/** * @file llstatbar.cpp * @brief A little map of the world with network information * * $LicenseInfo:firstyear=2001&license=viewerlgpl$ * Second Life Viewer Source Code * Copyright (C) 2010, Linden Research, Inc. * * This library is free software; you can redistribute it and/or * modify it under the terms of the GNU Lesser General Public * License as published by the Free Software Foundation; * version 2.1 of the License only. * * This library is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU * Lesser General Public License for more details. * * You should have received a copy of the GNU Lesser General Public * License along with this library; if not, write to the Free Software * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA * * Linden Research, Inc., 945 Battery Street, San Francisco, CA 94111 USA * $/LicenseInfo$ */ //#include "llviewerprecompiledheaders.h" #include "linden_common.h" #include "llstatbar.h" #include "llmath.h" #include "llui.h" #include "llgl.h" #include "llfontgl.h" #include "lluictrlfactory.h" #include "lltracerecording.h" #include "llcriticaldamp.h" /////////////////////////////////////////////////////////////////////////////////// LLStatBar::LLStatBar(const Params& p) : LLView(p), mLabel(p.label), mUnitLabel(p.unit_label), mMinBar(p.bar_min), mMaxBar(p.bar_max), mCurMaxBar(p.bar_max), mCountFloatp(LLTrace::CountStatHandle<>::getInstance(p.stat)), mCountIntp(LLTrace::CountStatHandle::getInstance(p.stat)), mMeasurementFloatp(LLTrace::MeasurementStatHandle<>::getInstance(p.stat)), mMeasurementIntp(LLTrace::MeasurementStatHandle::getInstance(p.stat)), mTickSpacing(p.tick_spacing), mPrecision(p.precision), mUpdatesPerSec(p.update_rate), mUnitScale(p.unit_scale), mNumFrames(p.num_frames), mMaxHeight(p.max_height), mPerSec(p.show_per_sec), mDisplayBar(p.show_bar), mDisplayHistory(p.show_history), mDisplayMean(p.show_mean), mOrientation(p.orientation), mScaleRange(p.scale_range) {} BOOL LLStatBar::handleMouseDown(S32 x, S32 y, MASK mask) { BOOL handled = LLView::handleMouseDown(x, y, mask); if (!handled) { if (mDisplayBar) { if (mDisplayHistory || mOrientation == HORIZONTAL) { mDisplayBar = FALSE; mDisplayHistory = FALSE; } else { mDisplayHistory = TRUE; } } else { mDisplayBar = TRUE; if (mOrientation == HORIZONTAL) { mDisplayHistory = TRUE; } } LLView* parent = getParent(); parent->reshape(parent->getRect().getWidth(), parent->getRect().getHeight(), FALSE); } return TRUE; } void LLStatBar::draw() { F32 current = 0.f, min = 0.f, max = 0.f, mean = 0.f; LLTrace::PeriodicRecording& frame_recording = LLTrace::get_frame_recording(); if (mCountFloatp) { LLTrace::Recording& last_frame_recording = frame_recording.getLastRecording(); if (mPerSec) { current = last_frame_recording.getPerSec(*mCountFloatp); min = frame_recording.getPeriodMinPerSec(*mCountFloatp, mNumFrames); max = frame_recording.getPeriodMaxPerSec(*mCountFloatp, mNumFrames); mean = frame_recording.getPeriodMeanPerSec(*mCountFloatp, mNumFrames); } else { current = last_frame_recording.getSum(*mCountFloatp); min = frame_recording.getPeriodMin(*mCountFloatp, mNumFrames); max = frame_recording.getPeriodMax(*mCountFloatp, mNumFrames); mean = frame_recording.getPeriodMean(*mCountFloatp, mNumFrames); } } else if (mCountIntp) { LLTrace::Recording& last_frame_recording = frame_recording.getLastRecording(); if (mPerSec) { current = last_frame_recording.getPerSec(*mCountIntp); min = frame_recording.getPeriodMinPerSec(*mCountIntp, mNumFrames); max = frame_recording.getPeriodMaxPerSec(*mCountIntp, mNumFrames); mean = frame_recording.getPeriodMeanPerSec(*mCountIntp, mNumFrames); } else { current = last_frame_recording.getSum(*mCountIntp); min = frame_recording.getPeriodMin(*mCountIntp, mNumFrames); max = frame_recording.getPeriodMax(*mCountIntp, mNumFrames); mean = frame_recording.getPeriodMean(*mCountIntp, mNumFrames); } } else if (mMeasurementFloatp) { LLTrace::Recording& last_frame_recording = frame_recording.getLastRecording(); current = last_frame_recording.getLastValue(*mMeasurementFloatp); min = frame_recording.getPeriodMin(*mMeasurementFloatp, mNumFrames); max = frame_recording.getPeriodMax(*mMeasurementFloatp, mNumFrames); mean = frame_recording.getPeriodMean(*mMeasurementFloatp, mNumFrames); } else if (mMeasurementIntp) { LLTrace::Recording& last_frame_recording = frame_recording.getLastRecording(); current = last_frame_recording.getLastValue(*mMeasurementIntp); min = frame_recording.getPeriodMin(*mMeasurementIntp, mNumFrames); max = frame_recording.getPeriodMax(*mMeasurementIntp, mNumFrames); mean = frame_recording.getPeriodMean(*mMeasurementIntp, mNumFrames); } current *= mUnitScale; min *= mUnitScale; max *= mUnitScale; mean *= mUnitScale; if ((mUpdatesPerSec == 0.f) || (mUpdateTimer.getElapsedTimeF32() > 1.f/mUpdatesPerSec) || (mValue == 0.f)) { if (mDisplayMean) { mValue = mean; } else { mValue = current; } mUpdateTimer.reset(); } S32 bar_top, bar_left, bar_right, bar_bottom; if (mOrientation == HORIZONTAL) { bar_top = llmax(5, getRect().getHeight() - 15); bar_left = 0; bar_right = getRect().getWidth() - 40; bar_bottom = llmin(bar_top - 5, 0); } else // VERTICAL { bar_top = llmax(5, getRect().getHeight() - 15); bar_left = 0; bar_right = getRect().getWidth(); bar_bottom = llmin(bar_top - 5, 20); } const S32 tick_length = 4; const S32 tick_width = 1; if (mScaleRange && min < max) { F32 cur_max = mTickSpacing; while(max > cur_max && mMaxBar > cur_max) { cur_max += mTickSpacing; } mCurMaxBar = LLSmoothInterpolation::lerp(mCurMaxBar, cur_max, 0.05f); } else { mCurMaxBar = mMaxBar; } F32 value_scale = (mOrientation == HORIZONTAL) ? (bar_top - bar_bottom)/(mCurMaxBar - mMinBar) : (bar_right - bar_left)/(mCurMaxBar - mMinBar); LLFontGL::getFontMonospace()->renderUTF8(mLabel, 0, 0, getRect().getHeight(), LLColor4(1.f, 1.f, 1.f, 1.f), LLFontGL::LEFT, LLFontGL::TOP); std::string value_format; std::string value_str; if (!mUnitLabel.empty()) { value_format = llformat( "%%.%df%%s", mPrecision); value_str = llformat( value_format.c_str(), mValue, mUnitLabel.c_str()); } else { value_format = llformat( "%%.%df", mPrecision); value_str = llformat( value_format.c_str(), mValue); } // Draw the value. if (mOrientation == HORIZONTAL) { LLFontGL::getFontMonospace()->renderUTF8(value_str, 0, bar_right, getRect().getHeight(), LLColor4(1.f, 1.f, 1.f, 0.5f), LLFontGL::RIGHT, LLFontGL::TOP); } else { LLFontGL::getFontMonospace()->renderUTF8(value_str, 0, bar_right, getRect().getHeight(), LLColor4(1.f, 1.f, 1.f, 0.5f), LLFontGL::RIGHT, LLFontGL::TOP); } value_format = llformat( "%%.