ddnet/src/game/editor/auto_map.cpp
def fd67259b77 Silence GCC warning
src/game/editor/auto_map.h:47:9: warning: ‘*((void*)& NewConf +16)’ may be used uninitialized in this function [-Wmaybe-uninitialized]

I don't think it's an actual problem
2020-05-23 18:11:35 +02:00

518 lines
15 KiB
C++

#include <stdio.h> // sscanf
#include <inttypes.h>
#include <engine/console.h>
#include <engine/storage.h>
#include <engine/shared/linereader.h>
#include "auto_map.h"
#include "editor.h"
// Based on triple32inc from https://github.com/skeeto/hash-prospector/tree/79a6074062a84907df6e45b756134b74e2956760
static uint32_t HashUInt32(uint32_t Num)
{
Num++;
Num ^= Num >> 17;
Num *= 0xed5ad4bbu;
Num ^= Num >> 11;
Num *= 0xac4c1b51u;
Num ^= Num >> 15;
Num *= 0x31848babu;
Num ^= Num >> 14;
return Num;
}
#define HASH_MAX 65536
static int HashLocation(uint32_t Seed, uint32_t Run, uint32_t Rule, uint32_t X, uint32_t Y)
{
const uint32_t Prime = 31;
uint32_t Hash = 1;
Hash = Hash * Prime + HashUInt32(Seed);
Hash = Hash * Prime + HashUInt32(Run);
Hash = Hash * Prime + HashUInt32(Rule);
Hash = Hash * Prime + HashUInt32(X);
Hash = Hash * Prime + HashUInt32(Y);
Hash = HashUInt32(Hash * Prime); // Just to double-check that values are well-distributed
return Hash % HASH_MAX;
}
CAutoMapper::CAutoMapper(CEditor *pEditor)
{
m_pEditor = pEditor;
m_FileLoaded = false;
}
void CAutoMapper::Load(const char* pTileName)
{
char aPath[256];
str_format(aPath, sizeof(aPath), "editor/%s.rules", pTileName);
IOHANDLE RulesFile = m_pEditor->Storage()->OpenFile(aPath, IOFLAG_READ, IStorage::TYPE_ALL);
if(!RulesFile)
return;
CLineReader LineReader;
LineReader.Init(RulesFile);
CConfiguration *pCurrentConf = 0;
CRun *pCurrentRun = 0;
CIndexRule *pCurrentIndex = 0;
char aBuf[256];
// read each line
while(char *pLine = LineReader.Get())
{
// skip blank/empty lines as well as comments
if(str_length(pLine) > 0 && pLine[0] != '#' && pLine[0] != '\n' && pLine[0] != '\r'
&& pLine[0] != '\t' && pLine[0] != '\v' && pLine[0] != ' ')
{
if(pLine[0]== '[')
{
// new configuration, get the name
pLine++;
CConfiguration NewConf;
NewConf.m_aName[0] = '\0';
NewConf.m_StartX = 0;
NewConf.m_StartY = 0;
NewConf.m_EndX = 0;
NewConf.m_EndY = 0;
int ConfigurationID = m_lConfigs.add(NewConf);
pCurrentConf = &m_lConfigs[ConfigurationID];
str_copy(pCurrentConf->m_aName, pLine, str_length(pLine));
// add start run
CRun NewRun;
NewRun.m_AutomapCopy = true;
int RunID = pCurrentConf->m_aRuns.add(NewRun);
pCurrentRun = &pCurrentConf->m_aRuns[RunID];
}
else if(str_startswith(pLine, "NewRun"))
{
// add new run
CRun NewRun;
NewRun.m_AutomapCopy = true;
int RunID = pCurrentConf->m_aRuns.add(NewRun);
pCurrentRun = &pCurrentConf->m_aRuns[RunID];
}
else if(str_startswith(pLine, "Index") && pCurrentRun)
{
// new index
int ID = 0;
