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/* Copyright (C) 2004 Rainmeter Project Developers
*
* This Source Code Form is subject to the terms of the GNU General Public
* License; either version 2 of the License, or (at your option) any later
* version. If a copy of the GPL was not distributed with this file, You can
* obtain one at <https://www.gnu.org/licenses/gpl-2.0.html>. */
#include "StdAfx.h"
#include "../Common/MathParser.h"
#include "../Common/PathUtil.h"
#include "ConfigParser.h"
#include "Util.h"
#include "Rainmeter.h"
#include "System.h"
#include "Measure.h"
#include "MeasureTime.h"
#include "Meter.h"
#include "resource.h"
using namespace Gdiplus;
std::unordered_map<std::wstring, std::wstring> ConfigParser::c_MonitorVariables;
ConfigParser::ConfigParser() :
m_LastReplaced(false),
m_LastDefaultUsed(false),
m_LastValueDefined(false),
m_CurrentSection(),
m_Skin()
{
}
ConfigParser::~ConfigParser()
{
}
void ConfigParser::Initialize(const std::wstring& filename, Skin* skin, LPCTSTR skinSection, const std::wstring* resourcePath)
{
m_Skin = skin;
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 = nullptr;
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, skin);
ResetMonitorVariables(skin);
System::UpdateIniFileMappingList();
ReadIniFile(filename, skinSection);
ReadVariables();
// Clear and minimize
m_FoundSections.clear();
m_ListVariables.clear();
m_SectionInsertPos = m_Sections.end();
}
void ConfigParser::SetBuiltInVariables(const std::wstring& filename, const std::wstring* resourcePath, Skin* skin)
{
auto insertVariable = [&](const WCHAR* name, std::wstring value)
{
return m_BuiltInVariables.insert(std::make_pair(name, value));
};
insertVariable(L"PROGRAMPATH", GetRainmeter().GetPath());
insertVariable(L"PROGRAMDRIVE", GetRainmeter().GetDrive());
insertVariable(L"SETTINGSPATH", GetRainmeter().GetSettingsPath());
insertVariable(L"SKINSPATH", GetRainmeter().GetSkinPath());
insertVariable(L"PLUGINSPATH", GetRainmeter().GetPluginPath());
insertVariable(L"CURRENTPATH", PathUtil::GetFolderFromFilePath(filename));
insertVariable(L"ADDONSPATH", GetRainmeter().GetAddonPath());
if (skin)
{
insertVariable(L"CURRENTFILE", skin->GetFileName());
insertVariable(L"CURRENTCONFIG", skin->GetFolderPath());
insertVariable(L"ROOTCONFIG", skin->GetRootName());
insertVariable(L"ROOTCONFIGPATH", skin->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 ConfigParser::ReadVariables()
{
std::list<std::wstring>::const_iterator iter = m_ListVariables.begin();
for ( ; iter != m_ListVariables.end(); ++iter)
{
SetVariable((*iter), ReadString(L"Variables", (*iter).c_str(), L"", false));
}
}
void ConfigParser::SetVariable(std::wstring strVariable, const std::wstring& strValue)
{
StrToUpperC(strVariable);
m_Variables[strVariable] = strValue;
}
void ConfigParser::SetBuiltInVariable(const std::wstring& strVariable, const std::wstring& strValue)
{
m_BuiltInVariables[strVariable] = strValue;
}
/*
** Gets a value for the variable. Returns nullptr if not found.
**
*/
const std::wstring* ConfigParser::GetVariable(const std::wstring& strVariable)
{
const std::wstring strTmp = StrToUpper(strVariable);
// #1: Built-in variables
std::unordered_map<std::wstring, std::wstring>::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 nullptr;
