/** * @file lltexlayer.cpp * @brief A texture layer. Used for avatars. * * $LicenseInfo:firstyear=2002&license=viewerlgpl$ * 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 "lltexlayer.h" #include "llavatarappearance.h" #include "llcrc.h" #include "llimagej2c.h" #include "llimagetga.h" #include "lldir.h" #include "llvfile.h" #include "llvfs.h" #include "lltexlayerparams.h" #include "lltexturemanagerbridge.h" #include "lllocaltextureobject.h" #include "../llui/llui.h" #include "llwearable.h" #include "llwearabledata.h" #include "llvertexbuffer.h" #include "llviewervisualparam.h" #include "llfasttimer.h" //#include "../tools/imdebug/imdebug.h" using namespace LLAvatarAppearanceDefines; // runway consolidate extern std::string self_av_string(); class LLTexLayerInfo { friend class LLTexLayer; friend class LLTexLayerTemplate; friend class LLTexLayerInterface; public: LLTexLayerInfo(); ~LLTexLayerInfo(); BOOL parseXml(LLXmlTreeNode* node); BOOL createVisualParams(LLAvatarAppearance *appearance); BOOL isUserSettable() { return mLocalTexture != -1; } S32 getLocalTexture() const { return mLocalTexture; } BOOL getOnlyAlpha() const { return mUseLocalTextureAlphaOnly; } std::string getName() const { return mName; } private: std::string mName; BOOL mWriteAllChannels; // Don't use masking. Just write RGBA into buffer, LLTexLayerInterface::ERenderPass mRenderPass; std::string mGlobalColor; LLColor4 mFixedColor; S32 mLocalTexture; std::string mStaticImageFileName; BOOL mStaticImageIsMask; BOOL mUseLocalTextureAlphaOnly; // Ignore RGB channels from the input texture. Use alpha as a mask BOOL mIsVisibilityMask; typedef std::vector< std::pair< std::string,BOOL > > morph_name_list_t; morph_name_list_t mMorphNameList; param_color_info_list_t mParamColorInfoList; param_alpha_info_list_t mParamAlphaInfoList; }; //----------------------------------------------------------------------------- // LLTexLayerSetBuffer // The composite image that a LLViewerTexLayerSet writes to. Each LLViewerTexLayerSet has one. //----------------------------------------------------------------------------- LLTexLayerSetBuffer::LLTexLayerSetBuffer(LLTexLayerSet* const owner) : mTexLayerSet(owner) { } LLTexLayerSetBuffer::~LLTexLayerSetBuffer() { } void LLTexLayerSetBuffer::pushProjection() const { gGL.matrixMode(LLRender::MM_PROJECTION); gGL.pushMatrix(); gGL.loadIdentity(); gGL.ortho(0.0f, getCompositeWidth(), 0.0f, getCompositeHeight(), -1.0f, 1.0f); gGL.matrixMode(LLRender::MM_MODELVIEW); gGL.pushMatrix(); gGL.loadIdentity(); } void LLTexLayerSetBuffer::popProjection() const { gGL.matrixMode(LLRender::MM_PROJECTION); gGL.popMatrix(); gGL.matrixMode(LLRender::MM_MODELVIEW); gGL.popMatrix(); } // virtual void LLTexLayerSetBuffer::preRenderTexLayerSet() { // Set up an ortho projection pushProjection(); } // virtual void LLTexLayerSetBuffer::postRenderTexLayerSet(BOOL success) { popProjection(); } BOOL LLTexLayerSetBuffer::renderTexLayerSet() { // Default color mask for tex layer render gGL.setColorMask(true, true); BOOL success = TRUE; bool use_shaders = LLGLSLShader::sNoFixedFunction; if (use_shaders) { gAlphaMaskProgram.bind(); gAlphaMaskProgram.setMinimumAlpha(0.004f); } else { gGL.setAlphaRejectSettings(LLRender::CF_GREATER, 0.00f); } LLVertexBuffer::unbind(); // Composite the color data LLGLSUIDefault gls_ui; success &= mTexLayerSet->render( getCompositeOriginX(), getCompositeOriginY(), getCompositeWidth(), getCompositeHeight() ); gGL.flush(); midRenderTexLayerSet(success); if (use_shaders) { gAlphaMaskProgram.unbind(); } LLVertexBuffer::unbind(); // reset GL state gGL.setColorMask(true, true); gGL.setSceneBlendType(LLRender::BT_ALPHA); return success; } //----------------------------------------------------------------------------- // LLTexLayerSetInfo // An ordered set of texture layers that get composited into a single texture. //----------------------------------------------------------------------------- LLTexLayerSetInfo::LLTexLayerSetInfo() : mBodyRegion( "" ), mWidth( 512 ), mHeight( 512 ), mClearAlpha( TRUE ) { } LLTexLayerSetInfo::~LLTexLayerSetInfo( ) { std::for_each(mLayerInfoList.begin(), mLayerInfoList.end(), DeletePointer()); mLayerInfoList.clear(); } BOOL LLTexLayerSetInfo::parseXml(LLXmlTreeNode* node) { llassert( node->hasName( "layer_set" ) ); if( !node->hasName( "layer_set" ) ) { return FALSE; } // body_region static LLStdStringHandle body_region_string = LLXmlTree::addAttributeString("body_region"); if( !node->getFastAttributeString( body_region_string, mBodyRegion ) ) { LL_WARNS() << " is missing body_region attribute" << LL_ENDL; return FALSE; } // width, height static LLStdStringHandle width_string = LLXmlTree::addAttributeString("width"); if( !node->getFastAttributeS32( width_string, mWidth ) ) { return FALSE; } static LLStdStringHandle height_string = LLXmlTree::addAttributeString("height"); if( !node->getFastAttributeS32( height_string, mHeight ) ) { return FALSE; } // Optional alpha component to apply after all compositing is complete. static LLStdStringHandle alpha_tga_file_string = LLXmlTree::addAttributeString("alpha_tga_file"); node->getFastAttributeString( alpha_tga_file_string, mStaticAlphaFileName ); static LLStdStringHandle clear_alpha_string = LLXmlTree::addAttributeString("clear_alpha"); node->getFastAttributeBOOL( clear_alpha_string, mClearAlpha ); // for (LLXmlTreeNode* child = node->getChildByName( "layer" ); child; child = node->getNextNamedChild()) { LLTexLayerInfo* info = new LLTexLayerInfo(); if( !info->parseXml( child )) { delete info; return FALSE; } mLayerInfoList.push_back( info ); } return TRUE; } // creates visual params without generating layersets or layers void LLTexLayerSetInfo::createVisualParams(LLAvatarAppearance *appearance) { //layer_info_list_t mLayerInfoList; for (layer_info_list_t::iterator layer_iter = mLayerInfoList.begin(); layer_iter != mLayerInfoList.end(); layer_iter++) { LLTexLayerInfo *layer_info = *layer_iter; layer_info->createVisualParams(appearance); } } //----------------------------------------------------------------------------- // LLTexLayerSet // An ordered set of texture layers that get composited into a single texture. //----------------------------------------------------------------------------- BOOL LLTexLayerSet::sHasCaches = FALSE; LLTexLayerSet::LLTexLayerSet(LLAvatarAppearance* const