char aOrientation1[128] = "";
char aOrientation2[128] = "";
char aOrientation3[128] = "";
sscanf(pLine, "Index %d %127s %127s %127s", &ID, aOrientation1, aOrientation2, aOrientation3);
CIndexRule NewIndexRule;
NewIndexRule.m_ID = ID;
NewIndexRule.m_Flag = 0;
NewIndexRule.m_RandomProbability = 1.0f;
NewIndexRule.m_DefaultRule = true;
NewIndexRule.m_SkipEmpty = false;
NewIndexRule.m_SkipFull = false;
if(str_length(aOrientation1) > 0)
{
if(!str_comp(aOrientation1, "XFLIP"))
NewIndexRule.m_Flag |= TILEFLAG_VFLIP;
else if(!str_comp(aOrientation1, "YFLIP"))
NewIndexRule.m_Flag |= TILEFLAG_HFLIP;
else if(!str_comp(aOrientation1, "ROTATE"))
NewIndexRule.m_Flag |= TILEFLAG_ROTATE;
}
if(str_length(aOrientation2) > 0)
{
if(!str_comp(aOrientation2, "XFLIP"))
NewIndexRule.m_Flag |= TILEFLAG_VFLIP;
else if(!str_comp(aOrientation2, "YFLIP"))
NewIndexRule.m_Flag |= TILEFLAG_HFLIP;
else if(!str_comp(aOrientation2, "ROTATE"))
NewIndexRule.m_Flag |= TILEFLAG_ROTATE;
}
if(str_length(aOrientation3) > 0)
{
if(!str_comp(aOrientation3, "XFLIP"))
NewIndexRule.m_Flag |= TILEFLAG_VFLIP;
else if(!str_comp(aOrientation3, "YFLIP"))
NewIndexRule.m_Flag |= TILEFLAG_HFLIP;
else if(!str_comp(aOrientation3, "ROTATE"))
NewIndexRule.m_Flag |= TILEFLAG_ROTATE;
}
// add the index rule object and make it current
int IndexRuleID = pCurrentRun->m_aIndexRules.add(NewIndexRule);
pCurrentIndex = &pCurrentRun->m_aIndexRules[IndexRuleID];
}
else if(str_startswith(pLine, "Pos") && pCurrentIndex)
{
int x = 0, y = 0;
char aValue[128];
int Value = CPosRule::NORULE;
array<CIndexInfo> NewIndexList;
sscanf(pLine, "Pos %d %d %127s", &x, &y, aValue);
if(!str_comp(aValue, "EMPTY"))
{
Value = CPosRule::INDEX;
CIndexInfo NewIndexInfo = {0, 0, false};
NewIndexList.add(NewIndexInfo);
}
else if(!str_comp(aValue, "FULL"))
{
Value = CPosRule::NOTINDEX;
CIndexInfo NewIndexInfo1 = {0, 0, false};
//CIndexInfo NewIndexInfo2 = {-1, 0};
NewIndexList.add(NewIndexInfo1);
//NewIndexList.add(NewIndexInfo2);
}
else if(!str_comp(aValue, "INDEX") || !str_comp(aValue, "NOTINDEX"))
{
if(!str_comp(aValue, "INDEX"))
Value = CPosRule::INDEX;
else
Value = CPosRule::NOTINDEX;
int pWord = 4;
while(true) {
int ID = 0;
char aOrientation1[128] = "";
char aOrientation2[128] = "";
char aOrientation3[128] = "";
char aOrientation4[128] = "";
sscanf(str_trim_words(pLine, pWord), "%d %127s %127s %127s %127s", &ID, aOrientation1, aOrientation2, aOrientation3, aOrientation4);
CIndexInfo NewIndexInfo;
NewIndexInfo.m_ID = ID;
NewIndexInfo.m_Flag = 0;
NewIndexInfo.m_TestFlag = false;
if(!str_comp(aOrientation1, "OR")) {
NewIndexList.add(NewIndexInfo);
pWord += 2;
continue;
} else if(str_length(aOrientation1) > 0) {
NewIndexInfo.m_TestFlag = true;
if(!str_comp(aOrientation1, "XFLIP"))
NewIndexInfo.m_Flag = TILEFLAG_VFLIP;
