
}
uint32_t operandB = HexUtilities::FromHex(tokens[index++]);
if(dynamic_cast<HdPackMemoryCheckCondition*>(condition.get())) {
if(usePpuMemory) {
checkConstraint(operandB >= 0 && operandB <= 0x3FFF, "[HDPack] Out of range memoryCheck operand");
operandB |= HdPackBaseMemoryCondition::PpuMemoryMarker;
} else {
checkConstraint(operandB >= 0 && operandB <= 0xFFFF, "[HDPack] Out of range memoryCheck operand");
}
_data->WatchedMemoryAddresses.emplace(operandB);
} else if(dynamic_cast<HdPackMemoryCheckConstantCondition*>(condition.get())) {
checkConstraint(operandB >= 0 && operandB <= 0xFF, "[HDPack] Out of range memoryCheckConstant operand");
}
_data->WatchedMemoryAddresses.emplace(operandA);
((HdPackBaseMemoryCondition*)condition.get())->Initialize(operandA, op, operandB);
} else if(dynamic_cast<HdPackFrameRangeCondition*>(condition.get())) {
checkConstraint(_data->Version >= 101, "[HDPack] This feature requires version 101+ of HD Packs");
checkConstraint(tokens.size() >= 4, "[HDPack] Condition tag should contain at least 4 parameters");
int operandA = HexUtilities::FromHex(tokens[index++]);
checkConstraint(operandA >= 0 && operandA <= 0xFFFF, "[HDPack] Out of range frameRange operand");
int operandB = HexUtilities::FromHex(tokens[index++]);
checkConstraint(operandB >= 0 && operandB <= 0xFFFF, "[HDPack] Out of range frameRange operand");
((HdPackFrameRangeCondition*)condition.get())->Initialize(operandA, operandB);
}
HdPackCondition *cond = condition.get();
condition.release();
_data->Conditions.emplace_back(unique_ptr<HdPackCondition>(cond));
}
void HdPackLoader::ProcessBackgroundTag(vector<string> &tokens, vector<HdPackCondition*> conditions)
{
checkConstraint(tokens.size() >= 2, "[HDPack] Background tag should contain at least 2 parameters");
HdBackgroundFileData* bgFileData = nullptr;
for(unique_ptr<HdBackgroundFileData> &bgData : _data->BackgroundFileData) {
if(bgData->PngName == tokens[0]) {
bgFileData = bgData.get();
}
}
if(!bgFileData) {
vector<uint8_t> pixelData;
uint32_t width, height;
vector<uint8_t> fileContent;
if(LoadFile(tokens[0], fileContent)) {
if(PNGHelper::ReadPNG(fileContent, pixelData, width, height)) {
_data->BackgroundFileData.push_back(unique_ptr<HdBackgroundFileData>(new HdBackgroundFileData()));
bgFileData = _data->BackgroundFileData.back().get();
bgFileData->PixelData.resize(pixelData.size() / 4);
memcpy(bgFileData->PixelData.data(), pixelData.data(), bgFileData->PixelData.size() * sizeof(bgFileData->PixelData[0]));
bgFileData->Width = width;
bgFileData->Height = height;
bgFileData->PngName = tokens[0];
}
}
}
HdBackgroundInfo backgroundInfo;
if(bgFileData) {
backgroundInfo.Data = bgFileData;
backgroundInfo.Brightness = (uint8_t)(std::stof(tokens[1]) * 255);
backgroundInfo.HorizontalScrollRatio = 0;
backgroundInfo.VerticalScrollRatio = 0;
backgroundInfo.BehindBgPrioritySprites = false;
for(HdPackCondition* condition : conditions) {
if(
!dynamic_cast<HdPackTileAtPositionCondition*>(condition) &&
!dynamic_cast<HdPackSpriteAtPositionCondition*>(condition) &&
!dynamic_cast<HdPackMemoryCheckCondition*>(condition) &&
!dynamic_cast<HdPackMemoryCheckConstantCondition*>(condition) &&
!dynamic_cast<HdPackFrameRangeCondition*>(condition)
) {
MessageManager::Log("[HDPack] Invalid condition type for background: " + tokens[0]);
return;
} else {
backgroundInfo.Conditions.push_back(condition);
}
}
if(tokens.size() > 2) {
