minetest/src/mapnode.cpp

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/*
Minetest
Copyright (C) 2013 celeron55, Perttu Ahola <celeron55@gmail.com>
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 "irrlichttypes_extrabloated.h"
#include "mapnode.h"
#include "porting.h"
#include "nodedef.h"
#include "map.h"
#include "content_mapnode.h" // For mapnode_translate_*_internal
#include "serialization.h" // For ser_ver_supported
#include "util/serialize.h"
#include "log.h"
#include "util/directiontables.h"
#include "util/numeric.h"
#include <string>
#include <sstream>
static const Rotation wallmounted_to_rot[] = {
ROTATE_0, ROTATE_180, ROTATE_90, ROTATE_270
};
static const u8 rot_to_wallmounted[] = {
2, 4, 3, 5
};
/*
MapNode
*/
void MapNode::getColor(const ContentFeatures &f, video::SColor *color) const
{
if (f.palette) {
*color = (*f.palette)[param2];
return;
}
*color = f.color;
}
u8 MapNode::getFaceDir(const NodeDefManager *nodemgr,
bool allow_wallmounted) const
{
const ContentFeatures &f = nodemgr->get(*this);
if (f.param_type_2 == CPT2_FACEDIR ||
f.param_type_2 == CPT2_COLORED_FACEDIR)
return (getParam2() & 0x1F) % 24;
if (f.param_type_2 == CPT2_4DIR ||
f.param_type_2 == CPT2_COLORED_4DIR)
return getParam2() & 0x03;
if (allow_wallmounted && (f.param_type_2 == CPT2_WALLMOUNTED ||
f.param_type_2 == CPT2_COLORED_WALLMOUNTED)) {
u8 wmountface = MYMIN(getParam2() & 0x07, DWM_COUNT - 1);
return wallmounted_to_facedir[wmountface];
}
return 0;
}
u8 MapNode::getWallMounted(const NodeDefManager *nodemgr) const
{
const ContentFeatures &f = nodemgr->get(*this);
if (f.param_type_2 == CPT2_WALLMOUNTED ||
f.param_type_2 == CPT2_COLORED_WALLMOUNTED)
return MYMIN(getParam2() & 0x07, DWM_COUNT - 1);
else if (f.drawtype == NDT_SIGNLIKE || f.drawtype == NDT_TORCHLIKE ||
f.drawtype == NDT_PLANTLIKE ||
f.drawtype == NDT_PLANTLIKE_ROOTED) {
return 1;
}
return 0;
}
v3s16 MapNode::getWallMountedDir(const NodeDefManager *nodemgr) const
{
switch(getWallMounted(nodemgr))
{
case 0: default: return v3s16(0,1,0);
case 1: return v3s16(0,-1,0);
case 2: return v3s16(1,0,0);
case 3: return v3s16(-1,0,0);
case 4: return v3s16(0,0,1);
case 5: return v3s16(0,0,-1);
}
}
u8 MapNode::getDegRotate(const NodeDefManager *nodemgr) const
{
const ContentFeatures &f = nodemgr->get(*this);
if (f.param_type_2 == CPT2_DEGROTATE)
return getParam2() % 240;
if (f.param_type_2 == CPT2_COLORED_DEGROTATE)
return 10 * ((getParam2() & 0x1F) % 24);
return 0;
}
void MapNode::rotateAlongYAxis(const NodeDefManager *nodemgr, Rotation rot)
{
ContentParamType2 cpt2 = nodemgr->get(*this).param_type_2;
if (cpt2 == CPT2_FACEDIR || cpt2 == CPT2_COLORED_FACEDIR ||
cpt2 == CPT2_4DIR || cpt2 == CPT2_COLORED_4DIR) {
static const u8 rotate_facedir[24 * 4] = {
