builtin/common/vector.lua


1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
76
77
78
79
80
81
82
83
84
85
86
87
88
89
90
91
92
93
94
95
96
97
98
99
100
101
102
103
104
105
106
107
108
109
110
111
112
113
114
115
116
117
118
119
120
121
122
123
124
125
126
127
128
129
130
131
132
133


vector = {}

function vector.new(a, b, c)
	if type(a) == "table" then
		assert(a.x and a.y and a.z, "Invalid vector passed to vector.new()")
		return {x=a.x, y=a.y, z=a.z}
	elseif a then
		assert(b and c, "Invalid arguments for vector.new()")
		return {x=a, y=b, z=c}
	end
	return {x=0, y=0, z=0}
end

function vector.equals(a, b)
	return a.x == b.x and
	       a.y == b.y and
	       a.z == b.z
end

function vector.length(v)
	return math.hypot(v.x, math.hypot(v.y, v.z))
end

function vector.normalize(v)
	local len = vector.length(v)
	if len == 0 then
		return {x=0, y=0, z=0}
	else
		return vector.divide(v, len)
	end
end

function vector.round(v)
	return {
		x = math.floor(v.x + 0.5),
		y = math.floor(v.y + 0.5),
		z = math.floor(v.z + 0.5)
	}
end

function vector.apply(v, func)
	return {
		x = func(v.x),
		y = func(v.y),
		z = func(v.z)
	}
end

function vector.distance(a, b)
	local x = a.x - b.x
	local y = a.y - b.y
	local z = a.z - b.z
	return math.hypot(x, math.hypot(y, z))
end

function vector.direction(pos1, pos2)
	local x_raw = pos2.x - pos1.x
	local y_raw = pos2.y - pos1.y
	local z_raw = pos2.z - pos1.z
	local x_abs = math.abs(x_raw)
	local y_abs = math.abs(y_raw)
	local z_abs = math.abs(z_raw)
	if x_abs >= y_abs and
	   x_abs >= z_abs then
		y_raw = y_raw * (1 / x_abs)
		z_raw = z_raw * (1 / x_abs)
		x_raw = x_raw / x_abs
	end
	if y_abs >= x_abs and
	   y_abs >= z_abs then
		x_raw = x_raw * (1 / y_abs)
		z_raw = z_raw * (1 / y_abs)
		y_raw = y_raw / y_abs
	end
	if z_abs >= y_abs and
	   z_abs >= x_abs then
		x_raw = x_raw * (1 / z_abs)
		y_raw = y_raw * (1 / z_abs)
		z_raw = z_raw / z_abs
	end
	return {x=x_raw, y=y_raw, z=z_raw}
end


function vector.add(a, b)
	if type(b) == "table" then
		return {x = a.x + b.x,
			y = a.y + b.y,
			z = a.z + b.z}
	else
		return {x = a.x + b,
			y = a.y + b,
			z = a.z + b}
	end
end

function vector.subtract(a, b)
	if type(b) == "table" then
		return {x = a.x - b.x,
			y = a.y - b.y,
			z = a.z - b.z}
	else
		return {x = a.x - b,
			y = a.y - b,
			z = a.z - b}
	end
end

function vector.multiply(a, b)
	if type(b) == "table" then
		return {x = a.x * b.x,
			y = a.y * b.y,
			z = a.z * b.z}
	else
		return {x = a.x * b,
			y = a.y * b,
			z = a.z * b}
	end
end

function vector.divide(a, b)
	if type(b) == "table" then
		return {x = a.x / b.x,
			y = a.y / b.y,
			z = a.z / b.z}
	else
		return {x = a.x / b,
			y = a.y / b,
			z = a.z / b}
	end
end
/*
Minetest
Copyright (C) 2010-2013 celeron55, Perttu Ahola <celeron55@gmail.com>,
			  2012-2013 RealBadAngel, Maciej Kasatkin <mk@realbadangel.pl>
This program is free software; you can redistribute it and/or modify
it under the terms of the GNU Lesser General Public License as published by
the Free Software Foundation; either version 2.1 of the License, or
(at your option) any later version.

This program is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
GNU Lesser General Public License for more details.

