//-----------------------------------------------------------------------------
// loadImage()
//-----------------------------------------------------------------------------
bool LLFloaterImagePreview::loadImage(const std::string& src_filename)
{
std::string exten = gDirUtilp->getExtension(src_filename);
U32 codec = LLImageBase::getCodecFromExtension(exten);
LLImageDimensionsInfo image_info;
if (!image_info.load(src_filename,codec))
{
mImageLoadError = image_info.getLastError();
return false;
}
S32 max_width = gSavedSettings.getS32("max_texture_dimension_X");
S32 max_height = gSavedSettings.getS32("max_texture_dimension_Y");
if ((image_info.getWidth() > max_width) || (image_info.getHeight() > max_height))
{
LLStringUtil::format_map_t args;
args["WIDTH"] = llformat("%d", max_width);
args["HEIGHT"] = llformat("%d", max_height);
mImageLoadError = LLTrans::getString("texture_load_dimensions_error", args);
return false;
}
// Load the image
LLPointer<LLImageFormatted> image = LLImageFormatted::createFromType(codec);
if (image.isNull())
{
return false;
}
if (!image->load(src_filename))
{
return false;
}
// Decompress or expand it in a raw image structure
LLPointer<LLImageRaw> raw_image = new LLImageRaw;
if (!image->decode(raw_image, 0.0f))
{
return false;
}
// Check the image constraints
if ((image->getComponents() != 3) && (image->getComponents() != 4))
{
image->setLastError("Image files with less than 3 or more than 4 components are not supported.");
return false;
}
raw_image->biasedScaleToPowerOfTwo(1024);
mRawImagep = raw_image;
return true;
}
BOOL LLViewerTextureList::createUploadFile(const std::string& filename,
const std::string& out_filename,
const U8 codec)
{
// Load the image
LLPointer<LLImageFormatted> image = LLImageFormatted::createFromType(codec);
if (image.isNull())
{
image->setLastError("Couldn't open the image to be uploaded.");
return FALSE;
}
if (!image->load(filename))
{
image->setLastError("Couldn't load the image to be uploaded.");
return FALSE;
}
// Decompress or expand it in a raw image structure
LLPointer<LLImageRaw> raw_image = new LLImageRaw;
if (!image->decode(raw_image, 0.0f))
{
image->setLastError("Couldn't decode the image to be uploaded.");
return FALSE;
}
// Check the image constraints
if ((image->getComponents() != 3) && (image->getComponents() != 4))
{
image->setLastError("Image files with less than 3 or more than 4 components are not supported.");
return FALSE;
}
// Convert to j2c (JPEG2000) and save the file locally
LLPointer<LLImageJ2C> compressedImage = convertToUploadFile(raw_image);
if (compressedImage.isNull())
{
image->setLastError("Couldn't convert the image to jpeg2000.");
llinfos << "Couldn't convert to j2c, file : " << filename << llendl;
return FALSE;
}
if (!compressedImage->save(out_filename))
{
image->setLastError("Couldn't create the jpeg2000 image for upload.");
llinfos << "Couldn't create output file : " << out_filename << llendl;
return FALSE;
}
// Test to see if the encode and save worked
LLPointer<LLImageJ2C> integrity_test = new LLImageJ2C;
if (!integrity_test->loadAndValidate( out_filename ))
{
image->setLastError("The created jpeg2000 image is corrupt.");
llinfos << "Image file : " << out_filename << " is corrupt" << llendl;
return FALSE;
}
return TRUE;
}
void output_image_stats(LLPointer<LLImageFormatted> image, const std::string &filename)
{
// Print out some statistical data on the image
std::cout << "Image stats for : " << filename << ", extension : " << image->getExtension() << std::endl;
std::cout << " with : " << (int)(image->getWidth()) << ", height : " << (int)(image->getHeight()) << std::endl;
std::cout << " comp : " << (int)(image->getComponents()) << ", levels : " << (int)(image->getDiscardLevel()) << std::endl;
std::cout << " head : " << (int)(image->calcHeaderSize()) << ", data : " << (int)(image->getDataSize()) << std::endl;
return;
}
// Load an image from file and return a raw (decompressed) instance of its data
LLPointer<LLImageRaw> load_image(const std::string &src_filename, int discard_level, int* region, bool output_stats)
{
LLPointer<LLImageFormatted> image = create_image(src_filename);
// This just loads the image file stream into a buffer. No decoding done.