appearance) : mAvatarAppearance( appearance ), mIsVisible( TRUE ), mBakedTexIndex(LLAvatarAppearanceDefines::BAKED_HEAD), mInfo( NULL ) { } // virtual LLTexLayerSet::~LLTexLayerSet() { deleteCaches(); std::for_each(mLayerList.begin(), mLayerList.end(), DeletePointer()); mLayerList.clear(); std::for_each(mMaskLayerList.begin(), mMaskLayerList.end(), DeletePointer()); mMaskLayerList.clear(); } //----------------------------------------------------------------------------- // setInfo //----------------------------------------------------------------------------- BOOL LLTexLayerSet::setInfo(const LLTexLayerSetInfo *info) { llassert(mInfo == NULL); mInfo = info; //mID = info->mID; // No ID mLayerList.reserve(info->mLayerInfoList.size()); for (LLTexLayerSetInfo::layer_info_list_t::const_iterator iter = info->mLayerInfoList.begin(); iter != info->mLayerInfoList.end(); iter++) { LLTexLayerInterface *layer = NULL; if ( (*iter)->isUserSettable() ) { layer = new LLTexLayerTemplate( this, getAvatarAppearance() ); } else { layer = new LLTexLayer(this); } // this is the first time this layer (of either type) is being created - make sure you add the parameters to the avatar appearance if (!layer->setInfo(*iter, NULL)) { mInfo = NULL; return FALSE; } if (!layer->isVisibilityMask()) { mLayerList.push_back( layer ); } else { mMaskLayerList.push_back(layer); } } requestUpdate(); stop_glerror(); return TRUE; } #if 0 // obsolete //----------------------------------------------------------------------------- // parseData //----------------------------------------------------------------------------- BOOL LLTexLayerSet::parseData(LLXmlTreeNode* node) { LLTexLayerSetInfo *info = new LLTexLayerSetInfo; if (!info->parseXml(node)) { delete info; return FALSE; } if (!setInfo(info)) { delete info; return FALSE; } return TRUE; } #endif void LLTexLayerSet::deleteCaches() { for( layer_list_t::iterator iter = mLayerList.begin(); iter != mLayerList.end(); iter++ ) { LLTexLayerInterface* layer = *iter; layer->deleteCaches(); } for (layer_list_t::iterator iter = mMaskLayerList.begin(); iter != mMaskLayerList.end(); iter++) { LLTexLayerInterface* layer = *iter; layer->deleteCaches(); } } BOOL LLTexLayerSet::render( S32 x, S32 y, S32 width, S32 height ) { BOOL success = TRUE; mIsVisible = TRUE; if (mMaskLayerList.size() > 0) { for (layer_list_t::iterator iter = mMaskLayerList.begin(); iter != mMaskLayerList.end(); iter++) { LLTexLayerInterface* layer = *iter; if (layer->isInvisibleAlphaMask()) { mIsVisible = FALSE; } } } bool use_shaders = LLGLSLShader::sNoFixedFunction; LLGLSUIDefault gls_ui; LLGLDepthTest gls_depth(GL_FALSE, GL_FALSE); gGL.setColorMask(true, true); // clear buffer area to ensure we don't pick up UI elements { gGL.flush(); LLGLDisable no_alpha(GL_ALPHA_TEST); if (use_shaders) { gAlphaMaskProgram.setMinimumAlpha(0.0f); } gGL.getTexUnit(0)->unbind(LLTexUnit::TT_TEXTURE); gGL.color4f( 0.f, 0.f, 0.f, 1.f ); gl_rect_2d_simple( width, height ); gGL.flush(); if (use_shaders) { gAlphaMaskProgram.setMinimumAlpha(0.004f); } } if (mIsVisible) { // composite color layers for( layer_list_t::iterator iter = mLayerList.begin(); iter != mLayerList.end(); iter++ ) { LLTexLayerInterface* layer = *iter; if (layer->getRenderPass() == LLTexLayer::RP_COLOR) { gGL.flush(); success &= layer->render(x, y, width, height); gGL.flush(); } } renderAlphaMaskTextures(x, y, width, height, false); stop_glerror(); } else { gGL.flush(); gGL.setSceneBlendType(LLRender::BT_REPLACE); LLGLDisable no_alpha(GL_ALPHA_TEST); if (use_shaders) { gAlphaMaskProgram.setMinimumAlpha(0.f); } gGL.getTexUnit(0)->unbind(LLTexUnit::TT_TEXTURE); gGL.color4f( 0.f, 0.f, 0.f, 0.f ); gl_rect_2d_simple( width, height ); gGL.setSceneBlendType(LLRender::BT_ALPHA); gGL.flush(); if (use_shaders) { gAlphaMaskProgram.setMinimumAlpha(0.004f); } } return success; } BOOL LLTexLayerSet::isBodyRegion(const std::string& region) const { return mInfo->mBodyRegion == region; } const std::string LLTexLayerSet::getBodyRegionName() const { return mInfo->mBodyRegion; } // virtual void LLTexLayerSet::asLLSD(LLSD& sd) const { sd["visible"] = LLSD::Boolean(isVisible()); LLSD layer_list_sd; layer_list_t::const_iterator layer_iter = mLayerList.begin(); layer_list_t::const_iterator layer_end = mLayerList.end(); for(; layer_iter != layer_end; ++layer_iter); { LLSD layer_sd; //LLTexLayerInterface* layer = (*layer_iter); //if (layer) //{ // layer->asLLSD(layer_sd); //} layer_list_sd.append(layer_sd); } LLSD mask_list_sd; LLSD info_sd; sd["layers"] = layer_list_sd; sd["masks"] = mask_list_sd; sd["info"] = info_sd; } void LLTexLayerSet::destroyComposite() { if( mComposite ) { mComposite = NULL; } } LLTexLayerSetBuffer* LLTexLayerSet::getComposite() { if (!mComposite) { createComposite(); } return mComposite; } const LLTexLayerSetBuffer* LLTexLayerSet::getComposite() const { return mComposite; } static LLTrace::BlockTimerStatHandle FTM_GATHER_MORPH_MASK_ALPHA("gatherMorphMaskAlpha"); void LLTexLayerSet::gatherMorphMaskAlpha(U8 *data, S32 origin_x, S32 origin_y, S32 width, S32 height) { LL_RECORD_BLOCK_TIME(FTM_GATHER_MORPH_MASK_ALPHA); memset(data, 255, width * height); for( layer_list_t::iterator iter = mLayerList.begin(); iter != mLayerList.end(); iter++ ) { LLTexLayerInterface* layer = *iter; layer->gatherAlphaMasks(data, origin_x, origin_y, width, height); } // Set alpha back to that of our alpha masks. renderAlphaMaskTextures(origin_x, origin_y, width, height, true); } static LLTrace::BlockTimerStatHandle FTM_RENDER_ALPHA_MASK_TEXTURES("renderAlphaMaskTextures"); void LLTexLayerSet::renderAlphaMaskTextures(S32 x, S32 y, S32 width, S32 height, bool forceClear) { LL_RECORD_BLOCK_TIME(FTM_RENDER_ALPHA_MASK_TEXTURES); const LLTexLayerSetInfo *info = getInfo(); bool use_shaders = LLGLSLShader::sNoFixedFunction; gGL.setColorMask(false, true); gGL.setSceneBlendType(LLRender::BT_REPLACE); // (Optionally) replace alpha with a single component image from a tga file. if (!info->mStaticAlphaFileName.empty()) { gGL.flush(); { LLGLTexture* tex = LLTexLayerStaticImageList::getInstance()->getTexture(info->mStaticAlphaFileName, TRUE); if( tex ) { LLGLSUIDefault gls_ui; gGL.getTexUnit(0)->bind(tex); gGL.getTexUnit(0)->setTextureBlendType( LLTexUnit::TB_REPLACE ); gl_rect_2d_simple_tex( width, height ); } } gGL.flush(); } else if (forceClear || info->mClearAlpha || (mMaskLayerList.size() > 