You should have received a copy of the GNU Lesser General Public License along
with this program; if not, write to the Free Software Foundation, Inc.,
51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA.
*/

#include "irr_v3d.h"
#include <stack>
#include "util/pointer.h"
#include "util/numeric.h"
#include "util/mathconstants.h"
#include "map.h"
#include "environment.h"
#include "nodedef.h"
#include "treegen.h"

namespace treegen
{

void make_tree(MMVManip &vmanip, v3s16 p0,
		bool is_apple_tree, INodeDefManager *ndef, s32 seed)
{
	/*
		NOTE: Tree-placing code is currently duplicated in the engine
		and in games that have saplings; both are deprecated but not
		replaced yet
	*/
	MapNode treenode(ndef->getId("mapgen_tree"));
	MapNode leavesnode(ndef->getId("mapgen_leaves"));
	MapNode applenode(ndef->getId("mapgen_apple"));

	PseudoRandom pr(seed);
	s16 trunk_h = pr.range(4, 5);
	v3s16 p1 = p0;
	for (s16 ii = 0; ii < trunk_h; ii++) {
		if (vmanip.m_area.contains(p1)) {
			u32 vi = vmanip.m_area.index(p1);
			vmanip.m_data[vi] = treenode;
		}
		p1.Y++;
	}

	// p1 is now the last piece of the trunk
	p1.Y -= 1;

	VoxelArea leaves_a(v3s16(-2, -1, -2), v3s16(2, 2, 2));
	//SharedPtr<u8> leaves_d(new u8[leaves_a.getVolume()]);
	Buffer<u8> leaves_d(leaves_a.getVolume());
	for (s32 i = 0; i < leaves_a.getVolume(); i++)
		leaves_d[i] = 0;

	// Force leaves at near the end of the trunk
	s16 d = 1;
	for (s16 z = -d; z <= d; z++)
	for (s16 y = -d; y <= d; y++)
	for (s16 x = -d; x <= d; x++) {
		leaves_d[leaves_a.index(v3s16(x, y, z))] = 1;
	}

	// Add leaves randomly
	for (u32 iii = 0; iii < 7; iii++) {
		v3s16 p(
			pr.range(leaves_a.MinEdge.X, leaves_a.MaxEdge.X - d),
			pr.range(leaves_a.MinEdge.Y, leaves_a.MaxEdge.Y - d),
			pr.range(leaves_a.MinEdge.Z, leaves_a.MaxEdge.Z - d)
		);

		for (s16 z = 0; z <= d; z++)
		for (s16 y = 0; y <= d; y++)
		for (s16 x = 0; x <= d; x++) {
			leaves_d[leaves_a.index(p + v3s16(x, y, z))] = 1;
		}
	}

	// Blit leaves to vmanip
	for (s16 z = leaves_a.MinEdge.Z; z <= leaves_a.MaxEdge.Z; z++)
	for (s16 y = leaves_a.MinEdge.Y; y <= leaves_a.MaxEdge.Y; y++) {
		v3s16 pmin(leaves_a.MinEdge.X, y, z);
		u32 i = leaves_a.index(pmin);
		u32 vi = vmanip.m_area.index(pmin + p1);
		for (s16 x = leaves_a.MinEdge.X; x <= leaves_a.MaxEdge.X; x++) {
			v3s16 p(x, y, z);
			if (vmanip.m_area.contains(p + p1) == true &&
					(vmanip.m_data[vi].getContent() == CONTENT_AIR ||
					vmanip.m_data[vi].getContent() == CONTENT_IGNORE)) {
				if (leaves_d[i] == 1) {
					bool is_apple = pr.range(0, 99) < 10;
					if (is_apple_tree && is_apple)
						vmanip.m_data[vi] = applenode;
					else
						vmanip.m_data[vi] = leavesnode;
				}
			}
			vi++;
			i++;
		}
	}
}


// L-System tree LUA spawner
treegen::error spawn_ltree(ServerEnvironment *env, v3s16 p0,
		INodeDefManager *ndef, TreeDef tree_definition)
{
	ServerMap *map = &env->getServerMap();
	std::map<v3s16, MapBlock*> modified_blocks;
	MMVManip vmanip(map);
	v3s16 tree_blockp = getNodeBlockPos(p0);
	treegen::error e;

	vmanip.initialEmerge(tree_blockp - v3s16(1, 1, 1), tree_blockp + v3s16(1, 3, 1));
	e = make_ltree(vmanip, p0, ndef, tree_definition);
	if (e != SUCCESS)
		return e;

	vmanip.blitBackAll(&modified_blocks);