}
/*
** Gets the value of a section variable. Returns true if strValue is set.
** The selector is stripped from strVariable.
**
*/
bool ConfigParser::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]
Meter* meter = m_Skin->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)
// EscapeRegExp: [Measure:EscapeRegExp] (Escapes regular expression syntax, used for 'IfMatch')
// EncodeUrl: [Measure:EncodeUrl] (Escapes URL reserved characters)
// TimeStamp: [TimeMeasure:TimeStamp] (ONLY for Time measures, returns the Windows timestamp of the measure)
enum class ValueType
{
Raw,
Percentual,
Max,
Min,
EscapeRegExp,
EncodeUrl,
TimeStamp
} valueType = ValueType::Raw;
if (isKeySelector)
{
if (_wcsicmp(selectorSz, L"MaxValue") == 0)
{
valueType = ValueType::Max;
}
else if (_wcsicmp(selectorSz, L"MinValue") == 0)
{
valueType = ValueType::Min;
}
else if (_wcsicmp(selectorSz, L"EscapeRegExp") == 0)
{
valueType = ValueType::EscapeRegExp;
}
else if (_wcsicmp(selectorSz, L"EncodeUrl") == 0)
{
valueType = ValueType::EncodeUrl;
}
else if (_wcsicmp(selectorSz, L"TimeStamp") == 0)
{
valueType = ValueType::TimeStamp;
}
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 = ValueType::Max;
}
else if (_wcsicmp(keySelectorSz, L"MinValue") == 0)
{
valueType = ValueType::Min;
}
else
{
// Section name contains ':' ?
break;
}
strVariable.resize(colonPos);
}
while (0);
}
}
Measure* measure = m_Skin->GetMeasure(strVariable);
if (measure)
{
if (valueType == ValueType::EscapeRegExp)
{
strValue = measure->GetStringValue();
StringUtil::EscapeRegExp(strValue);
return true;
}
else if (valueType == ValueType::EncodeUrl)
{
strValue = measure->GetStringValue();
StringUtil::EncodeUrl(strValue);
return true;
}
else if (measure->GetTypeID() == TypeID<MeasureTime>() && valueType == ValueType::TimeStamp)
{
MeasureTime* time = (MeasureTime*)measure;
strValue = std::to_wstring(time->GetTimeStamp().QuadPart / 10000000);
return true;
}
int scale = 1;
const WCHAR* decimalsSz = wcschr(selectorSz, L',');
if (decimalsSz)
{
++decimalsSz;
}
if (*selectorSz == L'%') // Percentual
{
if (valueType == ValueType::Max || valueType == ValueType::Min)
{
// '%' cannot be used with Max/Min values.
return false;
}
valueType = ValueType::Percentual;
}
else if (*selectorSz == L'/') // Scale
{
errno = 0;
scale = _wtoi(selectorSz + 1);
if (errno == EINVAL || scale == 0)
{
// Invalid scale value.
return false;
}
}
else
{
if (decimalsSz)
{
return false;
}
decimalsSz = selectorSz;
}
const double value =
(valueType == ValueType::Percentual) ? measure->GetRelativeValue() * 100.0 :
(valueType == ValueType::Max) ? measure->GetMaxValue() / scale :
(valueType == 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 = nullptr;
}
}
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 ConfigParser::ResetMonitorVariables(Skin* skin)
{
// Set the SCREENAREA/WORKAREA variables
if (c_MonitorVariables.empty())
{
SetMultiMonitorVariables(true);
}
// Set the SCREENAREA/WORKAREA variables for present monitor
SetAutoSelectedMonitorVariables(skin);
}
/*
** Sets new values for the SCREENAREA/WORKAREA variables.
**
*/
void ConfigParser::SetMultiMonitorVariables(bool reset)
{
auto setMonitorVariable = [&](const WCHAR* variable, const WCHAR* value)
{
c_MonitorVariables[variable] = value;
};
if (!reset && c_MonitorVariables.empty())
{
reset = true; // Set all variables
}
const size_t numOfMonitors = System::GetMonitorCount(); // intentional
const MultiMonitorInfo& monitorsInfo = System::GetMultiMonitorInfo();
const std::vector<MonitorInfo>& monitors = monitorsInfo.monitors;
WCHAR buffer[32];
const RECT workArea = monitors[monitorsInfo.primary - 1].work;
const RECT scrArea = monitors[monitorsInfo.primary - 1].screen;
_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)
{
_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(monitorsInfo.vsL, buffer, 10);
setMonitorVariable(L"VSCREENAREAX", buffer);
_itow_s(monitorsInfo.vsT, buffer, 10);
setMonitorVariable(L"VSCREENAREAY", buffer);
_itow_s(monitorsInfo.vsW, buffer, 10);
setMonitorVariable(L"VSCREENAREAWIDTH", buffer);
_itow_s(monitorsInfo.vsH, buffer, 10);
setMonitorVariable(L"VSCREENAREAHEIGHT", buffer);
}
int i = 1;
for (auto iter = monitors.cbegin(); iter != monitors.cend(); ++iter, ++i)
{
WCHAR buffer2[64];
const RECT work = ((*iter).active) ? (*iter).work : workArea;
_itow_s(work.left, buffer, 10);
