paysages : Clouds refactoring (WIP) + explorer improvements.

git-svn-id: https://subversion.assembla.com/svn/thunderk/paysages@511 b1fd45b6-86a6-48da-8261-f70d1f35bdcc
This commit is contained in:
Michaël Lemaire 2013-01-30 21:36:49 +00:00 committed by ThunderK
parent 620877bf64
commit c0f945fb27
13 changed files with 111 additions and 122 deletions

3
TODO
View file

@ -23,6 +23,9 @@ Technology Preview 2 :
- Clouds should keep distance to ground. - Clouds should keep distance to ground.
- Fix rendering when inside a cloud layer, with other upper or lower layers. - Fix rendering when inside a cloud layer, with other upper or lower layers.
- Improve cloud rendering precision (and beware of precision discontinuity when rendering clouds in front of ground (shorter distance)). - Improve cloud rendering precision (and beware of precision discontinuity when rendering clouds in front of ground (shorter distance)).
- Top-down previews and explorer renderings should be camera independant.
- Explorer should have a waiting message while init.
- Sun radius is too small.
Technlogy Preview 3 : Technlogy Preview 3 :
- Fully move layer management from BaseForm to BaseFormLayer. - Fully move layer management from BaseForm to BaseFormLayer.

View file

@ -64,6 +64,11 @@ bool BaseExplorerChunk::maintain()
_texture_changed = true; _texture_changed = true;
_lock_data.unlock(); _lock_data.unlock();
if (_texture_current_size < 8 && _texture_current_size < _texture_max_size)
{
maintain();
}
return true; return true;
} }
else else
@ -113,7 +118,10 @@ void BaseExplorerChunk::render(QGLWidget* widget)
_lock_data.unlock(); _lock_data.unlock();
// Delegate poly rendering to subclass // Delegate poly rendering to subclass
if (!_reset_needed)
{
onRenderEvent(widget); onRenderEvent(widget);
}
} }
void BaseExplorerChunk::askReset() void BaseExplorerChunk::askReset()

View file

@ -59,6 +59,11 @@ bool ExplorerChunkTerrain::onMaintainEvent()
_tessellation_current_size = new_tessellation_size; _tessellation_current_size = new_tessellation_size;
_lock_data.unlock(); _lock_data.unlock();
if (_tessellation_current_size < 8 && _tessellation_current_size < _tessellation_max_size)
{
onMaintainEvent();
}
return true; return true;
} }
else else

View file

@ -44,7 +44,7 @@ WidgetHeightMap::WidgetHeightMap(QWidget *parent, TerrainDefinition* terrain):
_brush_smoothing = 0.5; _brush_smoothing = 0.5;
_brush_strength = 1.0; _brush_strength = 1.0;
_brush_noise = noiseCreateGenerator(); _brush_noise = noiseCreateGenerator();
noiseAddLevelsSimple(_brush_noise, 10, 1.0, -0.5, 0.5); noiseAddLevelsSimple(_brush_noise, 10, 1.0, -0.5, 0.5, 0.5);
} }
WidgetHeightMap::~WidgetHeightMap() WidgetHeightMap::~WidgetHeightMap()

View file

@ -39,7 +39,7 @@ void autoGenRealisticLandscape(int seed)
texture = layersGetLayer(textures.layers, layer); texture = layersGetLayer(textures.layers, layer);
noiseClearLevels(texture->bump_noise); noiseClearLevels(texture->bump_noise);
noiseRandomizeOffsets(texture->bump_noise); noiseRandomizeOffsets(texture->bump_noise);
noiseAddLevelsSimple(texture->bump_noise, 8, 1.0, -0.5, 0.5); noiseAddLevelsSimple(texture->bump_noise, 8, 1.0, -0.5, 0.5, 0.5);
texture->bump_height = 0.01; texture->bump_height = 0.01;
texture->bump_scaling = 0.045; texture->bump_scaling = 0.045;
texture->material.base.r = 0.6; texture->material.base.r = 0.6;
@ -57,8 +57,8 @@ void autoGenRealisticLandscape(int seed)
zoneAddSlopeRangeQuick(texture->zone, 1.0, 0.0, 0.0, 0.05, 0.4); zoneAddSlopeRangeQuick(texture->zone, 1.0, 0.0, 0.0, 0.05, 0.4);
noiseClearLevels(texture->bump_noise); noiseClearLevels(texture->bump_noise);
noiseRandomizeOffsets(texture->bump_noise); noiseRandomizeOffsets(texture->bump_noise);
noiseAddLevelsSimple(texture->bump_noise, 5, 1.0, -0.2, 0.2); noiseAddLevelsSimple(texture->bump_noise, 5, 1.0, -0.2, 0.2, 0.5);
noiseAddLevelsSimple(texture->bump_noise, 2, 0.03, -0.04, 0.04); noiseAddLevelsSimple(texture->bump_noise, 2, 0.03, -0.04, 0.04, 0.5);
texture->bump_height = 0.002; texture->bump_height = 0.002;
texture->bump_scaling = 0.03; texture->bump_scaling = 0.03;
texture->material.base.r = 0.12; texture->material.base.r = 0.12;