	// update lighting
	std::map<v3s16, MapBlock*> lighting_modified_blocks;
	lighting_modified_blocks.insert(modified_blocks.begin(), modified_blocks.end());
	map->updateLighting(lighting_modified_blocks, modified_blocks);
	// Send a MEET_OTHER event
	MapEditEvent event;
	event.type = MEET_OTHER;
	for (std::map<v3s16, MapBlock*>::iterator
			i = modified_blocks.begin();
			i != modified_blocks.end(); ++i)
		event.modified_blocks.insert(i->first);
	map->dispatchEvent(&event);
	return SUCCESS;
}


//L-System tree generator
treegen::error make_ltree(MMVManip &vmanip, v3s16 p0,
		INodeDefManager *ndef, TreeDef tree_definition)
{
	MapNode dirtnode(ndef->getId("mapgen_dirt"));
	s32 seed;
	if (tree_definition.explicit_seed)
		seed = tree_definition.seed + 14002;
	else
		seed = p0.X * 2 + p0.Y * 4 + p0.Z;  // use the tree position to seed PRNG
	PseudoRandom ps(seed);

	// chance of inserting abcd rules
	double prop_a = 9;
	double prop_b = 8;
	double prop_c = 7;
	double prop_d = 6;

	//randomize tree growth level, minimum=2
	s16 iterations = tree_definition.iterations;
	if (tree_definition.iterations_random_level > 0)
		iterations -= ps.range(0, tree_definition.iterations_random_level);
	if (iterations < 2)
		iterations = 2;

	s16 MAX_ANGLE_OFFSET = 5;
	double angle_in_radians = (double)tree_definition.angle * M_PI / 180;
	double angleOffset_in_radians = (s16)(ps.range(0, 1) % MAX_ANGLE_OFFSET) * M_PI / 180;

	//initialize rotation matrix, position and stacks for branches
	core::matrix4 rotation;
	rotation = setRotationAxisRadians(rotation, M_PI / 2, v3f(0, 0, 1));
	v3f position;
	position.X = p0.X;
	position.Y = p0.Y;
	position.Z = p0.Z;
	std::stack <core::matrix4> stack_orientation;
	std::stack <v3f> stack_position;

	//generate axiom
	std::string axiom = tree_definition.initial_axiom;
	for (s16 i = 0; i < iterations; i++) {
		std::string temp = "";
		for (s16 j = 0; j < (s16)axiom.size(); j++) {
			char axiom_char = axiom.at(j);
			switch (axiom_char) {
			case 'A':
				temp += tree_definition.rules_a;
				break;
			case 'B':
				temp += tree_definition.rules_b;
				break;
			case 'C':
				temp += tree_definition.rules_c;
				break;
			case 'D':
				temp += tree_definition.rules_d;
				break;
			case 'a':
				if (prop_a >= ps.range(1, 10))
					temp += tree_definition.rules_a;
				break;
			case 'b':
				if (prop_b >= ps.range(1, 10))
					temp += tree_definition.rules_b;
				break;
			case 'c':
				if (prop_c >= ps.range(1, 10))
					temp += tree_definition.rules_c;
				break;
			case 'd':
				if (prop_d >= ps.range(1, 10))
					temp += tree_definition.rules_d;
				break;
			default:
				temp += axiom_char;
				break;
			}
		}
		axiom = temp;
	}

	//make sure tree is not floating in the air
	if (tree_definition.trunk_type == "double") {
		tree_node_placement(
			vmanip,
			v3f(position.X + 1, position.Y - 1, position.Z),
			dirtnode
		);
		tree_node_placement(
			vmanip,
			v3f(position.X, position.Y - 1, position.Z + 1),
			dirtnode
		);
		tree_node_placement(
			vmanip,
			v3f(position.X + 1, position.Y - 1, position.Z + 1),
			dirtnode
		);
	} else if (tree_definition.trunk_type == "crossed") {
		tree_node_placement(
			vmanip,
			v3f(position.X + 1, position.Y - 1, position.Z),
			dirtnode
		);
		tree_node_placement(
			vmanip,
			v3f(position.X - 1, position.Y - 1, position.Z),
			dirtnode
		);
		tree_node_placement(
			vmanip,
			v3f(position.X, position.Y - 1, position.Z + 1),
			dirtnode
		);
		tree_node_placement(
			vmanip,
			v3f(position.X, position.Y - 1, position.Z - 1),
			dirtnode
		);
	}