else if(!str_comp(aOrientation1, "YFLIP"))
NewIndexInfo.m_Flag = TILEFLAG_HFLIP;
else if(!str_comp(aOrientation1, "ROTATE"))
NewIndexInfo.m_Flag = TILEFLAG_ROTATE;
else if(!str_comp(aOrientation1, "NONE"))
NewIndexInfo.m_Flag = 0;
else
NewIndexInfo.m_TestFlag = false;
} else {
NewIndexList.add(NewIndexInfo);
break;
}
if(!str_comp(aOrientation2, "OR")) {
NewIndexList.add(NewIndexInfo);
pWord += 3;
continue;
} else if(str_length(aOrientation2) > 0 && NewIndexInfo.m_Flag != 0) {
if(!str_comp(aOrientation2, "XFLIP"))
NewIndexInfo.m_Flag |= TILEFLAG_VFLIP;
else if(!str_comp(aOrientation2, "YFLIP"))
NewIndexInfo.m_Flag |= TILEFLAG_HFLIP;
else if(!str_comp(aOrientation2, "ROTATE"))
NewIndexInfo.m_Flag |= TILEFLAG_ROTATE;
} else {
NewIndexList.add(NewIndexInfo);
break;
}
if(!str_comp(aOrientation3, "OR")) {
NewIndexList.add(NewIndexInfo);
pWord += 4;
continue;
} else if(str_length(aOrientation3) > 0 && NewIndexInfo.m_Flag != 0) {
if(!str_comp(aOrientation3, "XFLIP"))
NewIndexInfo.m_Flag |= TILEFLAG_VFLIP;
else if(!str_comp(aOrientation3, "YFLIP"))
NewIndexInfo.m_Flag |= TILEFLAG_HFLIP;
else if(!str_comp(aOrientation3, "ROTATE"))
NewIndexInfo.m_Flag |= TILEFLAG_ROTATE;
} else {
NewIndexList.add(NewIndexInfo);
break;
}
if(!str_comp(aOrientation4, "OR")) {
NewIndexList.add(NewIndexInfo);
pWord += 5;
continue;
} else {
NewIndexList.add(NewIndexInfo);
break;
}
}
}
if(Value != CPosRule::NORULE) {
CPosRule NewPosRule = {x, y, Value, NewIndexList};
pCurrentIndex->m_aRules.add(NewPosRule);
pCurrentConf->m_StartX = minimum(pCurrentConf->m_StartX, NewPosRule.m_X);
pCurrentConf->m_StartY = minimum(pCurrentConf->m_StartY, NewPosRule.m_Y);
pCurrentConf->m_EndX = maximum(pCurrentConf->m_EndX, NewPosRule.m_X);
pCurrentConf->m_EndY = maximum(pCurrentConf->m_EndY, NewPosRule.m_Y);
if(x == 0 && y == 0) {
for(int i = 0; i < NewIndexList.size(); ++i)
{
if(Value == CPosRule::INDEX && NewIndexList[i].m_ID == 0)
pCurrentIndex->m_SkipFull = true;
else
pCurrentIndex->m_SkipEmpty = true;
}
}
}
}
else if(str_startswith(pLine, "Random") && pCurrentIndex)
{
float Value;
char Specifier = ' ';
sscanf(pLine, "Random %f%c", &Value, &Specifier);
if(Specifier == '%')
{
pCurrentIndex->m_RandomProbability = Value / 100.0f;
}
else
{
pCurrentIndex->m_RandomProbability = 1.0f / Value;
}
}
else if(str_startswith(pLine, "NoDefaultRule") && pCurrentIndex)
{
pCurrentIndex->m_DefaultRule = false;
}
else if(str_startswith(pLine, "NoLayerCopy") && pCurrentRun)
{
pCurrentRun->m_AutomapCopy = false;
}
}
}
// add default rule for Pos 0 0 if there is none
for (int g = 0; g < m_lConfigs.size(); ++g)
{
for (int h = 0; h < m_lConfigs[g].m_aRuns.size(); ++h)
{
for(int i = 0; i < m_lConfigs[g].m_aRuns[h].m_aIndexRules.size(); ++i)
{
CIndexRule *pIndexRule = &m_lConfigs[g].m_aRuns[h].m_aIndexRules[i];
