/** * @file llcloud.cpp * @brief Implementation of viewer LLCloudLayer class * * $LicenseInfo:firstyear=2001&license=viewergpl$ * * Copyright (c) 2001-2008, 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://secondlifegrid.net/programs/open_source/licensing/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://secondlifegrid.net/programs/open_source/licensing/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 "llviewerprecompiledheaders.h" #include "llmath.h" //#include "vmath.h" #include "v3math.h" #include "v4math.h" #include "llquaternion.h" #include "v4color.h" #include "llwind.h" #include "llcloud.h" #include "llgl.h" #include "llviewerobjectlist.h" #include "llvoclouds.h" #include "llvosky.h" #include "llsky.h" #include "llviewerregion.h" #include "patch_dct.h" #include "patch_code.h" #include "llglheaders.h" #include "pipeline.h" #include "lldrawpool.h" #include "llworld.h" extern LLPipeline gPipeline; const F32 CLOUD_UPDATE_RATE = 1.0f; // Global time dilation for clouds const F32 CLOUD_GROW_RATE = 0.05f; const F32 CLOUD_DECAY_RATE = -0.05f; const F32 CLOUD_VELOCITY_SCALE = 0.01f; const F32 CLOUD_DENSITY = 25.f; const S32 CLOUD_COUNT_MAX = 20; const F32 CLOUD_HEIGHT_RANGE = 48.f; const F32 CLOUD_HEIGHT_MEAN = 192.f; enum { LL_PUFF_GROWING = 0, LL_PUFF_DYING = 1 }; // Used for patch decoder S32 gBuffer[16*16]; //static S32 LLCloudPuff::sPuffCount = 0; LLCloudPuff::LLCloudPuff() : mAlpha(0.01f), mRate(CLOUD_GROW_RATE*CLOUD_UPDATE_RATE), mLifeState(LL_PUFF_GROWING) { } LLCloudGroup::LLCloudGroup() : mCloudLayerp(NULL), mDensity(0.f), mTargetPuffCount(0), mVOCloudsp(NULL) { } void LLCloudGroup::cleanup() { if (mVOCloudsp) { if (!mVOCloudsp->isDead()) { gObjectList.killObject(mVOCloudsp); } mVOCloudsp = NULL; } } void LLCloudGroup::setCenterRegion(const LLVector3 ¢er) { mCenterRegion = center; } void LLCloudGroup::updatePuffs(const F32 dt) { mDensity = mCloudLayerp->getDensityRegion(mCenterRegion); if (!mVOCloudsp) { mVOCloudsp = (LLVOClouds *)gObjectList.createObjectViewer(LLViewerObject::LL_VO_CLOUDS, mCloudLayerp->getRegion()); mVOCloudsp->setCloudGroup(this); mVOCloudsp->setPositionRegion(mCenterRegion); mVOCloudsp->setScale(LLVector3(256.f/CLOUD_GROUPS_PER_EDGE + CLOUD_PUFF_WIDTH, 256.f/CLOUD_GROUPS_PER_EDGE + CLOUD_PUFF_WIDTH, CLOUD_HEIGHT_RANGE + CLOUD_PUFF_HEIGHT)*0.5f); gPipeline.addObject(mVOCloudsp); } LLVector3 velocity; LLVector3d vel_d; // Update the positions of all of the clouds for (U32 i = 0; i < mCloudPuffs.size(); i++) { LLCloudPuff &puff = mCloudPuffs[i]; velocity = mCloudLayerp->getRegion()->mWind.getCloudVelocity(mCloudLayerp->getRegion()->getPosRegionFromGlobal(puff.mPositionGlobal)); velocity *= CLOUD_VELOCITY_SCALE*CLOUD_UPDATE_RATE; vel_d.setVec(velocity); mCloudPuffs[i].mPositionGlobal += vel_d; mCloudPuffs[i].mAlpha += mCloudPuffs[i].mRate * dt; mCloudPuffs[i].mAlpha = llmin(1.f, mCloudPuffs[i].mAlpha); mCloudPuffs[i].mAlpha = llmax(0.f, mCloudPuffs[i].mAlpha); } } void LLCloudGroup::updatePuffOwnership() { U32 i = 0; while (i < mCloudPuffs.size()) { if (mCloudPuffs[i].getLifeState() == LL_PUFF_DYING) { i++; continue; } if (inGroup(mCloudPuffs[i])) { i++; continue; } //llinfos << "Cloud moving to new group" << llendl; LLCloudGroup *new_cgp = LLWorld::getInstance()->findCloudGroup(mCloudPuffs[i]); if (!new_cgp) { //llinfos << "Killing puff not in group" << llendl; mCloudPuffs[i].setLifeState(LL_PUFF_DYING); mCloudPuffs[i].mRate = CLOUD_DECAY_RATE*CLOUD_UPDATE_RATE; i++; continue; } //llinfos << "Puff handed off!" << llendl; LLCloudPuff puff; puff.mPositionGlobal = mCloudPuffs[i].mPositionGlobal; puff.mAlpha = mCloudPuffs[i].mAlpha; mCloudPuffs.erase(mCloudPuffs.begin() + i); new_cgp->mCloudPuffs.push_back(puff); } //llinfos << "Puff count: " << LLCloudPuff::sPuffCount << llendl; } void LLCloudGroup::updatePuffCount() { if (!mVOCloudsp) { return; } S32 i; S32 target_puff_count = llround(CLOUD_DENSITY * mDensity); target_puff_count = llmax(0, target_puff_count); target_puff_count = llmin(CLOUD_COUNT_MAX, target_puff_count); S32 current_puff_count = (S32) mCloudPuffs.size(); // Create a new cloud if we need one if (current_puff_count < target_puff_count) { LLVector3d puff_pos_global; mCloudPuffs.resize(target_puff_count); for (i = current_puff_count; i < target_puff_count; i++) { puff_pos_global = mVOCloudsp->getPositionGlobal(); F32 x = ll_frand(256.f/CLOUD_GROUPS_PER_EDGE) - 128.f/CLOUD_GROUPS_PER_EDGE; F32 y = ll_frand(256.f/CLOUD_GROUPS_PER_EDGE) - 128.f/CLOUD_GROUPS_PER_EDGE; F32 z = ll_frand(CLOUD_HEIGHT_RANGE) - 0.5f*CLOUD_HEIGHT_RANGE; puff_pos_global += LLVector3d(x, y, z); mCloudPuffs[i].mPositionGlobal = puff_pos_global; mCloudPuffs[i].mAlpha = 0.01f; LLCloudPuff::sPuffCount++; } } // Count the number of live puffs S32 live_puff_count = 0; for (i = 0; i < (S32) mCloudPuffs.size(); i++) { if (mCloudPuffs[i].getLifeState() != LL_PUFF_DYING) { live_puff_count++; } } // Start killing enough puffs so the live puff count == target puff count S32 new_dying_count = llmax(0, live_puff_count - target_puff_count); i = 0; while (new_dying_count > 0) { if (mCloudPuffs[i].getLifeState() != LL_PUFF_DYING) { //llinfos << "Killing extra live cloud" << llendl; mCloudPuffs[i].setLifeState(LL_PUFF_DYING); mCloudPuffs[i].mRate = CLOUD_DECAY_RATE*CLOUD_UPDATE_RATE; new_dying_count--; } i++; } // Remove fully dead puffs i = 0; while (i < (S32) mCloudPuffs.size()) { if (mCloudPuffs[i].isDead()) { //llinfos << "Removing dead puff!" << llendl; mCloudPuffs.erase(mCloudPuffs.begin() + i); LLCloudPuff::sPuffCount--; } else { i++; } } } BOOL LLCloudGroup::inGroup(const LLCloudPuff &puff) const { // Do min/max check on center of the cloud puff F32 min_x, min_y, max_x, max_y; F32 delta = 128.f/CLOUD_GROUPS_PER_EDGE; min_x = mCenterRegion.mV[VX] - delta; min_y = mCenterRegion.mV[VY] - delta; max_x = mCenterRegion.mV[VX] + delta; max_y = mCenterRegion.mV[VY] + delta; LLVector3 pos_region = mCloudLayerp->getRegion()->getPosRegionFromGlobal(puff.getPositionGlobal()); if ((pos_region.mV[VX] < min_x) || (pos_region.mV[VY] < min_y) || (pos_region.mV[VX] > max_x) || (pos_region.mV[VY] > max_y)) { return FALSE; } return TRUE; } LLCloudLayer::LLCloudLayer() : mOriginGlobal(0.0f, 0.0f, 0.0f), mMetersPerEdge(1.0f), mMetersPerGrid(1.0f), mWindp(NULL), mDensityp(NULL) { S32 i, j; for (i = 0; i < 4; i++) { mNeighbors[i] = NULL; } F32 x, y; for (i = 0; i < CLOUD_GROUPS_PER_EDGE; i++) { y = (0.5f + i)*(256.f/CLOUD_GROUPS_PER_EDGE); for (j = 0; j < CLOUD_GROUPS_PER_EDGE; j++) { x = (0.5f + j)*(256.f/CLOUD_GROUPS_PER_EDGE); mCloudGroups[i][j].setCloudLayerp(this); mCloudGroups[i][j].setCenterRegion(LLVector3(x, y, CLOUD_HEIGHT_MEAN)); } } } LLCloudLayer::~LLCloudLayer() { destroy(); } void LLCloudLayer::create(LLViewerRegion *regionp) { llassert(regionp); mRegionp = regionp; mDensityp = new F32 [CLOUD_GRIDS_PER_EDGE * CLOUD_GRIDS_PER_EDGE]; U32 i; for (i = 0; i < CLOUD_GRIDS_PER_EDGE*CLOUD_GRIDS_PER_EDGE; i++) { mDensityp[i] = 0.f; } } void LLCloudLayer::setRegion(LLViewerRegion *regionp) { mRegionp = regionp; } void LLCloudLayer::destroy() { // Kill all of the existing puffs S32 i, j; for (i = 0; i < CLOUD_GROUPS_PER_EDGE; i++) { for (j = 0; j < CLOUD_GROUPS_PER_EDGE; j++) { mCloudGroups[i][j].cleanup(); } } delete [] mDensityp; mDensityp = NULL; mWindp = NULL; } void LLCloudLayer::reset() { } void LLCloudLayer::setWindPointer(LLWind *windp) { if (mWindp) { mWindp->setCloudDensityPointer(NULL); } mWindp = windp; if (mWindp) { mWindp->setCloudDensityPointer(mDensityp); } } void LLCloudLayer::setWidth(F32 width) { mMetersPerEdge = width; mMetersPerGrid = width / CLOUD_GRIDS_PER_EDGE; } F32 LLCloudLayer::getDensityRegion(const LLVector3 &pos_region) { // "position" is region-local S32 i, j, ii, jj; i = lltrunc(pos_region.mV[VX] / mMetersPerGrid); j = lltrunc(pos_region.mV[VY] / mMetersPerGrid); ii = i + 1; jj = j + 1; // clamp if (i >= (S32)CLOUD_GRIDS_PER_EDGE) { i = CLOUD_GRIDS_PER_EDGE - 1; ii = i; } else if (i < 0) { i = 0; ii = i; } else if (ii >= (S32)CLOUD_GRIDS_PER_EDGE || ii < 0) { ii = i; } if (j >= (S32)CLOUD_GRIDS_PER_EDGE) { j = CLOUD_GRIDS_PER_EDGE - 1; jj = j; } else if (j < 0) { j = 0; jj = j; } else if (jj >= (S32)CLOUD_GRIDS_PER_EDGE || jj < 0) { jj = j; } F32 dx = (pos_region.mV[VX] - (F32) i * mMetersPerGrid) / mMetersPerGrid; F32 dy = (pos_region.mV[VY] - (F32) j * mMetersPerGrid) / mMetersPerGrid; F32 omdx = 1.0f - dx; F32 omdy = 1.0f - dy; F32 density = dx * dy * *(mDensityp + ii + jj * CLOUD_GRIDS_PER_EDGE) + dx * omdy * *(mDensityp + i + jj * CLOUD_GRIDS_PER_EDGE) + omdx * dy * *(mDensityp + ii + j * CLOUD_GRIDS_PER_EDGE) + omdx * omdy * *(mDensityp + i + j * CLOUD_GRIDS_PER_EDGE); return density; } void LLCloudLayer::decompress(LLBitPack &bitpack, LLGroupHeader *group_headerp) { LLPatchHeader patch_header; init_patch_decompressor(group_headerp->patch_size); // Don't use the packed group_header stride because the strides used on // simulator and viewer are not equal. group_headerp->stride = group_headerp->patch_size; // offset required to step up one row set_group_of_patch_header(group_headerp); decode_patch_header(bitpack, &patch_header); decode_patch(bitpack, gBuffer); decompress_patch(mDensityp, gBuffer, &patch_header); } void LLCloudLayer::updatePuffs(const F32 dt) { // We want to iterate through all of the cloud groups // and update their density targets S32 i, j; for (i = 0; i < CLOUD_GROUPS_PER_EDGE; i++) { for (j = 0; j < CLOUD_GROUPS_PER_EDGE; j++) { mCloudGroups[i][j].updatePuffs(dt); } } } void LLCloudLayer::updatePuffOwnership() { S32 i, j; for (i = 0; i < CLOUD_GROUPS_PER_EDGE; i++) { for (j = 0; j < CLOUD_GROUPS_PER_EDGE; j++) { mCloudGroups[i][j].updatePuffOwnership(); } } } void LLCloudLayer::updatePuffCount() { S32 i, j; for (i = 0; i < CLOUD_GROUPS_PER_EDGE; i++) { for (j = 0; j < CLOUD_GROUPS_PER_EDGE; j++) { mCloudGroups[i][j].updatePuffCount(); } } } LLCloudGroup *LLCloudLayer::findCloudGroup(const LLCloudPuff &puff) { S32 i, j; for (i = 0; i < CLOUD_GROUPS_PER_EDGE; i++) { for (j = 0; j < CLOUD_GROUPS_PER_EDGE; j++) { if (mCloudGroups[i][j].inGroup(puff)) { return &(mCloudGroups[i][j]); } } } return NULL; } void LLCloudLayer::connectNeighbor(LLCloudLayer *cloudp, U32 direction) { if (direction >= 4) { // Only care about cardinal 4 directions. return; } mNeighbors[direction] = cloudp; if (cloudp) mNeighbors[direction]->mNeighbors[gDirOpposite[direction]] = this; } void LLCloudLayer::disconnectNeighbor(U32 direction) { if (direction >= 4) { // Only care about cardinal 4 directions. return; } if (mNeighbors[direction]) { mNeighbors[direction]->mNeighbors[gDirOpposite[direction]] = NULL; mNeighbors[direction] = NULL; } } void LLCloudLayer::disconnectAllNeighbors() { S32 i; for (i = 0; i < 4; i++) { disconnectNeighbor(i); } }