	/* build tree out of generated axiom

	Key for Special L-System Symbols used in Axioms

    G  - move forward one unit with the pen up
    F  - move forward one unit with the pen down drawing trunks and branches
    f  - move forward one unit with the pen down drawing leaves (100% chance)
    T  - move forward one unit with the pen down drawing trunks only
    R  - move forward one unit with the pen down placing fruit
    A  - replace with rules set A
    B  - replace with rules set B
    C  - replace with rules set C
    D  - replace with rules set D
    a  - replace with rules set A, chance 90%
    b  - replace with rules set B, chance 80%
    c  - replace with rules set C, chance 70%
    d  - replace with rules set D, chance 60%
    +  - yaw the turtle right by angle degrees
    -  - yaw the turtle left by angle degrees
    &  - pitch the turtle down by angle degrees
    ^  - pitch the turtle up by angle degrees
    /  - roll the turtle to the right by angle degrees
    *  - roll the turtle to the left by angle degrees
    [  - save in stack current state info
    ]  - recover from stack state info

    */

	s16 x,y,z;
	for (s16 i = 0; i < (s16)axiom.size(); i++) {
		char axiom_char = axiom.at(i);
		core::matrix4 temp_rotation;
		temp_rotation.makeIdentity();
		v3f dir;
		switch (axiom_char) {
		case 'G':
			dir = v3f(1, 0, 0);
			dir = transposeMatrix(rotation, dir);
			position += dir;
			break;
		case 'T':
			tree_trunk_placement(
				vmanip,
				v3f(position.X, position.Y, position.Z),
				tree_definition
			);
			if (tree_definition.trunk_type == "double" &&
					!tree_definition.thin_branches) {
				tree_trunk_placement(
					vmanip,
					v3f(position.X + 1, position.Y, position.Z),
					tree_definition
				);
				tree_trunk_placement(
					vmanip,
					v3f(position.X, position.Y, position.Z + 1),
					tree_definition
				);
				tree_trunk_placement(
					vmanip,
					v3f(position.X + 1, position.Y, position.Z + 1),
					tree_definition
				);
			} else if (tree_definition.trunk_type == "crossed" &&
					!tree_definition.thin_branches) {
				tree_trunk_placement(
					vmanip,
					v3f(position.X + 1, position.Y, position.Z),
					tree_definition
				);
				tree_trunk_placement(
					vmanip,
					v3f(position.X - 1, position.Y, position.Z),
					tree_definition
				);
				tree_trunk_placement(
					vmanip,
					v3f(position.X, position.Y, position.Z + 1),
					tree_definition
				);
				tree_trunk_placement(
					vmanip,
					v3f(position.X, position.Y, position.Z - 1),
					tree_definition
				);
			}
			dir = v3f(1, 0, 0);
			dir = transposeMatrix(rotation, dir);
			position += dir;
			break;
		case 'F':
			tree_trunk_placement(
				vmanip,
				v3f(position.X, position.Y, position.Z),
				tree_definition
			);
			if ((stack_orientation.empty() &&
					tree_definition.trunk_type == "double") ||
					(!stack_orientation.empty() &&
					tree_definition.trunk_type == "double" &&
					!tree_definition.thin_branches)) {
				tree_trunk_placement(
					vmanip,
					v3f(position.X +1 , position.Y, position.Z),
					tree_definition
				);
				tree_trunk_placement(
					vmanip,
					v3f(position.X, position.Y, position.Z + 1),
					tree_definition
				);
				tree_trunk_placement(
					vmanip,
					v3f(position.X + 1, position.Y, position.Z + 1),
					tree_definition
				);
			} else if ((stack_orientation.empty() &&
					tree_definition.trunk_type == "crossed") ||
					(!stack_orientation.empty() &&
					tree_definition.trunk_type == "crossed" &&
					!tree_definition.thin_branches)) {
				tree_trunk_placement(
					vmanip,
					v3f(position.X + 1, position.Y, position.Z),
					tree_definition
				);
				tree_trunk_placement(
					vmanip,
					v3f(position.X - 1, position.Y, position.Z),
					tree_definition
				);
				tree_trunk_placement(
					vmanip,
					v3f(position.X, position.Y, position.Z + 1),
					tree_definition
				);
				tree_trunk_placement(
					vmanip,
					v3f(position.X, position.Y, position.Z - 1),
					tree_definition
				);
			} if (stack_orientation.empty() == false) {
				s16 size = 1;
				for (x = -size; x <= size; x++)
				for (y = -size; y <= size; y++)
				for (z = -size; z <= size; z++) {
					if (abs(x) == size &&
							abs(y) == size &&
							abs(z) == size) {
						tree_leaves_placement(
							vmanip,
							v3f(position.X + x + 1, position.Y + y,
									position.Z + z),
							ps.next(),
							tree_definition
						);
						tree_leaves_placement(
							vmanip,
							v3f(position.X + x - 1, position.Y + y,
									position.Z + z),
							ps.next(),
							tree_definition
						);
						tree_leaves_placement(
							vmanip,v3f(position.X + x, position.Y + y,
									position.Z + z + 1),
							ps.next(),
							tree_definition
						);
						tree_leaves_placement(
							vmanip,v3f(position.X + x, position.Y + y,
									position.Z + z - 1),
							ps.next(),
							tree_definition
						);
					}
				}
			}
			dir = v3f(1, 0, 0);
			dir = transposeMatrix(rotation, dir);
			position += dir;
			break;
		case 'f':
			tree_single_leaves_placement(
				vmanip,
				v3f(position.X, position.Y, position.Z),
				ps.next(),
				tree_definition
			);
			dir = v3f(1, 0, 0);
			dir = transposeMatrix(rotation, dir);
			position += dir;
			break;
		case 'R':
			tree_fruit_placement(
				vmanip,
				v3f(position.X, position.Y, position.Z),
				tree_definition
			);
			dir = v3f(1, 0, 0);
			dir = transposeMatrix(rotation, dir);
			position += dir;
			break;

