void object::test<5>()
{
set_test_name("bad type");
LLSD request;
request["uri"] = uri;
request["method"] = "getdict";
request["reply"] = "reply";
(void)request["params"];
// Set up a timeout filter so we don't spin forever waiting.
LLEventTimeout watchdog;
// Connect the timeout filter to the reply pump.
LLTempBoundListener temp(
pumps.obtain("reply").
listen("watchdog", boost::bind(&LLEventTimeout::post, boost::ref(watchdog), _1)));
// Now connect our target listener to the timeout filter.
watchdog.listen("captureReply", boost::bind(&data::captureReply, this, _1));
// Kick off the request...
reply.clear();
pumps.obtain("LLXMLRPCTransaction").post(request);
// Set the timer
F32 timeout(10);
watchdog.eventAfter(timeout, LLSD().insert("timeout", 0));
// and pump "mainloop" until we get something, whether from
// LLXMLRPCListener or from the watchdog filter.
LLTimer timer;
F32 start = timer.getElapsedTimeF32();
LLEventPump& mainloop(pumps.obtain("mainloop"));
while (reply.isUndefined())
{
mainloop.post(LLSD());
}
ensure("timeout works", (timer.getElapsedTimeF32() - start) < (timeout + 1));
ensure_equals(reply["status"].asString(), "BadType");
ensure_contains("bad type", reply["responses"]["nested_dict"].asString(), "bad XMLRPC type");
}
/*virtual*/ void completed(U32 status, const std::string& reason, const LLSD& content)
{
slmGetTimer.stop();
if (gSavedSettings.getBOOL("InventoryOutboxLogging"))
{
llinfos << " SLM GET status: " << status << llendl;
llinfos << " SLM GET reason: " << reason << llendl;
llinfos << " SLM GET content: " << content.asString() << llendl;
llinfos << " SLM GET timer: " << slmGetTimer.getElapsedTimeF32() << llendl;
}
if ((status == MarketplaceErrorCodes::IMPORT_AUTHENTICATION_ERROR) ||
(status == MarketplaceErrorCodes::IMPORT_JOB_TIMEOUT))
{
if (gSavedSettings.getBOOL("InventoryOutboxLogging"))
{
llinfos << " SLM GET clearing marketplace cookie due to authentication failure or timeout (" << status << " / " << reason << ")." << llendl;
}
sMarketplaceCookie.clear();
}
sImportInProgress = (status == MarketplaceErrorCodes::IMPORT_PROCESSING);
sImportGetPending = false;
sImportResultStatus = status;
sImportResults = content;
}
/*virtual*/ void completed(U32 status, const std::string& reason, const LLSD& content)
{
slmGetTimer.stop();
if (gSavedSettings.getBOOL("InventoryOutboxLogging"))
{
llinfos << " SLM GET status: " << status << llendl;
llinfos << " SLM GET reason: " << reason << llendl;
llinfos << " SLM GET content: " << content.asString() << llendl;
llinfos << " SLM GET timer: " << slmGetTimer.getElapsedTimeF32() << llendl;
}
// MAINT-2452 : Do not clear the cookie on IMPORT_DONE_WITH_ERRORS : Happens when trying to import objects with wrong permissions
// ACME-1221 : Do not clear the cookie on IMPORT_NOT_FOUND : Happens for newly created Merchant accounts that are initially empty
if ((status >= MarketplaceErrorCodes::IMPORT_BAD_REQUEST) &&
(status != MarketplaceErrorCodes::IMPORT_DONE_WITH_ERRORS) &&
(status != MarketplaceErrorCodes::IMPORT_NOT_FOUND))
{
if (gSavedSettings.getBOOL("InventoryOutboxLogging"))
{
llinfos << " SLM GET clearing marketplace cookie due to client or server error (" << status << " / " << reason << ")." << llendl;
}
sMarketplaceCookie.clear();
}
else if (gSavedSettings.getBOOL("InventoryOutboxLogging") && (status >= MarketplaceErrorCodes::IMPORT_BAD_REQUEST))
{
llinfos << " SLM GET : Got error status = " << status << ", but marketplace cookie not cleared." << llendl;
}
sImportInProgress = (status == MarketplaceErrorCodes::IMPORT_PROCESSING);
sImportGetPending = false;
sImportResultStatus = status;
sImportResults = content;
}
/*virtual*/ void completed(U32 status, const std::string& reason, const LLSD& content)
{
slmGetTimer.stop();
if (gSavedSettings.getBOOL("InventoryOutboxLogging"))
{
llinfos << " SLM GET status: " << status << llendl;
llinfos << " SLM GET reason: " << reason << llendl;
llinfos << " SLM GET content: " << content.asString() << llendl;
llinfos << " SLM GET timer: " << slmGetTimer.getElapsedTimeF32() << llendl;
}
// MAINT-2452 : Do not clear the cookie on IMPORT_DONE_WITH_ERRORS
if ((status >= MarketplaceErrorCodes::IMPORT_BAD_REQUEST) &&
(status != MarketplaceErrorCodes::IMPORT_DONE_WITH_ERRORS))
{
if (gSavedSettings.getBOOL("InventoryOutboxLogging"))
{
llinfos << " SLM GET clearing marketplace cookie due to client or server error (" << status << " / " << reason << ")." << llendl;
}
sMarketplaceCookie.clear();
}
else if (gSavedSettings.getBOOL("InventoryOutboxLogging") && (status == MarketplaceErrorCodes::IMPORT_DONE_WITH_ERRORS))
{
llinfos << " SLM GET : Got IMPORT_DONE_WITH_ERRORS, marketplace cookie not cleared." << llendl;
}
sImportInProgress = (status == MarketplaceErrorCodes::IMPORT_PROCESSING);
sImportGetPending = false;
sImportResultStatus = status;
sImportResults = content;
}
F32 pump_loop(LLPumpIO* pump, F32 seconds)
{
LLTimer timer;
timer.setTimerExpirySec(seconds);
while(!timer.hasExpired())
{
LLFrameTimer::updateFrameTime();