View file

@ -65,17 +65,17 @@ void cloudsLayerValidateDefinition(CloudsLayerDefinition* definition)
noiseClearLevels(definition->_edge_noise); noiseClearLevels(definition->_edge_noise);
noiseClearLevels(definition->_coverage_noise); noiseClearLevels(definition->_coverage_noise);
noiseAddLevelsSimple(definition->_coverage_noise, 3, 1.0, 0.0, 1.0, 0.0);
noiseSetFunctionParams(definition->_coverage_noise, NOISE_FUNCTION_NAIVE, 0.0, 0.0);
switch (definition->type) switch (definition->type)
{ {
case CLOUDS_TYPE_CIRRUS: case CLOUDS_TYPE_CIRRUS:
curveQuickAddPoint(definition->_coverage_by_altitude, 0.0, 0.0); curveQuickAddPoint(definition->_coverage_by_altitude, 0.0, 0.0);
curveQuickAddPoint(definition->_coverage_by_altitude, 0.5, 1.0); curveQuickAddPoint(definition->_coverage_by_altitude, 0.5, 1.0);
curveQuickAddPoint(definition->_coverage_by_altitude, 1.0, 0.0); curveQuickAddPoint(definition->_coverage_by_altitude, 1.0, 0.0);
noiseAddLevelsSimple(definition->_coverage_noise, 3, 1.0, -0.5, 0.5); noiseAddLevelsSimple(definition->_shape_noise, 3, 1.0, 0.0, 1.0, 0.5);
noiseSetFunctionParams(definition->_coverage_noise, NOISE_FUNCTION_SIMPLEX, 0.0, 0.0);
noiseAddLevelsSimple(definition->_shape_noise, 3, 1.0, -0.5, 0.5);
noiseSetFunctionParams(definition->_shape_noise, NOISE_FUNCTION_SIMPLEX, 0.0, 0.0); noiseSetFunctionParams(definition->_shape_noise, NOISE_FUNCTION_SIMPLEX, 0.0, 0.0);
noiseAddLevelsSimple(definition->_edge_noise, 4, 1.0, -0.5, 0.5); noiseAddLevelsSimple(definition->_edge_noise, 4, 1.0, -0.5, 0.5, 0.5);
noiseSetFunctionParams(definition->_edge_noise, NOISE_FUNCTION_SIMPLEX, -0.2, 0.0); noiseSetFunctionParams(definition->_edge_noise, NOISE_FUNCTION_SIMPLEX, -0.2, 0.0);
break; break;
case CLOUDS_TYPE_CUMULUS: case CLOUDS_TYPE_CUMULUS:
@ -84,9 +84,7 @@ void cloudsLayerValidateDefinition(CloudsLayerDefinition* definition)
curveQuickAddPoint(definition->_coverage_by_altitude, 0.4, 0.8); curveQuickAddPoint(definition->_coverage_by_altitude, 0.4, 0.8);
curveQuickAddPoint(definition->_coverage_by_altitude, 0.7, 1.0); curveQuickAddPoint(definition->_coverage_by_altitude, 0.7, 1.0);
curveQuickAddPoint(definition->_coverage_by_altitude, 1.0, 0.0); curveQuickAddPoint(definition->_coverage_by_altitude, 1.0, 0.0);
noiseAddLevelsSimple(definition->_coverage_noise, 3, 1.0, -0.5, 0.5); noiseAddLevelsSimple(definition->_shape_noise, 7, 1.0, 0.0, 1.0, 0.5);
noiseSetFunctionParams(definition->_coverage_noise, NOISE_FUNCTION_SIMPLEX, 0.4, 0.0);
noiseAddLevelsSimple(definition->_shape_noise, 7, 1.0, -0.5, 0.5);
noiseSetFunctionParams(definition->_shape_noise, NOISE_FUNCTION_SIMPLEX, 0.4, 0.0); noiseSetFunctionParams(definition->_shape_noise, NOISE_FUNCTION_SIMPLEX, 0.4, 0.0);
break; break;
case CLOUDS_TYPE_STRATOCUMULUS: case CLOUDS_TYPE_STRATOCUMULUS:
@ -94,11 +92,9 @@ void cloudsLayerValidateDefinition(CloudsLayerDefinition* definition)
curveQuickAddPoint(definition->_coverage_by_altitude, 0.2, 1.0); curveQuickAddPoint(definition->_coverage_by_altitude, 0.2, 1.0);
curveQuickAddPoint(definition->_coverage_by_altitude, 0.5, 1.0); curveQuickAddPoint(definition->_coverage_by_altitude, 0.5, 1.0);
curveQuickAddPoint(definition->_coverage_by_altitude, 1.0, 0.0); curveQuickAddPoint(definition->_coverage_by_altitude, 1.0, 0.0);
noiseAddLevelsSimple(definition->_coverage_noise, 2, 1.0, -0.5, 0.5); noiseAddLevelsSimple(definition->_shape_noise, 2, 1.0, 0.0, 1.0, 0.5);
noiseSetFunctionParams(definition->_coverage_noise, NOISE_FUNCTION_SIMPLEX, 0.3, 0.0);
noiseAddLevelsSimple(definition->_shape_noise, 2, 1.0, -0.5, 0.5);
noiseSetFunctionParams(definition->_shape_noise, NOISE_FUNCTION_SIMPLEX, 0.3, 0.0); noiseSetFunctionParams(definition->_shape_noise, NOISE_FUNCTION_SIMPLEX, 0.3, 0.0);
noiseAddLevelsSimple(definition->_edge_noise, 8, 1.0, -0.5, 0.5); noiseAddLevelsSimple(definition->_edge_noise, 8, 1.0, -0.5, 0.5, 0.5);
noiseSetFunctionParams(definition->_edge_noise, NOISE_FUNCTION_SIMPLEX, 0.5, 0.0); noiseSetFunctionParams(definition->_edge_noise, NOISE_FUNCTION_SIMPLEX, 0.5, 0.0);
break; break;
case CLOUDS_TYPE_STRATUS: case CLOUDS_TYPE_STRATUS:
@ -106,16 +102,17 @@ void cloudsLayerValidateDefinition(CloudsLayerDefinition* definition)
curveQuickAddPoint(definition->_coverage_by_altitude, 0.2, 1.0); curveQuickAddPoint(definition->_coverage_by_altitude, 0.2, 1.0);
curveQuickAddPoint(definition->_coverage_by_altitude, 0.8, 1.0); curveQuickAddPoint(definition->_coverage_by_altitude, 0.8, 1.0);
curveQuickAddPoint(definition->_coverage_by_altitude, 1.0, 0.0); curveQuickAddPoint(definition->_coverage_by_altitude, 1.0, 0.0);
noiseAddLevelsSimple(definition->_coverage_noise, 3, 1.0, -0.5, 0.5); noiseAddLevelsSimple(definition->_shape_noise, 3, 1.0, 0.0, 1.0, 0.5);
noiseSetFunctionParams(definition->_coverage_noise, NOISE_FUNCTION_SIMPLEX, -0.3, 0.0);
noiseAddLevelsSimple(definition->_shape_noise, 3, 1.0, -0.5, 0.5);
noiseSetFunctionParams(definition->_shape_noise, NOISE_FUNCTION_SIMPLEX, -0.3, 0.0); noiseSetFunctionParams(definition->_shape_noise, NOISE_FUNCTION_SIMPLEX, -0.3, 0.0);
noiseAddLevelsSimple(definition->_edge_noise, 4, 1.0, -0.5, 0.5); noiseAddLevelsSimple(definition->_edge_noise, 4, 1.0, -0.5, 0.5, 0.5);
noiseSetFunctionParams(definition->_edge_noise, NOISE_FUNCTION_SIMPLEX, -0.5, 0.0); noiseSetFunctionParams(definition->_edge_noise, NOISE_FUNCTION_SIMPLEX, -0.5, 0.0);
break; break;
default: default:
break; break;
} }
noiseNormalizeAmplitude(definition->_coverage_noise, 0.0, 1.0, 0);
noiseNormalizeAmplitude(definition->_shape_noise, -0.5, 0.5, 0);
} }
CloudsLayerDefinition* cloudsLayerCreateDefinition() CloudsLayerDefinition* cloudsLayerCreateDefinition()

