/* Copyright (C) 2004 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 "ConfigParser.h" #include "MathParser.h" #include "Litestep.h" #include "Rainmeter.h" #include "System.h" #include "Measure.h" #include "Meter.h" #include "resource.h" extern CRainmeter* Rainmeter; using namespace Gdiplus; std::unordered_map CConfigParser::c_MonitorVariables; /* ** The constructor ** */ CConfigParser::CConfigParser() : m_LastReplaced(false), m_LastDefaultUsed(false), m_LastValueDefined(false), m_CurrentSection() { } /* ** The destructor ** */ CConfigParser::~CConfigParser() { } void CConfigParser::Initialize(const std::wstring& filename, CMeterWindow* meterWindow, LPCTSTR skinSection, const std::wstring* resourcePath) { m_Measures.clear(); m_Sections.clear(); m_Values.clear(); m_BuiltInVariables.clear(); m_Variables.clear(); m_StyleTemplate.clear(); m_LastReplaced = false; m_LastDefaultUsed = false; m_LastValueDefined = false; m_CurrentSection = NULL; m_SectionInsertPos = m_Sections.end(); // Set the built-in variables. Do this before the ini file is read so that the paths can be used with @include SetBuiltInVariables(filename, resourcePath, meterWindow); ResetMonitorVariables(meterWindow); CSystem::UpdateIniFileMappingList(); ReadIniFile(filename, skinSection); ReadVariables(); // Clear and minimize m_FoundSections.clear(); m_ListVariables.clear(); m_SectionInsertPos = m_Sections.end(); m_MeterWindow = meterWindow; } void CConfigParser::SetBuiltInVariables(const std::wstring& filename, const std::wstring* resourcePath, CMeterWindow* meterWindow) { auto insertVariable = [&](const WCHAR* name, std::wstring value) { return m_BuiltInVariables.insert(std::make_pair(name, value)); }; insertVariable(L"PROGRAMPATH", Rainmeter->GetPath()); insertVariable(L"PROGRAMDRIVE", Rainmeter->GetDrive()); insertVariable(L"SETTINGSPATH", Rainmeter->GetSettingsPath()); insertVariable(L"SKINSPATH", Rainmeter->GetSkinPath()); insertVariable(L"PLUGINSPATH", Rainmeter->GetPluginPath()); insertVariable(L"CURRENTPATH", CRainmeter::ExtractPath(filename)); insertVariable(L"ADDONSPATH", Rainmeter->GetAddonPath()); if (meterWindow) { insertVariable(L"CURRENTFILE", meterWindow->GetFileName()); insertVariable(L"CURRENTCONFIG", meterWindow->GetFolderPath()); insertVariable(L"ROOTCONFIGPATH", meterWindow->GetRootPath()); } insertVariable(L"CRLF", L"\n"); m_CurrentSection = &(insertVariable(L"CURRENTSECTION", L"").first->second); // shortcut if (resourcePath) { SetVariable(L"@", *resourcePath); } } /* ** Sets all user-defined variables. ** */ void CConfigParser::ReadVariables() { std::list::const_iterator iter = m_ListVariables.begin(); for ( ; iter != m_ListVariables.end(); ++iter) { SetVariable((*iter), ReadString(L"Variables", (*iter).c_str(), L"", false)); } } /* ** Sets a new value for the variable. The DynamicVariables must be set to 1 in the ** meter/measure for the changes to be applied. ** */ void CConfigParser::SetVariable(std::unordered_map& variables, const std::wstring& strVariable, const std::wstring& strValue) { // LogWithArgs(LOG_DEBUG, L"Variable: %s=%s (size=%i)", strVariable.c_str(), strValue.c_str(), (int)variables.size()); const std::wstring strTmp = StrToUpper(strVariable); variables[strTmp] = strValue; } void CConfigParser::SetVariable(std::unordered_map& variables, const WCHAR* strVariable, const WCHAR* strValue) { // LogWithArgs(LOG_DEBUG, L"Variable: %s=%s (size=%i)", strVariable.c_str(), strValue.c_str(), (int)variables.size()); const std::wstring strTmp = StrToUpper(strVariable); variables[strTmp] = strValue; } /* ** Gets a value for the variable. Returns NULL if not found. ** */ const std::wstring* CConfigParser::GetVariable(const std::wstring& strVariable) { const std::wstring strTmp = StrToUpper(strVariable); // #1: Built-in variables std::unordered_map::const_iterator iter = m_BuiltInVariables.find(strTmp); if (iter != m_BuiltInVariables.end()) { return &(*iter).second; } // #2: Monitor variables iter = c_MonitorVariables.find(strTmp); if (iter != c_MonitorVariables.end()) { return &(*iter).second; } // #3: User-defined variables iter = m_Variables.find(strTmp); if (iter != m_Variables.end()) { return &(*iter).second; } return NULL; } /* ** Gets the value of a section variable. Returns