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-rw-r--r--src/Bindings/LuaState.h6
-rw-r--r--src/Bindings/ManualBindings.cpp2
-rw-r--r--src/BiomeDef.cpp62
-rw-r--r--src/BiomeDef.h15
-rw-r--r--src/ChunkMap.cpp1
-rw-r--r--src/ClientHandle.cpp2
-rw-r--r--src/Generating/BioGen.cpp268
-rw-r--r--src/Generating/CMakeLists.txt2
-rw-r--r--src/Generating/ComposableGenerator.cpp4
-rw-r--r--src/Generating/FinishGen.cpp5
-rw-r--r--src/Generating/HeiGen.cpp359
-rw-r--r--src/Generating/IntGen.h1406
-rw-r--r--src/Generating/Noise3DGenerator.cpp469
-rw-r--r--src/Generating/Noise3DGenerator.h134
-rw-r--r--src/Generating/ProtIntGen.h1351
-rw-r--r--src/Root.cpp16
-rw-r--r--src/Root.h3
-rw-r--r--src/World.cpp17
-rw-r--r--src/World.h3
19 files changed, 3951 insertions, 174 deletions
diff --git a/src/Bindings/LuaState.h b/src/Bindings/LuaState.h
index d1e9923b4..c13e36188 100644
--- a/src/Bindings/LuaState.h
+++ b/src/Bindings/LuaState.h
@@ -247,7 +247,11 @@ public:
template <typename FnT, typename... Args>
bool Call(const FnT & a_Function, Args &&... args)
{
- PushFunction(a_Function);
+ if (!PushFunction(a_Function))
+ {
+ // Pushing the function failed
+ return false;
+ }
return PushCallPop(args...);
}
diff --git a/src/Bindings/ManualBindings.cpp b/src/Bindings/ManualBindings.cpp
index a4a5d79b4..3d10e2abb 100644
--- a/src/Bindings/ManualBindings.cpp
+++ b/src/Bindings/ManualBindings.cpp
@@ -3368,6 +3368,7 @@ void ManualBindings::Bind(lua_State * tolua_S)
tolua_beginmodule(tolua_S, "cRoot");
tolua_function(tolua_S, "FindAndDoWithPlayer", tolua_DoWith <cRoot, cPlayer, &cRoot::FindAndDoWithPlayer>);
+ tolua_function(tolua_S, "DoWithPlayerByUUID", tolua_DoWith <cRoot, cPlayer, &cRoot::DoWithPlayerByUUID>);
tolua_function(tolua_S, "ForEachPlayer", tolua_ForEach<cRoot, cPlayer, &cRoot::ForEachPlayer>);
tolua_function(tolua_S, "ForEachWorld", tolua_ForEach<cRoot, cWorld, &cRoot::ForEachWorld>);
tolua_function(tolua_S, "GetFurnaceRecipe", tolua_cRoot_GetFurnaceRecipe);
@@ -3389,6 +3390,7 @@ void ManualBindings::Bind(lua_State * tolua_S)
tolua_function(tolua_S, "DoWithFlowerPotAt", tolua_DoWithXYZ<cWorld, cFlowerPotEntity, &cWorld::DoWithFlowerPotAt>);
tolua_function(tolua_S, "DoWithPlayer", tolua_DoWith< cWorld, cPlayer, &cWorld::DoWithPlayer>);
tolua_function(tolua_S, "FindAndDoWithPlayer", tolua_DoWith< cWorld, cPlayer, &cWorld::FindAndDoWithPlayer>);
+ tolua_function(tolua_S, "DoWithPlayerByUUID", tolua_DoWith< cWorld, cPlayer, &cWorld::DoWithPlayerByUUID>);
tolua_function(tolua_S, "ForEachBlockEntityInChunk", tolua_ForEachInChunk<cWorld, cBlockEntity, &cWorld::ForEachBlockEntityInChunk>);
tolua_function(tolua_S, "ForEachChestInChunk", tolua_ForEachInChunk<cWorld, cChestEntity, &cWorld::ForEachChestInChunk>);
tolua_function(tolua_S, "ForEachEntity", tolua_ForEach< cWorld, cEntity, &cWorld::ForEachEntity>);
diff --git a/src/BiomeDef.cpp b/src/BiomeDef.cpp
index 02f8c2232..188e06173 100644
--- a/src/BiomeDef.cpp
+++ b/src/BiomeDef.cpp
@@ -160,3 +160,65 @@ bool IsBiomeNoDownfall(EMCSBiome a_Biome)
}
}
}
+
+
+
+
+
+bool IsBiomeVeryCold(EMCSBiome a_Biome)
+{
+ switch (a_Biome)
+ {
+ case biFrozenOcean:
+ case biFrozenRiver:
+ case biIcePlains:
+ case biIceMountains:
+ case biColdBeach:
+ case biColdTaiga:
+ case biColdTaigaHills:
+ case biIcePlainsSpikes:
+ case biColdTaigaM:
+ {
+ return true;
+ }
+ default:
+ {
+ return false;
+ }
+ }
+}
+
+
+
+
+bool IsBiomeCold(EMCSBiome a_Biome)
+{
+ switch (a_Biome)
+ {
+ case biExtremeHills:
+ case biTaiga:
+ case biTaigaHills:
+ case biExtremeHillsEdge:
+ case biStoneBeach:
+ case biMegaTaiga:
+ case biMegaTaigaHills:
+ case biExtremeHillsPlus:
+ case biExtremeHillsM:
+ case biTaigaM:
+ case biColdTaigaM:
+ case biMegaSpruceTaiga:
+ case biMegaSpruceTaigaHills:
+ case biExtremeHillsPlusM:
+ {
+ return true;
+ }
+ default:
+ {
+ return false;
+ }
+ }
+}
+
+
+
+
diff --git a/src/BiomeDef.h b/src/BiomeDef.h
index f929596e9..84751cfd7 100644
--- a/src/BiomeDef.h
+++ b/src/BiomeDef.h
@@ -113,5 +113,20 @@ extern AString BiomeToString(int a_Biome);
/** Returns true if the biome has no downfall - deserts and savannas */
extern bool IsBiomeNoDownfall(EMCSBiome a_Biome);
+/** Returns true if the biome is an ocean biome. */
+inline bool IsBiomeOcean(int a_Biome)
+{
+ return ((a_Biome == biOcean) || (a_Biome == biDeepOcean));
+}
+
+/** Returns true if the biome is very cold
+(has snow on ground everywhere, turns top water to ice, has snowfall instead of rain everywhere).
+Doesn't report mildly cold biomes (where it snows above certain elevation), use IsBiomeCold() for those. */
+extern bool IsBiomeVeryCold(EMCSBiome a_Biome);
+
+/** Returns true if the biome is cold
+(has snow and snowfall at higher elevations but not at regular heights).
+Doesn't report Very Cold biomes, use IsBiomeVeryCold() for those. */
+extern bool IsBiomeCold(EMCSBiome a_Biome);
// tolua_end
diff --git a/src/ChunkMap.cpp b/src/ChunkMap.cpp
index 595040a54..8a8f17a1b 100644
--- a/src/ChunkMap.cpp
+++ b/src/ChunkMap.cpp
@@ -822,6 +822,7 @@ void cChunkMap::WakeUpSimulatorsInArea(int a_MinBlockX, int a_MaxBlockX, int a_M
int MinChunkX, MinChunkZ, MaxChunkX, MaxChunkZ;
cChunkDef::BlockToChunk(a_MinBlockX, a_MinBlockZ, MinChunkX, MinChunkZ);
cChunkDef::BlockToChunk(a_MaxBlockX, a_MaxBlockZ, MaxChunkX, MaxChunkZ);
+ cCSLock Lock(m_CSLayers);
for (int z = MinChunkZ; z <= MaxChunkZ; z++)
{
int MinZ = std::max(a_MinBlockZ, z * cChunkDef::Width);
diff --git a/src/ClientHandle.cpp b/src/ClientHandle.cpp
index 9b3bd9545..d7d97c6c4 100644
--- a/src/ClientHandle.cpp
+++ b/src/ClientHandle.cpp
@@ -557,7 +557,7 @@ void cClientHandle::UnloadOutOfRangeChunks(void)
for (cChunkCoordsList::iterator itr = ChunksToRemove.begin(); itr != ChunksToRemove.end(); ++itr)
{
m_Player->GetWorld()->RemoveChunkClient(itr->m_ChunkX, itr->m_ChunkZ, this);
- m_Protocol->SendUnloadChunk(itr->m_ChunkX, itr->m_ChunkZ);
+ SendUnloadChunk(itr->m_ChunkX, itr->m_ChunkZ);
}
}
diff --git a/src/Generating/BioGen.cpp b/src/Generating/BioGen.cpp
index 203faff56..2a4dbe794 100644
--- a/src/Generating/BioGen.cpp
+++ b/src/Generating/BioGen.cpp
@@ -5,6 +5,10 @@
#include "Globals.h"
#include "BioGen.h"
+#include <chrono>
+#include <iostream>
+#include "IntGen.h"
+#include "ProtIntGen.h"
#include "../IniFile.h"
#include "../LinearUpscale.h"
@@ -917,6 +921,214 @@ void cBioGenTwoLevel::InitializeBiomeGen(cIniFile & a_IniFile)
////////////////////////////////////////////////////////////////////////////////
+// cBioGenGrown:
+
+class cBioGenGrown:
+ public cBiomeGen
+{
+public:
+ cBioGenGrown(int a_Seed)
+ {
+ auto FinalRivers =
+ std::make_shared<cIntGenSmooth<8>> (a_Seed + 1,
+ std::make_shared<cIntGenZoom <10>> (a_Seed + 2,
+ std::make_shared<cIntGenRiver <7>> (a_Seed + 3,
+ std::make_shared<cIntGenZoom <9>> (a_Seed + 4,
+ std::make_shared<cIntGenSmooth<6>> (a_Seed + 5,
+ std::make_shared<cIntGenZoom <8>> (a_Seed + 8,
+ std::make_shared<cIntGenSmooth<6>> (a_Seed + 5,
+ std::make_shared<cIntGenZoom <8>> (a_Seed + 9,
+ std::make_shared<cIntGenSmooth<6>> (a_Seed + 5,
+ std::make_shared<cIntGenZoom <8>> (a_Seed + 10,
+ std::make_shared<cIntGenSmooth<6>> (a_Seed + 5,
+ std::make_shared<cIntGenSmooth<8>> (a_Seed + 6,
+ std::make_shared<cIntGenZoom <10>> (a_Seed + 11,
+ std::make_shared<cIntGenChoice<2, 7>>(a_Seed + 12
+ ))))))))))))));
+
+ auto alteration =
+ std::make_shared<cIntGenZoom <8>>(a_Seed,
+ std::make_shared<cIntGenLandOcean<6>>(a_Seed, 20
+ ));
+
+ auto alteration2 =
+ std::make_shared<cIntGenZoom <8>>(a_Seed + 1,
+ std::make_shared<cIntGenZoom <6>>(a_Seed + 2,
+ std::make_shared<cIntGenZoom <5>>(a_Seed + 1,
+ std::make_shared<cIntGenZoom <4>>(a_Seed + 2,
+ std::make_shared<cIntGenLandOcean<4>>(a_Seed + 1, 10
+ )))));
+
+ auto FinalBiomes =
+ std::make_shared<cIntGenSmooth <8>> (a_Seed + 1,
+ std::make_shared<cIntGenZoom <10>>(a_Seed + 15,
+ std::make_shared<cIntGenSmooth <7>> (a_Seed + 1,
+ std::make_shared<cIntGenZoom <9>> (a_Seed + 16,
+ std::make_shared<cIntGenBeaches <6>> (
+ std::make_shared<cIntGenZoom <8>> (a_Seed + 1,
+ std::make_shared<cIntGenAddIslands <6>> (a_Seed + 2004, 10,
+ std::make_shared<cIntGenAddToOcean <6>> (a_Seed + 10, 500, biDeepOcean,
+ std::make_shared<cIntGenReplaceRandomly<8>> (a_Seed + 1, biPlains, biSunflowerPlains, 20,
+ std::make_shared<cIntGenMBiomes <8>> (a_Seed + 5, alteration2,
+ std::make_shared<cIntGenAlternateBiomes<8>> (a_Seed + 1, alteration,
+ std::make_shared<cIntGenBiomeEdges <8>> (a_Seed + 3,
+ std::make_shared<cIntGenZoom <10>>(a_Seed + 2,
+ std::make_shared<cIntGenZoom <7>> (a_Seed + 4,
+ std::make_shared<cIntGenReplaceRandomly<5>> (a_Seed + 99, biIcePlains, biIcePlainsSpikes, 50,
+ std::make_shared<cIntGenZoom <5>> (a_Seed + 8,
+ std::make_shared<cIntGenAddToOcean <4>> (a_Seed + 10, 300, biDeepOcean,
+ std::make_shared<cIntGenAddToOcean <6>> (a_Seed + 9, 8, biMushroomIsland,
+ std::make_shared<cIntGenBiomes <8>> (a_Seed + 3000,
+ std::make_shared<cIntGenAddIslands <8>> (a_Seed + 2000, 200,
+ std::make_shared<cIntGenZoom <8>> (a_Seed + 5,
+ std::make_shared<cIntGenRareBiomeGroups<6>> (a_Seed + 5, 50,
+ std::make_shared<cIntGenBiomeGroupEdges<6>> (
+ std::make_shared<cIntGenAddIslands <8>> (a_Seed + 2000, 200,
+ std::make_shared<cIntGenZoom <8>> (a_Seed + 7,
+ std::make_shared<cIntGenSetRandomly <6>> (a_Seed + 8, 50, bgOcean,
+ std::make_shared<cIntGenReplaceRandomly<6>> (a_Seed + 101, bgIce, bgTemperate, 150,
+ std::make_shared<cIntGenAddIslands <6>> (a_Seed + 2000, 200,
+ std::make_shared<cIntGenSetRandomly <6>> (a_Seed + 9, 50, bgOcean,
+ std::make_shared<cIntGenZoom <6>> (a_Seed + 10,
+ std::make_shared<cIntGenLandOcean <5>> (a_Seed + 100, 30
+ )))))))))))))))))))))))))))))));
+
+ m_Gen =
+ std::make_shared<cIntGenSmooth <16>>(a_Seed,
+ std::make_shared<cIntGenZoom <18>>(a_Seed,
+ std::make_shared<cIntGenSmooth <11>>(a_Seed,
+ std::make_shared<cIntGenZoom <13>>(a_Seed,
+ std::make_shared<cIntGenMixRivers<8>> (
+ FinalBiomes, FinalRivers
+ )))));
+ }
+
+ virtual void GenBiomes(int a_ChunkX, int a_ChunkZ, cChunkDef::BiomeMap & a_Biomes) override
+ {
+ cIntGen<16, 16>::Values vals;
+ m_Gen->GetInts(a_ChunkX * cChunkDef::Width, a_ChunkZ * cChunkDef::Width, vals);
+ for (int z = 0; z < cChunkDef::Width; z++)
+ {
+ for (int x = 0; x < cChunkDef::Width; x++)
+ {
+ cChunkDef::SetBiome(a_Biomes, x, z, (EMCSBiome)vals[x + cChunkDef::Width * z]);
+ }
+ }
+ }
+
+protected:
+ std::shared_ptr<cIntGen<16, 16>> m_Gen;
+};
+
+
+
+
+
+////////////////////////////////////////////////////////////////////////////////
+// cBioGenGrown:
+
+class cBioGenProtGrown:
+ public cBiomeGen
+{
+public:
+ cBioGenProtGrown(int a_Seed)
+ {
+ auto FinalRivers =
+ std::make_shared<cProtIntGenSmooth>(a_Seed + 1,
+ std::make_shared<cProtIntGenZoom >(a_Seed + 2,
+ std::make_shared<cProtIntGenRiver >(a_Seed + 3,
+ std::make_shared<cProtIntGenZoom >(a_Seed + 4,
+ std::make_shared<cProtIntGenSmooth>(a_Seed + 5,
+ std::make_shared<cProtIntGenZoom >(a_Seed + 8,
+ std::make_shared<cProtIntGenSmooth>(a_Seed + 5,
+ std::make_shared<cProtIntGenZoom >(a_Seed + 9,
+ std::make_shared<cProtIntGenSmooth>(a_Seed + 5,
+ std::make_shared<cProtIntGenZoom >(a_Seed + 10,
+ std::make_shared<cProtIntGenSmooth>(a_Seed + 5,
+ std::make_shared<cProtIntGenSmooth>(a_Seed + 6,
+ std::make_shared<cProtIntGenZoom >(a_Seed + 11,
+ std::make_shared<cProtIntGenChoice>(a_Seed + 12, 2
+ ))))))))))))));
+
+ auto alteration =
+ std::make_shared<cProtIntGenZoom >(a_Seed,
+ std::make_shared<cProtIntGenLandOcean>(a_Seed, 20
+ ));
+
+ auto alteration2 =
+ std::make_shared<cProtIntGenZoom >(a_Seed + 1,
+ std::make_shared<cProtIntGenZoom >(a_Seed + 2,
+ std::make_shared<cProtIntGenZoom >(a_Seed + 1,
+ std::make_shared<cProtIntGenZoom >(a_Seed + 2,
+ std::make_shared<cProtIntGenLandOcean>(a_Seed + 1, 10
+ )))));
+
+ auto FinalBiomes =
+ std::make_shared<cProtIntGenSmooth >(a_Seed + 1,
+ std::make_shared<cProtIntGenZoom >(a_Seed + 15,
+ std::make_shared<cProtIntGenSmooth >(a_Seed + 1,
+ std::make_shared<cProtIntGenZoom >(a_Seed + 16,
+ std::make_shared<cProtIntGenBeaches >(
+ std::make_shared<cProtIntGenZoom >(a_Seed + 1,
+ std::make_shared<cProtIntGenAddIslands >(a_Seed + 2004, 10,
+ std::make_shared<cProtIntGenAddToOcean >(a_Seed + 10, 500, biDeepOcean,
+ std::make_shared<cProtIntGenReplaceRandomly>(a_Seed + 1, biPlains, biSunflowerPlains, 20,
+ std::make_shared<cProtIntGenMBiomes >(a_Seed + 5, alteration2,
+ std::make_shared<cProtIntGenAlternateBiomes>(a_Seed + 1, alteration,
+ std::make_shared<cProtIntGenBiomeEdges >(a_Seed + 3,
+ std::make_shared<cProtIntGenZoom >(a_Seed + 2,
+ std::make_shared<cProtIntGenZoom >(a_Seed + 4,
+ std::make_shared<cProtIntGenReplaceRandomly>(a_Seed + 99, biIcePlains, biIcePlainsSpikes, 50,
+ std::make_shared<cProtIntGenZoom >(a_Seed + 8,
+ std::make_shared<cProtIntGenAddToOcean >(a_Seed + 10, 300, biDeepOcean,
+ std::make_shared<cProtIntGenAddToOcean >(a_Seed + 9, 8, biMushroomIsland,
+ std::make_shared<cProtIntGenBiomes >(a_Seed + 3000,
+ std::make_shared<cProtIntGenAddIslands >(a_Seed + 2000, 200,
+ std::make_shared<cProtIntGenZoom >(a_Seed + 5,
+ std::make_shared<cProtIntGenRareBiomeGroups>(a_Seed + 5, 50,
+ std::make_shared<cProtIntGenBiomeGroupEdges>(
+ std::make_shared<cProtIntGenAddIslands >(a_Seed + 2000, 200,
+ std::make_shared<cProtIntGenZoom >(a_Seed + 7,
+ std::make_shared<cProtIntGenSetRandomly >(a_Seed + 8, 50, bgOcean,
+ std::make_shared<cProtIntGenReplaceRandomly>(a_Seed + 101, bgIce, bgTemperate, 150,
+ std::make_shared<cProtIntGenAddIslands >(a_Seed + 2000, 200,
+ std::make_shared<cProtIntGenSetRandomly >(a_Seed + 9, 50, bgOcean,
+ std::make_shared<cProtIntGenZoom >(a_Seed + 10,
+ std::make_shared<cProtIntGenLandOcean >(a_Seed + 100, 30
+ )))))))))))))))))))))))))))))));
+
+ m_Gen =
+ std::make_shared<cProtIntGenSmooth >(a_Seed,
+ std::make_shared<cProtIntGenZoom >(a_Seed,
+ std::make_shared<cProtIntGenSmooth >(a_Seed,
+ std::make_shared<cProtIntGenZoom >(a_Seed,
+ std::make_shared<cProtIntGenMixRivers>(
+ FinalBiomes, FinalRivers
+ )))));
+ }
+
+ virtual void GenBiomes(int a_ChunkX, int a_ChunkZ, cChunkDef::BiomeMap & a_Biomes) override
+ {
+ int vals[16 * 16];
+ m_Gen->GetInts(a_ChunkX * cChunkDef::Width, a_ChunkZ * cChunkDef::Width, 16, 16, vals);
+ for (int z = 0; z < cChunkDef::Width; z++)
+ {
+ for (int x = 0; x < cChunkDef::Width; x++)
+ {
+ cChunkDef::SetBiome(a_Biomes, x, z, (EMCSBiome)vals[x + cChunkDef::Width * z]);
+ }
+ }
+ }
+
+protected:
+ std::shared_ptr<cProtIntGen> m_Gen;
+};
+
+
+
+
+
+////////////////////////////////////////////////////////////////////////////////
// cBiomeGen:
cBiomeGenPtr cBiomeGen::CreateBiomeGen(cIniFile & a_IniFile, int a_Seed, bool & a_CacheOffByDefault)
@@ -952,6 +1164,14 @@ cBiomeGenPtr cBiomeGen::CreateBiomeGen(cIniFile & a_IniFile, int a_Seed, bool &
{
res = new cBioGenTwoLevel(a_Seed);
}
+ else if (NoCaseCompare(BiomeGenName, "grown") == 0)
+ {
+ res = new cBioGenGrown(a_Seed);
+ }
+ else if (NoCaseCompare(BiomeGenName, "grownprot") == 0)
+ {
+ res = new cBioGenProtGrown(a_Seed);
+ }
else
{
if (NoCaseCompare(BiomeGenName, "multistepmap") != 0)
@@ -981,3 +1201,51 @@ cBiomeGenPtr cBiomeGen::CreateBiomeGen(cIniFile & a_IniFile, int a_Seed, bool &
+
+////////////////////////////////////////////////////////////////////////////////
+// Performance tests:
+
+// Change to 1 to enable the perf test:
+#if 0
+
+class cBioGenPerfTest
+{
+public:
+ cBioGenPerfTest()
+ {
+ std::cout << "BioGen performance tests commencing, please wait..." << std::endl;
+ TestGen("MultiStepMap", std::make_unique<cBioGenMultiStepMap>(1).get());
+ TestGen("Grown", std::make_unique<cBioGenGrown>(1).get());
+ TestGen("GrownProt", std::make_unique<cBioGenProtGrown>(1).get());
+ std::cout << "BioGen performance tests complete." << std::endl;
+ }
+
+protected:
+ void TestGen(const AString && a_GenName, cBiomeGen * a_BioGen)
+ {
+ // Initialize the default settings for the generator:
+ cIniFile iniFile;
+ a_BioGen->InitializeBiomeGen(iniFile);
+
+ // Generate the biomes:
+ auto start = std::chrono::system_clock::now();
+ for (int z = 0; z < 100; z++)
+ {
+ for (int x = 0; x < 100; x++)
+ {
+ cChunkDef::BiomeMap biomes;
+ a_BioGen->GenBiomes(x, z, biomes);
+ } // for x
+ } // for z