0)) { // Set the alpha channel to one (clean up after previous blending) gGL.flush(); LLGLDisable no_alpha(GL_ALPHA_TEST); if (use_shaders) { gAlphaMaskProgram.setMinimumAlpha(0.f); } gGL.getTexUnit(0)->unbind(LLTexUnit::TT_TEXTURE); gGL.color4f( 0.f, 0.f, 0.f, 1.f ); gl_rect_2d_simple( width, height ); gGL.flush(); if (use_shaders) { gAlphaMaskProgram.setMinimumAlpha(0.004f); } } // (Optional) Mask out part of the baked texture with alpha masks // will still have an effect even if mClearAlpha is set or the alpha component was replaced if (mMaskLayerList.size() > 0) { gGL.setSceneBlendType(LLRender::BT_MULT_ALPHA); gGL.getTexUnit(0)->setTextureBlendType( LLTexUnit::TB_REPLACE ); for (layer_list_t::iterator iter = mMaskLayerList.begin(); iter != mMaskLayerList.end(); iter++) { LLTexLayerInterface* layer = *iter; gGL.flush(); layer->blendAlphaTexture(x,y,width, height); gGL.flush(); } } gGL.getTexUnit(0)->unbind(LLTexUnit::TT_TEXTURE); gGL.getTexUnit(0)->setTextureBlendType(LLTexUnit::TB_MULT); gGL.setColorMask(true, true); gGL.setSceneBlendType(LLRender::BT_ALPHA); } void LLTexLayerSet::applyMorphMask(U8* tex_data, S32 width, S32 height, S32 num_components) { mAvatarAppearance->applyMorphMask(tex_data, width, height, num_components, mBakedTexIndex); } BOOL LLTexLayerSet::isMorphValid() const { for(layer_list_t::const_iterator iter = mLayerList.begin(); iter != mLayerList.end(); iter++ ) { const LLTexLayerInterface* layer = *iter; if (layer && !layer->isMorphValid()) { return FALSE; } } return TRUE; } void LLTexLayerSet::invalidateMorphMasks() { for( layer_list_t::iterator iter = mLayerList.begin(); iter != mLayerList.end(); iter++ ) { LLTexLayerInterface* layer = *iter; if (layer) { layer->invalidateMorphMasks(); } } } //----------------------------------------------------------------------------- // LLTexLayerInfo //----------------------------------------------------------------------------- LLTexLayerInfo::LLTexLayerInfo() : mWriteAllChannels( FALSE ), mRenderPass(LLTexLayer::RP_COLOR), mFixedColor( 0.f, 0.f, 0.f, 0.f ), mLocalTexture( -1 ), mStaticImageIsMask( FALSE ), mUseLocalTextureAlphaOnly(FALSE), mIsVisibilityMask(FALSE) { } LLTexLayerInfo::~LLTexLayerInfo( ) { std::for_each(mParamColorInfoList.begin(), mParamColorInfoList.end(), DeletePointer()); mParamColorInfoList.clear(); std::for_each(mParamAlphaInfoList.begin(), mParamAlphaInfoList.end(), DeletePointer()); mParamAlphaInfoList.clear(); } BOOL LLTexLayerInfo::parseXml(LLXmlTreeNode* node) { llassert( node->hasName( "layer" ) ); // name attribute static LLStdStringHandle name_string = LLXmlTree::addAttributeString("name"); if( !node->getFastAttributeString( name_string, mName ) ) { return FALSE; } static LLStdStringHandle write_all_channels_string = LLXmlTree::addAttributeString("write_all_channels"); node->getFastAttributeBOOL( write_all_channels_string, mWriteAllChannels ); std::string render_pass_name; static LLStdStringHandle render_pass_string = LLXmlTree::addAttributeString("render_pass"); if( node->getFastAttributeString( render_pass_string, render_pass_name ) ) { if( render_pass_name == "bump" ) { mRenderPass = LLTexLayer::RP_BUMP; } } // Note: layers can have either a "global_color" attrib, a "fixed_color" attrib, or a child. // global color attribute (optional) static LLStdStringHandle global_color_string = LLXmlTree::addAttributeString("global_color"); node->getFastAttributeString( global_color_string, mGlobalColor ); // Visibility mask (optional) BOOL is_visibility; static LLStdStringHandle visibility_mask_string = LLXmlTree::addAttributeString("visibility_mask"); if (node->getFastAttributeBOOL(visibility_mask_string, is_visibility)) { mIsVisibilityMask = is_visibility; } // color attribute (optional) LLColor4U color4u; static LLStdStringHandle fixed_color_string = LLXmlTree::addAttributeString("fixed_color"); if( node->getFastAttributeColor4U( fixed_color_string, color4u ) ) { mFixedColor.setVec( color4u ); } // optional sub-element for (LLXmlTreeNode* texture_node = node->getChildByName( "texture" ); texture_node; texture_node = node->getNextNamedChild()) { std::string local_texture_name; static LLStdStringHandle tga_file_string = LLXmlTree::addAttributeString("tga_file"); static LLStdStringHandle local_texture_string = LLXmlTree::addAttributeString("local_texture"); static LLStdStringHandle file_is_mask_string = LLXmlTree::addAttributeString("file_is_mask"); static LLStdStringHandle local_texture_alpha_only_string = LLXmlTree::addAttributeString("local_texture_alpha_only"); if( texture_node->getFastAttributeString( tga_file_string, mStaticImageFileName ) ) { texture_node->getFastAttributeBOOL( file_is_mask_string, mStaticImageIsMask ); } else if (texture_node->getFastAttributeString(local_texture_string, local_texture_name)) { texture_node->getFastAttributeBOOL( local_texture_alpha_only_string, mUseLocalTextureAlphaOnly ); /* if ("upper_shirt" == local_texture_name) mLocalTexture = TEX_UPPER_SHIRT; */ mLocalTexture = TEX_NUM_INDICES; for (LLAvatarAppearanceDictionary::Textures::const_iterator iter = LLAvatarAppearanceDictionary::getInstance()->getTextures().begin(); iter != LLAvatarAppearanceDictionary::getInstance()->getTextures().end(); iter++) { const LLAvatarAppearanceDictionary::TextureEntry *texture_dict = iter->second; if (local_texture_name == texture_dict->mName) { mLocalTexture = iter->first; break; } } if (mLocalTexture == TEX_NUM_INDICES) { LL_WARNS() << " element has invalid local_texture attribute: " << mName << " " << local_texture_name << LL_ENDL; return FALSE; } } else { LL_WARNS() << " element is missing a required attribute. " << mName << LL_ENDL; return FALSE; } } for (LLXmlTreeNode* maskNode = node->getChildByName( "morph_mask" ); maskNode; maskNode = node->getNextNamedChild()) { std::string morph_name; static LLStdStringHandle morph_name_string = LLXmlTree::addAttributeString("morph_name"); if (maskNode->getFastAttributeString(morph_name_string, morph_name)) { BOOL invert = FALSE; static LLStdStringHandle invert_string = LLXmlTree::addAttributeString("invert"); maskNode->getFastAttributeBOOL(invert_string, invert); mMorphNameList.push_back(std::pair(morph_name,invert)); } } // optional sub-element (color or alpha params) for (LLXmlTreeNode* child = node->getChildByName( "param" ); child; child = node->getNextNamedChild()) { if( child->getChildByName( "param_color" ) ) { // LLTexLayerParamColorInfo* info = new LLTexLayerParamColorInfo(); if (!info->parseXml(child)) { delete info; return FALSE; } mParamColorInfoList.push_back(info); } else if( child->getChildByName( "param_alpha" ) ) { // LLTexLayerParamAlphaInfo* info = new LLTexLayerParamAlphaInfo( ); if (!info->parseXml(child)) { delete info; return FALSE; } mParamAlphaInfoList.push_back(info); } } return TRUE; } BOOL LLTexLayerInfo::createVisualParams(LLAvatarAppearance *appearance) { BOOL success = TRUE; for (param_color_info_list_t::iterator color_info_iter = mParamColorInfoList.begin(); color_info_iter != mParamColorInfoList.end(); color_info_iter++) { LLTexLayerParamColorInfo * color_info = *color_info_iter; LLTexLayerParamColor* param_color = new LLTexLayerParamColor(appearance); if (!param_color->setInfo(color_info, TRUE)) { LL_WARNS() << "NULL TexLayer Color Param could not be added to visual param list. Deleting." << LL_ENDL; delete param_color; success = FALSE; } } for (param_alpha_info_list_t::iterator alpha_info_iter = mParamAlphaInfoList.begin(); alpha_info_iter != mParamAlphaInfoList.end(); alpha_info_iter++) { LLTexLayerParamAlphaInfo * alpha_info = *alpha_info_iter; LLTexLayerParamAlpha* param_alpha = new LLTexLayerParamAlpha(appearance); if (!param_alpha->setInfo(alpha_info, TRUE)) { LL_WARNS() << "NULL TexLayer Alpha Param could not be added to visual param list. Deleting." << LL_ENDL; delete param_alpha; success = FALSE; } } return success; } LLTexLayerInterface::LLTexLayerInterface(LLTexLayerSet* const layer_set): mTexLayerSet( layer_set ), mMorphMasksValid( FALSE ), mInfo(NULL), mHasMorph(FALSE) { } LLTexLayerInterface::LLTexLayerInterface(const LLTexLayerInterface &layer, LLWearable *wearable): mTexLayerSet( layer.mTexLayerSet ), mInfo(NULL) { // don't add visual params for cloned layers setInfo(layer.getInfo(), wearable); mHasMorph = layer.mHasMorph; } BOOL LLTexLayerInterface::setInfo(const LLTexLayerInfo *info, LLWearable* wearable ) // This sets mInfo and calls initialization functions { // setInfo should only be called once. Code is not robust enough to handle redefinition of a texlayer. // Not a critical warning, but could be useful for debugging later issues. -Nyx if (mInfo != NULL) { LL_WARNS() << "mInfo != NULL" << LL_ENDL; } mInfo = info; //mID = info->mID; // No ID mParamColorList.reserve(mInfo->mParamColorInfoList.size()); for (param_color_info_list_t::const_iterator iter = mInfo->mParamColorInfoList.begin(); iter != mInfo->mParamColorInfoList.end(); iter++) { LLTexLayerParamColor* param_color; if (!wearable) { param_color = new LLTexLayerParamColor(this); if (!param_color->setInfo(*iter, TRUE)) { mInfo = NULL; return FALSE; } } else { param_color = (LLTexLayerParamColor*)wearable->getVisualParam((*iter)->getID()); if (!param_color) { mInfo = NULL; return FALSE; } } mParamColorList.push_back( param_color ); } mParamAlphaList.reserve(mInfo->mParamAlphaInfoList.size()); for (param_alpha_info_list_t::const_iterator iter = mInfo->mParamAlphaInfoList.begin(); iter != mInfo->mParamAlphaInfoList.end(); iter++) { LLTexLayerParamAlpha* param_alpha; if (!wearable) { param_alpha = new LLTexLayerParamAlpha( this ); if (!param_alpha->setInfo(*iter, TRUE)) { mInfo = NULL; return FALSE; } } else { param_alpha = (LLTexLayerParamAlpha*) wearable->getVisualParam((*iter)->getID()); if (!param_alpha) { mInfo = NULL; return FALSE; } } mParamAlphaList.push_back( param_alpha ); } return TRUE; } /*virtual*/ void LLTexLayerInterface::requestUpdate() { mTexLayerSet->requestUpdate(); } const std::string& LLTexLayerInterface::getName() const { return mInfo->mName; } ETextureIndex LLTexLayerInterface::getLocalTextureIndex() const { return (ETextureIndex) mInfo->mLocalTexture; } LLWearableType::EType LLTexLayerInterface::getWearableType() const { ETextureIndex te = getLocalTextureIndex(); if (TEX_INVALID == te) { LLWearableType::EType type = LLWearableType::WT_INVALID; param_color_list_t::const_iterator color_iter = mParamColorList.begin(); param_alpha_list_t::const_iterator alpha_iter = mParamAlphaList.begin(); for (; color_iter != mParamColorList.end(); color_iter++) { LLTexLayerParamColor* param = *color_iter; if (param) { LLWearableType::EType new_type = (LLWearableType::EType)param->getWearableType(); if (new_type != LLWearableType::WT_INVALID && new_type != type) { if (type != LLWearableType::WT_INVALID) { return LLWearableType::WT_INVALID; } type = new_type; } } } for (; alpha_iter != mParamAlphaList.end(); alpha_iter++) { LLTexLayerParamAlpha* param = *alpha_iter; if (param) { LLWearableType::EType new_type = (LLWearableType::EType)param->getWearableType(); if (new_type != LLWearableType::WT_INVALID && new_type != type) { if (type != LLWearableType::WT_INVALID) { return LLWearableType::WT_INVALID; } type = new_type; } } } return type; } return LLAvatarAppearanceDictionary::getTEWearableType(te); } LLTexLayerInterface::ERenderPass LLTexLayerInterface::getRenderPass() const { return mInfo->mRenderPass; } const std::string& LLTexLayerInterface::getGlobalColor() const { return mInfo->mGlobalColor; } BOOL LLTexLayerInterface::isVisibilityMask() const { return mInfo->mIsVisibilityMask; } void LLTexLayerInterface::invalidateMorphMasks() { mMorphMasksValid = FALSE; } LLViewerVisualParam* LLTexLayerInterface::getVisualParamPtr(S32 index) const { LLViewerVisualParam *result = NULL; for (param_color_list_t::const_iterator color_iter = mParamColorList.begin(); color_iter != mParamColorList.end() && !result; ++color_iter) { if ((*color_iter)->getID() == index) { result = *color_iter; } } for (param_alpha_list_t::const_iterator alpha_iter = mParamAlphaList.begin(); alpha_iter != mParamAlphaList.end() && !result; ++alpha_iter) { if ((*alpha_iter)->getID() == index) { result = *alpha_iter; } } return result; } //----------------------------------------------------------------------------- // LLTexLayer // A single texture layer, consisting of: // * color, consisting of either // * one or more color parameters (weighted colors) // * a reference to a global color // * a fixed color with non-zero alpha // * opaque white (the default) // * (optional) a texture defined by either // * a GUID // * a texture entry index (TE) // * (optional) one or more alpha parameters (weighted alpha textures) //----------------------------------------------------------------------------- LLTexLayer::LLTexLayer(LLTexLayerSet* const