// Save a raw image instance into a file
bool save_image(const std::string &dest_filename, LLPointer<LLImageRaw> raw_image, int blocks_size, int precincts_size, int levels, bool reversible, bool output_stats)
{
LLPointer<LLImageFormatted> image = create_image(dest_filename);
// Set the image codestream parameters on output in the case of a j2c image
if (image->getCodec() == IMG_CODEC_J2C)
{
// That method doesn't exist (and likely, doesn't make sense) for any other image file format
// hence the required cryptic cast.
if ((blocks_size != -1) || (precincts_size != -1) || (levels != 0))
{
((LLImageJ2C*)(image.get()))->initEncode(*raw_image, blocks_size, precincts_size, levels);
}
((LLImageJ2C*)(image.get()))->setReversible(reversible);
}
if (!image->encode(raw_image, 0.0f))
{
return false;
}
if (output_stats)
{
output_image_stats(image, dest_filename);
}
return image->save(dest_filename);
}
static void processForeignLandmark(LLLandmark* landmark,
const LLUUID& object_id, const LLUUID& notecard_inventory_id,
LLPointer<LLInventoryItem> item_ptr)
{
LLVector3d global_pos;
landmark->getGlobalPos(global_pos);
LLViewerInventoryItem* agent_landmark =
LLLandmarkActions::findLandmarkForGlobalPos(global_pos);
if (agent_landmark)
{
showInfo(agent_landmark->getUUID());
}
else
{
if (item_ptr.isNull())
{
// check to prevent a crash. See EXT-8459.
LL_WARNS() << "Passed handle contains a dead inventory item. Most likely notecard has been closed and embedded item was destroyed." << LL_ENDL;
}
else
{
LLInventoryItem* item = item_ptr.get();
LLPointer<LLEmbeddedLandmarkCopied> cb = new LLEmbeddedLandmarkCopied();
copy_inventory_from_notecard(get_folder_by_itemtype(item),
object_id,
notecard_inventory_id,
item,
gInventoryCallbacks.registerCB(cb));
}
}
}
// allocate the stack
LLWorld::LLWorld() :
mLandFarClip(DEFAULT_FAR_PLANE),
mLastPacketsIn(0),
mLastPacketsOut(0),
mLastPacketsLost(0),
mSpaceTimeUSec(0)
{
for (S32 i = 0; i < 8; i++)
{
mEdgeWaterObjects[i] = NULL;
}
if (gNoRender)
{
return;
}
LLPointer<LLImageRaw> raw = new LLImageRaw(1,1,4);
U8 *default_texture = raw->getData();
*(default_texture++) = MAX_WATER_COLOR.mV[0];
*(default_texture++) = MAX_WATER_COLOR.mV[1];
*(default_texture++) = MAX_WATER_COLOR.mV[2];
*(default_texture++) = MAX_WATER_COLOR.mV[3];
mDefaultWaterTexturep = LLViewerTextureManager::getLocalTexture(raw.get(), FALSE);
gGL.getTexUnit(0)->bind(mDefaultWaterTexturep);
mDefaultWaterTexturep->setAddressMode(LLTexUnit::TAM_CLAMP);
}
// Note: the caller SHOULD NOT keep the pointer that this function returns. It may be updated as more data arrives.
LLViewerTexture* LLBumpImageList::getBrightnessDarknessImage(LLViewerFetchedTexture* src_image, U8 bump_code )
{
llassert( (bump_code == BE_BRIGHTNESS) || (bump_code == BE_DARKNESS) );
LLViewerTexture* bump = NULL;
bump_image_map_t* entries_list = NULL;
void (*callback_func)( BOOL success, LLViewerFetchedTexture *src_vi, LLImageRaw* src, LLImageRaw* aux_src, S32 discard_level, BOOL final, void* userdata ) = NULL;
switch( bump_code )
{
case BE_BRIGHTNESS:
entries_list = &mBrightnessEntries;
callback_func = LLBumpImageList::onSourceBrightnessLoaded;
break;
case BE_DARKNESS:
entries_list = &mDarknessEntries;
callback_func = LLBumpImageList::onSourceDarknessLoaded;
break;
default:
llassert(0);
return NULL;
}
bump_image_map_t::iterator iter = entries_list->find(src_image->getID());
if (iter != entries_list->end() && iter->second.notNull())
{
bump = iter->second;
}
else
{
LLPointer<LLImageRaw> raw = new LLImageRaw(1,1,1);
raw->clear(0x77, 0x77, 0xFF, 0xFF);
(*entries_list)[src_image->getID()] = LLViewerTextureManager::getLocalTexture( raw.get(), TRUE);
bump = (*entries_list)[src_image->getID()]; // In case callback was called immediately and replaced the image
}
if (!src_image->hasCallbacks())
{ //if image has no callbacks but resolutions don't match, trigger raw image loaded callback again
if (src_image->getWidth() != bump->getWidth() ||
src_image->getHeight() != bump->getHeight())// ||
//(LLPipeline::sRenderDeferred && bump->getComponents() != 4))
{
src_image->setBoostLevel(LLGLTexture::BOOST_BUMP) ;
src_image->setLoadedCallback( callback_func, 0, TRUE, FALSE, new LLUUID(src_image->getID()), NULL );
src_image->forceToSaveRawImage(0) ;
}
}
return bump;
}
void LLCallFloater::initParticipantsVoiceState()
{
// Set initial status for each participant in the list.