+ auto dur = std::chrono::system_clock::now() - start;
+ double milliseconds = static_cast<double>((std::chrono::duration_cast<std::chrono::milliseconds>(dur)).count());
+
+ std::cout << a_GenName << ": " << 1000.0 * 100.0 * 100.0 / milliseconds << " chunks per second" << std::endl;
+ }
+} g_BioGenPerfTest;
+
+#endif
+
+
+
+
diff --git a/src/Generating/CMakeLists.txt b/src/Generating/CMakeLists.txt
index cd3d5a9f3..1a26bd0d5 100644
--- a/src/Generating/CMakeLists.txt
+++ b/src/Generating/CMakeLists.txt
@@ -46,6 +46,7 @@ SET (HDRS
FinishGen.h
GridStructGen.h
HeiGen.h
+ IntGen.h
MineShafts.h
NetherFortGen.h
Noise3DGenerator.h
@@ -53,6 +54,7 @@ SET (HDRS
PieceGenerator.h
Prefab.h
PrefabPiecePool.h
+ ProtIntGen.h
RainbowRoadsGen.h
Ravines.h
RoughRavines.h
diff --git a/src/Generating/ComposableGenerator.cpp b/src/Generating/ComposableGenerator.cpp
index 169821050..5f46574c7 100644
--- a/src/Generating/ComposableGenerator.cpp
+++ b/src/Generating/ComposableGenerator.cpp
@@ -73,6 +73,10 @@ cTerrainCompositionGenPtr cTerrainCompositionGen::CreateCompositionGen(cIniFile
{
res = new cCompoGenNether(a_Seed);
}
+ else if (NoCaseCompare(CompoGenName, "BiomalNoise3D") == 0)
+ {
+ res = new cBiomalNoise3DComposable(a_Seed, a_BiomeGen);
+ }
else if (NoCaseCompare(CompoGenName, "Noise3D") == 0)
{
res = new cNoise3DComposable(a_Seed);
diff --git a/src/Generating/FinishGen.cpp b/src/Generating/FinishGen.cpp
index 18f8ee2bc..b8afac09a 100644
--- a/src/Generating/FinishGen.cpp
+++ b/src/Generating/FinishGen.cpp
@@ -199,6 +199,11 @@ void cFinishGenTallGrass::GenFinish(cChunkDesc & a_ChunkDesc)
// Get the top block + 1. This is the place where the grass would finaly be placed:
int y = a_ChunkDesc.GetHeight(x, z) + 1;
+
+ if (y >= 255)
+ {
+ continue;
+ }
// Check if long grass can be placed:
if (
diff --git a/src/Generating/HeiGen.cpp b/src/Generating/HeiGen.cpp
index f4e231470..1d9f1e3aa 100644
--- a/src/Generating/HeiGen.cpp
+++ b/src/Generating/HeiGen.cpp
@@ -17,81 +17,6 @@
////////////////////////////////////////////////////////////////////////////////
-// cTerrainHeightGen:
-
-cTerrainHeightGenPtr cTerrainHeightGen::CreateHeightGen(cIniFile & a_IniFile, cBiomeGenPtr a_BiomeGen, int a_Seed, bool & a_CacheOffByDefault)
-{
- AString HeightGenName = a_IniFile.GetValueSet("Generator", "HeightGen", "");
- if (HeightGenName.empty())
- {
- LOGWARN("[Generator] HeightGen value not set in world.ini, using \"Biomal\".");
- HeightGenName = "Biomal";
- }
-
- a_CacheOffByDefault = false;
- cTerrainHeightGen * res = nullptr;
- if (NoCaseCompare(HeightGenName, "flat") == 0)
- {
- res = new cHeiGenFlat;
- a_CacheOffByDefault = true; // We're generating faster than a cache would retrieve data
- }
- else if (NoCaseCompare(HeightGenName, "classic") == 0)
- {
- res = new cHeiGenClassic(a_Seed);
- }
- else if (NoCaseCompare(HeightGenName, "DistortedHeightmap") == 0)
- {
- res = new cDistortedHeightmap(a_Seed, a_BiomeGen);
- }
- else if (NoCaseCompare(HeightGenName, "End") == 0)
- {
- res = new cEndGen(a_Seed);
- }
- else if (NoCaseCompare(HeightGenName, "Mountains") == 0)
- {
- res = new cHeiGenMountains(a_Seed);
- }
- else if (NoCaseCompare(HeightGenName, "Noise3D") == 0)
- {
- res = new cNoise3DComposable(a_Seed);
- }
- else if (NoCaseCompare(HeightGenName, "biomal") == 0)
- {
- res = new cHeiGenBiomal(a_Seed, a_BiomeGen);
-
- /*
- // Performance-testing:
- LOGINFO("Measuring performance of cHeiGenBiomal...");
- clock_t BeginTick = clock();
- for (int x = 0; x < 500; x++)
- {
- cChunkDef::HeightMap Heights;
- res->GenHeightMap(x * 5, x * 5, Heights);
- }
- clock_t Duration = clock() - BeginTick;
- LOGINFO("HeightGen for 500 chunks took %d ticks (%.02f sec)", Duration, (double)Duration / CLOCKS_PER_SEC);
- //*/
- }
- else
- {
- // No match found, force-set the default and retry
- LOGWARN("Unknown HeightGen \"%s\", using \"Biomal\" instead.", HeightGenName.c_str());
- a_IniFile.DeleteValue("Generator", "HeightGen");
- a_IniFile.SetValue("Generator", "HeightGen", "Biomal");
- return CreateHeightGen(a_IniFile, a_BiomeGen, a_Seed, a_CacheOffByDefault);
- }
-
- // Read the settings:
- res->InitializeHeightGen(a_IniFile);
-
- return cTerrainHeightGenPtr(res);
-}
-
-
-
-
-
-////////////////////////////////////////////////////////////////////////////////
// cHeiGenFlat:
void cHeiGenFlat::GenHeightMap(int a_ChunkX, int a_ChunkZ, cChunkDef::HeightMap & a_HeightMap)
@@ -611,3 +536,287 @@ NOISE_DATATYPE cHeiGenBiomal::GetHeightAt(int a_RelX, int a_RelZ, int a_ChunkX,
+////////////////////////////////////////////////////////////////////////////////
+// cHeiGenMinMax:
+
+class cHeiGenMinMax:
+ public cTerrainHeightGen
+{
+ typedef cTerrainHeightGen super;
+
+ /** Size of the averaging process, in columns (for each direction). Must be less than 16. */
+ static const int AVERAGING_SIZE = 4;
+
+public:
+ cHeiGenMinMax(int a_Seed, cBiomeGenPtr a_BiomeGen):
+ m_Noise(a_Seed),
+ m_BiomeGen(a_BiomeGen),
+ m_TotalWeight(0)
+ {
+ // Initialize the weights:
+ for (int z = 0; z <= AVERAGING_SIZE * 2; z++)
+ {
+ for (int x = 0; x <= AVERAGING_SIZE * 2; x++)
+ {
+ m_Weights[z][x] = 1 + 2 * AVERAGING_SIZE - std::abs(x - AVERAGING_SIZE) - std::abs(z - AVERAGING_SIZE);
+ m_TotalWeight += m_Weights[z][x];
+ }
+ }
+
+ // Initialize the Perlin generator:
+ m_Perlin.AddOctave(0.04f, 0.2f);
+ m_Perlin.AddOctave(0.02f, 0.1f);
+ m_Perlin.AddOctave(0.01f, 0.05f);
+ }
+
+
+ virtual void GenHeightMap(int a_ChunkX, int a_ChunkZ, cChunkDef::HeightMap & a_HeightMap)
+ {
+ // Generate the biomes for the 3*3 neighbors:
+ cChunkDef::BiomeMap neighborBiomes[3][3];
+ for (int z = 0; z < 3; z++) for (int x = 0; x < 3; x++)
+ {
+ m_BiomeGen->GenBiomes(a_ChunkX + x - 1, a_ChunkZ + z - 1, neighborBiomes[z][x]);
+ }
+
+ // Get the min and max heights based on the biomes:
+ double minHeight[cChunkDef::Width * cChunkDef::Width];
+ double maxHeight[cChunkDef::Width * cChunkDef::Width];
+ for (int z = 0; z < cChunkDef::Width; z++)
+ {
+ for (int x = 0; x < cChunkDef::Width; x++)
+ {
+ // For each column, sum the min and max values of the neighborhood around it:
+ double min = 0, max = 0;
+ for (int relz = 0; relz <= AVERAGING_SIZE * 2; relz++)
+ {
+ int bz = z + 16 + relz - AVERAGING_SIZE; // Biome Z coord relative to the neighborBiomes start
+ int cz = bz / 16; // Chunk Z coord relative to the neighborBiomes start
+ bz = bz % 16; // Biome Z coord relative to cz in neighborBiomes
+ for (int relx = 0; relx <= AVERAGING_SIZE * 2; relx++)
+ {
+ int bx = x + 16 + relx - AVERAGING_SIZE; // Biome X coord relative to the neighborBiomes start
+ int cx = bx / 16; // Chunk X coord relative to the neighborBiomes start
+ bx = bx % 16; // Biome X coord relative to cz in neighborBiomes
+
+ // Get the biome's min and max heights:
+ double bmin, bmax;
+ getBiomeMinMax(cChunkDef::GetBiome(neighborBiomes[cz][cx], bx, bz), bmin, bmax);
+
+ // Add them to the total, with the weight depending on their relative position to the column:
+ min += bmin * m_Weights[relz][relx];
+ max += bmax * m_Weights[relz][relx];
+ } // for relx
+ } // for relz
+ minHeight[x + z * cChunkDef::Width] = min / m_TotalWeight;
+ maxHeight[x + z * cChunkDef::Width] = max / m_TotalWeight;
+ } // for x
+ } // for z
+
+ // Generate the base noise:
+ NOISE_DATATYPE noise[cChunkDef::Width * cChunkDef::Width];
+ NOISE_DATATYPE workspace[cChunkDef::Width * cChunkDef::Width];
+ NOISE_DATATYPE startX = static_cast<float>(a_ChunkX * cChunkDef::Width);
+ NOISE_DATATYPE endX = startX + cChunkDef::Width - 1;
+ NOISE_DATATYPE startZ = static_cast<float>(a_ChunkZ * cChunkDef::Width);
+ NOISE_DATATYPE endZ = startZ + cChunkDef::Width - 1;
+ m_Perlin.Generate2D(noise, 16, 16, startX, endX, startZ, endZ, workspace);
+
+ // Make the height by ranging the noise between min and max:
+ for (int z = 0; z < cChunkDef::Width; z++)
+ {
+ for (int x = 0; x < cChunkDef::Width; x++)
+ {
+ double min = minHeight[x + z * cChunkDef::Width];
+ double max = maxHeight[x + z * cChunkDef::Width];
+ double h = (max + min) / 2 + noise[x + z * cChunkDef::Width] * (max - min);
+ cChunkDef::SetHeight(a_HeightMap, x, z, static_cast<HEIGHTTYPE>(h));
+ }
+ }
+ }
+
+
+ virtual void InitializeHeightGen(cIniFile & a_IniFile)
+ {
+ // No settings available
+ }
+
+protected:
+ cNoise m_Noise;
+
+ cPerlinNoise m_Perlin;
+
+ /** The biome generator to query for the underlying biomes. */
+ cBiomeGenPtr m_BiomeGen;
+
+ /** Weights applied to each of the min / max values in the neighborhood of the currently evaluated column. */
+ double m_Weights[AVERAGING_SIZE * 2 + 1][AVERAGING_SIZE * 2 + 1];
+
+ /** Sum of all the m_Weights items. */
+ double m_TotalWeight;
+
+
+ /** Returns the minimum and maximum heights for the given biome. */
+ void getBiomeMinMax(EMCSBiome a_Biome, double & a_Min, double & a_Max)
+ {
+ switch (a_Biome)
+ {
+ case biBeach: a_Min = 61; a_Max = 64; break;
+ case biBirchForest: a_Min = 63; a_Max = 75; break;
+ case biBirchForestHills: a_Min = 63; a_Max = 90; break;
+ case biBirchForestHillsM: a_Min = 63; a_Max = 90; break;
+ case biBirchForestM: a_Min = 63; a_Max = 75; break;
+ case biColdBeach: a_Min = 61; a_Max = 64; break;
+ case biColdTaiga: a_Min = 63; a_Max = 75; break;
+ case biColdTaigaHills: a_Min = 63; a_Max = 90; break;
+ case biColdTaigaM: a_Min = 63; a_Max = 75; break;
+ case biDeepOcean: a_Min = 30; a_Max = 60; break;
+ case biDesert: a_Min = 63; a_Max = 70; break;
+ case biDesertHills: a_Min = 63; a_Max = 85; break;
+ case biDesertM: a_Min = 63; a_Max = 70; break;
+ case biEnd: a_Min = 10; a_Max = 100; break;
+ case biExtremeHills: a_Min = 60; a_Max = 120; break;
+ case biExtremeHillsEdge: a_Min = 63; a_Max = 100; break;
+ case biExtremeHillsM: a_Min = 60; a_Max = 120; break;
+ case biExtremeHillsPlus: a_Min = 60; a_Max = 140; break;
+ case biExtremeHillsPlusM: a_Min = 60; a_Max = 140; break;
+ case biFlowerForest: a_Min = 63; a_Max = 75; break;
+ case biForest: a_Min = 63; a_Max = 75; break;
+ case biForestHills: a_Min = 63; a_Max = 90; break;
+ case biFrozenOcean: a_Min = 45; a_Max = 64; break;
+ case biFrozenRiver: a_Min = 60; a_Max = 62; break;
+ case biIceMountains: a_Min = 63; a_Max = 90; break;
+ case biIcePlains: a_Min = 63; a_Max = 70; break;
+ case biIcePlainsSpikes: a_Min = 60; a_Max = 70; break;
+ case biJungle: a_Min = 60; a_Max = 80; break;
+ case biJungleEdge: a_Min = 62; a_Max = 75; break;
+ case biJungleEdgeM: a_Min = 62; a_Max = 75; break;
+ case biJungleHills: a_Min = 60; a_Max = 90; break;
+ case biJungleM: a_Min = 60; a_Max = 75; break;
+ case biMegaSpruceTaiga: a_Min = 63; a_Max = 75; break;
+ case biMegaSpruceTaigaHills: a_Min = 63; a_Max = 90; break;
+ case biMegaTaiga: a_Min = 63; a_Max = 75; break;
+ case biMegaTaigaHills: a_Min = 63; a_Max = 90; break;
+ case biMesa: a_Min = 63; a_Max = 90; break;
+ case biMesaBryce: a_Min = 60; a_Max = 67; break;
+ case biMesaPlateau: a_Min = 75; a_Max = 85; break;
+ case biMesaPlateauF: a_Min = 80; a_Max = 90; break;
+ case biMesaPlateauFM: a_Min = 80; a_Max = 90; break;
+ case biMesaPlateauM: a_Min = 75; a_Max = 85; break;
+ case biMushroomIsland: a_Min = 63; a_Max = 90; break;
+ case biMushroomShore: a_Min = 60; a_Max = 75; break;
+ case biNether: a_Min = 10; a_Max = 100; break;
+ case biOcean: a_Min = 45; a_Max = 64; break;
+ case biPlains: a_Min = 63; a_Max = 70; break;
+ case biRiver: a_Min = 60; a_Max = 62; break;
+ case biRoofedForest: a_Min = 63; a_Max = 75; break;
+ case biRoofedForestM: a_Min = 63; a_Max = 75; break;
+ case biSavanna: a_Min = 63; a_Max = 75; break;
+ case biSavannaM: a_Min = 63; a_Max = 80; break;
+ case biSavannaPlateau: a_Min = 75; a_Max = 100; break;
+ case biSavannaPlateauM: a_Min = 80; a_Max = 160; break;
+ case biStoneBeach: a_Min = 60; a_Max = 64; break;
+ case biSunflowerPlains: a_Min = 63; a_Max = 70; break;
+ case biSwampland: a_Min = 60; a_Max = 67; break;
+ case biSwamplandM: a_Min = 61; a_Max = 67; break;
+ case biTaiga: a_Min = 63; a_Max = 75; break;
+ case biTaigaHills: a_Min = 63; a_Max = 90; break;
+ case biTaigaM: a_Min = 63; a_Max = 80; break;
+ default:
+ {
+ ASSERT(!"Unknown biome");
+ a_Min = 10;
+ a_Max = 10;
+ break;
+ }
+ }
+ }
+};
+
+
+
+
+
+////////////////////////////////////////////////////////////////////////////////
+// cTerrainHeightGen:
+
+cTerrainHeightGenPtr cTerrainHeightGen::CreateHeightGen(cIniFile & a_IniFile, cBiomeGenPtr a_BiomeGen, int a_Seed, bool & a_CacheOffByDefault)
+{
+ AString HeightGenName = a_IniFile.GetValueSet("Generator", "HeightGen", "");
+ if (HeightGenName.empty())
+ {
+ LOGWARN("[Generator] HeightGen value not set in world.ini, using \"Biomal\".");
+ HeightGenName = "Biomal";
+ }
+
+ a_CacheOffByDefault = false;
+ cTerrainHeightGen * res = nullptr;
+ if (NoCaseCompare(HeightGenName, "flat") == 0)
+ {
+ res = new cHeiGenFlat;
+ a_CacheOffByDefault = true; // We're generating faster than a cache would retrieve data
+ }
+ else if (NoCaseCompare(HeightGenName, "classic") == 0)
+ {
+ res = new cHeiGenClassic(a_Seed);
+ }
+ else if (NoCaseCompare(HeightGenName, "DistortedHeightmap") == 0)
+ {
+ res = new cDistortedHeightmap(a_Seed, a_BiomeGen);
+ }
+ else if (NoCaseCompare(HeightGenName, "End") == 0)
+ {
+ res = new cEndGen(a_Seed);
+ }
+ else if (NoCaseCompare(HeightGenName, "MinMax") == 0)
+ {
+ res = new cHeiGenMinMax(a_Seed, a_BiomeGen);
+ }
+ else if (NoCaseCompare(HeightGenName, "Mountains") == 0)
+ {
+ res = new cHeiGenMountains(a_Seed);
+ }
+ else if (NoCaseCompare(HeightGenName, "BiomalNoise3D") == 0)
+ {
+ res = new cBiomalNoise3DComposable(a_Seed, a_BiomeGen);
+ }
+ else if (NoCaseCompare(HeightGenName, "Noise3D") == 0)
+ {
+ res = new cNoise3DComposable(a_Seed);
+ }
+ else if (NoCaseCompare(HeightGenName, "biomal") == 0)
+ {
+ res = new cHeiGenBiomal(a_Seed, a_BiomeGen);
+
+ /*
+ // Performance-testing:
+ LOGINFO("Measuring performance of cHeiGenBiomal...");
+ clock_t BeginTick = clock();
+ for (int x = 0; x < 500; x++)
+ {
+ cChunkDef::HeightMap Heights;
+ res->GenHeightMap(x * 5, x * 5, Heights);
+ }
+ clock_t Duration = clock() - BeginTick;
+ LOGINFO("HeightGen for 500 chunks took %d ticks (%.02f sec)", Duration, (double)Duration / CLOCKS_PER_SEC);
+ //*/
+ }
+ else
+ {
+ // No match found, force-set the default and retry
+ LOGWARN("Unknown HeightGen \"%s\", using \"Biomal\" instead.", HeightGenName.c_str());
+ a_IniFile.DeleteValue("Generator", "HeightGen");
+ a_IniFile.SetValue("Generator", "HeightGen", "Biomal");
+ return CreateHeightGen(a_IniFile, a_BiomeGen, a_Seed, a_CacheOffByDefault);
+ }
+
+ // Read the settings:
+ res->InitializeHeightGen(a_IniFile);
+
+ return cTerrainHeightGenPtr(res);
+}
+
+
+
+
+
diff --git a/src/Generating/IntGen.h b/src/Generating/IntGen.h
new file mode 100644
index 000000000..b25e378c0
--- /dev/null
+++ b/src/Generating/IntGen.h
@@ -0,0 +1,1406 @@
+
+// IntGen.h
+
+// Declares the cIntGen class and descendants for generating and filtering various 2D arrays of ints
+
+/*
+The integers generated may be interpreted in several ways:
+- land/see designators
+ - 0 = ocean
+ - >0 = land
+- biome group
+ - 0 = ocean
+ - 1 = desert biomes
+ - 2 = temperate biomes
+ - 3 = mountains (hills and forests)
+ - 4 = ice biomes
+- biome group with "bgfRare" flag (for generating rare biomes for the group)
+- biome IDs
+The interpretation depends on the generator used and on the position in the chain.
+
+The generators can be chained together - one produces data that another one consumes.
+Some of such chain connections require changing the data dimensions between the two, which is handled automatically
+by using templates.
+*/
+
+
+
+
+
+#pragma once
+
+#include "../BiomeDef.h"
+
+
+
+
+
+/** Constants representing the biome group designators. */
+const int bgOcean = 0;
+const int bgDesert = 1;
+const int bgTemperate = 2;
+const int bgMountains = 3;
+const int bgIce = 4;
+const int bgLandOceanMax = 4; // Maximum biome group value generated in the landOcean generator
+const int bgfRare = 1024; // Flag added to values to generate rare biomes for the group
+
+
+
+
+
+/** Interface that all the generator classes provide. */
+template <int SizeX, int SizeZ = SizeX>
+class cIntGen
+{
+public:
+ /** Force a virtual destructor in all descendants.