layer_set) : LLTexLayerInterface( layer_set ), mLocalTextureObject(NULL) { } LLTexLayer::LLTexLayer(const LLTexLayer &layer, LLWearable *wearable) : LLTexLayerInterface( layer, wearable ), mLocalTextureObject(NULL) { } LLTexLayer::LLTexLayer(const LLTexLayerTemplate &layer_template, LLLocalTextureObject *lto, LLWearable *wearable) : LLTexLayerInterface( layer_template, wearable ), mLocalTextureObject(lto) { } LLTexLayer::~LLTexLayer() { // mParamAlphaList and mParamColorList are LLViewerVisualParam's and get // deleted with ~LLCharacter() //std::for_each(mParamAlphaList.begin(), mParamAlphaList.end(), DeletePointer()); //std::for_each(mParamColorList.begin(), mParamColorList.end(), DeletePointer()); for( alpha_cache_t::iterator iter = mAlphaCache.begin(); iter != mAlphaCache.end(); iter++ ) { U8* alpha_data = iter->second; ll_aligned_free_32(alpha_data); } } void LLTexLayer::asLLSD(LLSD& sd) const { // *TODO: Finish sd["id"] = getUUID(); } //----------------------------------------------------------------------------- // setInfo //----------------------------------------------------------------------------- BOOL LLTexLayer::setInfo(const LLTexLayerInfo* info, LLWearable* wearable ) { return LLTexLayerInterface::setInfo(info, wearable); } //static void LLTexLayer::calculateTexLayerColor(const param_color_list_t ¶m_list, LLColor4 &net_color) { for (param_color_list_t::const_iterator iter = param_list.begin(); iter != param_list.end(); iter++) { const LLTexLayerParamColor* param = *iter; LLColor4 param_net = param->getNetColor(); const LLTexLayerParamColorInfo *info = (LLTexLayerParamColorInfo *)param->getInfo(); switch(info->getOperation()) { case LLTexLayerParamColor::OP_ADD: net_color += param_net; break; case LLTexLayerParamColor::OP_MULTIPLY: net_color = net_color * param_net; break; case LLTexLayerParamColor::OP_BLEND: net_color = lerp(net_color, param_net, param->getWeight()); break; default: llassert(0); break; } } net_color.clamp(); } /*virtual*/ void LLTexLayer::deleteCaches() { // Only need to delete caches for alpha params. Color params don't hold extra memory for (param_alpha_list_t::iterator iter = mParamAlphaList.begin(); iter != mParamAlphaList.end(); iter++ ) { LLTexLayerParamAlpha* param = *iter; param->deleteCaches(); } } BOOL LLTexLayer::render(S32 x, S32 y, S32 width, S32 height) { LLGLEnable color_mat(GL_COLOR_MATERIAL); // *TODO: Is this correct? //gPipeline.disableLights(); stop_glerror(); if (!LLGLSLShader::sNoFixedFunction) { glDisable(GL_LIGHTING); } stop_glerror(); bool use_shaders = LLGLSLShader::sNoFixedFunction; LLColor4 net_color; BOOL color_specified = findNetColor(&net_color); if (mTexLayerSet->getAvatarAppearance()->mIsDummy) { color_specified = true; net_color = LLAvatarAppearance::getDummyColor(); } BOOL success = TRUE; // If you can't see the layer, don't render it. if( is_approx_zero( net_color.mV[VW] ) ) { return success; } BOOL alpha_mask_specified = FALSE; param_alpha_list_t::const_iterator iter = mParamAlphaList.begin(); if( iter != mParamAlphaList.end() ) { // If we have alpha masks, but we're skipping all of them, skip the whole layer. // However, we can't do this optimization if we have morph masks that need updating. /* if (!mHasMorph) { BOOL skip_layer = TRUE; while( iter != mParamAlphaList.end() ) { const LLTexLayerParamAlpha* param = *iter; if( !param->getSkip() ) { skip_layer = FALSE; break; } iter++; } if( skip_layer ) { return success; } }//*/ const bool force_render = true; renderMorphMasks(x, y, width, height, net_color, force_render); alpha_mask_specified = TRUE; gGL.flush(); gGL.blendFunc(LLRender::BF_DEST_ALPHA, LLRender::BF_ONE_MINUS_DEST_ALPHA); } gGL.color4fv( net_color.mV); if( getInfo()->mWriteAllChannels ) { gGL.flush(); gGL.setSceneBlendType(LLRender::BT_REPLACE); } if( (getInfo()->mLocalTexture != -1) && !getInfo()->mUseLocalTextureAlphaOnly ) { { LLGLTexture* tex = NULL; if (mLocalTextureObject && mLocalTextureObject->getImage()) { tex = mLocalTextureObject->getImage(); if (mLocalTextureObject->getID() == IMG_DEFAULT_AVATAR) { tex = NULL; } } else { LL_INFOS() << "lto not defined or image not defined: " << getInfo()->getLocalTexture() << " lto: " << mLocalTextureObject << LL_ENDL; } // if( mTexLayerSet->getAvatarAppearance()->getLocalTextureGL((ETextureIndex)getInfo()->mLocalTexture, &image_gl ) ) { if( tex ) { bool no_alpha_test = getInfo()->mWriteAllChannels; LLGLDisable alpha_test(no_alpha_test ? GL_ALPHA_TEST : 0); if (no_alpha_test) { if (use_shaders) { gAlphaMaskProgram.setMinimumAlpha(0.f); } } LLTexUnit::eTextureAddressMode old_mode = tex->getAddressMode(); gGL.getTexUnit(0)->bind(tex, TRUE); gGL.getTexUnit(0)->setTextureAddressMode(LLTexUnit::TAM_CLAMP); gl_rect_2d_simple_tex( width, height ); gGL.getTexUnit(0)->setTextureAddressMode(old_mode); gGL.getTexUnit(0)->unbind(LLTexUnit::TT_TEXTURE); if (no_alpha_test) { if (use_shaders) { gAlphaMaskProgram.setMinimumAlpha(0.004f); } } } } // else // { // success = FALSE; // } } } if( !getInfo()->mStaticImageFileName.empty() ) { { LLGLTexture* tex = LLTexLayerStaticImageList::getInstance()->getTexture(getInfo()->mStaticImageFileName, getInfo()->mStaticImageIsMask); if( tex ) { gGL.getTexUnit(0)->bind(tex, TRUE); gl_rect_2d_simple_tex( width, height ); gGL.getTexUnit(0)->unbind(LLTexUnit::TT_TEXTURE); } else { success = FALSE; } } } if(((-1 == getInfo()->mLocalTexture) || getInfo()->mUseLocalTextureAlphaOnly) && getInfo()->mStaticImageFileName.empty() && color_specified ) { LLGLDisable no_alpha(GL_ALPHA_TEST); if (use_shaders) { gAlphaMaskProgram.setMinimumAlpha(0.000f); } gGL.getTexUnit(0)->unbind(LLTexUnit::TT_TEXTURE); gGL.color4fv( net_color.mV ); gl_rect_2d_simple( width, height ); if (use_shaders) { gAlphaMaskProgram.setMinimumAlpha(0.004f); } } if( alpha_mask_specified || getInfo()->mWriteAllChannels ) { // Restore standard blend func value gGL.flush(); gGL.setSceneBlendType(LLRender::BT_ALPHA); stop_glerror(); } if( !success ) { LL_INFOS() << "LLTexLayer::render() partial: " << getInfo()->mName << LL_ENDL; } return success; } const U8* LLTexLayer::getAlphaData() const { LLCRC alpha_mask_crc; const LLUUID& uuid = getUUID(); alpha_mask_crc.update((U8*)(&uuid.mData), UUID_BYTES); for (param_alpha_list_t::const_iterator iter = mParamAlphaList.begin(); iter != mParamAlphaList.end(); iter++) { const LLTexLayerParamAlpha* param = *iter; // MULTI-WEARABLE: verify visual parameters used here F32 param_weight = param->getWeight(); alpha_mask_crc.update((U8*)¶m_weight, sizeof(F32)); } U32 cache_index = alpha_mask_crc.getCRC(); alpha_cache_t::const_iterator iter2 = mAlphaCache.find(cache_index); return (iter2 == mAlphaCache.end()) ? 