/* 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: 4996) #include "Error.h" #include "Meter.h" #include "MeterBitmap.h" #include "MeterBar.h" #include "MeterHistogram.h" #include "MeterString.h" #include "MeterImage.h" #include "MeterLine.h" #include "MeterRoundLine.h" #include "MeterRotator.h" #include "MeterButton.h" #include "Measure.h" #include "Rainmeter.h" using namespace Gdiplus; int CMeter::c_OldX = 0; int CMeter::c_OldY = 0; /* ** CMeter ** ** The constructor ** */ CMeter::CMeter(CMeterWindow* meterWindow) { m_Measure = NULL; m_X = 0; m_Y = 0; m_W = 0; m_H = 0; m_RelativeMeter = NULL; m_Hidden = false; m_SolidBevel = BEVELTYPE_NONE; m_MouseOver = false; m_UpdateDivider = 1; m_UpdateCounter = 0; m_RelativeX = POSITION_ABSOLUTE; m_RelativeY = POSITION_ABSOLUTE; m_MeterWindow = NULL; m_SolidAngle = 0.0; m_MeterWindow = meterWindow; m_AntiAlias = false; } /* ** ~CMeter ** ** The destructor ** */ CMeter::~CMeter() { } /* ** Initialize ** ** Initializes the meter. The base implementation just stores the pointer. ** Usually this method is overwritten by the inherited classes, which load ** bitmaps and such things during initialization. ** */ void CMeter::Initialize() { } /* ** GetX ** ** Returns the X-position of the meter. ** */ int CMeter::GetX(bool abs) { if (m_RelativeX != POSITION_ABSOLUTE && m_MeterWindow) { if (m_RelativeMeter == NULL) { std::list& meters = m_MeterWindow->GetMeters(); std::list::iterator iter = meters.begin(); // Find this meter for ( ; iter != meters.end(); iter++) { if (*iter == this && iter != meters.begin()) { iter--; m_RelativeMeter = (*iter); if (m_RelativeX == POSITION_RELATIVE_TL) { return m_RelativeMeter->GetX(true) + m_X; } else { return m_RelativeMeter->GetX(true) + m_RelativeMeter->GetW() + m_X; } } } } else { if (m_RelativeX == POSITION_RELATIVE_TL) { return m_RelativeMeter->GetX(true) + m_X; } else { return m_RelativeMeter->GetX(true) + m_RelativeMeter->GetW() + m_X; } } } return m_X; } /* ** GetY ** ** Returns the Y-position of the meter. ** */ int CMeter::GetY(bool abs) { if (m_RelativeY != POSITION_ABSOLUTE && m_MeterWindow) { if (m_RelativeMeter == NULL) { std::list& meters = m_MeterWindow->GetMeters(); std::list::iterator iter = meters.begin(); // Find this meter for ( ; iter != meters.end(); iter++) { if (*iter == this && iter != meters.begin()) { iter--; m_RelativeMeter = (*iter); if (m_RelativeY == POSITION_RELATIVE_TL) { return m_RelativeMeter->GetY() + m_Y; } else { return m_RelativeMeter->GetY() + m_RelativeMeter->GetH() + m_Y; } } } } else { if (m_RelativeY == POSITION_RELATIVE_TL) { return m_RelativeMeter->GetY() + m_Y; } else { return m_RelativeMeter->GetY() + m_RelativeMeter->GetH() + m_Y; } } } return m_Y; } /* ** HitTest ** ** Checks if the given point is inside the meter. ** */ bool CMeter::HitTest(int x, int y) { if (x >= GetX() && x <= GetX() + GetW() && y >= GetY() && y <= GetY() + GetH()) { return true; } return false; } /* ** ReadConfig ** ** Reads the meter-specific configs from the ini-file. The base implementation ** reads the common settings for all meters. The inherited classes must call ** the