View file

@ -4,7 +4,7 @@
#include "public.h" #include "public.h"
#define CLOUDS_MAX_LAYERS 6 #define CLOUDS_MAX_LAYERS 6
#define MAX_SEGMENT_COUNT 30 #define MAX_SEGMENT_COUNT 100
typedef struct typedef struct
{ {

View file

@ -7,55 +7,10 @@
#include "../renderer.h" #include "../renderer.h"
#include "../tools.h" #include "../tools.h"
static double _standardCoverageFunc(CloudsLayerDefinition* layer, Vector3 position)
{
if (position.y < layer->lower_altitude || position.y >= layer->lower_altitude + layer->thickness)
{
return 0.0;
}
else
{
return layer->base_coverage * curveGetValue(layer->_coverage_by_altitude, (position.y - layer->lower_altitude) / layer->thickness);
}
}
static inline double _getDistanceToBorder(CloudsLayerDefinition* layer, Vector3 position)
{
double density, coverage, val;
val = noiseGet3DTotal(layer->_shape_noise, position.x / layer->shape_scaling, position.y / layer->shape_scaling, position.z / layer->shape_scaling) / 0.5;
coverage = _standardCoverageFunc(layer, position);
density = 0.5 * val - 0.5 + coverage;
if (density <= 0.0)
{
/* outside the main shape */
return density * layer->shape_scaling;
}
else
{
/* inside the main shape, using edge noise */
density /= coverage;
if (density < layer->edge_length)
{
density /= layer->edge_length;
val = 0.5 * noiseGet3DTotal(layer->_edge_noise, position.x / layer->edge_scaling, position.y / layer->edge_scaling, position.z / layer->edge_scaling) / 0.5;
val = val - 0.5 + density;
return val * (density * coverage * layer->shape_scaling + (1.0 - density) * layer->edge_scaling);
}
else
{
return density * coverage * layer->shape_scaling;
}
}
}
static inline Vector3 _getNormal(CloudsLayerDefinition* layer, Vector3 position, double detail) static inline Vector3 _getNormal(CloudsLayerDefinition* layer, Vector3 position, double detail)
{ {
Vector3 result = {0.0, 0.0, 0.0}; Vector3 result = {0.0, 0.0, 0.0};
Vector3 dposition; /*Vector3 dposition;
double val, dval; double val, dval;
val = _getDistanceToBorder(layer, position); val = _getDistanceToBorder(layer, position);
@ -86,7 +41,7 @@ static inline Vector3 _getNormal(CloudsLayerDefinition* layer, Vector3 position,
dposition.z = position.z - detail; dposition.z = position.z - detail;
dval = val - _getDistanceToBorder(layer, dposition); dval = val - _getDistanceToBorder(layer, dposition);
result.z -= dval; result.z -= dval;*/
return v3Normalize(result); return v3Normalize(result);
} }
@ -153,13 +108,12 @@ static int _optimizeSearchLimits(CloudsLayerDefinition* layer, Vector3* start, V
} }
/** /**
* Go through the cloud layer to find segments (parts of the lookup that are inside the cloud). * Go through the cloud layer to find segments (parts of the lookup that are likely to contain cloud).
* *
* @param definition The cloud layer * @param definition The cloud layer
* @param renderer The renderer environment * @param renderer The renderer environment
* @param start Start position of the lookup (already optimized) * @param start Start position of the lookup (already optimized)
* @param direction Normalized direction of the lookup * @param direction Normalized direction of the lookup
* @param detail Level of noise detail required
* @param max_segments Maximum number of segments to collect * @param max_segments Maximum number of segments to collect
* @param max_inside_length Maximum length to spend inside the cloud * @param max_inside_length Maximum length to spend inside the cloud
* @param max_total_length Maximum lookup length * @param max_total_length Maximum lookup length
@ -168,13 +122,13 @@ static int _optimizeSearchLimits(CloudsLayerDefinition* layer, Vector3* start, V
* @param out_segments Allocated space to fill found segments * @param out_segments Allocated space to fill found segments
* @return Number of segments found * @return Number of segments found
*/ */
static int _findSegments(CloudsLayerDefinition* definition, Renderer* renderer, Vector3 start, Vector3 direction, double detail, int max_segments, double max_inside_length, double max_total_length, double* inside_length, double* total_length, CloudSegment* out_segments) static int _getPrimarySegments(CloudsLayerDefinition* definition, Renderer* renderer, Vector3 start, Vector3 direction, int max_segments, double max_inside_length, double max_total_length, double* inside_length, double* total_length, CloudSegment* out_segments)
{ {
int inside, segment_count; int inside, segment_count;
