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/**
* @file llwlparamset.cpp
* @brief Implementation for the LLWLParamSet class.
*
* $LicenseInfo:firstyear=2005&license=viewerlgpl$
* Second Life Viewer Source Code
* Copyright (C) 2010, Linden Research, Inc.
*
* This library 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;
* version 2.1 of the License only.
*
* This library 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 library; if not, write to the Free Software
* Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
*
* Linden Research, Inc., 945 Battery Street, San Francisco, CA 94111 USA
* $/LicenseInfo$
*/
#include "llviewerprecompiledheaders.h"
#include "llwlparamset.h"
#include "llwlanimator.h"
#include "llwlparammanager.h"
#include "llglslshader.h"
#include "lluictrlfactory.h"
#include "llsliderctrl.h"
#include "pipeline.h"
#include <llgl.h>
#include <sstream>
LLWLParamSet::LLWLParamSet(void) :
mName("Unnamed Preset"),
mCloudScrollXOffset(0.f), mCloudScrollYOffset(0.f)
{}
static LLTrace::TimeBlock FTM_WL_PARAM_UPDATE("WL Param Update");
void LLWLParamSet::update(LLGLSLShader * shader) const
{
LL_RECORD_BLOCK_TIME(FTM_WL_PARAM_UPDATE);
for(LLSD::map_const_iterator i = mParamValues.beginMap();
i != mParamValues.endMap();
++i)
{
const std::string& param = i->first;
if (param == "star_brightness" || param == "preset_num" || param == "sun_angle" ||
param == "east_angle" || param == "enable_cloud_scroll" ||
param == "cloud_scroll_rate" || param == "lightnorm" )
{
continue;
}
if (param == "cloud_pos_density1")
{
LLVector4 val;
val.mV[0] = F32(i->second[0].asReal()) + mCloudScrollXOffset;
val.mV[1] = F32(i->second[1].asReal()) + mCloudScrollYOffset;
val.mV[2] = (F32) i->second[2].asReal();
val.mV[3] = (F32) i->second[3].asReal();
stop_glerror();
shader->uniform4fv(param, 1, val.mV);
stop_glerror();
}
else if (param == "cloud_scale" || param == "cloud_shadow" ||
param == "density_multiplier" || param == "distance_multiplier" ||
param == "haze_density" || param == "haze_horizon" ||
param == "max_y" )
{
F32 val = (F32) i->second[0].asReal();
stop_glerror();
shader->uniform1f(param, val);
stop_glerror();
}
else // param is the uniform name
{
// handle all the different cases
if (i->second.isArray() && i->second.size() == 4)
{
LLVector4 val;
val.mV[0] = (F32) i->second[0].asReal();
val.mV[1] = (F32) i->second[1].asReal();
val.mV[2] = (F32) i->second[2].asReal();
val.mV[3] = (F32) i->second[3].asReal();
stop_glerror();
shader->uniform4fv(param, 1, val.mV);
stop_glerror();
}
else if (i->second.isReal())
{
F32 val = (F32) i->second.asReal();
stop_glerror();
shader->uniform1f(param, val);
stop_glerror();
}
else if (i->second.isInteger())
{
S32 val = (S32) i->second.asInteger();
stop_glerror();
shader->uniform1i(param, val);
stop_glerror();
}
else if (i->second.isBoolean())
{
S32 val = (i->second.asBoolean() ? 1 : 0);
stop_glerror();
shader->uniform1i(param, val);
stop_glerror();
}
}
}
if (LLPipeline::sRenderDeferred && !LLPipeline::sReflectionRender && !LLPipeline::sUnderWaterRender)
{
shader->uniform1f(LLShaderMgr::GLOBAL_GAMMA, 2.2);
} else {
shader->uniform1f(LLShaderMgr::GLOBAL_GAMMA, 1.0);