		// turtle orientation commands
		case '[':
			stack_orientation.push(rotation);
			stack_position.push(position);
			break;
		case ']':
			if (stack_orientation.empty())
				return UNBALANCED_BRACKETS;
			rotation = stack_orientation.top();
			stack_orientation.pop();
			position = stack_position.top();
			stack_position.pop();
			break;
		case '+':
			temp_rotation.makeIdentity();
			temp_rotation = setRotationAxisRadians(temp_rotation,
					angle_in_radians + angleOffset_in_radians, v3f(0, 0, 1));
			rotation *= temp_rotation;
			break;
		case '-':
			temp_rotation.makeIdentity();
			temp_rotation = setRotationAxisRadians(temp_rotation,
					angle_in_radians + angleOffset_in_radians, v3f(0, 0, -1));
			rotation *= temp_rotation;
			break;
		case '&':
			temp_rotation.makeIdentity();
			temp_rotation = setRotationAxisRadians(temp_rotation,
					angle_in_radians + angleOffset_in_radians, v3f(0, 1, 0));
			rotation *= temp_rotation;
			break;
		case '^':
			temp_rotation.makeIdentity();
			temp_rotation = setRotationAxisRadians(temp_rotation,
					angle_in_radians + angleOffset_in_radians, v3f(0, -1, 0));
			rotation *= temp_rotation;
			break;
		case '*':
			temp_rotation.makeIdentity();
			temp_rotation = setRotationAxisRadians(temp_rotation,
					angle_in_radians, v3f(1, 0, 0));
			rotation *= temp_rotation;
			break;
		case '/':
			temp_rotation.makeIdentity();
			temp_rotation = setRotationAxisRadians(temp_rotation,
					angle_in_radians, v3f(-1, 0, 0));
			rotation *= temp_rotation;
			break;
		default:
			break;
		}
	}

	return SUCCESS;
}


void tree_node_placement(MMVManip &vmanip, v3f p0, MapNode node)
{
	v3s16 p1 = v3s16(myround(p0.X), myround(p0.Y), myround(p0.Z));
	if (vmanip.m_area.contains(p1) == false)
		return;
	u32 vi = vmanip.m_area.index(p1);
	if (vmanip.m_data[vi].getContent() != CONTENT_AIR
			&& vmanip.m_data[vi].getContent() != CONTENT_IGNORE)
		return;
	vmanip.m_data[vmanip.m_area.index(p1)] = node;
}


void tree_trunk_placement(MMVManip &vmanip, v3f p0, TreeDef &tree_definition)
{
	v3s16 p1 = v3s16(myround(p0.X), myround(p0.Y), myround(p0.Z));
	if (vmanip.m_area.contains(p1) == false)
		return;
	u32 vi = vmanip.m_area.index(p1);
	if (vmanip.m_data[vi].getContent() != CONTENT_AIR
			&& vmanip.m_data[vi].getContent() != CONTENT_IGNORE)
		return;
	vmanip.m_data[vmanip.m_area.index(p1)] = tree_definition.trunknode;
}