double current_total_length, current_inside_length; double current_total_length, current_inside_length;
double step_length, segment_length, remaining_length; double step_length, segment_length;
double noise_distance, last_noise_distance;
Vector3 walker, step, segment_start; Vector3 walker, step, segment_start;
CloudsInfo info;
double render_precision; double render_precision;
if (max_segments <= 0) if (max_segments <= 0)
@ -197,69 +151,67 @@ static int _findSegments(CloudsLayerDefinition* definition, Renderer* renderer,
current_inside_length = 0.0; current_inside_length = 0.0;
segment_length = 0.0; segment_length = 0.0;
walker = start; walker = start;
noise_distance = _getDistanceToBorder(definition, start) * render_precision; info = renderer->clouds->getLayerInfo(renderer, definition, start);
inside = (noise_distance > 0.0) ? 1 : 0; inside = info.inside;
step = v3Scale(direction, render_precision); step = v3Scale(direction, render_precision);
do do
{ {
walker = v3Add(walker, step); walker = v3Add(walker, step);
step_length = v3Norm(step); step_length = v3Norm(step);
last_noise_distance = noise_distance;
noise_distance = _getDistanceToBorder(definition, walker) * render_precision;
current_total_length += step_length; current_total_length += step_length;
if (current_total_length >= max_total_length || current_inside_length > max_inside_length) if (current_total_length >= max_total_length || current_inside_length > max_inside_length)
{ {
noise_distance = 0.0; info.distance_to_edge = 0.0;
info.inside = 0;
}
else
{
info = renderer->clouds->getLayerInfo(renderer, definition, walker);
} }
if (noise_distance > 0.0) if (info.inside)
{ {
if (inside) if (inside)
{ {
// inside the cloud /* inside the cloud */
segment_length += step_length; segment_length += step_length;
current_inside_length += step_length; current_inside_length += step_length;
step = v3Scale(direction, (noise_distance < render_precision) ? render_precision : noise_distance);
} }
else else
{ {
// entering the cloud /* entering the cloud */
inside = 1; segment_length = step_length;
segment_length = step_length * noise_distance / (noise_distance - last_noise_distance); segment_start = walker;
segment_start = v3Add(walker, v3Scale(direction, -segment_length));
current_inside_length += segment_length; current_inside_length += segment_length;
step = v3Scale(direction, render_precision); /* TODO Refine entry position */
inside = 1;
} }
} }
else else
{ {
if (inside) if (inside)
{ {
// exiting the cloud /* exiting the cloud */
remaining_length = step_length * last_noise_distance / (last_noise_distance - noise_distance); segment_length += step_length;
segment_length += remaining_length; current_inside_length += step_length;
current_inside_length += remaining_length;
out_segments->start = segment_start; out_segments->start = segment_start;
out_segments->end = v3Add(walker, v3Scale(direction, remaining_length - step_length)); out_segments->end = walker;
out_segments->length = segment_length; out_segments->length = segment_length;
out_segments++; out_segments++;
if (++segment_count >= max_segments) if (++segment_count >= max_segments)
{ {
break; break;
} }
/* TODO Refine exit position */
inside = 0; inside = 0;
step = v3Scale(direction, render_precision);
}
else
{
// searching for a cloud
step = v3Scale(direction, (noise_distance > -render_precision) ? render_precision : -noise_distance);
} }
} }
step = v3Scale(direction, (info.distance_to_edge < render_precision) ? render_precision : info.distance_to_edge);
} while (inside || (walker.y <= definition->lower_altitude + definition->thickness + 0.001 && walker.y >= definition->lower_altitude - 0.001 && current_total_length < max_total_length && current_inside_length < max_inside_length)); } while (inside || (walker.y <= definition->lower_altitude + definition->thickness + 0.001 && walker.y >= definition->lower_altitude - 0.001 && current_total_length < max_total_length && current_inside_length < max_inside_length));
*total_length = current_total_length; *total_length = current_total_length;
@ -309,8 +261,8 @@ static Color _applyLayerLighting(CloudsLayerDefinition* definition, Renderer* re
Color cloudsApplyLayer(CloudsLayerDefinition* definition, Color base, Renderer* renderer, Vector3 start, Vector3 end) Color cloudsApplyLayer(CloudsLayerDefinition* definition, Color base, Renderer* renderer, Vector3 start, Vector3 end)
{ {
int i, segment_count; int segment_count;