_snwprintf_s(buffer2, _TRUNCATE, L"WORKAREAX@%i", i);
setMonitorVariable(buffer2, buffer);
_itow_s(work.top, buffer, 10);
_snwprintf_s(buffer2, _TRUNCATE, L"WORKAREAY@%i", i);
setMonitorVariable(buffer2, buffer);
_itow_s(work.right - work.left, buffer, 10);
_snwprintf_s(buffer2, _TRUNCATE, L"WORKAREAWIDTH@%i", i);
setMonitorVariable(buffer2, buffer);
_itow_s(work.bottom - work.top, buffer, 10);
_snwprintf_s(buffer2, _TRUNCATE, L"WORKAREAHEIGHT@%i", i);
setMonitorVariable(buffer2, buffer);
if (reset)
{
const RECT screen = ((*iter).active) ? (*iter).screen : scrArea;
_itow_s(screen.left, buffer, 10);
_snwprintf_s(buffer2, _TRUNCATE, L"SCREENAREAX@%i", i);
setMonitorVariable(buffer2, buffer);
_itow_s(screen.top, buffer, 10);
_snwprintf_s(buffer2, _TRUNCATE, L"SCREENAREAY@%i", i);
setMonitorVariable(buffer2, buffer);
_itow_s(screen.right - screen.left, buffer, 10);
_snwprintf_s(buffer2, _TRUNCATE, L"SCREENAREAWIDTH@%i", i);
setMonitorVariable(buffer2, buffer);
_itow_s(screen.bottom - screen.top, buffer, 10);
_snwprintf_s(buffer2, _TRUNCATE, L"SCREENAREAHEIGHT@%i", i);
setMonitorVariable(buffer2, buffer);
}
}
}
/*
** Sets new SCREENAREA/WORKAREA variables for present monitor.
**
*/
void ConfigParser::SetAutoSelectedMonitorVariables(Skin* skin)
{
if (skin)
{
const int numOfMonitors = (int)System::GetMonitorCount();
const MultiMonitorInfo& monitorsInfo = System::GetMultiMonitorInfo();
const std::vector<MonitorInfo>& monitors = monitorsInfo.monitors;
WCHAR buffer[32];
int w1, w2, s1, s2;
int screenIndex;
// Set X / WIDTH
screenIndex = monitorsInfo.primary;
if (skin->GetXScreenDefined())
{
int i = skin->GetXScreen();
if (i >= 0 && (i == 0 || i <= numOfMonitors && monitors[i - 1].active))
{
screenIndex = i;
}
}
if (screenIndex == 0)
{
s1 = w1 = monitorsInfo.vsL;
s2 = w2 = monitorsInfo.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 = monitorsInfo.primary;
if (skin->GetYScreenDefined())
{
int i = skin->GetYScreen();
if (i >= 0 && (i == 0 || i <= numOfMonitors && monitors[i - 1].active))
{
screenIndex = i;
}
}
if (screenIndex == 0)
{
s1 = w1 = monitorsInfo.vsL;
s2 = w2 = monitorsInfo.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);
}
}
/*
** Replaces environment and internal variables in the given string.
**
*/
bool ConfigParser::ReplaceVariables(std::wstring& result)
{
bool replaced = false;
PathUtil::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 ConfigParser::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);
Measure* measure = GetMeasure(var);
if (measure)
{
const WCHAR* value = measure->GetStringOrFormattedValue(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& ConfigParser::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<std::wstring>::const_reverse_iterator iter = m_StyleTemplate.rbegin();
for ( ; iter != m_StyleTemplate.rend(); ++iter)
{
const std::wstring& strStyleValue = GetValue((*iter), strKey, strDefault);
//LogDebugF(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)
{
m_CurrentSection->assign(strSection); // Set temporarily
if (ReplaceVariables(result))
{
m_LastReplaced = true;
}
m_CurrentSection->clear(); // Reset
}
else
{
PathUtil::ExpandEnvironmentVariables(result);
}
if (bReplaceMeasures && ReplaceMeasures(result))
{
m_LastReplaced = true;
}
}
}
return result;
}
bool ConfigParser::IsKeyDefined(LPCTSTR section, LPCTSTR key)
{
ReadString(section, key, L"", false);
return !m_LastDefaultUsed;
}
bool ConfigParser::IsValueDefined(LPCTSTR section, LPCTSTR key)
{
ReadString(section, key, L"", false);
return m_LastValueDefined;
}
void ConfigParser::AddMeasure(Measure* pMeasure)
{
if (pMeasure)
{
m_Measures[StrToUpper(pMeasure->GetOriginalName())] = pMeasure;
}
}
Measure* ConfigParser::GetMeasure(const std::wstring& name)
{
std::unordered_map<std::wstring, Measure*>::const_iterator iter = m_Measures.find(StrToUpper(name));
if (iter != m_Measures.end())
{
return (*iter).second;
}
return nullptr;
}
std::vector<Gdiplus::REAL> ConfigParser::ReadFloats(LPCTSTR section, LPCTSTR key)
{
std::vector<Gdiplus::REAL> result;
const std::wstring& str = ReadString(section, key, L"");
if (!str.empty())
{
// Tokenize and parse the floats
const WCHAR delimiter = L';';
size_t lastPos, pos = 0;
do
{
lastPos = str.find_first_not_of(delimiter, pos);
if (lastPos == std::wstring::npos) break;
pos = str.find_first_of(delimiter, lastPos + 1);