void tree_leaves_placement(MMVManip &vmanip, v3f p0,
		PseudoRandom ps, TreeDef &tree_definition)
{
	MapNode leavesnode = tree_definition.leavesnode;
	if (ps.range(1, 100) > 100 - tree_definition.leaves2_chance)
		leavesnode = tree_definition.leaves2node;
	v3s16 p1 = v3s16(myround(p0.X), myround(p0.Y), myround(p0.Z));
	if (vmanip.m_area.contains(p1) == false)
		return;
	u32 vi = vmanip.m_area.index(p1);
	if (vmanip.m_data[vi].getContent() != CONTENT_AIR
			&& vmanip.m_data[vi].getContent() != CONTENT_IGNORE)
		return;
	if (tree_definition.fruit_chance > 0) {
		if (ps.range(1, 100) > 100 - tree_definition.fruit_chance)
			vmanip.m_data[vmanip.m_area.index(p1)] = tree_definition.fruitnode;
		else
			vmanip.m_data[vmanip.m_area.index(p1)] = leavesnode;
	} else if (ps.range(1, 100) > 20) {
		vmanip.m_data[vmanip.m_area.index(p1)] = leavesnode;
	}
}


void tree_single_leaves_placement(MMVManip &vmanip, v3f p0,
		PseudoRandom ps, TreeDef &tree_definition)
{
	MapNode leavesnode = tree_definition.leavesnode;
	if (ps.range(1, 100) > 100 - tree_definition.leaves2_chance)
		leavesnode = tree_definition.leaves2node;
	v3s16 p1 = v3s16(myround(p0.X), myround(p0.Y), myround(p0.Z));
	if (vmanip.m_area.contains(p1) == false)
		return;
	u32 vi = vmanip.m_area.index(p1);
	if (vmanip.m_data[vi].getContent() != CONTENT_AIR
			&& vmanip.m_data[vi].getContent() != CONTENT_IGNORE)
		return;
	vmanip.m_data[vmanip.m_area.index(p1)] = leavesnode;
}


void tree_fruit_placement(MMVManip &vmanip, v3f p0, TreeDef &tree_definition)
{
	v3s16 p1 = v3s16(myround(p0.X), myround(p0.Y), myround(p0.Z));
	if (vmanip.m_area.contains(p1) == false)
		return;
	u32 vi = vmanip.m_area.index(p1);
	if (vmanip.m_data[vi].getContent() != CONTENT_AIR
			&& vmanip.m_data[vi].getContent() != CONTENT_IGNORE)
		return;
	vmanip.m_data[vmanip.m_area.index(p1)] = tree_definition.fruitnode;
}


irr::core::matrix4 setRotationAxisRadians(irr::core::matrix4 M, double angle, v3f axis)
{
	double c = cos(angle);
	double s = sin(angle);
	double t = 1.0 - c;

	double tx  = t * axis.X;
	double ty  = t * axis.Y;
	double tz  = t * axis.Z;
	double sx  = s * axis.X;
	double sy  = s * axis.Y;
	double sz  = s * axis.Z;

	M[0] = tx * axis.X + c;
	M[1] = tx * axis.Y + sz;
	M[2] = tx * axis.Z - sy;

	M[4] = ty * axis.X - sz;
	M[5] = ty * axis.Y + c;
	M[6] = ty * axis.Z + sx;

	M[8]  = tz * axis.X + sy;
	M[9]  = tz * axis.Y - sx;
	M[10] = tz * axis.Z + c;
	return M;
}


v3f transposeMatrix(irr::core::matrix4 M, v3f v)
{
	v3f translated;
	double x = M[0] * v.X + M[4] * v.Y + M[8]  * v.Z +M[12];
	double y = M[1] * v.X + M[5] * v.Y + M[9]  * v.Z +M[13];
	double z = M[2] * v.X + M[6] * v.Y + M[10] * v.Z +M[14];
	translated.X = x;
	translated.Y = y;
	translated.Z = z;
	return translated;
}


void make_jungletree(MMVManip &vmanip, v3s16 p0, INodeDefManager *ndef, s32 seed)
{
	/*
		NOTE: Tree-placing code is currently duplicated in the engine
		and in games that have saplings; both are deprecated but not
		replaced yet
	*/
	content_t c_tree   = ndef->getId("mapgen_jungletree");
	content_t c_leaves = ndef->getId("mapgen_jungleleaves");
	if (c_tree == CONTENT_IGNORE)
		c_tree = ndef->getId("mapgen_tree");
	if (c_leaves == CONTENT_IGNORE)
		c_leaves = ndef->getId("mapgen_leaves");