// Table value = rotated facedir
// Columns: 0, 90, 180, 270 degrees rotation around vertical axis
// Rotation is anticlockwise as seen from above (+Y)
0, 1, 2, 3, // Initial facedir 0 to 3
1, 2, 3, 0,
2, 3, 0, 1,
3, 0, 1, 2,
4, 13, 10, 19, // 4 to 7
5, 14, 11, 16,
6, 15, 8, 17,
7, 12, 9, 18,
8, 17, 6, 15, // 8 to 11
9, 18, 7, 12,
10, 19, 4, 13,
11, 16, 5, 14,
12, 9, 18, 7, // 12 to 15
13, 10, 19, 4,
14, 11, 16, 5,
15, 8, 17, 6,
16, 5, 14, 11, // 16 to 19
17, 6, 15, 8,
18, 7, 12, 9,
19, 4, 13, 10,
20, 23, 22, 21, // 20 to 23
21, 20, 23, 22,
22, 21, 20, 23,
23, 22, 21, 20
};
if (cpt2 == CPT2_FACEDIR || cpt2 == CPT2_COLORED_FACEDIR) {
u8 facedir = (param2 & 31) % 24;
u8 index = facedir * 4 + rot;
param2 &= ~31;
param2 |= rotate_facedir[index];
} else if (cpt2 == CPT2_4DIR || cpt2 == CPT2_COLORED_4DIR) {
u8 fourdir = param2 & 3;
u8 index = fourdir * 4 + rot;
param2 &= ~3;
param2 |= rotate_facedir[index];
}
} else if (cpt2 == CPT2_WALLMOUNTED ||
cpt2 == CPT2_COLORED_WALLMOUNTED) {
u8 wmountface = MYMIN(param2 & 0x07, DWM_COUNT - 1);
if (wmountface <= 1)
return;
Rotation oldrot = wallmounted_to_rot[wmountface - 2];
param2 &= ~7;
param2 |= rot_to_wallmounted[(oldrot - rot) & 3];
} else if (cpt2 == CPT2_DEGROTATE) {
int angle = param2; // in 1.5°
angle += 60 * rot; // dont do that on u8
angle %= 240;
param2 = angle;
} else if (cpt2 == CPT2_COLORED_DEGROTATE) {
int angle = param2 & 0x1F; // in 15°
int color = param2 & 0xE0;
angle += 6 * rot;
angle %= 24;
param2 = color | angle;
}
}
void transformNodeBox(const MapNode &n, const NodeBox &nodebox,
const NodeDefManager *nodemgr, std::vector<aabb3f> *p_boxes,
u8 neighbors = 0)
{
std::vector<aabb3f> &boxes = *p_boxes;
if (nodebox.type == NODEBOX_FIXED || nodebox.type == NODEBOX_LEVELED) {
const auto &fixed = nodebox.fixed;
int facedir = n.getFaceDir(nodemgr, true);
u8 axisdir = facedir>>2;
facedir&=0x03;
boxes.reserve(boxes.size() + fixed.size());
for (aabb3f box : fixed) {
if (nodebox.type == NODEBOX_LEVELED)
box.MaxEdge.Y = (-0.5f + n.getLevel(nodemgr) / 64.0f) * BS;
switch (axisdir) {
case 0:
if(facedir == 1)
{
box.MinEdge.rotateXZBy(-90);
box.MaxEdge.rotateXZBy(-90);
}
else if(facedir == 2)
{
box.MinEdge.rotateXZBy(180);
box.MaxEdge.rotateXZBy(180);
}
else if(facedir == 3)
{
box.MinEdge.rotateXZBy(90);
box.MaxEdge.rotateXZBy(90);
}
break;
case 1: // z+
box.MinEdge.rotateYZBy(90);
box.MaxEdge.rotateYZBy(90);
if(facedir == 1)
{
box.MinEdge.rotateXYBy(90);
box.MaxEdge.rotateXYBy(90);
}
else if(facedir == 2)
{
box.MinEdge.rotateXYBy(180);
box.MaxEdge.rotateXYBy(180);
}
else if(facedir == 3)
{
box.MinEdge.rotateXYBy(-90);
box.MaxEdge.rotateXYBy(-90);
}
break;
case 2: //z-
box.MinEdge.rotateYZBy(-90);
box.MaxEdge.rotateYZBy(-90);
if(facedir == 1)
{
box.MinEdge.rotateXYBy(-90);