if (!image->load(src_filename))
{
return NULL;
}
if( (image->getComponents() != 3) && (image->getComponents() != 4) )
{
std::cout << "Image files with less than 3 or more than 4 components are not supported\n";
return NULL;
}
if (output_stats)
{
output_image_stats(image, src_filename);
}
LLPointer<LLImageRaw> raw_image = new LLImageRaw;
// Set the image restriction on load in the case of a j2c image
if ((image->getCodec() == IMG_CODEC_J2C) && ((discard_level != -1) || (region != NULL)))
{
// That method doesn't exist (and likely, doesn't make sense) for any other image file format
// hence the required cryptic cast.
((LLImageJ2C*)(image.get()))->initDecode(*raw_image, discard_level, region);
}
if (!image->decode(raw_image, 0.0f))
{
return NULL;
}
return raw_image;
}
// virtual
void LLFloaterTexturePicker::draw()
{
S32 floater_header_size = getHeaderHeight();
if (mOwner)
{
// draw cone of context pointing back to texture swatch
LLRect owner_rect;
mOwner->localRectToOtherView(mOwner->getLocalRect(), &owner_rect, this);
LLRect local_rect = getLocalRect();
if (gFocusMgr.childHasKeyboardFocus(this) && mOwner->isInVisibleChain() && mContextConeOpacity > 0.001f)
{
gGL.getTexUnit(0)->unbind(LLTexUnit::TT_TEXTURE);
LLGLEnable(GL_CULL_FACE);
gGL.begin(LLRender::QUADS);
{
gGL.color4f(0.f, 0.f, 0.f, CONTEXT_CONE_IN_ALPHA * mContextConeOpacity);
gGL.vertex2i(owner_rect.mLeft, owner_rect.mTop);
gGL.vertex2i(owner_rect.mRight, owner_rect.mTop);
gGL.color4f(0.f, 0.f, 0.f, CONTEXT_CONE_OUT_ALPHA * mContextConeOpacity);
gGL.vertex2i(local_rect.mRight, local_rect.mTop);
gGL.vertex2i(local_rect.mLeft, local_rect.mTop);
gGL.color4f(0.f, 0.f, 0.f, CONTEXT_CONE_OUT_ALPHA * mContextConeOpacity);
gGL.vertex2i(local_rect.mLeft, local_rect.mTop);
gGL.vertex2i(local_rect.mLeft, local_rect.mBottom);
gGL.color4f(0.f, 0.f, 0.f, CONTEXT_CONE_IN_ALPHA * mContextConeOpacity);
gGL.vertex2i(owner_rect.mLeft, owner_rect.mBottom);
gGL.vertex2i(owner_rect.mLeft, owner_rect.mTop);
gGL.color4f(0.f, 0.f, 0.f, CONTEXT_CONE_OUT_ALPHA * mContextConeOpacity);
gGL.vertex2i(local_rect.mRight, local_rect.mBottom);
gGL.vertex2i(local_rect.mRight, local_rect.mTop);
gGL.color4f(0.f, 0.f, 0.f, CONTEXT_CONE_IN_ALPHA * mContextConeOpacity);
gGL.vertex2i(owner_rect.mRight, owner_rect.mTop);
gGL.vertex2i(owner_rect.mRight, owner_rect.mBottom);
gGL.color4f(0.f, 0.f, 0.f, CONTEXT_CONE_OUT_ALPHA * mContextConeOpacity);
gGL.vertex2i(local_rect.mLeft, local_rect.mBottom);
gGL.vertex2i(local_rect.mRight, local_rect.mBottom);
gGL.color4f(0.f, 0.f, 0.f, CONTEXT_CONE_IN_ALPHA * mContextConeOpacity);
gGL.vertex2i(owner_rect.mRight, owner_rect.mBottom);
gGL.vertex2i(owner_rect.mLeft, owner_rect.mBottom);
}
gGL.end();
}
}
if (gFocusMgr.childHasMouseCapture(getDragHandle()))
{
mContextConeOpacity = lerp(mContextConeOpacity, gSavedSettings.getF32("PickerContextOpacity"), LLCriticalDamp::getInterpolant(CONTEXT_FADE_TIME));
}
else
{