}
}
void LLWLParamSet::set(const std::string& paramName, float x)
{
// handle case where no array
if(mParamValues[paramName].isReal())
{
mParamValues[paramName] = x;
}
// handle array
else if(mParamValues[paramName].isArray() &&
mParamValues[paramName][0].isReal())
{
mParamValues[paramName][0] = x;
}
}
void LLWLParamSet::set(const std::string& paramName, float x, float y)
{
mParamValues[paramName][0] = x;
mParamValues[paramName][1] = y;
}
void LLWLParamSet::set(const std::string& paramName, float x, float y, float z)
{
mParamValues[paramName][0] = x;
mParamValues[paramName][1] = y;
mParamValues[paramName][2] = z;
}
void LLWLParamSet::set(const std::string& paramName, float x, float y, float z, float w)
{
mParamValues[paramName][0] = x;
mParamValues[paramName][1] = y;
mParamValues[paramName][2] = z;
mParamValues[paramName][3] = w;
}
void LLWLParamSet::set(const std::string& paramName, const float * val)
{
mParamValues[paramName][0] = val[0];
mParamValues[paramName][1] = val[1];
mParamValues[paramName][2] = val[2];
mParamValues[paramName][3] = val[3];
}
void LLWLParamSet::set(const std::string& paramName, const LLVector4 & val)
{
mParamValues[paramName][0] = val.mV[0];
mParamValues[paramName][1] = val.mV[1];
mParamValues[paramName][2] = val.mV[2];
mParamValues[paramName][3] = val.mV[3];
}
void LLWLParamSet::set(const std::string& paramName, const LLColor4 & val)
{
mParamValues[paramName][0] = val.mV[0];
mParamValues[paramName][1] = val.mV[1];
mParamValues[paramName][2] = val.mV[2];
mParamValues[paramName][3] = val.mV[3];
}
LLVector4 LLWLParamSet::getVector(const std::string& paramName, bool& error)
{
// test to see if right type
LLSD cur_val = mParamValues.get(paramName);
if (!cur_val.isArray())
{
error = true;
return LLVector4(0,0,0,0);
}
LLVector4 val;
val.mV[0] = (F32) cur_val[0].asReal();
val.mV[1] = (F32) cur_val[1].asReal();
val.mV[2] = (F32) cur_val[2].asReal();
val.mV[3] = (F32) cur_val[3].asReal();
error = false;
return val;
}
F32 LLWLParamSet::getFloat(const std::string& paramName, bool& error)
{
// test to see if right type
LLSD cur_val = mParamValues.get(paramName);
if (cur_val.isArray() && cur_val.size() != 0)
{
error = false;
return (F32) cur_val[0].asReal();
}
if(cur_val.isReal())
{
error = false;
return (F32) cur_val.asReal();
}
error = true;
return 0;
}
void LLWLParamSet::setSunAngle(float val)
{
// keep range 0 - 2pi
if(val > F_TWO_PI || val < 0)
{
F32 num = val / F_TWO_PI;
num -= floor(num);
val = F_TWO_PI * num;
}
mParamValues["sun_angle"] = val;
}
void LLWLParamSet::setEastAngle(float val)
{
// keep range 0 - 2pi
if(val > F_TWO_PI || val < 0)
{
F32 num = val / F_TWO_PI;
num -= floor(num);
val = F_TWO_PI * num;
}
mParamValues["east_angle"] = val;
}
void LLWLParamSet::mix(LLWLParamSet& src, LLWLParamSet& dest, F32 weight)
{
// set up the iterators
// keep cloud positions and coverage the same
/// TODO masking will do this later
F32 cloudPos1X = (F32) mParamValues["cloud_pos_density1"][0].asReal();
F32 cloudPos1Y = (F32) mParamValues["cloud_pos_density1"][1].asReal();
F32 cloudPos2X = (F32) mParamValues["cloud_pos_density2"][0].asReal();
