minetest/src/minimap.cpp
Loïc Blot 072bbba69a Some performance optimizations (#5424)
* Some performance optimizations

This is globally removing some memory useless copy

* use a const ref return on std::string Settings::get to prevent data copy on getters which doesn't need to copy it
 * pass some stack created strings to static const as they are not modified anywhere
 * Camera: return nametags per const ref instead of a list pointer, we only need to read it
 * INodeDefManager: getAll should be a result ref writer instead of a return copy
 * INodeDefManager: getAlias should return a const std::string ref
 * Minimap: unroll a Scolor creation in blitMinimapPixersToImageRadar to prvent many variable construct/destruct which are unneeded (we rewrite the content in the loop)
 * CNodeDefManager::updateAliases: prevent a idef getall copy
 * Profiler: constness
 * rollback_interface: create real_name later, and use const ref
 * MapBlockMesh updateFastFaceRow: unroll TileSpec next_tile, which has a cost of 1.8% CPU due to variable allocation/destruction,
 * MapBlockMesh updateFastFaceRow: copy next_tile to tile only if it's a different tilespec
 * MapBlockMesh updateFastFaceRow: use memcpy to copy next_lights to lights to do it in a single cpu operation
2017-03-22 21:41:02 +01:00

615 lines
18 KiB
C++

/*
Minetest
Copyright (C) 2010-2015 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 "minimap.h"
#include "threading/mutex_auto_lock.h"
#include "threading/semaphore.h"
#include "clientmap.h"
#include "settings.h"
#include "nodedef.h"
#include "porting.h"
#include "util/numeric.h"
#include "util/string.h"
#include "mapblock.h"
#include <math.h>
////
//// MinimapUpdateThread
////
MinimapUpdateThread::~MinimapUpdateThread()
{
for (std::map<v3s16, MinimapMapblock *>::iterator
it = m_blocks_cache.begin();
it != m_blocks_cache.end(); ++it) {
delete it->second;
}
for (std::deque<QueuedMinimapUpdate>::iterator
it = m_update_queue.begin();
it != m_update_queue.end(); ++it) {
QueuedMinimapUpdate &q = *it;
delete q.data;
}
}
bool MinimapUpdateThread::pushBlockUpdate(v3s16 pos, MinimapMapblock *data)
{
MutexAutoLock lock(m_queue_mutex);
// Find if block is already in queue.
// If it is, update the data and quit.
for (std::deque<QueuedMinimapUpdate>::iterator
it = m_update_queue.begin();
it != m_update_queue.end(); ++it) {
QueuedMinimapUpdate &q = *it;
if (q.pos == pos) {
delete q.data;
q.data = data;
return false;
}
}
// Add the block
QueuedMinimapUpdate q;
q.pos = pos;
q.data = data;
m_update_queue.push_back(q);
return true;
}
bool MinimapUpdateThread::popBlockUpdate(QueuedMinimapUpdate *update)
{
MutexAutoLock lock(m_queue_mutex);
if (m_update_queue.empty())
return false;
*update = m_update_queue.front();
m_update_queue.pop_front();
return true;
}
void MinimapUpdateThread::enqueueBlock(v3s16 pos, MinimapMapblock *data)
{
pushBlockUpdate(pos, data);
deferUpdate();
}
void MinimapUpdateThread::doUpdate()
{
QueuedMinimapUpdate update;
while (popBlockUpdate(&update)) {
if (update.data) {
// Swap two values in the map using single lookup
std::pair<std::map<v3s16, MinimapMapblock*>::iterator, bool>
result = m_blocks_cache.insert(std::make_pair(update.pos, update.data));
if (!result.second) {
delete result.first->second;
result.first->second = update.data;
}
} else {
std::map<v3s16, MinimapMapblock *>::iterator it;
it = m_blocks_cache.find(update.pos);
if (it != m_blocks_cache.end()) {
delete it->second;
m_blocks_cache.erase(it);
}
}
}
if (data->map_invalidated && data->mode != MINIMAP_MODE_OFF) {
getMap(data->pos, data->map_size, data->scan_height);
data->map_invalidated = false;
}
}
void MinimapUpdateThread::getMap(v3s16 pos, s16 size, s16 height)
{
v3s16 region(size, 0, size);
