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authorAlexander Harkness <bearbin@gmail.com>2013-07-29 13:13:03 +0200
committerAlexander Harkness <bearbin@gmail.com>2013-07-29 13:13:03 +0200
commit53e22b11857fed62e2313d6d84d90f88ed412ffb (patch)
treec61e56725da7dff0154d566722651e2c39c9d6c6 /source/Generating/Caves.cpp
parentWebAdmin: Removed the duplicate memory usage querying (diff)
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Diffstat (limited to '')
-rw-r--r--source/Generating/Caves.cpp1940
1 files changed, 970 insertions, 970 deletions
diff --git a/source/Generating/Caves.cpp b/source/Generating/Caves.cpp
index 2bfef8054..4221ea187 100644
--- a/source/Generating/Caves.cpp
+++ b/source/Generating/Caves.cpp
@@ -1,970 +1,970 @@
-
-// Caves.cpp
-
-// Implements the various cave structure generators:
-// - cStructGenWormNestCaves
-// - cStructGenDualRidgeCaves
-// - cStructGenMarbleCaves
-// - cStructGenNetherCaves
-
-/*
-WormNestCave generator:
-Caves are generated in "nests" - groups of tunnels generated from a single point.
-For each chunk, all the nests that could intersect it are generated.
-For each nest, first the schematic structure is generated (tunnel from ... to ..., branch, tunnel2 from ... to ...)
-Then each tunnel is randomized by inserting points in between its ends.
-Finally each tunnel is smoothed and Bresenham-3D-ed so that it is a collection of spheres with their centers next to each other.
-When the tunnels are ready, they are simply carved into the chunk, one by one.
-To optimize, each tunnel keeps track of its bounding box, so that it can be skipped for chunks that don't intersect it.
-
-MarbleCaves generator:
-For each voxel a 3D noise function is evaluated, if the value crosses a boundary, the voxel is dug out, otherwise it is kept.
-Problem with this is the amount of CPU work needed for each chunk.
-Also the overall shape of the generated holes is unsatisfactory - there are whole "sheets" of holes in the ground.
-
-DualRidgeCaves generator:
-Instead of evaluating a single noise function, two different noise functions are multiplied. This produces
-regular tunnels instead of sheets. However due to the sheer amount of CPU work needed, the noise functions need to be
-reduced in complexity in order for this generator to be useful, so the caves' shapes are "bubbly" at best.
-*/
-
-#include "Globals.h"
-#include "Caves.h"
-
-
-
-
-
-/// How many nests in each direction are generated for a given chunk. Must be an even number
-#define NEIGHBORHOOD_SIZE 8
-
-
-
-
-
-const int MIN_RADIUS = 3;
-const int MAX_RADIUS = 8;
-
-
-
-
-
-struct cCaveDefPoint
-{
- int m_BlockX;
- int m_BlockY;
- int m_BlockZ;
- int m_Radius;
-
- cCaveDefPoint(int a_BlockX, int a_BlockY, int a_BlockZ, int a_Radius) :
- m_BlockX(a_BlockX),
- m_BlockY(a_BlockY),
- m_BlockZ(a_BlockZ),
- m_Radius(a_Radius)
- {
- }
-} ;
-
-typedef std::vector<cCaveDefPoint> cCaveDefPoints;
-
-
-
-
-
-/// A single non-branching tunnel of a WormNestCave
-class cCaveTunnel
-{
- // The bounding box, including the radii around defpoints:
- int m_MinBlockX, m_MaxBlockX;
- int m_MinBlockY, m_MaxBlockY;
- int m_MinBlockZ, m_MaxBlockZ;
-
- /// Generates the shaping defpoints for the ravine, based on the ravine block coords and noise
- void Randomize(cNoise & a_Noise);
-
- /// Refines (adds and smooths) defpoints from a_Src into a_Dst; returns false if no refinement possible (segments too short)
- bool RefineDefPoints(const cCaveDefPoints & a_Src, cCaveDefPoints & a_Dst);
-
- /// Does rounds of smoothing, two passes of RefineDefPoints(), as long as they return true
- void Smooth(void);
-
- /// Linearly interpolates the points so that the maximum distance between two neighbors is max 1 block
- void FinishLinear(void);
-
- /// Calculates the bounding box of the points present
- void CalcBoundingBox(void);
-
-public:
- cCaveDefPoints m_Points;
-
- cCaveTunnel(
- int a_BlockStartX, int a_BlockStartY, int a_BlockStartZ, int a_StartRadius,
- int a_BlockEndX, int a_BlockEndY, int a_BlockEndZ, int a_EndRadius,
- cNoise & a_Noise
- );
-
- /// Carves the tunnel into the chunk specified
- void ProcessChunk(
- int a_ChunkX, int a_ChunkZ,
- cChunkDef::BlockTypes & a_BlockTypes,
- cChunkDef::HeightMap & a_HeightMap
- );
-
- #ifdef _DEBUG
- AString ExportAsSVG(int a_Color, int a_OffsetX, int a_OffsetZ) const;
- #endif // _DEBUG
-} ;
-
-typedef std::vector<cCaveTunnel *> cCaveTunnels;
-
-
-
-
-
-/// A collection of connected tunnels, possibly branching.
-class cStructGenWormNestCaves::cCaveSystem
-{
-public:
- // The generating block position; is read directly in cStructGenWormNestCaves::GetCavesForChunk()
- int m_BlockX;
- int m_BlockZ;
-
- cCaveSystem(int a_BlockX, int a_BlockZ, int a_MaxOffset, int a_Size, cNoise & a_Noise);
- ~cCaveSystem();
-
- /// Carves the cave system into the chunk specified
- void ProcessChunk(
- int a_ChunkX, int a_ChunkZ,
- cChunkDef::BlockTypes & a_BlockTypes,
- cChunkDef::HeightMap & a_HeightMap
- );
-
- #ifdef _DEBUG
- AString ExportAsSVG(int a_Color, int a_OffsetX, int a_OffsetZ) const;
- #endif // _DEBUG
-
-protected:
- int m_Size;
- cCaveTunnels m_Tunnels;
-
- void Clear(void);
-
- /// Generates a_Segment successive tunnels, with possible branches. Generates the same output for the same [x, y, z, a_Segments]
- void GenerateTunnelsFromPoint(
- int a_OriginX, int a_OriginY, int a_OriginZ,
- cNoise & a_Noise, int a_Segments
- );
-
- /// Returns a radius based on the location provided.
- int GetRadius(cNoise & a_Noise, int a_OriginX, int a_OriginY, int a_OriginZ);
-} ;
-
-
-
-
-
-///////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
-// cCaveTunnel:
-
-cCaveTunnel::cCaveTunnel(
- int a_BlockStartX, int a_BlockStartY, int a_BlockStartZ, int a_StartRadius,
- int a_BlockEndX, int a_BlockEndY, int a_BlockEndZ, int a_EndRadius,
- cNoise & a_Noise
-)
-{
- m_Points.push_back(cCaveDefPoint(a_BlockStartX, a_BlockStartY, a_BlockStartZ, a_StartRadius));
- m_Points.push_back(cCaveDefPoint(a_BlockEndX, a_BlockEndY, a_BlockEndZ, a_EndRadius));
-
- if ((a_BlockStartY <= 0) && (a_BlockEndY <= 0))
- {
- // Don't bother detailing this cave, it's under the world anyway
- return;
- }
-
- Randomize(a_Noise);
- Smooth();
-
- // We know that the linear finishing won't affect the bounding box, so let's calculate it now, as we have less data:
- CalcBoundingBox();
-
- FinishLinear();
-}
-
-
-
-
-
-void cCaveTunnel::Randomize(cNoise & a_Noise)
-{
- // Repeat 4 times:
- for (int i = 0; i < 4; i++)
- {
- // For each already present point, insert a point in between it and its predecessor, shifted randomly.
