/** * @file llpartdata.cpp * @brief Particle system data packing * * $LicenseInfo:firstyear=2003&license=viewergpl$ * * Copyright (c) 2003-2007, Linden Research, Inc. * * Second Life Viewer Source Code * The source code in this file ("Source Code") is provided by Linden Lab * to you under the terms of the GNU General Public License, version 2.0 * ("GPL"), unless you have obtained a separate licensing agreement * ("Other License"), formally executed by you and Linden Lab. Terms of * the GPL can be found in doc/GPL-license.txt in this distribution, or * online at http://secondlife.com/developers/opensource/gplv2 * * There are special exceptions to the terms and conditions of the GPL as * it is applied to this Source Code. View the full text of the exception * in the file doc/FLOSS-exception.txt in this software distribution, or * online at http://secondlife.com/developers/opensource/flossexception * * By copying, modifying or distributing this software, you acknowledge * that you have read and understood your obligations described above, * and agree to abide by those obligations. * * ALL LINDEN LAB SOURCE CODE IS PROVIDED "AS IS." LINDEN LAB MAKES NO * WARRANTIES, EXPRESS, IMPLIED OR OTHERWISE, REGARDING ITS ACCURACY, * COMPLETENESS OR PERFORMANCE. * $/LicenseInfo$ */ #include "linden_common.h" #include "llpartdata.h" #include "message.h" #include "lldatapacker.h" #include "v4coloru.h" #include "llsdutil.h" const S32 PS_PART_DATA_BLOCK_SIZE = 4 + 2 + 4 + 4 + 2 + 2; // 18 const S32 PS_DATA_BLOCK_SIZE = 68 + PS_PART_DATA_BLOCK_SIZE; // 68 + 18 = 86 const F32 MAX_PART_SCALE = 4.f; BOOL LLPartData::pack(LLDataPacker &dp) { LLColor4U coloru; dp.packU32(mFlags, "pdflags"); dp.packFixed(mMaxAge, "pdmaxage", FALSE, 8, 8); coloru.setVec(mStartColor); dp.packColor4U(coloru, "pdstartcolor"); coloru.setVec(mEndColor); dp.packColor4U(coloru, "pdendcolor"); dp.packFixed(mStartScale.mV[0], "pdstartscalex", FALSE, 3, 5); dp.packFixed(mStartScale.mV[1], "pdstartscaley", FALSE, 3, 5); dp.packFixed(mEndScale.mV[0], "pdendscalex", FALSE, 3, 5); dp.packFixed(mEndScale.mV[1], "pdendscaley", FALSE, 3, 5); return TRUE; } LLSD LLPartData::asLLSD() const { LLSD sd = LLSD(); sd["pdflags"] = ll_sd_from_U32(mFlags); sd["pdmaxage"] = mMaxAge; sd["pdstartcolor"] = ll_sd_from_color4(mStartColor); sd["pdendcolor"] = ll_sd_from_color4(mEndColor); sd["pdstartscale"] = ll_sd_from_vector2(mStartScale); sd["pdendscale"] = ll_sd_from_vector2(mEndScale); return sd; } bool LLPartData::fromLLSD(LLSD& sd) { mFlags = ll_U32_from_sd(sd["pdflags"]); mMaxAge = (F32)sd["pdmaxage"].asReal(); mStartColor = ll_color4_from_sd(sd["pdstartcolor"]); mEndColor = ll_color4_from_sd(sd["pdendcolor"]); mStartScale = ll_vector2_from_sd(sd["pdstartscale"]); mEndScale = ll_vector2_from_sd(sd["pdendscale"]); return true; } BOOL LLPartData::unpack(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); 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; } LLPartSysData::LLPartSysData() { mCRC = 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; 