/** * @file llpolymorph.cpp * @brief Implementation of LLPolyMesh class * * $LicenseInfo:firstyear=2001&license=viewerlgpl$ * 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 * $/LicenseInfo$ */ //----------------------------------------------------------------------------- // Header Files //----------------------------------------------------------------------------- #include "llpolymorph.h" #include "llavatarappearance.h" #include "llavatarjoint.h" #include "llwearable.h" #include "llxmltree.h" #include "llendianswizzle.h" #include "llpolymesh.h" #include "llfasttimer.h" //#include "../tools/imdebug/imdebug.h" const F32 NORMAL_SOFTEN_FACTOR = 0.65f; //----------------------------------------------------------------------------- // LLPolyMorphData() //----------------------------------------------------------------------------- LLPolyMorphData::LLPolyMorphData(const std::string& morph_name) : mName(morph_name) { mNumIndices = 0; mCurrentIndex = 0; mTotalDistortion = 0.f; mAvgDistortion.clear(); mMaxDistortion = 0.f; mVertexIndices = NULL; mCoords = NULL; mNormals = NULL; mBinormals = NULL; mTexCoords = NULL; mMesh = NULL; } LLPolyMorphData::LLPolyMorphData(const LLPolyMorphData &rhs) : mName(rhs.mName), mNumIndices(rhs.mNumIndices), mTotalDistortion(rhs.mTotalDistortion), mAvgDistortion(rhs.mAvgDistortion), mMaxDistortion(rhs.mMaxDistortion), mVertexIndices(NULL), mCoords(NULL), mNormals(NULL), mBinormals(NULL), mTexCoords(NULL) { const S32 numVertices = mNumIndices; U32 size = sizeof(LLVector4a)*numVertices; mCoords = static_cast( ll_aligned_malloc_16(size) ); mNormals = static_cast( ll_aligned_malloc_16(size) ); mBinormals = static_cast( ll_aligned_malloc_16(size) ); mTexCoords = new LLVector2[numVertices]; mVertexIndices = new U32[numVertices]; for (S32 v=0; v < numVertices; v++) { mCoords[v] = rhs.mCoords[v]; mNormals[v] = rhs.mNormals[v]; mBinormals[v] = rhs.mBinormals[v]; mTexCoords[v] = rhs.mTexCoords[v]; mVertexIndices[v] = rhs.mVertexIndices[v]; } } //----------------------------------------------------------------------------- // ~LLPolyMorphData() //----------------------------------------------------------------------------- LLPolyMorphData::~LLPolyMorphData() { freeData(); } //----------------------------------------------------------------------------- // loadBinary() //----------------------------------------------------------------------------- BOOL LLPolyMorphData::loadBinary(LLFILE *fp, LLPolyMeshSharedData *mesh) { S32 numVertices; S32 numRead; numRead = fread(&numVertices, sizeof(S32), 1, fp); llendianswizzle(&numVertices, sizeof(S32), 1); if (numRead != 1) { LL_WARNS() << "Can't read number of morph target vertices" << LL_ENDL; return FALSE; } //------------------------------------------------------------------------- // free any existing data //------------------------------------------------------------------------- freeData(); //------------------------------------------------------------------------- // allocate vertices //------------------------------------------------------------------------- U32 size = sizeof(LLVector4a)*numVertices; mCoords = static_cast(ll_aligned_malloc_16(size)); mNormals = static_cast(ll_aligned_malloc_16(size)); mBinormals = static_cast(ll_aligned_malloc_16(size)); mTexCoords = new LLVector2[numVertices]; // Actually, we are allocating more space than we need for the skiplist mVertexIndices = new U32[numVertices]; mNumIndices = 0; mTotalDistortion = 0.f; mMaxDistortion = 0.f; mAvgDistortion.clear(); mMesh = mesh; //------------------------------------------------------------------------- // read vertices //------------------------------------------------------------------------- for(S32 v = 0; v < numVertices; v++) { numRead = fread(&mVertexIndices[v], sizeof(U32), 1, fp); llendianswizzle(&mVertexIndices[v], sizeof(U32), 1); if (numRead != 1) { LL_WARNS() << "Can't read morph target vertex number" << LL_ENDL; return FALSE; } if (mVertexIndices[v] > 10000) { LL_ERRS() << "Bad morph index: " << mVertexIndices[v] << LL_ENDL; } numRead = fread(&mCoords[v], sizeof(F32), 3, fp); llendianswizzle(&mCoords[v], sizeof(F32), 3); if (numRead != 3) { LL_WARNS() << "Can't read morph target vertex coordinates" << LL_ENDL; return FALSE; } F32 magnitude = mCoords[v].getLength3().getF32(); mTotalDistortion += magnitude; LLVector4a t; t.setAbs(mCoords[v]); mAvgDistortion.add(t); if (magnitude > mMaxDistortion) { mMaxDistortion = magnitude; } numRead = fread(&mNormals[v], sizeof(F32), 3, fp); llendianswizzle(&mNormals[v], sizeof(F32), 3); if (numRead != 3) { LL_WARNS() << "Can't read morph target normal" << LL_ENDL; return FALSE; } numRead = fread(&mBinormals[v], sizeof(F32), 3, fp); llendianswizzle(&mBinormals[v], sizeof(F32), 3); if (numRead != 3) { LL_WARNS() << "Can't read morph target binormal" << LL_ENDL; return FALSE; } numRead = fread(&mTexCoords[v].mV, sizeof(F32), 2, fp); llendianswizzle(&mTexCoords[v].mV, sizeof(F32), 2); if (numRead != 2) { LL_WARNS() << "Can't read morph target uv" << LL_ENDL; return FALSE; } mNumIndices++; } mAvgDistortion.mul(1.f/(F32)mNumIndices); mAvgDistortion.normalize3fast(); return TRUE; } //----------------------------------------------------------------------------- // freeData() //----------------------------------------------------------------------------- void LLPolyMorphData::freeData() { if (mCoords != NULL) { ll_aligned_free_16(mCoords); mCoords = NULL; } if (mNormals != NULL) { ll_aligned_free_16(mNormals); mNormals = NULL; } if (mBinormals != NULL) { ll_aligned_free_16(mBinormals); mBinormals = NULL; } if (mTexCoords != NULL) { delete [] mTexCoords; mTexCoords = NULL; } if (mVertexIndices != NULL) { delete [] mVertexIndices; mVertexIndices = NULL; } } //----------------------------------------------------------------------------- // LLPolyMorphTargetInfo() //----------------------------------------------------------------------------- LLPolyMorphTargetInfo::LLPolyMorphTargetInfo() : mIsClothingMorph(FALSE) { } BOOL LLPolyMorphTargetInfo::parseXml(LLXmlTreeNode* node) { llassert( node->hasName( "param" ) && node->getChildByName( "param_morph" ) ); if (!LLViewerVisualParamInfo::parseXml(node)) return FALSE; // Get mixed-case name static LLStdStringHandle name_string = LLXmlTree::addAttributeString("name"); if( !node->getFastAttributeString( name_string, mMorphName ) ) { LL_WARNS() << "Avatar file: is missing name attribute" << LL_ENDL; return FALSE; // Continue, ignoring this tag } static LLStdStringHandle clothing_morph_string = LLXmlTree::addAttributeString("clothing_morph"); node->getFastAttributeBOOL(clothing_morph_string, mIsClothingMorph); LLXmlTreeNode *paramNode = node->getChildByName("param_morph"); if (NULL == paramNode) { LL_WARNS() << "Failed to getChildByName(\"param_morph\")" << LL_ENDL; return FALSE; } for (LLXmlTreeNode* child_node = paramNode->getFirstChild(); child_node; child_node = paramNode->getNextChild()) { static LLStdStringHandle name_string = LLXmlTree::addAttributeString("name"); if (child_node->hasName("volume_morph")) { std::string volume_name; if (child_node->getFastAttributeString(name_string, volume_name)) { LLVector3 scale; static LLStdStringHandle scale_string = LLXmlTree::addAttributeString("scale"); child_node->getFastAttributeVector3(scale_string, scale); LLVector3 pos; static LLStdStringHandle pos_string = LLXmlTree::addAttributeString("pos"); child_node->getFastAttributeVector3(pos_string, pos); mVolumeInfoList.push_back(LLPolyVolumeMorphInfo(volume_name,scale,pos)); } } } return TRUE; } //----------------------------------------------------------------------------- // LLPolyMorphTarget() //----------------------------------------------------------------------------- LLPolyMorphTarget::LLPolyMorphTarget(LLPolyMesh *poly_mesh) : mMorphData(NULL), mMesh(poly_mesh), mVertMask(NULL), mLastSex(SEX_FEMALE), mNumMorphMasksPending(0) { } //----------------------------------------------------------------------------- // ~LLPolyMorphTarget() //----------------------------------------------------------------------------- LLPolyMorphTarget::~LLPolyMorphTarget() { if (mVertMask) { delete mVertMask; } } //----------------------------------------------------------------------------- // setInfo() //----------------------------------------------------------------------------- BOOL LLPolyMorphTarget::setInfo(LLPolyMorphTargetInfo* info) { llassert(mInfo == NULL); if (info->mID < 0) return FALSE; mInfo = info; mID = info->mID; setWeight(getDefaultWeight()); LLAvatarAppearance* avatarp = mMesh->getAvatar(); LLPolyMorphTargetInfo::volume_info_list_t::iterator iter; for (iter = getInfo()->mVolumeInfoList.begin(); iter != getInfo()->mVolumeInfoList.end(); iter++) { LLPolyVolumeMorphInfo *volume_info = &(*iter); for (S32 i = 0; i < avatarp->mNumCollisionVolumes; i++) { if (avatarp->mCollisionVolumes[i].getName() == volume_info->mName) { mVolumeMorphs.push_back(LLPolyVolumeMorph(&avatarp->mCollisionVolumes[i], volume_info->mScale, volume_info->mPos)); break; } } } std::string morph_param_name = getInfo()->mMorphName; mMorphData = mMesh->getMorphData(morph_param_name); if (!mMorphData) { const std::string driven_tag = "_Driven"; U32 pos = morph_param_name.find(driven_tag); if (pos > 0) { morph_param_name = morph_param_name.substr(0,pos); mMorphData = mMesh->getMorphData(morph_param_name); } } if (!mMorphData) { LL_WARNS() << "No morph target named " << morph_param_name << " found in mesh." << LL_ENDL; return FALSE; // Continue, ignoring this tag } return TRUE; } /*virtual*/ LLViewerVisualParam* LLPolyMorphTarget::cloneParam(LLWearable* wearable) const { LLPolyMorphTarget *new_param = new LLPolyMorphTarget(mMesh); *new_param = *this; return new_param; } #if 0 // obsolete //----------------------------------------------------------------------------- // parseData() //----------------------------------------------------------------------------- BOOL LLPolyMorphTarget::parseData(LLXmlTreeNode* node) { LLPolyMorphTargetInfo* info = new LLPolyMorphTargetInfo; info->parseXml(node); if (!setInfo(info)) { delete info; return FALSE; } return TRUE; } #endif //----------------------------------------------------------------------------- // getVertexDistortion() //----------------------------------------------------------------------------- LLVector4a LLPolyMorphTarget::getVertexDistortion(S32 requested_index, LLPolyMesh *mesh) { if (!mMorphData || mMesh != mesh) return LLVector4a::getZero(); for(U32 index = 0; index < mMorphData->mNumIndices; index++) { if (mMorphData->mVertexIndices[index] == (U32)requested_index) { return mMorphData->mCoords[index]; } } return LLVector4a::getZero(); } //----------------------------------------------------------------------------- // getFirstDistortion() //----------------------------------------------------------------------------- const LLVector4a *LLPolyMorphTarget::getFirstDistortion(U32 *index, LLPolyMesh **poly_mesh) { if (!mMorphData) return &LLVector4a::getZero(); LLVector4a* resultVec; mMorphData->mCurrentIndex = 0; if (mMorphData->mNumIndices) { resultVec = &mMorphData->mCoords[mMorphData->mCurrentIndex]; if (index != NULL) { *index = mMorphData->mVertexIndices[mMorphData->mCurrentIndex]; } if (poly_mesh != NULL) { *poly_mesh = mMesh; } return resultVec; } return NULL; } //----------------------------------------------------------------------------- // getNextDistortion() //----------------------------------------------------------------------------- const LLVector4a *LLPolyMorphTarget::getNextDistortion(U32 *index, LLPolyMesh **poly_mesh) { if (!mMorphData) return &LLVector4a::getZero(); LLVector4a* resultVec; mMorphData->mCurrentIndex++; if (mMorphData->mCurrentIndex < mMorphData->mNumIndices) { resultVec = &mMorphData->mCoords[mMorphData->mCurrentIndex]; if (index != NULL) { *index = mMorphData->mVertexIndices[mMorphData->mCurrentIndex]; } if (poly_mesh != NULL) { *poly_mesh = mMesh; } return resultVec; } return NULL; } //----------------------------------------------------------------------------- // getTotalDistortion() //----------------------------------------------------------------------------- F32 LLPolyMorphTarget::getTotalDistortion() { if (mMorphData) { return mMorphData->mTotalDistortion; } else { return 0.f; } } //----------------------------------------------------------------------------- // getAvgDistortion() //----------------------------------------------------------------------------- const LLVector4a& LLPolyMorphTarget::getAvgDistortion() { if (mMorphData) { return mMorphData->mAvgDistortion; } else { return LLVector4a::getZero(); } } //----------------------------------------------------------------------------- // getMaxDistortion() //----------------------------------------------------------------------------- F32 LLPolyMorphTarget::getMaxDistortion() { if (mMorphData) { return mMorphData->mMaxDistortion; } else { return 0.f; } } //----------------------------------------------------------------------------- // apply() //----------------------------------------------------------------------------- static LLTrace::BlockTimerStatHandle FTM_APPLY_MORPH_TARGET("Apply Morph"); void LLPolyMorphTarget::apply( ESex avatar_sex ) { if (!mMorphData || mNumMorphMasksPending > 0) { return; } LL_RECORD_BLOCK_TIME(FTM_APPLY_MORPH_TARGET); mLastSex = avatar_sex; // Check for NaN condition (NaN is detected if a variable doesn't equal itself. if (mCurWeight != mCurWeight) { mCurWeight = 0.0; } if (mLastWeight != mLastWeight) { mLastWeight = mCurWeight+.001; } // perform differential update of morph F32 delta_weight = ( getSex() & avatar_sex ) ? (mCurWeight - mLastWeight) : (getDefaultWeight() - mLastWeight); // store last weight mLastWeight += delta_weight; if (delta_weight != 0.f) { llassert(!mMesh->isLOD()); LLVector4a *coords = mMesh->getWritableCoords(); LLVector4a *scaled_normals = mMesh->getScaledNormals(); LLVector4a *normals = mMesh->getWritableNormals(); LLVector4a *scaled_binormals = mMesh->getScaledBinormals(); LLVector4a *binormals = mMesh->getWritableBinormals(); LLVector4a *clothing_weights = mMesh->getWritableClothingWeights(); LLVector2 *tex_coords = mMesh->getWritableTexCoords(); F32 *maskWeightArray = (mVertMask) ? mVertMask->getMorphMaskWeights() : NULL; for(U32 vert_index_morph = 0; vert_index_morph < mMorphData->mNumIndices; vert_index_morph++) { S32 vert_index_mesh = mMorphData->mVertexIndices[vert_index_morph]; F32 maskWeight = 1.f; if (maskWeightArray) { maskWeight = maskWeightArray[vert_index_morph]; } LLVector4a pos = mMorphData->mCoords[vert_index_morph]; pos.mul(delta_weight*maskWeight); coords[vert_index_mesh].add(pos); if (getInfo()->mIsClothingMorph && clothing_weights) { LLVector4a clothing_offset = mMorphData->mCoords[vert_index_morph]; clothing_offset.mul(delta_weight * maskWeight); LLVector4a* clothing_weight = &clothing_weights[vert_index_mesh]; clothing_weight->add(clothing_offset); clothing_weight->getF32ptr()[VW] = maskWeight; } // calculate new normals based on half angles LLVector4a norm = mMorphData->mNormals[vert_index_morph]; norm.mul(delta_weight*maskWeight*NORMAL_SOFTEN_FACTOR); scaled_normals[vert_index_mesh].add(norm); norm = scaled_normals[vert_index_mesh]; // guard against degenerate input data before we create NaNs below! // norm.normalize3fast(); normals[vert_index_mesh] = norm; // calculate new binormals LLVector4a binorm = mMorphData->mBinormals[vert_index_morph]; // guard against degenerate input data before we create NaNs below! // if (!binorm.isFinite3() || (binorm.dot3(binorm).getF32() <= F_APPROXIMATELY_ZERO)) { binorm.set(1,0,0,1); } binorm.mul(delta_weight*maskWeight*NORMAL_SOFTEN_FACTOR); scaled_binormals[vert_index_mesh].add(binorm); LLVector4a tangent; tangent.setCross3(scaled_binormals[vert_index_mesh], norm); LLVector4a& normalized_binormal = binormals[vert_index_mesh]; normalized_binormal.setCross3(norm, tangent); normalized_binormal.normalize3fast(); tex_coords[vert_index_mesh] += mMorphData->mTexCoords[vert_index_morph] * delta_weight * maskWeight; } // now apply volume changes for( volume_list_t::iterator iter = mVolumeMorphs.begin(); iter != mVolumeMorphs.end(); iter++ ) { LLPolyVolumeMorph* volume_morph = &(*iter); LLVector3 scale_delta = volume_morph->mScale * delta_weight; LLVector3 pos_delta = volume_morph->mPos * delta_weight; volume_morph->mVolume->setScale(volume_morph->mVolume->getScale() + scale_delta); volume_morph->mVolume->setPosition(volume_morph->mVolume->getPosition() + pos_delta); } } if (mNext) { mNext->apply(avatar_sex); } } //----------------------------------------------------------------------------- // applyMask() //----------------------------------------------------------------------------- void LLPolyMorphTarget::applyMask(U8 *maskTextureData, S32 width, S32 height, S32 num_components, BOOL invert) { LLVector4a *clothing_weights = getInfo()->mIsClothingMorph ? mMesh->getWritableClothingWeights() : NULL; if (!mVertMask) { mVertMask = new LLPolyVertexMask(mMorphData); mNumMorphMasksPending--; } else { // remove effect of previous mask F32 *maskWeights = (mVertMask) ? mVertMask->getMorphMaskWeights() : NULL; if (maskWeights) { LLVector4a *coords = mMesh->getWritableCoords(); LLVector4a *scaled_normals = mMesh->getScaledNormals(); LLVector4a *scaled_binormals = mMesh->getScaledBinormals(); LLVector2 *tex_coords = mMesh->getWritableTexCoords(); LLVector4Logical clothing_mask; clothing_mask.clear(); clothing_mask.setElement<0>(); clothing_mask.setElement<1>(); clothing_mask.setElement<2>(); for(U32 vert = 0; vert < mMorphData->mNumIndices; vert++) { F32 lastMaskWeight = mLastWeight * maskWeights[vert]; S32 out_vert = mMorphData->mVertexIndices[vert]; // remove effect of existing masked morph LLVector4a t; t = mMorphData->mCoords[vert]; t.mul(lastMaskWeight); coords[out_vert].sub(t); t = mMorphData->mNormals[vert]; t.mul(lastMaskWeight*NORMAL_SOFTEN_FACTOR); scaled_normals[out_vert].sub(t); t = mMorphData->mBinormals[vert]; t.mul(lastMaskWeight*NORMAL_SOFTEN_FACTOR); scaled_binormals[out_vert].sub(t); tex_coords[out_vert] -= mMorphData->mTexCoords[vert] * lastMaskWeight; if (clothing_weights) { LLVector4a clothing_offset = mMorphData->mCoords[vert]; clothing_offset.mul(lastMaskWeight); LLVector4a* clothing_weight = &clothing_weights[out_vert]; LLVector4a t; t.setSub(*clothing_weight, clothing_offset); clothing_weight->setSelectWithMask(clothing_mask, t, *clothing_weight); } } } } // set last weight to 0, since we've removed the effect of this morph mLastWeight = 0.f; mVertMask->generateMask(maskTextureData, width, height, num_components, invert, clothing_weights); apply(mLastSex); } //----------------------------------------------------------------------------- // LLPolyVertexMask() //----------------------------------------------------------------------------- LLPolyVertexMask::LLPolyVertexMask(LLPolyMorphData* morph_data) { mWeights = new F32[morph_data->mNumIndices]; mMorphData = morph_data; mWeightsGenerated = FALSE; } //----------------------------------------------------------------------------- // ~LLPolyVertexMask() //----------------------------------------------------------------------------- LLPolyVertexMask::~LLPolyVertexMask() { delete[] mWeights; } //----------------------------------------------------------------------------- // generateMask() //----------------------------------------------------------------------------- void LLPolyVertexMask::generateMask(U8 *maskTextureData, S32 width, S32 height, S32 num_components, BOOL invert, LLVector4a *clothing_weights) { // RN debug output that uses Image Debugger (http://www.cs.unc.edu/~baxter/projects/imdebug/) // BOOL debugImg = FALSE; // if (debugImg) // { // if (invert) // { // imdebug("lum rbga=rgba b=8 w=%d h=%d *-1 %p", width, height, maskTextureData); // } // else // { // imdebug("lum rbga=rgba b=8 w=%d h=%d %p", width, height, maskTextureData); // } // } for (U32 index = 0; index < mMorphData->mNumIndices; index++) { S32 vertIndex = mMorphData->mVertexIndices[index]; const S32 *sharedVertIndex = mMorphData->mMesh->getSharedVert(vertIndex); LLVector2 uvCoords; if (sharedVertIndex) { uvCoords = mMorphData->mMesh->getUVs(*sharedVertIndex); } else { uvCoords = mMorphData->mMesh->getUVs(vertIndex); } U32 s = llclamp((U32)(uvCoords.mV[VX] * (F32)(width - 1)), (U32)0, (U32)width - 1); U32 t = llclamp((U32)(uvCoords.mV[VY] * (F32)(height - 1)), (U32)0, (U32)height - 1); mWeights[index] = ((F32) maskTextureData[((t * width + s) * num_components) + (num_components - 1)]) / 255.f; if (invert) { mWeights[index] = 1.f - mWeights[index]; } // now apply step function // mWeights[index] = mWeights[index] > 0.95f ? 1.f : 0.f; if (clothing_weights) { clothing_weights[vertIndex].getF32ptr()[VW] = mWeights[index]; } } mWeightsGenerated = TRUE; } //----------------------------------------------------------------------------- // getMaskForMorphIndex() //----------------------------------------------------------------------------- F32* LLPolyVertexMask::getMorphMaskWeights() { if (!mWeightsGenerated) { return NULL; } return mWeights; }