diff --git a/src/mapgen/mapgen_carpathian.cpp b/src/mapgen/mapgen_carpathian.cpp index 1a2456ae9..0cde17037 100644 --- a/src/mapgen/mapgen_carpathian.cpp +++ b/src/mapgen/mapgen_carpathian.cpp @@ -192,7 +192,7 @@ void MapgenCarpathianParams::writeParams(Settings *settings) const } -/////////////////////////////////////////////////////////////////////////////// +//////////////////////////////////////////////////////////////////////////////// // Lerp function @@ -212,7 +212,7 @@ float MapgenCarpathian::getSteps(float noise) } -/////////////////////////////////////////////////////////////////////////////// +//////////////////////////////////////////////////////////////////////////////// void MapgenCarpathian::makeChunk(BlockMakeData *data) @@ -298,7 +298,7 @@ void MapgenCarpathian::makeChunk(BlockMakeData *data) } -/////////////////////////////////////////////////////////////////////////////// +//////////////////////////////////////////////////////////////////////////////// int MapgenCarpathian::getSpawnLevelAtPoint(v2s16 p) @@ -338,14 +338,15 @@ float MapgenCarpathian::terrainLevelAtPoint(s16 x, s16 z) float hill2 = getLerp(height3, height4, mnt_var); float hill3 = getLerp(height3, height2, mnt_var); float hill4 = getLerp(height1, height4, mnt_var); - float hilliness = std::fmax(std::fmin(hill1, hill2), std::fmin(hill3, hill4)); + float hilliness = + std::fmax(std::fmin(hill1, hill2), std::fmin(hill3, hill4)); // Rolling hills float hill_mnt = hilliness * pow(n_hills, 2.f); float hills = pow(hter, 3.f) * hill_mnt; // Ridged mountains - float ridge_mnt = hilliness * (1.f - fabs(n_ridge_mnt)); + float ridge_mnt = hilliness * (1.f - std::fabs(n_ridge_mnt)); float ridged_mountains = pow(rter, 3.f) * ridge_mnt; // Step (terraced) mountains @@ -364,7 +365,7 @@ float MapgenCarpathian::terrainLevelAtPoint(s16 x, s16 z) } -/////////////////////////////////////////////////////////////////////////////// +//////////////////////////////////////////////////////////////////////////////// int MapgenCarpathian::generateTerrain() @@ -373,10 +374,6 @@ int MapgenCarpathian::generateTerrain() MapNode mn_stone(c_stone); MapNode mn_water(c_water_source); - s16 stone_surface_max_y = -MAX_MAP_GENERATION_LIMIT; - u32 index2d = 0; - u32 index3d = 0; - // Calculate noise for terrain generation noise_base->perlinMap2D(node_min.X, node_min.Z); noise_height1->perlinMap2D(node_min.X, node_min.Z); @@ -392,70 +389,81 @@ int MapgenCarpathian::generateTerrain() noise_mnt_var->perlinMap3D(node_min.X, node_min.Y - 1, node_min.Z); //// Place nodes - for (s16 z = node_min.Z; z <= node_max.Z; z++) { - for (s16 y = node_min.Y - 1; y <= node_max.Y + 1; y++) { - u32 vi = vm->m_area.index(node_min.X, y, z); - for (s16 x = node_min.X; x <= node_max.X; - x++, vi++, index2d++, index3d++) { - if (vm->m_data[vi].getContent() != CONTENT_IGNORE) - continue; + const v3s16 &em = vm->m_area.getExtent(); + s16 stone_surface_max_y = -MAX_MAP_GENERATION_LIMIT; + u32 index2d = 0; - // Base terrain - float ground = noise_base->result[index2d]; + for (s16 z = node_min.Z; z <= node_max.Z; z++) + for (s16 x = node_min.X; x <= node_max.X; x++, index2d++) { + // Base terrain + float ground = noise_base->result[index2d]; - // Gradient & shallow seabed - s32 grad = (y < water_level) ? grad_wl + (water_level - y) * 3 : 1 - y; + // Hill/Mountain height (hilliness) + float height1 = noise_height1->result[index2d]; + float height2 = noise_height2->result[index2d]; + float height3 = noise_height3->result[index2d]; + float height4 = noise_height4->result[index2d]; - // Hill/Mountain height (hilliness) - float height1 = noise_height1->result[index2d]; - float height2 = noise_height2->result[index2d]; - float height3 = noise_height3->result[index2d]; - float height4 = noise_height4->result[index2d]; - float mnt_var = noise_mnt_var->result[index3d]; - // Combine height noises and apply 3D variation - float hill1 = getLerp(height1, height2, mnt_var); - float hill2 = getLerp(height3, height4, mnt_var); - float hill3 = getLerp(height3, height2, mnt_var); - float hill4 = getLerp(height1, height4, mnt_var); - // 'hilliness' determines whether hills/mountains are - // small or large - float hilliness = std::fmax(std::fmin(hill1, hill2), std::fmin(hill3, hill4)); + // Rolling hills + float hterabs = std::fabs(noise_hills_terrain->result[index2d]); + float n_hills = noise_hills->result[index2d]; + float hill_mnt = hterabs * hterabs * hterabs * n_hills * n_hills; - // Rolling hills - float hter = noise_hills_terrain->result[index2d]; - float n_hills = noise_hills->result[index2d]; - float hill_mnt = hilliness * pow(n_hills, 2.f); - float hills = pow(fabs(hter), 3.f) * hill_mnt; + // Ridged mountains + float rterabs = std::fabs(noise_ridge_terrain->result[index2d]); + float n_ridge_mnt = noise_ridge_mnt->result[index2d]; + float ridge_mnt = rterabs * rterabs * rterabs * + (1.f - std::fabs(n_ridge_mnt)); - // Ridged mountains - float rter = noise_ridge_terrain->result[index2d]; - float n_ridge_mnt = noise_ridge_mnt->result[index2d]; - float ridge_mnt = hilliness * (1.f - fabs(n_ridge_mnt)); - float ridged_mountains = pow(fabs(rter), 3.f) * ridge_mnt; + // Step (terraced) mountains + float sterabs = std::fabs(noise_step_terrain->result[index2d]); + float n_step_mnt = noise_step_mnt->result[index2d]; + float step_mnt = sterabs * sterabs * sterabs * getSteps(n_step_mnt); - // Step (terraced) mountains - float ster = noise_step_terrain->result[index2d]; - float n_step_mnt = noise_step_mnt->result[index2d]; - float step_mnt = hilliness * getSteps(n_step_mnt); - float step_mountains = pow(fabs(ster), 3.f) * step_mnt; + // Initialise 3D noise index and voxelmanip index to column base + u32 index3d = (z - node_min.Z) * zstride_1u1d + (x - node_min.X); + u32 vi = vm->m_area.index(x, node_min.Y - 1, z); - // Final terrain level - float mountains = hills + ridged_mountains + step_mountains; - float surface_level = ground + mountains + grad; + for (s16 y = node_min.Y - 1; y <= node_max.Y + 1; + y++, + index3d += ystride, + VoxelArea::add_y(em, vi, 1)) { + if (vm->m_data[vi].getContent() != CONTENT_IGNORE) + continue; - if (y < surface_level) { - vm->m_data[vi] = mn_stone; // Stone - if (y > stone_surface_max_y) - stone_surface_max_y = y; - } else if (y <= water_level) { - vm->m_data[vi] = mn_water; // Sea water - } else { - vm->m_data[vi] = mn_air; // Air - } + // Combine height noises and apply 3D variation + float mnt_var = noise_mnt_var->result[index3d]; + float hill1 = getLerp(height1, height2, mnt_var); + float hill2 = getLerp(height3, height4, mnt_var); + float hill3 = getLerp(height3, height2, mnt_var); + float hill4 = getLerp(height1, height4, mnt_var); + + // 'hilliness' determines whether hills/mountains are + // small or large + float hilliness = + std::fmax(std::fmin(hill1, hill2), std::fmin(hill3, hill4)); + float hills = hill_mnt * hilliness; + float ridged_mountains = ridge_mnt * hilliness; + float step_mountains = step_mnt * hilliness; + + // Gradient & shallow seabed + s32 grad = (y < water_level) ? grad_wl + (water_level - y) * 3 : + 1 - y; + + // Final terrain level + float mountains = hills + ridged_mountains + step_mountains; + float surface_level = ground + mountains + grad; + + if (y < surface_level) { + vm->m_data[vi] = mn_stone; // Stone + if (y > stone_surface_max_y) + stone_surface_max_y = y; + } else if (y <= water_level) { + vm->m_data[vi] = mn_water; // Sea water + } else { + vm->m_data[vi] = mn_air; // Air } - index2d -= ystride; } - index2d += ystride; } return stone_surface_max_y;