paysages3d/lib_paysages/textures.c

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#include "textures.h"
#include <math.h>
#include <stdlib.h>
#include <string.h>
#include <assert.h>
#include "shared/types.h"
#include "color.h"
#include "euclid.h"
#include "lighting.h"
#include "terrain.h"
#include "tools.h"
static TextureLayerDefinition _NULL_LAYER;
typedef struct
{
double thickness;
Vector3 location;
Vector3 normal;
TextureLayerDefinition* definition;
} TextureResult;
void texturesInit()
{
_NULL_LAYER = texturesLayerCreateDefinition();
}
void texturesQuit()
{
texturesLayerDeleteDefinition(&_NULL_LAYER);
}
void texturesSave(PackStream* stream, TexturesDefinition* definition)
{
int i;
packWriteInt(stream, &definition->nblayers);
for (i = 0; i < definition->nblayers; i++)
{
packWriteString(stream, definition->layers[i].name, TEXTURES_MAX_NAME_LENGTH);
zoneSave(stream, definition->layers[i].zone);
noiseSaveGenerator(stream, definition->layers[i].bump_noise);
packWriteDouble(stream, &definition->layers[i].bump_height);
packWriteDouble(stream, &definition->layers[i].bump_scaling);
materialSave(stream, &definition->layers[i].material);
packWriteDouble(stream, &definition->layers[i].thickness);
packWriteDouble(stream, &definition->layers[i].slope_range);
packWriteDouble(stream, &definition->layers[i].thickness_transparency);
}
}
void texturesLoad(PackStream* stream, TexturesDefinition* definition)
{
TextureLayerDefinition* layer;
int i, n;
while (definition->nblayers > 0)
{
texturesDeleteLayer(definition, 0);
}
packReadInt(stream, &n);
for (i = 0; i < n; i++)
{
layer = definition->layers + texturesAddLayer(definition);
packReadString(stream, layer->name, TEXTURES_MAX_NAME_LENGTH);
zoneLoad(stream, layer->zone);
noiseLoadGenerator(stream, layer->bump_noise);
packReadDouble(stream, &layer->bump_height);
packReadDouble(stream, &layer->bump_scaling);
materialLoad(stream, &layer->material);
packReadDouble(stream, &definition->layers[i].thickness);
packReadDouble(stream, &definition->layers[i].slope_range);
packReadDouble(stream, &definition->layers[i].thickness_transparency);
}
texturesValidateDefinition(definition);
}
TexturesDefinition texturesCreateDefinition()
{
TexturesDefinition result;
result.nblayers = 0;
return result;
}
void texturesDeleteDefinition(TexturesDefinition* definition)
{
while (definition->nblayers > 0)
{
texturesDeleteLayer(definition, 0);
}
}
void texturesCopyDefinition(TexturesDefinition* source, TexturesDefinition* destination)
{
TextureLayerDefinition* layer;
int i;
while (destination->nblayers > 0)
{
texturesDeleteLayer(destination, 0);
}
for (i = 0; i < source->nblayers; i++)
{
layer = texturesGetLayer(destination, texturesAddLayer(destination));
texturesLayerCopyDefinition(source->layers + i, layer);
}
}
void texturesValidateDefinition(TexturesDefinition* definition)
{
int i;
for (i = 0; i < definition->nblayers; i++)
{
texturesLayerValidateDefinition(definition->layers + i);
}
}
TextureLayerDefinition texturesLayerCreateDefinition()
{
TextureLayerDefinition result;
texturesLayerSetName(&result, "Unnamed");
result.zone = zoneCreate();
result.bump_noise = noiseCreateGenerator();
noiseGenerateBaseNoise(result.bump_noise, 102400);
noiseAddLevelsSimple(result.bump_noise, 8, 1.0, 1.0);
result.bump_height = 0.1;
result.bump_scaling = 0.1;
result.material.base = COLOR_WHITE;
result.material.reflection = 0.0;
result.material.shininess = 0.0;
result.thickness = 0.0;
result.slope_range = 0.001;
result.thickness_transparency = 0.0;
return result;
}
void texturesLayerDeleteDefinition(TextureLayerDefinition* definition)
{
zoneDelete(definition->zone);
noiseDeleteGenerator(definition->bump_noise);
}
void texturesLayerCopyDefinition(TextureLayerDefinition* source, TextureLayerDefinition* destination)
{
strncpy(destination->name, source->name, TEXTURES_MAX_NAME_LENGTH);
destination->material = source->material;
destination->bump_height = source->bump_height;
destination->bump_scaling = source->bump_scaling;
destination->thickness = source->thickness;