result.push_back((Gdiplus::REAL)ParseDouble(str.substr(lastPos, pos - lastPos).c_str(), 0.0)); // (pos != std::wstring::npos) ? pos - lastPos : pos
if (pos == std::wstring::npos) break;
++pos;
}
while (true);
}
return result;
}
int ConfigParser::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;
}
LogErrorF(m_Skin, L"Formula: %s in key \"%s\" in [%s]", errMsg, key, section);
}
else if (*string)
{
errno = 0;
int intValue = wcstol(string, nullptr, 10);
if (errno != ERANGE)
{
return intValue;
}
}
}
return defValue;
}
uint32_t ConfigParser::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;
}
LogErrorF(m_Skin, L"Formula: %s in key \"%s\" in [%s]", errMsg, key, section);
}
else if (*string)
{
errno = 0;
uint32_t uintValue = wcstoul(string, nullptr, 10);
if (errno != ERANGE)
{
return uintValue;
}
}
}
return defValue;
}
uint64_t ConfigParser::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;
}
LogErrorF(m_Skin, L"Formula: %s in key \"%s\" in [%s]", errMsg, key, section);
}
else if (*string)
{
errno = 0;
uint64_t uint64Value = _wcstoui64(string, nullptr, 10);
if (errno != ERANGE)
{
return uint64Value;
}
}
}
return defValue;
}
double ConfigParser::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;
}
LogErrorF(m_Skin, L"Formula: %s in key \"%s\" in [%s]", errMsg, key, section);
}
else if (*string)
{
errno = 0;
value = wcstod(string, nullptr);
if (errno != ERANGE)
{
return value;
}
}
}
return defValue;
}
// Returns true if the formula was read successfully, false for failure.
bool ConfigParser::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 != nullptr)
{
LogErrorF(m_Skin, L"Formula: %s: %s", errMsg, string);
return false;
}
return true;
}
return false;
}
ARGB ConfigParser::ReadColor(LPCTSTR section, LPCTSTR key, ARGB defValue)
{
const std::wstring& result = ReadString(section, key, L"");
return (m_LastDefaultUsed) ? defValue : ParseColor(result.c_str());
}
Rect ConfigParser::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 ConfigParser::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.
** Now trims empty element in vector and white-space in each string.
**
** Modified from http://www.digitalpeer.com/id/simple
*/
std::vector<std::wstring> ConfigParser::Tokenize(const std::wstring& str, const std::wstring& delimiters)
{
std::vector<std::wstring> tokens;
size_t lastPos, pos = 0;
do
{
lastPos = str.find_first_not_of(delimiters, pos);
if (lastPos == std::wstring::npos) break;
pos = str.find_first_of(delimiters, lastPos + 1);
std::wstring token = str.substr(lastPos, pos - lastPos); // len = (pos != std::wstring::npos) ? pos - lastPos : pos
size_t pos2 = token.find_first_not_of(L" \t\r\n");
if (pos2 != std::wstring::npos)
{
size_t lastPos2 = token.find_last_not_of(L" \t\r\n");
if (pos2 != 0 || lastPos2 != (token.size() - 1))
{
// Trim white-space
token.assign(token, pos2, lastPos2 - pos2 + 1);
}
tokens.push_back(token);
}
if (pos == std::wstring::npos) break;
++pos;
}
while (true);
return tokens;
}
/*
** 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 ConfigParser::ParseDouble(LPCTSTR string, double defValue)
{
assert(string);
double value;
if (*string == L'(')
{
const WCHAR* errMsg = MathParser::CheckedParse(string, &value);
if (!errMsg)
{
return value;
}
LogErrorF(L"Formula: %s: %s", errMsg, string);
}
else if (*string)
{
errno = 0;
double value = wcstod(string, nullptr);
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 ConfigParser::ParseInt(LPCTSTR string, int defValue)
{
assert(string);
if (*string == L'(')
{
double dblValue;
const WCHAR* errMsg = MathParser::CheckedParse(string, &dblValue);
if (!errMsg)
{
return (int)dblValue;
}
LogErrorF(L"Formula: %s: %s", errMsg, string);
}
else if (*string)
{
errno = 0;
int intValue = wcstol(string, nullptr, 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 ConfigParser::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;
}
LogErrorF(L"Formula: %s: %s", errMsg, string);
}
else if (*string)
{
errno = 0;
uint32_t uintValue = wcstoul(string, nullptr, 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 ConfigParser::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;
}
LogErrorF(L"Formula: %s: %s", errMsg, string);
}
else if (*string)
{
errno = 0;
uint64_t uint64Value = _wcstoui64(string, nullptr, 10);
if (errno != ERANGE)
{
return uint64Value;
}
}
return defValue;