mContextConeOpacity = lerp(mContextConeOpacity, 0.f, LLCriticalDamp::getInterpolant(CONTEXT_FADE_TIME));
}
updateImageStats();
// if we're inactive, gray out "apply immediate" checkbox
getChildView("show_folders_check")->setEnabled(mActive && mCanApplyImmediately && !mNoCopyTextureSelected);
getChildView("Select")->setEnabled(mActive);
getChildView("Pipette")->setEnabled(mActive);
getChild<LLUICtrl>("Pipette")->setValue(LLToolMgr::getInstance()->getCurrentTool() == LLToolPipette::getInstance());
//BOOL allow_copy = FALSE;
if( mOwner )
{
mTexturep = NULL;
if(mImageAssetID.notNull())
{
mTexturep = LLViewerTextureManager::getFetchedTexture(mImageAssetID, MIPMAP_YES);
mTexturep->setBoostLevel(LLViewerTexture::BOOST_PREVIEW);
}
if (mTentativeLabel)
{
mTentativeLabel->setVisible( FALSE );
}
getChildView("Default")->setEnabled(mImageAssetID != mOwner->getDefaultImageAssetID());
getChildView("Blank")->setEnabled(mImageAssetID != mWhiteImageAssetID );
getChildView("None")->setEnabled(mOwner->getAllowNoTexture() && !mImageAssetID.isNull() );
LLFloater::draw();
if( isMinimized() )
{
return;
}
// Border
LLRect border( BORDER_PAD,
getRect().getHeight() - floater_header_size - BORDER_PAD,
((getMinWidth() / 2) - TEXTURE_INVENTORY_PADDING - HPAD) - BORDER_PAD,
BORDER_PAD + FOOTER_HEIGHT + (getRect().getHeight() - getMinHeight()));
gl_rect_2d( border, LLColor4::black, FALSE );
// Interior
LLRect interior = border;
interior.stretch( -1 );
// If the floater is focused, don't apply its alpha to the texture (STORM-677).
const F32 alpha = getTransparencyType() == TT_ACTIVE ? 1.0f : getCurrentTransparency();
if( mTexturep )
{
if( mTexturep->getComponents() == 4 )
{
gl_rect_2d_checkerboard( interior, alpha );
}
gl_draw_scaled_image( interior.mLeft, interior.mBottom, interior.getWidth(), interior.getHeight(), mTexturep, UI_VERTEX_COLOR % alpha );
// Pump the priority
mTexturep->addTextureStats( (F32)(interior.getWidth() * interior.getHeight()) );
}
else if (!mFallbackImage.isNull())
{
mFallbackImage->draw(interior, UI_VERTEX_COLOR % alpha);
}
else
{
gl_rect_2d( interior, LLColor4::grey % alpha, TRUE );
// Draw X
gl_draw_x(interior, LLColor4::black );
}
// Draw Tentative Label over the image
if( mOwner->getTentative() && !mViewModel->isDirty() )
{
mTentativeLabel->setVisible( TRUE );
drawChild(mTentativeLabel);
}
if (mSelectedItemPinned) return;
LLFolderView* folder_view = mInventoryPanel->getRootFolder();
if (!folder_view) return;
LLInventoryFilter* filter = folder_view->getFilter();
if (!filter) return;
bool is_filter_active = folder_view->getCompletedFilterGeneration() < filter->getCurrentGeneration() &&
filter->isNotDefault();
// After inventory panel filter is applied we have to update
// constraint rect for the selected item because of folder view
// AutoSelectOverride set to TRUE. We force PinningSelectedItem
// flag to FALSE state and setting filter "dirty" to update
// scroll container to show selected item (see LLFolderView::doIdle()).