	MapNode treenode(c_tree);
	MapNode leavesnode(c_leaves);

	PseudoRandom pr(seed);
	for (s16 x= -1; x <= 1; x++)
	for (s16 z= -1; z <= 1; z++) {
		if (pr.range(0, 2) == 0)
			continue;
		v3s16 p1 = p0 + v3s16(x, 0, z);
		v3s16 p2 = p0 + v3s16(x, -1, z);
		u32 vi1 = vmanip.m_area.index(p1);
		u32 vi2 = vmanip.m_area.index(p2);

		if (vmanip.m_area.contains(p2) &&
				vmanip.m_data[vi2].getContent() == CONTENT_AIR)
			vmanip.m_data[vi2] = treenode;
		else if (vmanip.m_area.contains(p1) &&
				vmanip.m_data[vi1].getContent() == CONTENT_AIR)
			vmanip.m_data[vi1] = treenode;
	}
	vmanip.m_data[vmanip.m_area.index(p0)] = treenode;

	s16 trunk_h = pr.range(8, 12);
	v3s16 p1 = p0;
	for (s16 ii = 0; ii < trunk_h; ii++) {
		if (vmanip.m_area.contains(p1)) {
			u32 vi = vmanip.m_area.index(p1);
			vmanip.m_data[vi] = treenode;
		}
		p1.Y++;
	}

	// p1 is now the last piece of the trunk
	p1.Y -= 1;

	VoxelArea leaves_a(v3s16(-3, -2, -3), v3s16(3, 2, 3));
	//SharedPtr<u8> leaves_d(new u8[leaves_a.getVolume()]);
	Buffer<u8> leaves_d(leaves_a.getVolume());
	for (s32 i = 0; i < leaves_a.getVolume(); i++)
		leaves_d[i] = 0;

	// Force leaves at near the end of the trunk
	s16 d = 1;
	for (s16 z = -d; z <= d; z++)
	for (s16 y = -d; y <= d; y++)
	for (s16 x = -d; x <= d; x++) {
		leaves_d[leaves_a.index(v3s16(x,y,z))] = 1;
	}

	// Add leaves randomly
	for (u32 iii = 0; iii < 30; iii++) {
		v3s16 p(
			pr.range(leaves_a.MinEdge.X, leaves_a.MaxEdge.X - d),
			pr.range(leaves_a.MinEdge.Y, leaves_a.MaxEdge.Y - d),
			pr.range(leaves_a.MinEdge.Z, leaves_a.MaxEdge.Z - d)
		);

		for (s16 z = 0; z <= d; z++)
		for (s16 y = 0; y <= d; y++)
		for (s16 x = 0; x <= d; x++) {
			leaves_d[leaves_a.index(p + v3s16(x, y, z))] = 1;
		}
	}

	// Blit leaves to vmanip
	for (s16 z = leaves_a.MinEdge.Z; z <= leaves_a.MaxEdge.Z; z++)
	for (s16 y = leaves_a.MinEdge.Y; y <= leaves_a.MaxEdge.Y; y++) {
		v3s16 pmin(leaves_a.MinEdge.X, y, z);
		u32 i = leaves_a.index(pmin);
		u32 vi = vmanip.m_area.index(pmin + p1);
		for (s16 x = leaves_a.MinEdge.X; x <= leaves_a.MaxEdge.X; x++) {
			v3s16 p(x, y, z);
			if (vmanip.m_area.contains(p + p1) == true &&
					(vmanip.m_data[vi].getContent() == CONTENT_AIR ||
					vmanip.m_data[vi].getContent() == CONTENT_IGNORE)) {
				if (leaves_d[i] == 1)
					vmanip.m_data[vi] = leavesnode;
			}
			vi++;
			i++;
		}
	}
}


void make_pine_tree(MMVManip &vmanip, v3s16 p0, INodeDefManager *ndef, s32 seed)
{
	/*
		NOTE: Tree-placing code is currently duplicated in the engine
		and in games that have saplings; both are deprecated but not
		replaced yet
	*/
	content_t c_tree   = ndef->getId("mapgen_pine_tree");
	content_t c_leaves = ndef->getId("mapgen_pine_needles");
	content_t c_snow = ndef->getId("mapgen_snow");
	if (c_tree == CONTENT_IGNORE)
		c_tree = ndef->getId("mapgen_tree");
	if (c_leaves == CONTENT_IGNORE)
		c_leaves = ndef->getId("mapgen_leaves");
	if (c_snow == CONTENT_IGNORE)
		c_snow = CONTENT_AIR;