double max_length, detail, total_length, inside_length; double max_length, total_length, inside_length;
Vector3 direction; Vector3 direction;
Color col; Color col;
CloudSegment segments[MAX_SEGMENT_COUNT]; CloudSegment segments[MAX_SEGMENT_COUNT];
@ -324,21 +276,20 @@ Color cloudsApplyLayer(CloudsLayerDefinition* definition, Color base, Renderer*
max_length = v3Norm(direction); max_length = v3Norm(direction);
direction = v3Normalize(direction); direction = v3Normalize(direction);
detail = renderer->getPrecision(renderer, start) / definition->shape_scaling; segment_count = _getPrimarySegments(definition, renderer, start, direction, MAX_SEGMENT_COUNT, definition->transparencydepth * (double)renderer->render_quality, max_length, &inside_length, &total_length, segments);
/* TODO Crawl in segments for render */
segment_count = _findSegments(definition, renderer, start, direction, detail, MAX_SEGMENT_COUNT, definition->transparencydepth * (double)renderer->render_quality, max_length, &inside_length, &total_length, segments); col = definition->material.base;
for (i = segment_count - 1; i >= 0; i--) if (definition->transparencydepth == 0 || inside_length >= definition->transparencydepth)
{ {
col = _applyLayerLighting(definition, renderer, segments[i].start, detail);
col.a = 1.0; col.a = 1.0;
col = renderer->atmosphere->applyAerialPerspective(renderer, start, col); }
col.a = (segments[i].length >= definition->transparencydepth) ? 1.0 : (segments[i].length / definition->transparencydepth); else
{
col.a = inside_length / definition->transparencydepth;
}
colorMask(&base, &col); colorMask(&base, &col);
}
if (inside_length >= definition->transparencydepth)
{
col.a = 1.0;
}
return base; return base;
} }
@ -348,9 +299,12 @@ Color cloudsLayerFilterLight(CloudsLayerDefinition* definition, Renderer* render
double inside_depth, total_depth, factor; double inside_depth, total_depth, factor;
CloudSegment segments[MAX_SEGMENT_COUNT]; CloudSegment segments[MAX_SEGMENT_COUNT];
_optimizeSearchLimits(definition, &location, &light_location); if (!_optimizeSearchLimits(definition, &location, &light_location))
{
return light;
}
_findSegments(definition, renderer, location, direction_to_light, 0.1, MAX_SEGMENT_COUNT, definition->lighttraversal, v3Norm(v3Sub(light_location, location)), &inside_depth, &total_depth, segments); _getPrimarySegments(definition, renderer, location, direction_to_light, MAX_SEGMENT_COUNT, definition->lighttraversal, v3Norm(v3Sub(light_location, location)), &inside_depth, &total_depth, segments);
if (definition->lighttraversal < 0.0001) if (definition->lighttraversal < 0.0001)
{ {
@ -381,7 +335,16 @@ Color cloudsLayerFilterLight(CloudsLayerDefinition* definition, Renderer* render
*/ */
static inline double _getLayerCoverage(CloudsLayerDefinition* layer, double x, double z) static inline double _getLayerCoverage(CloudsLayerDefinition* layer, double x, double z)
{ {
return sin(x) * cos(z); if (layer->base_coverage == 0.0)
{
return 0.0;
}
else
{
double coverage = noiseGet2DTotal(layer->_coverage_noise, x / layer->shape_scaling, z / layer->shape_scaling);
coverage -= (1.0 - layer->base_coverage);
return (coverage <= 0.0) ? 0.0 : coverage;
}
} }
/* /*
@ -391,7 +354,20 @@ static inline double _getLayerCoverage(CloudsLayerDefinition* layer, double x, d
*/ */
static inline double _getLayerDensity(CloudsLayerDefinition* layer, Vector3 location, double coverage) static inline double _getLayerDensity(CloudsLayerDefinition* layer, Vector3 location, double coverage)
{ {
if (coverage == 0.0)
{
return 0.0;
}
else if (coverage == 1.0)
{
return 1.0; return 1.0;
}
else
{
double density = noiseGet3DTotal(layer->_shape_noise, location.x / layer->shape_scaling, location.y / layer->shape_scaling, location.z / layer->shape_scaling);
density -= (0.5 - coverage);
return (density <= 0.0) ? 0.0 : density;
}
} }
CloudsInfo cloudsGetLayerInfo(Renderer* renderer, CloudsLayerDefinition* layer, Vector3 location) CloudsInfo cloudsGetLayerInfo(Renderer* renderer, CloudsLayerDefinition* layer, Vector3 location)
@ -401,7 +377,7 @@ CloudsInfo cloudsGetLayerInfo(Renderer* renderer, CloudsLayerDefinition* layer,
UNUSED(renderer); UNUSED(renderer);
result.density = 0.0; result.density = 0.0;
result.distance_to_edge = 1.0; result.distance_to_edge = 0.1;
/* Get coverage info */ /* Get coverage info */
double coverage = _getLayerCoverage(layer, location.x, location.z); double coverage = _getLayerCoverage(layer, location.x, location.z);