if (!is_filter_active && !mSelectedItemPinned)
{
folder_view->setPinningSelectedItem(mSelectedItemPinned);
folder_view->dirtyFilter();
folder_view->arrangeFromRoot();
mSelectedItemPinned = TRUE;
}
}
}
// virtual
void LLFloaterTexturePicker::draw()
{
if (mOwner)
{
// draw cone of context pointing back to texture swatch
LLRect owner_rect;
mOwner->localRectToOtherView(mOwner->getLocalRect(), &owner_rect, this);
LLRect local_rect = getLocalRect();
if (gFocusMgr.childHasKeyboardFocus(this) && mOwner->isInVisibleChain() && mContextConeOpacity > 0.001f)
{
gGL.getTexUnit(0)->unbind(LLTexUnit::TT_TEXTURE);
LLGLEnable(GL_CULL_FACE);
gGL.begin(LLRender::QUADS);
{
gGL.color4f(0.f, 0.f, 0.f, CONTEXT_CONE_IN_ALPHA * mContextConeOpacity);
gGL.vertex2i(owner_rect.mLeft, owner_rect.mTop);
gGL.vertex2i(owner_rect.mRight, owner_rect.mTop);
gGL.color4f(0.f, 0.f, 0.f, CONTEXT_CONE_OUT_ALPHA * mContextConeOpacity);
gGL.vertex2i(local_rect.mRight, local_rect.mTop);
gGL.vertex2i(local_rect.mLeft, local_rect.mTop);
gGL.color4f(0.f, 0.f, 0.f, CONTEXT_CONE_OUT_ALPHA * mContextConeOpacity);
gGL.vertex2i(local_rect.mLeft, local_rect.mTop);
gGL.vertex2i(local_rect.mLeft, local_rect.mBottom);
gGL.color4f(0.f, 0.f, 0.f, CONTEXT_CONE_IN_ALPHA * mContextConeOpacity);
gGL.vertex2i(owner_rect.mLeft, owner_rect.mBottom);
gGL.vertex2i(owner_rect.mLeft, owner_rect.mTop);
gGL.color4f(0.f, 0.f, 0.f, CONTEXT_CONE_OUT_ALPHA * mContextConeOpacity);
gGL.vertex2i(local_rect.mRight, local_rect.mBottom);
gGL.vertex2i(local_rect.mRight, local_rect.mTop);
gGL.color4f(0.f, 0.f, 0.f, CONTEXT_CONE_IN_ALPHA * mContextConeOpacity);
gGL.vertex2i(owner_rect.mRight, owner_rect.mTop);
gGL.vertex2i(owner_rect.mRight, owner_rect.mBottom);
gGL.color4f(0.f, 0.f, 0.f, CONTEXT_CONE_OUT_ALPHA * mContextConeOpacity);
gGL.vertex2i(local_rect.mLeft, local_rect.mBottom);
gGL.vertex2i(local_rect.mRight, local_rect.mBottom);
gGL.color4f(0.f, 0.f, 0.f, CONTEXT_CONE_IN_ALPHA * mContextConeOpacity);
gGL.vertex2i(owner_rect.mRight, owner_rect.mBottom);
gGL.vertex2i(owner_rect.mLeft, owner_rect.mBottom);
}
gGL.end();
}
}
if (gFocusMgr.childHasMouseCapture(getDragHandle()))
{
mContextConeOpacity = lerp(mContextConeOpacity, gSavedSettings.getF32("PickerContextOpacity"), LLCriticalDamp::getInterpolant(CONTEXT_FADE_TIME));
}
else
{
mContextConeOpacity = lerp(mContextConeOpacity, 0.f, LLCriticalDamp::getInterpolant(CONTEXT_FADE_TIME));
}
updateImageStats();
// if we're inactive, gray out "apply immediate" checkbox
childSetEnabled("show_folders_check", mActive && mCanApplyImmediately && !mNoCopyTextureSelected);
childSetEnabled("Select", mActive);
childSetEnabled("Pipette", mActive);
childSetValue("Pipette", LLToolMgr::getInstance()->getCurrentTool() == LLToolPipette::getInstance());
//RN: reset search bar to reflect actual search query (all caps, for example)
mSearchEdit->setText(mInventoryPanel->getFilterSubString());
//BOOL allow_copy = FALSE;
if( mOwner )
{
mTexturep = NULL;
if(mImageAssetID.notNull())
{
