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/**
* @file llpartdata.cpp
* @brief Particle system data packing
*
* $LicenseInfo:firstyear=2003&license=viewerlgpl$
* 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 "linden_common.h"
#include "llpartdata.h"
#include "message.h"
#include "lldatapacker.h"
#include "v4coloru.h"
#include "llsdutil.h"
#include "llsdutil_math.h"
const S32 PS_PART_DATA_GLOW_SIZE = 2;
const S32 PS_PART_DATA_BLEND_SIZE = 2;
const S32 PS_LEGACY_PART_DATA_BLOCK_SIZE = 4 + 2 + 4 + 4 + 2 + 2; //18
const S32 PS_SYS_DATA_BLOCK_SIZE = 68;
const S32 PS_MAX_DATA_BLOCK_SIZE = PS_SYS_DATA_BLOCK_SIZE+
PS_LEGACY_PART_DATA_BLOCK_SIZE +
PS_PART_DATA_BLEND_SIZE +
PS_PART_DATA_GLOW_SIZE+
8; //two S32 size fields
const S32 PS_LEGACY_DATA_BLOCK_SIZE = PS_SYS_DATA_BLOCK_SIZE + PS_LEGACY_PART_DATA_BLOCK_SIZE;
const F32 MAX_PART_SCALE = 4.f;
bool LLPartData::hasGlow() const
{
return mStartGlow > 0.f || mEndGlow > 0.f;
}
bool LLPartData::hasBlendFunc() const
{
return mBlendFuncSource != LLPartData::LL_PART_BF_SOURCE_ALPHA || mBlendFuncDest != LLPartData::LL_PART_BF_ONE_MINUS_SOURCE_ALPHA;
}
S32 LLPartData::getSize() const
{
S32 size = PS_LEGACY_PART_DATA_BLOCK_SIZE;
if (hasGlow()) size += PS_PART_DATA_GLOW_SIZE;
if (hasBlendFunc()) size += PS_PART_DATA_BLEND_SIZE;
return size;
}
BOOL LLPartData::unpackLegacy(LLDataPacker &dp)
{
LLColor4U coloru;
dp.unpackU32(mFlags, "pdflags");
dp.unpackFixed(mMaxAge, "pdmaxage", FALSE, 8, 8);
dp.unpackColor4U(coloru, "pdstartcolor");
mStartColor.setVec(coloru);
dp.unpackColor4U(coloru, "pdendcolor");
mEndColor.setVec(coloru);
dp.unpackFixed(mStartScale.mV[0], "pdstartscalex", FALSE, 3, 5);
dp.unpackFixed(mStartScale.mV[1], "pdstartscaley", FALSE, 3, 5);
dp.unpackFixed(mEndScale.mV[0], "pdendscalex", FALSE, 3, 5);
dp.unpackFixed(mEndScale.mV[1], "pdendscaley", FALSE, 3, 5);
mStartGlow = 0.f;
mEndGlow = 0.f;
mBlendFuncSource = LLPartData::LL_PART_BF_SOURCE_ALPHA;
mBlendFuncDest = LLPartData::LL_PART_BF_ONE_MINUS_SOURCE_ALPHA;
return TRUE;
}
BOOL LLPartData::unpack(LLDataPacker &dp)
{
S32 size = 0;
dp.unpackS32(size, "partsize");
unpackLegacy(dp);
size -= PS_LEGACY_PART_DATA_BLOCK_SIZE;
if (mFlags & LL_PART_DATA_GLOW)
{
if (size < PS_PART_DATA_GLOW_SIZE) return FALSE;
U8 tmp_glow = 0;
dp.unpackU8(tmp_glow,"pdstartglow");
mStartGlow = tmp_glow / 255.f;
dp.unpackU8(tmp_glow,"pdendglow");
mEndGlow = tmp_glow / 255.f;
size -= PS_PART_DATA_GLOW_SIZE;
}
else
{
mStartGlow = 0.f;
mEndGlow = 0.f;
}
if (mFlags & LL_PART_DATA_BLEND)
{
if (size < PS_PART_DATA_BLEND_SIZE) return FALSE;
dp.unpackU8(mBlendFuncSource,"pdblendsource");
dp.unpackU8(mBlendFuncDest,"pdblenddest");
size -= PS_PART_DATA_BLEND_SIZE;
}
else
{
mBlendFuncSource = LLPartData::LL_PART_BF_SOURCE_ALPHA;
mBlendFuncDest = LLPartData::LL_PART_BF_ONE_MINUS_SOURCE_ALPHA;
}
if (size > 0)
{ //leftover bytes, unrecognized parameters
U8 feh = 0;
while (size > 0)
{ //read remaining bytes in block
dp.unpackU8(feh, "whippang");
size--;
}
//this particle system won't display properly, better to not show anything
return FALSE;
}
return TRUE;
}
void LLPartData::setFlags(const U32 flags)
{
mFlags = flags;
}
void LLPartData::setMaxAge(const F32 max_age)
{
mMaxAge = llclamp(max_age, 0.f, 30.f);