- int PrevX = m_Points.front().m_BlockX;
- int PrevY = m_Points.front().m_BlockY;
- int PrevZ = m_Points.front().m_BlockZ;
- int PrevR = m_Points.front().m_Radius;
- cCaveDefPoints Pts;
- Pts.reserve(m_Points.size() * 2 + 1);
- Pts.push_back(m_Points.front());
- for (cCaveDefPoints::const_iterator itr = m_Points.begin() + 1, end = m_Points.end(); itr != end; ++itr)
- {
- int Random = a_Noise.IntNoise3DInt(PrevX, PrevY, PrevZ + i) / 11;
- int len = (PrevX - itr->m_BlockX) * (PrevX - itr->m_BlockX);
- len += (PrevY - itr->m_BlockY) * (PrevY - itr->m_BlockY);
- len += (PrevZ - itr->m_BlockZ) * (PrevZ - itr->m_BlockZ);
- len = 3 * (int)sqrt((double)len) / 4;
- int Rad = std::min(MAX_RADIUS, std::max(MIN_RADIUS, (PrevR + itr->m_Radius) / 2 + (Random % 3) - 1));
- Random /= 4;
- int x = (itr->m_BlockX + PrevX) / 2 + (Random % (len + 1) - len / 2);
- Random /= 256;
- int y = (itr->m_BlockY + PrevY) / 2 + (Random % (len / 2 + 1) - len / 4);
- Random /= 256;
- int z = (itr->m_BlockZ + PrevZ) / 2 + (Random % (len + 1) - len / 2);
- Pts.push_back(cCaveDefPoint(x, y, z, Rad));
- Pts.push_back(*itr);
- PrevX = itr->m_BlockX;
- PrevY = itr->m_BlockY;
- PrevZ = itr->m_BlockZ;
- PrevR = itr->m_Radius;
- }
- std::swap(Pts, m_Points);
- }
-}
-
-
-
-
-
-bool cCaveTunnel::RefineDefPoints(const cCaveDefPoints & a_Src, cCaveDefPoints & a_Dst)
-{
- // Smoothing: for each line segment, add points on its 1/4 lengths
- bool res = false;
- int Num = a_Src.size() - 2; // this many intermediary points
- a_Dst.clear();
- a_Dst.reserve(Num * 2 + 2);
- cCaveDefPoints::const_iterator itr = a_Src.begin() + 1;
- a_Dst.push_back(a_Src.front());
- int PrevX = a_Src.front().m_BlockX;
- int PrevY = a_Src.front().m_BlockY;
- int PrevZ = a_Src.front().m_BlockZ;
- int PrevR = a_Src.front().m_Radius;
- for (int i = 0; i <= Num; ++i, ++itr)
- {
- int dx = itr->m_BlockX - PrevX;
- int dy = itr->m_BlockY - PrevY;
- int dz = itr->m_BlockZ - PrevZ;
- if (abs(dx) + abs(dz) + abs(dy) < 6)
- {
- // Too short a segment to smooth-subdivide into quarters
- PrevX = itr->m_BlockX;
- PrevY = itr->m_BlockY;
- PrevZ = itr->m_BlockZ;
- PrevR = itr->m_Radius;
- continue;
- }
- int dr = itr->m_Radius - PrevR;
- int Rad1 = std::max(PrevR + 1 * dr / 4, 1);
- int Rad2 = std::max(PrevR + 3 * dr / 4, 1);
- a_Dst.push_back(cCaveDefPoint(PrevX + 1 * dx / 4, PrevY + 1 * dy / 4, PrevZ + 1 * dz / 4, Rad1));
- a_Dst.push_back(cCaveDefPoint(PrevX + 3 * dx / 4, PrevY + 3 * dy / 4, PrevZ + 3 * dz / 4, Rad2));
- PrevX = itr->m_BlockX;
- PrevY = itr->m_BlockY;
- PrevZ = itr->m_BlockZ;
- PrevR = itr->m_Radius;
- res = true;
- }
- a_Dst.push_back(a_Src.back());
- return res && (a_Src.size() < a_Dst.size());
-}
-
-
-
-
-
-void cCaveTunnel::Smooth(void)
-{
- cCaveDefPoints Pts;
- while (true)
- {
- if (!RefineDefPoints(m_Points, Pts))
- {
- std::swap(Pts, m_Points);
- return;
- }
- if (!RefineDefPoints(Pts, m_Points))
- {
- return;
- }
- }
-}
-
-
-
-
-
-void cCaveTunnel::FinishLinear(void)
-{
- // For each segment, use Bresenham's 3D line algorithm to draw a "line" of defpoints
- cCaveDefPoints Pts;
- std::swap(Pts, m_Points);
-
- m_Points.reserve(Pts.size() * 3);
- int PrevX = Pts.front().m_BlockX;
- int PrevY = Pts.front().m_BlockY;
- int PrevZ = Pts.front().m_BlockZ;
- for (cCaveDefPoints::const_iterator itr = Pts.begin() + 1, end = Pts.end(); itr != end; ++itr)
- {
- int x1 = itr->m_BlockX;
- int y1 = itr->m_BlockY;
- int z1 = itr->m_BlockZ;
- int dx = abs(x1 - PrevX);
- int dy = abs(y1 - PrevY);
- int dz = abs(z1 - PrevZ);
- int sx = (PrevX < x1) ? 1 : -1;
- int sy = (PrevY < y1) ? 1 : -1;
- int sz = (PrevZ < z1) ? 1 : -1;
- int err = dx - dz;
- int R = itr->m_Radius;
-
- if (dx >= std::max(dy, dz)) // x dominant
- {
- int yd = dy - dx / 2;
- int zd = dz - dx / 2;
-
- while (true)
- {
- m_Points.push_back(cCaveDefPoint(PrevX, PrevY, PrevZ, R));
-
- if (PrevX == x1)
- {
- break;
- }
-
- if (yd >= 0) // move along y
- {
- PrevY += sy;
- yd -= dx;
- }
-
- if (zd >= 0) // move along z
- {
- PrevZ += sz;
- zd -= dx;
- }
-
- // move along x
- PrevX += sx;
- yd += dy;
- zd += dz;
- }
- }
- else if (dy >= std::max(dx, dz)) // y dominant
- {
- int xd = dx - dy / 2;
- int zd = dz - dy / 2;
-
- while (true)
- {
- m_Points.push_back(cCaveDefPoint(PrevX, PrevY, PrevZ, R));
-
- if (PrevY == y1)
- {
- break;
- }
-
- if (xd >= 0) // move along x
- {
- PrevX += sx;
- xd -= dy;
- }
-
- if (zd >= 0) // move along z
- {
- PrevZ += sz;
- zd -= dy;
- }
-
- // move along y
- PrevY += sy;
- xd += dx;
- zd += dz;
- }
- }
- else
- {
- // z dominant
- ASSERT(dz >= std::max(dx, dy));
- int xd = dx - dz / 2;
- int yd = dy - dz / 2;
-
- while (true)
- {
- m_Points.push_back(cCaveDefPoint(PrevX, PrevY, PrevZ, R));
-
- if (PrevZ == z1)
- {
- break;
- }
-
- if (xd >= 0) // move along x
- {
- PrevX += sx;
- xd -= dz;
- }
-
- if (yd >= 0) // move along y
- {
- PrevY += sy;
- yd -= dz;
- }
-
- // move along z
- PrevZ += sz;
- xd += dx;
- yd += dy;
- }
- } // if (which dimension is dominant)
- } // for itr
-}
-
-
-
-
-
-void cCaveTunnel::CalcBoundingBox(void)
-{
- m_MinBlockX = m_MaxBlockX = m_Points.front().m_BlockX;
- m_MinBlockY = m_MaxBlockY = m_Points.front().m_BlockY;
- m_MinBlockZ = m_MaxBlockZ = m_Points.front().m_BlockZ;
- for (cCaveDefPoints::const_iterator itr = m_Points.begin() + 1, end = m_Points.end(); itr != end; ++itr)
- {
- m_MinBlockX = std::min(m_MinBlockX, itr->m_BlockX - itr->m_Radius);
- m_MaxBlockX = std::max(m_MaxBlockX, itr->m_BlockX + itr->m_Radius);
- m_MinBlockY = std::min(m_MinBlockY, itr->m_BlockY - itr->m_Radius);
- m_MaxBlockY = std::max(m_MaxBlockY, itr->m_BlockY + itr->m_Radius);
- m_MinBlockZ = std::min(m_MinBlockZ, itr->m_BlockZ - itr->m_Radius);
- m_MaxBlockZ = std::max(m_MaxBlockZ, itr->m_BlockZ + itr->m_Radius);
- } // for itr - m_Points[]
-}
-
-
-
-
-
-void cCaveTunnel::ProcessChunk(
- int a_ChunkX, int a_ChunkZ,
- cChunkDef::BlockTypes & a_BlockTypes,
- cChunkDef::HeightMap & a_HeightMap
-)
-{
- int BaseX = a_ChunkX * cChunkDef::Width;
- int BaseZ = a_ChunkZ * cChunkDef::Width;
- if (
- (BaseX > m_MaxBlockX) || (BaseX + cChunkDef::Width < m_MinBlockX) ||
- (BaseX > m_MaxBlockX) || (BaseX + cChunkDef::Width < m_MinBlockX)
- )
- {
- // Tunnel does not intersect the chunk at all, bail out
- return;
- }
-
- int BlockStartX = a_ChunkX * cChunkDef::Width;
- int BlockStartZ = a_ChunkZ * cChunkDef::Width;
- int BlockEndX = BlockStartX + cChunkDef::Width;
- int BlockEndZ = BlockStartZ + cChunkDef::Width;
- for (cCaveDefPoints::const_iterator itr = m_Points.begin(), end = m_Points.end(); itr != end; ++itr)
- {
- if (
- (itr->m_BlockX + itr->m_Radius < BlockStartX) ||
- (itr->m_BlockX - itr->m_Radius > BlockEndX) ||
- (itr->m_BlockZ + itr->m_Radius < BlockStartZ) ||
- (itr->m_BlockZ - itr->m_Radius > BlockEndZ)
- )
- {
- // Cannot intersect, bail out early
- continue;
- }
-
- // Carve out a sphere around the xyz point, m_Radius in diameter; skip 3/7 off the top and bottom:
- int DifX = itr->m_BlockX - BlockStartX; // substitution for faster calc
- int DifY = itr->m_BlockY;
- int DifZ = itr->m_BlockZ - BlockStartZ; // substitution for faster calc
- int Bottom = std::max(itr->m_BlockY - 3 * itr->m_Radius / 7, 1);
- int Top = std::min(itr->m_BlockY + 3 * itr->m_Radius / 7, (int)(cChunkDef::Height));
- int SqRad = itr->m_Radius * itr->m_Radius;