true if strValue is set. ** The selector is stripped from strVariable. ** */ bool CConfigParser::GetSectionVariable(std::wstring& strVariable, std::wstring& strValue) { size_t colonPos = strVariable.find_last_of(L':'); if (colonPos == std::wstring::npos) { return false; } const std::wstring selector = strVariable.substr(colonPos + 1); const WCHAR* selectorSz = selector.c_str(); strVariable.resize(colonPos); bool isKeySelector = (!selector.empty() && iswalpha(selectorSz[0])); if (isKeySelector) { // [Meter:X], [Meter:Y], [Meter:W], [Meter:H] CMeter* meter = m_MeterWindow->GetMeter(strVariable); if (meter) { WCHAR buffer[32]; if (_wcsicmp(selectorSz, L"X") == 0) { _itow_s(meter->GetX(), buffer, 10); } else if (_wcsicmp(selectorSz, L"Y") == 0) { _itow_s(meter->GetY(), buffer, 10); } else if (_wcsicmp(selectorSz, L"W") == 0) { _itow_s(meter->GetW(), buffer, 10); } else if (_wcsicmp(selectorSz, L"H") == 0) { _itow_s(meter->GetH(), buffer, 10); } else { return false; } strValue = buffer; return true; } } // Number: [Measure:], [Measure:dec] // Percentual: [Measure:%], [Measure:%, dec] // Scale: [Measure:/scale], [Measure:/scale, dec] // Max/Min: [Measure:MaxValue], [Measure:MaxValue:/scale, dec] ('%' cannot be used) enum VALUETYPE { RAW = 0, PERCENTUAL = 1, MAX = 2, MIN = 3 } valueType = RAW; if (isKeySelector) { if (_wcsicmp(selectorSz, L"MaxValue") == 0) { valueType = MAX; } else if (_wcsicmp(selectorSz, L"MinValue") == 0) { valueType = MIN; } else { return false; } selectorSz = L""; } else { colonPos = strVariable.find_last_of(L':'); if (colonPos != std::wstring::npos) { do { const WCHAR* keySelectorSz = strVariable.c_str() + colonPos + 1; if (_wcsicmp(keySelectorSz, L"MaxValue") == 0) { valueType = MAX; } else if (_wcsicmp(keySelectorSz, L"MinValue") == 0) { valueType = MIN; } else { // Section name contains ':' ? break; } strVariable.resize(colonPos); } while (0); } } CMeasure* measure = m_MeterWindow->GetMeasure(strVariable); if (measure) { double scale = 1.0; const WCHAR* decimalsSz = wcschr(selectorSz, L','); if (decimalsSz) { ++decimalsSz; } if (*selectorSz == L'%') // Percentual { if (valueType == MAX || valueType == MIN) // '%' cannot be used with MAX/MIN value { return false; } valueType = PERCENTUAL; } else if (*selectorSz == L'/') // Scale { errno = 0; scale = _wtoi(selectorSz + 1); if (errno == EINVAL) { scale = 1.0; } } else { if (decimalsSz) { return false; } decimalsSz = selectorSz; } double value = (valueType == PERCENTUAL) ? measure->GetRelativeValue() * 100.0 : (valueType == MAX) ? measure->GetMaxValue() / scale : (valueType == MIN) ? measure->GetMinValue() / scale : measure->GetValue() / scale; int decimals = 10; if (decimalsSz) { while (iswspace(*decimalsSz)) ++decimalsSz; if (*decimalsSz) { decimals = _wtoi(decimalsSz); decimals = max(0, decimals); decimals = min(32, decimals); } else { decimalsSz = NULL; } } WCHAR format[32]; WCHAR buffer[128]; _snwprintf_s(format, _TRUNCATE, L"%%.%if", decimals); int bufferLen = _snwprintf_s(buffer, _TRUNCATE, format, value); if (!decimalsSz) { // Remove trailing zeros if decimal count was not specified. measure->RemoveTrailingZero(buffer, bufferLen); bufferLen = (int)wcslen(buffer); } strValue.assign(buffer, bufferLen); return true; } return false; } void CConfigParser::ResetMonitorVariables(CMeterWindow* meterWindow) { // Set the SCREENAREA/WORKAREA variables if (c_MonitorVariables.empty()) { SetMultiMonitorVariables(true); } // Set the SCREENAREA/WORKAREA variables for present monitor SetAutoSelectedMonitorVariables(meterWindow); } /* ** Sets new values for the SCREENAREA/WORKAREA variables. ** */ void CConfigParser::SetMultiMonitorVariables(bool reset) { WCHAR buffer[32]; RECT workArea, scrArea; if (!reset && c_MonitorVariables.empty()) { reset = true; // Set all variables } SystemParametersInfo(SPI_GETWORKAREA, 0, &workArea, 0); _itow_s(workArea.left, buffer, 10); SetMonitorVariable(L"WORKAREAX", buffer); SetMonitorVariable(L"PWORKAREAX", buffer); _itow_s(workArea.top, buffer, 10); SetMonitorVariable(L"WORKAREAY", buffer); SetMonitorVariable(L"PWORKAREAY", buffer); _itow_s(workArea.right - workArea.left, buffer, 10); SetMonitorVariable(L"WORKAREAWIDTH", buffer); SetMonitorVariable(L"PWORKAREAWIDTH", buffer); _itow_s(workArea.bottom - workArea.top, buffer, 10); SetMonitorVariable(L"WORKAREAHEIGHT", buffer); SetMonitorVariable(L"PWORKAREAHEIGHT", buffer); if (reset) { scrArea.left = 0; scrArea.top = 0; scrArea.right = GetSystemMetrics(SM_CXSCREEN); scrArea.bottom = GetSystemMetrics(SM_CYSCREEN); _itow_s(scrArea.left, buffer, 10); SetMonitorVariable(L"SCREENAREAX", buffer); SetMonitorVariable(L"PSCREENAREAX", buffer); _itow_s(scrArea.top, buffer, 10); SetMonitorVariable(L"SCREENAREAY", buffer); SetMonitorVariable(L"PSCREENAREAY", buffer); _itow_s(scrArea.right - scrArea.left, buffer, 10); SetMonitorVariable(L"SCREENAREAWIDTH", buffer); SetMonitorVariable(L"PSCREENAREAWIDTH", buffer); _itow_s(scrArea.bottom - scrArea.top, buffer, 10); SetMonitorVariable(L"SCREENAREAHEIGHT", buffer); SetMonitorVariable(L"PSCREENAREAHEIGHT", buffer); _itow_s(GetSystemMetrics(SM_XVIRTUALSCREEN), buffer, 10); SetMonitorVariable(L"VSCREENAREAX", buffer); _itow_s(GetSystemMetrics(SM_YVIRTUALSCREEN), buffer, 10); SetMonitorVariable(L"VSCREENAREAY", buffer); _itow_s(GetSystemMetrics(SM_CXVIRTUALSCREEN), buffer, 10); SetMonitorVariable(L"VSCREENAREAWIDTH", buffer); _itow_s(GetSystemMetrics(SM_CYVIRTUALSCREEN), buffer, 10); SetMonitorVariable(L"VSCREENAREAHEIGHT", buffer); } if (CSystem::GetMonitorCount() > 0) { const MultiMonitorInfo& multimonInfo = CSystem::GetMultiMonitorInfo(); const std::vector& monitors = multimonInfo.monitors; for (size_t i = 0, isize = monitors.size(); i < isize; ++i) { WCHAR buffer2[64]; const RECT work = (monitors[i].active) ? monitors[i].work : workArea; _itow_s(work.left, buffer, 10); _snwprintf_s(buffer2, _TRUNCATE, L"WORKAREAX@%i", (int)i + 1); SetMonitorVariable(buffer2, buffer); _itow_s(work.top, buffer, 10); _snwprintf_s(buffer2, _TRUNCATE, L"WORKAREAY@%i", (int)i + 1); SetMonitorVariable(buffer2, buffer); _itow_s(work.right - work.left, buffer, 10); _snwprintf_s(buffer2, _TRUNCATE, L"WORKAREAWIDTH@%i", (int)i + 1); SetMonitorVariable(buffer2, buffer); _itow_s(work.bottom - work.top, buffer, 10); _snwprintf_s(buffer2, _TRUNCATE, L"WORKAREAHEIGHT@%i", (int)i + 1); SetMonitorVariable(buffer2, buffer); if (reset) { const RECT screen = (monitors[i].active) ? monitors[i].screen : scrArea; _itow_s(screen.left, buffer, 10); _snwprintf_s(buffer2, _TRUNCATE, L"SCREENAREAX@%i", (int)i + 1); SetMonitorVariable(buffer2, buffer); _itow_s(screen.top, buffer, 10); _snwprintf_s(buffer2, _TRUNCATE, L"SCREENAREAY@%i", (int)i + 1); SetMonitorVariable(buffer2, buffer); _itow_s(screen.right - screen.left, buffer, 10); _snwprintf_s(buffer2, _TRUNCATE, L"SCREENAREAWIDTH@%i", (int)i + 1); SetMonitorVariable(buffer2, buffer); _itow_s(screen.bottom - screen.top, buffer, 10); _snwprintf_s(buffer2, _TRUNCATE, L"SCREENAREAHEIGHT@%i", (int)i + 1); SetMonitorVariable(buffer2, buffer); } } } } /* ** Sets new SCREENAREA/WORKAREA variables for present monitor. ** */ void CConfigParser::SetAutoSelectedMonitorVariables(CMeterWindow* meterWindow) { if (meterWindow) { WCHAR buffer[32]; if (CSystem::GetMonitorCount() > 0) { int w1, w2, s1, s2; int screenIndex; const MultiMonitorInfo& multimonInfo = CSystem::GetMultiMonitorInfo(); const std::vector& monitors = multimonInfo.monitors; // Set X / WIDTH screenIndex = multimonInfo.primary; if (meterWindow->GetXScreenDefined()) { int i = meterWindow->GetXScreen(); if (i >= 0 && (i == 0 || i <= (int)monitors.size() && monitors[i-1].active)) { screenIndex = i; } } if (screenIndex == 0) { s1 = w1 = multimonInfo.vsL; s2 = w2 = multimonInfo.vsW; } else { w1 = monitors[screenIndex-1].work.left; w2 = monitors[screenIndex-1].work.right - monitors[screenIndex-1].work.left; s1 = monitors[screenIndex-1].screen.left; s2 = monitors[screenIndex-1].screen.right - monitors[screenIndex-1].screen.left; } _itow_s(w1, buffer, 10); SetBuiltInVariable(L"WORKAREAX", buffer); _itow_s(w2, buffer, 10); SetBuiltInVariable(L"WORKAREAWIDTH", buffer); _itow_s(s1, buffer, 10); SetBuiltInVariable(L"SCREENAREAX", buffer); _itow_s(s2, buffer, 10); SetBuiltInVariable(L"SCREENAREAWIDTH", buffer); // Set Y / HEIGHT screenIndex = multimonInfo.primary; if (meterWindow->GetYScreenDefined()) { int i = meterWindow->GetYScreen(); if (i >= 0 && (i == 0 || i <= (int)monitors.size() && monitors[i-1].active)) { screenIndex = i; } } if (screenIndex == 0) { s1 = w1 = multimonInfo.vsL; s2 = w2 = multimonInfo.vsW; } else { w1 = monitors[screenIndex-1].work.top; w2 = monitors[screenIndex-1].work.bottom - monitors[screenIndex-1].work.top; s1 = monitors[screenIndex-1].screen.top; s2 = monitors[screenIndex-1].screen.bottom - monitors[screenIndex-1].screen.top; } _itow_s(w1, buffer, 10); SetBuiltInVariable(L"WORKAREAY", buffer); _itow_s(w2, buffer, 10); SetBuiltInVariable(L"WORKAREAHEIGHT", buffer); _itow_s(s1, buffer, 10); SetBuiltInVariable(L"SCREENAREAY", buffer); _itow_s(s2, buffer, 10); SetBuiltInVariable(L"SCREENAREAHEIGHT", buffer); } else { RECT r; // Set default WORKAREA SystemParametersInfo(SPI_GETWORKAREA, 0, &r, 0); _itow_s(r.left, buffer, 10); SetBuiltInVariable(L"WORKAREAX", buffer); _itow_s(r.top, buffer, 10); SetBuiltInVariable(L"WORKAREAY", buffer); _itow_s(r.right - r.left, buffer, 10); SetBuiltInVariable(L"WORKAREAWIDTH", buffer); _itow_s(r.bottom - r.top, buffer, 10); SetBuiltInVariable(L"WORKAREAHEIGHT", buffer); // Set default SCREENAREA r.left = 0; r.top = 0; r.right = GetSystemMetrics(SM_CXSCREEN); r.bottom = GetSystemMetrics(SM_CYSCREEN); _itow_s(r.left, buffer, 10); SetBuiltInVariable(L"SCREENAREAX", buffer); _itow_s(r.top, buffer, 10); SetBuiltInVariable(L"SCREENAREAY", buffer); _itow_s(r.right - r.left, buffer, 10); SetBuiltInVariable(L"SCREENAREAWIDTH", buffer); _itow_s(r.bottom - r.top, buffer, 10); SetBuiltInVariable(L"SCREENAREAHEIGHT", buffer); } } } /* ** Replaces environment and internal variables in the given string. ** */ bool CConfigParser::ReplaceVariables(std::wstring& result) { bool replaced = false; CRainmeter::ExpandEnvironmentVariables(result); if (c_MonitorVariables.empty()) { SetMultiMonitorVariables(true); } // Check for variables (#VAR#) size_t start = 0, end; bool loop = true; do { start = result.find(L'#', start); if (start != std::wstring::npos) { size_t si = start + 1; end = result.find(L'#', si); if (end != std::wstring::npos) { size_t ei = end - 1; if (si != ei && result[si] == L'*' && result[ei] == L'*') { result.erase(ei, 1); result.erase(si, 1); start = ei; } else { std::wstring strVariable = result.substr(si, end - si); const std::wstring* value = GetVariable(strVariable); if (value) { // Variable found, replace it with the value result.replace(start, end - start + 1, *value); start += (*value).length(); replaced = true; } else { start = end; } } } else { loop = false; } } else { loop = false; } } while (loop); return replaced; } /* ** Replaces measures in the given string. ** */ bool CConfigParser::ReplaceMeasures(std::wstring& result) { bool replaced = false; size_t start = 0; while ((start = result.find(L'[', start)) != std::wstring::npos) { size_t si = start + 1; size_t end = result.find(L']', si); if (end == std::wstring::npos) { break; } size_t next = result.find(L'[', si); if (next == std::wstring::npos || end < next) { size_t ei = end - 1; if (si != ei && result[si] == L'*' && result[ei] == L'*') { result.erase(ei, 1); result.erase(si, 1); start = ei; } else { std::wstring var = result.substr(si, end - si); CMeasure* measure = GetMeasure(var); if (measure) { const WCHAR* value = measure->GetStringValue(AUTOSCALE_OFF, 1, -1, false); size_t valueLen = wcslen(value); // Measure found, replace it with the value result.replace(start, end - start + 1, value, valueLen); start += valueLen; replaced = true; } else { std::wstring value; if (GetSectionVariable(var, value)) { // Replace section variable with the value. result.replace(start, end - start + 1, value); start += value.length(); replaced = true; } else { start = end; } } } } else { start = next; } } return replaced; } const std::wstring& CConfigParser::ReadString(LPCTSTR section, LPCTSTR key, LPCTSTR defValue, bool bReplaceMeasures) { static std::wstring result; // Clear last status m_LastReplaced = false; m_LastDefaultUsed = false; m_LastValueDefined = false; const std::wstring strSection = section; const std::wstring strKey = key; const std::wstring strDefault = defValue; const std::wstring& strValue = GetValue(strSection, strKey, strDefault); if (&strValue == &strDefault) { bool foundStyleValue = false; // If the template is defined read the value from there. std::vector::const_reverse_iterator