pump->pump();
pump->callback();
}
return timer.getElapsedTimeF32();
}
void LLProgressBar::draw()
{
static LLTimer timer;
F32 alpha = getDrawContext().mAlpha;
LLColor4 image_bar_color = mColorBackground.get();
image_bar_color.setAlpha(alpha);
mImageBar->draw(getLocalRect(), image_bar_color);
alpha *= 0.5f + 0.5f*0.5f*(1.f + (F32)sin(3.f*timer.getElapsedTimeF32()));
LLColor4 bar_color = mColorBar.get();
bar_color.mV[VALPHA] *= alpha; // modulate alpha
LLRect progress_rect = getLocalRect();
progress_rect.mRight = llround(getRect().getWidth() * (mPercentDone / 100.f));
mImageFill->draw(progress_rect, bar_color);
}
void LLTextureCache::purgeTextureFilesTimeSliced(BOOL force_all)
{
LLMutexLock lock(&mHeaderMutex);
F32 delay_between_passes = 1.0f; // seconds
F32 max_time_per_pass = 0.1f; // seconds
if (!force_all && mTimeLastFileDelete.getElapsedTimeF32() <= delay_between_passes)
{
return;
}
LLTimer timer;
S32 howmany = 0;
if (mFilesToDelete.size() > 0)
{
llinfos << "TEXTURE CACHE: " << mFilesToDelete.size() << " files scheduled for deletion" << llendl;
}
for (LLTextureCache::filename_list_t::iterator iter = mFilesToDelete.begin(); iter!=mFilesToDelete.end(); )
{
LLTextureCache::filename_list_t::iterator iter2 = iter++;
ll_apr_file_remove(*iter2, NULL);
mFilesToDelete.erase(iter2);
howmany++;
if (!force_all && timer.getElapsedTimeF32() > max_time_per_pass)
{
break;
}
}
if (!mFilesToDelete.empty())
{
llinfos << "TEXTURE CACHE: "<< howmany << " files deleted ("
<< mFilesToDelete.size() << " files left for next pass)"
<< llendl;
}
mTimeLastFileDelete.reset();
}
void LLProgressBar::draw()
{
static LLTimer timer;
LLUIImagePtr shadow_imagep = LLUI::getUIImage("rounded_square_soft.tga");
LLUIImagePtr bar_fg_imagep = LLUI::getUIImage("progressbar_fill.tga");
LLUIImagePtr bar_bg_imagep = LLUI::getUIImage("progressbar_track.tga");
LLUIImagePtr bar_imagep = LLUI::getUIImage("rounded_square.tga");
LLColor4 background_color = LLUI::sColorsGroup->getColor("LoginProgressBarBgColor");
bar_bg_imagep->draw(getLocalRect(),
background_color);
F32 alpha = 0.5f + 0.5f*0.5f*(1.f + (F32)sin(3.f*timer.getElapsedTimeF32()));
LLColor4 bar_color = LLUI::sColorsGroup->getColor("LoginProgressBarFgColor");
bar_color.mV[3] = alpha;
LLRect progress_rect = getLocalRect();
progress_rect.mRight = llround(getRect().getWidth() * (mPercentDone / 100.f));
bar_fg_imagep->draw(progress_rect);
}
/*virtual*/ void completed(U32 status, const std::string& reason, const LLSD& content)
{
slmPostTimer.stop();
if (gSavedSettings.getBOOL("InventoryOutboxLogging"))
{
llinfos << " SLM POST status: " << status << llendl;
llinfos << " SLM POST reason: " << reason << llendl;
llinfos << " SLM POST content: " << content.asString() << llendl;
llinfos << " SLM POST timer: " << slmPostTimer.getElapsedTimeF32() << llendl;
}
// MAINT-2301 : we determined we can safely ignore that error in that context
if (status == MarketplaceErrorCodes::IMPORT_JOB_TIMEOUT)
{
if (gSavedSettings.getBOOL("InventoryOutboxLogging"))
{
llinfos << " SLM POST : Ignoring time out status and treating it as success" << llendl;
}
status = MarketplaceErrorCodes::IMPORT_DONE;
}
if (status >= MarketplaceErrorCodes::IMPORT_BAD_REQUEST)
{
if (gSavedSettings.getBOOL("InventoryOutboxLogging"))
{
llinfos << " SLM POST clearing marketplace cookie due to client or server error" << llendl;
}
sMarketplaceCookie.clear();
}
sImportInProgress = (status == MarketplaceErrorCodes::IMPORT_DONE);
sImportPostPending = false;
sImportResultStatus = status;
sImportId = content;
}
BOOL LLPacketRing::sendPacket(int h_socket, char * send_buffer, S32 buf_size, LLHost host)
{
//<edit>
LLMessageLog::log(LLHost(16777343, gMessageSystem->getListenPort()), host, (U8*)send_buffer, buf_size);
//</edit>
BOOL status = TRUE;
if (!mUseOutThrottle)
{
return doSendPacket(h_socket, send_buffer, buf_size, host );
}
else
{
mActualBitsOut += buf_size * 8;
LLPacketBuffer *packetp = NULL;
// See if we've got enough throttle to send a packet.
while (!mOutThrottle.checkOverflow(0.f))
{
// While we have enough bandwidth, send a packet from the queue or the current packet
S32 packet_size = 0;
if (!mSendQueue.empty())
{
// Send a packet off of the queue
LLPacketBuffer *packetp = mSendQueue.front();
mSendQueue.pop();
mOutBufferLength -= packetp->getSize();
packet_size = packetp->getSize();
status = doSendPacket(h_socket, packetp->getData(), packet_size, packetp->getHost());
delete packetp;
// Update the throttle
mOutThrottle.throttleOverflow(packet_size * 8.f);
}
else
{
// If the queue's empty, we can just send this packet right away.
status = doSendPacket(h_socket, send_buffer, buf_size, host );
packet_size = buf_size;
// Update the throttle
mOutThrottle.throttleOverflow(packet_size * 8.f);
// This was the packet we're sending now, there are no other packets
// that we need to send
return status;
}
}
// We haven't sent the incoming packet, add it to the queue
if (mOutBufferLength + buf_size > mMaxBufferLength)
{
// Nuke this packet, we overflowed the buffer.