- for (int z = 0; z < cChunkDef::Width; z++) for (int x = 0; x < cChunkDef::Width; x++)
- {
- for (int y = Bottom; y <= Top; y++)
- {
- int SqDist = (DifX - x) * (DifX - x) + (DifY - y) * (DifY - y) + (DifZ - z) * (DifZ - z);
- if (4 * SqDist <= SqRad)
- {
- switch (cChunkDef::GetBlock(a_BlockTypes, x, y, z))
- {
- // Only carve out these specific block types
- case E_BLOCK_DIRT:
- case E_BLOCK_GRASS:
- case E_BLOCK_STONE:
- case E_BLOCK_COBBLESTONE:
- case E_BLOCK_GRAVEL:
- case E_BLOCK_SAND:
- case E_BLOCK_SANDSTONE:
- case E_BLOCK_NETHERRACK:
- case E_BLOCK_COAL_ORE:
- case E_BLOCK_IRON_ORE:
- case E_BLOCK_GOLD_ORE:
- case E_BLOCK_DIAMOND_ORE:
- case E_BLOCK_REDSTONE_ORE:
- case E_BLOCK_REDSTONE_ORE_GLOWING:
- {
- cChunkDef::SetBlock(a_BlockTypes, x, y, z, E_BLOCK_AIR);
- break;
- }
- default: break;
- }
- }
- } // for y
- } // for x, z
- } // for itr - m_Points[]
-
- /*
- #ifdef _DEBUG
- // For debugging purposes, outline the shape of the cave using glowstone, *after* carving the entire cave:
- for (cCaveDefPoints::const_iterator itr = m_Points.begin(), end = m_Points.end(); itr != end; ++itr)
- {
- int DifX = itr->m_BlockX - BlockStartX; // substitution for faster calc
- int DifZ = itr->m_BlockZ - BlockStartZ; // substitution for faster calc
- if (
- (DifX >= 0) && (DifX < cChunkDef::Width) &&
- (itr->m_BlockY > 0) && (itr->m_BlockY < cChunkDef::Height) &&
- (DifZ >= 0) && (DifZ < cChunkDef::Width)
- )
- {
- cChunkDef::SetBlock(a_BlockTypes, DifX, itr->m_BlockY, DifZ, E_BLOCK_GLOWSTONE);
- }
- } // for itr - m_Points[]
- #endif // _DEBUG
- //*/
-}
-
-
-
-
-
-#ifdef _DEBUG
-AString cCaveTunnel::ExportAsSVG(int a_Color, int a_OffsetX, int a_OffsetZ) const
-{
- AString SVG;
- SVG.reserve(m_Points.size() * 20 + 200);
- AppendPrintf(SVG, "<path style=\"fill:none;stroke:#%06x;stroke-width:1px;\"\nd=\"", a_Color);
- char Prefix = 'M'; // The first point needs "M" prefix, all the others need "L"
- for (cCaveDefPoints::const_iterator itr = m_Points.begin(); itr != m_Points.end(); ++itr)
- {
- AppendPrintf(SVG, "%c %d,%d ", Prefix, a_OffsetX + itr->m_BlockX, a_OffsetZ + itr->m_BlockZ);
- Prefix = 'L';
- }
- SVG.append("\"/>\n");
- return SVG;
-}
-#endif // _DEBUG
-
-
-
-
-
-///////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
-// cStructGenWormNestCaves::cCaveSystem:
-
-cStructGenWormNestCaves::cCaveSystem::cCaveSystem(int a_BlockX, int a_BlockZ, int a_MaxOffset, int a_Size, cNoise & a_Noise) :
- m_BlockX(a_BlockX),
- m_BlockZ(a_BlockZ),
- m_Size(a_Size)
-{
- int Num = 1 + a_Noise.IntNoise2DInt(a_BlockX, a_BlockZ) % 3;
- for (int i = 0; i < Num; i++)
- {
- int OriginX = a_BlockX + (a_Noise.IntNoise3DInt(13 * a_BlockX, 17 * a_BlockZ, 11 * i) / 19) % a_MaxOffset;
- int OriginZ = a_BlockZ + (a_Noise.IntNoise3DInt(17 * a_BlockX, 13 * a_BlockZ, 11 * i) / 23) % a_MaxOffset;
- int OriginY = 20 + (a_Noise.IntNoise3DInt(19 * a_BlockX, 13 * a_BlockZ, 11 * i) / 17) % 20;
-
- // Generate three branches from the origin point:
- // The tunnels generated depend on X, Y, Z and Branches,
- // for the same set of numbers it generates the same offsets!
- // That's why we add a +1 to X in the third line
- GenerateTunnelsFromPoint(OriginX, OriginY, OriginZ, a_Noise, 3);
- GenerateTunnelsFromPoint(OriginX, OriginY, OriginZ, a_Noise, 2);
- GenerateTunnelsFromPoint(OriginX + 1, OriginY, OriginZ, a_Noise, 3);
- }
-}
-
-
-
-
-
-cStructGenWormNestCaves::cCaveSystem::~cCaveSystem()
-{
- Clear();
-}
-
-
-
-
-
-
-void cStructGenWormNestCaves::cCaveSystem::ProcessChunk(
- int a_ChunkX, int a_ChunkZ,
- cChunkDef::BlockTypes & a_BlockTypes,
- cChunkDef::HeightMap & a_HeightMap
-)
-{
- for (cCaveTunnels::const_iterator itr = m_Tunnels.begin(), end = m_Tunnels.end(); itr != end; ++itr)
- {
- (*itr)->ProcessChunk(a_ChunkX, a_ChunkZ, a_BlockTypes, a_HeightMap);
- } // for itr - m_Tunnels[]
-}
-
-
-
-
-
-#ifdef _DEBUG
-AString cStructGenWormNestCaves::cCaveSystem::ExportAsSVG(int a_Color, int a_OffsetX, int a_OffsetZ) const
-{
- AString SVG;
- SVG.reserve(512 * 1024);
- for (cCaveTunnels::const_iterator itr = m_Tunnels.begin(), end = m_Tunnels.end(); itr != end; ++itr)
- {
- SVG.append((*itr)->ExportAsSVG(a_Color, a_OffsetX, a_OffsetZ));
- } // for itr - m_Tunnels[]
-
- // Base point highlight:
- AppendPrintf(SVG, "<path style=\"fill:none;stroke:#ff0000;stroke-width:1px;\"\nd=\"M %d,%d L %d,%d\"/>\n",
- a_OffsetX + m_BlockX - 5, a_OffsetZ + m_BlockZ, a_OffsetX + m_BlockX + 5, a_OffsetZ + m_BlockZ
- );
- AppendPrintf(SVG, "<path style=\"fill:none;stroke:#ff0000;stroke-width:1px;\"\nd=\"M %d,%d L %d,%d\"/>\n",
- a_OffsetX + m_BlockX, a_OffsetZ + m_BlockZ - 5, a_OffsetX + m_BlockX, a_OffsetZ + m_BlockZ + 5
- );
-
- // A gray line from the base point to the first point of the ravine, for identification:
- AppendPrintf(SVG, "<path style=\"fill:none;stroke:#cfcfcf;stroke-width:1px;\"\nd=\"M %d,%d L %d,%d\"/>\n",
- a_OffsetX + m_BlockX, a_OffsetZ + m_BlockZ,
- a_OffsetX + m_Tunnels.front()->m_Points.front().m_BlockX,
- a_OffsetZ + m_Tunnels.front()->m_Points.front().m_BlockZ
- );
-
- // Offset guides:
- if (a_OffsetX > 0)
- {
- AppendPrintf(SVG, "<path style=\"fill:none;stroke:#0000ff;stroke-width:1px;\"\nd=\"M %d,0 L %d,1024\"/>\n",
- a_OffsetX, a_OffsetX
- );
- }
- if (a_OffsetZ > 0)
- {
- AppendPrintf(SVG, "<path style=\"fill:none;stroke:#0000ff;stroke-width:1px;\"\nd=\"M 0,%d L 1024,%d\"/>\n",
- a_OffsetZ, a_OffsetZ
- );
- }
-
- return SVG;
-}
-#endif // _DEBUG
-
-
-
-
-
-void cStructGenWormNestCaves::cCaveSystem::Clear(void)
-{
- for (cCaveTunnels::const_iterator itr = m_Tunnels.begin(), end = m_Tunnels.end(); itr != end; ++itr)
- {
- delete *itr;
- }
- m_Tunnels.clear();
-}
-
-
-
-
-
-void cStructGenWormNestCaves::cCaveSystem::GenerateTunnelsFromPoint(
- int a_OriginX, int a_OriginY, int a_OriginZ,
- cNoise & a_Noise, int a_NumSegments
-)
-{
- int DoubleSize = m_Size * 2;
- int Radius = GetRadius(a_Noise, a_OriginX + a_OriginY, a_OriginY + a_OriginZ, a_OriginZ + a_OriginX);
- for (int i = a_NumSegments - 1; i >= 0; --i)
- {
- int EndX = a_OriginX + (((a_Noise.IntNoise3DInt(a_OriginX, a_OriginY, a_OriginZ + 11 * a_NumSegments) / 7) % DoubleSize) - m_Size) / 2;
- int EndY = a_OriginY + (((a_Noise.IntNoise3DInt(a_OriginY, 13 * a_NumSegments, a_OriginZ + a_OriginX) / 7) % DoubleSize) - m_Size) / 4;
- int EndZ = a_OriginZ + (((a_Noise.IntNoise3DInt(a_OriginZ + 17 * a_NumSegments, a_OriginX, a_OriginY) / 7) % DoubleSize) - m_Size) / 2;
- int EndR = GetRadius(a_Noise, a_OriginX + 7 * i, a_OriginY + 11 * i, a_OriginZ + a_OriginX);
- m_Tunnels.push_back(new cCaveTunnel(a_OriginX, a_OriginY, a_OriginZ, Radius, EndX, EndY, EndZ, EndR, a_Noise));
- GenerateTunnelsFromPoint(EndX, EndY, EndZ, a_Noise, i);
- a_OriginX = EndX;
- a_OriginY = EndY;
- a_OriginZ = EndZ;
- Radius = EndR;
- } // for i - a_NumSegments
-}
-
-
-
-
-
-int cStructGenWormNestCaves::cCaveSystem::GetRadius(cNoise & a_Noise, int a_OriginX, int a_OriginY, int a_OriginZ)
-{
- // Instead of a flat distribution noise function, we need to shape it, so that most caves are smallish and only a few select are large
- int rnd = a_Noise.IntNoise3DInt(a_OriginX, a_OriginY, a_OriginZ) / 11;
- /*
- // Not good enough:
- // The algorithm of choice: emulate gauss-distribution noise by adding 3 flat noises, then fold it in half using absolute value.