box.MaxEdge.rotateXYBy(-90);
}
else if(facedir == 2)
{
box.MinEdge.rotateXYBy(180);
box.MaxEdge.rotateXYBy(180);
}
else if(facedir == 3)
{
box.MinEdge.rotateXYBy(90);
box.MaxEdge.rotateXYBy(90);
}
break;
case 3: //x+
box.MinEdge.rotateXYBy(-90);
box.MaxEdge.rotateXYBy(-90);
if(facedir == 1)
{
box.MinEdge.rotateYZBy(90);
box.MaxEdge.rotateYZBy(90);
}
else if(facedir == 2)
{
box.MinEdge.rotateYZBy(180);
box.MaxEdge.rotateYZBy(180);
}
else if(facedir == 3)
{
box.MinEdge.rotateYZBy(-90);
box.MaxEdge.rotateYZBy(-90);
}
break;
case 4: //x-
box.MinEdge.rotateXYBy(90);
box.MaxEdge.rotateXYBy(90);
if(facedir == 1)
{
box.MinEdge.rotateYZBy(-90);
box.MaxEdge.rotateYZBy(-90);
}
else if(facedir == 2)
{
box.MinEdge.rotateYZBy(180);
box.MaxEdge.rotateYZBy(180);
}
else if(facedir == 3)
{
box.MinEdge.rotateYZBy(90);
box.MaxEdge.rotateYZBy(90);
}
break;
case 5:
box.MinEdge.rotateXYBy(-180);
box.MaxEdge.rotateXYBy(-180);
if(facedir == 1)
{
box.MinEdge.rotateXZBy(90);
box.MaxEdge.rotateXZBy(90);
}
else if(facedir == 2)
{
box.MinEdge.rotateXZBy(180);
box.MaxEdge.rotateXZBy(180);
}
else if(facedir == 3)
{
box.MinEdge.rotateXZBy(-90);
box.MaxEdge.rotateXZBy(-90);
}
break;
default:
break;
}
box.repair();
boxes.push_back(box);
}
}
else if(nodebox.type == NODEBOX_WALLMOUNTED)
{
v3s16 dir = n.getWallMountedDir(nodemgr);
// top
if(dir == v3s16(0,1,0))
{
boxes.push_back(nodebox.wall_top);
}
// bottom
else if(dir == v3s16(0,-1,0))
{
boxes.push_back(nodebox.wall_bottom);
}
// side
else
{
v3f vertices[2] =
{
nodebox.wall_side.MinEdge,
nodebox.wall_side.MaxEdge
};
for (v3f &vertex : vertices) {
if(dir == v3s16(-1,0,0))
vertex.rotateXZBy(0);
if(dir == v3s16(1,0,0))
vertex.rotateXZBy(180);
if(dir == v3s16(0,0,-1))
vertex.rotateXZBy(90);
if(dir == v3s16(0,0,1))
vertex.rotateXZBy(-90);
}
aabb3f box = aabb3f(vertices[0]);
box.addInternalPoint(vertices[1]);
boxes.push_back(box);
}
}
else if (nodebox.type == NODEBOX_CONNECTED)
{
size_t boxes_size = boxes.size();
boxes_size += nodebox.fixed.size();
const auto &c = nodebox.getConnected();
if (neighbors & 1)
boxes_size += c.connect_top.size();
else
boxes_size += c.disconnected_top.size();
if (neighbors & 2)
boxes_size += c.connect_bottom.size();
else
boxes_size += c.disconnected_bottom.size();
if (neighbors & 4)
boxes_size += c.connect_front.size();
else
boxes_size += c.disconnected_front.size();
if (neighbors & 8)
boxes_size += c.connect_left.size();
else
boxes_size += c.disconnected_left.size();
if (neighbors & 16)
boxes_size += c.connect_back.size();
else
boxes_size += c.disconnected_back.size();
if (neighbors & 32)
boxes_size += c.connect_right.size();
else
boxes_size += c.disconnected_right.size();
if (neighbors == 0)
boxes_size += c.disconnected.size();
if (neighbors < 4)