+ Descendants contain virtual functions and are referred to via pointer-to-base, so they need a virtual destructor. */
+ virtual ~cIntGen() {}
+
+ /** Holds the array of values generated by this class (descendant). */
+ typedef int Values[SizeX * SizeZ];
+
+ /** Generates the array of templated size into a_Values, based on given min coords. */
+ virtual void GetInts(int a_MinX, int a_MinZ, Values & a_Values) = 0;
+};
+
+
+
+
+
+/** Provides additional cNoise member and its helper functions. */
+template <int SizeX, int SizeZ = SizeX>
+class cIntGenWithNoise :
+ public cIntGen<SizeX, SizeZ>
+{
+ typedef cIntGen<SizeX, SizeZ> super;
+
+public:
+ cIntGenWithNoise(int a_Seed) :
+ m_Noise(a_Seed)
+ {
+ }
+
+protected:
+ cNoise m_Noise;
+
+ /** Chooses one of a_Val1 or a_Val2, based on m_Noise and the coordinates for querying the noise. */
+ int ChooseRandomOne(int a_RndX, int a_RndZ, int a_Val1, int a_Val2)
+ {
+ int rnd = m_Noise.IntNoise2DInt(a_RndX, a_RndZ) / 7;
+ return ((rnd & 1) == 0) ? a_Val1 : a_Val2;
+ }
+
+ /** Chooses one of a_ValN, based on m_Noise and the coordinates for querying the noise. */
+ int ChooseRandomOne(int a_RndX, int a_RndZ, int a_Val1, int a_Val2, int a_Val3, int a_Val4)
+ {
+ int rnd = m_Noise.IntNoise2DInt(a_RndX, a_RndZ) / 7;
+ switch (rnd % 4)
+ {
+ case 0: return a_Val1;
+ case 1: return a_Val2;
+ case 2: return a_Val3;
+ default: return a_Val4;
+ }
+ }
+};
+
+
+
+
+
+
+/** Generates a 2D array of random integers in the specified range [0 .. Range). */
+template <int Range, int SizeX, int SizeZ = SizeX>
+class cIntGenChoice :
+ public cIntGenWithNoise<SizeX, SizeZ>
+{
+ typedef cIntGenWithNoise<SizeX, SizeZ> super;
+
+public:
+ cIntGenChoice(int a_Seed) :
+ super(a_Seed)
+ {
+ }
+
+
+ virtual void GetInts(int a_MinX, int a_MinZ, typename super::Values & a_Values) override
+ {
+ for (int z = 0; z < SizeZ; z++)
+ {
+ int BaseZ = a_MinZ + z;
+ for (int x = 0; x < SizeX; x++)
+ {
+ a_Values[x + SizeX * z] = (super::m_Noise.IntNoise2DInt(a_MinX + x, BaseZ) / 7) % Range;
+ }
+ } // for z
+ }
+};
+
+
+
+
+
+
+/** Decides between the ocean and landmass biomes.
+Has a threshold (in percent) of how much land, the larger the threshold, the more land.
+Generates 0 for ocean, biome group ID for landmass. */
+template <int SizeX, int SizeZ = SizeX>
+class cIntGenLandOcean :
+ public cIntGenWithNoise<SizeX, SizeZ>
+{
+ typedef cIntGenWithNoise<SizeX, SizeZ> super;
+
+public:
+ cIntGenLandOcean(int a_Seed, int a_Threshold) :
+ super(a_Seed),
+ m_Threshold(a_Threshold)
+ {
+ }
+
+
+ virtual void GetInts(int a_MinX, int a_MinZ, typename super::Values & a_Values) override
+ {
+ for (int z = 0; z < SizeZ; z++)
+ {
+ int BaseZ = a_MinZ + z;
+ for (int x = 0; x < SizeX; x++)
+ {
+ int rnd = (super::m_Noise.IntNoise2DInt(a_MinX + x, BaseZ) / 7);
+ a_Values[x + SizeX * z] = ((rnd % 100) < m_Threshold) ? ((rnd / 101) % bgLandOceanMax + 1) : 0;
+ }
+ }
+
+ // If the centerpoint of the world is within the area, set it to bgTemperate, always:
+ if ((a_MinX <= 0) && (a_MinZ <= 0) && (a_MinX + SizeX > 0) && (a_MinZ + SizeZ > 0))
+ {
+ a_Values[-a_MinX - a_MinZ * SizeX] = bgTemperate;
+ }
+ }
+
+protected:
+ int m_Threshold;
+};
+
+
+
+
+
+/** Zooms the underlying value array to twice the size. Uses random-neighbor for the pixels in-between.
+This means that the zoome out image is randomly distorted. Applying zoom several times provides all
+the distortion that the generators need. */
+template <int SizeX, int SizeZ = SizeX>
+class cIntGenZoom :
+ public cIntGenWithNoise<SizeX, SizeZ>
+{
+ typedef cIntGenWithNoise<SizeX, SizeZ> super;
+
+protected:
+ static const int m_LowerSizeX = (SizeX / 2) + 2;
+ static const int m_LowerSizeZ = (SizeZ / 2) + 2;
+
+public:
+ typedef std::shared_ptr<cIntGen<m_LowerSizeX, m_LowerSizeZ>> Underlying;
+
+
+ cIntGenZoom(int a_Seed, Underlying a_UnderlyingGen) :
+ super(a_Seed),
+ m_UnderlyingGen(a_UnderlyingGen)
+ {
+ }
+
+
+ virtual void GetInts(int a_MinX, int a_MinZ, typename super::Values & a_Values) override
+ {
+ // Generate the underlying data with half the resolution:
+ int lowerMinX = a_MinX >> 1;
+ int lowerMinZ = a_MinZ >> 1;
+ int lowerData[m_LowerSizeX * m_LowerSizeZ];
+ m_UnderlyingGen->GetInts(lowerMinX, lowerMinZ, lowerData);
+ const int lowStepX = (m_LowerSizeX - 1) * 2;
+ const int lowStepZ = (m_LowerSizeZ - 1) * 2;
+ int cache[lowStepX * lowStepZ];
+
+ // Discreet-interpolate the values into twice the size:
+ for (int z = 0; z < m_LowerSizeZ - 1; ++z)
+ {
+ int idx = (z * 2) * lowStepX;
+ int PrevZ0 = lowerData[z * m_LowerSizeX];
+ int PrevZ1 = lowerData[(z + 1) * m_LowerSizeX];
+
+ for (int x = 0; x < m_LowerSizeX - 1; ++x)
+ {
+ int ValX1Z0 = lowerData[x + 1 + z * m_LowerSizeX];
+ int ValX1Z1 = lowerData[x + 1 + (z + 1) * m_LowerSizeX];
+ int RndX = (x + lowerMinX) * 2;
+ int RndZ = (z + lowerMinZ) * 2;
+ cache[idx] = PrevZ0;
+ cache[idx + lowStepX] = super::ChooseRandomOne(RndX, RndZ + 1, PrevZ0, PrevZ1);
+ cache[idx + 1] = super::ChooseRandomOne(RndX, RndZ - 1, PrevZ0, ValX1Z0);
+ cache[idx + 1 + lowStepX] = super::ChooseRandomOne(RndX, RndZ, PrevZ0, ValX1Z0, PrevZ1, ValX1Z1);
+ idx += 2;
+ PrevZ0 = ValX1Z0;
+ PrevZ1 = ValX1Z1;
+ }
+ }
+
+ // Copy from Cache into a_Values; take into account the even/odd offsets in a_Min:
+ for (int z = 0; z < SizeZ; ++z)
+ {
+ memcpy(a_Values + z * SizeX, cache + (z + (a_MinZ & 1)) * lowStepX + (a_MinX & 1), SizeX * sizeof(int));
+ }
+ }
+
+protected:
+ Underlying m_UnderlyingGen;
+};
+
+
+
+
+
+/** Smoothes out some artifacts generated by the zooming - mostly single-pixel values.
+Compares each pixel to its neighbors and if the neighbors are equal, changes the pixel to their value. */
+template <int SizeX, int SizeZ = SizeX>
+class cIntGenSmooth :
+ public cIntGenWithNoise<SizeX, SizeZ>
+{
+ typedef cIntGenWithNoise<SizeX, SizeZ> super;
+ static const int m_LowerSizeX = SizeX + 2;
+ static const int m_LowerSizeZ = SizeZ + 2;
+
+public:
+ typedef std::shared_ptr<cIntGen<m_LowerSizeX, m_LowerSizeZ>> Underlying;
+
+
+ cIntGenSmooth(int a_Seed, Underlying a_Underlying) :
+ super(a_Seed),
+ m_Underlying(a_Underlying)
+ {
+ }
+
+
+ virtual void GetInts(int a_MinX, int a_MinZ, typename super::Values & a_Values) override
+ {
+ // Generate the underlying values:
+ int lowerData[m_LowerSizeX * m_LowerSizeZ];
+ m_Underlying->GetInts(a_MinX - 1, a_MinZ - 1, lowerData);
+
+ // Smooth - for each square check if the surroundings are the same, if so, expand them diagonally.
+ // Also get rid of single-pixel irregularities (A-B-A):
+ for (int z = 0; z < SizeZ; z++)
+ {
+ int NoiseZ = a_MinZ + z;
+ for (int x = 0; x < SizeX; x++)
+ {
+ int val = lowerData[x + 1 + (z + 1) * m_LowerSizeX];
+ int above = lowerData[x + 1 + z * m_LowerSizeX];
+ int below = lowerData[x + 1 + (z + 2) * m_LowerSizeX];
+ int left = lowerData[x + (z + 1) * m_LowerSizeX];
+ int right = lowerData[x + 2 + (z + 1) * m_LowerSizeX];
+
+ if ((left == right) && (above == below))
+ {
+ if (((super::m_Noise.IntNoise2DInt(a_MinX + x, NoiseZ) / 7) % 2) == 0)
+ {
+ val = left;
+ }
+ else
+ {
+ val = above;
+ }
+ }
+ else
+ {
+ if (left == right)
+ {
+ val = left;
+ }
+
+ if (above == below)
+ {
+ val = above;
+ }
+ }
+
+ a_Values[x + z * SizeX] = val;
+ }
+ }
+ }
+
+protected:
+ Underlying m_Underlying;
+};
+
+
+
+
+
+/** Converts land biomes at the edge of an ocean into the respective beach biome. */
+template <int SizeX, int SizeZ = SizeX>
+class cIntGenBeaches :
+ public cIntGen<SizeX, SizeZ>
+{
+ typedef cIntGen<SizeX, SizeZ> super;
+ static const int m_UnderlyingSizeX = SizeX + 2;
+ static const int m_UnderlyingSizeZ = SizeZ + 2;
+
+public:
+ typedef std::shared_ptr<cIntGen<m_UnderlyingSizeX, m_UnderlyingSizeZ>> Underlying;
+
+
+ cIntGenBeaches(Underlying a_Underlying) :
+ m_Underlying(a_Underlying)
+ {
+ }
+
+
+ virtual void GetInts(int a_MinX, int a_MinZ, typename super::Values & a_Values) override
+ {
+ // Map for biome -> its beach:
+ static const int ToBeach[] =
+ {
+ /* biOcean */ biOcean,
+ /* biPlains */ biBeach,
+ /* biDesert */ biBeach,
+ /* biExtremeHills */ biStoneBeach,
+ /* biForest */ biBeach,
+ /* biTaiga */ biColdBeach,
+ /* biSwampland */ biSwampland,
+ /* biRiver */ biRiver,
+ /* biNether */ biNether,
+ /* biEnd */ biEnd,
+ /* biFrozenOcean */ biColdBeach,
+ /* biFrozenRiver */ biColdBeach,
+ /* biIcePlains */ biColdBeach,
+ /* biIceMountains */ biColdBeach,
+ /* biMushroomIsland */ biMushroomShore,
+ /* biMushroomShore */ biMushroomShore,
+ /* biBeach */ biBeach,
+ /* biDesertHills */ biBeach,
+ /* biForestHills */ biBeach,
+ /* biTaigaHills */ biColdBeach,
+ /* biExtremeHillsEdge */ biStoneBeach,
+ /* biJungle */ biBeach,
+ /* biJungleHills */ biBeach,
+ /* biJungleEdge */ biBeach,
+ /* biDeepOcean */ biOcean,
+ /* biStoneBeach */ biStoneBeach,
+ /* biColdBeach */ biColdBeach,
+ /* biBirchForest */ biBeach,
+ /* biBirchForestHills */ biBeach,
+ /* biRoofedForest */ biBeach,
+ /* biColdTaiga */ biColdBeach,
+ /* biColdTaigaHills */ biColdBeach,
+ /* biMegaTaiga */ biStoneBeach,
+ /* biMegaTaigaHills */ biStoneBeach,
+ /* biExtremeHillsPlus */ biStoneBeach,
+ /* biSavanna */ biBeach,
+ /* biSavannaPlateau */ biBeach,
+ /* biMesa */ biMesa,
+ /* biMesaPlateauF */ biMesa,
+ /* biMesaPlateau */ biMesa,
+ };
+
+ // Generate the underlying values:
+ int lowerValues[m_UnderlyingSizeX * m_UnderlyingSizeZ];
+ m_Underlying->GetInts(a_MinX - 1, a_MinZ - 1, lowerValues);
+
+ // Add beaches between ocean and biomes:
+ for (int z = 0; z < SizeZ; z++)
+ {
+ for (int x = 0; x < SizeX; x++)
+ {
+ int val = lowerValues[x + 1 + (z + 1) * m_UnderlyingSizeX];
+ int above = lowerValues[x + 1 + z * m_UnderlyingSizeX];
+ int below = lowerValues[x + 1 + (z + 2) * m_UnderlyingSizeX];
+ int left = lowerValues[x + (z + 1) * m_UnderlyingSizeX];
+ int right = lowerValues[x + 2 + (z + 1) * m_UnderlyingSizeX];
+ if (!IsBiomeOcean(val))
+ {
+ if (IsBiomeOcean(above) || IsBiomeOcean(below) || IsBiomeOcean(left) || IsBiomeOcean(right))
+ {
+ // First convert the value to a regular biome (drop the M flag), then modulo by our biome count:
+ val = ToBeach[(val % 128) % ARRAYCOUNT(ToBeach)];
+ }
+ }
+ a_Values[x + z * SizeX] = val;
+ }
+ }
+ }
+
+protected:
+ Underlying m_Underlying;
+};
+
+
+
+
+
+/** Generates the underlying numbers and then randomly changes some ocean group pixels into random land
+biome group pixels, based on the predefined chance. */
+template <int SizeX, int SizeZ = SizeX>
+class cIntGenAddIslands :
+ public cIntGenWithNoise<SizeX, SizeZ>
+{
+ typedef cIntGenWithNoise<SizeX, SizeZ> super;
+
+public:
+ typedef std::shared_ptr<cIntGen<SizeX, SizeZ>> Underlying;
+
+
+ cIntGenAddIslands(int a_Seed, int a_Chance, Underlying a_Underlying) :
+ super(a_Seed),
+ m_Chance(a_Chance),
+ m_Underlying(a_Underlying)
+ {
+ }
+
+
+ virtual void GetInts(int a_MinX, int a_MinZ, typename super::Values & a_Values) override
+ {
+ m_Underlying->GetInts(a_MinX, a_MinZ, a_Values);
+ for (int z = 0; z < SizeZ; z++)
+ {
+ for (int x = 0; x < SizeX; x++)
+ {
+ if (a_Values[x + z * SizeX] == bgOcean)
+ {
+ int rnd = super::m_Noise.IntNoise2DInt(a_MinX + x, a_MinZ + z) / 7;
+ if (rnd % 1000 < m_Chance)
+ {
+ a_Values[x + z * SizeX] = (rnd / 1003) % bgLandOceanMax;
+ }
+ }
+ } // for x
+ } // for z
+ }
+
+protected:
+ /** Chance, in permille, of an island being generated in ocean. */
+ int m_Chance;
+
+ Underlying m_Underlying;
+};
+
+
+
+
+
+/** A filter that adds an edge biome group between two biome groups that need an edge between them. */
+template <int SizeX, int SizeZ = SizeX>
+class cIntGenBiomeGroupEdges :
+ public cIntGen<SizeX, SizeZ>
+{
+ typedef cIntGen<SizeX, SizeZ> super;
+
+ static const int m_UnderlyingSizeX = SizeX + 2;
+ static const int m_UnderlyingSizeZ = SizeZ + 2;
+
+public:
+
+ typedef std::shared_ptr<cIntGen<m_UnderlyingSizeX, m_UnderlyingSizeZ>> Underlying;
+
+ cIntGenBiomeGroupEdges(Underlying a_Underlying) :
+ m_Underlying(a_Underlying)
+ {
+ }
+
+
+ virtual void GetInts(int a_MinX, int a_MinZ, typename super::Values & a_Values)
+ {
+ // Generate the underlying biome groups:
+ int lowerValues[m_UnderlyingSizeX * m_UnderlyingSizeZ];
+ m_Underlying->GetInts(a_MinX, a_MinZ, lowerValues);
+
+ // Change the biomes on incompatible edges into an edge biome:
+ for (int z = 0; z < SizeZ; z++)
+ {
+ for (int x = 0; x < SizeX; x++)
+ {
+ int val = lowerValues[x + 1 + (z + 1) * m_UnderlyingSizeX];
+ int above = lowerValues[x + 1 + z * m_UnderlyingSizeX];
+ int below = lowerValues[x + 1 + (z + 2) * m_UnderlyingSizeX];
+ int left = lowerValues[x + (z + 1) * m_UnderlyingSizeX];
+ int right = lowerValues[x + 2 + (z + 1) * m_UnderlyingSizeX];
+ switch (val)
+ {
+ // Desert should neighbor only oceans, desert and temperates; change to temperate when another:
+ case bgDesert:
+ {
+ if (
+ !isDesertCompatible(above) ||
+ !isDesertCompatible(below) ||
+ !isDesertCompatible(left) ||
+ !isDesertCompatible(right)
+ )
+ {
+ val = bgTemperate;
+ }
+ break;
+ } // case bgDesert
+
+ // Ice should not neighbor deserts; change to temperate:
+ case bgIce:
+ {
+ if (
+ (above == bgDesert) ||
+ (below == bgDesert) ||
+ (left == bgDesert) ||
+ (right == bgDesert)
+ )
+ {
+ val = bgTemperate;
+ }
+ break;
+ } // case bgIce
+ }
+ a_Values[x + z * SizeX] = val;
+ } // for x
+ } // for z
+ }
+
+protected:
+ Underlying m_Underlying;
+
+
+ inline bool isDesertCompatible(int a_BiomeGroup)
+ {
+ switch (a_BiomeGroup)
+ {
+ case bgOcean:
+ case bgDesert:
+ case bgTemperate:
+ {
+ return true;
+ }
+ default:
+ {
+ return false;
+ }
+ }
+ }
+};
+
+
+
+
+
+/** Turns biome group indices into real biomes.
+For each pixel, takes its biome group and chooses a random biome from that group; replaces the value with
+that biome. */
+template <int SizeX, int SizeZ = SizeX>
+class cIntGenBiomes :
+ public cIntGenWithNoise<SizeX, SizeZ>
+{
+ typedef cIntGenWithNoise<SizeX, SizeZ> super;
+
+public:
+ typedef std::shared_ptr<cIntGen<SizeX, SizeZ>> Underlying;
+
+
+ cIntGenBiomes(int a_Seed, Underlying a_Underlying) :
+ super(a_Seed),
+ m_Underlying(a_Underlying)
+ {
+ }
+
+
+ virtual void GetInts(int a_MinX, int a_MinZ, typename super::Values & a_Values) override
+ {
+ // Define the per-biome-group biomes:
+ static const int oceanBiomes[] =
+ {
+ biOcean, // biDeepOcean,
+ };
+
+ // Same as oceanBiomes, there are no rare oceanic biomes (mushroom islands are handled separately)
+ static const int rareOceanBiomes[] =
+ {
+ biOcean,
+ };
+
+ static const int desertBiomes[] =
+ {
+ biDesert, biDesert, biDesert, biDesert, biDesert, biDesert, biSavanna, biSavanna, biPlains,
+ };
+
+ static const int rareDesertBiomes[] =
+ {
+ biMesaPlateau, biMesaPlateauF,
+ };
+
+ static const int temperateBiomes[] =
+ {
+ biForest, biForest, biRoofedForest, biExtremeHills, biPlains, biBirchForest, biSwampland,
+ };
+
+ static const int rareTemperateBiomes[] =
+ {
+ biJungle, // Jungle is not strictly temperate, but let's piggyback it here
+ };
+
+ static const int mountainBiomes[] =
+ {
+ biExtremeHills, biForest, biTaiga, biPlains,
+ };
+
+ static const int rareMountainBiomes[] =
+ {
+ biMegaTaiga,
+ };
+
+ static const int iceBiomes[] =
+ {
+ biIcePlains, biIcePlains, biIcePlains, biIcePlains, biColdTaiga,
+ };
+
+ // Same as iceBiomes, there's no rare ice biome
+ static const int rareIceBiomes[] =
+ {
+ biIcePlains, biIcePlains, biIcePlains, biIcePlains, biColdTaiga,
+ };
+
+ static const cBiomesInGroups biomesInGroups[] =
+ {
+ /* bgOcean */ { static_cast<int>(ARRAYCOUNT(oceanBiomes)), oceanBiomes},
+ /* bgDesert */ { static_cast<int>(ARRAYCOUNT(desertBiomes)), desertBiomes},
+ /* bgTemperate */ { static_cast<int>(ARRAYCOUNT(temperateBiomes)), temperateBiomes},
+ /* bgMountains */ { static_cast<int>(ARRAYCOUNT(mountainBiomes)), mountainBiomes},
+ /* bgIce */ { static_cast<int>(ARRAYCOUNT(iceBiomes)), iceBiomes},
+ };
+
+ static const cBiomesInGroups rareBiomesInGroups[] =
+ {
+ /* bgOcean */ { static_cast<int>(ARRAYCOUNT(rareOceanBiomes)), rareOceanBiomes},
+ /* bgDesert */ { static_cast<int>(ARRAYCOUNT(rareDesertBiomes)), rareDesertBiomes},
+ /* bgTemperate */ { static_cast<int>(ARRAYCOUNT(rareTemperateBiomes)), rareTemperateBiomes},
+ /* bgMountains */ { static_cast<int>(ARRAYCOUNT(rareMountainBiomes)), rareMountainBiomes},
+ /* bgIce */ { static_cast<int>(ARRAYCOUNT(rareIceBiomes)), rareIceBiomes},
+ };
+
+ // Generate the underlying values, representing biome groups:
+ m_Underlying->GetInts(a_MinX, a_MinZ, a_Values);
+
+ // Overwrite each biome group with a random biome from that group:
+ for (int z = 0; z < SizeZ; z++)
+ {
+ int IdxZ = z * SizeX;
+ for (int x = 0; x < SizeX; x++)
+ {
+ int val = a_Values[x + IdxZ];
+ const cBiomesInGroups & Biomes = (val > bgfRare) ?