mTexturep = LLViewerTextureManager::getFetchedTexture(mImageAssetID, MIPMAP_YES, LLViewerTexture::BOOST_PREVIEW);
}
else if (!mFallbackImageName.empty())
{
mTexturep = LLViewerTextureManager::getFetchedTextureFromFile(mFallbackImageName, MIPMAP_YES, LLViewerTexture::BOOST_PREVIEW);
}
if (mTentativeLabel)
{
mTentativeLabel->setVisible( FALSE );
}
childSetEnabled("Default", mImageAssetID != mOwner->getDefaultImageAssetID());
childSetEnabled("Blank", mImageAssetID != mWhiteImageAssetID );
childSetEnabled("Invisible", mOwner->getAllowInvisibleTexture() && mImageAssetID != mInvisibleImageAssetID );
childSetEnabled("Alpha", mImageAssetID != mAlphaImageAssetID );
LLFloater::draw();
if( isMinimized() )
{
return;
}
// Border
LLRect border( BORDER_PAD,
getRect().getHeight() - LLFLOATER_HEADER_SIZE - BORDER_PAD,
((TEX_PICKER_MIN_WIDTH / 2) - TEXTURE_INVENTORY_PADDING - HPAD) - BORDER_PAD,
BORDER_PAD + FOOTER_HEIGHT + (getRect().getHeight() - TEX_PICKER_MIN_HEIGHT));
gl_rect_2d( border, LLColor4::black, FALSE );
// Interior
LLRect interior = border;
interior.stretch( -1 );
if( mTexturep )
{
if( mTexturep->getComponents() == 4 )
{
gl_rect_2d_checkerboard( interior );
}
gl_draw_scaled_image( interior.mLeft, interior.mBottom, interior.getWidth(), interior.getHeight(), mTexturep );
// Pump the priority
mTexturep->addTextureStats( (F32)(interior.getWidth() * interior.getHeight()) );
// Draw Tentative Label over the image
if( mOwner->getTentative() && !mIsDirty )
{
mTentativeLabel->setVisible( TRUE );
drawChild(mTentativeLabel);
}
}
else
{
gl_rect_2d( interior, LLColor4::grey, TRUE );
// Draw X
gl_draw_x(interior, LLColor4::black );
}
}
}
// virtual
void LLFloaterTexturePicker::draw()
{
if (mOwner)
{
// draw cone of context pointing back to texture swatch
LLRect owner_rect;
mOwner->localRectToOtherView(mOwner->getLocalRect(), &owner_rect, this);
LLRect local_rect = getLocalRect();
if (gFocusMgr.childHasKeyboardFocus(this) && mOwner->isInVisibleChain() && mContextConeOpacity > 0.001f)
{
gGL.getTexUnit(0)->unbind(LLTexUnit::TT_TEXTURE);
LLGLEnable(GL_CULL_FACE);
gGL.begin(LLRender::TRIANGLE_STRIP);
{
gGL.color4f(0.f, 0.f, 0.f, CONTEXT_CONE_OUT_ALPHA * mContextConeOpacity);
gGL.vertex2i(local_rect.mLeft, local_rect.mTop);
gGL.color4f(0.f, 0.f, 0.f, CONTEXT_CONE_IN_ALPHA * mContextConeOpacity);
gGL.vertex2i(owner_rect.mLeft, owner_rect.mTop);
gGL.color4f(0.f, 0.f, 0.f, CONTEXT_CONE_OUT_ALPHA * mContextConeOpacity);
gGL.vertex2i(local_rect.mRight, local_rect.mTop);
gGL.color4f(0.f, 0.f, 0.f, CONTEXT_CONE_IN_ALPHA * mContextConeOpacity);
gGL.vertex2i(owner_rect.mRight, owner_rect.mTop);
gGL.color4f(0.f, 0.f, 0.f, CONTEXT_CONE_OUT_ALPHA * mContextConeOpacity);
gGL.vertex2i(local_rect.mRight, local_rect.mBottom);
gGL.color4f(0.f, 0.f, 0.f, CONTEXT_CONE_IN_ALPHA * mContextConeOpacity);
gGL.vertex2i(owner_rect.mRight, owner_rect.mBottom);
gGL.color4f(0.f, 0.f, 0.f, CONTEXT_CONE_OUT_ALPHA * mContextConeOpacity);
gGL.vertex2i(local_rect.mLeft, local_rect.mBottom);
gGL.color4f(0.f, 0.f, 0.f, CONTEXT_CONE_IN_ALPHA * mContextConeOpacity);