std::vector<LLPanel*> items;
mAvatarList->getItems(items);
std::vector<LLPanel*>::const_iterator
it = items.begin(),
it_end = items.end();
uuid_vec_t speakers_uuids;
get_voice_participants_uuids(speakers_uuids);
for(; it != it_end; ++it)
{
LLAvatarListItem *item = dynamic_cast<LLAvatarListItem*>(*it);
if (!item) continue;
LLUUID speaker_id = item->getAvatarId();
uuid_vec_t::const_iterator speaker_iter = std::find(speakers_uuids.begin(), speakers_uuids.end(), speaker_id);
// If an avatarID assigned to a panel is found in a speakers list
// obtained from VoiceClient we assign the JOINED status to the owner
// of this avatarID.
if (speaker_iter != speakers_uuids.end())
{
setState(item, STATE_JOINED);
}
else
{
LLPointer<LLSpeaker> speakerp = mSpeakerManager->findSpeaker(speaker_id);
// If someone has already left the call before, we create his
// avatar row panel with HAS_LEFT status and remove it after
// the timeout, otherwise we create a panel with INVITED status
if (speakerp.notNull() && speakerp.get()->mHasLeftCurrentCall)
{
setState(item, STATE_LEFT);
}
else
{
setState(item, STATE_INVITED);
}
}
}
}
static void processForeignLandmark(LLLandmark* landmark,
const LLUUID& object_id, const LLUUID& notecard_inventory_id,
LLPointer<LLInventoryItem> item_ptr)
{
LLVector3d global_pos;
landmark->getGlobalPos(global_pos);
LLViewerInventoryItem* agent_landmark =
LLLandmarkActions::findLandmarkForGlobalPos(global_pos);
if (agent_landmark)
{
showInfo(agent_landmark->getUUID());
}
// else
// [SL:KB] - Patch: UI-Notecards | Checked: 2010-09-05 (Catznip-2.1.2a) | Added: Catznip-2.1.2a
else if (gSavedSettings.getBOOL("EmbeddedLandmarkCopyToInventory"))
// [/SL:KB]
{
if (item_ptr.isNull())
{
// check to prevent a crash. See EXT-8459.
llwarns << "Passed handle contains a dead inventory item. Most likely notecard has been closed and embedded item was destroyed." << llendl;
}
else
{
LLInventoryItem* item = item_ptr.get();
LLPointer<LLEmbeddedLandmarkCopied> cb = new LLEmbeddedLandmarkCopied();
copy_inventory_from_notecard(get_folder_by_itemtype(item),
object_id,
notecard_inventory_id,
item,
gInventoryCallbacks.registerCB(cb));
}
}
// [SL:KB] - Patch: UI-Notecards | Checked: 2010-09-05 (Catznip-2.1.2a) | Added: Catznip-2.1.2a
else
{
showInfo(global_pos);
}
// [/SL:KB]
}
// 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;
}
void LLSurface::createSTexture()
{
if (!mSTexturep)
{
// Fill with dummy gray data.