}
void LLPartData::setStartScale(const F32 xs, const F32 ys)
{
mStartScale.mV[VX] = llmin(xs, MAX_PART_SCALE);
mStartScale.mV[VY] = llmin(ys, MAX_PART_SCALE);
}
void LLPartData::setEndScale(const F32 xs, const F32 ys)
{
mEndScale.mV[VX] = llmin(xs, MAX_PART_SCALE);
mEndScale.mV[VY] = llmin(ys, MAX_PART_SCALE);
}
void LLPartData::setStartColor(const LLVector3 &rgb)
{
mStartColor.setVec(rgb.mV[0], rgb.mV[1], rgb.mV[2]);
}
void LLPartData::setEndColor(const LLVector3 &rgb)
{
mEndColor.setVec(rgb.mV[0], rgb.mV[1], rgb.mV[2]);
}
void LLPartData::setStartAlpha(const F32 alpha)
{
mStartColor.mV[3] = alpha;
}
void LLPartData::setEndAlpha(const F32 alpha)
{
mEndColor.mV[3] = alpha;
}
// static
bool LLPartData::validBlendFunc(S32 func)
{
if (func >= 0
&& func < LL_PART_BF_COUNT
&& func != UNSUPPORTED_DEST_ALPHA
&& func != UNSUPPORTED_ONE_MINUS_DEST_ALPHA)
{
return true;
}
return false;
}
LLPartSysData::LLPartSysData()
{
mCRC = 0;
mFlags = 0;
mPartData.mFlags = 0;
mPartData.mStartColor = LLColor4(1.f, 1.f, 1.f, 1.f);
mPartData.mEndColor = LLColor4(1.f, 1.f, 1.f, 1.f);
mPartData.mStartScale = LLVector2(1.f, 1.f);
mPartData.mEndScale = LLVector2(1.f, 1.f);
mPartData.mMaxAge = 10.0;
mPartData.mBlendFuncSource = LLPartData::LL_PART_BF_SOURCE_ALPHA;
mPartData.mBlendFuncDest = LLPartData::LL_PART_BF_ONE_MINUS_SOURCE_ALPHA;
mPartData.mStartGlow = 0.f;
mPartData.mEndGlow = 0.f;
mMaxAge = 0.0;
mStartAge = 0.0;
mPattern = LL_PART_SRC_PATTERN_DROP; // Pattern for particle velocity
mInnerAngle = 0.0; // Inner angle of PATTERN_ANGLE_*
mOuterAngle = 0.0; // Outer angle of PATTERN_ANGLE_*
mBurstRate = 0.1f; // How often to do a burst of particles
mBurstPartCount = 1; // How many particles in a burst
mBurstSpeedMin = 1.f; // Minimum particle velocity
mBurstSpeedMax = 1.f; // Maximum particle velocity
mBurstRadius = 0.f;
mNumParticles = 0;
}
BOOL LLPartSysData::unpackSystem(LLDataPacker &dp)
{
dp.unpackU32(mCRC, "pscrc");
dp.unpackU32(mFlags, "psflags");
dp.unpackU8(mPattern, "pspattern");
dp.unpackFixed(mMaxAge, "psmaxage", FALSE, 8, 8);
dp.unpackFixed(mStartAge, "psstartage", FALSE, 8, 8);
dp.unpackFixed(mInnerAngle, "psinnerangle", FALSE, 3, 5);
dp.unpackFixed(mOuterAngle, "psouterangle", FALSE, 3, 5);
dp.unpackFixed(mBurstRate, "psburstrate", FALSE, 8, 8);
mBurstRate = llmax(0.01f, mBurstRate);
dp.unpackFixed(mBurstRadius, "psburstradius", FALSE, 8, 8);
dp.unpackFixed(mBurstSpeedMin, "psburstspeedmin", FALSE, 8, 8);
dp.unpackFixed(mBurstSpeedMax, "psburstspeedmax", FALSE, 8, 8);
dp.unpackU8(mBurstPartCount, "psburstpartcount");
dp.unpackFixed(mAngularVelocity.mV[0], "psangvelx", TRUE, 8, 7);
dp.unpackFixed(mAngularVelocity.mV[1], "psangvely", TRUE, 8, 7);
dp.unpackFixed(mAngularVelocity.mV[2], "psangvelz", TRUE, 8, 7);
dp.unpackFixed(mPartAccel.mV[0], "psaccelx", TRUE, 8, 7);
dp.unpackFixed(mPartAccel.mV[1], "psaccely", TRUE, 8, 7);
dp.unpackFixed(mPartAccel.mV[2], "psaccelz", TRUE, 8, 7);
dp.unpackUUID(mPartImageID, "psuuid");
dp.unpackUUID(mTargetUUID, "pstargetuuid");
return TRUE;
}
BOOL LLPartSysData::unpackLegacy(LLDataPacker &dp)
{
unpackSystem(dp);
mPartData.unpackLegacy(dp);
return TRUE;
}
BOOL LLPartSysData::unpack(LLDataPacker &dp)
{