// Toss it.
llwarns << "Throwing away outbound packet, overflowing buffer" << llendl;
}
else
{
static LLTimer queue_timer;
if ((mOutBufferLength > 4192) && queue_timer.getElapsedTimeF32() > 1.f)
{
// Add it to the queue
llinfos << "Outbound packet queue " << mOutBufferLength << " bytes" << llendl;
queue_timer.reset();
}
packetp = new LLPacketBuffer(host, send_buffer, buf_size);
mOutBufferLength += packetp->getSize();
mSendQueue.push(packetp);
}
}
return status;
}
BOOL LLVOWLSky::updateGeometry(LLDrawable * drawable)
{
LLFastTimer ftm(FTM_GEO_SKY);
LLStrider<LLVector3> vertices;
LLStrider<LLVector2> texCoords;
LLStrider<U16> indices;
#if DOME_SLICES
{
mFanVerts = new LLVertexBuffer(LLDrawPoolWLSky::SKY_VERTEX_DATA_MASK, GL_STATIC_DRAW_ARB);
mFanVerts->allocateBuffer(getFanNumVerts(), getFanNumIndices(), TRUE);
BOOL success = mFanVerts->getVertexStrider(vertices)
&& mFanVerts->getTexCoord0Strider(texCoords)
&& mFanVerts->getIndexStrider(indices);
if(!success)
{
llerrs << "Failed updating WindLight sky geometry." << llendl;
}
buildFanBuffer(vertices, texCoords, indices);
mFanVerts->flush();
}
{
const U32 max_buffer_bytes = gSavedSettings.getS32("RenderMaxVBOSize")*1024;
const U32 data_mask = LLDrawPoolWLSky::SKY_VERTEX_DATA_MASK;
const U32 max_verts = max_buffer_bytes / LLVertexBuffer::calcVertexSize(data_mask);
const U32 total_stacks = getNumStacks();
const U32 verts_per_stack = getNumSlices();
// each seg has to have one more row of verts than it has stacks
// then round down
const U32 stacks_per_seg = (max_verts - verts_per_stack) / verts_per_stack;
// round up to a whole number of segments
const U32 strips_segments = (total_stacks+stacks_per_seg-1) / stacks_per_seg;
llinfos << "WL Skydome strips in " << strips_segments << " batches." << llendl;
mStripsVerts.resize(strips_segments, NULL);
LLTimer timer;
timer.start();
for (U32 i = 0; i < strips_segments ;++i)
{
LLVertexBuffer * segment = new LLVertexBuffer(LLDrawPoolWLSky::SKY_VERTEX_DATA_MASK, GL_STATIC_DRAW_ARB);
mStripsVerts[i] = segment;
U32 num_stacks_this_seg = stacks_per_seg;
if ((i == strips_segments - 1) && (total_stacks % stacks_per_seg) != 0)
{
// for the last buffer only allocate what we'll use
num_stacks_this_seg = total_stacks % stacks_per_seg;
}
// figure out what range of the sky we're filling
const U32 begin_stack = i * stacks_per_seg;
const U32 end_stack = begin_stack + num_stacks_this_seg;
llassert(end_stack <= total_stacks);
const U32 num_verts_this_seg = verts_per_stack * (num_stacks_this_seg+1);
llassert(num_verts_this_seg <= max_verts);
const U32 num_indices_this_seg = 1+num_stacks_this_seg*(2+2*verts_per_stack);
llassert(num_indices_this_seg * sizeof(U16) <= max_buffer_bytes);
segment->allocateBuffer(num_verts_this_seg, num_indices_this_seg, TRUE);
// lock the buffer
BOOL success = segment->getVertexStrider(vertices)
&& segment->getTexCoord0Strider(texCoords)
&& segment->getIndexStrider(indices);
if(!success)
{
llerrs << "Failed updating WindLight sky geometry." << llendl;
}
// fill it
buildStripsBuffer(begin_stack, end_stack, vertices, texCoords, indices);
// and unlock the buffer
segment->flush();
}
llinfos << "completed in " << llformat("%.2f", timer.getElapsedTimeF32()) << "seconds" << llendl;
}
#else
mStripsVerts = new LLVertexBuffer(LLDrawPoolWLSky::SKY_VERTEX_DATA_MASK, GL_STATIC_DRAW_ARB);
const F32 RADIUS = LLWLParamManager::sParamMgr->getDomeRadius();
LLPointer<LLVertexBuffer> temp = new LLVertexBuffer(LLVertexBuffer::MAP_VERTEX, 0);
temp->allocateBuffer(12, 60, TRUE);
BOOL success = temp->getVertexStrider(vertices)
&& temp->getIndexStrider(indices);
if (success)
{
for (U32 i = 0; i < 12; i++)
{
*vertices++ = icosahedron_vert[i];
}
for (U32 i = 0; i < 60; i++)
{
*indices++ = icosahedron_ind[i];
}
}
LLPointer<LLVertexBuffer> temp2;
for (U32 i = 0; i < 8; i++)
{
temp2 = new LLVertexBuffer(LLVertexBuffer::MAP_VERTEX, 0);
subdivide(*temp, temp2);
temp = temp2;
}
temp->getVertexStrider(vertices);
for (S32 i = 0; i < temp->getNumVerts(); i++)
{
LLVector3 v = vertices[i];
v.normVec();
vertices[i] = v*RADIUS;
}
temp2 = new LLVertexBuffer(LLVertexBuffer::MAP_VERTEX, 0);
chop(*temp, temp2);
mStripsVerts->allocateBuffer(temp2->getNumVerts(), temp2->getNumIndices(), TRUE);
success = mStripsVerts->getVertexStrider(vertices)
&& mStripsVerts->getTexCoordStrider(texCoords)
&& mStripsVerts->getIndexStrider(indices);
LLStrider<LLVector3> v;
temp2->getVertexStrider(v);
LLStrider<U16> ind;
temp2->getIndexStrider(ind);
if (success)
{
for (S32 i = 0; i < temp2->getNumVerts(); ++i)
{
LLVector3 vert = *v++;
vert.normVec();
F32 z0 = vert.mV[2];
F32 x0 = vert.mV[0];
vert *= RADIUS;
*vertices++ = vert;
*texCoords++ = LLVector2((-z0 + 1.f) / 2.f, (-x0 + 1.f) / 2.f);
}
for (S32 i = 0; i < temp2->getNumIndices(); ++i)
{
*indices++ = *ind++;
}
}
mStripsVerts->flush();
#endif
updateStarColors();
updateStarGeometry(drawable);
LLPipeline::sCompiles++;
return TRUE;
}
// decode a given message
BOOL LLTemplateMessageReader::decodeData(const U8* buffer, const LLHost& sender )
{
llassert( mReceiveSize >= 0 );
llassert( mCurrentRMessageTemplate);
llassert( !mCurrentRMessageData );
delete mCurrentRMessageData; // just to make sure
// The offset tells us how may bytes to skip after the end of the
// message name.