gGL.vertex2i(owner_rect.mLeft, owner_rect.mBottom);
gGL.color4f(0.f, 0.f, 0.f, CONTEXT_CONE_OUT_ALPHA * mContextConeOpacity);
gGL.vertex2i(local_rect.mLeft, local_rect.mTop);
gGL.color4f(0.f, 0.f, 0.f, CONTEXT_CONE_IN_ALPHA * mContextConeOpacity);
gGL.vertex2i(owner_rect.mLeft, owner_rect.mTop);
}
gGL.end();
}
}
if (gFocusMgr.childHasMouseCapture(getDragHandle()))
{
mContextConeOpacity = lerp(mContextConeOpacity, gSavedSettings.getF32("PickerContextOpacity"), LLSmoothInterpolation::getInterpolant(CONTEXT_FADE_TIME));
}
else
{
mContextConeOpacity = lerp(mContextConeOpacity, 0.f, LLSmoothInterpolation::getInterpolant(CONTEXT_FADE_TIME));
}
updateImageStats();
// if we're inactive, gray out "apply immediate" checkbox
getChildView("show_folders_check")->setEnabled(mActive && mCanApplyImmediately && !mNoCopyTextureSelected);
getChildView("Select")->setEnabled(mActive && mCanApply);
getChildView("Pipette")->setEnabled(mActive);
getChild<LLUICtrl>("Pipette")->setValue(LLToolMgr::getInstance()->getCurrentTool() == LLToolPipette::getInstance());
//RN: reset search bar to reflect actual search query (all caps, for example)
mFilterEdit->setText(mInventoryPanel->getFilterSubString());
//BOOL allow_copy = FALSE;
if( mOwner )
{
mTexturep = NULL;
if(mImageAssetID.notNull())
{
mTexturep = LLViewerTextureManager::getFetchedTexture(mImageAssetID, FTT_DEFAULT, MIPMAP_YES, LLGLTexture::BOOST_PREVIEW);
}
else if (!mFallbackImageName.empty())
{
mTexturep = LLViewerTextureManager::getFetchedTextureFromFile(mFallbackImageName, FTT_LOCAL_FILE, MIPMAP_YES, LLGLTexture::BOOST_PREVIEW);
}
if (mTentativeLabel)
{
mTentativeLabel->setVisible( FALSE );
}
getChildView("Default")->setEnabled(mImageAssetID != mOwner->getDefaultImageAssetID());
getChildView("Blank")->setEnabled(mImageAssetID != mWhiteImageAssetID);
getChildView("None")->setEnabled(mOwner->getAllowNoTexture() && !mImageAssetID.isNull() );
getChildView("Invisible")->setEnabled(mOwner->getAllowInvisibleTexture() && mImageAssetID != mInvisibleImageAssetID);
getChildView("Alpha")->setEnabled(mImageAssetID != mAlphaImageAssetID);
LLFloater::draw();
if( isMinimized() )
{
return;
}
// Border
LLRect border( BORDER_PAD,
getRect().getHeight() - LLFLOATER_HEADER_SIZE - BORDER_PAD,
((TEX_PICKER_MIN_WIDTH / 2) - TEXTURE_INVENTORY_PADDING - HPAD) - BORDER_PAD,
BORDER_PAD + FOOTER_HEIGHT + (getRect().getHeight() - TEX_PICKER_MIN_HEIGHT));
gl_rect_2d( border, LLColor4::black, FALSE );
// Interior
LLRect interior = border;
interior.stretch( -1 );
if( mTexturep )
{
if( mTexturep->getComponents() == 4 )
{
gl_rect_2d_checkerboard( calcScreenRect(), interior );
}
gl_draw_scaled_image( interior.mLeft, interior.mBottom, interior.getWidth(), interior.getHeight(), mTexturep );
// Pump the priority
mTexturep->addTextureStats( (F32)(interior.getWidth() * interior.getHeight()) );
// Draw Tentative Label over the image
if( mOwner->getTentative() && !mIsDirty )
{
mTentativeLabel->setVisible( TRUE );
drawChild(mTentativeLabel);
}
}
else
{