iter = m_StyleTemplate.rbegin(); for ( ; iter != m_StyleTemplate.rend(); ++iter) { const std::wstring& strStyleValue = GetValue((*iter), strKey, strDefault); //LogWithArgs(LOG_DEBUG, L"StyleTemplate: [%s] %s (from [%s]) : strDefault=%s (0x%p), strStyleValue=%s (0x%p)", // section, key, (*iter).c_str(), strDefault.c_str(), &strDefault, strStyleValue.c_str(), &strStyleValue); if (&strStyleValue != &strDefault) { result = strStyleValue; foundStyleValue = true; break; } } if (!foundStyleValue) { result = strDefault; m_LastDefaultUsed = true; return result; } } else { result = strValue; } if (!result.empty()) { m_LastValueDefined = true; if (result.size() >= 3) { if (result.find(L'#') != std::wstring::npos) { SetCurrentSection(strSection); // Set temporarily if (ReplaceVariables(result)) { m_LastReplaced = true; } ClearCurrentSection(); // Reset } else { CRainmeter::ExpandEnvironmentVariables(result); } if (bReplaceMeasures && ReplaceMeasures(result)) { m_LastReplaced = true; } } } return result; } bool CConfigParser::IsKeyDefined(LPCTSTR section, LPCTSTR key) { ReadString(section, key, L"", false); return !m_LastDefaultUsed; } bool CConfigParser::IsValueDefined(LPCTSTR section, LPCTSTR key) { ReadString(section, key, L"", false); return m_LastValueDefined; } void CConfigParser::AddMeasure(CMeasure* pMeasure) { if (pMeasure) { m_Measures[StrToUpper(pMeasure->GetOriginalName())] = pMeasure; } } CMeasure* CConfigParser::GetMeasure(const std::wstring& name) { std::unordered_map::const_iterator iter = m_Measures.find(StrToUpper(name)); if (iter != m_Measures.end()) { return (*iter).second; } return NULL; } std::vector CConfigParser::ReadFloats(LPCTSTR section, LPCTSTR key) { std::vector result; const std::wstring& string = ReadString(section, key, L""); if (!string.empty()) { // Tokenize and parse the floats std::vector tokens = Tokenize(string, L";"); std::vector::const_iterator iter = tokens.begin(); for ( ; iter != tokens.end(); ++iter) { result.push_back((Gdiplus::REAL)ParseDouble((*iter).c_str(), 0.0)); } } return result; } int CConfigParser::ReadInt(LPCTSTR section, LPCTSTR key, int defValue) { const std::wstring& result = ReadString(section, key, L""); if (!m_LastDefaultUsed) { const WCHAR* string = result.c_str(); if (*string == L'(') { double dblValue; const WCHAR* errMsg = MathParser::CheckedParse(string, &dblValue); if (!errMsg) { return (int)dblValue; } LogWithArgs(LOG_ERROR, L"Formula: %s in key \"%s\" in [%s]", errMsg, key, section); } else if (*string) { errno = 0; int intValue = wcstol(string, NULL, 10); if (errno != ERANGE) { return intValue; } } } return defValue; } uint32_t CConfigParser::ReadUInt(LPCTSTR section, LPCTSTR key, uint32_t defValue) { const std::wstring& result = ReadString(section, key, L""); if (!m_LastDefaultUsed) { const WCHAR* string = result.c_str(); if (*string == L'(') { double dblValue; const WCHAR* errMsg = MathParser::CheckedParse(string, &dblValue); if (!errMsg) { return (uint32_t)dblValue; } LogWithArgs(LOG_ERROR, L"Formula: %s in key \"%s\" in [%s]", errMsg, key, section); } else if (*string) { errno = 0; uint32_t uintValue = wcstoul(string, NULL, 10); if (errno != ERANGE) { return uintValue; } } } return defValue; } uint64_t CConfigParser::ReadUInt64(LPCTSTR section, LPCTSTR key, uint64_t defValue) { const std::wstring& result = ReadString(section, key, L""); if (!m_LastDefaultUsed) { const WCHAR* string = result.c_str(); if (*string == L'(') { double dblValue; const WCHAR* errMsg = MathParser::CheckedParse(string, &dblValue); if (!errMsg) { return (uint64_t)dblValue; } LogWithArgs(LOG_ERROR, L"Formula: %s in key \"%s\" in [%s]", errMsg, key, section); } else if (*string) { errno = 0; uint64_t uint64Value = _wcstoui64(string, NULL, 10); if (errno != ERANGE) { return uint64Value; } } } return defValue; } double CConfigParser::ReadFloat(LPCTSTR section, LPCTSTR key, double defValue) { const std::wstring& result = ReadString(section, key, L""); if (!m_LastDefaultUsed) { double value; const WCHAR* string = result.c_str(); if (*string == L'(') { const WCHAR* errMsg = MathParser::CheckedParse(string, &value); if (!errMsg) { return value; } LogWithArgs(LOG_ERROR, L"Formula: %s in key \"%s\" in [%s]", errMsg, key, section); } else