v3s16 pos_min(pos.X - size / 2, pos.Y - height / 2, pos.Z - size / 2);
v3s16 pos_max(pos_min.X + size - 1, pos.Y + height / 2, pos_min.Z + size - 1);
v3s16 blockpos_min = getNodeBlockPos(pos_min);
v3s16 blockpos_max = getNodeBlockPos(pos_max);
// clear the map
for (int z = 0; z < size; z++)
for (int x = 0; x < size; x++) {
MinimapPixel &mmpixel = data->minimap_scan[x + z * size];
mmpixel.air_count = 0;
mmpixel.height = 0;
mmpixel.n = MapNode(CONTENT_AIR);
}
// draw the map
v3s16 blockpos;
for (blockpos.Z = blockpos_min.Z; blockpos.Z <= blockpos_max.Z; ++blockpos.Z)
for (blockpos.Y = blockpos_min.Y; blockpos.Y <= blockpos_max.Y; ++blockpos.Y)
for (blockpos.X = blockpos_min.X; blockpos.X <= blockpos_max.X; ++blockpos.X) {
std::map<v3s16, MinimapMapblock *>::const_iterator pblock =
m_blocks_cache.find(blockpos);
if (pblock == m_blocks_cache.end())
continue;
const MinimapMapblock &block = *pblock->second;
v3s16 block_node_min(blockpos * MAP_BLOCKSIZE);
v3s16 block_node_max(block_node_min + MAP_BLOCKSIZE - 1);
// clip
v3s16 range_min = componentwise_max(block_node_min, pos_min);
v3s16 range_max = componentwise_min(block_node_max, pos_max);
v3s16 pos;
pos.Y = range_min.Y;
for (pos.Z = range_min.Z; pos.Z <= range_max.Z; ++pos.Z)
for (pos.X = range_min.X; pos.X <= range_max.X; ++pos.X) {
v3s16 inblock_pos = pos - block_node_min;
const MinimapPixel &in_pixel =
block.data[inblock_pos.Z * MAP_BLOCKSIZE + inblock_pos.X];
v3s16 inmap_pos = pos - pos_min;
MinimapPixel &out_pixel =
data->minimap_scan[inmap_pos.X + inmap_pos.Z * size];
out_pixel.air_count += in_pixel.air_count;
if (in_pixel.n.param0 != CONTENT_AIR) {
out_pixel.n = in_pixel.n;
out_pixel.height = inmap_pos.Y + in_pixel.height;
}
}
}
}
////
//// Mapper
////
Minimap::Minimap(IrrlichtDevice *device, Client *client)
{
this->client = client;
this->driver = device->getVideoDriver();
this->m_tsrc = client->getTextureSource();
this->m_shdrsrc = client->getShaderSource();
this->m_ndef = client->getNodeDefManager();
m_angle = 0.f;
// Initialize static settings
m_enable_shaders = g_settings->getBool("enable_shaders");
m_surface_mode_scan_height =
g_settings->getBool("minimap_double_scan_height") ? 256 : 128;
// Initialize minimap data
data = new MinimapData;
data->mode = MINIMAP_MODE_OFF;
data->is_radar = false;
data->map_invalidated = true;
data->heightmap_image = NULL;
data->minimap_image = NULL;
data->texture = NULL;
data->heightmap_texture = NULL;
data->minimap_shape_round = g_settings->getBool("minimap_shape_round");
// Get round minimap textures
data->minimap_mask_round = driver->createImage(
m_tsrc->getTexture("minimap_mask_round.png"),
core::position2d<s32>(0, 0),
core::dimension2d<u32>(MINIMAP_MAX_SX, MINIMAP_MAX_SY));
data->minimap_overlay_round = m_tsrc->getTexture("minimap_overlay_round.png");
// Get square minimap textures
data->minimap_mask_square = driver->createImage(
m_tsrc->getTexture("minimap_mask_square.png"),
core::position2d<s32>(0, 0),
core::dimension2d<u32>(MINIMAP_MAX_SX, MINIMAP_MAX_SY));
data->minimap_overlay_square = m_tsrc->getTexture("minimap_overlay_square.png");
// Create player marker texture
data->player_marker = m_tsrc->getTexture("player_marker.png");
// Create object marker texture
data->object_marker_red = m_tsrc->getTexture("object_marker_red.png");
// Create mesh buffer for minimap
m_meshbuffer = getMinimapMeshBuffer();
// Initialize and start thread
m_minimap_update_thread = new MinimapUpdateThread();
m_minimap_update_thread->data = data;
m_minimap_update_thread->start();
}
Minimap::~Minimap()
{
m_minimap_update_thread->stop();
m_minimap_update_thread->wait();
m_meshbuffer->drop();
data->minimap_mask_round->drop();
data->minimap_mask_square->drop();
driver->removeTexture(data->texture);