bool Found = false;
for(int j = 0; j < pIndexRule->m_aRules.size(); ++j)
{
CPosRule *pRule = &pIndexRule->m_aRules[j];
if(pRule && pRule->m_X == 0 && pRule->m_Y == 0)
{
Found = true;
break;
}
}
if(!Found && pIndexRule->m_DefaultRule)
{
array<CIndexInfo> NewIndexList;
CIndexInfo NewIndexInfo = {0, 0, false};
NewIndexList.add(NewIndexInfo);
CPosRule NewPosRule = {0, 0, CPosRule::NOTINDEX, NewIndexList};
pIndexRule->m_aRules.add(NewPosRule);
pIndexRule->m_SkipEmpty = true;
pIndexRule->m_SkipFull = false;
}
if(pIndexRule->m_SkipEmpty && pIndexRule->m_SkipFull)
{
pIndexRule->m_SkipEmpty = false;
pIndexRule->m_SkipFull = false;
}
}
}
}
io_close(RulesFile);
str_format(aBuf, sizeof(aBuf),"loaded %s", aPath);
m_pEditor->Console()->Print(IConsole::OUTPUT_LEVEL_DEBUG, "editor", aBuf);
m_FileLoaded = true;
}
const char* CAutoMapper::GetConfigName(int Index)
{
if(Index < 0 || Index >= m_lConfigs.size())
return "";
return m_lConfigs[Index].m_aName;
}
void CAutoMapper::ProceedLocalized(CLayerTiles *pLayer, int ConfigID, int Seed, int X, int Y, int Width, int Height)
{
if(!m_FileLoaded || pLayer->m_Readonly || ConfigID < 0 || ConfigID >= m_lConfigs.size())
return;
if(Width < 0)
Width = pLayer->m_Width;
if(Height < 0)
Height = pLayer->m_Height;
CConfiguration *pConf = &m_lConfigs[ConfigID];
int CommitFromX = clamp(X + pConf->m_StartX, 0, pLayer->m_Width);
int CommitFromY = clamp(Y + pConf->m_StartY, 0, pLayer->m_Height);
int CommitToX = clamp(X + Width + pConf->m_EndX, 0, pLayer->m_Width);
int CommitToY = clamp(Y + Height + pConf->m_EndY, 0, pLayer->m_Height);
int UpdateFromX = clamp(X + 3 * pConf->m_StartX, 0, pLayer->m_Width);
int UpdateFromY = clamp(Y + 3 * pConf->m_StartY, 0, pLayer->m_Height);
int UpdateToX = clamp(X + Width + 3 * pConf->m_EndX, 0, pLayer->m_Width);
int UpdateToY = clamp(Y + Height + 3 * pConf->m_EndY, 0, pLayer->m_Height);
CLayerTiles *pUpdateLayer;
if (UpdateFromX != 0 || UpdateFromY != 0 || UpdateToX != pLayer->m_Width || UpdateToY != pLayer->m_Width)
{ // Needs a layer to work on
pUpdateLayer = new CLayerTiles(UpdateToX - UpdateFromX, UpdateToY - UpdateFromY);
for(int y = UpdateFromY; y < UpdateToY; y++) {
for(int x = UpdateFromX; x < UpdateToX; x++)
{
CTile *in = &pLayer->m_pTiles[y*pLayer->m_Width+x];
CTile *out = &pUpdateLayer->m_pTiles[(y-UpdateFromY)*pUpdateLayer->m_Width+x-UpdateFromX];
out->m_Index = in->m_Index;
out->m_Flags = in->m_Flags;
}
}
}
else
{
pUpdateLayer = pLayer;
}
Proceed(pUpdateLayer, ConfigID, Seed, UpdateFromX, UpdateFromY);
for(int y = CommitFromY; y < CommitToY; y++) {
for(int x = CommitFromX; x < CommitToX; x++)
{
CTile *in = &pUpdateLayer->m_pTiles[(y-UpdateFromY)*pUpdateLayer->m_Width+x-UpdateFromX];
CTile *out = &pLayer->m_pTiles[y*pLayer->m_Width+x];
out->m_Index = in->m_Index;