base implementation if they overwrite this method. ** */ void CMeter::ReadConfig(const WCHAR* section) { CConfigParser& parser = m_MeterWindow->GetParser(); const std::wstring& x = parser.ReadString(section, L"X", L"0"); if (x.size() > 0) { m_X = _wtoi(x.c_str()); if (x[x.size() - 1] == L'r') { m_RelativeX = POSITION_RELATIVE_TL; } else if (x[x.size() - 1] == L'R') { m_RelativeX = POSITION_RELATIVE_BR; } } const std::wstring& y = parser.ReadString(section, L"Y", L"0"); if (y.size() > 0) { m_Y = _wtoi(y.c_str()); if (y[y.size() - 1] == L'r') { m_RelativeY = POSITION_RELATIVE_TL; } else if (y[y.size() - 1] == L'R') { m_RelativeY = POSITION_RELATIVE_BR; } } m_W = parser.ReadInt(section, L"W", 1); m_H = parser.ReadInt(section, L"H", 1); m_Hidden = 0!=parser.ReadInt(section, L"Hidden", 0); m_SolidBevel = (BEVELTYPE)parser.ReadInt(section, L"BevelType", m_SolidBevel); m_SolidColor = parser.ReadColor(section, L"SolidColor", Color(0, 0, 0, 0)); m_SolidColor2 = parser.ReadColor(section, L"SolidColor2", m_SolidColor); m_SolidAngle = (Gdiplus::REAL)parser.ReadFloat(section, L"GradientAngle", 0.0); m_RightMouseDownAction = parser.ReadString(section, L"RightMouseDownAction", L""); m_LeftMouseDownAction = parser.ReadString(section, L"LeftMouseDownAction", L""); m_RightMouseUpAction = parser.ReadString(section, L"RightMouseUpAction", L""); m_LeftMouseUpAction = parser.ReadString(section, L"LeftMouseUpAction", L""); m_MouseOverAction = parser.ReadString(section, L"MouseOverAction", L""); m_MouseLeaveAction = parser.ReadString(section, L"MouseLeaveAction", L""); m_MeasureName = parser.ReadString(section, L"MeasureName", L""); m_UpdateDivider = parser.ReadInt(section, L"UpdateDivider", 1); m_UpdateCounter = m_UpdateDivider; m_AntiAlias = 0!=parser.ReadInt(section, L"AntiAlias", 0); std::vector matrix = parser.ReadFloats(section, L"TransformationMatrix"); if (matrix.size() == 6) { m_Transformation.SetElements(matrix[0], matrix[1], matrix[2], matrix[3], matrix[4], matrix[5]); } else if (!matrix.empty()) { DebugLog(L"The transformation matrix has incorrect number of values:", parser.ReadString(section, L"TransformationMatrix", L"").c_str()); } if (m_W == 0 || m_H == 0) { throw CError(std::wstring(L"The meter ") + section + L" has zero dimensions.", __LINE__, __FILE__); } } /* ** BindMeasure ** ** Binds this meter to the given measure. The same measure can be bound to ** several meters but one meter and only be bound to one measure. ** */ void CMeter::BindMeasure(std::list& measures) { // The meter is not bound to anything if (m_MeasureName.empty()) { throw CError(std::wstring(L"The meter [") + m_Name + L"] is not bound to anything!", __LINE__, __FILE__); } // Go through the list and check it there is a measure for us std::list::iterator i = measures.begin(); for( ; i != measures.end(); i++) { if(_wcsicmp((*i)->GetName(), m_MeasureName.c_str()) == 0) { m_Measure = (*i); return; } } // Error :) throw CError(std::wstring(L"The meter [") + m_Name + L"] cannot be bound with [" + m_MeasureName + L"]!", __LINE__, __FILE__); } /* ** Create ** ** Creates the given meter. This is the factory method