/* Copyright (C) 2001 Kimmo Pekkola This program is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 2 of the License, or (at your option) any later version. This program is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with this program; if not, write to the Free Software Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA. */ #include "StdAfx.h" #include "MeasureNet.h" #include "Rainmeter.h" #include "System.h" BYTE* CMeasureNet::c_Table = NULL; UINT CMeasureNet::c_NumOfTables = 0; std::vector CMeasureNet::c_StatValues; std::vector CMeasureNet::c_OldStatValues; FPGETIFTABLE2 CMeasureNet::c_GetIfTable2 = NULL; FPFREEMIBTABLE CMeasureNet::c_FreeMibTable = NULL; extern CRainmeter* Rainmeter; /* ** The constructor. This is the base class for the net-meters. ** */ CMeasureNet::CMeasureNet(CMeterWindow* meterWindow, const WCHAR* name, NET type) : CMeasure(meterWindow, name), m_Net(type), m_Interface(), m_Octets(), m_FirstTime(true), m_Cumulative(false) { } /* ** The destructor ** */ CMeasureNet::~CMeasureNet() { } /* ** Reads the tables for all net interfaces ** */ void CMeasureNet::UpdateIFTable() { bool logging = false; if (c_GetIfTable2) { if (c_Table) { c_FreeMibTable(c_Table); c_Table = NULL; } if (c_GetIfTable2((MIB_IF_TABLE2**)&c_Table) == NO_ERROR) { MIB_IF_TABLE2* ifTable = (MIB_IF_TABLE2*)c_Table; if (c_NumOfTables != ifTable->NumEntries) { c_NumOfTables = ifTable->NumEntries; logging = true; } if (Rainmeter->GetDebug() && logging) { Log(LOG_DEBUG, L"------------------------------"); LogWithArgs(LOG_DEBUG, L"* NETWORK-INTERFACE: Count=%i", c_NumOfTables); for (size_t i = 0; i < c_NumOfTables; ++i) { const WCHAR* type = L"Other"; switch (ifTable->Table[i].Type) { case IF_TYPE_ETHERNET_CSMACD: type = L"Ethernet"; break; case IF_TYPE_PPP: type = L"PPP"; break; case IF_TYPE_SOFTWARE_LOOPBACK: type = L"Loopback"; break; case IF_TYPE_IEEE80211: type = L"IEEE802.11"; break; case IF_TYPE_TUNNEL: type = L"Tunnel"; break; case IF_TYPE_IEEE1394: type = L"IEEE1394"; break; } LogWithArgs(LOG_DEBUG, L"%i: %s", (int)i + 1, ifTable->Table[i].Description); LogWithArgs(LOG_DEBUG, L" Alias: %s", ifTable->Table[i].Alias); LogWithArgs(LOG_DEBUG, L" Type=%s(%i), Hardware=%s, Filter=%s", type, ifTable->Table[i].Type, (ifTable->Table[i].InterfaceAndOperStatusFlags.HardwareInterface == 1) ? L"Yes" : L"No", (ifTable->Table[i].InterfaceAndOperStatusFlags.FilterInterface == 1) ? L"Yes" : L"No"); } Log(LOG_DEBUG, L"------------------------------"); } } else { // Something's wrong. Unable to get the table. c_Table = NULL; c_NumOfTables = 0; } } else { if (c_Table == NULL) { // Gotta reserve few bytes for the tables DWORD value = 0; if (GetNumberOfInterfaces(&value) == NO_ERROR) { if (c_NumOfTables != value) { c_NumOfTables = value; logging = true; } if (c_NumOfTables > 0) { DWORD size = sizeof(MIB_IFTABLE) + sizeof(MIB_IFROW) * c_NumOfTables; c_Table = new BYTE[size]; } } } if (c_Table) { DWORD ret, size = 0; MIB_IFTABLE* ifTable = (MIB_IFTABLE*)c_Table; if ((ret = GetIfTable(ifTable, &size, FALSE)) == ERROR_INSUFFICIENT_BUFFER) { delete [] c_Table; c_Table = new BYTE[size]; ifTable = (MIB_IFTABLE*)c_Table; ret = GetIfTable(ifTable, &size, FALSE); } if (ret == NO_ERROR) { if (c_NumOfTables != ifTable->dwNumEntries) { c_NumOfTables = ifTable->dwNumEntries; logging = true; } if (Rainmeter->GetDebug() && logging) { Log(LOG_DEBUG, L"------------------------------"); LogWithArgs(LOG_DEBUG, L"* NETWORK-INTERFACE: Count=%i", c_NumOfTables); for (size_t i = 0; i < c_NumOfTables; ++i) { const WCHAR* type = L""; switch (ifTable->table[i].dwType) { case IF_TYPE_ETHERNET_CSMACD: type = L"Ethernet"; break; case IF_TYPE_PPP: type = L"PPP"; break; case IF_TYPE_SOFTWARE_LOOPBACK: type = L"Loopback"; break; case IF_TYPE_IEEE80211: type = L"IEEE802.11"; break; case IF_TYPE_TUNNEL: type = L"Tunnel"; break; case IF_TYPE_IEEE1394: type = L"IEEE1394"; break; default: type = L"Other"; break; } LogWithArgs(LOG_DEBUG, L"%i: %.*S", (int)i + 1, ifTable->table[i].dwDescrLen, (char*)ifTable->table[i].bDescr); LogWithArgs(LOG_DEBUG, L" Type=%s(%i)", type, ifTable->table[i].dwType); } Log(LOG_DEBUG, L"------------------------------"); } } else { // Something's wrong. Unable to get the table. delete [] c_Table; c_Table = NULL; c_NumOfTables = 0; } } } } /* ** Reads the amount of octets. This is the same for in, out and total. ** the net-parameter informs which inherited class called this method. ** */ ULONG64 CMeasureNet::GetNetOctets(NET net) { ULONG64 value = 0; if (c_GetIfTable2) { MIB_IF_ROW2* table = (MIB_IF_ROW2*)((MIB_IF_TABLE2*)c_Table)->Table; if (m_Interface == 0) { // Get all interfaces for (UINT i = 0; i < c_NumOfTables; ++i) { // Ignore the loopback and filter interfaces if (table[i].Type == IF_TYPE_SOFTWARE_LOOPBACK || table[i].InterfaceAndOperStatusFlags.FilterInterface == 1) continue; switch (net) { case NET_IN: value += table[i].InOctets; break; case NET_OUT: value += table[i].OutOctets; break; case NET_TOTAL: value += table[i].InOctets; value += table[i].OutOctets; break; } } } else { // Get the selected interface if (m_Interface <= c_NumOfTables) { switch (net) { case NET_IN: value += table[m_Interface - 1].InOctets; break; case NET_OUT: value += table[m_Interface - 1].OutOctets; break; case NET_TOTAL: value += table[m_Interface - 1].InOctets; value += table[m_Interface - 1].OutOctets; break; } } } } else { MIB_IFROW* table = (MIB_IFROW*)((MIB_IFTABLE*)c_Table)->table; if (m_Interface == 0) { // Get all interfaces for (UINT i = 0; i < c_NumOfTables; ++i) { // Ignore the loopback if (table[i].dwType == IF_TYPE_SOFTWARE_LOOPBACK) continue; switch (net) { case NET_IN: value += table[i].dwInOctets; break; case NET_OUT: value += table[i].dwOutOctets; break; case NET_TOTAL: value += table[i].dwInOctets; value += table[i].dwOutOctets; break; } } } else { // Get the selected interface if (m_Interface <= c_NumOfTables) { switch (net) { case NET_IN: value += table[m_Interface - 1].dwInOctets; break; case NET_OUT: value += table[m_Interface - 1].dwOutOctets; break; case NET_TOTAL: value += table[m_Interface - 1].dwInOctets; value += table[m_Interface - 1].dwOutOctets; break; } } } } return value; } /* ** Returns the stats value of the interface ** */ ULONG64 CMeasureNet::GetNetStatsValue(NET net) { ULONG64 value = 0; size_t statsSize = c_StatValues.size() / 2; if (m_Interface == 0) { // Get all interfaces for (size_t i = 0; i < statsSize; ++i) { // Ignore the loopback and filter interfaces if (c_NumOfTables == statsSize) { if (c_GetIfTable2) { if (((MIB_IF_TABLE2*)c_Table)->Table[i].Type == IF_TYPE_SOFTWARE_LOOPBACK || ((MIB_IF_TABLE2*)c_Table)->Table[i].InterfaceAndOperStatusFlags.FilterInterface == 1) continue; } else { if (((MIB_IFTABLE*)c_Table)->table[i].dwType == IF_TYPE_SOFTWARE_LOOPBACK) continue; } } switch (net) { case NET_IN: value += c_StatValues[i * 2 + 0]; break; case NET_OUT: value += c_StatValues[i * 2 + 1]; break; case NET_TOTAL: value += c_StatValues[i * 2 + 0]; value += c_StatValues[i * 2 + 1]; break; } } } else { // Get the selected interface if (m_Interface <= statsSize) { switch (net) { case NET_IN: value += c_StatValues[(m_Interface - 1) * 2 + 0]; break; case NET_OUT: value += c_StatValues[(m_Interface - 1) * 2 + 1]; break; case NET_TOTAL: value += c_StatValues[(m_Interface - 1) * 2 + 0]; value += c_StatValues[(m_Interface - 1) * 2 + 1]; break; } } } return value; } /* ** Updates the current value. ** */ void CMeasureNet::UpdateValue() { if (c_Table == NULL) return; if (m_Cumulative) { m_Value = (double)(__int64)GetNetStatsValue(m_Net); } else { ULONG64 value = 0; if (!m_FirstTime) { value = GetNetOctets(m_Net); if (value > m_Octets) { ULONG64 tmpValue = value; value -= m_Octets; m_Octets = tmpValue; } else { m_Octets = value; value = 0; } } else { m_Octets = GetNetOctets(m_Net); m_FirstTime = false; } m_Value = (double)(__int64)value; } } /* ** Read the options specified in the ini file. ** */ void CMeasureNet::ReadOptions(CConfigParser& parser, const WCHAR* section) { CMeasure::ReadOptions(parser, section); double value; const WCHAR* netName = NULL; if (m_Net == NET_IN) { netName = L"NetInSpeed"; value = Rainmeter->GetGlobalOptions().netInSpeed; } else if (m_Net == NET_OUT) { netName = L"NetOutSpeed"; value = Rainmeter->GetGlobalOptions().netOutSpeed; } else // if (m_Net == NET_TOTAL) { netName = L"NetTotalSpeed"; value = Rainmeter->GetGlobalOptions().netInSpeed + Rainmeter->GetGlobalOptions().netOutSpeed; } double maxValue = parser.ReadFloat(section, L"MaxValue", -1); if (maxValue == -1) { maxValue = parser.ReadFloat(section, netName, -1); if (maxValue == -1) { maxValue = value; } } m_Interface = parser.ReadInt(section, L"Interface", 0); m_Cumulative = 0!=parser.ReadInt(section, L"Cumulative", 0); if (m_Cumulative) { Rainmeter->SetNetworkStatisticsTimer(); } if (maxValue == 0.0) { if (!m_LogMaxValue) { m_MaxValue = 1.0; m_LogMaxValue = true; m_MedianValues.clear(); } } else { m_MaxValue = maxValue / 8; m_LogMaxValue = false; } } /* ** Updates the statistics. ** */ void CMeasureNet::UpdateStats() { if (c_Table) { size_t statsSize = c_NumOfTables * 2; // Fill the vectors if (c_StatValues.size() < statsSize) { c_StatValues.resize(statsSize, 0); } if (c_OldStatValues.size() < statsSize) { c_OldStatValues.resize(statsSize, 0); } for (UINT i = 0; i < c_NumOfTables; ++i) { ULONG64 in, out; if (c_GetIfTable2) { in = ((MIB_IF_TABLE2*)c_Table)->Table[i].InOctets; out = ((MIB_IF_TABLE2*)c_Table)->Table[i].OutOctets; } else { in = ((MIB_IFTABLE*)c_Table)->table[i].dwInOctets; out = ((MIB_IFTABLE*)c_Table)->table[i].dwOutOctets; } if (c_OldStatValues[i * 2 + 0] != 0) { if (in > c_OldStatValues[i * 2 + 0]) { c_StatValues[i * 2 + 0] += in - c_OldStatValues[i * 2 + 0]; } } if (c_OldStatValues[i * 2 + 1] != 0) { if (out > c_OldStatValues[i * 2 + 1]) { c_StatValues[i * 2 + 1] += out - c_OldStatValues[i * 2 + 1]; } } c_OldStatValues[i * 2 + 0] = in; c_OldStatValues[i * 2 + 1] = out; } } } /* ** Resets the statistics. ** */ void CMeasureNet::ResetStats() { c_StatValues.clear(); } /* ** Reads statistics. ** */ void CMeasureNet::ReadStats(const std::wstring& iniFile, std::wstring& statsDate) { WCHAR buffer[48]; CConfigParser parser; parser.Initialize(iniFile, NULL, L"Statistics"); const std::wstring& date = parser.ReadString(L"Statistics", L"Since", L"", false); if (!date.empty()) { statsDate = date; } uint32_t count = parser.ReadUInt(L"Statistics", L"Count", 0); if (parser.GetLastDefaultUsed()) { count = parser.ReadUInt(L"Statistics", L"NetStatsCount", 0); } c_StatValues.clear(); c_StatValues.reserve(count * 2); for (uint32_t i = 1; i <= count; ++i) { ULARGE_INTEGER value; _snwprintf_s(buffer, _TRUNCATE, L"In%u", i); value.QuadPart = parser.ReadUInt64(L"Statistics", buffer, 0); if (parser.GetLastDefaultUsed()) { _snwprintf_s(buffer, _TRUNCATE, L"NetStatsInHigh%u", i); value.HighPart = parser.ReadUInt(L"Statistics", buffer, 0); _snwprintf_s(buffer, _TRUNCATE, L"NetStatsInLow%u", i); value.LowPart = parser.ReadUInt(L"Statistics", buffer, 0); } c_StatValues.push_back(value.QuadPart); _snwprintf_s(buffer, _TRUNCATE, L"Out%u", i); value.QuadPart = parser.ReadUInt64(L"Statistics", buffer, 0); if (parser.GetLastDefaultUsed()) { _snwprintf_s(buffer, _TRUNCATE, L"NetStatsOutHigh%u", i); value.HighPart = parser.ReadUInt(L"Statistics", buffer, 0); _snwprintf_s(buffer, _TRUNCATE, L"NetStatsOutLow%u", i); value.LowPart = parser.ReadUInt(L"Statistics", buffer, 0); } c_StatValues.push_back(value.QuadPart); } } /* ** Writes statistics. ** */ void CMeasureNet::WriteStats(const WCHAR* iniFile, const std::wstring& statsDate) { WCHAR buffer[48]; int len; uint32_t count = c_StatValues.size() / 2; // Reserve sufficient buffer for statistics std::wstring data; data.reserve(48 * (2 + count)); // Add date data = L"Since="; data += statsDate; data += L'\0'; auto appendStatsValue = [&]() { data.append(buffer, len); data += L'\0'; }; // Add stats count len = _snwprintf_s(buffer, _TRUNCATE, L"Count=%u", count); appendStatsValue(); // Add stats for (uint32_t i = 0; i < count; ++i) { if (c_StatValues[i * 2] > 0) { len = _snwprintf_s(buffer, _TRUNCATE, L"In%u=%llu", i + 1, c_StatValues[i * 2]); appendStatsValue(); } if (c_StatValues[i * 2 + 1] > 0) { len = _snwprintf_s(buffer, _TRUNCATE, L"Out%u=%llu", i + 1, c_StatValues[i * 2 + 1]); appendStatsValue(); } } // Write statistics WritePrivateProfileSection(L"Statistics", data.c_str(), iniFile); } /* ** Prepares in order to use the new APIs which are available on Vista or newer. ** */ void CMeasureNet::InitializeNewApi() { if (CSystem::GetOSPlatform() >= OSPLATFORM_VISTA) { HMODULE IpHlpApiLibrary = GetModuleHandle(L"IpHlpApi.dll"); if (IpHlpApiLibrary) { c_GetIfTable2 = (FPGETIFTABLE2)GetProcAddress(IpHlpApiLibrary, "GetIfTable2"); c_FreeMibTable = (FPFREEMIBTABLE)GetProcAddress(IpHlpApiLibrary, "FreeMibTable"); } if (!c_GetIfTable2 || !c_FreeMibTable) { c_GetIfTable2 = NULL; c_FreeMibTable = NULL; } } if (Rainmeter->GetDebug()) { UpdateIFTable(); } } /* ** Frees the resources. ** */ void CMeasureNet::FinalizeNewApi() { if (c_GetIfTable2) { if (c_Table) { c_FreeMibTable(c_Table); } c_GetIfTable2 = NULL; c_FreeMibTable = NULL; } else { delete [] c_Table; } c_Table = NULL; c_NumOfTables = 0; }