- // To save on processing, use one random value and extract 3 bytes to be separately added as the gaussian noise
- int sum = (rnd & 0xff) + ((rnd >> 8) & 0xff) + ((rnd >> 16) & 0xff);
- // sum is now a gaussian-distribution noise within [0 .. 767], with center at 384.
- // We want mapping 384 -> 3, 0 -> 19, 768 -> 19, so divide by 24 to get [0 .. 31] with center at 16, then use abs() to fold around the center
- int res = 3 + abs((sum / 24) - 16);
- */
-
- // Algorithm of choice: random value in the range of zero to random value - heavily towards zero
- int res = MIN_RADIUS + (rnd >> 8) % ((rnd % (MAX_RADIUS - MIN_RADIUS)) + 1);
- return res;
-}
-
-
-
-
-
-///////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
-// cStructGenWormNestCaves:
-
-cStructGenWormNestCaves::~cStructGenWormNestCaves()
-{
- ClearCache();
-}
-
-
-
-
-
-void cStructGenWormNestCaves::ClearCache(void)
-{
- for (cCaveSystems::const_iterator itr = m_Cache.begin(), end = m_Cache.end(); itr != end; ++itr)
- {
- delete *itr;
- } // for itr - m_Cache[]
- m_Cache.clear();
-}
-
-
-
-
-
-void cStructGenWormNestCaves::GenStructures(cChunkDesc & a_ChunkDesc)
-{
- int ChunkX = a_ChunkDesc.GetChunkX();
- int ChunkZ = a_ChunkDesc.GetChunkZ();
- cCaveSystems Caves;
- GetCavesForChunk(ChunkX, ChunkZ, Caves);
- for (cCaveSystems::const_iterator itr = Caves.begin(); itr != Caves.end(); ++itr)
- {
- (*itr)->ProcessChunk(ChunkX, ChunkZ, a_ChunkDesc.GetBlockTypes(), a_ChunkDesc.GetHeightMap());
- } // for itr - Caves[]
-}
-
-
-
-
-
-void cStructGenWormNestCaves::GetCavesForChunk(int a_ChunkX, int a_ChunkZ, cStructGenWormNestCaves::cCaveSystems & a_Caves)
-{
- int BaseX = a_ChunkX * cChunkDef::Width / m_Grid;
- int BaseZ = a_ChunkZ * cChunkDef::Width / m_Grid;
- if (BaseX < 0)
- {
- --BaseX;
- }
- if (BaseZ < 0)
- {
- --BaseZ;
- }
- BaseX -= NEIGHBORHOOD_SIZE / 2;
- BaseZ -= NEIGHBORHOOD_SIZE / 2;
-
- // Walk the cache, move each cave system that we want into a_Caves:
- int StartX = BaseX * m_Grid;
- int EndX = (BaseX + NEIGHBORHOOD_SIZE + 1) * m_Grid;
- int StartZ = BaseZ * m_Grid;
- int EndZ = (BaseZ + NEIGHBORHOOD_SIZE + 1) * m_Grid;
- for (cCaveSystems::iterator itr = m_Cache.begin(), end = m_Cache.end(); itr != end;)
- {
- if (
- ((*itr)->m_BlockX >= StartX) && ((*itr)->m_BlockX < EndX) &&
- ((*itr)->m_BlockZ >= StartZ) && ((*itr)->m_BlockZ < EndZ)
- )
- {
- // want
- a_Caves.push_back(*itr);
- itr = m_Cache.erase(itr);
- }
- else
- {
- // don't want
- ++itr;
- }
- } // for itr - m_Cache[]
-
- for (int x = 0; x < NEIGHBORHOOD_SIZE; x++)
- {
- int RealX = (BaseX + x) * m_Grid;
- for (int z = 0; z < NEIGHBORHOOD_SIZE; z++)
- {
- int RealZ = (BaseZ + z) * m_Grid;
- bool Found = false;
- for (cCaveSystems::const_iterator itr = a_Caves.begin(), end = a_Caves.end(); itr != end; ++itr)
- {
- if (((*itr)->m_BlockX == RealX) && ((*itr)->m_BlockZ == RealZ))
- {
- Found = true;
- break;
- }
- }
- if (!Found)
- {
- a_Caves.push_back(new cCaveSystem(RealX, RealZ, m_MaxOffset, m_Size, m_Noise));
- }
- }
- }
-
- // Copy a_Caves into m_Cache to the beginning:
- cCaveSystems CavesCopy(a_Caves);
- m_Cache.splice(m_Cache.begin(), CavesCopy, CavesCopy.begin(), CavesCopy.end());
-
- // Trim the cache if it's too long:
- if (m_Cache.size() > 100)
- {
- cCaveSystems::iterator itr = m_Cache.begin();
- std::advance(itr, 100);
- for (cCaveSystems::iterator end = m_Cache.end(); itr != end; ++itr)
- {
- delete *itr;
- }
- itr = m_Cache.begin();
- std::advance(itr, 100);
- m_Cache.erase(itr, m_Cache.end());
- }
-
- /*
- // Uncomment this block for debugging the caves' shapes in 2D using an SVG export
- #ifdef _DEBUG
- AString SVG;
- SVG.append("<?xml version=\"1.0\" encoding=\"UTF-8\" standalone=\"no\"?>\n<svg xmlns=\"http://www.w3.org/2000/svg\" width=\"1024\" height = \"1024\">\n");
- SVG.reserve(2 * 1024 * 1024);
- for (cCaveSystems::const_iterator itr = a_Caves.begin(), end = a_Caves.end(); itr != end; ++itr)
- {
- int Color = 0x10 * abs((*itr)->m_BlockX / m_Grid);
- Color |= 0x1000 * abs((*itr)->m_BlockZ / m_Grid);
- SVG.append((*itr)->ExportAsSVG(Color, 512, 512));
- }
- SVG.append("</svg>\n");
-
- AString fnam;
- Printf(fnam, "wnc\\%03d_%03d.svg", a_ChunkX, a_ChunkZ);
- cFile File(fnam, cFile::fmWrite);
- File.Write(SVG.c_str(), SVG.size());
- #endif // _DEBUG
- //*/
-}
-
-
-
-
-
-
-///////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
-// cStructGenMarbleCaves:
-
-static float GetMarbleNoise( float x, float y, float z, cNoise & a_Noise )
-{
- static const float PI_2 = 1.57079633f;
- float oct1 = (a_Noise.CubicNoise3D(x * 0.1f, y * 0.1f, z * 0.1f )) * 4;
-
- oct1 = oct1 * oct1 * oct1;
- if (oct1 < 0.f) oct1 = PI_2;
- if (oct1 > PI_2) oct1 = PI_2;
-
- return oct1;
-}
-
-
-
-
-
-void cStructGenMarbleCaves::GenStructures(cChunkDesc & a_ChunkDesc)
-{
- cNoise Noise(m_Seed);
- for (int z = 0; z < cChunkDef::Width; z++)
- {
- const float zz = (float)(a_ChunkDesc.GetChunkZ() * cChunkDef::Width + z);
- for (int x = 0; x < cChunkDef::Width; x++)
- {
- const float xx = (float)(a_ChunkDesc.GetChunkX() * cChunkDef::Width + x);
-
- int Top = a_ChunkDesc.GetHeight(x, z);
- for (int y = 1; y < Top; ++y )
- {
- if (a_ChunkDesc.GetBlockType(x, y, z) != E_BLOCK_STONE)
- {
- continue;
- }
-
- const float yy = (float)y;
- const float WaveNoise = 1;
- if (cosf(GetMarbleNoise(xx, yy * 0.5f, zz, Noise)) * fabs(cosf(yy * 0.2f + WaveNoise * 2) * 0.75f + WaveNoise) > 0.0005f)
- {
- a_ChunkDesc.SetBlockType(x, y, z, E_BLOCK_AIR);
- }
- } // for y
- } // for x
- } // for z
-}
-
-
-
-
-
-///////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
-// cStructGenDualRidgeCaves:
-
-void cStructGenDualRidgeCaves::GenStructures(cChunkDesc & a_ChunkDesc)
-{
- for (int z = 0; z < cChunkDef::Width; z++)
- {
- const float zz = (float)(a_ChunkDesc.GetChunkZ() * cChunkDef::Width + z) / 10;
- for (int x = 0; x < cChunkDef::Width; x++)
- {
- const float xx = (float)(a_ChunkDesc.GetChunkX() * cChunkDef::Width + x) / 10;
-
- int Top = a_ChunkDesc.GetHeight(x, z);
- for (int y = 1; y <= Top; ++y)
- {
- const float yy = (float)y / 10;
- const float WaveNoise = 1;
- float n1 = m_Noise1.CubicNoise3D(xx, yy, zz);
- float n2 = m_Noise2.CubicNoise3D(xx, yy, zz);
- float n3 = m_Noise1.CubicNoise3D(xx * 4, yy * 4, zz * 4) / 4;
- float n4 = m_Noise2.CubicNoise3D(xx * 4, yy * 4, zz * 4) / 4;
- if ((abs(n1 + n3) * abs(n2 + n4)) > m_Threshold)
- {
- a_ChunkDesc.SetBlockType(x, y, z, E_BLOCK_AIR);
- }
- } // for y
- } // for x
- } // for z
-}
-
-
-
-
+
+// Caves.cpp
+
+// Implements the various cave structure generators:
+// - cStructGenWormNestCaves
+// - cStructGenDualRidgeCaves
+// - cStructGenMarbleCaves
+// - cStructGenNetherCaves
+
+/*
+WormNestCave generator:
+Caves are generated in "nests" - groups of tunnels generated from a single point.