U8 offset = buffer[PHL_OFFSET];
S32 decode_pos = LL_PACKET_ID_SIZE + (S32)(mCurrentRMessageTemplate->mFrequency) + offset;
// create base working data set
mCurrentRMessageData = new LLMsgData(mCurrentRMessageTemplate->mName);
// loop through the template building the data structure as we go
LLMessageTemplate::message_block_map_t::const_iterator iter;
for(iter = mCurrentRMessageTemplate->mMemberBlocks.begin();
iter != mCurrentRMessageTemplate->mMemberBlocks.end();
++iter)
{
LLMessageBlock* mbci = *iter;
U8 repeat_number;
S32 i;
// how many of this block?
if (mbci->mType == MBT_SINGLE)
{
// just one
repeat_number = 1;
}
else if (mbci->mType == MBT_MULTIPLE)
{
// a known number
repeat_number = mbci->mNumber;
}
else if (mbci->mType == MBT_VARIABLE)
{
// need to read the number from the message
// repeat number is a single byte
if (decode_pos >= mReceiveSize)
{
// commented out - hetgrid says that missing variable blocks
// at end of message are legal
// logRanOffEndOfPacket(sender, decode_pos, 1);
// default to 0 repeats
repeat_number = 0;
}
else
{
repeat_number = buffer[decode_pos];
decode_pos++;
}
}
else
{
llerrs << "Unknown block type" << llendl;
return FALSE;
}
LLMsgBlkData* cur_data_block = NULL;
// now loop through the block
for (i = 0; i < repeat_number; i++)
{
if (i)
{
// build new name to prevent collisions
// TODO: This should really change to a vector
cur_data_block = new LLMsgBlkData(mbci->mName, repeat_number);
cur_data_block->mName = mbci->mName + i;
}
else
{
cur_data_block = new LLMsgBlkData(mbci->mName, repeat_number);
}
// add the block to the message
mCurrentRMessageData->addBlock(cur_data_block);
// now read the variables
for (LLMessageBlock::message_variable_map_t::const_iterator iter =
mbci->mMemberVariables.begin();
iter != mbci->mMemberVariables.end(); iter++)
{
const LLMessageVariable& mvci = **iter;
// ok, build out the variables
// add variable block
cur_data_block->addVariable(mvci.getName(), mvci.getType());
// what type of variable?
if (mvci.getType() == MVT_VARIABLE)
{
// variable, get the number of bytes to read from the template
S32 data_size = mvci.getSize();
U8 tsizeb = 0;
U16 tsizeh = 0;
U32 tsize = 0;
if ((decode_pos + data_size) > mReceiveSize)
{
logRanOffEndOfPacket(sender, decode_pos, data_size);
// default to 0 length variable blocks
tsize = 0;
}
else
{
switch(data_size)
{
case 1:
htonmemcpy(&tsizeb, &buffer[decode_pos], MVT_U8, 1);
tsize = tsizeb;
break;
case 2:
htonmemcpy(&tsizeh, &buffer[decode_pos], MVT_U16, 2);
tsize = tsizeh;
break;
case 4:
htonmemcpy(&tsize, &buffer[decode_pos], MVT_U32, 4);
break;
default:
llerrs << "Attempting to read variable field with unknown size of " << data_size << llendl;
break;
}
}
decode_pos += data_size;
cur_data_block->addData(mvci.getName(), &buffer[decode_pos], tsize, mvci.getType());
decode_pos += tsize;
}
else
{
// fixed!
// so, copy data pointer and set data size to fixed size
if ((decode_pos + mvci.getSize()) > mReceiveSize)
{
logRanOffEndOfPacket(sender, decode_pos, mvci.getSize());
// default to 0s.