driver->removeTexture(data->heightmap_texture);
driver->removeTexture(data->minimap_overlay_round);
driver->removeTexture(data->minimap_overlay_square);
driver->removeTexture(data->object_marker_red);
delete data;
delete m_minimap_update_thread;
}
void Minimap::addBlock(v3s16 pos, MinimapMapblock *data)
{
m_minimap_update_thread->enqueueBlock(pos, data);
}
void Minimap::toggleMinimapShape()
{
MutexAutoLock lock(m_mutex);
data->minimap_shape_round = !data->minimap_shape_round;
g_settings->setBool("minimap_shape_round", data->minimap_shape_round);
m_minimap_update_thread->deferUpdate();
}
void Minimap::setMinimapMode(MinimapMode mode)
{
static const MinimapModeDef modedefs[MINIMAP_MODE_COUNT] = {
{false, 0, 0},
{false, m_surface_mode_scan_height, 256},
{false, m_surface_mode_scan_height, 128},
{false, m_surface_mode_scan_height, 64},
{true, 32, 128},
{true, 32, 64},
{true, 32, 32}
};
if (mode >= MINIMAP_MODE_COUNT)
return;
MutexAutoLock lock(m_mutex);
data->is_radar = modedefs[mode].is_radar;
data->scan_height = modedefs[mode].scan_height;
data->map_size = modedefs[mode].map_size;
data->mode = mode;
m_minimap_update_thread->deferUpdate();
}
void Minimap::setPos(v3s16 pos)
{
bool do_update = false;
{
MutexAutoLock lock(m_mutex);
if (pos != data->old_pos) {
data->old_pos = data->pos;
data->pos = pos;
do_update = true;
}
}
if (do_update)
m_minimap_update_thread->deferUpdate();
}
void Minimap::setAngle(f32 angle)
{
m_angle = angle;
}
void Minimap::blitMinimapPixelsToImageRadar(video::IImage *map_image)
{
video::SColor c(240, 0, 0, 0);
for (s16 x = 0; x < data->map_size; x++)
for (s16 z = 0; z < data->map_size; z++) {
MinimapPixel *mmpixel = &data->minimap_scan[x + z * data->map_size];
if (mmpixel->air_count > 0)
c.setGreen(core::clamp(core::round32(32 + mmpixel->air_count * 8), 0, 255));
else
c.setGreen(0);
map_image->setPixel(x, data->map_size - z - 1, c);
}
}
void Minimap::blitMinimapPixelsToImageSurface(
video::IImage *map_image, video::IImage *heightmap_image)
{
// This variable creation/destruction has a 1% cost on rendering minimap
video::SColor tilecolor;
for (s16 x = 0; x < data->map_size; x++)
for (s16 z = 0; z < data->map_size; z++) {
MinimapPixel *mmpixel = &data->minimap_scan[x + z * data->map_size];
const ContentFeatures &f = m_ndef->get(mmpixel->n);
const TileDef *tile = &f.tiledef[0];
// Color of the 0th tile (mostly this is the topmost)
if(tile->has_color)
tilecolor = tile->color;
else
mmpixel->n.getColor(f, &tilecolor);
tilecolor.setRed(tilecolor.getRed() * f.minimap_color.getRed() / 255);
tilecolor.setGreen(tilecolor.getGreen() * f.minimap_color.getGreen() / 255);
tilecolor.setBlue(tilecolor.getBlue() * f.minimap_color.getBlue() / 255);
tilecolor.setAlpha(240);
map_image->setPixel(x, data->map_size - z - 1, tilecolor);
u32 h = mmpixel->height;
heightmap_image->setPixel(x,data->map_size - z - 1,
video::SColor(255, h, h, h));
}
}
video::ITexture *Minimap::getMinimapTexture()
{
// update minimap textures when new scan is ready
if (data->map_invalidated)
return data->texture;
// create minimap and heightmap images in memory
core::dimension2d<u32> dim(data->map_size, data->map_size);
video::IImage *map_image = driver->createImage(video::ECF_A8R8G8B8, dim);
video::IImage *heightmap_image = driver->createImage(video::ECF_A8R8G8B8, dim);
video::IImage *minimap_image = driver->createImage(video::ECF_A8R8G8B8,
core::dimension2d<u32>(MINIMAP_MAX_SX, MINIMAP_MAX_SY));
// Blit MinimapPixels to images
if (data->is_radar)
blitMinimapPixelsToImageRadar(map_image);
else
blitMinimapPixelsToImageSurface(map_image, heightmap_image);
map_image->copyToScaling(minimap_image);
map_image->drop();
video::IImage *minimap_mask = data->minimap_shape_round ?