LLPointer<LLImageRaw> raw = new LLImageRaw(sTextureSize, sTextureSize, 3);
U8 *default_texture = raw->getData();
for (S32 i = 0; i < sTextureSize; i++)
{
for (S32 j = 0; j < sTextureSize; j++)
{
*(default_texture + (i*sTextureSize + j)*3) = 128;
*(default_texture + (i*sTextureSize + j)*3 + 1) = 128;
*(default_texture + (i*sTextureSize + j)*3 + 2) = 128;
}
}
mSTexturep = LLViewerTextureManager::getLocalTexture(raw.get(), FALSE);
mSTexturep->dontDiscard();
gGL.getTexUnit(0)->bind(mSTexturep);
mSTexturep->setAddressMode(LLTexUnit::TAM_CLAMP);
}
}
void LLSurface::createWaterTexture()
{
if (!mWaterTexturep)
{
// Create the water texture
LLPointer<LLImageRaw> raw = new LLImageRaw(sTextureSize/2, sTextureSize/2, 4);
U8 *default_texture = raw->getData();
for (S32 i = 0; i < sTextureSize/2; i++)
{
for (S32 j = 0; j < sTextureSize/2; j++)
{
*(default_texture + (i*sTextureSize/2 + j)*4) = MAX_WATER_COLOR.mV[0];
*(default_texture + (i*sTextureSize/2 + j)*4 + 1) = MAX_WATER_COLOR.mV[1];
*(default_texture + (i*sTextureSize/2 + j)*4 + 2) = MAX_WATER_COLOR.mV[2];
*(default_texture + (i*sTextureSize/2 + j)*4 + 3) = MAX_WATER_COLOR.mV[3];
}
}
mWaterTexturep = LLViewerTextureManager::getLocalTexture(raw.get(), FALSE);
mWaterTexturep->dontDiscard();
gGL.getTexUnit(0)->bind(mWaterTexturep);
mWaterTexturep->setAddressMode(LLTexUnit::TAM_CLAMP);
}
}
void render_disconnected_background()
{
if (!gDisconnectedImagep && gDisconnected)
{
llinfos << "Loading last bitmap..." << llendl;
std::string temp_str;
temp_str = gDirUtilp->getLindenUserDir() + gDirUtilp->getDirDelimiter() + SCREEN_LAST_FILENAME;
LLPointer<LLImageBMP> image_bmp = new LLImageBMP;
if( !image_bmp->load(temp_str) )
{
//llinfos << "Bitmap load failed" << llendl;
return;
}
LLPointer<LLImageRaw> raw = new LLImageRaw;
if (!image_bmp->decode(raw, 0.0f))
{
llinfos << "Bitmap decode failed" << llendl;
gDisconnectedImagep = NULL;
return;
}
U8 *rawp = raw->getData();
S32 npixels = (S32)image_bmp->getWidth()*(S32)image_bmp->getHeight();
for (S32 i = 0; i < npixels; i++)
{
S32 sum = 0;
sum = *rawp + *(rawp+1) + *(rawp+2);
sum /= 3;
*rawp = ((S32)sum*6 + *rawp)/7;
rawp++;
*rawp = ((S32)sum*6 + *rawp)/7;
rawp++;
*rawp = ((S32)sum*6 + *rawp)/7;
rawp++;
}
raw->expandToPowerOfTwo();
gDisconnectedImagep = LLViewerTextureManager::getLocalTexture(raw.get(), FALSE );
gStartTexture = gDisconnectedImagep;
}
// Make sure the progress view always fills the entire window.
S32 width = gViewerWindow->getWindowWidthScaled();
S32 height = gViewerWindow->getWindowHeightScaled();
if (gDisconnectedImagep)
{
if (LLGLSLShader::sNoFixedFunction)
{
gUIProgram.bind();
}
LLGLSUIDefault gls_ui;
gViewerWindow->setup2DRender();
gGL.pushMatrix();
{
// scale ui to reflect UIScaleFactor
// this can't be done in setup2DRender because it requires a
// pushMatrix/popMatrix pair
const LLVector2& display_scale = gViewerWindow->getDisplayScale();
gGL.scalef(display_scale.mV[VX], display_scale.mV[VY], 1.f);
gGL.getTexUnit(0)->bind(gDisconnectedImagep);
gGL.color4f(1.f, 1.f, 1.f, 1.f);
gl_rect_2d_simple_tex(width, height);
gGL.getTexUnit(0)->unbind(LLTexUnit::TT_TEXTURE);
}
gGL.popMatrix();
gGL.flush();
if (LLGLSLShader::sNoFixedFunction)
{
gUIProgram.unbind();
}
}
}
// static
void LLWebProfile::post(LLPointer<LLImageFormatted> image, const LLSD& config, const std::string& url)
{
if (dynamic_cast<LLImagePNG*>(image.get()) == 0)
{
llwarns << "Image to upload is not a PNG" << llendl;
llassert(dynamic_cast<LLImagePNG*>(image.get()) != 0);
return;
}
const std::string boundary = "----------------------------0123abcdefab";
LLSD headers = LLViewerMedia::getHeaders();
headers["Cookie"] = getAuthCookie();
headers["Content-Type"] = "multipart/form-data; boundary=" + boundary;
std::ostringstream body;
// *NOTE: The order seems to matter.