if (*string) { errno = 0; value = wcstod(string, NULL); if (errno != ERANGE) { return value; } } } return defValue; } // Returns true if the formula was read successfully, false for failure. bool CConfigParser::ParseFormula(const std::wstring& formula, double* resultValue) { // Formulas must be surrounded by parenthesis if (!formula.empty() && formula[0] == L'(' && formula[formula.size() - 1] == L')') { const WCHAR* string = formula.c_str(); const WCHAR* errMsg = MathParser::CheckedParse(string, resultValue); if (errMsg != NULL) { LogWithArgs(LOG_ERROR, L"Formula: %s: %s", errMsg, string); return false; } return true; } return false; } ARGB CConfigParser::ReadColor(LPCTSTR section, LPCTSTR key, ARGB defValue) { const std::wstring& result = ReadString(section, key, L""); return (m_LastDefaultUsed) ? defValue : ParseColor(result.c_str()); } Rect CConfigParser::ReadRect(LPCTSTR section, LPCTSTR key, const Rect& defValue) { const std::wstring& result = ReadString(section, key, L""); return (m_LastDefaultUsed) ? defValue : ParseRect(result.c_str()); } RECT CConfigParser::ReadRECT(LPCTSTR section, LPCTSTR key, const RECT& defValue) { const std::wstring& result = ReadString(section, key, L""); RECT r; if (m_LastDefaultUsed) { r = defValue; } else { r = ParseRECT(result.c_str()); } return r; } /* ** Splits the string from the delimiters ** ** http://www.digitalpeer.com/id/simple */ std::vector CConfigParser::Tokenize(const std::wstring& str, const std::wstring& delimiters) { std::vector tokens; std::wstring::size_type lastPos = str.find_first_not_of(delimiters, 0); // skip delimiters at beginning. std::wstring::size_type pos = str.find_first_of(delimiters, lastPos); // find first "non-delimiter". while (std::wstring::npos != pos || std::wstring::npos != lastPos) { tokens.push_back(str.substr(lastPos, pos - lastPos)); // found a token, add it to the vector. lastPos = str.find_first_not_of(delimiters, pos); // skip delimiters. Note the "not_of" pos = str.find_first_of(delimiters, lastPos); // find next "non-delimiter" } return tokens; } /* ** Trims empty element in vector and white-space in each string. ** */ void CConfigParser::Shrink(std::vector& vec) { if (!vec.empty()) { std::vector::reverse_iterator iter = vec.rbegin(); while (iter != vec.rend()) { std::wstring::size_type pos = (*iter).find_first_not_of(L" \t\r\n"); if (pos != std::wstring::npos) { std::wstring::size_type lastPos = (*iter).find_last_not_of(L" \t\r\n"); if (pos != 0 || lastPos != ((*iter).size() - 1)) { // Trim white-space (*iter).assign((*iter), pos, lastPos - pos + 1); } ++iter; } else { // Remove empty element vec.erase((++iter).base()); } } } } /* ** Helper method that parses the floating-point value from the given string. ** If the given string is invalid format or causes overflow/underflow, returns given default value. ** */ double CConfigParser::ParseDouble(LPCTSTR string, double defValue) { assert(string); double value; if (*string == L'(') { const WCHAR* errMsg = MathParser::CheckedParse(string, &value); if (!errMsg) { return value; } LogWithArgs(LOG_ERROR, L"Formula: %s: %s", errMsg, string); } else if (*string) { errno = 0; double value = wcstod(string, NULL); if (errno != ERANGE) { return value; } } return defValue; } /* ** Helper method that parses the integer value from the given string. ** If the given string is invalid format or causes overflow/underflow, returns given default value. ** */ int CConfigParser::ParseInt(LPCTSTR string, int defValue) { assert(string); if (*string == L'(') { double dblValue; const WCHAR* errMsg = MathParser::CheckedParse(string, &dblValue); if (!errMsg) { return (int)dblValue; } LogWithArgs(LOG_ERROR, L"Formula: %s: %s", errMsg, string); } else if (*string) { errno = 0; int intValue = wcstol(string, NULL, 10); if (errno != ERANGE) { return intValue; } } return defValue; } /* ** Helper method that parses the unsigned integer value from the given string. ** If the given string is invalid format or causes overflow/underflow, returns given default value. ** */ uint32_t CConfigParser::ParseUInt(LPCTSTR string, uint32_t defValue) { assert(string); if (*string == L'(') { double dblValue; const WCHAR* errMsg = MathParser::CheckedParse(string, &dblValue); if (!errMsg) { return (uint32_t)dblValue; } LogWithArgs(LOG_ERROR, L"Formula: %s: %s", errMsg, string); } else if (*string) { errno = 0; uint32_t uintValue = wcstoul(string, NULL, 10); if (errno != ERANGE) { return uintValue; } } return defValue; } /* ** Helper method that parses the 64bit unsigned integer value from the given string. ** If the given string is invalid format or causes overflow/underflow, returns given default value. ** */ uint64_t CConfigParser::ParseUInt64(LPCTSTR string, uint64_t defValue) { assert(string); if (*string == L'(') { double dblValue; const WCHAR* errMsg = MathParser::CheckedParse(string, &dblValue); if (!errMsg) { return (uint64_t)dblValue; } LogWithArgs(LOG_ERROR, L"Formula: %s: %s", errMsg, string); } else if (*string) { errno = 0; uint64_t uint64Value = _wcstoui64(string, NULL, 10); if (errno != ERANGE) { return uint64Value; } } return defValue; } /* ** Helper template that parses four comma separated values from the given string. ** */ template bool ParseInt4(LPCTSTR string, T& v1, T& v2, T& v3, T& v4) { if (wcschr(string, L',')) { WCHAR* parseSz = _wcsdup(string); WCHAR* token; token = wcstok(parseSz, L","); if (token) { v1 = CConfigParser::ParseInt(token, 0); token = wcstok(NULL, L","); if (token) { v2 = CConfigParser::ParseInt(token, 0); token = wcstok(NULL, L","); if (token) { v3 = CConfigParser::ParseInt(token, 0); token = wcstok(NULL, L","); if (token) { v4 = CConfigParser::ParseInt(token, 0); } } } } free(parseSz); return true; } return false; } /* ** Helper method that parses the color values from the given string. ** The color can be supplied as three/four comma separated values or as one ** hex-value. ** */ ARGB CConfigParser::ParseColor(LPCTSTR string) { int R = 255, G = 255, B = 255, A = 255; if (!ParseInt4(string, R, G, B, A)) { if (wcsncmp(string, L"0x", 2) == 0) { string += 2; // skip prefix } size_t len = wcslen(string); if (len >= 8 && !iswspace(string[6])) { swscanf(string, L"%02x%02x%02x%02x", &R, &G, &B, &A); } else if (len >= 6) { swscanf(string, L"%02x%02x%02x", &R, &G, &B); } } return Color::MakeARGB(A, R, G, B); } /* ** Helper method that parses the Gdiplus::Rect values from the given string. ** The rect can be supplied as four comma separated values (X/Y/Width/Height). ** */ Rect CConfigParser::ParseRect(LPCTSTR string) { Rect r; ParseInt4(string, r.X, r.Y, r.Width, r.Height); return r; } /* ** Helper method that parses the RECT values from the given string. ** The rect can be supplied as four comma separated values (left/top/right/bottom). ** */ RECT CConfigParser::ParseRECT(LPCTSTR string) { RECT r = {0}; ParseInt4(string, r.left, r.top, r.right, r.bottom); return r; } /* ** Reads the given ini file and fills the m_Values and m_Keys maps. ** */ void CConfigParser::ReadIniFile(const std::wstring& iniFile, LPCTSTR skinSection, int depth) { if (depth > 100) // Is 100 enough to assume the include loop never ends? { Rainmeter->ShowMessage(NULL, GetString(ID_STR_INCLUDEINFINITELOOP), MB_OK | MB_ICONERROR); return; } // Verify whether the file exists if (_waccess(iniFile.c_str(), 0) == -1) { LogWithArgs(LOG_ERROR, L"Unable to read file: %s", iniFile.c_str()); return; } // Avoid "IniFileMapping" std::wstring iniRead = CSystem::GetTemporaryFile(iniFile); bool temporary = (!iniRead.empty() && (iniRead.size() != 1 || iniRead[0] != L'?')); if (temporary) { if (Rainmeter->GetDebug()) LogWithArgs(LOG_DEBUG, L"Reading file: %s (Temp: %s)", iniFile.c_str(), iniRead.c_str()); } else { if (Rainmeter->GetDebug()) LogWithArgs(LOG_DEBUG, L"Reading file: %s", iniFile.c_str()); iniRead = iniFile; } // Get all the sections (i.e. different meters) std::list sections; std::unordered_set unique; std::wstring key, value; // buffer DWORD itemsSize = MAX_LINE_LENGTH; WCHAR* items = new WCHAR[itemsSize]; WCHAR* pos = NULL; WCHAR* epos = NULL; if (skinSection == NULL) { // Get all the sections do { items[0] = 0; DWORD res = GetPrivateProfileSectionNames(items, itemsSize, iniRead.c_str()); if (res == 0) // File not found { delete [] items; if (temporary) CSystem::RemoveFile(iniRead); return; } if (res < itemsSize - 2) // Fits in the buffer { epos = items + res; break; } delete [] items; itemsSize *= 2; items = new WCHAR[itemsSize]; } while (true); // Read