data->minimap_mask_round : data->minimap_mask_square;
if (minimap_mask) {
for (s16 y = 0; y < MINIMAP_MAX_SY; y++)
for (s16 x = 0; x < MINIMAP_MAX_SX; x++) {
const video::SColor &mask_col = minimap_mask->getPixel(x, y);
if (!mask_col.getAlpha())
minimap_image->setPixel(x, y, video::SColor(0,0,0,0));
}
}
if (data->texture)
driver->removeTexture(data->texture);
if (data->heightmap_texture)
driver->removeTexture(data->heightmap_texture);
data->texture = driver->addTexture("minimap__", minimap_image);
data->heightmap_texture =
driver->addTexture("minimap_heightmap__", heightmap_image);
minimap_image->drop();
heightmap_image->drop();
data->map_invalidated = true;
return data->texture;
}
v3f Minimap::getYawVec()
{
if (data->minimap_shape_round) {
return v3f(
cos(m_angle * core::DEGTORAD),
sin(m_angle * core::DEGTORAD),
1.0);
} else {
return v3f(1.0, 0.0, 1.0);
}
}
scene::SMeshBuffer *Minimap::getMinimapMeshBuffer()
{
scene::SMeshBuffer *buf = new scene::SMeshBuffer();
buf->Vertices.set_used(4);
buf->Indices.set_used(6);
static const video::SColor c(255, 255, 255, 255);
buf->Vertices[0] = video::S3DVertex(-1, -1, 0, 0, 0, 1, c, 0, 1);
buf->Vertices[1] = video::S3DVertex(-1, 1, 0, 0, 0, 1, c, 0, 0);
buf->Vertices[2] = video::S3DVertex( 1, 1, 0, 0, 0, 1, c, 1, 0);
buf->Vertices[3] = video::S3DVertex( 1, -1, 0, 0, 0, 1, c, 1, 1);
buf->Indices[0] = 0;
buf->Indices[1] = 1;
buf->Indices[2] = 2;
buf->Indices[3] = 2;
buf->Indices[4] = 3;
buf->Indices[5] = 0;
return buf;
}
void Minimap::drawMinimap()
{
video::ITexture *minimap_texture = getMinimapTexture();
if (!minimap_texture)
return;
updateActiveMarkers();
v2u32 screensize = porting::getWindowSize();
const u32 size = 0.25 * screensize.Y;
core::rect<s32> oldViewPort = driver->getViewPort();
core::matrix4 oldProjMat = driver->getTransform(video::ETS_PROJECTION);
core::matrix4 oldViewMat = driver->getTransform(video::ETS_VIEW);
driver->setViewPort(core::rect<s32>(
screensize.X - size - 10, 10,
screensize.X - 10, size + 10));
driver->setTransform(video::ETS_PROJECTION, core::matrix4());
driver->setTransform(video::ETS_VIEW, core::matrix4());
core::matrix4 matrix;
matrix.makeIdentity();
video::SMaterial &material = m_meshbuffer->getMaterial();
material.setFlag(video::EMF_TRILINEAR_FILTER, true);
material.Lighting = false;
material.TextureLayer[0].Texture = minimap_texture;
material.TextureLayer[1].Texture = data->heightmap_texture;
if (m_enable_shaders && !data->is_radar) {
u16 sid = m_shdrsrc->getShader("minimap_shader", 1, 1);
material.MaterialType = m_shdrsrc->getShaderInfo(sid).material;
} else {
material.MaterialType = video::EMT_TRANSPARENT_ALPHA_CHANNEL;
}
if (data->minimap_shape_round)
matrix.setRotationDegrees(core::vector3df(0, 0, 360 - m_angle));
// Draw minimap
driver->setTransform(video::ETS_WORLD, matrix);
driver->setMaterial(material);
driver->drawMeshBuffer(m_meshbuffer);
// Draw overlay
video::ITexture *minimap_overlay = data->minimap_shape_round ?