+ rareBiomesInGroups[(val & (bgfRare - 1)) % ARRAYCOUNT(rareBiomesInGroups)] :
+ biomesInGroups[val % ARRAYCOUNT(biomesInGroups)];
+ int rnd = (super::m_Noise.IntNoise2DInt(x + a_MinX, z + a_MinZ) / 7);
+ a_Values[x + IdxZ] = Biomes.Biomes[rnd % Biomes.Count];
+ }
+ }
+ }
+
+protected:
+
+ struct cBiomesInGroups
+ {
+ const int Count;
+ const int * Biomes;
+ };
+
+
+ /** The underlying int generator */
+ Underlying m_Underlying;
+};
+
+
+
+
+
+/** Randomly replaces pixels of one value to another value, using the given chance. */
+template <int SizeX, int SizeZ = SizeX>
+class cIntGenReplaceRandomly :
+ public cIntGenWithNoise<SizeX, SizeZ>
+{
+ typedef cIntGenWithNoise<SizeX, SizeZ> super;
+
+public:
+ typedef std::shared_ptr<cIntGen<SizeX, SizeZ>> Underlying;
+
+
+ cIntGenReplaceRandomly(int a_From, int a_To, int a_Chance, int a_Seed, Underlying a_Underlying) :
+ super(a_Seed),
+ m_From(a_From),
+ m_To(a_To),
+ m_Chance(a_Chance),
+ m_Underlying(a_Underlying)
+ {
+ }
+
+
+ virtual void GetInts(int a_MinX, int a_MinZ, typename super::Values & a_Values) override
+ {
+ // Generate the underlying values:
+ m_Underlying->GetInts(a_MinX, a_MinZ, a_Values);
+
+ // Replace some of the values:
+ for (int z = 0; z < SizeZ; z++)
+ {
+ int idxZ = z * SizeX;
+ for (int x = 0; x < SizeX; x++)
+ {
+ int idx = x + idxZ;
+ if (a_Values[idx] == m_From)
+ {
+ int rnd = super::m_Noise.IntNoise2DInt(x + a_MinX, z + a_MinZ) / 7;
+ if (rnd % 1000 < m_Chance)
+ {
+ a_Values[idx] = m_To;
+ }
+ }
+ }
+ } // for z
+ }
+
+
+protected:
+ /** The original value to be replaced. */
+ int m_From;
+
+ /** The destination value to which to replace. */
+ int m_To;
+
+ /** Chance, in permille, of replacing the value. */
+ int m_Chance;
+
+ Underlying m_Underlying;
+};
+
+
+
+
+
+/** Mixer that joins together finalized biomes and rivers.
+It first checks for oceans, if there is an ocean in the Biomes, it keeps the ocean.
+If there's no ocean, it checks Rivers for a river, if there is a river, it uses the Biomes to select either
+regular river or frozen river, based on the biome. */
+template <int SizeX, int SizeZ = SizeX>
+class cIntGenMixRivers:
+ public cIntGen<SizeX, SizeZ>
+{
+ typedef cIntGen<SizeX, SizeZ> super;
+
+public:
+ typedef std::shared_ptr<cIntGen<SizeX, SizeZ>> Underlying;
+
+
+ cIntGenMixRivers(Underlying a_Biomes, Underlying a_Rivers):
+ m_Biomes(a_Biomes),
+ m_Rivers(a_Rivers)
+ {
+ }
+
+
+ virtual void GetInts(int a_MinX, int a_MinZ, typename super::Values & a_Values) override
+ {
+ // Generate the underlying data:
+ m_Biomes->GetInts(a_MinX, a_MinZ, a_Values);
+ typename super::Values riverData;
+ m_Rivers->GetInts(a_MinX, a_MinZ, riverData);
+
+ // Mix the values:
+ for (int z = 0; z < SizeZ; z++)
+ {
+ int idxZ = z * SizeX;
+ for (int x = 0; x < SizeX; x++)
+ {
+ int idx = x + idxZ;
+ if (IsBiomeOcean(a_Values[idx]))
+ {
+ // Oceans are kept without any changes
+ continue;
+ }
+ if (riverData[idx] != biRiver)
+ {
+ // There's no river, keep the current value
+ continue;
+ }
+
+ // There's a river, change the output to a river or a frozen river, based on the original biome:
+ if (IsBiomeVeryCold((EMCSBiome)a_Values[idx]))
+ {
+ a_Values[idx] = biFrozenRiver;
+ }
+ else
+ {
+ a_Values[idx] = biRiver;
+ }
+ } // for x
+ } // for z
+ }
+
+protected:
+ Underlying m_Biomes;
+ Underlying m_Rivers;
+};
+
+
+
+
+
+/** Generates a river based on the underlying data.
+This is basically an edge detector over the underlying data. The rivers are the edges where the underlying data
+changes from one pixel to its neighbor. */
+template <int SizeX, int SizeZ = SizeX>
+class cIntGenRiver:
+ public cIntGenWithNoise<SizeX, SizeZ>
+{
+ typedef cIntGenWithNoise<SizeX, SizeZ> super;
+ static const int UnderlyingSizeX = SizeX + 2;
+ static const int UnderlyingSizeZ = SizeZ + 2;
+
+public:
+ typedef std::shared_ptr<cIntGen<UnderlyingSizeX, UnderlyingSizeZ>> Underlying;
+
+
+ cIntGenRiver(int a_Seed, Underlying a_Underlying):
+ super(a_Seed),
+ m_Underlying(a_Underlying)
+ {
+ }
+
+
+ virtual void GetInts(int a_MinX, int a_MinZ, typename super::Values & a_Values) override
+ {
+ // Generate the underlying data:
+ int Cache[UnderlyingSizeX * UnderlyingSizeZ];
+ m_Underlying->GetInts(a_MinX - 1, a_MinZ - 1, Cache);
+
+ // Detect the edges:
+ for (int z = 0; z < SizeZ; z++)
+ {
+ for (int x = 0; x < SizeX; x++)
+ {
+ int Above = Cache[x + 1 + z * UnderlyingSizeX];
+ int Below = Cache[x + 1 + (z + 2) * UnderlyingSizeX];
+ int Left = Cache[x + (z + 1) * UnderlyingSizeX];
+ int Right = Cache[x + 2 + (z + 1) * UnderlyingSizeX];
+ int val = Cache[x + 1 + (z + 1) * UnderlyingSizeX];
+
+ if ((val == Above) && (val == Below) && (val == Left) && (val == Right))
+ {
+ val = 0;
+ }
+ else
+ {
+ val = biRiver;
+ }
+ a_Values[x + z * SizeX] = val;
+ } // for x
+ } // for z
+ }
+
+protected:
+ Underlying m_Underlying;
+};
+
+
+
+
+
+/** Turns some of the oceans into the specified biome. Used for mushroom and deep ocean.
+The biome is only placed if at least 3 of its neighbors are ocean and only with the specified chance. */
+template <int SizeX, int SizeZ = SizeX>
+class cIntGenAddToOcean:
+ public cIntGenWithNoise<SizeX, SizeZ>
+{
+ typedef cIntGenWithNoise<SizeX, SizeZ> super;
+ static const int UnderlyingSizeX = SizeX + 2;
+ static const int UnderlyingSizeZ = SizeZ + 2;
+
+public:
+ typedef std::shared_ptr<cIntGen<UnderlyingSizeX, UnderlyingSizeZ>> Underlying;
+
+
+ cIntGenAddToOcean(int a_Seed, int a_Chance, int a_ToValue, Underlying a_Underlying):
+ super(a_Seed),
+ m_Chance(a_Chance),
+ m_ToValue(a_ToValue),
+ m_Underlying(a_Underlying)
+ {
+ }
+
+
+ virtual void GetInts(int a_MinX, int a_MinZ, typename super::Values & a_Values) override
+ {
+ // Generate the underlying data:
+ int Cache[UnderlyingSizeX * UnderlyingSizeZ];
+ m_Underlying->GetInts(a_MinX - 1, a_MinZ - 1, Cache);
+
+ // Add the mushroom islands:
+ for (int z = 0; z < SizeZ; z++)
+ {
+ for (int x = 0; x < SizeX; x++)
+ {
+ int val = Cache[x + 1 + (z + 1) * UnderlyingSizeX];
+ if (!IsBiomeOcean(val))
+ {
+ a_Values[x + z * SizeX] = val;
+ continue;
+ }
+
+ // Count the ocean neighbors:
+ int Above = Cache[x + 1 + z * UnderlyingSizeX];
+ int Below = Cache[x + 1 + (z + 2) * UnderlyingSizeX];
+ int Left = Cache[x + (z + 1) * UnderlyingSizeX];
+ int Right = Cache[x + 2 + (z + 1) * UnderlyingSizeX];
+ int NumOceanNeighbors = 0;
+ if (IsBiomeOcean(Above))
+ {
+ NumOceanNeighbors += 1;
+ }
+ if (IsBiomeOcean(Below))
+ {
+ NumOceanNeighbors += 1;
+ }
+ if (IsBiomeOcean(Left))
+ {
+ NumOceanNeighbors += 1;
+ }
+ if (IsBiomeOcean(Right))
+ {
+ NumOceanNeighbors += 1;
+ }
+
+ // If at least 3 ocean neighbors and the chance is right, change:
+ if (
+ (NumOceanNeighbors >= 3) &&
+ ((super::m_Noise.IntNoise2DInt(x + a_MinX, z + a_MinZ) / 7) % 1000 < m_Chance)
+ )
+ {
+ a_Values[x + z * SizeX] = m_ToValue;
+ }
+ else
+ {
+ a_Values[x + z * SizeX] = val;
+ }
+ } // for x
+ } // for z
+ }
+
+protected:
+ /** Chance, in permille, of changing the biome. */
+ int m_Chance;
+
+ /** The value to change the ocean into. */
+ int m_ToValue;
+
+ Underlying m_Underlying;
+};
+
+
+
+
+
+/** Changes random pixels of the underlying data to the specified value. */
+template <int SizeX, int SizeZ = SizeX>
+class cIntGenSetRandomly :
+ public cIntGenWithNoise<SizeX, SizeZ>
+{
+ typedef cIntGenWithNoise<SizeX, SizeZ> super;
+
+public:
+ typedef std::shared_ptr<cIntGen<SizeX, SizeZ>> Underlying;
+
+ cIntGenSetRandomly(int a_Seed, int a_Chance, int a_ToValue, Underlying a_Underlying) :
+ super(a_Seed),
+ m_Chance(a_Chance),
+ m_ToValue(a_ToValue),
+ m_Underlying(a_Underlying)
+ {
+ }
+
+
+ virtual void GetInts(int a_MinX, int a_MinZ, typename super::Values & a_Values) override
+ {
+ // Generate the underlying data:
+ m_Underlying->GetInts(a_MinX, a_MinZ, a_Values);
+
+ // Change random pixels to bgOcean:
+ for (int z = 0; z < SizeZ; z++)
+ {
+ for (int x = 0; x < SizeX; x++)
+ {
+ int rnd = super::m_Noise.IntNoise2DInt(x + a_MinX, z + a_MinZ) / 7;
+ if (rnd % 1000 < m_Chance)
+ {
+ a_Values[x + z * SizeX] = m_ToValue;
+ }
+ }
+ }
+ }
+
+protected:
+ /** Chance, in permille, of changing each pixel. */
+ int m_Chance;
+
+ /** The value to which to set the pixel. */
+ int m_ToValue;
+
+ Underlying m_Underlying;
+};
+
+
+
+
+
+
+/** Adds a "rare" flag to random biome groups, based on the given chance. */
+template <int SizeX, int SizeZ = SizeX>
+class cIntGenRareBiomeGroups:
+ public cIntGenWithNoise<SizeX, SizeZ>
+{
+ typedef cIntGenWithNoise<SizeX, SizeZ> super;
+
+public:
+ typedef std::shared_ptr<cIntGen<SizeX, SizeZ>> Underlying;
+
+
+ cIntGenRareBiomeGroups(int a_Seed, int a_Chance, Underlying a_Underlying):
+ super(a_Seed),
+ m_Chance(a_Chance),
+ m_Underlying(a_Underlying)
+ {
+ }
+
+
+ virtual void GetInts(int a_MinX, int a_MinZ, typename super::Values & a_Values) override
+ {
+ // Generate the underlying data:
+ m_Underlying->GetInts(a_MinX, a_MinZ, a_Values);
+
+ // Change some of the biome groups into rare biome groups:
+ for (int z = 0; z < SizeZ; z++)
+ {
+ for (int x = 0; x < SizeX; x++)
+ {
+ int rnd = super::m_Noise.IntNoise2DInt(x + a_MinX, z + a_MinZ) / 7;
+ if (rnd % 1000 < m_Chance)
+ {
+ int idx = x + SizeX * z;
+ a_Values[idx] = a_Values[idx] | bgfRare;
+ }
+ }
+ }
+ }
+
+protected:
+ /** Chance, in permille, of changing each pixel into the rare biome group. */
+ int m_Chance;
+
+ /** The underlying generator. */
+ Underlying m_Underlying;
+};
+
+
+
+
+
+/** Changes biomes in the parent data into an alternate versions (usually "hill" variants), in such places
+that have their alterations set. */
+template <int SizeX, int SizeZ = SizeX>
+class cIntGenAlternateBiomes:
+ public cIntGenWithNoise<SizeX, SizeZ>
+{
+ typedef cIntGenWithNoise<SizeX, SizeZ> super;
+
+public:
+ typedef std::shared_ptr<cIntGen<SizeX, SizeZ>> Underlying;
+
+
+ cIntGenAlternateBiomes(int a_Seed, Underlying a_Alterations, Underlying a_BaseBiomes):
+ super(a_Seed),
+ m_Alterations(a_Alterations),
+ m_BaseBiomes(a_BaseBiomes)
+ {
+ }
+
+
+ virtual void GetInts(int a_MinX, int a_MinZ, typename super::Values & a_Values) override
+ {
+ // Generate the base biomes and the alterations:
+ m_BaseBiomes->GetInts(a_MinX, a_MinZ, a_Values);
+ typename super::Values alterations;
+ m_Alterations->GetInts(a_MinX, a_MinZ, alterations);
+
+ // Change the biomes into their alternate versions:
+ for (int idx = 0; idx < SizeX * SizeZ; ++idx)
+ {
+ if (alterations[idx] == 0)
+ {
+ // No change
+ continue;
+ }
+
+ // Change to alternate biomes:
+ int val = a_Values[idx];
+ switch (val)
+ {
+ case biBirchForest: val = biBirchForestHills; break;
+ case biDesert: val = biDesertHills; break;
+ case biExtremeHills: val = biExtremeHillsPlus; break;
+ case biForest: val = biForestHills; break;
+ case biIcePlains: val = biIceMountains; break;
+ case biJungle: val = biJungleHills; break;
+ case biMegaTaiga: val = biMegaTaigaHills; break;
+ case biMesaPlateau: val = biMesa; break;
+ case biMesaPlateauF: val = biMesa; break;
+ case biMesaPlateauM: val = biMesa; break;
+ case biMesaPlateauFM: val = biMesa; break;
+ case biPlains: val = biForest; break;
+ case biRoofedForest: val = biPlains; break;
+ case biSavanna: val = biSavannaPlateau; break;
+ case biTaiga: val = biTaigaHills; break;
+ }
+ a_Values[idx] = val;
+ } // for idx - a_Values[]
+ }
+
+protected:
+ Underlying m_Alterations;
+ Underlying m_BaseBiomes;
+};
+
+
+
+
+
+/** Adds an edge between two specifically incompatible biomes, such as mesa and forest. */
+template <int SizeX, int SizeZ = SizeX>
+class cIntGenBiomeEdges:
+ public cIntGenWithNoise<SizeX, SizeZ>
+{
+ typedef cIntGenWithNoise<SizeX, SizeZ> super;
+ static const int m_LowerSizeX = SizeX + 2;
+ static const int m_LowerSizeZ = SizeZ + 2;
+
+public:
+ typedef std::shared_ptr<cIntGen<m_LowerSizeX, m_LowerSizeZ>> Underlying;
+
+
+ cIntGenBiomeEdges(int a_Seed, Underlying a_Underlying):
+ super(a_Seed),
+ m_Underlying(a_Underlying)
+ {
+ }
+
+
+ virtual void GetInts(int a_MinX, int a_MinZ, typename super::Values & a_Values) override
+ {
+ // Generate the underlying biomes:
+ typename Underlying::element_type::Values lowerValues;
+ m_Underlying->GetInts(a_MinX - 1, a_MinZ - 1, lowerValues);
+
+ // Convert incompatible edges into neutral biomes:
+ for (int z = 0; z < SizeZ; z++)
+ {
+ for (int x = 0; x < SizeX; x++)
+ {
+ int biome = lowerValues[x + 1 + (z + 1) * m_LowerSizeX];
+ int above = lowerValues[x + 1 + z * m_LowerSizeX];
+ int below = lowerValues[x + 1 + (z + 2) * m_LowerSizeX];
+ int left = lowerValues[x + (z + 1) * m_LowerSizeX];
+ int right = lowerValues[x + 2 + (z + 1) * m_LowerSizeX];
+
+ switch (biome)
+ {
+ case biDesert:
+ case biDesertM:
+ case biDesertHills:
+ {
+ if (
+ IsBiomeVeryCold(static_cast<EMCSBiome>(above)) ||
+ IsBiomeVeryCold(static_cast<EMCSBiome>(below)) ||
+ IsBiomeVeryCold(static_cast<EMCSBiome>(left)) ||
+ IsBiomeVeryCold(static_cast<EMCSBiome>(right))
+ )
+ {
+ biome = biPlains;
+ }
+ break;
+ } // case biDesert
+
+ case biMesaPlateau:
+ case biMesaPlateauF:
+ case biMesaPlateauFM:
+ case biMesaPlateauM:
+ {
+ if (
+ !isMesaCompatible(above) ||
+ !isMesaCompatible(below) ||
+ !isMesaCompatible(left) ||
+ !isMesaCompatible(right)
+ )
+ {
+ biome = biDesert;
+ }
+ break;
+ } // Mesa biomes
+
+ case biJungle:
+ case biJungleM:
+ {
+ if (
+ !isJungleCompatible(above) ||
+ !isJungleCompatible(below) ||
+ !isJungleCompatible(left) ||
+ !isJungleCompatible(right)
+ )
+ {
+ biome = (biome == biJungle) ? biJungleEdge : biJungleEdgeM;
+ }
+ break;
+ } // Jungle biomes
+
+ case biSwampland:
+ case biSwamplandM:
+ {
+ if (
+ IsBiomeNoDownfall(static_cast<EMCSBiome>(above)) ||
+ IsBiomeNoDownfall(static_cast<EMCSBiome>(below)) ||
+ IsBiomeNoDownfall(static_cast<EMCSBiome>(left)) ||
+ IsBiomeNoDownfall(static_cast<EMCSBiome>(right))
+ )
+ {
+ biome = biPlains;
+ }
+ break;
+ } // Swampland biomes
+ } // switch (biome)
+
+ a_Values[x + z * SizeX] = biome;
+ } // for x
+ } // for z
+ }
+
+
+protected:
+ Underlying m_Underlying;
+
+
+ bool isMesaCompatible(int a_Biome)
+ {
+ switch (a_Biome)
+ {
+ case biDesert:
+ case biMesa:
+ case biMesaBryce:
+ case biMesaPlateau:
+ case biMesaPlateauF:
+ case biMesaPlateauFM:
+ case biMesaPlateauM:
+ case biOcean:
+ case biDeepOcean:
+ {
+ return true;
+ }
+ default:
+ {
+ return false;
+ }
+ }
+ }
+
+
+ bool isJungleCompatible(int a_Biome)
+ {
+ switch (a_Biome)
+ {
+ case biJungle:
+ case biJungleM:
+ case biJungleEdge:
+ case biJungleEdgeM:
+ case biJungleHills:
+ {
+ return true;
+ }
+ default:
+ {
+ return false;
+ }
+ }
+ }
+};
+
+
+
+
+
+/** Changes biomes in the parent data into their alternate versions ("M" variants), in such places that
+have their alterations set. */
+template <int SizeX, int SizeZ = SizeX>
+class cIntGenMBiomes:
+ public cIntGenWithNoise<SizeX, SizeZ>
+{
+ typedef cIntGenWithNoise<SizeX, SizeZ> super;
+
+public:
+ typedef std::shared_ptr<cIntGen<SizeX, SizeZ>> Underlying;
+
+
+ cIntGenMBiomes(int a_Seed, Underlying a_Alteration, Underlying a_Underlying):
+ super(a_Seed),
+ m_Underlying(a_Underlying),
+ m_Alteration(a_Alteration)
+ {
+ }
+
+
+ virtual void GetInts(int a_MinX, int a_MinZ, typename super::Values & a_Values) override
+ {
+ // Generate the underlying biomes and the alterations:
+ m_Underlying->GetInts(a_MinX, a_MinZ, a_Values);
+ typename super::Values alterations;
+ m_Alteration->GetInts(a_MinX, a_MinZ, alterations);
+
+ // Wherever alterations are nonzero, change into alternate biome, if available:
+ for (int idx = 0; idx < SizeX * SizeZ; ++idx)
+ {
+ if (alterations[idx] == 0)
+ {
+ continue;
+ }
+
+ // Ice spikes biome was removed from here, because it was generated way too often
+ switch (a_Values[idx])
+ {
+ case biPlains: a_Values[idx] = biSunflowerPlains; break;
+ case biDesert: a_Values[idx] = biDesertM; break;
+ case biExtremeHills: a_Values[idx] = biExtremeHillsM; break;
+ case biForest: a_Values[idx] = biFlowerForest; break;
+ case biTaiga: a_Values[idx] = biTaigaM; break;
+ case biSwampland: a_Values[idx] = biSwamplandM; break;
+ case biJungle: a_Values[idx] = biJungleM; break;
+ case biJungleEdge: a_Values[idx] = biJungleEdgeM; break;
+ case biBirchForest: a_Values[idx] = biBirchForestM; break;
+ case biBirchForestHills: a_Values[idx] = biBirchForestHillsM; break;
+ case biRoofedForest: a_Values[idx] = biRoofedForestM; break;
+ case biColdTaiga: a_Values[idx] = biColdTaigaM; break;
+ case biMegaSpruceTaiga: a_Values[idx] = biMegaSpruceTaiga; break;
+ case biMegaSpruceTaigaHills: a_Values[idx] = biMegaSpruceTaigaHills; break;
+ case biExtremeHillsPlus: a_Values[idx] = biExtremeHillsPlusM; break;
+ case biSavanna: a_Values[idx] = biSavannaM; break;
+ case biSavannaPlateau: a_Values[idx] = biSavannaPlateauM; break;
+ case biMesa: a_Values[idx] = biMesaBryce; break;
+ case biMesaPlateauF: a_Values[idx] = biMesaPlateauFM; break;
+ case biMesaPlateau: a_Values[idx] = biMesaBryce; break;
+ }
+ } // for idx - a_Values[] / alterations[]
+ }
+
+protected:
+ Underlying m_Underlying;
+ Underlying m_Alteration;
+};
+
+
+
+
diff --git a/src/Generating/Noise3DGenerator.cpp b/src/Generating/Noise3DGenerator.cpp
index 5a4cb44cf..91bdce458 100644
--- a/src/Generating/Noise3DGenerator.cpp
+++ b/src/Generating/Noise3DGenerator.cpp
@@ -61,6 +61,35 @@ public:
+/** Linearly interpolates between two values.