the sections pos = items; while (pos < epos) { if (*pos) { value = pos; // section name StrToUpperC(key.assign(value)); if (unique.insert(key).second) { if (m_FoundSections.insert(key).second) { m_Sections.insert(m_SectionInsertPos, value); } sections.push_back(value); } pos += value.size() + 1; } else // Empty string { ++pos; } } } else { // Special case: Read only "Rainmeter" and specified section from "Rainmeter.ini" const std::wstring strRainmeter = L"Rainmeter"; const std::wstring strFolder = skinSection; sections.push_back(strRainmeter); sections.push_back(strFolder); if (depth == 0) // Add once { m_Sections.push_back(strRainmeter); m_Sections.push_back(strFolder); } } // Read the keys and values for (auto it = sections.cbegin(); it != sections.cend(); ++it) { unique.clear(); const WCHAR* sectionName = (*it).c_str(); bool isVariables = (_wcsicmp(sectionName, L"Variables") == 0); bool isMetadata = (skinSection == NULL && !isVariables && _wcsicmp(sectionName, L"Metadata") == 0); bool resetInsertPos = true; // Read all "key=value" from the section do { items[0] = 0; DWORD res = GetPrivateProfileSection(sectionName, items, itemsSize, iniRead.c_str()); if (res < itemsSize - 2) // Fits in the buffer { epos = items + res; break; } delete [] items; itemsSize *= 2; items = new WCHAR[itemsSize]; } while (true); pos = items; while (pos < epos) { if (*pos) { size_t len = wcslen(pos); WCHAR* sep = wmemchr(pos, L'=', len); if (sep != NULL && sep != pos) { size_t clen = sep - pos; // key's length StrToUpperC(key.assign(pos, clen)); if (unique.insert(key).second) { ++sep; clen = len - (clen + 1); // value's length // Trim surrounded quotes from value if (clen >= 2 && (sep[0] == L'"' || sep[0] == L'\'') && sep[clen - 1] == sep[0]) { clen -= 2; ++sep; } if (wcsncmp(key.c_str(), L"@INCLUDE", 8) == 0) { if (clen > 0) { value.assign(sep, clen); ReadVariables(); ReplaceVariables(value); if (!CSystem::IsAbsolutePath(value)) { // Relative to the ini folder value.insert(0, CRainmeter::ExtractPath(iniFile)); } if (resetInsertPos) { auto jt = it; if (++jt == sections.end()) // Special case: @include was used in the last section of the current file { // Set the insertion place to the last m_SectionInsertPos = m_Sections.end(); resetInsertPos = false; } else { // Find the appropriate insertion place for (jt = m_Sections.cbegin(); jt != m_Sections.cend(); ++jt) { if (_wcsicmp((*jt).c_str(), sectionName) == 0) { m_SectionInsertPos = ++jt; resetInsertPos = false; break; } } } } ReadIniFile(value, skinSection, depth + 1); } } else { if (!isMetadata) // Uncache Metadata's key-value pair in the skin { value.assign(sep, clen); SetValue((*it), key, value); if (isVariables) { m_ListVariables.push_back(key); } } } } } pos += len + 1; } else // Empty string { ++pos; } } } delete [] items; if (temporary) CSystem::RemoveFile(iniRead); } /* ** Sets the value for the key under the given section. ** */ void CConfigParser::SetValue(const std::wstring& strSection, const std::wstring& strKey, const std::wstring& strValue) { // LogWithArgs(LOG_DEBUG, L"[%s] %s=%s (size: %i)", strSection.c_str(), strKey.c_str(), strValue.c_str(), (int)m_Values.size()); std::wstring strTmp; strTmp.reserve(strSection.size() + 1 + strKey.size()); strTmp = strSection; strTmp += L'~'; strTmp += strKey; m_Values[StrToUpperC(strTmp)] = strValue; } /* ** Deletes the value for the key under the given section. ** */ void CConfigParser::DeleteValue(const std::wstring& strSection, const std::wstring& strKey) { std::wstring strTmp; strTmp.reserve(strSection.size() + 1 + strKey.size()); strTmp = strSection; strTmp += L'~'; strTmp += strKey; std::unordered_map::const_iterator iter = m_Values.find(StrToUpperC(strTmp)); if (iter != m_Values.end()) { m_Values.erase(iter); } } /* ** Returns the value for the key under the given section. ** */ const std::wstring& CConfigParser::GetValue(const std::wstring& strSection, const std::wstring& strKey, const std::wstring& strDefault) { std::wstring strTmp; strTmp.reserve(strSection.size() + 1 + strKey.size()); strTmp = strSection; strTmp += L'~'; strTmp += strKey; std::unordered_map::const_iterator iter = m_Values.find(StrToUpperC(strTmp)); return (iter != m_Values.end()) ? (*iter).second : strDefault; }