	MapNode treenode(c_tree);
	MapNode leavesnode(c_leaves);
	MapNode snownode(c_snow);

	PseudoRandom pr(seed);
	u16 trunk_h = pr.range(9, 13);
	v3s16 p1 = p0;
	for (u16 ii = 0; ii < trunk_h; ii++) {
		if (vmanip.m_area.contains(p1)) {
			u32 vi = vmanip.m_area.index(p1);
			vmanip.m_data[vi] = treenode;
		}
		p1.Y++;
	}

	// Make p1 the top node of the trunk
	p1.Y -= 1;

	VoxelArea leaves_a(v3s16(-3, -6, -3), v3s16(3, 3, 3));
	//SharedPtr<u8> leaves_d(new u8[leaves_a.getVolume()]);
	Buffer<u8> leaves_d(leaves_a.getVolume());
	for (s32 i = 0; i < leaves_a.getVolume(); i++)
		leaves_d[i] = 0;

	// Upper branches
	u16 dev = 3;
	for (s16 yy = -1; yy <= 1; yy++) {
		for (s16 zz = -dev; zz <= dev; zz++) {
			u32 i = leaves_a.index(v3s16(-dev, yy, zz));
			u32 ia = leaves_a.index(v3s16(-dev, yy+1, zz));
			for (s16 xx = -dev; xx <= dev; xx++) {
				if (pr.range(0, 20) <= 19 - dev) {
					leaves_d[i] = 1;
					leaves_d[ia] = 2;
				}
				i++;
				ia++;
			}
		}
		dev--;
	}

	// Centre top nodes
	u32 i = leaves_a.index(v3s16(0, 1, 0));
	leaves_d[i] = 1;
	i = leaves_a.index(v3s16(0, 2, 0));
	leaves_d[i] = 1;
	i = leaves_a.index(v3s16(0, 3, 0));
	leaves_d[i] = 2;

	// Lower branches
	s16 my = -6;
	for (u32 iii = 0; iii < 20; iii++) {
		s16 xi = pr.range(-3, 2);
		s16 yy = pr.range(-6, -5);
		s16 zi = pr.range(-3, 2);
		if (yy > my)
			my = yy;
		for (s16 zz = zi; zz <= zi + 1; zz++) {
			u32 i = leaves_a.index(v3s16(xi, yy, zz));
			u32 ia = leaves_a.index(v3s16(xi, yy + 1, zz));
			for (s16 xx = xi; xx <= xi + 1; xx++) {
				leaves_d[i] = 1;
				if (leaves_d[ia] == 0)
					leaves_d[ia] = 2;
				i++;
				ia++;
			}
		}
	}

	dev = 2;
	for (s16 yy = my + 1; yy <= my + 2; yy++) {
		for (s16 zz = -dev; zz <= dev; zz++) {
			u32 i = leaves_a.index(v3s16(-dev, yy, zz));
			u32 ia = leaves_a.index(v3s16(-dev, yy + 1, zz));
			for (s16 xx = -dev; xx <= dev; xx++) {
				if (pr.range(0, 20) <= 19 - dev) {
					leaves_d[i] = 1;
					leaves_d[ia] = 2;
				}
				i++;
				ia++;
			}
		}
		dev--;
	}

	// Blit leaves to vmanip
	for (s16 z = leaves_a.MinEdge.Z; z <= leaves_a.MaxEdge.Z; z++)
	for (s16 y = leaves_a.MinEdge.Y; y <= leaves_a.MaxEdge.Y; y++) {
		v3s16 pmin(leaves_a.MinEdge.X, y, z);
		u32 i = leaves_a.index(pmin);
		u32 vi = vmanip.m_area.index(pmin + p1);
		for (s16 x = leaves_a.MinEdge.X; x <= leaves_a.MaxEdge.X; x++) {
			v3s16 p(x, y, z);
			if (vmanip.m_area.contains(p + p1) == true &&
					(vmanip.m_data[vi].getContent() == CONTENT_AIR ||
					vmanip.m_data[vi].getContent() == CONTENT_IGNORE ||
					vmanip.m_data[vi] == snownode)) {
				if (leaves_d[i] == 1)
					vmanip.m_data[vi] = leavesnode;
				else if (leaves_d[i] == 2)
					vmanip.m_data[vi] = snownode;
			}
			vi++;
			i++;
		}
	}
}

}; // namespace treegen