// syssize is currently unused. Adding now when modifying the 'version to make extensible in the future
S32 size = 0;
dp.unpackS32(size, "syssize");
if (size != PS_SYS_DATA_BLOCK_SIZE)
{ //unexpected size, this viewer doesn't know how to parse this particle system
//skip to LLPartData block
U8 feh = 0;
for (U32 i = 0; i < size; ++i)
{
dp.unpackU8(feh, "whippang");
}
dp.unpackS32(size, "partsize");
//skip LLPartData block
for (U32 i = 0; i < size; ++i)
{
dp.unpackU8(feh, "whippang");
}
return FALSE;
}
unpackSystem(dp);
return mPartData.unpack(dp);
}
std::ostream& operator<<(std::ostream& s, const LLPartSysData &data)
{
s << "Flags: " << std::hex << data.mFlags;
s << " Pattern: " << std::hex << (U32) data.mPattern << "\n";
s << "Age: [" << data.mStartAge << ", " << data.mMaxAge << "]\n";
s << "Angle: [" << data.mInnerAngle << ", " << data.mOuterAngle << "]\n";
s << "Burst Rate: " << data.mBurstRate << "\n";
s << "Burst Radius: " << data.mBurstRadius << "\n";
s << "Burst Speed: [" << data.mBurstSpeedMin << ", " << data.mBurstSpeedMax << "]\n";
s << "Burst Part Count: " << std::hex << (U32) data.mBurstPartCount << "\n";
s << "Angular Velocity: " << data.mAngularVelocity << "\n";
s << "Accel: " << data.mPartAccel;
return s;
}
BOOL LLPartSysData::isNullPS(const S32 block_num)
{
U8 ps_data_block[PS_MAX_DATA_BLOCK_SIZE];
U32 crc;
S32 size;
// Check size of block
size = gMessageSystem->getSize("ObjectData", block_num, "PSBlock");
if (!size)
{
return TRUE;
}
if (size > PS_MAX_DATA_BLOCK_SIZE)
{
//size is too big, newer particle version unsupported
return TRUE;
}
gMessageSystem->getBinaryData("ObjectData", "PSBlock", ps_data_block, size, block_num, PS_MAX_DATA_BLOCK_SIZE);
LLDataPackerBinaryBuffer dp(ps_data_block, size);
if (size > PS_LEGACY_DATA_BLOCK_SIZE)
{
// non legacy systems pack a size before the CRC
S32 tmp = 0;
dp.unpackS32(tmp, "syssize");
if (tmp > PS_SYS_DATA_BLOCK_SIZE)
{ //unknown system data block size, don't know how to parse it, treat as NULL
return TRUE;
}
}
dp.unpackU32(crc, "crc");
if (crc == 0)
{
return TRUE;
}
return FALSE;
}
BOOL LLPartSysData::unpackBlock(const S32 block_num)
{
U8 ps_data_block[PS_MAX_DATA_BLOCK_SIZE];
// Check size of block
S32 size = gMessageSystem->getSize("ObjectData", block_num, "PSBlock");
if (size > PS_MAX_DATA_BLOCK_SIZE)
{
// Larger packets are newer and unsupported
return FALSE;
}
// Get from message
gMessageSystem->getBinaryData("ObjectData", "PSBlock", ps_data_block, size, block_num, PS_MAX_DATA_BLOCK_SIZE);
LLDataPackerBinaryBuffer dp(ps_data_block, size);
if (size == PS_LEGACY_DATA_BLOCK_SIZE)
{
return unpackLegacy(dp);
}
else
{
return unpack(dp);
}
}
bool LLPartSysData::isLegacyCompatible() const
{
return !mPartData.hasGlow() && !mPartData.hasBlendFunc();
}
void LLPartSysData::clampSourceParticleRate()
{
F32 particle_rate = 0;
particle_rate = mBurstPartCount/mBurstRate;
if (particle_rate > 256.f)
{
mBurstPartCount = llfloor(((F32)mBurstPartCount)*(256.f/particle_rate));
}
}
void LLPartSysData::setPartAccel(const LLVector3 &accel)
{
mPartAccel.mV[VX] = llclamp(accel.mV[VX], -100.f, 100.f);
mPartAccel.mV[VY] = llclamp(accel.mV[VY], -100.f, 100.f);
mPartAccel.mV[VZ] = llclamp(accel.mV[VZ], -100.f, 100.f);
}
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