/* Copyright (C) 2000 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. */ #include "StdAfx.h" #include "Measure.h" #include "MeasureCPU.h" #include "MeasureMemory.h" #include "MeasurePhysicalMemory.h" #include "MeasureVirtualMemory.h" #include "MeasureNetIn.h" #include "MeasureNetOut.h" #include "MeasureNetTotal.h" #include "MeasureDiskSpace.h" #include "MeasureUptime.h" #include "MeasurePlugin.h" #include "MeasureRegistry.h" #include "MeasureTime.h" #include "MeasureCalc.h" #include "MeasureScript.h" #include "Rainmeter.h" #include "Error.h" #include "Litestep.h" enum AUTOSCALE_INDEX { AUTOSCALE_INDEX_1024 = 0, AUTOSCALE_INDEX_1000 = 1 }; static const double g_TblScale[2][4] = { { 1024.0 * 1024.0 * 1024.0 * 1024.0, 1024.0 * 1024.0 * 1024.0, 1024.0 * 1024.0, 1024.0 }, { 1000.0 * 1000.0 * 1000.0 * 1000.0, 1000.0 * 1000.0 * 1000.0, 1000.0 * 1000.0, 1000.0 } }; const int MEDIAN_SIZE = 7; extern CRainmeter* Rainmeter; /* ** CMeasure ** ** The constructor ** */ CMeasure::CMeasure(CMeterWindow* meterWindow, const WCHAR* name) : m_MeterWindow(meterWindow), m_Name(name), m_ANSIName(ConvertToAscii(name)), m_DynamicVariables(false), m_Invert(false), m_LogMaxValue(false), m_MinValue(), m_MaxValue(1.0), m_Value(), m_MedianPos(), m_AveragePos(), m_AverageSize(), m_IfEqualValue(), m_IfAboveValue(), m_IfBelowValue(), m_IfEqualCommited(false), m_IfAboveCommited(false), m_IfBelowCommited(false), m_Disabled(false), m_UpdateDivider(1), m_UpdateCounter(1), m_Initialized(false) { } /* ** ~CMeasure ** ** The destructor ** */ CMeasure::~CMeasure() { } /* ** Initialize ** ** Initializes the measure. ** */ void CMeasure::Initialize() { m_Initialized = true; } /* ** ReadConfig ** ** Reads the common configs for all Measures. The inherited classes ** must call the base implementation if they overwrite this method. ** */ void CMeasure::ReadConfig(CConfigParser& parser, const WCHAR* section) { // Clear substitutes to prevent from being added more than once. if (!m_Substitute.empty()) { m_Substitute.clear(); } m_Invert = 0!=parser.ReadInt(section, L"InvertMeasure", 0); if (!m_Initialized) { m_Disabled = 0!=parser.ReadInt(section, L"Disabled", 0); } else { const std::wstring& result = parser.ReadString(section, L"Disabled", L"0"); if (parser.GetLastReplaced()) { m_Disabled = 0!=(int)parser.ParseDouble(result, 0.0, true); } } int updateDivider = parser.ReadInt(section, L"UpdateDivider", 1); if (updateDivider != m_UpdateDivider) { m_UpdateCounter = m_UpdateDivider = updateDivider; } m_MinValue = parser.ReadFloat(section, L"MinValue", m_MinValue); m_MaxValue = parser.ReadFloat(section, L"MaxValue", m_MaxValue); // The ifabove/ifbelow define actions that are ran when the value goes above/below the given number. m_IfAboveValue = parser.ReadFloat(section, L"IfAboveValue", 0.0); m_IfAboveAction = parser.ReadString(section, L"IfAboveAction", L"", false); m_IfBelowValue = parser.ReadFloat(section, L"IfBelowValue", 0.0); m_IfBelowAction = parser.ReadString(section, L"IfBelowAction", L"", false); m_IfEqualValue = parser.ReadFloat(section, L"IfEqualValue", 0.0); m_IfEqualAction = parser.ReadString(section, L"IfEqualAction", L"", false); m_AverageSize = parser.ReadUInt(section, L"AverageSize", 0); m_DynamicVariables = 0!