out->m_Flags = in->m_Flags;
}
}
}
void CAutoMapper::Proceed(CLayerTiles *pLayer, int ConfigID, int Seed, int SeedOffsetX, int SeedOffsetY)
{
if(!m_FileLoaded || pLayer->m_Readonly || ConfigID < 0 || ConfigID >= m_lConfigs.size())
return;
if(Seed == 0)
Seed = rand();
CConfiguration *pConf = &m_lConfigs[ConfigID];
// for every run: copy tiles, automap, overwrite tiles
for(int h = 0; h < pConf->m_aRuns.size(); ++h) {
CRun *pRun = &pConf->m_aRuns[h];
// don't make copy if it's requested
CLayerTiles *pReadLayer;
if(pRun->m_AutomapCopy)
{
pReadLayer = new CLayerTiles(pLayer->m_Width, pLayer->m_Height);
for(int y = 0; y < pLayer->m_Height; y++) {
for(int x = 0; x < pLayer->m_Width; x++)
{
CTile *in = &pLayer->m_pTiles[y*pLayer->m_Width+x];
CTile *out = &pReadLayer->m_pTiles[y*pLayer->m_Width+x];
out->m_Index = in->m_Index;
out->m_Flags = in->m_Flags;
}
}
}
else
{
pReadLayer = pLayer;
}
// auto map
for(int y = 0; y < pLayer->m_Height; y++) {
for(int x = 0; x < pLayer->m_Width; x++)
{
CTile *pTile = &(pLayer->m_pTiles[y*pLayer->m_Width+x]);
m_pEditor->m_Map.m_Modified = true;
for(int i = 0; i < pRun->m_aIndexRules.size(); ++i)
{
CIndexRule *pIndexRule = &pRun->m_aIndexRules[i];
if(pIndexRule->m_SkipEmpty && pTile->m_Index == 0) // skip empty tiles
continue;
if(pIndexRule->m_SkipFull && pTile->m_Index != 0) // skip full tiles
continue;
bool RespectRules = true;
for(int j = 0; j < pIndexRule->m_aRules.size() && RespectRules; ++j)
{
CPosRule *pRule = &pIndexRule->m_aRules[j];
int CheckIndex, CheckFlags;
int CheckX = x + pRule->m_X;
int CheckY = y + pRule->m_Y;
if(CheckX >= 0 && CheckX < pLayer->m_Width && CheckY >= 0 && CheckY < pLayer->m_Height) {
int CheckTile = CheckY * pLayer->m_Width + CheckX;
CheckIndex = pReadLayer->m_pTiles[CheckTile].m_Index;
CheckFlags = pReadLayer->m_pTiles[CheckTile].m_Flags & (TILEFLAG_ROTATE | TILEFLAG_VFLIP | TILEFLAG_HFLIP);
} else {
CheckIndex = -1;
CheckFlags = 0;
}
if(pRule->m_Value == CPosRule::INDEX)
{
RespectRules = false;
for(int i = 0; i < pRule->m_aIndexList.size(); ++i) {
if(CheckIndex == pRule->m_aIndexList[i].m_ID && (!pRule->m_aIndexList[i].m_TestFlag || CheckFlags == pRule->m_aIndexList[i].m_Flag))
{
RespectRules = true;
break;
}
}
}
else if(pRule->m_Value == CPosRule::NOTINDEX)
{
for(int i = 0; i < pRule->m_aIndexList.size(); ++i) {
if(CheckIndex == pRule->m_aIndexList[i].m_ID && (!pRule->m_aIndexList[i].m_TestFlag || CheckFlags == pRule->m_aIndexList[i].m_Flag))
{
RespectRules = false;
break;
}
}
}
}
if(RespectRules &&
(pIndexRule->m_RandomProbability >= 1.0f || HashLocation(Seed, h, i, x + SeedOffsetX, y + SeedOffsetY) < HASH_MAX * pIndexRule->m_RandomProbability))
{
pTile->m_Index = pIndexRule->m_ID;
pTile->m_Flags = pIndexRule->m_Flag;
}
}
}
}
// clean-up
if(pRun->m_AutomapCopy)
delete pReadLayer;
}
}