+Assumes that a_Ratio is in range [0, 1]. */
+inline static NOISE_DATATYPE Lerp(NOISE_DATATYPE a_Val1, NOISE_DATATYPE a_Val2, NOISE_DATATYPE a_Ratio)
+{
+ return a_Val1 + (a_Val2 - a_Val1) * a_Ratio;
+}
+
+
+
+
+
+/** Linearly interpolates between two values, clamping the ratio to [0, 1] first. */
+inline static NOISE_DATATYPE ClampedLerp(NOISE_DATATYPE a_Val1, NOISE_DATATYPE a_Val2, NOISE_DATATYPE a_Ratio)
+{
+ if (a_Ratio < 0)
+ {
+ return a_Val1;
+ }
+ if (a_Ratio > 1)
+ {
+ return a_Val2;
+ }
+ return Lerp(a_Val1, a_Val2, a_Ratio);
+}
+
+
+
+
+
////////////////////////////////////////////////////////////////////////////////
// cNoise3DGenerator:
@@ -346,9 +375,10 @@ void cNoise3DGenerator::ComposeTerrain(cChunkDesc & a_ChunkDesc)
// cNoise3DComposable:
cNoise3DComposable::cNoise3DComposable(int a_Seed) :
- m_Noise1(a_Seed + 1000),
- m_Noise2(a_Seed + 2000),
- m_Noise3(a_Seed + 3000)
+ m_ChoiceNoise(a_Seed),
+ m_DensityNoiseA(a_Seed + 1),
+ m_DensityNoiseB(a_Seed + 2),
+ m_BaseNoise(a_Seed + 3)
{
}
@@ -359,13 +389,51 @@ cNoise3DComposable::cNoise3DComposable(int a_Seed) :
void cNoise3DComposable::Initialize(cIniFile & a_IniFile)
{
// Params:
+ // The defaults generate extreme hills terrain
m_SeaLevel = a_IniFile.GetValueSetI("Generator", "Noise3DSeaLevel", 62);
- m_HeightAmplification = (NOISE_DATATYPE)a_IniFile.GetValueSetF("Generator", "Noise3DHeightAmplification", 0);
+ m_HeightAmplification = (NOISE_DATATYPE)a_IniFile.GetValueSetF("Generator", "Noise3DHeightAmplification", 0.045);
m_MidPoint = (NOISE_DATATYPE)a_IniFile.GetValueSetF("Generator", "Noise3DMidPoint", 75);
- m_FrequencyX = (NOISE_DATATYPE)a_IniFile.GetValueSetF("Generator", "Noise3DFrequencyX", 10);
- m_FrequencyY = (NOISE_DATATYPE)a_IniFile.GetValueSetF("Generator", "Noise3DFrequencyY", 10);
- m_FrequencyZ = (NOISE_DATATYPE)a_IniFile.GetValueSetF("Generator", "Noise3DFrequencyZ", 10);
- m_AirThreshold = (NOISE_DATATYPE)a_IniFile.GetValueSetF("Generator", "Noise3DAirThreshold", 0.5);
+ m_FrequencyX = (NOISE_DATATYPE)a_IniFile.GetValueSetF("Generator", "Noise3DFrequencyX", 40);
+ m_FrequencyY = (NOISE_DATATYPE)a_IniFile.GetValueSetF("Generator", "Noise3DFrequencyY", 40);
+ m_FrequencyZ = (NOISE_DATATYPE)a_IniFile.GetValueSetF("Generator", "Noise3DFrequencyZ", 40);
+ m_BaseFrequencyX = (NOISE_DATATYPE)a_IniFile.GetValueSetF("Generator", "Noise3DBaseFrequencyX", 40);
+ m_BaseFrequencyZ = (NOISE_DATATYPE)a_IniFile.GetValueSetF("Generator", "Noise3DBaseFrequencyZ", 40);
+ m_ChoiceFrequencyX = (NOISE_DATATYPE)a_IniFile.GetValueSetF("Generator", "Noise3DChoiceFrequencyX", 40);
+ m_ChoiceFrequencyY = (NOISE_DATATYPE)a_IniFile.GetValueSetF("Generator", "Noise3DChoiceFrequencyY", 80);
+ m_ChoiceFrequencyZ = (NOISE_DATATYPE)a_IniFile.GetValueSetF("Generator", "Noise3DChoiceFrequencyZ", 40);
+ m_AirThreshold = (NOISE_DATATYPE)a_IniFile.GetValueSetF("Generator", "Noise3DAirThreshold", 0);
+ int NumChoiceOctaves = a_IniFile.GetValueSetI("Generator", "Noise3DNumChoiceOctaves", 4);
+ int NumDensityOctaves = a_IniFile.GetValueSetI("Generator", "Noise3DNumDensityOctaves", 6);
+ int NumBaseOctaves = a_IniFile.GetValueSetI("Generator", "Noise3DNumBaseOctaves", 6);
+ NOISE_DATATYPE BaseNoiseAmplitude = (NOISE_DATATYPE)a_IniFile.GetValueSetF("Generator", "Noise3DBaseAmplitude", 1);
+
+ // Add octaves for the choice noise:
+ NOISE_DATATYPE wavlen = 1, ampl = 0.5;
+ for (int i = 0; i < NumChoiceOctaves; i++)
+ {
+ m_ChoiceNoise.AddOctave(wavlen, ampl);
+ wavlen = wavlen * 2;
+ ampl = ampl / 2;
+ }
+
+ // Add octaves for the density noises:
+ wavlen = 1, ampl = 1;
+ for (int i = 0; i < NumDensityOctaves; i++)
+ {
+ m_DensityNoiseA.AddOctave(wavlen, ampl);
+ m_DensityNoiseB.AddOctave(wavlen, ampl);
+ wavlen = wavlen * 2;
+ ampl = ampl / 2;
+ }
+
+ // Add octaves for the base noise:
+ wavlen = 1, ampl = BaseNoiseAmplitude;
+ for (int i = 0; i < NumBaseOctaves; i++)
+ {
+ m_BaseNoise.AddOctave(wavlen, ampl);
+ wavlen = wavlen * 2;
+ ampl = ampl / 2;
+ }
}
@@ -376,126 +444,347 @@ void cNoise3DComposable::GenerateNoiseArrayIfNeeded(int a_ChunkX, int a_ChunkZ)
{
if ((a_ChunkX == m_LastChunkX) && (a_ChunkZ == m_LastChunkZ))
{
- // The noise for this chunk is already generated in m_Noise
+ // The noise for this chunk is already generated in m_NoiseArray
return;
}
m_LastChunkX = a_ChunkX;
m_LastChunkZ = a_ChunkZ;
- // Upscaling parameters:
- const int UPSCALE_X = 8;
- const int UPSCALE_Y = 4;
- const int UPSCALE_Z = 8;
-
- // Precalculate a "height" array:
- NOISE_DATATYPE Height[17 * 17]; // x + 17 * z
- for (int z = 0; z < 17; z += UPSCALE_Z)
+ // Generate all the noises:
+ NOISE_DATATYPE ChoiceNoise[5 * 5 * 33];
+ NOISE_DATATYPE Workspace[5 * 5 * 33];
+ NOISE_DATATYPE DensityNoiseA[5 * 5 * 33];
+ NOISE_DATATYPE DensityNoiseB[5 * 5 * 33];
+ NOISE_DATATYPE BaseNoise[5 * 5];
+ NOISE_DATATYPE BlockX = static_cast<NOISE_DATATYPE>(a_ChunkX * cChunkDef::Width);
+ NOISE_DATATYPE BlockZ = static_cast<NOISE_DATATYPE>(a_ChunkZ * cChunkDef::Width);
+ // Note that we have to swap the coords, because noise generator uses [x + SizeX * y + SizeX * SizeY * z] ordering and we want "BlockY" to be "z":
+ m_ChoiceNoise.Generate3D (ChoiceNoise, 5, 5, 33, BlockX / m_ChoiceFrequencyX, (BlockX + 17) / m_ChoiceFrequencyX, BlockZ / m_ChoiceFrequencyZ, (BlockZ + 17) / m_ChoiceFrequencyZ, 0, 257 / m_ChoiceFrequencyY, Workspace);
+ m_DensityNoiseA.Generate3D(DensityNoiseA, 5, 5, 33, BlockX / m_FrequencyX, (BlockX + 17) / m_FrequencyX, BlockZ / m_FrequencyZ, (BlockZ + 17) / m_FrequencyZ, 0, 257 / m_FrequencyY, Workspace);
+ m_DensityNoiseB.Generate3D(DensityNoiseB, 5, 5, 33, BlockX / m_FrequencyX, (BlockX + 17) / m_FrequencyX, BlockZ / m_FrequencyZ, (BlockZ + 17) / m_FrequencyZ, 0, 257 / m_FrequencyY, Workspace);
+ m_BaseNoise.Generate2D (BaseNoise, 5, 5, BlockX / m_BaseFrequencyX, (BlockX + 17) / m_BaseFrequencyX, BlockZ / m_FrequencyZ, (BlockZ + 17) / m_FrequencyZ, Workspace);
+
+ // Calculate the final noise based on the partial noises:
+ for (int y = 0; y < 33; y++)
{
- NOISE_DATATYPE NoiseZ = ((NOISE_DATATYPE)(a_ChunkZ * cChunkDef::Width + z)) / m_FrequencyZ;
- for (int x = 0; x < 17; x += UPSCALE_X)
+ NOISE_DATATYPE AddHeight = (static_cast<NOISE_DATATYPE>(y * 8) - m_MidPoint) * m_HeightAmplification;
+
+ // If "underground", make the terrain smoother by forcing the vertical linear gradient into steeper slope:
+ if (AddHeight < 0)
{
- NOISE_DATATYPE NoiseX = ((NOISE_DATATYPE)(a_ChunkX * cChunkDef::Width + x)) / m_FrequencyX;
- NOISE_DATATYPE val = std::abs(m_Noise1.CubicNoise2D(NoiseX / 5, NoiseZ / 5)) * m_HeightAmplification + 1;
- Height[x + 17 * z] = val * val * val;
+ AddHeight *= 4;
}
- }
- for (int y = 0; y < 257; y += UPSCALE_Y)
- {
- NOISE_DATATYPE NoiseY = ((NOISE_DATATYPE)y) / m_FrequencyY;
- NOISE_DATATYPE AddHeight = (y - m_MidPoint) / 20;
- AddHeight *= AddHeight * AddHeight;
- NOISE_DATATYPE * CurFloor = &(m_NoiseArray[y * 17 * 17]);
- for (int z = 0; z < 17; z += UPSCALE_Z)
+ for (int z = 0; z < 5; z++)
{
- NOISE_DATATYPE NoiseZ = ((NOISE_DATATYPE)(a_ChunkZ * cChunkDef::Width + z)) / m_FrequencyZ;
- for (int x = 0; x < 17; x += UPSCALE_X)
+ for (int x = 0; x < 5; x++)
{
- NOISE_DATATYPE NoiseX = ((NOISE_DATATYPE)(a_ChunkX * cChunkDef::Width + x)) / m_FrequencyX;
- CurFloor[x + 17 * z] = (
- m_Noise1.CubicNoise3D(NoiseX, NoiseY, NoiseZ) * (NOISE_DATATYPE)0.5 +
- m_Noise2.CubicNoise3D(NoiseX / 2, NoiseY / 2, NoiseZ / 2) +
- m_Noise3.CubicNoise3D(NoiseX / 4, NoiseY / 4, NoiseZ / 4) * 2 +
- AddHeight / Height[x + 17 * z]
- );
+ int idx = x + 5 * z + 5 * 5 * y;
+ Workspace[idx] = ClampedLerp(DensityNoiseA[idx], DensityNoiseB[idx], 8 * (ChoiceNoise[idx] + 0.5f)) + AddHeight + BaseNoise[x + 5 * z];
}
}
- // Linear-interpolate this XZ floor:
- LinearUpscale2DArrayInPlace<17, 17, UPSCALE_X, UPSCALE_Z>(CurFloor);
}
+ LinearUpscale3DArray<NOISE_DATATYPE>(Workspace, 5, 5, 33, m_NoiseArray, 4, 4, 8);
+}
+
+
- // Finish the 3D linear interpolation by interpolating between each XZ-floors on the Y axis
- for (int y = 1; y < cChunkDef::Height; y++)
+
+
+void cNoise3DComposable::GenHeightMap(int a_ChunkX, int a_ChunkZ, cChunkDef::HeightMap & a_HeightMap)
+{
+ GenerateNoiseArrayIfNeeded(a_ChunkX, a_ChunkZ);
+
+ for (int z = 0; z < cChunkDef::Width; z++)
{
- if ((y % UPSCALE_Y) == 0)
+ for (int x = 0; x < cChunkDef::Width; x++)
{
- // This is the interpolation source floor, already calculated
- continue;
- }
- int LoFloorY = (y / UPSCALE_Y) * UPSCALE_Y;
- int HiFloorY = LoFloorY + UPSCALE_Y;
- NOISE_DATATYPE * LoFloor = &(m_NoiseArray[LoFloorY * 17 * 17]);
- NOISE_DATATYPE * HiFloor = &(m_NoiseArray[HiFloorY * 17 * 17]);
- NOISE_DATATYPE * CurFloor = &(m_NoiseArray[y * 17 * 17]);
- NOISE_DATATYPE Ratio = ((NOISE_DATATYPE)(y % UPSCALE_Y)) / UPSCALE_Y;
- int idx = 0;
- for (int z = 0; z < cChunkDef::Width; z++)
+ cChunkDef::SetHeight(a_HeightMap, x, z, m_SeaLevel);
+ for (int y = cChunkDef::Height - 1; y > m_SeaLevel; y--)
+ {
+ if (m_NoiseArray[y * 17 * 17 + z * 17 + x] <= m_AirThreshold)
+ {
+ cChunkDef::SetHeight(a_HeightMap, x, z, y);
+ break;
+ }
+ } // for y
+ } // for x
+ } // for z
+}
+
+
+
+
+
+void cNoise3DComposable::ComposeTerrain(cChunkDesc & a_ChunkDesc)
+{
+ GenerateNoiseArrayIfNeeded(a_ChunkDesc.GetChunkX(), a_ChunkDesc.GetChunkZ());
+
+ a_ChunkDesc.FillBlocks(E_BLOCK_AIR, 0);
+
+ // Make basic terrain composition:
+ for (int z = 0; z < cChunkDef::Width; z++)
+ {
+ for (int x = 0; x < cChunkDef::Width; x++)
{
- for (int x = 0; x < cChunkDef::Width; x++)
+ int LastAir = a_ChunkDesc.GetHeight(x, z) + 1;
+ bool HasHadWater = false;
+ for (int y = LastAir; y < m_SeaLevel; y++)
{
- CurFloor[idx] = LoFloor[idx] + (HiFloor[idx] - LoFloor[idx]) * Ratio;
- idx += 1;
+ a_ChunkDesc.SetBlockType(x, y, z, E_BLOCK_STATIONARY_WATER);
}
- idx += 1; // Skipping one X column
+ for (int y = LastAir - 1; y > 0; y--)
+ {
+ if (m_NoiseArray[x + 17 * z + 17 * 17 * y] > m_AirThreshold)
+ {
+ // "air" part
+ LastAir = y;
+ if (y < m_SeaLevel)
+ {
+ a_ChunkDesc.SetBlockType(x, y, z, E_BLOCK_STATIONARY_WATER);
+ HasHadWater = true;
+ }
+ continue;
+ }
+ // "ground" part:
+ if (LastAir - y > 4)
+ {
+ a_ChunkDesc.SetBlockType(x, y, z, E_BLOCK_STONE);
+ continue;
+ }
+ if (HasHadWater)
+ {
+ a_ChunkDesc.SetBlockType(x, y, z, E_BLOCK_SAND);
+ }
+ else
+ {
+ a_ChunkDesc.SetBlockType(x, y, z, (LastAir == y + 1) ? E_BLOCK_GRASS : E_BLOCK_DIRT);
+ }
+ } // for y
+ a_ChunkDesc.SetBlockType(x, 0, z, E_BLOCK_BEDROCK);
+ } // for x
+ } // for z
+}
+
+
+
+
+
+////////////////////////////////////////////////////////////////////////////////
+// cBiomalNoise3DComposable:
+
+cBiomalNoise3DComposable::cBiomalNoise3DComposable(int a_Seed, cBiomeGenPtr a_BiomeGen) :
+ m_ChoiceNoise(a_Seed),
+ m_DensityNoiseA(a_Seed + 1),
+ m_DensityNoiseB(a_Seed + 2),
+ m_BaseNoise(a_Seed + 3),
+ m_BiomeGen(a_BiomeGen)
+{
+ // Generate the weight distribution for summing up neighboring biomes:
+ m_WeightSum = 0;
+ for (int z = 0; z <= AVERAGING_SIZE * 2; z++)
+ {
+ for (int x = 0; x <= AVERAGING_SIZE * 2; x++)
+ {
+ m_Weight[z][x] = static_cast<NOISE_DATATYPE>((5 - std::abs(5 - x)) + (5 - std::abs(5 - z)));
+ m_WeightSum += m_Weight[z][x];
}
}
+}
+
+
+
+
+
+void cBiomalNoise3DComposable::Initialize(cIniFile & a_IniFile)
+{
+ // Params:
+ // The defaults generate extreme hills terrain
+ m_SeaLevel = a_IniFile.GetValueSetI("Generator", "BiomalNoise3DSeaLevel", 62);
+ m_FrequencyX = (NOISE_DATATYPE)a_IniFile.GetValueSetF("Generator", "BiomalNoise3DFrequencyX", 40);
+ m_FrequencyY = (NOISE_DATATYPE)a_IniFile.GetValueSetF("Generator", "BiomalNoise3DFrequencyY", 40);
+ m_FrequencyZ = (NOISE_DATATYPE)a_IniFile.GetValueSetF("Generator", "BiomalNoise3DFrequencyZ", 40);
+ m_BaseFrequencyX = (NOISE_DATATYPE)a_IniFile.GetValueSetF("Generator", "BiomalNoise3DBaseFrequencyX", 40);
+ m_BaseFrequencyZ = (NOISE_DATATYPE)a_IniFile.GetValueSetF("Generator", "BiomalNoise3DBaseFrequencyZ", 40);
+ m_ChoiceFrequencyX = (NOISE_DATATYPE)a_IniFile.GetValueSetF("Generator", "BiomalNoise3DChoiceFrequencyX", 40);
+ m_ChoiceFrequencyY = (NOISE_DATATYPE)a_IniFile.GetValueSetF("Generator", "BiomalNoise3DChoiceFrequencyY", 80);
+ m_ChoiceFrequencyZ = (NOISE_DATATYPE)a_IniFile.GetValueSetF("Generator", "BiomalNoise3DChoiceFrequencyZ", 40);
+ m_AirThreshold = (NOISE_DATATYPE)a_IniFile.GetValueSetF("Generator", "BiomalNoise3DAirThreshold", 0);
+ int NumChoiceOctaves = a_IniFile.GetValueSetI("Generator", "BiomalNoise3DNumChoiceOctaves", 4);
+ int NumDensityOctaves = a_IniFile.GetValueSetI("Generator", "BiomalNoise3DNumDensityOctaves", 6);
+ int NumBaseOctaves = a_IniFile.GetValueSetI("Generator", "BiomalNoise3DNumBaseOctaves", 6);
+ NOISE_DATATYPE BaseNoiseAmplitude = (NOISE_DATATYPE)a_IniFile.GetValueSetF("Generator", "BiomalNoise3DBaseAmplitude", 1);
+
+ // Add octaves for the choice noise:
+ NOISE_DATATYPE wavlen = 1, ampl = 0.5;
+ for (int i = 0; i < NumChoiceOctaves; i++)
+ {
+ m_ChoiceNoise.AddOctave(wavlen, ampl);
+ wavlen = wavlen * 2;
+ ampl = ampl / 2;
+ }
- // The noise array is now fully interpolated
- /*
- // DEBUG: Output two images of the array, sliced by XY and XZ:
- cFile f1;
- if (f1.Open(Printf("Chunk_%d_%d_XY.raw", a_ChunkX, a_ChunkZ), cFile::fmWrite))
+ // Add octaves for the density noises:
+ wavlen = 1, ampl = 1;
+ for (int i = 0; i < NumDensityOctaves; i++)
{
- for (int z = 0; z < cChunkDef::Width; z++)
+ m_DensityNoiseA.AddOctave(wavlen, ampl);
+ m_DensityNoiseB.AddOctave(wavlen, ampl);
+ wavlen = wavlen * 2;
+ ampl = ampl / 2;
+ }
+
+ // Add octaves for the base noise:
+ wavlen = 1, ampl = BaseNoiseAmplitude;
+ for (int i = 0; i < NumBaseOctaves; i++)
+ {
+ m_BaseNoise.AddOctave(wavlen, ampl);
+ wavlen = wavlen * 2;
+ ampl = ampl / 2;
+ }
+}
+
+
+
+
+
+void cBiomalNoise3DComposable::GenerateNoiseArrayIfNeeded(int a_ChunkX, int a_ChunkZ)
+{
+ if ((a_ChunkX == m_LastChunkX) && (a_ChunkZ == m_LastChunkZ))
+ {
+ // The noise for this chunk is already generated in m_NoiseArray
+ return;
+ }
+ m_LastChunkX = a_ChunkX;
+ m_LastChunkZ = a_ChunkZ;
+
+ // Calculate the parameters for the biomes:
+ ChunkParam MidPoint;
+ ChunkParam HeightAmp;
+ CalcBiomeParamArrays(a_ChunkX, a_ChunkZ, HeightAmp, MidPoint);
+
+ // Generate all the noises:
+ NOISE_DATATYPE ChoiceNoise[5 * 5 * 33];
+ NOISE_DATATYPE Workspace[5 * 5 * 33];
+ NOISE_DATATYPE DensityNoiseA[5 * 5 * 33];
+ NOISE_DATATYPE DensityNoiseB[5 * 5 * 33];
+ NOISE_DATATYPE BaseNoise[5 * 5];
+ NOISE_DATATYPE BlockX = static_cast<NOISE_DATATYPE>(a_ChunkX * cChunkDef::Width);
+ NOISE_DATATYPE BlockZ = static_cast<NOISE_DATATYPE>(a_ChunkZ * cChunkDef::Width);
+ // Note that we have to swap the coords, because noise generator uses [x + SizeX * y + SizeX * SizeY * z] ordering and we want "BlockY" to be "z":
+ m_ChoiceNoise.Generate3D (ChoiceNoise, 5, 5, 33, BlockX / m_ChoiceFrequencyX, (BlockX + 17) / m_ChoiceFrequencyX, BlockZ / m_ChoiceFrequencyZ, (BlockZ + 17) / m_ChoiceFrequencyZ, 0, 257 / m_ChoiceFrequencyY, Workspace);
+ m_DensityNoiseA.Generate3D(DensityNoiseA, 5, 5, 33, BlockX / m_FrequencyX, (BlockX + 17) / m_FrequencyX, BlockZ / m_FrequencyZ, (BlockZ + 17) / m_FrequencyZ, 0, 257 / m_FrequencyY, Workspace);