boxes_size += c.disconnected_sides.size();
boxes.reserve(boxes_size);
#define BOXESPUSHBACK(c) \
for (std::vector<aabb3f>::const_iterator \
it = (c).begin(); \
it != (c).end(); ++it) \
(boxes).push_back(*it);
BOXESPUSHBACK(nodebox.fixed);
if (neighbors & 1) {
BOXESPUSHBACK(c.connect_top);
} else {
BOXESPUSHBACK(c.disconnected_top);
}
if (neighbors & 2) {
BOXESPUSHBACK(c.connect_bottom);
} else {
BOXESPUSHBACK(c.disconnected_bottom);
}
if (neighbors & 4) {
BOXESPUSHBACK(c.connect_front);
} else {
BOXESPUSHBACK(c.disconnected_front);
}
if (neighbors & 8) {
BOXESPUSHBACK(c.connect_left);
} else {
BOXESPUSHBACK(c.disconnected_left);
}
if (neighbors & 16) {
BOXESPUSHBACK(c.connect_back);
} else {
BOXESPUSHBACK(c.disconnected_back);
}
if (neighbors & 32) {
BOXESPUSHBACK(c.connect_right);
} else {
BOXESPUSHBACK(c.disconnected_right);
}
if (neighbors == 0) {
BOXESPUSHBACK(c.disconnected);
}
if (neighbors < 4) {
BOXESPUSHBACK(c.disconnected_sides);
}
}
else // NODEBOX_REGULAR
{
boxes.emplace_back(-BS/2,-BS/2,-BS/2,BS/2,BS/2,BS/2);
}
}
static inline void getNeighborConnectingFace(
const v3s16 &p, const NodeDefManager *nodedef,
Map *map, MapNode n, u8 bitmask, u8 *neighbors)
{
MapNode n2 = map->getNode(p);
if (nodedef->nodeboxConnects(n, n2, bitmask))
*neighbors |= bitmask;
}
u8 MapNode::getNeighbors(v3s16 p, Map *map) const
{
const NodeDefManager *nodedef = map->getNodeDefManager();
u8 neighbors = 0;
const ContentFeatures &f = nodedef->get(*this);
// locate possible neighboring nodes to connect to
if (f.drawtype == NDT_NODEBOX && f.node_box.type == NODEBOX_CONNECTED) {
v3s16 p2 = p;
p2.Y++;
getNeighborConnectingFace(p2, nodedef, map, *this, 1, &neighbors);
p2 = p;
p2.Y--;
getNeighborConnectingFace(p2, nodedef, map, *this, 2, &neighbors);
p2 = p;
p2.Z--;
getNeighborConnectingFace(p2, nodedef, map, *this, 4, &neighbors);
p2 = p;
p2.X--;
getNeighborConnectingFace(p2, nodedef, map, *this, 8, &neighbors);
p2 = p;
p2.Z++;
getNeighborConnectingFace(p2, nodedef, map, *this, 16, &neighbors);
p2 = p;
p2.X++;
getNeighborConnectingFace(p2, nodedef, map, *this, 32, &neighbors);
}
return neighbors;
}
void MapNode::getNodeBoxes(const NodeDefManager *nodemgr,
std::vector<aabb3f> *boxes, u8 neighbors) const
{
const ContentFeatures &f = nodemgr->get(*this);
transformNodeBox(*this, f.node_box, nodemgr, boxes, neighbors);
}
void MapNode::getCollisionBoxes(const NodeDefManager *nodemgr,
std::vector<aabb3f> *boxes, u8 neighbors) const
{
const ContentFeatures &f = nodemgr->get(*this);
if (f.collision_box.fixed.empty())
transformNodeBox(*this, f.node_box, nodemgr, boxes, neighbors);
else
transformNodeBox(*this, f.collision_box, nodemgr, boxes, neighbors);
}
void MapNode::getSelectionBoxes(const NodeDefManager *nodemgr,
std::vector<aabb3f> *boxes, u8 neighbors) const
