/* 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., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA. */ #include "StdAfx.h" #include "MeterLine.h" #include "Measure.h" #include "Error.h" using namespace Gdiplus; /* ** The constructor ** */ CMeterLine::CMeterLine(CMeterWindow* meterWindow, const WCHAR* name) : CMeter(meterWindow, name), m_Autoscale(false), m_HorizontalLines(false), m_Flip(false), m_LineWidth(1.0), m_HorizontalColor(Color::Black), m_CurrentPos(), m_GraphStartLeft(false), m_GraphHorizontalOrientation(false) { } /* ** The destructor ** */ CMeterLine::~CMeterLine() { } /* ** create the buffer for the lines ** */ void CMeterLine::Initialize() { CMeter::Initialize(); size_t colorsSize = m_Colors.size(); size_t allValuesSize = m_AllValues.size(); size_t num = (allValuesSize > 0) ? m_AllValues[0].size() : 0; int maxSize = m_GraphHorizontalOrientation ? m_H : m_W; if (colorsSize != allValuesSize) { if (colorsSize > allValuesSize) { for (size_t i = allValuesSize; i < colorsSize; ++i) { m_AllValues.push_back(std::vector()); if (maxSize > 0) { m_AllValues.back().assign(maxSize, 0.0); } } } else { m_AllValues.resize(colorsSize); } } if (maxSize < 0 || num != (size_t)maxSize) { if (m_CurrentPos >= maxSize) m_CurrentPos = 0; num = (maxSize < 0) ? 0 : maxSize; for (size_t i = 0; i < allValuesSize; ++i) { if (num != m_AllValues[i].size()) { m_AllValues[i].resize(num, 0.0); } } } } /* ** Read the options specified in the ini file. ** */ void CMeterLine::ReadOptions(CConfigParser& parser, const WCHAR* section) { WCHAR tmpName[64]; // Store the current number of lines so we know if the buffer needs to be updated int oldLineCount = (int)m_Colors.size(); int oldSize = m_GraphHorizontalOrientation ? m_H : m_W; bool oldGraphHorizontalOrientation = m_GraphHorizontalOrientation; CMeter::ReadOptions(parser, section); int lineCount = parser.ReadInt(section, L"LineCount", 1); m_Colors.clear(); m_ScaleValues.clear(); for (int i = 0; i < lineCount; ++i) { if (i == 0) { wcsncpy_s(tmpName, L"LineColor", _TRUNCATE); } else { _snwprintf_s(tmpName, _TRUNCATE, L"LineColor%i", i + 1); } m_Colors.push_back(parser.ReadColor(section, tmpName, Color::White)); if (i == 0) { wcsncpy_s(tmpName, L"Scale", _TRUNCATE); } else { _snwprintf_s(tmpName, _TRUNCATE, L"Scale%i", i + 1); } m_ScaleValues.push_back(parser.ReadFloat(section, tmpName, 1.0)); } m_Flip = 0!=parser.ReadInt(section, L"Flip", 0); m_Autoscale = 0!=parser.ReadInt(section, L"AutoScale", 0); m_LineWidth = parser.ReadFloat(section, L"LineWidth", 1.0); m_HorizontalLines = 0!=parser.ReadInt(section, L"HorizontalLines", 0); ARGB color = parser.ReadColor(section, L"HorizontalColor", Color::Black); // This is left here for backwards compatibility m_HorizontalColor = parser.ReadColor(section, L"HorizontalLineColor", color); // This is what it should be const WCHAR* graph = parser.ReadString(section, L"GraphStart", L"RIGHT").c_str(); if (_wcsicmp(graph, L"RIGHT") == 0) { m_GraphStartLeft = false; } else if (_wcsicmp(graph, L"LEFT") == 0) { m_GraphStartLeft = true; } else { LogWithArgs(LOG_ERROR, L"GraphStart=%s is not valid in [%s]", graph, m_Name.c_str()); } graph = parser.ReadString(section, L"GraphOrientation", L"VERTICAL").c_str(); if (_wcsicmp(graph, L"VERTICAL") == 0) { m_GraphHorizontalOrientation = false; } else if (_wcsicmp(graph, L"HORIZONTAL") == 0) { m_GraphHorizontalOrientation = true; } else { LogWithArgs(LOG_ERROR, L"GraphOrientation=%s is not valid in [%s]", graph, m_Name.c_str()); } if (m_Initialized) { int maxSize = m_GraphHorizontalOrientation ? m_H : m_W; if (oldLineCount != lineCount || oldSize != maxSize || oldGraphHorizontalOrientation != m_GraphHorizontalOrientation) { m_AllValues.clear(); m_CurrentPos = 0; Initialize(); } } } /* ** Updates the value(s) from the measures. ** */ bool CMeterLine::Update() { if (CMeter::Update() && !m_Measures.empty()) { int maxSize = m_GraphHorizontalOrientation ? m_H : m_W; if (maxSize > 0) { int allValuesSize = (int)m_AllValues.size(); int counter = 0; for (auto i = m_Measures.cbegin(); counter < allValuesSize && i != m_Measures.cend(); ++i, ++counter) { m_AllValues[counter][m_CurrentPos] = (*i)->GetValue(); } ++m_CurrentPos; if (m_CurrentPos >= maxSize) m_CurrentPos = 0; } return true; } return false; } /* ** Draws the meter on the double buffer ** */ bool CMeterLine::Draw(Graphics& graphics) { int maxSize = m_GraphHorizontalOrientation ? m_H : m_W; if (!CMeter::Draw(graphics) || maxSize <= 0) return false; double maxValue = 0.0; int counter = 0; // Find the maximum value if (m_Autoscale) { double newValue = 0; std::vector< std::vector >::const_iterator i = m_AllValues.begin(); counter = 0; for (; i != m_AllValues.end(); ++i) { double scale = m_ScaleValues[counter]; std::vector::const_iterator j = (*i).begin(); for (; j != (*i).end(); ++j) { double val = (*j) * scale; newValue = max(newValue, val); } ++counter; } // Scale the value up to nearest power of 2 if (newValue > DBL_MAX / 2.0) { maxValue = DBL_MAX; } else { maxValue = 2.0; while (maxValue < newValue) { maxValue *= 2.0; } } } else { if (!m_Measures.empty()) { maxValue = m_Measures[0]->GetMaxValue(); std::vector::const_iterator i = m_Measures.begin(); for (; i != m_Measures.end(); ++i) { double val = (*i)->GetMaxValue(); maxValue = max(maxValue, val); } } if (maxValue == 0.0) { maxValue = 1.0; } } 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 if (m_GraphHorizontalOrientation) { const REAL W = m_W - 1.0f; counter = 0; std::vector< std::vector >::const_iterator i = m_AllValues.begin(); for (; i != m_AllValues.end(); ++i) { // Draw a line REAL X, oldX; const double scale = m_ScaleValues[counter] * W / maxValue; int pos = m_CurrentPos; oldX = (REAL)((*i)[pos] * scale); oldX = min(oldX, W); oldX = max(oldX, 0.0f); oldX = x + (m_GraphStartLeft ? oldX : W - oldX); // Cache all lines GraphicsPath path; if (!m_Flip) { for (int j = y + 1, R = y + m_H; j < R; ++j) { ++pos; if (pos >= m_H) pos = 0; X = (REAL)((*i)[pos] * scale); X = min(X, W); X = max(X, 0.0f); X = x + (m_GraphStartLeft ? X : W - X); path.AddLine(oldX, (REAL)(j - 1), X, (REAL)j); oldX = X; } } else { for (int j = y + m_H, R = y + 1; j > R; --j) { ++pos; if (pos >= m_H) pos = 0; X = (REAL)((*i)[pos] * scale); X = min(X, W); X = max(X, 0.0f); X = x + (m_GraphStartLeft ? X : W - X); path.AddLine(oldX, (REAL)(j - 1), X, (REAL)(j - 2)); oldX = X; } } // Draw cached lines Pen pen(m_Colors[counter], (REAL)m_LineWidth); pen.SetLineJoin(LineJoinBevel); graphics.DrawPath(&pen, &path); ++counter; } } else { const REAL H = m_H - 1.0f; counter = 0; std::vector< std::vector >::const_iterator i = m_AllValues.begin(); for (; i != m_AllValues.end(); ++i) { // Draw a line REAL Y, oldY; const double scale = m_ScaleValues[counter] * H / maxValue; int pos = m_CurrentPos; oldY = (REAL)((*i)[pos] * scale); oldY = min(oldY, H); oldY = max(oldY, 0.0f); oldY = y + (m_Flip ? oldY : H - oldY); // Cache all lines GraphicsPath path; if (!m_GraphStartLeft) { for (int j = x + 1, R = x + m_W; j < R; ++j) { ++pos; if (pos >= m_W) pos = 0; Y = (REAL)((*i)[pos] * scale); Y = min(Y, H); Y = max(Y, 0.0f); Y = y + (m_Flip ? Y : H - Y); path.AddLine((REAL)(j - 1), oldY, (REAL)j, Y); oldY = Y; } } else { for (int j = x + m_W, R = x + 1; j > R; --j) { ++pos; if (pos >= m_W) pos = 0; Y = (REAL)((*i)[pos] * scale); Y = min(Y, H); Y = max(Y, 0.0f); Y = y + (m_Flip ? Y : H - Y); path.AddLine((REAL)(j - 1), oldY, (REAL)(j - 2), Y); oldY = Y; } } // Draw cached lines Pen pen(m_Colors[counter], (REAL)m_LineWidth); pen.SetLineJoin(LineJoinBevel); graphics.DrawPath(&pen, &path); ++counter; } } return true; } /* ** Overwritten method to handle the other measure bindings. ** */ void CMeterLine::BindMeasures(CConfigParser& parser, const WCHAR* section) { if (BindPrimaryMeasure(parser, section, false)) { BindSecondaryMeasures(parser, section); } }