+ m_DensityNoiseB.Generate3D(DensityNoiseB, 5, 5, 33, BlockX / m_FrequencyX, (BlockX + 17) / m_FrequencyX, BlockZ / m_FrequencyZ, (BlockZ + 17) / m_FrequencyZ, 0, 257 / m_FrequencyY, Workspace);
+ m_BaseNoise.Generate2D (BaseNoise, 5, 5, BlockX / m_BaseFrequencyX, (BlockX + 17) / m_BaseFrequencyX, BlockZ / m_FrequencyZ, (BlockZ + 17) / m_FrequencyZ, Workspace);
+
+ // Calculate the final noise based on the partial noises:
+ for (int y = 0; y < 33; y++)
+ {
+ NOISE_DATATYPE BlockHeight = static_cast<NOISE_DATATYPE>(y * 8);
+ for (int z = 0; z < 5; z++)
{
- for (int y = 0; y < cChunkDef::Height; y++)
+ for (int x = 0; x < 5; x++)
{
- int idx = y * 17 * 17 + z * 17;
- unsigned char buf[16];
- for (int x = 0; x < cChunkDef::Width; x++)
+ NOISE_DATATYPE AddHeight = (BlockHeight - MidPoint[x + 5 * z]) * HeightAmp[x + 5 * z];
+
+ // If "underground", make the terrain smoother by forcing the vertical linear gradient into steeper slope:
+ if (AddHeight < 0)
{
- buf[x] = (unsigned char)(std::min(256, std::max(0, (int)(128 + 128 * m_Noise[idx++]))));
+ AddHeight *= 4;
}
- f1.Write(buf, 16);
- } // for y
- } // for z
- } // if (XY file open)
- cFile f2;
- if (f2.Open(Printf("Chunk_%d_%d_XZ.raw", a_ChunkX, a_ChunkZ), cFile::fmWrite))
+ int idx = x + 5 * z + 5 * 5 * y;
+ Workspace[idx] = ClampedLerp(DensityNoiseA[idx], DensityNoiseB[idx], 8 * (ChoiceNoise[idx] + 0.5f)) + AddHeight + BaseNoise[x + 5 * z];
+ }
+ }
+ }
+ LinearUpscale3DArray<NOISE_DATATYPE>(Workspace, 5, 5, 33, m_NoiseArray, 4, 4, 8);
+}
+
+
+
+
+
+void cBiomalNoise3DComposable::CalcBiomeParamArrays(int a_ChunkX, int a_ChunkZ, ChunkParam & a_HeightAmp, ChunkParam & a_MidPoint)
+{
+ // Generate the 3*3 chunks of biomes around this chunk:
+ cChunkDef::BiomeMap neighborBiomes[3 * 3];
+ for (int z = 0; z < 3; z++)
{
- for (int y = 0; y < cChunkDef::Height; y++)
+ for (int x = 0; x < 3; x++)
{
- for (int z = 0; z < cChunkDef::Width; z++)
+ m_BiomeGen->GenBiomes(a_ChunkX + x - 1, a_ChunkZ + z - 1, neighborBiomes[x + 3 * z]);
+ }
+ }
+
+ // Sum up the biome values:
+ for (int z = 0; z < 5; z++)
+ {
+ for (int x = 0; x < 5; x++)
+ {
+ NOISE_DATATYPE totalHeightAmp = 0;
+ NOISE_DATATYPE totalMidPoint = 0;
+ // Add up the biomes around this point:
+ for (int relz = 0; relz <= AVERAGING_SIZE * 2; ++relz)
{
- int idx = y * 17 * 17 + z * 17;
- unsigned char buf[16];
- for (int x = 0; x < cChunkDef::Width; x++)
+ int colz = 16 + z * 4 + relz - AVERAGING_SIZE; // Biome Z coord relative to the neighborBiomes start
+ int neicellz = colz / 16; // Chunk Z coord relative to the neighborBiomes start
+ int neirelz = colz % 16; // Biome Z coord relative to cz in neighborBiomes
+ for (int relx = 0; relx <= AVERAGING_SIZE * 2; ++relx)
{
- buf[x] = (unsigned char)(std::min(256, std::max(0, (int)(128 + 128 * m_Noise[idx++]))));
- }
- f2.Write(buf, 16);
- } // for z
- } // for y
- } // if (XZ file open)
- */
+ int colx = 16 + x * 4 + relx - AVERAGING_SIZE; // Biome X coord relative to the neighborBiomes start
+ int neicellx = colx / 16; // Chunk X coord relative to the neighborBiomes start
+ int neirelx = colx % 16; // Biome X coord relative to cz in neighborBiomes
+ EMCSBiome biome = cChunkDef::GetBiome(neighborBiomes[neicellx + neicellz * 3], neirelx, neirelz);
+ NOISE_DATATYPE heightAmp, midPoint;
+ GetBiomeParams(biome, heightAmp, midPoint);
+ totalHeightAmp += heightAmp * m_Weight[relz][relx];
+ totalMidPoint += midPoint * m_Weight[relz][relx];
+ } // for relx
+ } // for relz
+ a_HeightAmp[x + 5 * z] = totalHeightAmp / m_WeightSum;
+ a_MidPoint[x + 5 * z] = totalMidPoint / m_WeightSum;
+ } // for x
+ } // for z
}
-void cNoise3DComposable::GenHeightMap(int a_ChunkX, int a_ChunkZ, cChunkDef::HeightMap & a_HeightMap)
+void cBiomalNoise3DComposable::GetBiomeParams(EMCSBiome a_Biome, NOISE_DATATYPE & a_HeightAmp, NOISE_DATATYPE & a_MidPoint)
+{
+ switch (a_Biome)
+ {
+ case biDeepOcean: a_HeightAmp = 0.17f; a_MidPoint = 35; break;
+ case biDesert: a_HeightAmp = 0.29f; a_MidPoint = 62; break; // Needs verification
+ case biExtremeHills: a_HeightAmp = 0.045f; a_MidPoint = 75; break;
+ case biExtremeHillsPlus: a_HeightAmp = 0.04f; a_MidPoint = 80; break;
+ case biFrozenRiver: a_HeightAmp = 0.4f; a_MidPoint = 53; break;
+ case biFrozenOcean: a_HeightAmp = 0.17f; a_MidPoint = 47; break;
+ case biJungle: a_HeightAmp = 0.1f; a_MidPoint = 63; break;
+ case biJungleM: a_HeightAmp = 0.1f; a_MidPoint = 63; break;
+ case biOcean: a_HeightAmp = 0.17f; a_MidPoint = 47; break;
+ case biPlains: a_HeightAmp = 0.3f; a_MidPoint = 62; break; // Needs verification
+ case biRiver: a_HeightAmp = 0.4f; a_MidPoint = 53; break;
+ case biSwampland: a_HeightAmp = 0.25f; a_MidPoint = 59; break;
+ case biSwamplandM: a_HeightAmp = 0.11f; a_MidPoint = 59; break;
+
+ default:
+ {
+ // Make a crazy terrain so that it stands out
+ a_HeightAmp = 0.001f;
+ a_MidPoint = 90;
+ break;
+ }
+ }
+}
+
+
+
+
+
+void cBiomalNoise3DComposable::GenHeightMap(int a_ChunkX, int a_ChunkZ, cChunkDef::HeightMap & a_HeightMap)
{
GenerateNoiseArrayIfNeeded(a_ChunkX, a_ChunkZ);
@@ -520,7 +809,7 @@ void cNoise3DComposable::GenHeightMap(int a_ChunkX, int a_ChunkZ, cChunkDef::Hei
-void cNoise3DComposable::ComposeTerrain(cChunkDesc & a_ChunkDesc)
+void cBiomalNoise3DComposable::ComposeTerrain(cChunkDesc & a_ChunkDesc)
{
GenerateNoiseArrayIfNeeded(a_ChunkDesc.GetChunkX(), a_ChunkDesc.GetChunkZ());
diff --git a/src/Generating/Noise3DGenerator.h b/src/Generating/Noise3DGenerator.h
index 42f61a854..ba541fbcc 100644
--- a/src/Generating/Noise3DGenerator.h
+++ b/src/Generating/Noise3DGenerator.h
@@ -1,7 +1,11 @@
// Noise3DGenerator.h
-// Generates terrain using 3D noise, rather than composing. Is a test.
+// Declares cNoise3DGenerator and cNoise3DComposable classes, representing 3D-noise-based generators.
+// They generate terrain shape by combining a lerp of two 3D noises with a vertical linear gradient
+// cNoise3DGenerator is obsolete and unmaintained.
+// cNoise3DComposable is used to test parameter combinations for single-biome worlds.
+
@@ -74,31 +78,147 @@ public:
void Initialize(cIniFile & a_IniFile);
protected:
- cNoise m_Noise1;
- cNoise m_Noise2;
- cNoise m_Noise3;
+ /** The noise that is used to choose between density noise A and B. */
+ cPerlinNoise m_ChoiceNoise;
+
+ /** Density 3D noise, variant A. */
+ cPerlinNoise m_DensityNoiseA;
+
+ /** Density 3D noise, variant B. */
+ cPerlinNoise m_DensityNoiseB;
+
+ /** Heightmap-like noise used to provide variance for low-amplitude biomes. */
+ cPerlinNoise m_BaseNoise;
- int m_SeaLevel;
+ /** Block height of the sealevel, used for composing the terrain. */
+ int m_SeaLevel;
+
+ /** The main parameter of the generator, specifies the slope of the vertical linear gradient.
+ A higher value means a steeper slope and a smaller total amplitude of the generated terrain. */
NOISE_DATATYPE m_HeightAmplification;
- NOISE_DATATYPE m_MidPoint; // Where the vertical "center" of the noise should be
+
+ /** Where the vertical "center" of the noise should be, as block height. */
+ NOISE_DATATYPE m_MidPoint;
+
+ // Frequency of the 3D noise's first octave:
NOISE_DATATYPE m_FrequencyX;
NOISE_DATATYPE m_FrequencyY;
NOISE_DATATYPE m_FrequencyZ;
+
+ // Frequency of the base terrain noise:
+ NOISE_DATATYPE m_BaseFrequencyX;
+ NOISE_DATATYPE m_BaseFrequencyZ;
+
+ // Frequency of the choice noise:
+ NOISE_DATATYPE m_ChoiceFrequencyX;
+ NOISE_DATATYPE m_ChoiceFrequencyY;
+ NOISE_DATATYPE m_ChoiceFrequencyZ;
+
+ // Threshold for when the values are considered air:
NOISE_DATATYPE m_AirThreshold;
+ // Cache for the last calculated chunk (reused between heightmap and composition queries):
int m_LastChunkX;
int m_LastChunkZ;
NOISE_DATATYPE m_NoiseArray[17 * 17 * 257]; // x + 17 * z + 17 * 17 * y
- /// Generates the 3D noise array used for terrain generation, unless the LastChunk coords are equal to coords given
+ /** Generates the 3D noise array used for terrain generation (m_NoiseArray), unless the LastChunk coords are equal to coords given */
void GenerateNoiseArrayIfNeeded(int a_ChunkX, int a_ChunkZ);
// cTerrainHeightGen overrides:
virtual void GenHeightMap(int a_ChunkX, int a_ChunkZ, cChunkDef::HeightMap & a_HeightMap) override;
+ virtual void InitializeHeightGen(cIniFile & a_IniFile) override { Initialize(a_IniFile); }
+
+ // cTerrainCompositionGen overrides:
+ virtual void ComposeTerrain(cChunkDesc & a_ChunkDesc) override;
+ virtual void InitializeCompoGen(cIniFile & a_IniFile) override { Initialize(a_IniFile); }
+} ;
+
+
+
+
+
+class cBiomalNoise3DComposable :
+ public cTerrainHeightGen,
+ public cTerrainCompositionGen
+{
+public:
+ cBiomalNoise3DComposable(int a_Seed, cBiomeGenPtr a_BiomeGen);
+
+ void Initialize(cIniFile & a_IniFile);
+
+protected:
+ /** Number of columns around the pixel to query for biomes for averaging. */
+ static const int AVERAGING_SIZE = 5;
+
+ /** Type used for a single parameter across the entire (downscaled) chunk. */
+ typedef NOISE_DATATYPE ChunkParam[5 * 5];
+
+
+ /** The noise that is used to choose between density noise A and B. */
+ cPerlinNoise m_ChoiceNoise;
+
+ /** Density 3D noise, variant A. */
+ cPerlinNoise m_DensityNoiseA;
+
+ /** Density 3D noise, variant B. */
+ cPerlinNoise m_DensityNoiseB;
+
+ /** Heightmap-like noise used to provide variance for low-amplitude biomes. */
+ cPerlinNoise m_BaseNoise;
+
+ /** The underlying biome generator. */
+ cBiomeGenPtr m_BiomeGen;
+
+ /** Block height of the sealevel, used for composing the terrain. */
+ int m_SeaLevel;
+
+ // Frequency of the 3D noise's first octave:
+ NOISE_DATATYPE m_FrequencyX;
+ NOISE_DATATYPE m_FrequencyY;
+ NOISE_DATATYPE m_FrequencyZ;
+
+ // Frequency of the base terrain noise:
+ NOISE_DATATYPE m_BaseFrequencyX;
+ NOISE_DATATYPE m_BaseFrequencyZ;
+
+ // Frequency of the choice noise:
+ NOISE_DATATYPE m_ChoiceFrequencyX;
+ NOISE_DATATYPE m_ChoiceFrequencyY;
+ NOISE_DATATYPE m_ChoiceFrequencyZ;
+
+ // Threshold for when the values are considered air:
+ NOISE_DATATYPE m_AirThreshold;
+
+ // Cache for the last calculated chunk (reused between heightmap and composition queries):
+ int m_LastChunkX;
+ int m_LastChunkZ;
+ NOISE_DATATYPE m_NoiseArray[17 * 17 * 257]; // x + 17 * z + 17 * 17 * y
+
+ /** Weights for summing up neighboring biomes. */
+ NOISE_DATATYPE m_Weight[AVERAGING_SIZE * 2 + 1][AVERAGING_SIZE * 2 + 1];
+
+ /** The sum of m_Weight[]. */
+ NOISE_DATATYPE m_WeightSum;
+
+
+ /** Generates the 3D noise array used for terrain generation (m_NoiseArray), unless the LastChunk coords are equal to coords given */
+ void GenerateNoiseArrayIfNeeded(int a_ChunkX, int a_ChunkZ);
+
+ /** Calculates the biome-related parameters for the chunk. */
+ void CalcBiomeParamArrays(int a_ChunkX, int a_ChunkZ, ChunkParam & a_HeightAmp, ChunkParam & a_MidPoint);
+
+ /** Returns the parameters for the specified biome. */
+ void GetBiomeParams(EMCSBiome a_Biome, NOISE_DATATYPE & a_HeightAmp, NOISE_DATATYPE & a_MidPoint);
+
+ // cTerrainHeightGen overrides:
+ virtual void GenHeightMap(int a_ChunkX, int a_ChunkZ, cChunkDef::HeightMap & a_HeightMap) override;
+ virtual void InitializeHeightGen(cIniFile & a_IniFile) override { Initialize(a_IniFile); }
// cTerrainCompositionGen overrides:
virtual void ComposeTerrain(cChunkDesc & a_ChunkDesc) override;
+ virtual void InitializeCompoGen(cIniFile & a_IniFile) override { Initialize(a_IniFile); }
} ;
diff --git a/src/Generating/ProtIntGen.h b/src/Generating/ProtIntGen.h
new file mode 100644
index 000000000..73ed27096
--- /dev/null
+++ b/src/Generating/ProtIntGen.h
@@ -0,0 +1,1351 @@
+
+// ProtIntGen.h
+
+// Declares the prototyping integer generators - cProtIntGen class and its descendants
+
+/*
+These classes generate 2D arrays of integers that have various interpretations. The main purpose of these
+classes is to provide fast prototyping for cIntGen classes - unlike cIntGen classes, these are not
+template-based and so they take care of the underlying sizes automatically. This makes them easier to chain
+and re-chain, since the size parameters don't need to be adjusted after each such case. Their performance is,
+however, slightly worse, which is why we use cIntGen classes in the final generator.
+
+Because there is no SizeX / SizeZ template param, the generators would have to either alloc memory for each
+underlying generator's values, or use a maximum-size buffer. We chose the latter, to avoid memory allocation
+overhead; this however means that there's (an arbitrary) limit to the size of the generated data.
+*/
+
+
+
+
+
+#pragma once
+
+// We need the biome group constants defined there:
+#include "IntGen.h"
+
+
+
+
+
+/** Interface that all the generator classes provide. */
+class cProtIntGen
+{
+protected:
+ /** Maximum size of the generated area.
+ Adjust the constant if you need larger areas, these are just so that we can use fixed-size buffers. */
+ static const int m_BufferSize = 900;
+
+public:
+
+ /** Type of the generic interface used for storing links to the underlying generators. */
+ typedef std::shared_ptr<cProtIntGen> Underlying;
+
+
+ /** Force a virtual destructor in all descendants.
+ Descendants contain virtual functions and are referred to via pointer-to-base, so they need a virtual destructor. */
+ virtual ~cProtIntGen() {}
+
+ /** Generates the array of specified size into a_Values, based on given min coords. */
+ virtual void GetInts(int a_MinX, int a_MinZ, int a_SizeX, int a_SizeZ, int * a_Values) = 0;
+};
+
+
+
+
+
+/** Provides additional cNoise member and its helper functions. */
+class cProtIntGenWithNoise :
+ public cProtIntGen
+{
+ typedef cProtIntGen super;
+
+public:
+ cProtIntGenWithNoise(int a_Seed) :
+ m_Noise(a_Seed)
+ {
+ }
+
+protected:
+ cNoise m_Noise;
+
+ /** Chooses one of a_Val1 or a_Val2, based on m_Noise and the coordinates for querying the noise. */
+ int chooseRandomOne(int a_RndX, int a_RndZ, int a_Val1, int a_Val2)
+ {
+ int rnd = m_Noise.IntNoise2DInt(a_RndX, a_RndZ) / 7;
+ return ((rnd & 1) == 0) ? a_Val1 : a_Val2;
+ }
+
+ /** Chooses one of a_ValN, based on m_Noise and the coordinates for querying the noise. */
+ int chooseRandomOne(int a_RndX, int a_RndZ, int a_Val1, int a_Val2, int a_Val3, int a_Val4)
+ {
+ int rnd = m_Noise.IntNoise2DInt(a_RndX, a_RndZ) / 7;
+ switch (rnd % 4)
+ {
+ case 0: return a_Val1;
+ case 1: return a_Val2;
+ case 2: return a_Val3;
+ default: return a_Val4;
+ }
+ }
+};
+
+
+
+
+
+
+/** Generates a 2D array of random integers in the specified range [0 .. Range). */
+class cProtIntGenChoice :
+ public cProtIntGenWithNoise
+{
+ typedef cProtIntGenWithNoise super;
+
+public:
+ cProtIntGenChoice(int a_Seed, int a_Range) :
+ super(a_Seed),
+ m_Range(a_Range)
+ {
+ }
+
+
+ virtual void GetInts(int a_MinX, int a_MinZ, int a_SizeX, int a_SizeZ, int * a_Values) override
+ {
+ for (int z = 0; z < a_SizeZ; z++)
+ {
+ int BaseZ = a_MinZ + z;
+ for (int x = 0; x < a_SizeX; x++)
+ {
+ a_Values[x + a_SizeX * z] = (super::m_Noise.IntNoise2DInt(a_MinX + x, BaseZ) / 7) % m_Range;
+ }
+ } // for z
+ }
+
+protected:
+ int m_Range;
+};
+
+
+
+
+
+
+/** Decides between the ocean and landmass biomes.
+Has a threshold (in percent) of how much land, the larger the threshold, the more land.