+For each chunk, all the nests that could intersect it are generated.
+For each nest, first the schematic structure is generated (tunnel from ... to ..., branch, tunnel2 from ... to ...)
+Then each tunnel is randomized by inserting points in between its ends.
+Finally each tunnel is smoothed and Bresenham-3D-ed so that it is a collection of spheres with their centers next to each other.
+When the tunnels are ready, they are simply carved into the chunk, one by one.
+To optimize, each tunnel keeps track of its bounding box, so that it can be skipped for chunks that don't intersect it.
+
+MarbleCaves generator:
+For each voxel a 3D noise function is evaluated, if the value crosses a boundary, the voxel is dug out, otherwise it is kept.
+Problem with this is the amount of CPU work needed for each chunk.
+Also the overall shape of the generated holes is unsatisfactory - there are whole "sheets" of holes in the ground.
+
+DualRidgeCaves generator:
+Instead of evaluating a single noise function, two different noise functions are multiplied. This produces
+regular tunnels instead of sheets. However due to the sheer amount of CPU work needed, the noise functions need to be
+reduced in complexity in order for this generator to be useful, so the caves' shapes are "bubbly" at best.
+*/
+
+#include "Globals.h"
+#include "Caves.h"
+
+
+
+
+
+/// How many nests in each direction are generated for a given chunk. Must be an even number
+#define NEIGHBORHOOD_SIZE 8
+
+
+
+
+
+const int MIN_RADIUS = 3;
+const int MAX_RADIUS = 8;
+
+
+
+
+
+struct cCaveDefPoint
+{
+ int m_BlockX;
+ int m_BlockY;
+ int m_BlockZ;
+ int m_Radius;
+
+ cCaveDefPoint(int a_BlockX, int a_BlockY, int a_BlockZ, int a_Radius) :
+ m_BlockX(a_BlockX),
+ m_BlockY(a_BlockY),
+ m_BlockZ(a_BlockZ),
+ m_Radius(a_Radius)
+ {
+ }
+} ;
+
+typedef std::vector<cCaveDefPoint> cCaveDefPoints;
+
+
+
+
+
+/// A single non-branching tunnel of a WormNestCave
+class cCaveTunnel
+{
+ // The bounding box, including the radii around defpoints:
+ int m_MinBlockX, m_MaxBlockX;
+ int m_MinBlockY, m_MaxBlockY;
+ int m_MinBlockZ, m_MaxBlockZ;
+
+ /// Generates the shaping defpoints for the ravine, based on the ravine block coords and noise
+ void Randomize(cNoise & a_Noise);
+
+ /// Refines (adds and smooths) defpoints from a_Src into a_Dst; returns false if no refinement possible (segments too short)
+ bool RefineDefPoints(const cCaveDefPoints & a_Src, cCaveDefPoints & a_Dst);
+
+ /// Does rounds of smoothing, two passes of RefineDefPoints(), as long as they return true
+ void Smooth(void);
+
+ /// Linearly interpolates the points so that the maximum distance between two neighbors is max 1 block
+ void FinishLinear(void);
+
+ /// Calculates the bounding box of the points present
+ void CalcBoundingBox(void);
+
+public:
+ cCaveDefPoints m_Points;
+
+ cCaveTunnel(
+ int a_BlockStartX, int a_BlockStartY, int a_BlockStartZ, int a_StartRadius,
+ int a_BlockEndX, int a_BlockEndY, int a_BlockEndZ, int a_EndRadius,
+ cNoise & a_Noise
+ );
+
+ /// Carves the tunnel into the chunk specified
+ void ProcessChunk(
+ int a_ChunkX, int a_ChunkZ,
+ cChunkDef::BlockTypes & a_BlockTypes,
+ cChunkDef::HeightMap & a_HeightMap
+ );
+
+ #ifdef _DEBUG
+ AString ExportAsSVG(int a_Color, int a_OffsetX, int a_OffsetZ) const;
+ #endif // _DEBUG
+} ;
+
+typedef std::vector<cCaveTunnel *> cCaveTunnels;
+
+
+
+
+
+/// A collection of connected tunnels, possibly branching.
+class cStructGenWormNestCaves::cCaveSystem
+{
+public:
+ // The generating block position; is read directly in cStructGenWormNestCaves::GetCavesForChunk()
+ int m_BlockX;
+ int m_BlockZ;
+
+ cCaveSystem(int a_BlockX, int a_BlockZ, int a_MaxOffset, int a_Size, cNoise & a_Noise);
+ ~cCaveSystem();
+
+ /// Carves the cave system into the chunk specified
+ void ProcessChunk(
+ int a_ChunkX, int a_ChunkZ,
+ cChunkDef::BlockTypes & a_BlockTypes,
+ cChunkDef::HeightMap & a_HeightMap
+ );
+
+ #ifdef _DEBUG
+ AString ExportAsSVG(int a_Color, int a_OffsetX, int a_OffsetZ) const;
+ #endif // _DEBUG
+
+protected:
+ int m_Size;
+ cCaveTunnels m_Tunnels;
+
+ void Clear(void);
+
+ /// Generates a_Segment successive tunnels, with possible branches. Generates the same output for the same [x, y, z, a_Segments]
+ void GenerateTunnelsFromPoint(
+ int a_OriginX, int a_OriginY, int a_OriginZ,
+ cNoise & a_Noise, int a_Segments
+ );
+
+ /// Returns a radius based on the location provided.
+ int GetRadius(cNoise & a_Noise, int a_OriginX, int a_OriginY, int a_OriginZ);
+} ;
+
+
+
+
+
+///////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
+// cCaveTunnel:
+
+cCaveTunnel::cCaveTunnel(
+ int a_BlockStartX, int a_BlockStartY, int a_BlockStartZ, int a_StartRadius,
+ int a_BlockEndX, int a_BlockEndY, int a_BlockEndZ, int a_EndRadius,
+ cNoise & a_Noise
+)
+{
+ m_Points.push_back(cCaveDefPoint(a_BlockStartX, a_BlockStartY, a_BlockStartZ, a_StartRadius));
+ m_Points.push_back(cCaveDefPoint(a_BlockEndX, a_BlockEndY, a_BlockEndZ, a_EndRadius));
+
+ if ((a_BlockStartY <= 0) && (a_BlockEndY <= 0))
+ {
+ // Don't bother detailing this cave, it's under the world anyway
+ return;
+ }
+
+ Randomize(a_Noise);
+ Smooth();
+
+ // We know that the linear finishing won't affect the bounding box, so let's calculate it now, as we have less data:
+ CalcBoundingBox();
+
+ FinishLinear();
+}
+
+
+
+
+
+void cCaveTunnel::Randomize(cNoise & a_Noise)
+{
+ // Repeat 4 times:
+ for (int i = 0; i < 4; i++)
+ {
+ // For each already present point, insert a point in between it and its predecessor, shifted randomly.
+ int PrevX = m_Points.front().m_BlockX;
+ int PrevY = m_Points.front().m_BlockY;
+ int PrevZ = m_Points.front().m_BlockZ;
+ int PrevR = m_Points.front().m_Radius;
+ cCaveDefPoints Pts;
+ Pts.reserve(m_Points.size() * 2 + 1);
+ Pts.push_back(m_Points.front());
+ for (cCaveDefPoints::const_iterator itr = m_Points.begin() + 1, end = m_Points.end(); itr != end; ++itr)
+ {
+ int Random = a_Noise.IntNoise3DInt(PrevX, PrevY, PrevZ + i) / 11;
+ int len = (PrevX - itr->m_BlockX) * (PrevX - itr->m_BlockX);
+ len += (PrevY - itr->m_BlockY) * (PrevY - itr->m_BlockY);
+ len += (PrevZ - itr->m_BlockZ) * (PrevZ - itr->m_BlockZ);
+ len = 3 * (int)sqrt((double)len) / 4;
+ int Rad = std::min(MAX_RADIUS, std::max(MIN_RADIUS, (PrevR + itr->m_Radius) / 2 + (Random % 3) - 1));
+ Random /= 4;
+ int x = (itr->m_BlockX + PrevX) / 2 + (Random % (len + 1) - len / 2);
+ Random /= 256;
+ int y = (itr->m_BlockY + PrevY) / 2 + (Random % (len / 2 + 1) - len / 4);
+ Random /= 256;
+ int z = (itr->m_BlockZ + PrevZ) / 2 + (Random % (len + 1) - len / 2);
+ Pts.push_back(cCaveDefPoint(x, y, z, Rad));
+ Pts.push_back(*itr);
+ PrevX = itr->m_BlockX;
+ PrevY = itr->m_BlockY;
+ PrevZ = itr->m_BlockZ;