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; } BOOL LLPartSysData::pack(LLDataPacker &dp) { dp.packU32(mCRC, "pscrc"); dp.packU32(mFlags, "psflags"); dp.packU8(mPattern, "pspattern"); dp.packFixed(mMaxAge, "psmaxage", FALSE, 8, 8); dp.packFixed(mStartAge, "psstartage", FALSE, 8, 8); dp.packFixed(mInnerAngle, "psinnerangle", FALSE, 3, 5); dp.packFixed(mOuterAngle, "psouterangle", FALSE, 3, 5); dp.packFixed(mBurstRate, "psburstrate", FALSE, 8, 8); dp.packFixed(mBurstRadius, "psburstradius", FALSE, 8, 8); dp.packFixed(mBurstSpeedMin, "psburstspeedmin", FALSE, 8, 8); dp.packFixed(mBurstSpeedMax, "psburstspeedmax", FALSE, 8, 8); dp.packU8(mBurstPartCount, "psburstpartcount"); dp.packFixed(mAngularVelocity.mV[0], "psangvelx", TRUE, 8, 7); dp.packFixed(mAngularVelocity.mV[1], "psangvely", TRUE, 8, 7); dp.packFixed(mAngularVelocity.mV[2], "psangvelz", TRUE, 8, 7); dp.packFixed(mPartAccel.mV[0], "psaccelx", TRUE, 8, 7); dp.packFixed(mPartAccel.mV[1], "psaccely", TRUE, 8, 7); dp.packFixed(mPartAccel.mV[2], "psaccelz", TRUE, 8, 7); dp.packUUID(mPartImageID, "psuuid"); dp.packUUID(mTargetUUID, "pstargetuuid"); mPartData.pack(dp); return TRUE; } BOOL LLPartSysData::unpack(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"); mPartData.unpack(dp); return TRUE; } 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_DATA_BLOCK_SIZE]; U32 crc; S32 size; // Check size of block size = gMessageSystem->getSize("ObjectData", block_num, "PSBlock"); if (!size) { return TRUE; } else if (size != PS_DATA_BLOCK_SIZE) { llwarns << "PSBlock is wrong size for particle system data - got " << size << ", expecting " << PS_DATA_BLOCK_SIZE << llendl; return TRUE; } gMessageSystem->getBinaryData("ObjectData", "PSBlock", ps_data_block, PS_DATA_BLOCK_SIZE, block_num, PS_DATA_BLOCK_SIZE); LLDataPackerBinaryBuffer dp(ps_data_block, PS_DATA_BLOCK_SIZE); dp.unpackU32(crc, "crc"); if (crc == 0) { return TRUE; } return FALSE; } //static BOOL LLPartSysData::packNull() { U8 ps_data_block[PS_DATA_BLOCK_SIZE]; gMessageSystem->addBinaryData("PSBlock", ps_data_block, 0); return TRUE; } BOOL LLPartSysData::packBlock() { U8 ps_data_block[PS_DATA_BLOCK_SIZE]; LLDataPackerBinaryBuffer dp(ps_data_block, PS_DATA_BLOCK_SIZE); pack(dp); // Add to message gMessageSystem->addBinaryData("PSBlock", ps_data_block, PS_DATA_BLOCK_SIZE); return TRUE; } BOOL LLPartSysData::unpackBlock(const S32 block_num) { U8 ps_data_block[PS_DATA_BLOCK_SIZE]; // Check size of block S32 size = gMessageSystem->getSize("ObjectData", block_num, "PSBlock"); if (size != PS_DATA_BLOCK_SIZE) { llwarns << "PSBlock is wrong size for particle system data - got " << size << ", expecting " << PS_DATA_BLOCK_SIZE << llendl; return FALSE; } // Get from message gMessageSystem->getBinaryData("ObjectData", "PSBlock", ps_data_block, PS_DATA_BLOCK_SIZE, block_num, PS_DATA_BLOCK_SIZE); LLDataPackerBinaryBuffer dp(ps_data_block, PS_DATA_BLOCK_SIZE); unpack(dp); return TRUE; } 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); }