{
const ContentFeatures &f = nodemgr->get(*this);
transformNodeBox(*this, f.selection_box, nodemgr, boxes, neighbors);
}
u8 MapNode::getMaxLevel(const NodeDefManager *nodemgr) const
{
const ContentFeatures &f = nodemgr->get(*this);
// todo: after update in all games leave only if (f.param_type_2 ==
if( f.liquid_type == LIQUID_FLOWING || f.param_type_2 == CPT2_FLOWINGLIQUID)
return LIQUID_LEVEL_MAX;
if(f.leveled || f.param_type_2 == CPT2_LEVELED)
return f.leveled_max;
return 0;
}
u8 MapNode::getLevel(const NodeDefManager *nodemgr) const
{
const ContentFeatures &f = nodemgr->get(*this);
// todo: after update in all games leave only if (f.param_type_2 ==
if(f.liquid_type == LIQUID_SOURCE)
return LIQUID_LEVEL_SOURCE;
if (f.param_type_2 == CPT2_FLOWINGLIQUID)
return getParam2() & LIQUID_LEVEL_MASK;
if(f.liquid_type == LIQUID_FLOWING) // can remove if all param_type_2 set
return getParam2() & LIQUID_LEVEL_MASK;
if (f.param_type_2 == CPT2_LEVELED) {
u8 level = getParam2() & LEVELED_MASK;
if (level)
return level;
}
// Return static value from nodedef if param2 isn't used for level
if (f.leveled > f.leveled_max)
return f.leveled_max;
return f.leveled;
}
s8 MapNode::setLevel(const NodeDefManager *nodemgr, s16 level)
{
s8 rest = 0;
const ContentFeatures &f = nodemgr->get(*this);
if (f.param_type_2 == CPT2_FLOWINGLIQUID
|| f.liquid_type == LIQUID_FLOWING
|| f.liquid_type == LIQUID_SOURCE) {
if (level <= 0) { // liquid cant exist with zero level
setContent(CONTENT_AIR);
return 0;
}
if (level >= LIQUID_LEVEL_SOURCE) {
rest = level - LIQUID_LEVEL_SOURCE;
setContent(f.liquid_alternative_source_id);
setParam2(0);
} else {
setContent(f.liquid_alternative_flowing_id);
setParam2((level & LIQUID_LEVEL_MASK) | (getParam2() & ~LIQUID_LEVEL_MASK));
}
} else if (f.param_type_2 == CPT2_LEVELED) {
if (level < 0) { // zero means default for a leveled nodebox
rest = level;
level = 0;
} else if (level > f.leveled_max) {
rest = level - f.leveled_max;
level = f.leveled_max;
}
setParam2((level & LEVELED_MASK) | (getParam2() & ~LEVELED_MASK));
}
return rest;
}
s8 MapNode::addLevel(const NodeDefManager *nodemgr, s16 add)
{
s16 level = getLevel(nodemgr);
level += add;
return setLevel(nodemgr, level);
}
u32 MapNode::serializedLength(u8 version)
{
if(!ser_ver_supported(version))
throw VersionMismatchException("ERROR: MapNode format not supported");
if (version == 0)
return 1;
if (version <= 9)
return 2;
if (version <= 23)
return 3;
return 4;
}
void MapNode::serialize(u8 *dest, u8 version) const
{
if(!ser_ver_supported(version))
throw VersionMismatchException("ERROR: MapNode format not supported");
// Can't do this anymore; we have 16-bit dynamically allocated node IDs
// in memory; conversion just won't work in this direction.