%df", mPrecision); if (mDisplayBar && (mCountFloatp || mCountIntp || mMeasurementFloatp || mMeasurementIntp)) { std::string tick_label; // Draw the tick marks. LLGLSUIDefault gls_ui; gGL.getTexUnit(0)->unbind(LLTexUnit::TT_TEXTURE); S32 last_tick = 0; S32 last_label = 0; const S32 MIN_TICK_SPACING = mOrientation == HORIZONTAL ? 20 : 30; const S32 MIN_LABEL_SPACING = mOrientation == HORIZONTAL ? 40 : 60; for (F32 tick_value = mMinBar + mTickSpacing; tick_value <= mCurMaxBar; tick_value += mTickSpacing) { const S32 begin = llfloor((tick_value - mMinBar)*value_scale); const S32 end = begin + tick_width; if (begin - last_tick < MIN_TICK_SPACING) { continue; } last_tick = begin; tick_label = llformat( value_format.c_str(), tick_value); if (mOrientation == HORIZONTAL) { if (begin - last_label > MIN_LABEL_SPACING) { gl_rect_2d(bar_left, end, bar_right - tick_length, begin, LLColor4(1.f, 1.f, 1.f, 0.25f)); LLFontGL::getFontMonospace()->renderUTF8(tick_label, 0, bar_right, begin, LLColor4(1.f, 1.f, 1.f, 0.5f), LLFontGL::LEFT, LLFontGL::VCENTER); last_label = begin; } else { gl_rect_2d(bar_left, end, bar_right - tick_length/2, begin, LLColor4(1.f, 1.f, 1.f, 0.1f)); } } else { if (begin - last_label > MIN_LABEL_SPACING) { gl_rect_2d(begin, bar_top, end, bar_bottom - tick_length, LLColor4(1.f, 1.f, 1.f, 0.25f)); LLFontGL::getFontMonospace()->renderUTF8(tick_label, 0, begin - 1, bar_bottom - tick_length, LLColor4(1.f, 1.f, 1.f, 0.5f), LLFontGL::RIGHT, LLFontGL::TOP); last_label = begin; } else { gl_rect_2d(begin, bar_top, end, bar_bottom - tick_length/2, LLColor4(1.f, 1.f, 1.f, 0.1f)); } } } // draw background bar. gl_rect_2d(bar_left, bar_top, bar_right, bar_bottom, LLColor4(0.f, 0.f, 0.f, 0.25f)); if (frame_recording.getNumPeriods() == 0) { // No data, don't draw anything... return; } // draw min and max S32 begin = (S32) ((min - mMinBar) * value_scale); if (begin < 0) { begin = 0; llwarns << "Min:" << min << llendl; } S32 end = (S32) ((max - mMinBar) * value_scale); if (mOrientation == HORIZONTAL) { gl_rect_2d(bar_left, end, bar_right, begin, LLColor4(1.f, 0.f, 0.f, 0.25f)); } else // VERTICAL { gl_rect_2d(begin, bar_top, end, bar_bottom, LLColor4(1.f, 0.f, 0.f, 0.25f)); } F32 span = (mOrientation == HORIZONTAL) ? (bar_right - bar_left) : (bar_top - bar_bottom); if (mDisplayHistory && (mCountFloatp || mCountIntp || mMeasurementFloatp || mMeasurementIntp)) { const S32 num_values = frame_recording.getNumPeriods() - 1; F32 begin = 0; F32 end = 0; S32 i; gGL.color4f( 1.f, 0.f, 0.f, 1.f ); gGL.begin( LLRender::QUADS ); const S32 max_frame = llmin(mNumFrames, num_values); U32 num_samples = 0; for (i = 1; i <= max_frame; i++) { F32 offset = ((F32)i / (F32)mNumFrames) * span; LLTrace::Recording& recording = frame_recording.getPrevRecording(i); if (mPerSec) { if (mCountFloatp) { begin = ((recording.getPerSec(*mCountFloatp) - mMinBar) * value_scale); end = ((recording.getPerSec(*mCountFloatp) - mMinBar) * value_scale) + 1; num_samples = recording.getSampleCount(*mCountFloatp); } else if (mCountIntp) { begin = ((recording.getPerSec(*mCountIntp) - mMinBar) * value_scale); end = ((recording.getPerSec(*mCountIntp) - mMinBar) * value_scale) + 1; num_samples = recording.getSampleCount(*mCountIntp); } else if (mMeasurementFloatp) { //rate isn't defined for measurement stats, so