0 : iter2->second; } BOOL LLTexLayer::findNetColor(LLColor4* net_color) const { // Color is either: // * one or more color parameters (weighted colors) (which may make use of a global color or fixed color) // * a reference to a global color // * a fixed color with non-zero alpha // * opaque white (the default) if( !mParamColorList.empty() ) { if( !getGlobalColor().empty() ) { net_color->setVec( mTexLayerSet->getAvatarAppearance()->getGlobalColor( getInfo()->mGlobalColor ) ); } else if (getInfo()->mFixedColor.mV[VW]) { net_color->setVec( getInfo()->mFixedColor ); } else { net_color->setVec( 0.f, 0.f, 0.f, 0.f ); } calculateTexLayerColor(mParamColorList, *net_color); return TRUE; } if( !getGlobalColor().empty() ) { net_color->setVec( mTexLayerSet->getAvatarAppearance()->getGlobalColor( getGlobalColor() ) ); return TRUE; } if( getInfo()->mFixedColor.mV[VW] ) { net_color->setVec( getInfo()->mFixedColor ); return TRUE; } net_color->setToWhite(); return FALSE; // No need to draw a separate colored polygon } BOOL LLTexLayer::blendAlphaTexture(S32 x, S32 y, S32 width, S32 height) { BOOL success = TRUE; gGL.flush(); bool use_shaders = LLGLSLShader::sNoFixedFunction; if( !getInfo()->mStaticImageFileName.empty() ) { LLGLTexture* tex = LLTexLayerStaticImageList::getInstance()->getTexture( getInfo()->mStaticImageFileName, getInfo()->mStaticImageIsMask ); if( tex ) { LLGLSNoAlphaTest gls_no_alpha_test; if (use_shaders) { gAlphaMaskProgram.setMinimumAlpha(0.f); } gGL.getTexUnit(0)->bind(tex, TRUE); gl_rect_2d_simple_tex( width, height ); gGL.getTexUnit(0)->unbind(LLTexUnit::TT_TEXTURE); if (use_shaders) { gAlphaMaskProgram.setMinimumAlpha(0.004f); } } else { success = FALSE; } } else { if (getInfo()->mLocalTexture >=0 && getInfo()->mLocalTexture < TEX_NUM_INDICES) { LLGLTexture* tex = mLocalTextureObject->getImage(); if (tex) { LLGLSNoAlphaTest gls_no_alpha_test; if (use_shaders) { gAlphaMaskProgram.setMinimumAlpha(0.f); } gGL.getTexUnit(0)->bind(tex); gl_rect_2d_simple_tex( width, height ); gGL.getTexUnit(0)->unbind(LLTexUnit::TT_TEXTURE); success = TRUE; if (use_shaders) { gAlphaMaskProgram.setMinimumAlpha(0.004f); } } } } return success; } /*virtual*/ void LLTexLayer::gatherAlphaMasks(U8 *data, S32 originX, S32 originY, S32 width, S32 height) { addAlphaMask(data, originX, originY, width, height); } static LLTrace::BlockTimerStatHandle FTM_RENDER_MORPH_MASKS("renderMorphMasks"); void LLTexLayer::renderMorphMasks(S32 x, S32 y, S32 width, S32 height, const LLColor4 &layer_color, bool force_render) { if (!force_render && !hasMorph()) { LL_DEBUGS() << "skipping renderMorphMasks for " << getUUID() << LL_ENDL; return; } LL_RECORD_BLOCK_TIME(FTM_RENDER_MORPH_MASKS); BOOL success = TRUE; llassert( !mParamAlphaList.empty() ); bool use_shaders = LLGLSLShader::sNoFixedFunction; if (use_shaders) { gAlphaMaskProgram.setMinimumAlpha(0.f); } gGL.setColorMask(false, true); LLTexLayerParamAlpha* first_param = *mParamAlphaList.begin(); // Note: if the first param is a mulitply, multiply against the current buffer's alpha if( !first_param || !first_param->getMultiplyBlend() ) { LLGLDisable no_alpha(GL_ALPHA_TEST); gGL.getTexUnit(0)->unbind(LLTexUnit::TT_TEXTURE); // Clear the alpha gGL.flush(); gGL.setSceneBlendType(LLRender::BT_REPLACE); gGL.color4f( 0.f, 0.f, 0.f, 0.f ); gl_rect_2d_simple( width, height ); } // Accumulate alphas LLGLSNoAlphaTest gls_no_alpha_test; gGL.color4f( 1.f, 1.f, 1.f, 1.f ); for (param_alpha_list_t::iterator iter = mParamAlphaList.begin(); iter != mParamAlphaList.end(); iter++) { LLTexLayerParamAlpha* param = *iter; success &= param->render( x, y, width, height ); if (!success && !force_render) { LL_DEBUGS() << "Failed to render param " << param->getID() << " ; skipping morph mask." << LL_ENDL; return; } } // Approximates a min() function gGL.flush(); gGL.setSceneBlendType(LLRender::BT_MULT_ALPHA); // Accumulate the alpha component of the texture if( getInfo()->mLocalTexture != -1 ) { LLGLTexture* tex = mLocalTextureObject->getImage(); if( tex && (tex->getComponents() == 4) ) { LLGLSNoAlphaTest gls_no_alpha_test; LLTexUnit::eTextureAddressMode old_mode = tex->getAddressMode(); gGL.getTexUnit(0)->bind(tex, TRUE); gGL.getTexUnit(0)->setTextureAddressMode(LLTexUnit::TAM_CLAMP); gl_rect_2d_simple_tex( width, height ); gGL.getTexUnit(0)->setTextureAddressMode(old_mode); gGL.getTexUnit(0)->unbind(LLTexUnit::TT_TEXTURE); } } if( !getInfo()->mStaticImageFileName.empty() && getInfo()->mStaticImageIsMask ) { LLGLTexture* tex = LLTexLayerStaticImageList::getInstance()->getTexture(getInfo()->mStaticImageFileName, getInfo()->mStaticImageIsMask); if( tex ) { if( (tex->getComponents() == 4) || (tex->getComponents() == 1) ) { LLGLSNoAlphaTest gls_no_alpha_test; gGL.getTexUnit(0)->bind(tex, TRUE); gl_rect_2d_simple_tex( width, height ); gGL.getTexUnit(0)->unbind(LLTexUnit::TT_TEXTURE); } else { LL_WARNS() << "Skipping rendering of " << getInfo()->mStaticImageFileName << "; expected 1 or 4 components." << LL_ENDL; } } } // Draw a rectangle with the layer color to multiply the alpha by that color's alpha. // Note: we're still using gGL.blendFunc( GL_DST_ALPHA, GL_ZERO ); if ( !is_approx_equal(layer_color.mV[VW], 1.f) ) { LLGLDisable no_alpha(GL_ALPHA_TEST); gGL.getTexUnit(0)->unbind(LLTexUnit::TT_TEXTURE); gGL.color4fv(layer_color.mV); gl_rect_2d_simple( width, height ); } if (use_shaders) { gAlphaMaskProgram.setMinimumAlpha(0.004f); } LLGLSUIDefault gls_ui; gGL.setColorMask(true, true); if (hasMorph() && success) { LLCRC alpha_mask_crc; const LLUUID& uuid = getUUID(); alpha_mask_crc.update((U8*)(&uuid.mData), UUID_BYTES); for (param_alpha_list_t::const_iterator iter = mParamAlphaList.begin(); iter != mParamAlphaList.end(); iter++) { const LLTexLayerParamAlpha* param = *iter; F32 param_weight = param->getWeight(); alpha_mask_crc.update((U8*)¶m_weight, sizeof(F32)); } U32 cache_index = alpha_mask_crc.getCRC(); U8* alpha_data = NULL; // We believe we need to generate morph masks, do not assume that the cached version is accurate. // We can get bad morph masks during login, on minimize, and occasional gl errors. // We should only be doing this when we believe something has changed with respect to the user's appearance. { LL_DEBUGS("Avatar") << "gl alpha cache of morph mask not found, doing readback: " << getName() << LL_ENDL; // clear out a slot if we have filled our cache S32 max_cache_entries = getTexLayerSet()->getAvatarAppearance()->isSelf() ? 