gl_rect_2d( interior, LLColor4::grey, TRUE );
// Draw X
gl_draw_x(interior, LLColor4::black );
}
if (mSelectedItemPinned) return;
LLFolderView* folder_view = mInventoryPanel->getRootFolder();
if (!folder_view) return;
LLInventoryFilter* filter = folder_view->getFilter();
if (!filter) return;
bool is_filter_active = folder_view->getCompletedFilterGeneration() < filter->getCurrentGeneration() &&
filter->isNotDefault();
// After inventory panel filter is applied we have to update
// constraint rect for the selected item because of folder view
// AutoSelectOverride set to TRUE. We force PinningSelectedItem
// flag to FALSE state and setting filter "dirty" to update
// scroll container to show selected item (see LLFolderView::doIdle()).
if (!is_filter_active && !mSelectedItemPinned)
{
folder_view->setPinningSelectedItem(mSelectedItemPinned);
folder_view->dirtyFilter();
folder_view->arrangeFromRoot();
mSelectedItemPinned = TRUE;
}
}
}
// Load an image from file and return a raw (decompressed) instance of its data
LLPointer<LLImageRaw> load_image(const std::string &src_filename, int discard_level, int* region, int load_size, bool output_stats)
{
LLPointer<LLImageFormatted> image = create_image(src_filename);
// We support partial loading only for j2c images
if (image->getCodec() == IMG_CODEC_J2C)
{
// Load the header
if (!image->load(src_filename, 600))
{
return NULL;
}
S32 h = ((LLImageJ2C*)(image.get()))->calcHeaderSize();
S32 d = (load_size > 0 ? ((LLImageJ2C*)(image.get()))->calcDiscardLevelBytes(load_size) : 0);
S8 r = ((LLImageJ2C*)(image.get()))->getRawDiscardLevel();
std::cout << "Merov debug : header = " << h << ", load_size = " << load_size << ", discard level = " << d << ", raw discard level = " << r << std::endl;
for (d = 0; d < MAX_DISCARD_LEVEL; d++)
{
S32 data_size = ((LLImageJ2C*)(image.get()))->calcDataSize(d);
std::cout << "Merov debug : discard_level = " << d << ", data_size = " << data_size << std::endl;
}
if (load_size < 0)
{
load_size = (discard_level != -1 ? ((LLImageJ2C*)(image.get()))->calcDataSize(discard_level) : 0);
}
// Load the requested byte range
if (!image->load(src_filename, load_size))
{
return NULL;
}
}
else
{
// This just loads the image file stream into a buffer. No decoding done.
if (!image->load(src_filename))
{
return NULL;
}
}
if( (image->getComponents() != 3) && (image->getComponents() != 4) )
{
std::cout << "Image files with less than 3 or more than 4 components are not supported\n";
return NULL;
}
if (output_stats)
{
output_image_stats(image, src_filename);
}
LLPointer<LLImageRaw> raw_image = new LLImageRaw;
// Set the image restriction on load in the case of a j2c image
if ((image->getCodec() == IMG_CODEC_J2C) && ((discard_level != -1) || (region != NULL)))
{
// That method doesn't exist (and likely, doesn't make sense) for any other image file format
// hence the required cryptic cast.
((LLImageJ2C*)(image.get()))->initDecode(*raw_image, discard_level, region);
}
if (!image->decode(raw_image, 0.0f))
{
return NULL;
}
return raw_image;
}