+ PrevR = itr->m_Radius;
+ }
+ std::swap(Pts, m_Points);
+ }
+}
+
+
+
+
+
+bool cCaveTunnel::RefineDefPoints(const cCaveDefPoints & a_Src, cCaveDefPoints & a_Dst)
+{
+ // Smoothing: for each line segment, add points on its 1/4 lengths
+ bool res = false;
+ int Num = a_Src.size() - 2; // this many intermediary points
+ a_Dst.clear();
+ a_Dst.reserve(Num * 2 + 2);
+ cCaveDefPoints::const_iterator itr = a_Src.begin() + 1;
+ a_Dst.push_back(a_Src.front());
+ int PrevX = a_Src.front().m_BlockX;
+ int PrevY = a_Src.front().m_BlockY;
+ int PrevZ = a_Src.front().m_BlockZ;
+ int PrevR = a_Src.front().m_Radius;
+ for (int i = 0; i <= Num; ++i, ++itr)
+ {
+ int dx = itr->m_BlockX - PrevX;
+ int dy = itr->m_BlockY - PrevY;
+ int dz = itr->m_BlockZ - PrevZ;
+ if (abs(dx) + abs(dz) + abs(dy) < 6)
+ {
+ // Too short a segment to smooth-subdivide into quarters
+ PrevX = itr->m_BlockX;
+ PrevY = itr->m_BlockY;
+ PrevZ = itr->m_BlockZ;
+ PrevR = itr->m_Radius;
+ continue;
+ }
+ int dr = itr->m_Radius - PrevR;
+ int Rad1 = std::max(PrevR + 1 * dr / 4, 1);
+ int Rad2 = std::max(PrevR + 3 * dr / 4, 1);
+ a_Dst.push_back(cCaveDefPoint(PrevX + 1 * dx / 4, PrevY + 1 * dy / 4, PrevZ + 1 * dz / 4, Rad1));
+ a_Dst.push_back(cCaveDefPoint(PrevX + 3 * dx / 4, PrevY + 3 * dy / 4, PrevZ + 3 * dz / 4, Rad2));
+ PrevX = itr->m_BlockX;
+ PrevY = itr->m_BlockY;
+ PrevZ = itr->m_BlockZ;
+ PrevR = itr->m_Radius;
+ res = true;
+ }
+ a_Dst.push_back(a_Src.back());
+ return res && (a_Src.size() < a_Dst.size());
+}
+
+
+
+
+
+void cCaveTunnel::Smooth(void)
+{
+ cCaveDefPoints Pts;
+ while (true)
+ {
+ if (!RefineDefPoints(m_Points, Pts))
+ {
+ std::swap(Pts, m_Points);
+ return;
+ }
+ if (!RefineDefPoints(Pts, m_Points))
+ {
+ return;
+ }
+ }
+}
+
+
+
+
+
+void cCaveTunnel::FinishLinear(void)
+{
+ // For each segment, use Bresenham's 3D line algorithm to draw a "line" of defpoints
+ cCaveDefPoints Pts;
+ std::swap(Pts, m_Points);
+
+ m_Points.reserve(Pts.size() * 3);
+ int PrevX = Pts.front().m_BlockX;
+ int PrevY = Pts.front().m_BlockY;
+ int PrevZ = Pts.front().m_BlockZ;
+ for (cCaveDefPoints::const_iterator itr = Pts.begin() + 1, end = Pts.end(); itr != end; ++itr)
+ {
+ int x1 = itr->m_BlockX;
+ int y1 = itr->m_BlockY;
+ int z1 = itr->m_BlockZ;
+ int dx = abs(x1 - PrevX);
+ int dy = abs(y1 - PrevY);
+ int dz = abs(z1 - PrevZ);
+ int sx = (PrevX < x1) ? 1 : -1;
+ int sy = (PrevY < y1) ? 1 : -1;
+ int sz = (PrevZ < z1) ? 1 : -1;
+ int err = dx - dz;
+ int R = itr->m_Radius;
+
+ if (dx >= std::max(dy, dz)) // x dominant
+ {
+ int yd = dy - dx / 2;
+ int zd = dz - dx / 2;
+
+ while (true)
+ {
+ m_Points.push_back(cCaveDefPoint(PrevX, PrevY, PrevZ, R));
+
+ if (PrevX == x1)
+ {
+ break;
+ }
+
+ if (yd >= 0) // move along y
+ {
+ PrevY += sy;
+ yd -= dx;
+ }
+
+ if (zd >= 0) // move along z
+ {
+ PrevZ += sz;
+ zd -= dx;
+ }
+
+ // move along x
+ PrevX += sx;
+ yd += dy;
+ zd += dz;
+ }
+ }
+ else if (dy >= std::max(dx, dz)) // y dominant
+ {
+ int xd = dx - dy / 2;
+ int zd = dz - dy / 2;
+
+ while (true)
+ {
+ m_Points.push_back(cCaveDefPoint(PrevX, PrevY, PrevZ, R));
+
+ if (PrevY == y1)
+ {
+ break;
+ }
+
+ if (xd >= 0) // move along x
+ {
+ PrevX += sx;
+ xd -= dy;
+ }
+
+ if (zd >= 0) // move along z
+ {
+ PrevZ += sz;
+ zd -= dy;
+ }
+
+ // move along y
+ PrevY += sy;
+ xd += dx;
+ zd += dz;
+ }
+ }
+ else
+ {
+ // z dominant
+ ASSERT(dz >= std::max(dx, dy));
+ int xd = dx - dz / 2;
+ int yd = dy - dz / 2;
+
+ while (true)
+ {
+ m_Points.push_back(cCaveDefPoint(PrevX, PrevY, PrevZ, R));
+
+ if (PrevZ == z1)
+ {
+ break;
+ }
+
+ if (xd >= 0) // move along x
+ {
+ PrevX += sx;
+ xd -= dz;
+ }
+
+ if (yd >= 0) // move along y
+ {
+ PrevY += sy;
+ yd -= dz;
+ }
+
+ // move along z
+ PrevZ += sz;
+ xd += dx;
+ yd += dy;
+ }
+ } // if (which dimension is dominant)
+ } // for itr
+}
+
+
+
+
+
+void cCaveTunnel::CalcBoundingBox(void)
+{
+ m_MinBlockX = m_MaxBlockX = m_Points.front().m_BlockX;
+ m_MinBlockY = m_MaxBlockY = m_Points.front().m_BlockY;
+ m_MinBlockZ = m_MaxBlockZ = m_Points.front().m_BlockZ;
+ for (cCaveDefPoints::const_iterator itr = m_Points.begin() + 1, end = m_Points.end(); itr != end; ++itr)
+ {
+ m_MinBlockX = std::min(m_MinBlockX, itr->m_BlockX - itr->m_Radius);
+ m_MaxBlockX = std::max(m_MaxBlockX, itr->m_BlockX + itr->m_Radius);
+ m_MinBlockY = std::min(m_MinBlockY, itr->m_BlockY - itr->m_Radius);
+ m_MaxBlockY = std::max(m_MaxBlockY, itr->m_BlockY + itr->m_Radius);
+ m_MinBlockZ = std::min(m_MinBlockZ, itr->m_BlockZ - itr->m_Radius);
+ m_MaxBlockZ = std::max(m_MaxBlockZ, itr->m_BlockZ + itr->m_Radius);
+ } // for itr - m_Points[]
+}
+
+
+
+
+
+void cCaveTunnel::ProcessChunk(
+ int a_ChunkX, int a_ChunkZ,
+ cChunkDef::BlockTypes & a_BlockTypes,
+ cChunkDef::HeightMap & a_HeightMap
+)
+{
+ int BaseX = a_ChunkX * cChunkDef::Width;
+ int BaseZ = a_ChunkZ * cChunkDef::Width;
+ if (
+ (BaseX > m_MaxBlockX) || (BaseX + cChunkDef::Width < m_MinBlockX) ||
+ (BaseX > m_MaxBlockX) || (BaseX + cChunkDef::Width < m_MinBlockX)
+ )
+ {
+ // Tunnel does not intersect the chunk at all, bail out
+ return;
+ }
+
+ int BlockStartX = a_ChunkX * cChunkDef::Width;
+ int BlockStartZ = a_ChunkZ * cChunkDef::Width;
+ int BlockEndX = BlockStartX + cChunkDef::Width;
+ int BlockEndZ = BlockStartZ + cChunkDef::Width;
+ for (cCaveDefPoints::const_iterator itr = m_Points.begin(), end = m_Points.end(); itr != end; ++itr)
+ {
+ if (
+ (itr->m_BlockX + itr->m_Radius < BlockStartX) ||
+ (itr->m_BlockX - itr->m_Radius > BlockEndX) ||
+ (itr->m_BlockZ + itr->m_Radius < BlockStartZ) ||
+ (itr->m_BlockZ - itr->m_Radius > BlockEndZ)
+ )
+ {
+ // Cannot intersect, bail out early
+ continue;
+ }
+
+ // Carve out a sphere around the xyz point, m_Radius in diameter; skip 3/7 off the top and bottom:
+ int DifX = itr->m_BlockX - BlockStartX; // substitution for faster calc
+ int DifY = itr->m_BlockY;
+ int DifZ = itr->m_BlockZ - BlockStartZ; // substitution for faster calc
+ int Bottom = std::max(itr->m_BlockY - 3 * itr->m_Radius / 7, 1);
+ int Top = std::min(itr->m_BlockY + 3 * itr->m_Radius / 7, (int)(cChunkDef::Height));
+ int SqRad = itr->m_Radius * itr->m_Radius;
+ for (int z = 0; z < cChunkDef::Width; z++) for (int x = 0; x < cChunkDef::Width; x++)
+ {
+ for (int y = Bottom; y <= Top; y++)
+ {
+ int SqDist = (DifX - x) * (DifX - x) + (DifY - y) * (DifY - y) + (DifZ - z) * (DifZ - z);
+ if (4 * SqDist <= SqRad)
+ {
+ switch (cChunkDef::GetBlock(a_BlockTypes, x, y, z))
+ {
+ // Only carve out these specific block types
+ case E_BLOCK_DIRT:
+ case E_BLOCK_GRASS:
+ case E_BLOCK_STONE:
+ case E_BLOCK_COBBLESTONE:
+ case E_BLOCK_GRAVEL:
+ case E_BLOCK_SAND:
+ case E_BLOCK_SANDSTONE:
+ case E_BLOCK_NETHERRACK:
+ case E_BLOCK_COAL_ORE:
+ case E_BLOCK_IRON_ORE:
+ case E_BLOCK_GOLD_ORE:
+ case E_BLOCK_DIAMOND_ORE:
+ case E_BLOCK_REDSTONE_ORE:
+ case E_BLOCK_REDSTONE_ORE_GLOWING:
+ {
+ cChunkDef::SetBlock(a_BlockTypes, x, y, z, E_BLOCK_AIR);
+ break;
+ }
+ default: break;
+ }
+ }
+ } // for y
+ } // for x, z
+ } // for itr - m_Points[]
+
+ /*
+ #ifdef _DEBUG
+ // For debugging purposes, outline the shape of the cave using glowstone, *after* carving the entire cave:
+ for (cCaveDefPoints::const_iterator itr = m_Points.begin(), end = m_Points.end(); itr != end; ++itr)
+ {
+ int DifX = itr->m_BlockX - BlockStartX; // substitution for faster calc
+ int DifZ = itr->m_BlockZ - BlockStartZ; // substitution for faster calc
+ if (
+ (DifX >= 0) && (DifX < cChunkDef::Width) &&
+ (itr->m_BlockY > 0) && (itr->m_BlockY < cChunkDef::Height) &&
+ (DifZ >= 0) && (DifZ < cChunkDef::Width)
+ )
+ {
+ cChunkDef::SetBlock(a_BlockTypes, DifX, itr->m_BlockY, DifZ, E_BLOCK_GLOWSTONE);
+ }
+ } // for itr - m_Points[]
+ #endif // _DEBUG
+ //*/
+}
+
+
+
+
+
+#ifdef _DEBUG
+AString cCaveTunnel::ExportAsSVG(int a_Color, int a_OffsetX, int a_OffsetZ) const
+{
+ AString SVG;
+ SVG.reserve(m_Points.size() * 20 + 200);
+ AppendPrintf(SVG, "<path style=\"fill:none;stroke:#%06x;stroke-width:1px;\"\nd=\"", a_Color);
+ char Prefix = 'M'; // The first point needs "M" prefix, all the others need "L"
+ for (cCaveDefPoints::const_iterator itr = m_Points.begin(); itr != m_Points.end(); ++itr)
+ {
+ AppendPrintf(SVG, "%c %d,%d ", Prefix, a_OffsetX + itr->m_BlockX, a_OffsetZ + itr->m_BlockZ);
+ Prefix = 'L';
+ }
+ SVG.append("\"/>\n");
+ return SVG;
+}
+#endif // _DEBUG
+
+
+
+
+
+///////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
+// cStructGenWormNestCaves::cCaveSystem:
+
+cStructGenWormNestCaves::cCaveSystem::cCaveSystem(int a_BlockX, int a_BlockZ, int a_MaxOffset, int a_Size, cNoise & a_Noise) :
+ m_BlockX(a_BlockX),
+ m_BlockZ(a_BlockZ),
+ m_Size(a_Size)
+{
+ int Num = 1 + a_Noise.IntNoise2DInt(a_BlockX, a_BlockZ) % 3;
+ for (int i = 0; i < Num; i++)
+ {
+ int OriginX = a_BlockX + (a_Noise.IntNoise3DInt(13 * a_BlockX, 17 * a_BlockZ, 11 * i) / 19) % a_MaxOffset;
+ int OriginZ = a_BlockZ + (a_Noise.IntNoise3DInt(17 * a_BlockX, 13 * a_BlockZ, 11 * i) / 23) % a_MaxOffset;
+ int OriginY = 20 + (a_Noise.IntNoise3DInt(19 * a_BlockX, 13 * a_BlockZ, 11 * i) / 17) % 20;
+
+ // Generate three branches from the origin point:
+ // The tunnels generated depend on X, Y, Z and Branches,
+ // for the same set of numbers it generates the same offsets!
+ // That's why we add a +1 to X in the third line
+ GenerateTunnelsFromPoint(OriginX, OriginY, OriginZ, a_Noise, 3);
+ GenerateTunnelsFromPoint(OriginX, OriginY, OriginZ, a_Noise, 2);
+ GenerateTunnelsFromPoint(OriginX + 1, OriginY, OriginZ, a_Noise, 3);
+ }
+}
+
+
+
+
+
+cStructGenWormNestCaves::cCaveSystem::~cCaveSystem()
+{
+ Clear();
+}
+
+
+
+
+
+
+void cStructGenWormNestCaves::cCaveSystem::ProcessChunk(
+ int a_ChunkX, int a_ChunkZ,
+ cChunkDef::BlockTypes & a_BlockTypes,
+ cChunkDef::HeightMap & a_HeightMap
+)
+{
+ for (cCaveTunnels::const_iterator itr = m_Tunnels.begin(), end = m_Tunnels.end(); itr != end; ++itr)
+ {
+ (*itr)->ProcessChunk(a_ChunkX, a_ChunkZ, a_BlockTypes, a_HeightMap);
+ } // for itr - m_Tunnels[]
+}
+
+
+
+
+
+#ifdef _DEBUG
+AString cStructGenWormNestCaves::cCaveSystem::ExportAsSVG(int a_Color, int a_OffsetX, int a_OffsetZ) const
+{
+ AString SVG;
+ SVG.reserve(512 * 1024);
+ for (cCaveTunnels::const_iterator itr = m_Tunnels.begin(), end = m_Tunnels.end(); itr != end; ++itr)
+ {
+ SVG.append((*itr)->ExportAsSVG(a_Color, a_OffsetX, a_OffsetZ));
+ } // for itr - m_Tunnels[]
+
+ // Base point highlight:
+ AppendPrintf(SVG, "<path style=\"fill:none;stroke:#ff0000;stroke-width:1px;\"\nd=\"M %d,%d L %d,%d\"/>\n",
+ a_OffsetX + m_BlockX - 5, a_OffsetZ + m_BlockZ, a_OffsetX + m_BlockX + 5, a_OffsetZ + m_BlockZ
+ );
+ AppendPrintf(SVG, "<path style=\"fill:none;stroke:#ff0000;stroke-width:1px;\"\nd=\"M %d,%d L %d,%d\"/>\n",
+ a_OffsetX + m_BlockX, a_OffsetZ + m_BlockZ - 5, a_OffsetX + m_BlockX, a_OffsetZ + m_BlockZ + 5
+ );
+
+ // A gray line from the base point to the first point of the ravine, for identification:
+ AppendPrintf(SVG, "<path style=\"fill:none;stroke:#cfcfcf;stroke-width:1px;\"\nd=\"M %d,%d L %d,%d\"/>\n",
+ a_OffsetX + m_BlockX, a_OffsetZ + m_BlockZ,
+ a_OffsetX + m_Tunnels.front()->m_Points.front().m_BlockX,
+ a_OffsetZ + m_Tunnels.front()->m_Points.front().m_BlockZ
+ );
+
+ // Offset guides:
+ if (a_OffsetX > 0)
+ {
+ AppendPrintf(SVG, "<path style=\"fill:none;stroke:#0000ff;stroke-width:1px;\"\nd=\"M %d,0 L %d,1024\"/>\n",
+ a_OffsetX, a_OffsetX
+ );
+ }
+ if (a_OffsetZ > 0)
+ {
+ AppendPrintf(SVG, "<path style=\"fill:none;stroke:#0000ff;stroke-width:1px;\"\nd=\"M 0,%d L 1024,%d\"/>\n",
+ a_OffsetZ, a_OffsetZ
+ );
+ }
+
+ return SVG;
+}
+#endif // _DEBUG
+
+
+
+
+
+void cStructGenWormNestCaves::cCaveSystem::Clear(void)
+{
+ for (cCaveTunnels::const_iterator itr = m_Tunnels.begin(), end = m_Tunnels.end(); itr != end; ++itr)
+ {
+ delete *itr;
+ }
+ m_Tunnels.clear();
+}
+
+
+
+
+
+void cStructGenWormNestCaves::cCaveSystem::GenerateTunnelsFromPoint(
+ int a_OriginX, int a_OriginY, int a_OriginZ,
+ cNoise & a_Noise, int a_NumSegments
+)
+{
+ int DoubleSize = m_Size * 2;
+ int Radius = GetRadius(a_Noise, a_OriginX + a_OriginY, a_OriginY + a_OriginZ, a_OriginZ + a_OriginX);
+ for (int i = a_NumSegments - 1; i >= 0; --i)
+ {
+ int EndX = a_OriginX + (((a_Noise.IntNoise3DInt(a_OriginX, a_OriginY, a_OriginZ + 11 * a_NumSegments) / 7) % DoubleSize) - m_Size) / 2;
+ int EndY = a_OriginY + (((a_Noise.IntNoise3DInt(a_OriginY, 13 * a_NumSegments, a_OriginZ + a_OriginX) / 7) % DoubleSize) - m_Size) / 4;
+ int EndZ = a_OriginZ + (((a_Noise.IntNoise3DInt(a_OriginZ + 17 * a_NumSegments, a_OriginX, a_OriginY) / 7) % DoubleSize) - m_Size) / 2;
+ int EndR = GetRadius(a_Noise, a_OriginX + 7 * i, a_OriginY + 11 * i, a_OriginZ + a_OriginX);
+ m_Tunnels.push_back(new cCaveTunnel(a_OriginX, a_OriginY, a_OriginZ, Radius, EndX, EndY, EndZ, EndR, a_Noise));
+ GenerateTunnelsFromPoint(EndX, EndY, EndZ, a_Noise, i);
+ a_OriginX = EndX;
+ a_OriginY = EndY;
+ a_OriginZ = EndZ;
+ Radius = EndR;
+ } // for i - a_NumSegments
+}
+
+
+
+
+
+int cStructGenWormNestCaves::cCaveSystem::GetRadius(cNoise & a_Noise, int a_OriginX, int a_OriginY, int a_OriginZ)
+{
+ // Instead of a flat distribution noise function, we need to shape it, so that most caves are smallish and only a few select are large
+ int rnd = a_Noise.IntNoise3DInt(a_OriginX, a_OriginY, a_OriginZ) / 11;
+ /*
+ // Not good enough:
+ // The algorithm of choice: emulate gauss-distribution noise by adding 3 flat noises, then fold it in half using absolute value.