}
/*
** Helper template that parses four comma separated values from the given string.
**
*/
template <typename T>
bool ParseInt4(LPCTSTR string, T& v1, T& v2, T& v3, T& v4)
{
if (wcschr(string, L','))
{
std::wstring str = string;
std::vector<T> tokens;
size_t start = 0;
size_t end = 0;
int parens = 0;
auto getToken = [&]() -> void
{
start = str.find_first_not_of(L" \t", start); // skip any leading whitespace
if (start <= end)
{
tokens.push_back(ConfigParser::ParseInt(str.substr(start, end - start).c_str(), 0));
}
};
for (auto iter : str)
{
switch (iter)
{
case '(': ++parens; break;
case ')': --parens; break;
case ',':
{
if (parens == 0)
{
getToken();
start = end + 1; // skip comma
break;
}
//else multi arg function ?
}
}
++end;
}
// read last token
getToken();
size_t size = tokens.size();
if (size > 0) v1 = tokens[0];
if (size > 1) v2 = tokens[1];
if (size > 2) v3 = tokens[2];
if (size > 3) v4 = tokens[3];
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 ConfigParser::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 ConfigParser::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 ConfigParser::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 ConfigParser::ReadIniFile(const std::wstring& iniFile, LPCTSTR skinSection, int depth)
{
if (depth > 100) // Is 100 enough to assume the include loop never ends?
{
GetRainmeter().ShowMessage(nullptr, GetString(ID_STR_INCLUDEINFINITELOOP), MB_OK | MB_ICONERROR);
return;
}
// Verify whether the file exists
if (_waccess(iniFile.c_str(), 0) == -1)
{
LogErrorF(m_Skin, L"Unable to read file: %s", iniFile.c_str());
return;
}
// Avoid "IniFileMapping"
std::wstring iniRead = System::GetTemporaryFile(iniFile);
bool temporary = (!iniRead.empty() && (iniRead.size() != 1 || iniRead[0] != L'?'));
if (temporary)
{
if (GetRainmeter().GetDebug()) LogDebugF(m_Skin, L"Reading file: %s (Temp: %s)", iniFile.c_str(), iniRead.c_str());
}
else
{
if (GetRainmeter().GetDebug()) LogDebugF(m_Skin, L"Reading file: %s", iniFile.c_str());
iniRead = iniFile;
}
// Get all the sections (i.e. different meters)
std::list<std::wstring> sections;
std::unordered_set<std::wstring> unique;
std::wstring key, value; // buffer
DWORD itemsSize = MAX_LINE_LENGTH;
WCHAR* items = new WCHAR[itemsSize];
WCHAR* pos = nullptr;
WCHAR* epos = nullptr;
if (skinSection == nullptr)
{
// 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) System::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 == nullptr && !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 != nullptr && 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 (!PathUtil::IsAbsolute(value))
{
// Relative to the ini folder
value.insert(0, PathUtil::GetFolderFromFilePath(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) System::RemoveFile(iniRead);
}
/*
** Sets the value for the key under the given section.
**
*/
void ConfigParser::SetValue(const std::wstring& strSection, const std::wstring& strKey, const std::wstring& strValue)
{
// LogDebugF(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 ConfigParser::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<std::wstring, std::wstring>::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& ConfigParser::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<std::wstring, std::wstring>::const_iterator iter = m_Values.find(StrToUpperC(strTmp));
return (iter != m_Values.end()) ? (*iter).second : strDefault;
}