4 : 1; while ((S32)mAlphaCache.size() >= max_cache_entries) { alpha_cache_t::iterator iter2 = mAlphaCache.begin(); // arbitrarily grab the first entry alpha_data = iter2->second; ll_aligned_free_32(alpha_data); mAlphaCache.erase(iter2); } // GPUs tend to be very uptight about memory alignment as the DMA used to convey // said data to the card works better when well-aligned so plain old default-aligned heap mem is a no-no //new U8[width * height]; size_t mem_size = (width * height); size_t rem = (mem_size & 0x3F); mem_size += rem > 0 ? (mem_size + (32 - rem)) : 0; alpha_data = (U8*)ll_aligned_malloc_32(mem_size); mAlphaCache[cache_index] = alpha_data; bool skip_readback = LLRender::sNsightDebugSupport; // nSight doesn't support use of glReadPixels // SL-10625 and neither does Intel in many cases skip_readback = skip_readback || gGLManager.mIsIntel; if (!skip_readback) { glReadPixels(x, y, width, height, GL_ALPHA, GL_UNSIGNED_BYTE, alpha_data); } else { ll_aligned_free_32(alpha_data); alpha_data = nullptr; } } getTexLayerSet()->getAvatarAppearance()->dirtyMesh(); mMorphMasksValid = TRUE; getTexLayerSet()->applyMorphMask(alpha_data, width, height, 1); } } static LLTrace::BlockTimerStatHandle FTM_ADD_ALPHA_MASK("addAlphaMask"); void LLTexLayer::addAlphaMask(U8 *data, S32 originX, S32 originY, S32 width, S32 height) { LL_RECORD_BLOCK_TIME(FTM_ADD_ALPHA_MASK); S32 size = width * height; const U8* alphaData = getAlphaData(); if (!alphaData && hasAlphaParams()) { LLColor4 net_color; findNetColor( &net_color ); // TODO: eliminate need for layer morph mask valid flag invalidateMorphMasks(); const bool force_render = false; renderMorphMasks(originX, originY, width, height, net_color, force_render); alphaData = getAlphaData(); } if (alphaData) { for( S32 i = 0; i < size; i++ ) { U8 curAlpha = data[i]; U16 resultAlpha = curAlpha; resultAlpha *= ( ((U16)alphaData[i]) + 1); resultAlpha = resultAlpha >> 8; data[i] = (U8)resultAlpha; } } } /*virtual*/ BOOL LLTexLayer::isInvisibleAlphaMask() const { if (mLocalTextureObject) { if (mLocalTextureObject->getID() == IMG_INVISIBLE) { return TRUE; } } return FALSE; } LLUUID LLTexLayer::getUUID() const { LLUUID uuid; if( getInfo()->mLocalTexture != -1 ) { LLGLTexture* tex = mLocalTextureObject->getImage(); if (tex) { uuid = mLocalTextureObject->getID(); } } if( !getInfo()->mStaticImageFileName.empty() ) { LLGLTexture* tex = LLTexLayerStaticImageList::getInstance()->getTexture(getInfo()->mStaticImageFileName, getInfo()->mStaticImageIsMask); if( tex ) { uuid = tex->getID(); } } return uuid; } //----------------------------------------------------------------------------- // LLTexLayerTemplate // A single texture layer, consisting of: // * color, consisting of either // * one or more color parameters (weighted colors) // * a reference to a global color // * a fixed color with non-zero alpha // * opaque white (the default) // * (optional) a texture defined by either // * a GUID // * a texture entry index (TE) // * (optional) one or more alpha parameters (weighted alpha textures) //----------------------------------------------------------------------------- LLTexLayerTemplate::LLTexLayerTemplate(LLTexLayerSet* layer_set, LLAvatarAppearance* const appearance) : LLTexLayerInterface(layer_set), mAvatarAppearance( appearance ) { } LLTexLayerTemplate::LLTexLayerTemplate(const LLTexLayerTemplate &layer) : LLTexLayerInterface(layer), mAvatarAppearance(layer.getAvatarAppearance()) { } LLTexLayerTemplate::~LLTexLayerTemplate() { } //----------------------------------------------------------------------------- // setInfo //----------------------------------------------------------------------------- /*virtual*/ BOOL LLTexLayerTemplate::setInfo(const LLTexLayerInfo* info, LLWearable* wearable ) { return LLTexLayerInterface::setInfo(info, wearable); } U32 LLTexLayerTemplate::updateWearableCache() const { mWearableCache.clear(); LLWearableType::EType wearable_type = getWearableType(); if (LLWearableType::WT_INVALID == wearable_type) { //this isn't a cloneable layer return 0; } U32 num_wearables = getAvatarAppearance()->getWearableData()->getWearableCount(wearable_type); U32 added = 0; for (U32 i = 0; i < num_wearables; i++) { LLWearable* wearable = getAvatarAppearance()->getWearableData()->getWearable(wearable_type, i); if (!wearable) { continue; } mWearableCache.push_back(wearable); added++; } return added; } LLTexLayer* LLTexLayerTemplate::getLayer(U32 i) const { if (mWearableCache.size() <= i) { return NULL; } LLWearable *wearable = mWearableCache[i]; LLLocalTextureObject *lto = NULL; LLTexLayer *layer = NULL; if (wearable) { lto = wearable->getLocalTextureObject(mInfo->mLocalTexture); } if (lto) { layer = lto->getTexLayer(getName()); } return layer; } /*virtual*/ BOOL LLTexLayerTemplate::render(S32 x, S32 y, S32 width, S32 height) { if(!mInfo) { return FALSE ; } BOOL success = TRUE; updateWearableCache(); for (wearable_cache_t::const_iterator iter = mWearableCache.begin(); iter!= mWearableCache.end(); iter++) { LLWearable* wearable = NULL; LLLocalTextureObject *lto = NULL; LLTexLayer *layer = NULL; wearable = *iter; if (wearable) { lto = wearable->getLocalTextureObject(mInfo->mLocalTexture); } if (lto) { layer = lto->getTexLayer(getName()); } if (layer) { wearable->writeToAvatar(mAvatarAppearance); layer->setLTO(lto); success &= layer->render(x,y,width,height); } } return success; } /*virtual*/ BOOL LLTexLayerTemplate::blendAlphaTexture( S32 x, S32 y, S32 width, S32 height) // Multiplies a single alpha texture against the frame buffer { BOOL success = TRUE; U32 num_wearables = updateWearableCache(); for (U32 i = 0; i < num_wearables; i++) { LLTexLayer *layer = getLayer(i); if (layer) { success &= layer->blendAlphaTexture(x,y,width,height); } } return success; } /*virtual*/ void LLTexLayerTemplate::gatherAlphaMasks(U8 *data, S32 originX, S32 originY, S32 width, S32 height) { U32 num_wearables = updateWearableCache(); U32 i = num_wearables - 1; // For rendering morph masks, we only want to use the top wearable LLTexLayer *layer = getLayer(i); if (layer) { layer->addAlphaMask(data, originX, originY, width, height); } } /*virtual*/ void LLTexLayerTemplate::setHasMorph(BOOL newval) { mHasMorph = newval; U32 num_wearables = updateWearableCache(); for (U32 i = 0; i < num_wearables; i++) { LLTexLayer *layer = getLayer(i); if (layer) { layer->setHasMorph(newval); } } } /*virtual*/ void LLTexLayerTemplate::deleteCaches() { U32 num_wearables = updateWearableCache(); for (U32 i = 0; i < num_wearables; i++) { LLTexLayer *layer = getLayer(i); if (layer) { layer->deleteCaches(); } } } /*virtual*/ BOOL LLTexLayerTemplate::isInvisibleAlphaMask() const { U32 num_wearables = updateWearableCache(); for (U32 i = 0; i < num_wearables; i++) { LLTexLayer *layer = getLayer(i); if (layer) { if (layer->isInvisibleAlphaMask()) { return TRUE; } } } return FALSE; } //----------------------------------------------------------------------------- // finds a specific layer based on a passed in name //----------------------------------------------------------------------------- LLTexLayerInterface* LLTexLayerSet::findLayerByName(const std::string& name) { for (layer_list_t::iterator iter = mLayerList.begin(); iter != mLayerList.end(); iter++ ) { LLTexLayerInterface* layer = *iter; if (layer->getName() == name) { return layer; } } for (layer_list_t::iterator iter = mMaskLayerList.begin(); iter != mMaskLayerList.end(); iter++ ) { LLTexLayerInterface* layer = *iter; if (layer->getName() == name) { return layer; } } return NULL; } void LLTexLayerSet::cloneTemplates(LLLocalTextureObject *lto, LLAvatarAppearanceDefines::ETextureIndex tex_index, LLWearable *wearable) { // initialize all texlayers with this texture type for this LTO for( LLTexLayerSet::layer_list_t::iterator iter = mLayerList.begin(); iter != mLayerList.end(); iter++ ) { LLTexLayerTemplate* layer = (LLTexLayerTemplate*)*iter; if (layer->getInfo()->getLocalTexture() == (S32) tex_index) { lto->addTexLayer(layer, wearable); } } for( LLTexLayerSet::layer_list_t::iterator iter = mMaskLayerList.begin(); iter != mMaskLayerList.end(); iter++ ) { LLTexLayerTemplate* layer = (LLTexLayerTemplate*)*iter; if (layer->getInfo()->getLocalTexture() == (S32) tex_index) { lto->addTexLayer(layer, wearable); } } } //----------------------------------------------------------------------------- // LLTexLayerStaticImageList //----------------------------------------------------------------------------- LLTexLayerStaticImageList::LLTexLayerStaticImageList() : mGLBytes(0), mTGABytes(0), mImageNames(16384) { } LLTexLayerStaticImageList::~LLTexLayerStaticImageList() { deleteCachedImages(); } void LLTexLayerStaticImageList::dumpByteCount() const { LL_INFOS() << "Avatar Static Textures " << "KB GL:" << (mGLBytes / 1024) << "KB TGA:" << (mTGABytes / 1024) << "KB" << LL_ENDL; } void LLTexLayerStaticImageList::deleteCachedImages() { if( mGLBytes || mTGABytes ) { LL_INFOS() << "Clearing Static Textures " << "KB GL:" << (mGLBytes / 1024) << "KB TGA:" << (mTGABytes / 1024) << "KB" << LL_ENDL; //mStaticImageLists uses LLPointers, clear() will cause deletion mStaticImageListTGA.clear(); mStaticImageList.clear(); mGLBytes = 0; mTGABytes = 0; } } // Note: in general, for a given image image we'll call either getImageTga() or getTexture(). // We call getImageTga() if the image is used as an alpha gradient. // Otherwise, we call getTexture() // Returns an LLImageTGA that contains the encoded data from a tga file named file_name. // Caches the result to speed identical subsequent requests. static LLTrace::BlockTimerStatHandle FTM_LOAD_STATIC_TGA("getImageTGA"); LLImageTGA* LLTexLayerStaticImageList::getImageTGA(const std::string& file_name) { LL_RECORD_BLOCK_TIME(FTM_LOAD_STATIC_TGA); const char *namekey = mImageNames.addString(file_name); image_tga_map_t::const_iterator iter = mStaticImageListTGA.find(namekey); if( iter != mStaticImageListTGA.end() ) { return iter->second; } else { std::string path; path = gDirUtilp->getExpandedFilename(LL_PATH_CHARACTER,file_name); LLPointer image_tga = new LLImageTGA( path ); if( image_tga->getDataSize() > 0 ) { mStaticImageListTGA[ namekey ] = image_tga; mTGABytes += image_tga->getDataSize(); return image_tga; } else { return NULL; } } } // Returns a GL Image (without a backing ImageRaw) that contains the decoded data from a tga file named file_name. // Caches the result to speed identical subsequent requests. static LLTrace::BlockTimerStatHandle FTM_LOAD_STATIC_TEXTURE("getTexture"); LLGLTexture* LLTexLayerStaticImageList::getTexture(const std::string& file_name, BOOL is_mask) { LL_RECORD_BLOCK_TIME(FTM_LOAD_STATIC_TEXTURE); LLPointer tex; const char *namekey = mImageNames.addString(file_name); texture_map_t::const_iterator iter = mStaticImageList.find(namekey); if( iter != mStaticImageList.end() ) { tex = iter->second; } else { llassert(gTextureManagerBridgep); tex = gTextureManagerBridgep->getLocalTexture( FALSE ); LLPointer image_raw = new LLImageRaw; if( loadImageRaw( file_name, image_raw ) ) { if( (image_raw->getComponents() == 1) && is_mask ) { // Convert grayscale alpha masks from single channel into RGBA. // Fill RGB with black to allow fixed function gl calls // to match shader implementation. LLPointer alpha_image_raw = image_raw; image_raw = new LLImageRaw(image_raw->getWidth(), image_raw->getHeight(), 4); image_raw->copyUnscaledAlphaMask(alpha_image_raw, LLColor4U::black); } tex->createGLTexture(0, image_raw, 0, TRUE, LLGLTexture::LOCAL); gGL.getTexUnit(0)->bind(tex); tex->setAddressMode(LLTexUnit::TAM_CLAMP); mStaticImageList [ namekey ] = tex; mGLBytes += (S32)tex->getWidth() * tex->getHeight() * tex->getComponents(); } else { tex = NULL; } } return tex; } // Reads a .tga file, decodes it, and puts the decoded data in image_raw. // Returns TRUE if successful. static LLTrace::BlockTimerStatHandle FTM_LOAD_IMAGE_RAW("loadImageRaw"); BOOL LLTexLayerStaticImageList::loadImageRaw(const std::string& file_name, LLImageRaw* image_raw) { LL_RECORD_BLOCK_TIME(FTM_LOAD_IMAGE_RAW); BOOL success = FALSE; std::string path; path = gDirUtilp->getExpandedFilename(LL_PATH_CHARACTER,file_name); LLPointer image_tga = new LLImageTGA( path ); if( image_tga->getDataSize() > 0 ) { // Copy data from tga to raw. success = image_tga->decode( image_raw ); } return success; }