data->minimap_overlay_round : data->minimap_overlay_square;
material.TextureLayer[0].Texture = minimap_overlay;
material.MaterialType = video::EMT_TRANSPARENT_ALPHA_CHANNEL;
driver->setMaterial(material);
driver->drawMeshBuffer(m_meshbuffer);
// If round minimap, draw player marker
if (!data->minimap_shape_round) {
matrix.setRotationDegrees(core::vector3df(0, 0, m_angle));
material.TextureLayer[0].Texture = data->player_marker;
driver->setTransform(video::ETS_WORLD, matrix);
driver->setMaterial(material);
driver->drawMeshBuffer(m_meshbuffer);
}
// Reset transformations
driver->setTransform(video::ETS_VIEW, oldViewMat);
driver->setTransform(video::ETS_PROJECTION, oldProjMat);
driver->setViewPort(oldViewPort);
// Draw player markers
v2s32 s_pos(screensize.X - size - 10, 10);
core::dimension2di imgsize(data->object_marker_red->getOriginalSize());
core::rect<s32> img_rect(0, 0, imgsize.Width, imgsize.Height);
static const video::SColor col(255, 255, 255, 255);
static const video::SColor c[4] = {col, col, col, col};
f32 sin_angle = sin(m_angle * core::DEGTORAD);
f32 cos_angle = cos(m_angle * core::DEGTORAD);
s32 marker_size2 = 0.025 * (float)size;
for (std::list<v2f>::const_iterator
i = m_active_markers.begin();
i != m_active_markers.end(); ++i) {
v2f posf = *i;
if (data->minimap_shape_round) {
f32 t1 = posf.X * cos_angle - posf.Y * sin_angle;
f32 t2 = posf.X * sin_angle + posf.Y * cos_angle;
posf.X = t1;
posf.Y = t2;
}
posf.X = (posf.X + 0.5) * (float)size;
posf.Y = (posf.Y + 0.5) * (float)size;
core::rect<s32> dest_rect(
s_pos.X + posf.X - marker_size2,
s_pos.Y + posf.Y - marker_size2,
s_pos.X + posf.X + marker_size2,
s_pos.Y + posf.Y + marker_size2);
driver->draw2DImage(data->object_marker_red, dest_rect,
img_rect, &dest_rect, &c[0], true);
}
}
void Minimap::updateActiveMarkers()
{
video::IImage *minimap_mask = data->minimap_shape_round ?
data->minimap_mask_round : data->minimap_mask_square;
const std::list<Nametag *> &nametags = client->getCamera()->getNametags();
m_active_markers.clear();
for (std::list<Nametag *>::const_iterator i = nametags.begin();
i != nametags.end(); ++i) {
v3s16 pos = floatToInt((*i)->parent_node->getPosition() +
intToFloat(client->getCamera()->getOffset(), BS), BS);
pos -= data->pos - v3s16(data->map_size / 2,
data->scan_height / 2,
data->map_size / 2);
if (pos.X < 0 || pos.X > data->map_size ||
pos.Y < 0 || pos.Y > data->scan_height ||
pos.Z < 0 || pos.Z > data->map_size) {
continue;
}
pos.X = ((float)pos.X / data->map_size) * MINIMAP_MAX_SX;
pos.Z = ((float)pos.Z / data->map_size) * MINIMAP_MAX_SY;
const video::SColor &mask_col = minimap_mask->getPixel(pos.X, pos.Z);
if (!mask_col.getAlpha()) {
continue;
}
m_active_markers.push_back(v2f(((float)pos.X / (float)MINIMAP_MAX_SX) - 0.5,
(1.0 - (float)pos.Z / (float)MINIMAP_MAX_SY) - 0.5));
}
}
////
//// MinimapMapblock
////
void MinimapMapblock::getMinimapNodes(VoxelManipulator *vmanip, v3s16 pos)
{
for (s16 x = 0; x < MAP_BLOCKSIZE; x++)
for (s16 z = 0; z < MAP_BLOCKSIZE; z++) {
s16 air_count = 0;
bool surface_found = false;
MinimapPixel *mmpixel = &data[z * MAP_BLOCKSIZE + x];
for (s16 y = MAP_BLOCKSIZE -1; y >= 0; y--) {
v3s16 p(x, y, z);
MapNode n = vmanip->getNodeNoEx(pos + p);
if (!surface_found && n.getContent() != CONTENT_AIR) {
mmpixel->height = y;
mmpixel->n = n;
surface_found = true;
} else if (n.getContent() == CONTENT_AIR) {
air_count++;
}
}
if (!surface_found)
mmpixel->n = MapNode(CONTENT_AIR);
mmpixel->air_count = air_count;
}
}