F32 cloudPos2Y = (F32) mParamValues["cloud_pos_density2"][1].asReal();
F32 cloudCover = (F32) mParamValues["cloud_shadow"][0].asReal();
LLSD srcVal;
LLSD destVal;
// Iterate through values
for(LLSD::map_iterator iter = mParamValues.beginMap(); iter != mParamValues.endMap(); ++iter)
{
// If param exists in both src and dest, set the holder variables, otherwise skip
if(src.mParamValues.has(iter->first) && dest.mParamValues.has(iter->first))
{
srcVal = src.mParamValues[iter->first];
destVal = dest.mParamValues[iter->first];
}
else
{
continue;
}
if(iter->second.isReal()) // If it's a real, interpolate directly
{
iter->second = srcVal.asReal() + ((destVal.asReal() - srcVal.asReal()) * weight);
}
else if(iter->second.isArray() && iter->second[0].isReal() // If it's an array of reals, loop through the reals and interpolate on those
&& iter->second.size() == srcVal.size() && iter->second.size() == destVal.size())
{
// Actually do interpolation: old value + (difference in values * factor)
for(int i=0; i < iter->second.size(); ++i)
{
// iter->second[i] = (1.f-weight)*(F32)srcVal[i].asReal() + weight*(F32)destVal[i].asReal(); // old way of doing it -- equivalent but one more operation
iter->second[i] = srcVal[i].asReal() + ((destVal[i].asReal() - srcVal[i].asReal()) * weight);
}
}
else // Else, skip
{
continue;
}
}
// now mix the extra parameters
setStarBrightness((1 - weight) * (F32) src.getStarBrightness()
+ weight * (F32) dest.getStarBrightness());
llassert(src.getSunAngle() >= - F_PI &&
src.getSunAngle() <= 3 * F_PI);
llassert(dest.getSunAngle() >= - F_PI &&
dest.getSunAngle() <= 3 * F_PI);
llassert(src.getEastAngle() >= 0 &&
src.getEastAngle() <= 4 * F_PI);
llassert(dest.getEastAngle() >= 0 &&
dest.getEastAngle() <= 4 * F_PI);
// sun angle and east angle require some handling to make sure
// they go in circles. Yes quaternions would work better.
F32 srcSunAngle = src.getSunAngle();
F32 destSunAngle = dest.getSunAngle();
F32 srcEastAngle = src.getEastAngle();
F32 destEastAngle = dest.getEastAngle();
if(fabsf(srcSunAngle - destSunAngle) > F_PI)
{
if(srcSunAngle > destSunAngle)
{
destSunAngle += 2 * F_PI;
}
else
{
srcSunAngle += 2 * F_PI;
}
}
if(fabsf(srcEastAngle - destEastAngle) > F_PI)
{
if(srcEastAngle > destEastAngle)
{
destEastAngle += 2 * F_PI;
}
else
{
srcEastAngle += 2 * F_PI;
}
}
setSunAngle((1 - weight) * srcSunAngle + weight * destSunAngle);
setEastAngle((1 - weight) * srcEastAngle + weight * destEastAngle);
// now setup the sun properly
// reset those cloud positions
mParamValues["cloud_pos_density1"][0] = cloudPos1X;
mParamValues["cloud_pos_density1"][1] = cloudPos1Y;
mParamValues["cloud_pos_density2"][0] = cloudPos2X;
mParamValues["cloud_pos_density2"][1] = cloudPos2Y;
mParamValues["cloud_shadow"][0] = cloudCover;
}
void LLWLParamSet::updateCloudScrolling(void)
{
static LLTimer s_cloud_timer;
F64 delta_t = s_cloud_timer.getElapsedTimeAndResetF64();
if(getEnableCloudScrollX())
{
mCloudScrollXOffset += F32(delta_t * (getCloudScrollX() - 10.f) / 100.f);
}
if(getEnableCloudScrollY())
{
mCloudScrollYOffset += F32(delta_t * (getCloudScrollY() - 10.f) / 100.f);
}
}
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