+Generates 0 for ocean, biome group ID for landmass. */
+class cProtIntGenLandOcean :
+ public cProtIntGenWithNoise
+{
+ typedef cProtIntGenWithNoise super;
+
+public:
+ cProtIntGenLandOcean(int a_Seed, int a_Threshold) :
+ super(a_Seed),
+ m_Threshold(a_Threshold)
+ {
+ }
+
+
+ virtual void GetInts(int a_MinX, int a_MinZ, int a_SizeX, int a_SizeZ, int * a_Values) override
+ {
+ for (int z = 0; z < a_SizeZ; z++)
+ {
+ int BaseZ = a_MinZ + z;
+ for (int x = 0; x < a_SizeX; x++)
+ {
+ int rnd = (super::m_Noise.IntNoise2DInt(a_MinX + x, BaseZ) / 7);
+ a_Values[x + a_SizeX * z] = ((rnd % 100) < m_Threshold) ? ((rnd / 101) % bgLandOceanMax + 1) : 0;
+ }
+ }
+
+ // If the centerpoint of the world is within the area, set it to bgTemperate, always:
+ if ((a_MinX <= 0) && (a_MinZ <= 0) && (a_MinX + a_SizeX > 0) && (a_MinZ + a_SizeZ > 0))
+ {
+ a_Values[-a_MinX - a_MinZ * a_SizeX] = bgTemperate;
+ }
+ }
+
+protected:
+ int m_Threshold;
+};
+
+
+
+
+
+/** Zooms the underlying value array to twice the size. Uses random-neighbor for the pixels in-between.
+This means that the zoome out image is randomly distorted. Applying zoom several times provides all
+the distortion that the generators need. */
+class cProtIntGenZoom :
+ public cProtIntGenWithNoise
+{
+ typedef cProtIntGenWithNoise super;
+
+public:
+ cProtIntGenZoom(int a_Seed, Underlying a_UnderlyingGen) :
+ super(a_Seed),
+ m_UnderlyingGen(a_UnderlyingGen)
+ {
+ }
+
+
+ virtual void GetInts(int a_MinX, int a_MinZ, int a_SizeX, int a_SizeZ, int * a_Values) override
+ {
+ // Get the coords for the lower generator:
+ int lowerMinX = a_MinX >> 1;
+ int lowerMinZ = a_MinZ >> 1;
+ int lowerSizeX = a_SizeX / 2 + 2;
+ int lowerSizeZ = a_SizeZ / 2 + 2;
+ ASSERT(lowerSizeX * lowerSizeZ <= m_BufferSize);
+ ASSERT(lowerSizeX > 0);
+ ASSERT(lowerSizeZ > 0);
+
+ // Generate the underlying data with half the resolution:
+ int lowerData[m_BufferSize];
+ m_UnderlyingGen->GetInts(lowerMinX, lowerMinZ, lowerSizeX, lowerSizeZ, lowerData);
+ const int lowStepX = (lowerSizeX - 1) * 2;
+ int cache[m_BufferSize];
+
+ // Discreet-interpolate the values into twice the size:
+ for (int z = 0; z < lowerSizeZ - 1; ++z)
+ {
+ int idx = (z * 2) * lowStepX;
+ int PrevZ0 = lowerData[z * lowerSizeX];
+ int PrevZ1 = lowerData[(z + 1) * lowerSizeX];
+
+ for (int x = 0; x < lowerSizeX - 1; ++x)
+ {
+ int ValX1Z0 = lowerData[x + 1 + z * lowerSizeX];
+ int ValX1Z1 = lowerData[x + 1 + (z + 1) * lowerSizeX];
+ int RndX = (x + lowerMinX) * 2;
+ int RndZ = (z + lowerMinZ) * 2;
+ cache[idx] = PrevZ0;
+ cache[idx + lowStepX] = super::chooseRandomOne(RndX, RndZ + 1, PrevZ0, PrevZ1);
+ cache[idx + 1] = super::chooseRandomOne(RndX, RndZ - 1, PrevZ0, ValX1Z0);
+ cache[idx + 1 + lowStepX] = super::chooseRandomOne(RndX, RndZ, PrevZ0, ValX1Z0, PrevZ1, ValX1Z1);
+ idx += 2;
+ PrevZ0 = ValX1Z0;
+ PrevZ1 = ValX1Z1;
+ }
+ }
+
+ // Copy from Cache into a_Values; take into account the even/odd offsets in a_Min:
+ for (int z = 0; z < a_SizeZ; ++z)
+ {
+ memcpy(a_Values + z * a_SizeX, cache + (z + (a_MinZ & 1)) * lowStepX + (a_MinX & 1), a_SizeX * sizeof(int));
+ }
+ }
+
+protected:
+ Underlying m_UnderlyingGen;
+};
+
+
+
+
+
+/** Smoothes out some artifacts generated by the zooming - mostly single-pixel values.
+Compares each pixel to its neighbors and if the neighbors are equal, changes the pixel to their value. */
+class cProtIntGenSmooth :
+ public cProtIntGenWithNoise
+{
+ typedef cProtIntGenWithNoise super;
+
+public:
+ cProtIntGenSmooth(int a_Seed, Underlying a_Underlying) :
+ super(a_Seed),
+ m_Underlying(a_Underlying)
+ {
+ }
+
+
+ virtual void GetInts(int a_MinX, int a_MinZ, int a_SizeX, int a_SizeZ, int * a_Values) override
+ {
+ // Generate the underlying values:
+ int lowerSizeX = a_SizeX + 2;
+ int lowerSizeZ = a_SizeZ + 2;
+ ASSERT(lowerSizeX * lowerSizeZ <= m_BufferSize);
+ int lowerData[m_BufferSize];
+ m_Underlying->GetInts(a_MinX - 1, a_MinZ - 1, lowerSizeX, lowerSizeZ, lowerData);
+
+ // Smooth - for each square check if the surroundings are the same, if so, expand them diagonally.
+ // Also get rid of single-pixel irregularities (A-B-A):
+ for (int z = 0; z < a_SizeZ; z++)
+ {
+ int NoiseZ = a_MinZ + z;
+ for (int x = 0; x < a_SizeX; x++)
+ {
+ int val = lowerData[x + 1 + (z + 1) * lowerSizeX];
+ int above = lowerData[x + 1 + z * lowerSizeX];
+ int below = lowerData[x + 1 + (z + 2) * lowerSizeX];
+ int left = lowerData[x + (z + 1) * lowerSizeX];
+ int right = lowerData[x + 2 + (z + 1) * lowerSizeX];
+
+ if ((left == right) && (above == below))
+ {
+ if (((super::m_Noise.IntNoise2DInt(a_MinX + x, NoiseZ) / 7) % 2) == 0)
+ {
+ val = left;
+ }
+ else
+ {
+ val = above;
+ }
+ }
+ else
+ {
+ if (left == right)
+ {
+ val = left;
+ }
+
+ if (above == below)
+ {
+ val = above;
+ }
+ }
+
+ a_Values[x + z * a_SizeX] = val;
+ }
+ }
+ }
+
+protected:
+ Underlying m_Underlying;
+};
+
+
+
+
+
+/** Converts land biomes at the edge of an ocean into the respective beach biome. */
+class cProtIntGenBeaches :
+ public cProtIntGen
+{
+ typedef cProtIntGen super;
+
+public:
+ cProtIntGenBeaches(Underlying a_Underlying) :
+ m_Underlying(a_Underlying)
+ {
+ }
+
+
+ virtual void GetInts(int a_MinX, int a_MinZ, int a_SizeX, int a_SizeZ, int * a_Values) override
+ {
+ // Map for biome -> its beach:
+ static const int ToBeach[] =
+ {
+ /* biOcean */ biOcean,
+ /* biPlains */ biBeach,
+ /* biDesert */ biBeach,
+ /* biExtremeHills */ biStoneBeach,
+ /* biForest */ biBeach,
+ /* biTaiga */ biColdBeach,
+ /* biSwampland */ biSwampland,
+ /* biRiver */ biRiver,
+ /* biNether */ biNether,
+ /* biEnd */ biEnd,
+ /* biFrozenOcean */ biColdBeach,
+ /* biFrozenRiver */ biColdBeach,
+ /* biIcePlains */ biColdBeach,
+ /* biIceMountains */ biColdBeach,
+ /* biMushroomIsland */ biMushroomShore,
+ /* biMushroomShore */ biMushroomShore,
+ /* biBeach */ biBeach,
+ /* biDesertHills */ biBeach,
+ /* biForestHills */ biBeach,
+ /* biTaigaHills */ biColdBeach,
+ /* biExtremeHillsEdge */ biStoneBeach,
+ /* biJungle */ biBeach,
+ /* biJungleHills */ biBeach,
+ /* biJungleEdge */ biBeach,
+ /* biDeepOcean */ biOcean,
+ /* biStoneBeach */ biStoneBeach,
+ /* biColdBeach */ biColdBeach,
+ /* biBirchForest */ biBeach,
+ /* biBirchForestHills */ biBeach,
+ /* biRoofedForest */ biBeach,
+ /* biColdTaiga */ biColdBeach,
+ /* biColdTaigaHills */ biColdBeach,
+ /* biMegaTaiga */ biStoneBeach,
+ /* biMegaTaigaHills */ biStoneBeach,
+ /* biExtremeHillsPlus */ biStoneBeach,
+ /* biSavanna */ biBeach,
+ /* biSavannaPlateau */ biBeach,
+ /* biMesa */ biMesa,
+ /* biMesaPlateauF */ biMesa,
+ /* biMesaPlateau */ biMesa,
+ };
+
+ // Generate the underlying values:
+ int lowerSizeX = a_SizeX + 2;
+ int lowerSizeZ = a_SizeZ + 2;
+ ASSERT(lowerSizeX * lowerSizeZ <= m_BufferSize);
+ int lowerValues[m_BufferSize];
+ m_Underlying->GetInts(a_MinX - 1, a_MinZ - 1, lowerSizeX, lowerSizeZ, lowerValues);
+
+ // Add beaches between ocean and biomes:
+ for (int z = 0; z < a_SizeZ; z++)
+ {
+ for (int x = 0; x < a_SizeX; x++)
+ {
+ int val = lowerValues[x + 1 + (z + 1) * lowerSizeX];
+ int above = lowerValues[x + 1 + z * lowerSizeX];
+ int below = lowerValues[x + 1 + (z + 2) * lowerSizeX];
+ int left = lowerValues[x + (z + 1) * lowerSizeX];
+ int right = lowerValues[x + 2 + (z + 1) * lowerSizeX];
+ if (!IsBiomeOcean(val))
+ {
+ if (IsBiomeOcean(above) || IsBiomeOcean(below) || IsBiomeOcean(left) || IsBiomeOcean(right))
+ {
+ // First convert the value to a regular biome (drop the M flag), then modulo by our biome count:
+ val = ToBeach[(val % 128) % ARRAYCOUNT(ToBeach)];
+ }
+ }
+ a_Values[x + z * a_SizeX] = val;
+ }
+ }
+ }
+
+protected:
+ Underlying m_Underlying;
+};
+
+
+
+
+
+/** Generates the underlying numbers and then randomly changes some ocean group pixels into random land
+biome group pixels, based on the predefined chance. */
+class cProtIntGenAddIslands :
+ public cProtIntGenWithNoise
+{
+ typedef cProtIntGenWithNoise super;
+
+public:
+ typedef std::shared_ptr<cProtIntGen> Underlying;
+
+
+ cProtIntGenAddIslands(int a_Seed, int a_Chance, Underlying a_Underlying) :
+ super(a_Seed),
+ m_Chance(a_Chance),
+ m_Underlying(a_Underlying)
+ {
+ }
+
+
+ virtual void GetInts(int a_MinX, int a_MinZ, int a_SizeX, int a_SizeZ, int * a_Values) override
+ {
+ m_Underlying->GetInts(a_MinX, a_MinZ, a_SizeX, a_SizeZ, a_Values);
+ for (int z = 0; z < a_SizeZ; z++)
+ {
+ for (int x = 0; x < a_SizeX; x++)
+ {
+ if (a_Values[x + z * a_SizeX] == bgOcean)
+ {
+ int rnd = super::m_Noise.IntNoise2DInt(a_MinX + x, a_MinZ + z) / 7;
+ if (rnd % 1000 < m_Chance)
+ {
+ a_Values[x + z * a_SizeX] = (rnd / 1003) % bgLandOceanMax;
+ }
+ }
+ }
+ }
+ }
+
+protected:
+ /** Chance of each ocean pixel being converted, in permille. */
+ int m_Chance;
+
+ Underlying m_Underlying;
+};
+
+
+
+
+
+/** A filter that adds an edge biome group between two biome groups that need an edge between them. */
+class cProtIntGenBiomeGroupEdges :
+ public cProtIntGen
+{
+ typedef cProtIntGen super;
+
+public:
+ cProtIntGenBiomeGroupEdges(Underlying a_Underlying) :
+ m_Underlying(a_Underlying)
+ {
+ }
+
+
+ virtual void GetInts(int a_MinX, int a_MinZ, int a_SizeX, int a_SizeZ, int * a_Values)
+ {
+ // Generate the underlying biome groups:
+ int lowerSizeX = a_SizeX + 2;
+ int lowerSizeZ = a_SizeZ + 2;
+ ASSERT(lowerSizeX * lowerSizeZ <= m_BufferSize);
+ int lowerValues[m_BufferSize];
+ m_Underlying->GetInts(a_MinX, a_MinZ, lowerSizeX, lowerSizeZ, lowerValues);
+
+ // Change the biomes on incompatible edges into an edge biome:
+ for (int z = 0; z < a_SizeZ; z++)
+ {
+ for (int x = 0; x < a_SizeX; x++)
+ {
+ int val = lowerValues[x + 1 + (z + 1) * lowerSizeX];
+ int Above = lowerValues[x + 1 + z * lowerSizeX];
+ int Below = lowerValues[x + 1 + (z + 2) * lowerSizeX];
+ int Left = lowerValues[x + (z + 1) * lowerSizeX];
+ int Right = lowerValues[x + 2 + (z + 1) * lowerSizeX];
+ switch (val)
+ {
+ // Desert should neighbor only oceans, desert and temperates; change to temperate when another:
+ case bgDesert:
+ {
+ if (
+ !isDesertCompatible(Above) ||
+ !isDesertCompatible(Below) ||
+ !isDesertCompatible(Left) ||
+ !isDesertCompatible(Right)
+ )
+ {
+ val = bgTemperate;
+ }
+ break;
+ } // case bgDesert
+
+ // Ice should not neighbor deserts; change to temperate:
+ case bgIce:
+ {
+ if (
+ (Above == bgDesert) ||
+ (Below == bgDesert) ||
+ (Left == bgDesert) ||
+ (Right == bgDesert)
+ )
+ {
+ val = bgTemperate;
+ }
+ break;
+ } // case bgIce
+ }
+ a_Values[x + z * a_SizeX] = val;
+ } // for x
+ } // for z
+ }
+
+protected:
+ Underlying m_Underlying;
+
+
+ inline bool isDesertCompatible(int a_BiomeGroup)
+ {
+ switch (a_BiomeGroup)
+ {
+ case bgOcean:
+ case bgDesert:
+ case bgTemperate:
+ {
+ return true;
+ }
+ default:
+ {
+ return false;
+ }
+ }
+ }
+};
+
+
+
+
+
+/** Turns biome group indices into real biomes.
+For each pixel, takes its biome group and chooses a random biome from that group; replaces the value with
+that biome. */
+class cProtIntGenBiomes :
+ public cProtIntGenWithNoise
+{
+ typedef cProtIntGenWithNoise super;
+
+public:
+ cProtIntGenBiomes(int a_Seed, Underlying a_Underlying) :
+ super(a_Seed),
+ m_Underlying(a_Underlying)
+ {
+ }
+
+
+ virtual void GetInts(int a_MinX, int a_MinZ, int a_SizeX, int a_SizeZ, int * a_Values) override
+ {
+ // Define the per-biome-group biomes:
+ static const int oceanBiomes[] =
+ {
+ biOcean, // biDeepOcean,
+ };
+
+ // Same as oceanBiomes, there are no rare oceanic biomes (mushroom islands are handled separately)
+ static const int rareOceanBiomes[] =
+ {
+ biOcean,
+ };
+
+ static const int desertBiomes[] =
+ {
+ biDesert, biDesert, biDesert, biDesert, biDesert, biDesert, biSavanna, biSavanna, biPlains,
+ };
+
+ static const int rareDesertBiomes[] =
+ {
+ biMesaPlateau, biMesaPlateauF,
+ };
+
+ static const int temperateBiomes[] =
+ {
+ biForest, biForest, biRoofedForest, biExtremeHills, biPlains, biBirchForest, biSwampland,
+ };
+
+ static const int rareTemperateBiomes[] =
+ {
+ biJungle, // Jungle is not strictly temperate, but let's piggyback it here
+ };
+
+ static const int mountainBiomes[] =
+ {
+ biExtremeHills, biForest, biTaiga, biPlains,
+ };
+
+ static const int rareMountainBiomes[] =
+ {
+ biMegaTaiga,
+ };
+
+ static const int iceBiomes[] =
+ {
+ biIcePlains, biIcePlains, biIcePlains, biIcePlains, biColdTaiga,
+ };
+
+ // Same as iceBiomes, there's no rare ice biome
+ static const int rareIceBiomes[] =
+ {
+ biIcePlains, biIcePlains, biIcePlains, biIcePlains, biColdTaiga,
+ };
+
+ static const cBiomesInGroups biomesInGroups[] =
+ {
+ /* bgOcean */ { static_cast<int>(ARRAYCOUNT(oceanBiomes)), oceanBiomes},
+ /* bgDesert */ { static_cast<int>(ARRAYCOUNT(desertBiomes)), desertBiomes},
+ /* bgTemperate */ { static_cast<int>(ARRAYCOUNT(temperateBiomes)), temperateBiomes},
+ /* bgMountains */ { static_cast<int>(ARRAYCOUNT(mountainBiomes)), mountainBiomes},
+ /* bgIce */ { static_cast<int>(ARRAYCOUNT(iceBiomes)), iceBiomes},
+ };
+
+ static const cBiomesInGroups rareBiomesInGroups[] =
+ {
+ /* bgOcean */ { static_cast<int>(ARRAYCOUNT(rareOceanBiomes)), rareOceanBiomes},
+ /* bgDesert */ { static_cast<int>(ARRAYCOUNT(rareDesertBiomes)), rareDesertBiomes},
+ /* bgTemperate */ { static_cast<int>(ARRAYCOUNT(rareTemperateBiomes)), rareTemperateBiomes},
+ /* bgMountains */ { static_cast<int>(ARRAYCOUNT(rareMountainBiomes)), rareMountainBiomes},
+ /* bgIce */ { static_cast<int>(ARRAYCOUNT(rareIceBiomes)), rareIceBiomes},
+ };
+
+ // Generate the underlying values, representing biome groups:
+ m_Underlying->GetInts(a_MinX, a_MinZ, a_SizeX, a_SizeZ, a_Values);
+
+ // Overwrite each biome group with a random biome from that group:
+ // Take care of the bgfRare flag
+ for (int z = 0; z < a_SizeZ; z++)
+ {
+ int IdxZ = z * a_SizeX;
+ for (int x = 0; x < a_SizeX; x++)
+ {
+ int val = a_Values[x + IdxZ];
+ const cBiomesInGroups & Biomes = (val > bgfRare) ?
+ rareBiomesInGroups[(val & (bgfRare - 1)) % ARRAYCOUNT(rareBiomesInGroups)] :
+ biomesInGroups[val % ARRAYCOUNT(biomesInGroups)];
+ int rnd = (super::m_Noise.IntNoise2DInt(x + a_MinX, z + a_MinZ) / 7);
+ a_Values[x + IdxZ] = Biomes.Biomes[rnd % Biomes.Count];
+ }
+ }
+ }
+
+protected:
+
+ struct cBiomesInGroups
+ {
+ const int Count;
+ const int * Biomes;
+ };
+
+
+ /** The underlying int generator */
+ Underlying m_Underlying;
+};
+
+
+
+
+
+/** Randomly replaces pixels of one value to another value, using the given chance. */
+class cProtIntGenReplaceRandomly :
+ public cProtIntGenWithNoise
+{
+ typedef cProtIntGenWithNoise super;
+
+public:
+ typedef std::shared_ptr<cProtIntGen> Underlying;
+
+
+ cProtIntGenReplaceRandomly(int a_Seed, int a_From, int a_To, int a_Chance, Underlying a_Underlying) :
+ super(a_Seed),
+ m_From(a_From),
+ m_To(a_To),
+ m_Chance(a_Chance),
+ m_Underlying(a_Underlying)
+ {
+ }
+
+
+ virtual void GetInts(int a_MinX, int a_MinZ, int a_SizeX, int a_SizeZ, int * a_Values) override
+ {
+ // Generate the underlying values:
+ m_Underlying->GetInts(a_MinX, a_MinZ, a_SizeX, a_SizeZ, a_Values);
+
+ // Replace some of the values:
+ for (int z = 0; z < a_SizeZ; z++)
+ {
+ int idxZ = z * a_SizeX;
+ for (int x = 0; x < a_SizeX; x++)
+ {
+ int idx = x + idxZ;
+ if (a_Values[idx] == m_From)
+ {
+ int rnd = super::m_Noise.IntNoise2DInt(x + a_MinX, z + a_MinZ) / 7;
+ if (rnd % 1000 < m_Chance)
+ {
+ a_Values[idx] = m_To;
+ }
+ }
+ }
+ } // for z
+ }
+
+
+protected:
+ /** The original value to be replaced. */
+ int m_From;
+
+ /** The destination value to which to replace. */
+ int m_To;
+
+ /** Chance, in permille, of replacing the value. */
+ int m_Chance;
+
+ Underlying m_Underlying;
+};
+
+
+
+
+
+/** Mixer that joins together finalized biomes and rivers.
+It first checks for oceans, if there is an ocean in the Biomes, it keeps the ocean.