=parser.ReadInt(section, L"DynamicVariables", 0); std::wstring subs = parser.ReadString(section, L"Substitute", L""); if (!subs.empty() && (subs[0] != L'\"' || subs[subs.length() - 1] != L'\'') && (subs[0] != L'\'' || subs[subs.length() - 1] != L'\"')) { // Add quotes since they are removed by the GetProfileString subs.insert(0, L"\""); subs.append(L"\""); } if (!ParseSubstitute(subs)) { LogWithArgs(LOG_WARNING, L"Incorrect substitute string: %s", subs.c_str()); } const std::wstring& group = parser.ReadString(section, L"Group", L""); InitializeGroup(group); } /* ** CheckSubstitute ** ** Substitutes part of the text */ const WCHAR* CMeasure::CheckSubstitute(const WCHAR* buffer) { static std::wstring str; if (!m_Substitute.empty()) { str = buffer; for (size_t i = 0, isize = m_Substitute.size(); i < isize; i += 2) { if (str.empty() && m_Substitute[i].empty()) { // Empty result and empty substitute -> use second str = m_Substitute[i + 1]; } else if (!m_Substitute[i].empty()) { size_t start = 0; size_t pos = std::wstring::npos; do { pos = str.find(m_Substitute[i], start); if (pos != std::wstring::npos) { str.replace(pos, m_Substitute[i].length(), m_Substitute[i + 1]); start = pos + m_Substitute[i + 1].length(); } } while (pos != std::wstring::npos); } } return str.c_str(); } else { return buffer; } } /* ** ParseSubstitute ** ** Reads the buffer for "Name":"Value"-pairs separated with comma and ** fills the map with the parsed data. */ bool CMeasure::ParseSubstitute(std::wstring buffer) { if (buffer.empty()) return true; while (!buffer.empty()) { std::wstring word1 = ExtractWord(buffer); std::wstring sep = ExtractWord(buffer); if (sep != L":") return false; std::wstring word2 = ExtractWord(buffer); if (word1 != word2) { m_Substitute.push_back(word1); m_Substitute.push_back(word2); } sep = ExtractWord(buffer); if (!sep.empty() && sep != L",") return false; } return true; } /* ** ExtractWord ** ** Returns the first word from the buffer. The word can be inside quotes. ** If not, the separators are ' ', '\t', ',' and ':'. Whitespaces are removed ** and buffer _will_ be modified. */ std::wstring CMeasure::ExtractWord(std::wstring& buffer) { std::wstring::size_type end, len; std::wstring ret; if (buffer.empty()) return ret; len = buffer.size(); // Remove whitespaces end = 0; while (end < len && (buffer[end] == L' ' || buffer[end] == L'\t' || buffer[end] == L'\n')) ++end; if (end == len) { // End of line reached end = std::wstring::npos; } else { buffer.erase(0, end); len = buffer.size(); if (buffer[0] == L'\"' || buffer[0] == L'\'') { WCHAR quote = buffer[0]; end = 1; // Skip the '"' // Quotes around the word while (end < len && (buffer[end] != quote)) ++end; if (end == len) end = std::wstring::npos; if (end != std::wstring::npos) { ret.assign(buffer, 1, end - 1); ++end; } else { // End of string reached - discard result } } else { end = 0; while (end < len && (buffer[end] != L',' && buffer[end] != L':' && buffer[end] != L' ' && buffer[end] != L'\t')) ++end; if (end == len) end = std::wstring::npos; if (end == std::wstring::npos) { // End of line reached ret = buffer; } else { ret.assign(buffer, 0, ++end); // The separator is also returned! } } } buffer.erase(0, end); return ret; } /* ** PreUpdate ** ** The base implementation of the update method. This includes the code ** that is common for all measures. This is called every time the measure ** is updated. The inherited classes must call the base implementation if ** they overwrite this method. If this method returns false, the update ** needs not to be done. ** */ bool CMeasure::PreUpdate() { if (IsDisabled()) { m_Value = 0.0; // Disable measures return 0 as value return false; } // Only update the counter if the divider ++m_UpdateCounter; if (m_UpdateCounter < m_UpdateDivider) return false; m_UpdateCounter = 0; // If we're logging the maximum value of the measure, check if // the new value is greater than the old one, and update if necessary. if (m_LogMaxValue) { if (m_MedianMaxValues.empty()) { m_MedianMaxValues.resize(MEDIAN_SIZE, 0); m_MedianMinValues.resize(MEDIAN_SIZE, 0); } m_MedianMaxValues[m_MedianPos] = m_Value; m_MedianMinValues[m_MedianPos] = m_Value; ++m_MedianPos; m_MedianPos %= MEDIAN_SIZE; std::vector medianArray; medianArray = m_MedianMaxValues; std::sort(medianArray.begin(), medianArray.end()); m_MaxValue = max(m_MaxValue, medianArray[MEDIAN_SIZE / 2]); medianArray = m_MedianMinValues; std::sort(medianArray.begin(), medianArray.end()); m_MinValue = min(m_MinValue, medianArray[MEDIAN_SIZE / 2]); } if (m_MeterWindow) { // Check the IfEqualValue if (!m_IfEqualAction.empty()) { if ((int)m_Value == (int)m_IfEqualValue) { if (!m_IfEqualCommited) { m_IfEqualCommited = true; // To avoid crashing by !RainmeterUpdate due to infinite loop Rainmeter->ExecuteCommand(m_IfEqualAction.c_str(), m_MeterWindow); } } else { m_IfEqualCommited = false; } } // Check the IfAboveValue if (!m_IfAboveAction.empty()) { if (m_Value > m_IfAboveValue) { if (!m_IfAboveCommited) { m_IfAboveCommited = true; // To avoid crashing by !RainmeterUpdate due to infinite loop Rainmeter->ExecuteCommand(m_IfAboveAction.c_str(), m_MeterWindow); } } else { m_IfAboveCommited = false; } } // Check the IfBelowValue if (!m_IfBelowAction.empty()) { if (m_Value < m_IfBelowValue) { if (!m_IfBelowCommited) { m_IfBelowCommited = true; // To avoid crashing by !RainmeterUpdate due to infinite loop Rainmeter->ExecuteCommand(m_IfBelowAction.c_str(), m_MeterWindow); } } else { m_IfBelowCommited = false; } } } return true; } /* ** PostUpdate ** ** Does post measuring things to the value. All measures must call this ** after they have set the m_Value. ** */ bool CMeasure::PostUpdate() { if (m_AverageSize > 0) { size_t averageValuesSize = m_AverageValues.size(); if (m_AverageSize != averageValuesSize) { m_AverageValues.resize(m_AverageSize, m_Value); averageValuesSize = m_AverageValues.size(); if (m_AveragePos >= averageValuesSize) m_AveragePos = 0; } m_AverageValues[m_AveragePos] = m_Value; ++m_AveragePos; m_AveragePos %= averageValuesSize; // Calculate the average value m_Value = 0; for (size_t i = 0; i < averageValuesSize; ++i) { m_Value += m_AverageValues[i]; } m_Value /= (double)averageValuesSize; } return true; } /* ** GetValue ** ** Returns the value of the measure. ** */ double CMeasure::GetValue() { // Invert if so requested if (m_Invert) { return m_MaxValue - m_Value + m_MinValue; } return m_Value; } /* ** GetRelativeValue ** ** Returns the relative value of the measure (0.0 - 1.0). ** */ double CMeasure::GetRelativeValue() { double range = GetValueRange(); if (range != 0.0) { double value = GetValue(); value = min(m_MaxValue, value); value = max(m_MinValue, value); value -= m_MinValue; return value / range; } return 1.0; } /* ** GetValueRange ** ** Returns the value range. ** */ double CMeasure::GetValueRange() { return m_MaxValue - m_MinValue; } /* ** GetStringValue ** ** This method returns the value as text string. The actual value is ** get with GetValue() so we don't have to worry about m_Invert. ** ** autoScale If true, scale the value automatically to some sensible range. ** scale The scale to use if autoScale is false. ** decimals Number of decimals used in the value. If -1, get rid of ".00000" for dynamic variables. ** percentual Return the value as % from the maximum value. */ const WCHAR* CMeasure::GetStringValue(AUTOSCALE autoScale, double scale, int decimals, bool percentual) { static WCHAR buffer[MAX_LINE_LENGTH]; WCHAR format[32]; if (percentual) { double val = 100.0 * GetRelativeValue(); if (decimals == 0) { _snwprintf_s(buffer, _TRUNCATE, L"%i", (int)val); } else { _snwprintf_s(format, _TRUNCATE, L"%%.%if", decimals); _snwprintf_s(buffer, _TRUNCATE, format, val); } } else if (autoScale != AUTOSCALE_OFF) { GetScaledValue(autoScale, decimals, GetValue(), buffer, _countof(buffer)); } else { double val = GetValue() / scale; if (decimals == 0) { val += (val >= 0) ? 0.5 : -0.5; _snwprintf_s(buffer, _TRUNCATE, L"%lli", (LONGLONG)val); } else if (decimals == -1) { int len = _snwprintf_s(buffer, _TRUNCATE, L"%.5f", val); RemoveTrailingZero(buffer, len); } else { _snwprintf_s(format, _TRUNCATE, L"%%.