View file

@ -311,14 +311,14 @@ void noiseAddLevels(NoiseGenerator* generator, int level_count, NoiseLevel start
} }
} }
void noiseAddLevelsSimple(NoiseGenerator* generator, int level_count, double scaling, double minvalue, double maxvalue) void noiseAddLevelsSimple(NoiseGenerator* generator, int level_count, double scaling, double minvalue, double maxvalue, double center_factor)
{ {
NoiseLevel level; NoiseLevel level;
level.wavelength = scaling; level.wavelength = scaling;
level.minvalue = minvalue; level.minvalue = minvalue;
level.amplitude = maxvalue - minvalue; level.amplitude = maxvalue - minvalue;
noiseAddLevels(generator, level_count, level, 0.5, 0.5, 0.5); noiseAddLevels(generator, level_count, level, 0.5, 0.5, center_factor);
} }
void noiseRemoveLevel(NoiseGenerator* generator, int level) void noiseRemoveLevel(NoiseGenerator* generator, int level)

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@ -55,7 +55,7 @@ void noiseClearLevels(NoiseGenerator* generator);
void noiseAddLevel(NoiseGenerator* generator, NoiseLevel level, int protect_offsets); void noiseAddLevel(NoiseGenerator* generator, NoiseLevel level, int protect_offsets);
void noiseAddLevelSimple(NoiseGenerator* generator, double scaling, double minvalue, double maxvalue); void noiseAddLevelSimple(NoiseGenerator* generator, double scaling, double minvalue, double maxvalue);
void noiseAddLevels(NoiseGenerator* generator, int level_count, NoiseLevel start_level, double scaling_factor, double amplitude_factor, double center_factor); void noiseAddLevels(NoiseGenerator* generator, int level_count, NoiseLevel start_level, double scaling_factor, double amplitude_factor, double center_factor);
void noiseAddLevelsSimple(NoiseGenerator* generator, int level_count, double scaling, double minvalue, double maxvalue); void noiseAddLevelsSimple(NoiseGenerator* generator, int level_count, double scaling, double minvalue, double maxvalue, double center_factor);
void noiseRemoveLevel(NoiseGenerator* generator, int level); void noiseRemoveLevel(NoiseGenerator* generator, int level);
int noiseGetLevel(NoiseGenerator* generator, int level, NoiseLevel* params); int noiseGetLevel(NoiseGenerator* generator, int level, NoiseLevel* params);
void noiseSetLevel(NoiseGenerator* generator, int index, NoiseLevel level, int protect_offsets); void noiseSetLevel(NoiseGenerator* generator, int index, NoiseLevel level, int protect_offsets);

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@ -14,7 +14,7 @@ void terrainAutoPreset(TerrainDefinition* definition, TerrainPreset preset)