use mean begin = ((recording.getMean(*mMeasurementFloatp) - mMinBar) * value_scale); end = ((recording.getMean(*mMeasurementFloatp) - mMinBar) * value_scale) + 1; num_samples = recording.getSampleCount(*mMeasurementFloatp); } else if (mMeasurementIntp) { //rate isn't defined for measurement stats, so use mean begin = ((recording.getMean(*mMeasurementIntp) - mMinBar) * value_scale); end = ((recording.getMean(*mMeasurementIntp) - mMinBar) * value_scale) + 1; num_samples = recording.getSampleCount(*mMeasurementIntp); } } else { if (mCountFloatp) { begin = ((recording.getSum(*mCountFloatp) - mMinBar) * value_scale); end = ((recording.getSum(*mCountFloatp) - mMinBar) * value_scale) + 1; num_samples = recording.getSampleCount(*mCountFloatp); } else if (mCountIntp) { begin = ((recording.getSum(*mCountIntp) - mMinBar) * value_scale); end = ((recording.getSum(*mCountIntp) - mMinBar) * value_scale) + 1; num_samples = recording.getSampleCount(*mCountIntp); } else if (mMeasurementFloatp) { begin = ((recording.getMean(*mMeasurementFloatp) - mMinBar) * value_scale); end = ((recording.getMean(*mMeasurementFloatp) - mMinBar) * value_scale) + 1; num_samples = recording.getSampleCount(*mMeasurementFloatp); } else if (mMeasurementIntp) { begin = ((recording.getMean(*mMeasurementIntp) - mMinBar) * value_scale); end = ((recording.getMean(*mMeasurementIntp) - mMinBar) * value_scale) + 1; num_samples = recording.getSampleCount(*mMeasurementIntp); } } if (!num_samples) continue; if (mOrientation == HORIZONTAL) { gGL.vertex2f((F32)bar_right - offset, end); gGL.vertex2f((F32)bar_right - offset, begin); gGL.vertex2f((F32)bar_right - offset - 1.f, begin); gGL.vertex2f((F32)bar_right - offset - 1.f, end); } else { gGL.vertex2f(begin, (F32)bar_bottom+offset+1.f); gGL.vertex2f(begin, (F32)bar_bottom+offset); gGL.vertex2f(end, (F32)bar_bottom+offset); gGL.vertex2f(end, (F32)bar_bottom+offset+1.f); } } gGL.end(); } else { S32 begin = (S32) ((current - mMinBar) * value_scale) - 1; S32 end = (S32) ((current - mMinBar) * value_scale) + 1; // draw current if (mOrientation == HORIZONTAL) { gl_rect_2d(bar_left, end, bar_right, begin, LLColor4(1.f, 0.f, 0.f, 1.f)); } else { gl_rect_2d(begin, bar_top, end, bar_bottom, LLColor4(1.f, 0.f, 0.f, 1.f)); } } // draw mean bar { const S32 begin = (S32) ((mean - mMinBar) * value_scale) - 1; const S32 end = (S32) ((mean - mMinBar) * value_scale) + 1; if (mOrientation == HORIZONTAL) { gl_rect_2d(bar_left - 2, begin, bar_right + 2, end, LLColor4(0.f, 1.f, 0.f, 1.f)); } else { gl_rect_2d(begin, bar_top + 2, end, bar_bottom - 2, LLColor4(0.f, 1.f, 0.f, 1.f)); } } } LLView::draw(); } void LLStatBar::setStat(const std::string& stat_name) { mCountFloatp = LLTrace::CountStatHandle<>::getInstance(stat_name); mCountIntp = LLTrace::CountStatHandle::getInstance(stat_name); mMeasurementFloatp = LLTrace::MeasurementStatHandle<>::getInstance(stat_name); mMeasurementIntp = LLTrace::MeasurementStatHandle::getInstance(stat_name); } void LLStatBar::setRange(F32 bar_min, F32 bar_max, F32 tick_spacing) { mMinBar = bar_min; mMaxBar = bar_max; mTickSpacing = tick_spacing; } LLRect LLStatBar::getRequiredRect() { LLRect rect; if (mDisplayBar) { if (mDisplayHistory) { rect.mTop = mMaxHeight; } else { rect.mTop = 40; } } else { rect.mTop = 14; } return rect; }