/* Copyright (C) 2001 Kimmo Pekkola This program is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 2 of the License, or (at your option) any later version. This program 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 General Public License for more details. You should have received a copy of the GNU General Public License along with this program; if not, write to the Free Software Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA. */ #pragma warning(disable: 4786) #pragma warning(disable: 4996) #include "MeterLine.h" #include "Measure.h" #include "Error.h" #include #include using namespace Gdiplus; /* ** CMeterLine ** ** The constructor ** */ CMeterLine::CMeterLine(CMeterWindow* meterWindow) : CMeter(meterWindow) { m_Autoscale = false; m_AntiAlias = false; m_HorizontalLines = false; m_HorizontalColor = 0; m_CurrentPos = 0; m_Flip = false; m_LineWidth = 1.0; } /* ** ~CMeterLine ** ** The destructor ** */ CMeterLine::~CMeterLine() { } /* ** Initialize ** ** create the buffer for the lines ** */ void CMeterLine::Initialize() { CMeter::Initialize(); std::vector::iterator i = m_Colors.begin(); for ( ; i != m_Colors.end(); i++) { m_AllValues.push_back(std::vector()); } } /* ** ReadConfig ** ** Read the meter-specific configs from the ini-file. ** */ void CMeterLine::ReadConfig(const WCHAR* section) { int i; WCHAR tmpName[256]; // Read common configs CMeter::ReadConfig(section); CConfigParser& parser = m_MeterWindow->GetParser(); int lineCount = parser.ReadInt(section, L"LineCount", 1); for (i = 0; i < lineCount; i++) { if (i == 0) { wcscpy(tmpName, L"LineColor"); } else { swprintf(tmpName, L"LineColor%i", i + 1); } m_Colors.push_back(parser.ReadColor(section, tmpName, Color::White)); if (i == 0) { wcscpy(tmpName, L"Scale"); } else { swprintf(tmpName, L"Scale%i", i + 1); } m_ScaleValues.push_back(parser.ReadFloat(section, tmpName, 1.0)); if (i != 0) { swprintf(tmpName, L"MeasureName%i", i + 1); m_MeasureNames.push_back(parser.ReadString(section, tmpName, L"")); } } m_Flip = 0!=parser.ReadInt(section, L"Flip", 0); m_Autoscale = 0!=parser.ReadInt(section, L"AutoScale", 0); m_AntiAlias = 0!=parser.ReadInt(section, L"AntiAlias", 0); m_LineWidth = parser.ReadFloat(section, L"LineWidth", 1.0); m_HorizontalLines = 0!=parser.ReadInt(section, L"HorizontalLines", 0); m_HorizontalColor = parser.ReadColor(section, L"HorizontalColor", Color::Black); // This is left here for backwards compatibility m_HorizontalColor = parser.ReadColor(section, L"HorizontalLineColor", m_HorizontalColor); // This is what it should be } /* ** Update ** ** Updates the value(s) from the measures. ** */ bool CMeterLine::Update() { if (CMeter::Update() && m_Measure) { // Collect the values if (!m_Measure->IsDisabled()) { double value = m_Measure->GetValue(); if ((int)m_AllValues[0].size() < m_W) { m_AllValues[0].push_back(value); } else { m_AllValues[0][m_CurrentPos] = value; } } int counter = 1; std::vector::iterator i = m_Measures.begin(); for ( ; i != m_Measures.end(); i++) { double value = (*i)->GetValue(); if ((int)m_AllValues[counter].size() < m_W) { m_AllValues[counter].push_back(value); } else { m_AllValues[counter][m_CurrentPos] = value; } counter++; } m_CurrentPos++; if (m_CurrentPos >= m_W) { m_CurrentPos = 0; } return true; } return false; } /* ** Draw ** ** Draws the meter on the double buffer ** */ bool CMeterLine::Draw(Graphics& graphics) { if(!CMeter::Draw(graphics)) return false; double maxValue = 0.0; int counter = 0; // Find the maximum value if (m_Autoscale) { double newValue = 0; std::vector< std::vector >::iterator i = m_AllValues.begin(); counter = 0; for (; i != m_AllValues.end(); i++) { std::vector::iterator j = (*i).begin(); for (; j != (*i).end(); j++) { newValue = max(newValue, (*j) * m_ScaleValues[counter]); } counter++; } // Scale the value up to nearest power of 2 maxValue = 2; while(maxValue < newValue && maxValue != 0) { maxValue *= 2; } } else { if (m_Measure) { maxValue = m_Measure->GetMaxValue(); std::vector::iterator i = m_Measures.begin(); for (; i != m_Measures.end(); i++) { maxValue = max(maxValue, (*i)->GetMaxValue()); } } } if (maxValue == 0.0) { maxValue = 1.0; } SmoothingMode mode = graphics.GetSmoothingMode(); if (m_AntiAlias) { graphics.SetSmoothingMode(SmoothingModeAntiAlias); } int x = GetX(); int y = GetY(); // Draw the horizontal lines if (m_HorizontalLines) { // Calc the max number of lines we should draw int maxLines = m_H / 4; // one line per 4 pixels is max int numOfLines; // Check the highest power of 2 that fits in maxLines int power = 2; while(power < maxLines) { power *= 2; } numOfLines = ((int)maxValue % power) + 1; Pen pen(m_HorizontalColor); REAL Y; for (int j = 0; j < numOfLines; j++) { Y = (REAL)((j + 1) * m_H / (numOfLines + 1)); Y = y + m_H - Y - 1; graphics.DrawLine(&pen, (REAL)x, Y, (REAL)(x + m_W - 1), Y); // GDI+ } } // Draw all the lines counter = 0; std::vector< std::vector >::iterator i = m_AllValues.begin(); for (; i != m_AllValues.end(); i++) { // Draw a line int X = x; REAL Y = 0; REAL oldY = 0; int pos = m_CurrentPos; if (pos >= m_W) pos = 0; Pen pen(m_Colors[counter], (REAL)m_LineWidth); for (int j = 0; j < m_W; j++) { if (pos < (int)(*i).size()) { Y = (REAL)((*i)[pos] * m_ScaleValues[counter] * (m_H - 1) / maxValue); Y = min(Y, m_H - 1); Y = max(Y, 0); } else { Y = 0; } if (m_Flip) { Y = y + Y; } else { Y = y + m_H - Y - 1; } if (j != 0) { graphics.DrawLine(&pen, (REAL)X - 1, oldY, (REAL)X, Y); // GDI+ } oldY = Y; X++; pos++; if (pos >= m_W) pos = 0; } counter++; } if (m_AntiAlias) { graphics.SetSmoothingMode(mode); } return true; } /* ** BindMeasure ** ** Overwritten method to handle the other measure bindings. ** */ void CMeterLine::BindMeasure(std::list& measures) { CMeter::BindMeasure(measures); std::vector::iterator j = m_MeasureNames.begin(); for (; j != m_MeasureNames.end(); j++) { // Go through the list and check it there is a secondary measure for us std::list::iterator i = measures.begin(); for( ; i != measures.end(); i++) { if(_wcsicmp((*i)->GetName(), (*j).c_str()) == 0) { m_Measures.push_back(*i); break; } } if (i == measures.end()) { throw CError(std::wstring(L"The meter [") + m_Name + L"] cannot be bound with [" + (*j) + L"]!", __LINE__, __FILE__); } } }