U32 size = mvci.getSize();
std::vector<U8> data(size);
if (size) memset(&(data[0]), 0, size);
cur_data_block->addData(mvci.getName(), &(data[0]),
size, mvci.getType());
}
else
{
cur_data_block->addData(mvci.getName(),
&buffer[decode_pos],
mvci.getSize(),
mvci.getType());
}
decode_pos += mvci.getSize();
}
}
}
}
if (mCurrentRMessageData->mMemberBlocks.empty()
&& !mCurrentRMessageTemplate->mMemberBlocks.empty())
{
lldebugs << "Empty message '" << mCurrentRMessageTemplate->mName << "' (no blocks)" << llendl;
return FALSE;
}
{
static LLTimer decode_timer;
if(LLMessageReader::getTimeDecodes() || gMessageSystem->getTimingCallback())
{
decode_timer.reset();
}
{
LLFastTimer t(LLFastTimer::FTM_PROCESS_MESSAGES);
if( !mCurrentRMessageTemplate->callHandlerFunc(gMessageSystem) )
{
llwarns << "Message from " << sender << " with no handler function received: " << mCurrentRMessageTemplate->mName << llendl;
}
}
if(LLMessageReader::getTimeDecodes() || gMessageSystem->getTimingCallback())
{
F32 decode_time = decode_timer.getElapsedTimeF32();
if (gMessageSystem->getTimingCallback())
{
(gMessageSystem->getTimingCallback())(mCurrentRMessageTemplate->mName,
decode_time,
gMessageSystem->getTimingCallbackData());
}
if (LLMessageReader::getTimeDecodes())
{
mCurrentRMessageTemplate->mDecodeTimeThisFrame += decode_time;
mCurrentRMessageTemplate->mTotalDecoded++;
mCurrentRMessageTemplate->mTotalDecodeTime += decode_time;
if( mCurrentRMessageTemplate->mMaxDecodeTimePerMsg < decode_time )
{
mCurrentRMessageTemplate->mMaxDecodeTimePerMsg = decode_time;
}
if(decode_time > LLMessageReader::getTimeDecodesSpamThreshold())
{
lldebugs << "--------- Message " << mCurrentRMessageTemplate->mName << " decode took " << decode_time << " seconds. (" <<
mCurrentRMessageTemplate->mMaxDecodeTimePerMsg << " max, " <<
(mCurrentRMessageTemplate->mTotalDecodeTime / mCurrentRMessageTemplate->mTotalDecoded) << " avg)" << llendl;
}
}
}
}
return TRUE;
}
void LLPanelGroupGeneral::updateMembers()
{
mPendingMemberUpdate = FALSE;
LLGroupMgrGroupData* gdatap = LLGroupMgr::getInstance()->getGroupData(mGroupID);
if (!mListVisibleMembers || !gdatap
|| !gdatap->isMemberDataComplete())
{
return;
}
static LLTimer all_timer;
static LLTimer sd_timer;
static LLTimer element_timer;
all_timer.reset();
S32 i = 0;
for( ; mMemberProgress != gdatap->mMembers.end() && i<UPDATE_MEMBERS_PER_FRAME;
++mMemberProgress, ++i)
{
//llinfos << "Adding " << iter->first << ", " << iter->second->getTitle() << llendl;
LLGroupMemberData* member = mMemberProgress->second;
if (!member)
{
continue;
}
// Owners show up in bold.
std::string style = "NORMAL";
if ( member->isOwner() )
{
style = "BOLD";
}
sd_timer.reset();
LLSD row;
row["id"] = member->getID();
row["columns"][0]["column"] = "name";
row["columns"][0]["font-style"] = style;
// value is filled in by name list control
row["columns"][1]["column"] = "title";
row["columns"][1]["value"] = member->getTitle();
row["columns"][1]["font-style"] = style;
row["columns"][2]["column"] = "online";
row["columns"][2]["value"] = member->getOnlineStatus();
row["columns"][2]["font-style"] = style;
sSDTime += sd_timer.getElapsedTimeF32();
element_timer.reset();
mListVisibleMembers->addElement(row);//, ADD_SORTED);
sElementTime += element_timer.getElapsedTimeF32();
}
sAllTime += all_timer.getElapsedTimeF32();
llinfos << "Updated " << i << " of " << UPDATE_MEMBERS_PER_FRAME << "members in the list." << llendl;
if (mMemberProgress == gdatap->mMembers.end())
{
llinfos << " member list completed." << llendl;
mListVisibleMembers->setEnabled(TRUE);
llinfos << "All Time: " << sAllTime << llendl;
llinfos << "SD Time: " << sSDTime << llendl;
llinfos << "Element Time: " << sElementTime << llendl;
}
else
{
mPendingMemberUpdate = TRUE;
mListVisibleMembers->setEnabled(FALSE);
}
}
F32 gpu_benchmark()
{
if (!gGLManager.mHasShaderObjects || !gGLManager.mHasTimerQuery)
{ // don't bother benchmarking the fixed function
// or venerable drivers which don't support accurate timing anyway
// and are likely to be correctly identified by the GPU table already.
return -1.f;
}
if (gBenchmarkProgram.mProgramObject == 0)
{
LLViewerShaderMgr::instance()->initAttribsAndUniforms();
gBenchmarkProgram.mName = "Benchmark Shader";
gBenchmarkProgram.mFeatures.attachNothing = true;
gBenchmarkProgram.mShaderFiles.clear();
gBenchmarkProgram.mShaderFiles.push_back(std::make_pair("interface/benchmarkV.glsl", GL_VERTEX_SHADER_ARB));
gBenchmarkProgram.mShaderFiles.push_back(std::make_pair("interface/benchmarkF.glsl", GL_FRAGMENT_SHADER_ARB));
gBenchmarkProgram.mShaderLevel = 1;
if (!gBenchmarkProgram.createShader(NULL, NULL))
{
return -1.f;
}
}
LLGLDisable blend(GL_BLEND);
//measure memory bandwidth by:
// - allocating a batch of textures and render targets
// - rendering those textures to those render targets
// - recording time taken
// - taking the median time for a given number of samples
//resolution of textures/render targets
const U32 res = 1024;
//number of textures
const U32 count = 32;
//number of samples to take
const S32 samples = 64;
if (gGLManager.mHasTimerQuery)
{
LLGLSLShader::initProfile();
}
LLRenderTarget dest[count];
U32 source[count];
LLImageGL::generateTextures(count, source);
std::vector<F32> results;
//build a random texture
U8* pixels = new U8[res*res*4];
for (U32 i = 0; i < res*res*4; ++i)
{
pixels[i] = (U8) ll_rand(255);
}
gGL.setColorMask(true, true);
LLGLDepthTest depth(GL_FALSE);
for (U32 i = 0; i < count; ++i)
{ //allocate render targets and textures
dest[i].allocate(res,res,GL_RGBA,false, false, LLTexUnit::TT_TEXTURE, true);
dest[i].bindTarget();
dest[i].clear();
dest[i].flush();
gGL.getTexUnit(0)->bindManual(LLTexUnit::TT_TEXTURE, source[i]);
LLImageGL::setManualImage(GL_TEXTURE_2D, 0, GL_RGBA, res,res,GL_RGBA, GL_UNSIGNED_BYTE, pixels);
}
delete [] pixels;
//make a dummy triangle to draw with
LLPointer<LLVertexBuffer> buff = new LLVertexBuffer(LLVertexBuffer::MAP_VERTEX | LLVertexBuffer::MAP_TEXCOORD0, GL_STATIC_DRAW_ARB);
buff->allocateBuffer(3, 0, true);
LLStrider<LLVector3> v;
LLStrider<LLVector2> tc;
buff->getVertexStrider(v);
v[0].set(-1,1,0);
v[1].set(-1,-3,0);
v[2].set(3,1,0);
buff->flush();
gBenchmarkProgram.bind();
bool busted_finish = false;
buff->setBuffer(LLVertexBuffer::MAP_VERTEX);
glFinish();
for (S32 c = -1; c < samples; ++c)
{
LLTimer timer;
timer.start();
for (U32 i = 0; i < count; ++i)
{
dest[i].bindTarget();
gGL.getTexUnit(0)->bindManual(LLTexUnit::TT_TEXTURE, source[i]);
buff->drawArrays(LLRender::TRIANGLES, 0, 3);
dest[i].flush();
}
//wait for current batch of copies to finish
if (busted_finish)
{
//read a pixel off the last target since some drivers seem to ignore glFinish
dest[count-1].bindTarget();
U32 pixel = 0;
glReadPixels(0,0,1,1,GL_RGBA, GL_UNSIGNED_BYTE, &pixel);
dest[count-1].flush();
}
else
{
glFinish();
}
F32 time = timer.getElapsedTimeF32();
if (c >= 0) // <-- ignore the first sample as it tends to be artificially slow
{
//store result in gigabytes per second
F32 gb = (F32) ((F64) (res*res*8*count))/(1000000000);
F32 gbps = gb/time;
if (!gGLManager.mHasTimerQuery && !busted_finish && gbps > 128.f)
{ //unrealistically high bandwidth for a card without timer queries, glFinish is probably ignored
busted_finish = true;
LL_WARNS() << "GPU Benchmark detected GL driver with broken glFinish implementation." << LL_ENDL;
}
else
{
results.push_back(gbps);
}
}
}
gBenchmarkProgram.unbind();
if (gGLManager.mHasTimerQuery)
{
LLGLSLShader::finishProfile(false);
}
LLImageGL::deleteTextures(count, source);
std::sort(results.begin(), results.end());
F32 gbps = results[results.size()/2];
LL_INFOS() << "Memory bandwidth is " << llformat("%.3f", gbps) << "GB/sec according to CPU timers" << LL_ENDL;
#if LL_DARWIN
if (gbps > 512.f)
{
LL_WARNS() << "Memory bandwidth is improbably high and likely incorrect; discarding result." << LL_ENDL;
//OSX is probably lying, discard result
gbps = -1.f;
}
#endif
F32 ms = gBenchmarkProgram.mTimeElapsed/1000000.f;
F32 seconds = ms/1000.f;
F64 samples_drawn = res*res*count*samples;
F32 samples_sec = (samples_drawn/1000000000.0)/seconds;
gbps = samples_sec*8;
LL_INFOS() << "Memory bandwidth is " << llformat("%.3f", gbps) << "GB/sec according to ARB_timer_query" << LL_ENDL;
return gbps;
}
bool LLXMLRPCTransaction::Impl::process()
{
switch(mStatus)
{
case LLXMLRPCTransaction::StatusComplete:
case LLXMLRPCTransaction::StatusCURLError:
case LLXMLRPCTransaction::StatusXMLRPCError:
case LLXMLRPCTransaction::StatusOtherError:
{
return true;
}
case LLXMLRPCTransaction::StatusNotStarted:
{
setStatus(LLXMLRPCTransaction::StatusStarted);
break;
}
default:
{
// continue onward
}
}
const F32 MAX_PROCESSING_TIME = 0.05f;
LLTimer timer;
while (mCurlRequest->perform() > 0)
{
if (timer.getElapsedTimeF32() >= MAX_PROCESSING_TIME)
{
return false;
}
}
while(1)
{
CURLcode result;
bool newmsg = mCurlRequest->getResult(&result, &mTransferInfo);
if (newmsg)
{
if (result != CURLE_OK)
{
if ((result != CURLE_SSL_PEER_CERTIFICATE) &&
(result != CURLE_SSL_CACERT))
{
// if we have a curl error that's not already been handled
// (a non cert error), then generate the error message as
// appropriate
setCurlStatus(result);
llwarns << "LLXMLRPCTransaction CURL error "
<< mCurlCode << ": " << mCurlRequest->getErrorString() << llendl;
llwarns << "LLXMLRPCTransaction request URI: "
<< mURI << llendl;
}
return true;
}
setStatus(LLXMLRPCTransaction::StatusComplete);