%if", decimals); _snwprintf_s(buffer, _TRUNCATE, format, val); } } return CheckSubstitute(buffer); } void CMeasure::GetScaledValue(AUTOSCALE autoScale, int decimals, double theValue, WCHAR* buffer, size_t sizeInWords) { WCHAR format[32]; double value = 0; if (decimals == 0) { wcsncpy_s(format, L"%.0f", _TRUNCATE); } else { _snwprintf_s(format, _TRUNCATE, L"%%.%if", decimals); } int index = (autoScale == AUTOSCALE_1000 || autoScale == AUTOSCALE_1000K) ? AUTOSCALE_INDEX_1000 : AUTOSCALE_INDEX_1024; if (theValue > (g_TblScale[index][0] * 0.99)) { wcsncat_s(format, L" T", _TRUNCATE); value = theValue / g_TblScale[index][0]; } else if (theValue > (g_TblScale[index][1] * 0.99)) { wcsncat_s(format, L" G", _TRUNCATE); value = theValue / g_TblScale[index][1]; } else if (theValue > (g_TblScale[index][2] * 0.99)) { wcsncat_s(format, L" M", _TRUNCATE); value = theValue / g_TblScale[index][2]; } else if (autoScale == AUTOSCALE_1024K || autoScale == AUTOSCALE_1000K || theValue > (g_TblScale[index][3] * 0.99)) { wcsncat_s(format, L" k", _TRUNCATE); value = theValue / g_TblScale[index][3]; } else { wcsncat_s(format, L" ", _TRUNCATE); value = theValue; } _snwprintf_s(buffer, sizeInWords, _TRUNCATE, format, value); } void CMeasure::RemoveTrailingZero(WCHAR* str, int strLen) { --strLen; while (strLen >= 0) { if (str[strLen] == L'0') { str[strLen] = L'\0'; --strLen; } else { if (str[strLen] == L'.') { str[strLen] = L'\0'; } break; } } } /* ** GetStats ** ** Returns the stats as string. The stats are shown in the About dialog. */ const WCHAR* CMeasure::GetStats() { static std::wstring value; value = GetStringValue(AUTOSCALE_ON, 1, 1, false); return value.c_str(); } /* ** Create ** ** Creates the given measure. This is the factory method for the measures. ** If new measures are implemented this method needs to be updated. ** */ CMeasure* CMeasure::Create(const WCHAR* measure, CMeterWindow* meterWindow, const WCHAR* name) { // Comparison is caseinsensitive if (*measure == L'\0') { return NULL; } else if (_wcsicmp(L"CPU", measure) == 0) { return new CMeasureCPU(meterWindow, name); } else if (_wcsicmp(L"Memory", measure) == 0) { return new CMeasureMemory(meterWindow, name); } else if (_wcsicmp(L"NetIn", measure) == 0) { return new CMeasureNetIn(meterWindow, name); } else if (_wcsicmp(L"NetOut", measure) == 0) { return new CMeasureNetOut(meterWindow, name); } else if (_wcsicmp(L"NetTotal", measure) == 0) { return new CMeasureNetTotal(meterWindow, name); } else if (_wcsicmp(L"PhysicalMemory", measure) == 0) { return new CMeasurePhysicalMemory(meterWindow, name); } else if (_wcsicmp(L"SwapMemory", measure) == 0) { return new CMeasureVirtualMemory(meterWindow, name); } else if (_wcsicmp(L"FreeDiskSpace", measure) == 0) { return new CMeasureDiskSpace(meterWindow, name); } else if (_wcsicmp(L"Uptime", measure) == 0) { return new CMeasureUptime(meterWindow, name); } else if (_wcsicmp(L"Time", measure) == 0) { return new CMeasureTime(meterWindow, name); } else if (_wcsicmp(L"Plugin", measure) == 0) { return new CMeasurePlugin(meterWindow, name); } else if (_wcsicmp(L"Registry", measure) == 0) { return new CMeasureRegistry(meterWindow, name); } else if (_wcsicmp(L"Calc", measure) == 0) { return new CMeasureCalc(meterWindow, name); } else if (_wcsicmp(L"script", measure) == 0) { return new CMeasureScript(meterWindow, name); } // Error std::wstring error = L"Measure="; error += measure; error += L" is not valid in section ["; error += name; error += L"]."; throw CError(error, __LINE__, __FILE__); return NULL; } /* ** ExecuteBang ** ** Executes a custom bang */ void CMeasure::ExecuteBang(const WCHAR* args) { LogWithArgs(LOG_WARNING, L"[%s] doesn't support this bang: %s", m_Name.c_str(), args); }