case TERRAIN_PRESET_STANDARD: case TERRAIN_PRESET_STANDARD:
noiseRandomizeOffsets(definition->_height_noise); noiseRandomizeOffsets(definition->_height_noise);
noiseClearLevels(definition->_height_noise); noiseClearLevels(definition->_height_noise);
noiseAddLevelsSimple(definition->_height_noise, resolution, pow(2.0, resolution - 1), -12.5, 12.5); noiseAddLevelsSimple(definition->_height_noise, resolution, pow(2.0, resolution - 1), -12.5, 12.5, 0.5);
noiseSetFunctionParams(definition->_height_noise, NOISE_FUNCTION_SIMPLEX, 0.0, 0.0); noiseSetFunctionParams(definition->_height_noise, NOISE_FUNCTION_SIMPLEX, 0.0, 0.0);
definition->scaling = 1.0; definition->scaling = 1.0;
definition->height = 1.0; definition->height = 1.0;

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@ -62,7 +62,7 @@ TextureLayerDefinition* texturesLayerCreateDefinition()
result->zone = zoneCreate(); result->zone = zoneCreate();
result->bump_noise = noiseCreateGenerator(); result->bump_noise = noiseCreateGenerator();
noiseAddLevelsSimple(result->bump_noise, 8, 1.0, -0.5, 0.5); noiseAddLevelsSimple(result->bump_noise, 8, 1.0, -0.5, 0.5, 0.5);
result->bump_height = 0.1; result->bump_height = 0.1;
result->bump_scaling = 0.1; result->bump_scaling = 0.1;
result->material.base = COLOR_WHITE; result->material.base = COLOR_WHITE;

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@ -138,11 +138,11 @@ void waterValidateDefinition(WaterDefinition* definition)
noiseClearLevels(definition->_waves_noise); noiseClearLevels(definition->_waves_noise);
if (definition->waves_height > 0.0) if (definition->waves_height > 0.0)
{ {
noiseAddLevelsSimple(definition->_waves_noise, 2, scaling, -definition->waves_height * scaling * 0.015, definition->waves_height * scaling * 0.015); noiseAddLevelsSimple(definition->_waves_noise, 2, scaling, -definition->waves_height * scaling * 0.015, definition->waves_height * scaling * 0.015, 0.5);
} }
if (definition->detail_height > 0.0) if (definition->detail_height > 0.0)
{ {
noiseAddLevelsSimple(definition->_waves_noise, 3, scaling * 0.1, -definition->detail_height * scaling * 0.015, definition->detail_height * scaling * 0.015); noiseAddLevelsSimple(definition->_waves_noise, 3, scaling * 0.1, -definition->detail_height * scaling * 0.015, definition->detail_height * scaling * 0.015, 0.5);
} }
noiseSetFunctionParams(definition->_waves_noise, NOISE_FUNCTION_SIMPLEX, -definition->turbulence, 0.0); noiseSetFunctionParams(definition->_waves_noise, NOISE_FUNCTION_SIMPLEX, -definition->turbulence, 0.0);
noiseValidate(definition->_waves_noise); noiseValidate(definition->_waves_noise);