if(version < 24)
throw SerializationError("MapNode::serialize: serialization to "
"version < 24 not possible");
writeU16(dest+0, param0);
writeU8(dest+2, param1);
writeU8(dest+3, param2);
}
void MapNode::deSerialize(u8 *source, u8 version)
{
if(!ser_ver_supported(version))
throw VersionMismatchException("ERROR: MapNode format not supported");
if(version <= 21)
{
deSerialize_pre22(source, version);
return;
}
if(version >= 24){
param0 = readU16(source+0);
param1 = readU8(source+2);
param2 = readU8(source+3);
}else{
param0 = readU8(source+0);
param1 = readU8(source+1);
param2 = readU8(source+2);
if(param0 > 0x7F){
param0 |= ((param2&0xF0)<<4);
param2 &= 0x0F;
}
}
}
SharedBuffer<u8> MapNode::serializeBulk(int version,
const MapNode *nodes, u32 nodecount,
u8 content_width, u8 params_width)
{
if (!ser_ver_supported(version))
throw VersionMismatchException("ERROR: MapNode format not supported");
sanity_check(content_width == 2);
sanity_check(params_width == 2);
// Can't do this anymore; we have 16-bit dynamically allocated node IDs
// in memory; conversion just won't work in this direction.
if (version < 24)
throw SerializationError("MapNode::serializeBulk: serialization to "
"version < 24 not possible");
SharedBuffer<u8> databuf(nodecount * (content_width + params_width));
u32 start1 = content_width * nodecount;
u32 start2 = (content_width + 1) * nodecount;
// Serialize content
for (u32 i = 0; i < nodecount; i++) {
writeU16(&databuf[i * 2], nodes[i].param0);
writeU8(&databuf[start1 + i], nodes[i].param1);
writeU8(&databuf[start2 + i], nodes[i].param2);
}
return databuf;
}
// Deserialize bulk node data
void MapNode::deSerializeBulk(std::istream &is, int version,
MapNode *nodes, u32 nodecount,
u8 content_width, u8 params_width)
{
if(!ser_ver_supported(version))
throw VersionMismatchException("ERROR: MapNode format not supported");
if (version < 22
|| (content_width != 1 && content_width != 2)
|| params_width != 2)
FATAL_ERROR("Deserialize bulk node data error");
// read data
const u32 len = nodecount * (content_width + params_width);
Buffer<u8> databuf(len);
is.read(reinterpret_cast<char*>(*databuf), len);
// Deserialize content
if(content_width == 1)
{
for(u32 i=0; i<nodecount; i++)
nodes[i].param0 = readU8(&databuf[i]);
}
else if(content_width == 2)
{
for(u32 i=0; i<nodecount; i++)
nodes[i].param0 = readU16(&databuf[i*2]);
}
// Deserialize param1
u32 start1 = content_width * nodecount;
for(u32 i=0; i<nodecount; i++)
nodes[i].param1 = readU8(&databuf[start1 + i]);
// Deserialize param2
u32 start2 = (content_width + 1) * nodecount;
if(content_width == 1)
{
for(u32 i=0; i<nodecount; i++) {
nodes[i].param2 = readU8(&databuf[start2 + i]);
if(nodes[i].param0 > 0x7F){
nodes[i].param0 <<= 4;
nodes[i].param0 |= (nodes[i].param2&0xF0)>>4;
nodes[i].param2 &= 0x0F;
}
}
}
else if(content_width == 2)
{
for(u32 i=0; i<nodecount; i++)
nodes[i].param2 = readU8(&databuf[start2 + i]);
}
}
/*
Legacy serialization
*/
void MapNode::deSerialize_pre22(const u8 *source, u8 version)
{
if(version <= 1)
{
param0 = source[0];
}
else if(version <= 9)
{
param0 = source[0];
param1 = source[1];
}
else
{
param0 = source[0];
param1 = source[1];
param2 = source[2];
if(param0 > 0x7f){
param0 <<= 4;
param0 |= (param2&0xf0)>>4;
param2 &= 0x0f;
}
}
// Convert special values from old version to new
if(version <= 19)
{
// In these versions, CONTENT_IGNORE and CONTENT_AIR
// are 255 and 254
// Version 19 is messed up with sometimes the old values and sometimes not
if(param0 == 255)
param0 = CONTENT_IGNORE;
else if(param0 == 254)
param0 = CONTENT_AIR;
}
// Translate to our known version
*this = mapnode_translate_to_internal(*this, version);
}