mResponse = XMLRPC_REQUEST_FromXML(
mResponseText.data(), mResponseText.size(), NULL);
bool hasError = false;
bool hasFault = false;
int faultCode = 0;
std::string faultString;
LLXMLRPCValue error(XMLRPC_RequestGetError(mResponse));
if (error.isValid())
{
hasError = true;
faultCode = error["faultCode"].asInt();
faultString = error["faultString"].asString();
}
else if (XMLRPC_ResponseIsFault(mResponse))
{
hasFault = true;
faultCode = XMLRPC_GetResponseFaultCode(mResponse);
faultString = XMLRPC_GetResponseFaultString(mResponse);
}
if (hasError || hasFault)
{
setStatus(LLXMLRPCTransaction::StatusXMLRPCError);
llwarns << "LLXMLRPCTransaction XMLRPC "
<< (hasError ? "error " : "fault ")
<< faultCode << ": "
<< faultString << llendl;
llwarns << "LLXMLRPCTransaction request URI: "
<< mURI << llendl;
}
return true;
}
else
{
break; // done
}
}
return false;
}
void LLViewerImageList::decodeAllImages(F32 max_time)
{
LLTimer timer;
if(gNoRender) return;
// Update texture stats and priorities
std::vector<LLPointer<LLViewerImage> > image_list;
for (image_priority_list_t::iterator iter = mImageList.begin();
iter != mImageList.end(); )
{
LLViewerImage* imagep = *iter++;
image_list.push_back(imagep);
imagep->mInImageList = FALSE;
}
mImageList.clear();
for (std::vector<LLPointer<LLViewerImage> >::iterator iter = image_list.begin();
iter != image_list.end(); ++iter)
{
LLViewerImage* imagep = *iter;
imagep->processTextureStats();
F32 decode_priority = imagep->calcDecodePriority();
imagep->setDecodePriority(decode_priority);
mImageList.insert(imagep);
imagep->mInImageList = TRUE;
}
image_list.clear();
// Update fetch (decode)
for (image_priority_list_t::iterator iter = mImageList.begin();
iter != mImageList.end(); )
{
LLViewerImage* imagep = *iter++;
imagep->updateFetch();
}
// Run threads
S32 fetch_pending = 0;
while (1)
{
LLAppViewer::instance()->getTextureCache()->update(1); // unpauses the texture cache thread
LLAppViewer::instance()->getImageDecodeThread()->update(1); // unpauses the image thread
fetch_pending = LLAppViewer::instance()->getTextureFetch()->update(1); // unpauses the texture fetch thread
if (fetch_pending == 0 || timer.getElapsedTimeF32() > max_time)
{
break;
}
}
// Update fetch again
for (image_priority_list_t::iterator iter = mImageList.begin();
iter != mImageList.end(); )
{
LLViewerImage* imagep = *iter++;
imagep->updateFetch();
}
max_time -= timer.getElapsedTimeF32();
max_time = llmax(max_time, .001f);
F32 create_time = updateImagesCreateTextures(max_time);
LL_DEBUGS("ViewerImages") << "decodeAllImages() took " << timer.getElapsedTimeF32() << " seconds. "
<< " fetch_pending " << fetch_pending
<< " create_time " << create_time
<< LL_ENDL;
}
bool LLXMLRPCTransaction::Impl::process()
{
switch(mStatus)
{
case LLXMLRPCTransaction::StatusComplete:
case LLXMLRPCTransaction::StatusCURLError:
case LLXMLRPCTransaction::StatusXMLRPCError:
case LLXMLRPCTransaction::StatusOtherError:
{
return true;
}
case LLXMLRPCTransaction::StatusNotStarted:
{
setStatus(LLXMLRPCTransaction::StatusStarted);
break;
}
default:
{
// continue onward
}
}
const F32 MAX_PROCESSING_TIME = 0.05f;
LLTimer timer;
int count;
while (CURLM_CALL_MULTI_PERFORM == curl_multi_perform(mCurlMulti, &count))
{
if (timer.getElapsedTimeF32() >= MAX_PROCESSING_TIME)
{
return false;
}
}
while(CURLMsg* curl_msg = curl_multi_info_read(mCurlMulti, &count))
{
if (CURLMSG_DONE == curl_msg->msg)
{
if (curl_msg->data.result != CURLE_OK)
{
setCurlStatus(curl_msg->data.result);
llwarns << "LLXMLRPCTransaction CURL error "
<< mCurlCode << ": " << mCurlErrorBuffer << llendl;
llwarns << "LLXMLRPCTransaction request URI: "
<< mURI << llendl;
return true;
}
setStatus(LLXMLRPCTransaction::StatusComplete);
mResponse = XMLRPC_REQUEST_FromXML(
mResponseText.data(), mResponseText.size(), NULL);
bool hasError = false;
bool hasFault = false;
int faultCode = 0;
std::string faultString;
LLXMLRPCValue error(XMLRPC_RequestGetError(mResponse));
if (error.isValid())
{
hasError = true;
faultCode = error["faultCode"].asInt();
faultString = error["faultString"].asString();
}
else if (XMLRPC_ResponseIsFault(mResponse))
{
hasFault = true;
faultCode = XMLRPC_GetResponseFaultCode(mResponse);
faultString = XMLRPC_GetResponseFaultString(mResponse);
}
if (hasError || hasFault)
{
setStatus(LLXMLRPCTransaction::StatusXMLRPCError);
llwarns << "LLXMLRPCTransaction XMLRPC "
<< (hasError ? "error " : "fault ")
<< faultCode << ": "
<< faultString << llendl;
llwarns << "LLXMLRPCTransaction request URI: "
<< mURI << llendl;
}
return true;
}
}
return false;
}
void LLProgressView::draw()
{
static LLTimer timer;
if (gNoRender)
{
return;
}
// Make sure the progress view always fills the entire window.