destination->slope_range = source->slope_range;
destination->thickness_transparency = source->thickness_transparency;
noiseCopy(source->bump_noise, destination->bump_noise);
zoneCopy(source->zone, destination->zone);
}
void texturesLayerValidateDefinition(TextureLayerDefinition* definition)
{
definition->name[TEXTURES_MAX_NAME_LENGTH] = '\0';
if (definition->bump_scaling < 0.000001)
{
definition->bump_scaling = 0.000001;
}
if (definition->slope_range < 0.001)
{
definition->slope_range = 0.001;
}
}
void texturesLayerSetName(TextureLayerDefinition* definition, const char* name)
{
strncpy(definition->name, name, TEXTURES_MAX_NAME_LENGTH);
}
int texturesGetLayerCount(TexturesDefinition* definition)
{
return definition->nblayers;
}
TextureLayerDefinition* texturesGetLayer(TexturesDefinition* definition, int layer)
{
if (layer >= 0 && layer < definition->nblayers)
{
return definition->layers + layer;
}
else
{
return &_NULL_LAYER;
}
}
int texturesAddLayer(TexturesDefinition* definition)
{
if (definition->nblayers < TEXTURES_MAX_LAYERS)
{
definition->layers[definition->nblayers] = texturesLayerCreateDefinition();
return definition->nblayers++;
}
else
{
return -1;
}
}
void texturesDeleteLayer(TexturesDefinition* definition, int layer)
{
if (layer >= 0 && layer < definition->nblayers)
{
texturesLayerDeleteDefinition(definition->layers + layer);
if (definition->nblayers > 1 && layer < definition->nblayers - 1)
{
memmove(definition->layers + layer, definition->layers + layer + 1, sizeof(TextureLayerDefinition) * (definition->nblayers - layer - 1));
}
definition->nblayers--;
}
}
void texturesMoveLayer(TexturesDefinition* definition, int layer, int new_position)
{
if (layer >= 0 && layer < definition->nblayers && new_position != layer && new_position >= 0 && new_position < definition->nblayers)
{
TextureLayerDefinition temp;
temp = definition->layers[layer];
if (new_position > layer)
{
memmove(definition->layers + layer, definition->layers + layer + 1, sizeof(TextureLayerDefinition) * (new_position - layer));
}
else
{
memmove(definition->layers + new_position + 1, definition->layers + new_position, sizeof(TextureLayerDefinition) * (layer - new_position));
}
definition->layers[new_position] = temp;
}
}
static inline Vector3 _getNormal4(Vector3 center, Vector3 north, Vector3 east, Vector3 south, Vector3 west)
{
Vector3 dnorth, deast, dsouth, dwest, normal;
dnorth = v3Sub(north, center);
deast = v3Sub(east, center);
dsouth = v3Sub(south, center);
dwest = v3Sub(west, center);
normal = v3Cross(deast, dnorth);
normal = v3Add(normal, v3Cross(dsouth, deast));
normal = v3Add(normal, v3Cross(dwest, dsouth));
normal = v3Add(normal, v3Cross(dnorth, dwest));
return v3Normalize(normal);
}
static inline Vector3 _getNormal2(Vector3 center, Vector3 east, Vector3 south)
{
return v3Normalize(v3Cross(v3Sub(south, center), v3Sub(east, center)));
}
static inline TextureResult _getTerrainResult(Renderer* renderer, double x, double z, double detail)
{
TextureResult result;
Vector3 center, north, east, south, west;
/* TODO This method is better suited in terrain.c */
center.x = x;
center.z = z;
center.y = renderer->getTerrainHeight(renderer, center.x, center.z);
east.x = x + detail;
east.z = z;
east.y = renderer->getTerrainHeight(renderer, east.x, east.z);
south.x = x;
south.z = z + detail;
south.y = renderer->getTerrainHeight(renderer, south.x, south.z);
if (renderer->render_quality > 5)
{
west.x = x - detail;
west.z = z;
west.y = renderer->getTerrainHeight(renderer, west.x, west.z);
north.x = x;
north.z = z - detail;
north.y = renderer->getTerrainHeight(renderer, north.x, north.z);
result.normal = _getNormal4(center, north, east, south, west);
}
else
{
result.normal = _getNormal2(center, east, south);
}
result.location = center;
result.thickness = -100.0;
result.definition = NULL;
return result;
}
static inline void _getLayerThickness(TextureLayerDefinition* definition, Renderer* renderer, double x, double z, TextureResult* result)
{
TextureResult base;
double coverage;
base = _getTerrainResult(renderer, x, z, definition->slope_range);