checkConstraint(_data->Version >= 101, "[HDPack] This feature requires version 101+ of HD Packs");
backgroundInfo.HorizontalScrollRatio = std::stof(tokens[2]);
if(tokens.size() > 3) {
backgroundInfo.VerticalScrollRatio = std::stof(tokens[3]);
}
if(tokens.size() > 4) {
checkConstraint(_data->Version >= 102, "[HDPack] This feature requires version 102+ of HD Packs");
backgroundInfo.BehindBgPrioritySprites = tokens[4] == "Y";
}
}
_data->Backgrounds.push_back(backgroundInfo);
} else {
MessageManager::Log("[HDPack] Error while loading background: " + tokens[0]);
}
}
int HdPackLoader::ProcessSoundTrack(string albumString, string trackString, string filename)
{
int album = std::stoi(albumString);
if(album < 0 || album > 255) {
MessageManager::Log("[HDPack] Invalid album value: " + albumString);
return -1;
}
int track = std::stoi(trackString);
if(track < 0 || track > 255) {
MessageManager::Log("[HDPack] Invalid track value: " + trackString);
return -1;
}
if(!CheckFile(filename)) {
MessageManager::Log("[HDPack] OGG file not found: " + filename);
return -1;
}
return album * 256 + track;
}
void HdPackLoader::ProcessBgmTag(vector<string> &tokens)
{
int trackId = ProcessSoundTrack(tokens[0], tokens[1], tokens[2]);
if(trackId >= 0) {
if(_loadFromZip) {
VirtualFile file(_hdPackFolder, tokens[2]);
_data->BgmFilesById[trackId] = file;
} else {
_data->BgmFilesById[trackId] = FolderUtilities::CombinePath(_hdPackFolder, tokens[2]);
}
}
}
void HdPackLoader::ProcessSfxTag(vector<string> &tokens)
{
int trackId = ProcessSoundTrack(tokens[0], tokens[1], tokens[2]);
if(trackId >= 0) {
if(_loadFromZip) {
VirtualFile file(_hdPackFolder, tokens[2]);
_data->SfxFilesById[trackId] = file;
} else {
_data->SfxFilesById[trackId] = FolderUtilities::CombinePath(_hdPackFolder, tokens[2]);
}
}
}
vector<HdPackCondition*> HdPackLoader::ParseConditionString(string conditionString, vector<unique_ptr<HdPackCondition>> &conditions)
{
vector<string> conditionNames = StringUtilities::Split(conditionString, '&');
vector<HdPackCondition*> result;
for(string conditionName : conditionNames) {
conditionName.erase(conditionName.find_last_not_of(" \n\r\t") + 1);
bool found = false;
for(unique_ptr<HdPackCondition> &condition : conditions) {
if(conditionName == condition->Name) {
result.push_back(condition.get());
found = true;
break;
}
}
if(!found) {
MessageManager::Log("[HDPack] Condition not found: " + conditionName);
}
}
return result;
}
void HdPackLoader::LoadCustomPalette()
{
vector<uint8_t> fileData;
if(LoadFile("palette.dat", fileData)) {
vector<uint32_t> paletteData;
for(size_t i = 0; i < fileData.size(); i+= 3){
paletteData.push_back(0xFF000000 | (fileData[i] << 16) | (fileData[i+1] << 8) | fileData[i+2]);
}
if(paletteData.size() == 0x40) {
_data->Palette = paletteData;
}
}
}
void HdPackLoader::InitializeHdPack()
{
for(unique_ptr<HdPackTileInfo> &tileInfo : _data->Tiles) {
auto tiles = _data->TileByKey.find(tileInfo->GetKey(false));
if(tiles == _data->TileByKey.end()) {
_data->TileByKey[tileInfo->GetKey(false)] = vector<HdPackTileInfo*>();
}
_data->TileByKey[tileInfo->GetKey(false)].push_back(tileInfo.get());
if(tileInfo->DefaultTile) {
auto tiles = _data->TileByKey.find(tileInfo->GetKey(true));
if(tiles == _data->TileByKey.end()) {
_data->TileByKey[tileInfo->GetKey(true)] = vector<HdPackTileInfo*>();
}
_data->TileByKey[tileInfo->GetKey(true)].push_back(tileInfo.get());
}
}
}