for the meters. ** If new meters are implemented this method needs to be updated. ** */ CMeter* CMeter::Create(const WCHAR* meter, CMeterWindow* meterWindow) { if(_wcsicmp(L"HISTOGRAM", meter) == 0) { return new CMeterHistogram(meterWindow); } else if(_wcsicmp(L"STRING", meter) == 0) { return new CMeterString(meterWindow); } else if(_wcsicmp(L"BAR", meter) == 0) { return new CMeterBar(meterWindow); } else if(_wcsicmp(L"BITMAP", meter) == 0) { return new CMeterBitmap(meterWindow); } else if(_wcsicmp(L"IMAGE", meter) == 0) { return new CMeterImage(meterWindow); } else if(_wcsicmp(L"LINE", meter) == 0) { return new CMeterLine(meterWindow); } else if(_wcsicmp(L"ROUNDLINE", meter) == 0) { return new CMeterRoundLine(meterWindow); } else if(_wcsicmp(L"ROTATOR", meter) == 0) { return new CMeterRotator(meterWindow); } else if(_wcsicmp(L"BUTTON", meter) == 0) { return new CMeterButton(meterWindow); } // Error throw CError(std::wstring(L"No such meter: ") + meter, __LINE__, __FILE__); return NULL; } /* ** Update ** ** Updates the value(s) from the measures. Derived classes should ** only update if this returns true; */ bool CMeter::Update() { // Only update the meter's value when the divider is equal to the counter m_UpdateCounter++; if (m_UpdateCounter < m_UpdateDivider) return false; m_UpdateCounter = 0; return true; } /* ** Draw ** ** Draws the solid background & bevel if such are defined */ bool CMeter::Draw(Graphics& graphics) { if (IsHidden()) return false; if (m_AntiAlias) { graphics.SetInterpolationMode(InterpolationModeBicubic); graphics.SetSmoothingMode(SmoothingModeAntiAlias); } else { graphics.SetInterpolationMode(InterpolationModeDefault); graphics.SetSmoothingMode(SmoothingModeNone); } if (m_SolidColor.GetA() != 0 || m_SolidColor2.GetA() != 0) { int x = GetX(); int y = GetY(); if (m_SolidColor.GetValue() == m_SolidColor2.GetValue()) { SolidBrush solid(m_SolidColor); graphics.FillRectangle(&solid, x, y, m_W, m_H); } else { Rect r(x, y, m_W, m_H); LinearGradientBrush gradient(r, m_SolidColor, m_SolidColor2, m_SolidAngle, TRUE); graphics.FillRectangle(&gradient, r); } } if (m_SolidBevel != BEVELTYPE_NONE) { int x = GetX(); int y = GetY(); Pen light(Color(255, 255, 255, 255)); Pen dark(Color(255, 0, 0, 0)); if (m_SolidBevel == BEVELTYPE_DOWN) { light.SetColor(Color(255, 0, 0, 0)); dark.SetColor(Color(255, 255, 255, 255)); } // The bevel is drawn outside the meter Rect rect(x - 2, y - 2, m_W + 4, m_H + 4); DrawBevel(graphics, rect, light, dark); } return true; } /* ** DrawBevel ** ** Draws a bevel inside the given area */ void CMeter::DrawBevel(Graphics& graphics, Rect& rect, Pen& light, Pen& dark) { int l = rect.GetLeft(); int r = rect.GetRight() - 1; int t = rect.GetTop(); int b = rect.GetBottom() - 1; graphics.DrawLine(&light, l, t, l, b); graphics.DrawLine(&light, l, t, r, t); graphics.DrawLine(&light, l + 1, t + 1, l + 1, b - 1); graphics.DrawLine(&light, l + 1, t + 1, r - 1, l + 1); graphics.DrawLine(&dark, l, b, r, b); graphics.DrawLine(&dark, r, t, r, b); graphics.DrawLine(&dark, l + 1, b - 1, r - 1, b - 1); graphics.DrawLine(&dark, r - 1, t + 1, r - 1, b - 1); }