coverage = zoneGetValue(definition->zone, base.location, base.normal);
if (coverage > 0.0)
{
result->thickness = coverage * definition->thickness;
result->thickness += noiseGet2DTotal(definition->bump_noise, base.location.x / definition->bump_scaling, base.location.z / definition->bump_scaling) * definition->bump_height;
result->location = v3Add(base.location, v3Scale(base.normal, result->thickness));
}
else
{
result->thickness = -1000.0;
result->location = base.location;
}
}
static inline TextureResult _getLayerResult(TextureLayerDefinition* definition, Renderer* renderer, double x, double z, double detail)
{
TextureResult result_center, result_north, result_east, result_south, result_west;
_getLayerThickness(definition, renderer, x, z, &result_center);
_getLayerThickness(definition, renderer, x + detail, z, &result_east);
_getLayerThickness(definition, renderer, x, z + detail, &result_south);
if (renderer->render_quality > 5)
{
_getLayerThickness(definition, renderer, x - detail, z, &result_west);
_getLayerThickness(definition, renderer, x, z - detail, &result_north);
result_center.normal = _getNormal4(result_center.location, result_north.location, result_east.location, result_south.location, result_west.location);
}
else
{
result_center.normal = _getNormal2(result_center.location, result_east.location, result_south.location);
}
result_center.definition = definition;
return result_center;
}
static int _cmpResults(const void* result1, const void* result2)
{
return ((TextureResult*)result1)->thickness > ((TextureResult*)result2)->thickness;
}
double texturesGetLayerCoverage(TextureLayerDefinition* definition, Renderer* renderer, Vector3 location, double detail)
{
TextureResult base = _getTerrainResult(renderer, location.x, location.z, definition->slope_range);
return zoneGetValue(definition->zone, base.location, base.normal);
}
static inline Color _getLayerColor(Renderer* renderer, TextureResult result, LightStatus* light)
{
return renderer->applyLightStatus(renderer, light, result.location, result.normal, result.definition->material);
}
Color texturesGetLayerColor(TextureLayerDefinition* definition, Renderer* renderer, Vector3 location, double detail)
{
LightStatus light;
TextureResult result = _getLayerResult(definition, renderer, location.x, location.z, detail);
renderer->getLightStatus(renderer, &light, result.location);
return _getLayerColor(renderer, result, &light);
}
Color texturesGetColor(TexturesDefinition* definition, Renderer* renderer, double x, double z, double detail)
{
TextureResult results[TEXTURES_MAX_LAYERS + 1];
Color result, color;
double thickness, last_height;
int i, start;
detail *= 0.1;
results[0] = _getTerrainResult(renderer, x, z, detail);
for (i = 0; i < definition->nblayers; i++)
{
results[i + 1] = _getLayerResult(definition->layers + i, renderer, x, z, detail);
}
qsort(results, definition->nblayers + 1, sizeof(TextureResult), _cmpResults);
/* Pre compute alpha channel */
start = 0;
last_height = results[0].thickness;
for (i = 1; i <= definition->nblayers; i++)
{
thickness = results[i].thickness - last_height;
last_height = results[i].thickness;
if (results[i].definition)
{
if (thickness < results[i].definition->thickness_transparency)
{
results[i].thickness = thickness / results[i].definition->thickness_transparency;
}
else
{
results[i].thickness = (thickness > 0.0) ? 1.0 : 0.0;
}
}
else
{
color = COLOR_GREEN;
results[i].thickness = 1.0;
}
if (results[i].thickness >= 0.999999)
{
start = i;
}
colorMask(&result, &color);
}
/* Apply colors and alphas */
LightStatus light;
renderer->getLightStatus(renderer, &light, results[start].location);
if (results[start].definition)
{
result = _getLayerColor(renderer, results[start], &light);
}
else
{
result = COLOR_GREEN;
}
for (i = start; i <= definition->nblayers; i++)
{
if (results[i].thickness)
{
if (results[i].definition)
{
color = _getLayerColor(renderer, results[i], &light);
color.a = results[i].thickness;
}
else
{
color = COLOR_GREEN;
}
colorMask(&result, &color);
}
}
return result;
}