S32 width = gViewerWindow->getWindowWidth();
S32 height = gViewerWindow->getWindowHeight();
if( (width != getRect().getWidth()) || (height != getRect().getHeight()) )
{
reshape( width, height );
}
// Paint bitmap if we've got one
glPushMatrix();
if (gStartImageGL)
{
LLGLSUIDefault gls_ui;
LLViewerImage::bindTexture(gStartImageGL);
gGL.color4f(1.f, 1.f, 1.f, mFadeTimer.getStarted() ? clamp_rescale(mFadeTimer.getElapsedTimeF32(), 0.f, FADE_IN_TIME, 1.f, 0.f) : 1.f);
F32 image_aspect = (F32)gStartImageWidth / (F32)gStartImageHeight;
F32 view_aspect = (F32)width / (F32)height;
// stretch image to maintain aspect ratio
if (image_aspect > view_aspect)
{
glTranslatef(-0.5f * (image_aspect / view_aspect - 1.f) * width, 0.f, 0.f);
glScalef(image_aspect / view_aspect, 1.f, 1.f);
}
else
{
glTranslatef(0.f, -0.5f * (view_aspect / image_aspect - 1.f) * height, 0.f);
glScalef(1.f, view_aspect / image_aspect, 1.f);
}
gl_rect_2d_simple_tex( getRect().getWidth(), getRect().getHeight() );
gStartImageGL->unbindTexture(0, GL_TEXTURE_2D);
}
else
{
LLGLSNoTexture gls_no_texture;
gGL.color4f(0.f, 0.f, 0.f, 1.f);
gl_rect_2d(getRect());
}
glPopMatrix();
// Handle fade-in animation
if (mFadeTimer.getStarted())
{
LLView::draw();
if (mFadeTimer.getElapsedTimeF32() > FADE_IN_TIME)
{
gFocusMgr.removeTopCtrlWithoutCallback(this);
LLView::setVisible(FALSE);
gStartImageGL = NULL;
}
return;
}
S32 line_x = getRect().getWidth() / 2;
S32 line_one_y = getRect().getHeight() / 2 + 64;
const S32 LINE_SPACING = 25;
S32 line_two_y = line_one_y - LINE_SPACING;
const LLFontGL* font = LLFontGL::sSansSerif;
LLUIImagePtr shadow_imagep = LLUI::getUIImage("rounded_square_soft.tga");
LLUIImagePtr bar_fg_imagep = LLUI::getUIImage("progressbar_fill.tga");
LLUIImagePtr bar_bg_imagep = LLUI::getUIImage("progressbar_track.tga");
LLUIImagePtr bar_imagep = LLUI::getUIImage("rounded_square.tga");
LLColor4 background_color = gColors.getColor("LoginProgressBarBgColor");
F32 alpha = 0.5f + 0.5f*0.5f*(1.f + (F32)sin(3.f*timer.getElapsedTimeF32()));
// background_color.mV[3] = background_color.mV[3]*alpha;
std::string top_line = LLAppViewer::instance()->getSecondLifeTitle();
S32 bar_bottom = line_two_y - 30;
S32 bar_height = 18;
S32 bar_width = getRect().getWidth() * 2 / 3;
S32 bar_left = (getRect().getWidth() / 2) - (bar_width / 2);
// translucent outline box
S32 background_box_left = ( ( ( getRect().getWidth() / 2 ) - ( bar_width / 2 ) ) / 4 ) * 3;
S32 background_box_top = ( getRect().getHeight() / 2 ) + LINE_SPACING * 5;
S32 background_box_right = getRect().getWidth() - background_box_left;
S32 background_box_bottom = ( getRect().getHeight() / 2 ) - LINE_SPACING * 5;
S32 background_box_width = background_box_right - background_box_left + 1;
S32 background_box_height = background_box_top - background_box_bottom + 1;
// shadow_imagep->draw( background_box_left + 2,
// background_box_bottom - 2,
// background_box_width,
// background_box_height,
// gColors.getColor( "LoginProgressBoxShadowColor" ) );
// bar_outline_imagep->draw( background_box_left,
// background_box_bottom,
// background_box_width,
// background_box_height,
// gColors.getColor("LoginProgressBoxBorderColor") );
bar_imagep->draw( background_box_left + 1,
background_box_bottom + 1,
background_box_width - 2,
background_box_height - 2,
gColors.getColor("LoginProgressBoxCenterColor") );
// we'll need this later for catching a click if it looks like it contains a link
if ( mMessage.find( "http://" ) != std::string::npos )
mOutlineRect.set( background_box_left, background_box_top, background_box_right, background_box_bottom );
else
mOutlineRect.set( 0, 0, 0, 0 );
// draw loading bar
font->renderUTF8(top_line, 0,
line_x, line_one_y,
//LLColor4::white,
gColors.getColor("LoginProgressBoxTextColor"),
LLFontGL::HCENTER, LLFontGL::BASELINE,
LLFontGL::DROP_SHADOW);
font->renderUTF8(mText, 0,
line_x, line_two_y,
//LLColor4::white,
gColors.getColor("LoginProgressBoxTextColor"),
LLFontGL::HCENTER, LLFontGL::BASELINE,
LLFontGL::DROP_SHADOW);
// shadow_imagep->draw(
// bar_left + 2,
// bar_bottom - 2,
// bar_width,
// bar_height,
// gColors.getColor("LoginProgressBoxShadowColor"));
// bar_imagep->draw(
// bar_left,
// bar_bottom,
// bar_width,
// bar_height,
// LLColor4(0.7f, 0.7f, 0.8f, 1.0f));
bar_bg_imagep->draw(
bar_left + 2,
bar_bottom + 2,
bar_width - 4,
bar_height - 4,
background_color);
LLColor4 bar_color = gColors.getColor("LoginProgressBarFgColor");
bar_color.mV[3] = alpha;
bar_fg_imagep->draw(
bar_left + 2,
bar_bottom + 2,
llround((bar_width - 4) * (mPercentDone / 100.f)),
bar_height - 4,
bar_color);
S32 line_three_y = line_two_y - LINE_SPACING * 3;
// draw the message if there is one
if(!mMessage.empty())
{
LLColor4 text_message_color = gColors.getColor("LoginProgressBoxTextColor");
LLWString wmessage = utf8str_to_wstring(mMessage);
const F32 MAX_PIXELS = 640.0f;
S32 chars_left = wmessage.length();
S32 chars_this_time = 0;
S32 msgidx = 0;
while(chars_left > 0)
{
chars_this_time = font->maxDrawableChars(wmessage.substr(msgidx).c_str(),
MAX_PIXELS,
MAX_STRING - 1,
TRUE);
LLWString wbuffer = wmessage.substr(msgidx, chars_this_time);
font->render(wbuffer, 0,
(F32)line_x, (F32)line_three_y,
//LLColor4::white,
gColors.getColor("LoginProgressBoxTextColor"),
LLFontGL::HCENTER, LLFontGL::BASELINE,
LLFontGL::DROP_SHADOW);
msgidx += chars_this_time;
chars_left -= chars_this_time;
line_three_y -= LINE_SPACING;
}
}
// draw children
LLView::draw();
}