+ // To save on processing, use one random value and extract 3 bytes to be separately added as the gaussian noise
+ int sum = (rnd & 0xff) + ((rnd >> 8) & 0xff) + ((rnd >> 16) & 0xff);
+ // sum is now a gaussian-distribution noise within [0 .. 767], with center at 384.
+ // We want mapping 384 -> 3, 0 -> 19, 768 -> 19, so divide by 24 to get [0 .. 31] with center at 16, then use abs() to fold around the center
+ int res = 3 + abs((sum / 24) - 16);
+ */
+
+ // Algorithm of choice: random value in the range of zero to random value - heavily towards zero
+ int res = MIN_RADIUS + (rnd >> 8) % ((rnd % (MAX_RADIUS - MIN_RADIUS)) + 1);
+ return res;
+}
+
+
+
+
+
+///////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
+// cStructGenWormNestCaves:
+
+cStructGenWormNestCaves::~cStructGenWormNestCaves()
+{
+ ClearCache();
+}
+
+
+
+
+
+void cStructGenWormNestCaves::ClearCache(void)
+{
+ for (cCaveSystems::const_iterator itr = m_Cache.begin(), end = m_Cache.end(); itr != end; ++itr)
+ {
+ delete *itr;
+ } // for itr - m_Cache[]
+ m_Cache.clear();
+}
+
+
+
+
+
+void cStructGenWormNestCaves::GenStructures(cChunkDesc & a_ChunkDesc)
+{
+ int ChunkX = a_ChunkDesc.GetChunkX();
+ int ChunkZ = a_ChunkDesc.GetChunkZ();
+ cCaveSystems Caves;
+ GetCavesForChunk(ChunkX, ChunkZ, Caves);
+ for (cCaveSystems::const_iterator itr = Caves.begin(); itr != Caves.end(); ++itr)
+ {
+ (*itr)->ProcessChunk(ChunkX, ChunkZ, a_ChunkDesc.GetBlockTypes(), a_ChunkDesc.GetHeightMap());
+ } // for itr - Caves[]
+}
+
+
+
+
+
+void cStructGenWormNestCaves::GetCavesForChunk(int a_ChunkX, int a_ChunkZ, cStructGenWormNestCaves::cCaveSystems & a_Caves)
+{
+ int BaseX = a_ChunkX * cChunkDef::Width / m_Grid;
+ int BaseZ = a_ChunkZ * cChunkDef::Width / m_Grid;
+ if (BaseX < 0)
+ {
+ --BaseX;
+ }
+ if (BaseZ < 0)
+ {
+ --BaseZ;
+ }
+ BaseX -= NEIGHBORHOOD_SIZE / 2;
+ BaseZ -= NEIGHBORHOOD_SIZE / 2;
+
+ // Walk the cache, move each cave system that we want into a_Caves:
+ int StartX = BaseX * m_Grid;
+ int EndX = (BaseX + NEIGHBORHOOD_SIZE + 1) * m_Grid;
+ int StartZ = BaseZ * m_Grid;
+ int EndZ = (BaseZ + NEIGHBORHOOD_SIZE + 1) * m_Grid;
+ for (cCaveSystems::iterator itr = m_Cache.begin(), end = m_Cache.end(); itr != end;)
+ {
+ if (
+ ((*itr)->m_BlockX >= StartX) && ((*itr)->m_BlockX < EndX) &&
+ ((*itr)->m_BlockZ >= StartZ) && ((*itr)->m_BlockZ < EndZ)
+ )
+ {
+ // want
+ a_Caves.push_back(*itr);
+ itr = m_Cache.erase(itr);
+ }
+ else
+ {
+ // don't want
+ ++itr;
+ }
+ } // for itr - m_Cache[]
+
+ for (int x = 0; x < NEIGHBORHOOD_SIZE; x++)
+ {
+ int RealX = (BaseX + x) * m_Grid;
+ for (int z = 0; z < NEIGHBORHOOD_SIZE; z++)
+ {
+ int RealZ = (BaseZ + z) * m_Grid;
+ bool Found = false;
+ for (cCaveSystems::const_iterator itr = a_Caves.begin(), end = a_Caves.end(); itr != end; ++itr)
+ {
+ if (((*itr)->m_BlockX == RealX) && ((*itr)->m_BlockZ == RealZ))
+ {
+ Found = true;
+ break;
+ }
+ }
+ if (!Found)
+ {
+ a_Caves.push_back(new cCaveSystem(RealX, RealZ, m_MaxOffset, m_Size, m_Noise));
+ }
+ }
+ }
+
+ // Copy a_Caves into m_Cache to the beginning:
+ cCaveSystems CavesCopy(a_Caves);
+ m_Cache.splice(m_Cache.begin(), CavesCopy, CavesCopy.begin(), CavesCopy.end());
+
+ // Trim the cache if it's too long:
+ if (m_Cache.size() > 100)
+ {
+ cCaveSystems::iterator itr = m_Cache.begin();
+ std::advance(itr, 100);
+ for (cCaveSystems::iterator end = m_Cache.end(); itr != end; ++itr)
+ {
+ delete *itr;
+ }
+ itr = m_Cache.begin();
+ std::advance(itr, 100);
+ m_Cache.erase(itr, m_Cache.end());
+ }
+
+ /*
+ // Uncomment this block for debugging the caves' shapes in 2D using an SVG export
+ #ifdef _DEBUG
+ AString SVG;
+ SVG.append("<?xml version=\"1.0\" encoding=\"UTF-8\" standalone=\"no\"?>\n<svg xmlns=\"http://www.w3.org/2000/svg\" width=\"1024\" height = \"1024\">\n");
+ SVG.reserve(2 * 1024 * 1024);
+ for (cCaveSystems::const_iterator itr = a_Caves.begin(), end = a_Caves.end(); itr != end; ++itr)
+ {
+ int Color = 0x10 * abs((*itr)->m_BlockX / m_Grid);
+ Color |= 0x1000 * abs((*itr)->m_BlockZ / m_Grid);
+ SVG.append((*itr)->ExportAsSVG(Color, 512, 512));
+ }
+ SVG.append("</svg>\n");
+
+ AString fnam;
+ Printf(fnam, "wnc\\%03d_%03d.svg", a_ChunkX, a_ChunkZ);
+ cFile File(fnam, cFile::fmWrite);
+ File.Write(SVG.c_str(), SVG.size());
+ #endif // _DEBUG
+ //*/
+}
+
+
+
+
+
+
+///////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
+// cStructGenMarbleCaves:
+
+static float GetMarbleNoise( float x, float y, float z, cNoise & a_Noise )
+{
+ static const float PI_2 = 1.57079633f;
+ float oct1 = (a_Noise.CubicNoise3D(x * 0.1f, y * 0.1f, z * 0.1f )) * 4;
+
+ oct1 = oct1 * oct1 * oct1;
+ if (oct1 < 0.f) oct1 = PI_2;
+ if (oct1 > PI_2) oct1 = PI_2;
+
+ return oct1;
+}
+
+
+
+
+
+void cStructGenMarbleCaves::GenStructures(cChunkDesc & a_ChunkDesc)
+{
+ cNoise Noise(m_Seed);
+ for (int z = 0; z < cChunkDef::Width; z++)
+ {
+ const float zz = (float)(a_ChunkDesc.GetChunkZ() * cChunkDef::Width + z);
+ for (int x = 0; x < cChunkDef::Width; x++)
+ {
+ const float xx = (float)(a_ChunkDesc.GetChunkX() * cChunkDef::Width + x);
+
+ int Top = a_ChunkDesc.GetHeight(x, z);
+ for (int y = 1; y < Top; ++y )
+ {
+ if (a_ChunkDesc.GetBlockType(x, y, z) != E_BLOCK_STONE)
+ {
+ continue;
+ }
+
+ const float yy = (float)y;
+ const float WaveNoise = 1;
+ if (cosf(GetMarbleNoise(xx, yy * 0.5f, zz, Noise)) * fabs(cosf(yy * 0.2f + WaveNoise * 2) * 0.75f + WaveNoise) > 0.0005f)
+ {
+ a_ChunkDesc.SetBlockType(x, y, z, E_BLOCK_AIR);
+ }
+ } // for y
+ } // for x
+ } // for z
+}
+
+
+
+
+
+///////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
+// cStructGenDualRidgeCaves:
+
+void cStructGenDualRidgeCaves::GenStructures(cChunkDesc & a_ChunkDesc)
+{
+ for (int z = 0; z < cChunkDef::Width; z++)
+ {
+ const float zz = (float)(a_ChunkDesc.GetChunkZ() * cChunkDef::Width + z) / 10;
+ for (int x = 0; x < cChunkDef::Width; x++)
+ {
+ const float xx = (float)(a_ChunkDesc.GetChunkX() * cChunkDef::Width + x) / 10;
+
+ int Top = a_ChunkDesc.GetHeight(x, z);
+ for (int y = 1; y <= Top; ++y)
+ {
+ const float yy = (float)y / 10;
+ const float WaveNoise = 1;
+ float n1 = m_Noise1.CubicNoise3D(xx, yy, zz);
+ float n2 = m_Noise2.CubicNoise3D(xx, yy, zz);
+ float n3 = m_Noise1.CubicNoise3D(xx * 4, yy * 4, zz * 4) / 4;
+ float n4 = m_Noise2.CubicNoise3D(xx * 4, yy * 4, zz * 4) / 4;
+ if ((abs(n1 + n3) * abs(n2 + n4)) > m_Threshold)
+ {
+ a_ChunkDesc.SetBlockType(x, y, z, E_BLOCK_AIR);
+ }
+ } // for y
+ } // for x
+ } // for z
+}
+
+
+
+