body << "--" << boundary << "\r\n"
<< "Content-Disposition: form-data; name=\"key\"\r\n\r\n"
<< config["key"].asString() << "\r\n";
body << "--" << boundary << "\r\n"
<< "Content-Disposition: form-data; name=\"AWSAccessKeyId\"\r\n\r\n"
<< config["AWSAccessKeyId"].asString() << "\r\n";
body << "--" << boundary << "\r\n"
<< "Content-Disposition: form-data; name=\"acl\"\r\n\r\n"
<< config["acl"].asString() << "\r\n";
body << "--" << boundary << "\r\n"
<< "Content-Disposition: form-data; name=\"Content-Type\"\r\n\r\n"
<< config["Content-Type"].asString() << "\r\n";
body << "--" << boundary << "\r\n"
<< "Content-Disposition: form-data; name=\"policy\"\r\n\r\n"
<< config["policy"].asString() << "\r\n";
body << "--" << boundary << "\r\n"
<< "Content-Disposition: form-data; name=\"signature\"\r\n\r\n"
<< config["signature"].asString() << "\r\n";
body << "--" << boundary << "\r\n"
<< "Content-Disposition: form-data; name=\"success_action_redirect\"\r\n\r\n"
<< config["success_action_redirect"].asString() << "\r\n";
body << "--" << boundary << "\r\n"
<< "Content-Disposition: form-data; name=\"file\"; filename=\"snapshot.png\"\r\n"
<< "Content-Type: image/png\r\n\r\n";
// Insert the image data.
// *FIX: Treating this as a string will probably screw it up ...
U8* image_data = image->getData();
for (S32 i = 0; i < image->getDataSize(); ++i)
{
body << image_data[i];
}
body << "\r\n--" << boundary << "--\r\n";
// postRaw() takes ownership of the buffer and releases it later.
size_t size = body.str().size();
U8 *data = new U8[size];
memcpy(data, body.str().data(), size);
// Send request, successful upload will trigger posting metadata.
LLHTTPClient::postRaw(url, data, size, new LLWebProfileResponders::PostImageResponder(), headers);
}
// static
void LLWebProfile::post(LLPointer<LLImageFormatted> image, const LLSD& config, const std::string& url)
{
if (dynamic_cast<LLImagePNG*>(image.get()) == 0)
{
LL_WARNS() << "Image to upload is not a PNG" << LL_ENDL;
llassert(dynamic_cast<LLImagePNG*>(image.get()) != 0);
return;
}
const std::string boundary = "----------------------------0123abcdefab";
AIHTTPHeaders headers;
headers.addHeader("Accept", "*/*");
headers.addHeader("Cookie", LLWebProfile::getAuthCookie());
headers.addHeader("User-Agent", LLViewerMedia::getCurrentUserAgent());
headers.addHeader("Content-Type", "multipart/form-data; boundary=" + boundary);
std::ostringstream body;
// *NOTE: The order seems to matter.
body << "--" << boundary << "\r\n"
<< "Content-Disposition: form-data; name=\"key\"\r\n\r\n"
<< config["key"].asString() << "\r\n";
body << "--" << boundary << "\r\n"
<< "Content-Disposition: form-data; name=\"AWSAccessKeyId\"\r\n\r\n"
<< config["AWSAccessKeyId"].asString() << "\r\n";
body << "--" << boundary << "\r\n"
<< "Content-Disposition: form-data; name=\"acl\"\r\n\r\n"
<< config["acl"].asString() << "\r\n";
body << "--" << boundary << "\r\n"
<< "Content-Disposition: form-data; name=\"Content-Type\"\r\n\r\n"
<< config["Content-Type"].asString() << "\r\n";
body << "--" << boundary << "\r\n"
<< "Content-Disposition: form-data; name=\"policy\"\r\n\r\n"
<< config["policy"].asString() << "\r\n";
body << "--" << boundary << "\r\n"
<< "Content-Disposition: form-data; name=\"signature\"\r\n\r\n"
<< config["signature"].asString() << "\r\n";
body << "--" << boundary << "\r\n"
<< "Content-Disposition: form-data; name=\"success_action_redirect\"\r\n\r\n"
<< config["success_action_redirect"].asString() << "\r\n";
body << "--" << boundary << "\r\n"
<< "Content-Disposition: form-data; name=\"file\"; filename=\"snapshot.png\"\r\n"
<< "Content-Type: image/png\r\n\r\n";
size_t const body_size = body.str().size();
std::ostringstream footer;
footer << "\r\n--" << boundary << "--\r\n";
size_t const footer_size = footer.str().size();
size_t size = body_size + image->getDataSize() + footer_size;
// postRaw() takes ownership of the buffer and releases it later.
U8* data = new U8 [size];
memcpy(data, body.str().data(), body_size);
// Insert the image data.
memcpy(data + body_size, image->getData(), image->getDataSize());
memcpy(data + body_size + image->getDataSize(), footer.str().data(), footer_size);
// Send request, successful upload will trigger posting metadata.
LLHTTPClient::postRaw(url, data, size, new LLWebProfileResponders::PostImageResponder(), headers/*,*/ DEBUG_CURLIO_PARAM(debug_off), no_keep_alive);
}
// 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;
}