+If there's no ocean, it checks Rivers for a river, if there is a river, it uses the Biomes to select either
+regular river or frozen river, based on the biome. */
+class cProtIntGenMixRivers:
+ public cProtIntGen
+{
+ typedef cProtIntGen super;
+
+public:
+ cProtIntGenMixRivers(Underlying a_Biomes, Underlying a_Rivers):
+ m_Biomes(a_Biomes),
+ m_Rivers(a_Rivers)
+ {
+ }
+
+
+ virtual void GetInts(int a_MinX, int a_MinZ, int a_SizeX, int a_SizeZ, int * a_Values) override
+ {
+ // Generate the underlying data:
+ ASSERT(a_SizeX * a_SizeZ <= m_BufferSize);
+ m_Biomes->GetInts(a_MinX, a_MinZ, a_SizeX, a_SizeZ, a_Values);
+ int riverData[m_BufferSize];
+ m_Rivers->GetInts(a_MinX, a_MinZ, a_SizeX, a_SizeZ, riverData);
+
+ // Mix the values:
+ for (int z = 0; z < a_SizeZ; z++)
+ {
+ int idxZ = z * a_SizeX;
+ for (int x = 0; x < a_SizeX; x++)
+ {
+ int idx = x + idxZ;
+ if (IsBiomeOcean(a_Values[idx]))
+ {
+ // Oceans are kept without any changes
+ continue;
+ }
+ if (riverData[idx] != biRiver)
+ {
+ // There's no river, keep the current value
+ continue;
+ }
+
+ // There's a river, change the output to a river or a frozen river, based on the original biome:
+ if (IsBiomeVeryCold((EMCSBiome)a_Values[idx]))
+ {
+ a_Values[idx] = biFrozenRiver;
+ }
+ else
+ {
+ a_Values[idx] = biRiver;
+ }
+ } // for x
+ } // for z
+ }
+
+protected:
+ Underlying m_Biomes;
+ Underlying m_Rivers;
+};
+
+
+
+
+
+/** Generates a river based on the underlying data.
+This is basically an edge detector over the underlying data. The rivers are the edges where the underlying
+data changes from one pixel to its neighbor. */
+class cProtIntGenRiver:
+ public cProtIntGenWithNoise
+{
+ typedef cProtIntGenWithNoise super;
+
+public:
+ cProtIntGenRiver(int a_Seed, Underlying a_Underlying):
+ super(a_Seed),
+ m_Underlying(a_Underlying)
+ {
+ }
+
+
+ virtual void GetInts(int a_MinX, int a_MinZ, int a_SizeX, int a_SizeZ, int * a_Values) override
+ {
+ // Generate the underlying data:
+ int lowerSizeX = a_SizeX + 2;
+ int lowerSizeZ = a_SizeZ + 2;
+ ASSERT(lowerSizeX * lowerSizeZ <= m_BufferSize);
+ int lowerValues[m_BufferSize];
+ m_Underlying->GetInts(a_MinX - 1, a_MinZ - 1, lowerSizeX, lowerSizeZ, lowerValues);
+
+ // Detect the edges:
+ for (int z = 0; z < a_SizeZ; z++)
+ {
+ for (int x = 0; x < a_SizeX; x++)
+ {
+ int Above = lowerValues[x + 1 + z * lowerSizeX];
+ int Below = lowerValues[x + 1 + (z + 2) * lowerSizeX];
+ int Left = lowerValues[x + (z + 1) * lowerSizeX];
+ int Right = lowerValues[x + 2 + (z + 1) * lowerSizeX];
+ int val = lowerValues[x + 1 + (z + 1) * lowerSizeX];
+
+ if ((val == Above) && (val == Below) && (val == Left) && (val == Right))
+ {
+ val = 0;
+ }
+ else
+ {
+ val = biRiver;
+ }
+ a_Values[x + z * a_SizeX] = val;
+ } // for x
+ } // for z
+ }
+
+protected:
+ Underlying m_Underlying;
+};
+
+
+
+
+
+/** Turns some of the oceans into the specified biome. Used for mushroom and deep ocean.
+The biome is only placed if at least 3 of its neighbors are ocean and only with the specified chance. */
+class cProtIntGenAddToOcean:
+ public cProtIntGenWithNoise
+{
+ typedef cProtIntGenWithNoise super;
+
+public:
+ cProtIntGenAddToOcean(int a_Seed, int a_Chance, int a_ToValue, Underlying a_Underlying):
+ super(a_Seed),
+ m_Chance(a_Chance),
+ m_ToValue(a_ToValue),
+ m_Underlying(a_Underlying)
+ {
+ }
+
+
+ virtual void GetInts(int a_MinX, int a_MinZ, int a_SizeX, int a_SizeZ, int * a_Values) override
+ {
+ // Generate the underlying data:
+ int lowerSizeX = a_SizeX + 2;
+ int lowerSizeZ = a_SizeZ + 2;
+ ASSERT(lowerSizeX * lowerSizeZ <= m_BufferSize);
+ int lowerValues[m_BufferSize];
+ m_Underlying->GetInts(a_MinX - 1, a_MinZ - 1, lowerSizeX, lowerSizeZ, lowerValues);
+
+ // Add the mushroom islands:
+ for (int z = 0; z < a_SizeZ; z++)
+ {
+ for (int x = 0; x < a_SizeX; x++)
+ {
+ int val = lowerValues[x + 1 + (z + 1) * lowerSizeX];
+ if (!IsBiomeOcean(val))
+ {
+ a_Values[x + z * a_SizeX] = val;
+ continue;
+ }
+
+ // Count the ocean neighbors:
+ int Above = lowerValues[x + 1 + z * lowerSizeX];
+ int Below = lowerValues[x + 1 + (z + 2) * lowerSizeX];
+ int Left = lowerValues[x + (z + 1) * lowerSizeX];
+ int Right = lowerValues[x + 2 + (z + 1) * lowerSizeX];
+ int NumOceanNeighbors = 0;
+ if (IsBiomeOcean(Above))
+ {
+ NumOceanNeighbors += 1;
+ }
+ if (IsBiomeOcean(Below))
+ {
+ NumOceanNeighbors += 1;
+ }
+ if (IsBiomeOcean(Left))
+ {
+ NumOceanNeighbors += 1;
+ }
+ if (IsBiomeOcean(Right))
+ {
+ NumOceanNeighbors += 1;
+ }
+
+ // If at least 3 ocean neighbors and the chance is right, change:
+ if (
+ (NumOceanNeighbors >= 3) &&
+ ((super::m_Noise.IntNoise2DInt(x + a_MinX, z + a_MinZ) / 7) % 1000 < m_Chance)
+ )
+ {
+ a_Values[x + z * a_SizeX] = m_ToValue;
+ }
+ else
+ {
+ a_Values[x + z * a_SizeX] = val;
+ }
+ } // for x
+ } // for z
+ }
+
+protected:
+ /** Chance, in permille, of changing the biome. */
+ int m_Chance;
+
+ /** The value to change the ocean into. */
+ int m_ToValue;
+
+ Underlying m_Underlying;
+};
+
+
+
+
+
+/** Changes random pixels of the underlying data to the specified value. */
+class cProtIntGenSetRandomly :
+ public cProtIntGenWithNoise
+{
+ typedef cProtIntGenWithNoise super;
+
+public:
+ cProtIntGenSetRandomly(int a_Seed, int a_Chance, int a_ToValue, Underlying a_Underlying) :
+ super(a_Seed),
+ m_Chance(a_Chance),
+ m_ToValue(a_ToValue),
+ m_Underlying(a_Underlying)
+ {
+ }
+
+
+ virtual void GetInts(int a_MinX, int a_MinZ, int a_SizeX, int a_SizeZ, int * a_Values) override
+ {
+ // Generate the underlying data:
+ m_Underlying->GetInts(a_MinX, a_MinZ, a_SizeX, a_SizeZ, a_Values);
+
+ // Change random pixels to bgOcean:
+ for (int z = 0; z < a_SizeZ; z++)
+ {
+ for (int x = 0; x < a_SizeX; x++)
+ {
+ int rnd = super::m_Noise.IntNoise2DInt(x + a_MinX, z + a_MinZ) / 7;
+ if (rnd % 1000 < m_Chance)
+ {
+ a_Values[x + z * a_SizeX] = m_ToValue;
+ }
+ }
+ }
+ }
+
+protected:
+ /** Chance, in permille, of changing each pixel. */
+ int m_Chance;
+
+ /** The value to which to set the pixel. */
+ int m_ToValue;
+
+ Underlying m_Underlying;
+};
+
+
+
+
+
+
+/** Adds a "rare" flag to random biome groups, based on the given chance. */
+class cProtIntGenRareBiomeGroups:
+ public cProtIntGenWithNoise
+{
+ typedef cProtIntGenWithNoise super;
+
+public:
+ cProtIntGenRareBiomeGroups(int a_Seed, int a_Chance, Underlying a_Underlying):
+ super(a_Seed),
+ m_Chance(a_Chance),
+ m_Underlying(a_Underlying)
+ {
+ }
+
+
+ virtual void GetInts(int a_MinX, int a_MinZ, int a_SizeX, int a_SizeZ, int * a_Values) override
+ {
+ // Generate the underlying data:
+ m_Underlying->GetInts(a_MinX, a_MinZ, a_SizeX, a_SizeZ, a_Values);
+
+ // Change some of the biome groups into rare biome groups:
+ for (int z = 0; z < a_SizeZ; z++)
+ {
+ for (int x = 0; x < a_SizeX; x++)
+ {
+ int rnd = super::m_Noise.IntNoise2DInt(x + a_MinX, z + a_MinZ) / 7;
+ if (rnd % 1000 < m_Chance)
+ {
+ int idx = x + a_SizeX * z;
+ a_Values[idx] = a_Values[idx] | bgfRare;
+ }
+ }
+ }
+ }
+
+protected:
+ /** Chance, in permille, of changing each pixel into the rare biome group. */
+ int m_Chance;
+
+ /** The underlying generator. */
+ Underlying m_Underlying;
+};
+
+
+
+
+
+/** Changes biomes in the parent data into an alternate versions (usually "hill" variants), in such places
+that have their alterations set. */
+class cProtIntGenAlternateBiomes:
+ public cProtIntGenWithNoise
+{
+ typedef cProtIntGenWithNoise super;
+
+public:
+ cProtIntGenAlternateBiomes(int a_Seed, Underlying a_Alterations, Underlying a_BaseBiomes):
+ super(a_Seed),
+ m_Alterations(a_Alterations),
+ m_BaseBiomes(a_BaseBiomes)
+ {
+ }
+
+
+ virtual void GetInts(int a_MinX, int a_MinZ, int a_SizeX, int a_SizeZ, int * a_Values) override
+ {
+ // Generate the base biomes and the alterations:
+ m_BaseBiomes->GetInts(a_MinX, a_MinZ, a_SizeX, a_SizeZ, a_Values);
+ int alterations[m_BufferSize];
+ m_Alterations->GetInts(a_MinX, a_MinZ, a_SizeX, a_SizeZ, alterations);
+
+ // Change the biomes into their alternate versions:
+ int len = a_SizeX * a_SizeZ;
+ for (int idx = 0; idx < len; ++idx)
+ {
+ if (alterations[idx] == 0)
+ {
+ // No change
+ continue;
+ }
+
+ // Change to alternate biomes:
+ int val = a_Values[idx];
+ switch (val)
+ {
+ case biBirchForest: val = biBirchForestHills; break;
+ case biDesert: val = biDesertHills; break;
+ case biExtremeHills: val = biExtremeHillsPlus; break;
+ case biForest: val = biForestHills; break;
+ case biIcePlains: val = biIceMountains; break;
+ case biJungle: val = biJungleHills; break;
+ case biMegaTaiga: val = biMegaTaigaHills; break;
+ case biMesaPlateau: val = biMesa; break;
+ case biMesaPlateauF: val = biMesa; break;
+ case biMesaPlateauM: val = biMesa; break;
+ case biMesaPlateauFM: val = biMesa; break;
+ case biPlains: val = biForest; break;
+ case biRoofedForest: val = biPlains; break;
+ case biSavanna: val = biSavannaPlateau; break;
+ case biTaiga: val = biTaigaHills; break;
+ }
+ a_Values[idx] = val;
+ } // for idx - a_Values[]
+ }
+
+protected:
+ Underlying m_Alterations;
+ Underlying m_BaseBiomes;
+};
+
+
+
+
+
+/** Adds an edge between two specifically incompatible biomes, such as mesa and forest. */
+class cProtIntGenBiomeEdges:
+ public cProtIntGenWithNoise
+{
+ typedef cProtIntGenWithNoise super;
+
+public:
+ cProtIntGenBiomeEdges(int a_Seed, Underlying a_Underlying):
+ super(a_Seed),
+ m_Underlying(a_Underlying)
+ {
+ }
+
+
+ virtual void GetInts(int a_MinX, int a_MinZ, int a_SizeX, int a_SizeZ, int * a_Values) override
+ {
+ // Generate the underlying biomes:
+ int lowerSizeX = a_SizeX + 2;
+ int lowerSizeZ = a_SizeZ + 2;
+ ASSERT(lowerSizeX * lowerSizeZ <= m_BufferSize);
+ int lowerValues[m_BufferSize];
+ m_Underlying->GetInts(a_MinX - 1, a_MinZ - 1, lowerSizeX, lowerSizeZ, lowerValues);
+
+ // Convert incompatible edges into neutral biomes:
+ for (int z = 0; z < a_SizeZ; z++)
+ {
+ for (int x = 0; x < a_SizeX; x++)
+ {
+ int biome = lowerValues[x + 1 + (z + 1) * lowerSizeX];
+ int above = lowerValues[x + 1 + z * lowerSizeX];
+ int below = lowerValues[x + 1 + (z + 2) * lowerSizeX];
+ int left = lowerValues[x + (z + 1) * lowerSizeX];
+ int right = lowerValues[x + 2 + (z + 1) * lowerSizeX];
+
+ switch (biome)
+ {
+ case biDesert:
+ case biDesertM:
+ case biDesertHills:
+ {
+ if (
+ IsBiomeVeryCold(static_cast<EMCSBiome>(above)) ||
+ IsBiomeVeryCold(static_cast<EMCSBiome>(below)) ||
+ IsBiomeVeryCold(static_cast<EMCSBiome>(left)) ||
+ IsBiomeVeryCold(static_cast<EMCSBiome>(right))
+ )
+ {
+ biome = biPlains;
+ }
+ break;
+ } // case biDesert
+
+ case biMesaPlateau:
+ case biMesaPlateauF:
+ case biMesaPlateauFM:
+ case biMesaPlateauM:
+ {
+ if (
+ !isMesaCompatible(above) ||
+ !isMesaCompatible(below) ||
+ !isMesaCompatible(left) ||
+ !isMesaCompatible(right)
+ )
+ {
+ biome = biDesert;
+ }
+ break;
+ } // Mesa biomes
+
+ case biJungle:
+ case biJungleM:
+ {
+ if (
+ !isJungleCompatible(above) ||
+ !isJungleCompatible(below) ||
+ !isJungleCompatible(left) ||
+ !isJungleCompatible(right)
+ )
+ {
+ biome = (biome == biJungle) ? biJungleEdge : biJungleEdgeM;
+ }
+ break;
+ } // Jungle biomes
+
+ case biSwampland:
+ case biSwamplandM:
+ {
+ if (
+ IsBiomeNoDownfall(static_cast<EMCSBiome>(above)) ||
+ IsBiomeNoDownfall(static_cast<EMCSBiome>(below)) ||
+ IsBiomeNoDownfall(static_cast<EMCSBiome>(left)) ||
+ IsBiomeNoDownfall(static_cast<EMCSBiome>(right))
+ )
+ {
+ biome = biPlains;
+ }
+ break;
+ } // Swampland biomes
+ } // switch (biome)
+
+ a_Values[x + z * a_SizeX] = biome;
+ } // for x
+ } // for z
+ }
+
+
+protected:
+ Underlying m_Underlying;
+
+
+ bool isMesaCompatible(int a_Biome)
+ {
+ switch (a_Biome)
+ {
+ case biDesert:
+ case biMesa:
+ case biMesaBryce:
+ case biMesaPlateau:
+ case biMesaPlateauF:
+ case biMesaPlateauFM:
+ case biMesaPlateauM:
+ case biOcean:
+ case biDeepOcean:
+ {
+ return true;
+ }
+ default:
+ {
+ return false;
+ }
+ }
+ }
+
+
+ bool isJungleCompatible(int a_Biome)
+ {
+ switch (a_Biome)
+ {
+ case biJungle:
+ case biJungleM:
+ case biJungleEdge:
+ case biJungleEdgeM:
+ case biJungleHills:
+ {
+ return true;
+ }
+ default:
+ {
+ return false;
+ }
+ }
+ }
+};
+
+
+
+
+
+/** Changes biomes in the parent data into their alternate versions ("M" variants), in such places that
+have their alterations set. */
+class cProtIntGenMBiomes:
+ public cProtIntGenWithNoise
+{
+ typedef cProtIntGenWithNoise super;
+
+public:
+ cProtIntGenMBiomes(int a_Seed, Underlying a_Alteration, Underlying a_Underlying):
+ super(a_Seed),
+ m_Underlying(a_Underlying),
+ m_Alteration(a_Alteration)
+ {
+ }
+
+
+ virtual void GetInts(int a_MinX, int a_MinZ, int a_SizeX, int a_SizeZ, int * a_Values) override
+ {
+ // Generate the underlying biomes and the alterations:
+ m_Underlying->GetInts(a_MinX, a_MinZ, a_SizeX, a_SizeZ, a_Values);
+ int alterations[m_BufferSize];
+ m_Alteration->GetInts(a_MinX, a_MinZ, a_SizeX, a_SizeZ, alterations);
+
+ // Wherever alterations are nonzero, change into alternate biome, if available:
+ int len = a_SizeX * a_SizeZ;
+ for (int idx = 0; idx < len; ++idx)
+ {
+ if (alterations[idx] == 0)
+ {
+ continue;
+ }
+
+ // Ice spikes biome was removed from here, because it was generated way too often
+ switch (a_Values[idx])
+ {
+ case biPlains: a_Values[idx] = biSunflowerPlains; break;
+ case biDesert: a_Values[idx] = biDesertM; break;
+ case biExtremeHills: a_Values[idx] = biExtremeHillsM; break;
+ case biForest: a_Values[idx] = biFlowerForest; break;
+ case biTaiga: a_Values[idx] = biTaigaM; break;
+ case biSwampland: a_Values[idx] = biSwamplandM; break;
+ case biJungle: a_Values[idx] = biJungleM; break;
+ case biJungleEdge: a_Values[idx] = biJungleEdgeM; break;
+ case biBirchForest: a_Values[idx] = biBirchForestM; break;
+ case biBirchForestHills: a_Values[idx] = biBirchForestHillsM; break;
+ case biRoofedForest: a_Values[idx] = biRoofedForestM; break;
+ case biColdTaiga: a_Values[idx] = biColdTaigaM; break;
+ case biMegaSpruceTaiga: a_Values[idx] = biMegaSpruceTaiga; break;
+ case biMegaSpruceTaigaHills: a_Values[idx] = biMegaSpruceTaigaHills; break;
+ case biExtremeHillsPlus: a_Values[idx] = biExtremeHillsPlusM; break;
+ case biSavanna: a_Values[idx] = biSavannaM; break;
+ case biSavannaPlateau: a_Values[idx] = biSavannaPlateauM; break;
+ case biMesa: a_Values[idx] = biMesaBryce; break;
+ case biMesaPlateauF: a_Values[idx] = biMesaPlateauFM; break;
+ case biMesaPlateau: a_Values[idx] = biMesaBryce; break;
+ }
+ } // for idx - a_Values[] / alterations[]
+ }
+
+protected:
+ Underlying m_Underlying;
+ Underlying m_Alteration;
+};
+
+
+
+
diff --git a/src/Root.cpp b/src/Root.cpp
index 24c1a4cc8..55e1c1156 100644
--- a/src/Root.cpp
+++ b/src/Root.cpp
@@ -633,6 +633,22 @@ bool cRoot::FindAndDoWithPlayer(const AString & a_PlayerName, cPlayerListCallbac
+bool cRoot::DoWithPlayerByUUID(const AString & a_PlayerUUID, cPlayerListCallback & a_Callback)
+{
+ for (WorldMap::iterator itr = m_WorldsByName.begin(); itr != m_WorldsByName.end();itr++)
+ {
+ if (itr->second->DoWithPlayerByUUID(a_PlayerUUID, a_Callback))
+ {
+ return true;
+ }
+ }
+ return false;
+}
+
+
+
+
+
AString cRoot::GetProtocolVersionTextFromInt(int a_ProtocolVersion)
{
return cProtocolRecognizer::GetVersionTextFromInt(a_ProtocolVersion);
diff --git a/src/Root.h b/src/Root.h
index 020a6cff0..ec6b83fcc 100644
--- a/src/Root.h
+++ b/src/Root.h
@@ -126,6 +126,9 @@ public:
/// Finds a player from a partial or complete player name and calls the callback - case-insensitive
bool FindAndDoWithPlayer(const AString & a_PlayerName, cPlayerListCallback & a_Callback); // >> EXPORTED IN MANUALBINDINGS <<
+ /** Finds the player over his uuid and calls the callback */
+ bool DoWithPlayerByUUID(const AString & a_PlayerUUID, cPlayerListCallback & a_Callback); // >> EXPORTED IN MANUALBINDINGS <<
+
// tolua_begin
/// Sends a chat message to all connected clients (in all worlds)
diff --git a/src/World.cpp b/src/World.cpp
index 4e6ca264f..288cf0154 100644
--- a/src/World.cpp
+++ b/src/World.cpp
@@ -2732,6 +2732,23 @@ bool cWorld::FindAndDoWithPlayer(const AString & a_PlayerNameHint, cPlayerListCa
+bool cWorld::DoWithPlayerByUUID(const AString & a_PlayerUUID, cPlayerListCallback & a_Callback)
+{
+ cCSLock Lock(m_CSPlayers);
+ for (cPlayerList::iterator itr = m_Players.begin(); itr != m_Players.end(); ++itr)
+ {
+ if ((*itr)->GetUUID() == a_PlayerUUID)
+ {
+ return a_Callback.Item(*itr);
+ }
+ }
+ return false;
+}
+
+
+
+
+
// TODO: This interface is dangerous!
cPlayer * cWorld::FindClosestPlayer(const Vector3d & a_Pos, float a_SightLimit, bool a_CheckLineOfSight)
{
diff --git a/src/World.h b/src/World.h
index a782bb5ec..03d99c538 100644
--- a/src/World.h
+++ b/src/World.h
@@ -324,6 +324,9 @@ public:
// TODO: This interface is dangerous - rewrite to DoWithClosestPlayer(pos, sight, action)
cPlayer * FindClosestPlayer(const Vector3d & a_Pos, float a_SightLimit, bool a_CheckLineOfSight = true);
+ /** Finds the player over his uuid and calls the callback */
+ bool DoWithPlayerByUUID(const AString & a_PlayerUUID, cPlayerListCallback & a_Callback); // >> EXPORTED IN MANUALBINDINGS <<
+
void SendPlayerList(cPlayer * a_DestPlayer); // Sends playerlist to the player
/** Adds the entity into its appropriate chunk; takes ownership of the entity ptr.