/****************************************************************************** * Icinga 2 * * Copyright (C) 2012-2015 Icinga Development Team (http://www.icinga.org) * * * * 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 St, Fifth Floor, Boston, MA 02110-1301, USA. * ******************************************************************************/ #include "icinga/macroprocessor.hpp" #include "icinga/macroresolver.hpp" #include "icinga/customvarobject.hpp" #include "base/array.hpp" #include "base/objectlock.hpp" #include "base/logger.hpp" #include "base/context.hpp" #include "base/configobject.hpp" #include "base/scriptframe.hpp" #include "base/convert.hpp" #include "base/exception.hpp" #include #include #include #include using namespace icinga; Value MacroProcessor::ResolveMacros(const Value& str, const ResolverList& resolvers, const CheckResult::Ptr& cr, String *missingMacro, const MacroProcessor::EscapeCallback& escapeFn, const Dictionary::Ptr& resolvedMacros, bool useResolvedMacros, int recursionLevel) { Value result; if (str.IsEmpty()) return Empty; if (str.IsScalar()) { result = InternalResolveMacros(str, resolvers, cr, missingMacro, escapeFn, resolvedMacros, useResolvedMacros, recursionLevel + 1); } else if (str.IsObjectType()) { Array::Ptr resultArr = new Array(); Array::Ptr arr = str; ObjectLock olock(arr); BOOST_FOREACH(const Value& arg, arr) { /* Note: don't escape macros here. */ Value value = InternalResolveMacros(arg, resolvers, cr, missingMacro, EscapeCallback(), resolvedMacros, useResolvedMacros, recursionLevel + 1); if (value.IsObjectType()) resultArr->Add(Utility::Join(value, ';')); else resultArr->Add(value); } result = resultArr; } else if (str.IsObjectType()) { Dictionary::Ptr resultDict = new Dictionary(); Dictionary::Ptr dict = str; ObjectLock olock(dict); BOOST_FOREACH(const Dictionary::Pair& kv, dict) { /* Note: don't escape macros here. */ resultDict->Set(kv.first, InternalResolveMacros(kv.second, resolvers, cr, missingMacro, EscapeCallback(), resolvedMacros, useResolvedMacros, recursionLevel + 1)); } result = resultDict; } else if (str.IsObjectType()) { result = EvaluateFunction(str, resolvers, cr, escapeFn, resolvedMacros, useResolvedMacros, 0); } else { BOOST_THROW_EXCEPTION(std::invalid_argument("Macro is not a string or array.")); } return result; } bool MacroProcessor::ResolveMacro(const String& macro, const ResolverList& resolvers, const CheckResult::Ptr& cr, Value *result, bool *recursive_macro) { CONTEXT("Resolving macro '" + macro + "'"); *recursive_macro = false; std::vector tokens; boost::algorithm::split(tokens, macro, boost::is_any_of(".")); String objName; if (tokens.size() > 1) { objName = tokens[0]; tokens.erase(tokens.begin()); } BOOST_FOREACH(const ResolverSpec& resolver, resolvers) { if (!objName.IsEmpty() && objName != resolver.first) continue; if (objName.IsEmpty()) { CustomVarObject::Ptr dobj = dynamic_pointer_cast(resolver.second); if (dobj) { Dictionary::Ptr vars = dobj->GetVars(); if (vars && vars->Contains(macro)) { *result = vars->Get(macro); *recursive_macro = true; return true; } } } MacroResolver *mresolver = dynamic_cast(resolver.second.get()); if (mresolver && mresolver->ResolveMacro(boost::algorithm::join(tokens, "."), cr, result)) return true; Value ref = resolver.second; bool valid = true; BOOST_FOREACH(const String& token, tokens) { if (ref.IsObjectType()) { Dictionary::Ptr dict = ref; if (dict->Contains(token)) { ref = dict->Get(token); continue; } else { valid = false; break; } } else if (ref.IsObject()) { Object::Ptr object = ref; Type::Ptr type = object->GetReflectionType(); if (!type) { valid = false; break; } int field = type->GetFieldId(token); if (field == -1) { valid = false; break; } ref = object->GetField(field); } } if (valid) { if (tokens[0] == "vars" || tokens[0] == "action_url" || tokens[0] == "notes_url" || tokens[0] == "notes") *recursive_macro = true; *result = ref; return true; } } return false; } Value MacroProcessor::InternalResolveMacrosShim(const std::vector& args, const ResolverList& resolvers, const CheckResult::Ptr& cr, const MacroProcessor::EscapeCallback& escapeFn, const Dictionary::Ptr& resolvedMacros, bool useResolvedMacros, int recursionLevel) { if (args.size() < 1) BOOST_THROW_EXCEPTION(std::invalid_argument("Too few arguments for function")); String missingMacro; return MacroProcessor::InternalResolveMacros(args[0], resolvers, cr, &missingMacro, escapeFn, resolvedMacros, useResolvedMacros, recursionLevel); } Value MacroProcessor::InternalResolveArgumentsShim(const std::vector& args, const ResolverList& resolvers, const CheckResult::Ptr& cr, const Dictionary::Ptr& resolvedMacros, bool useResolvedMacros, int recursionLevel) { if (args.size() < 2) BOOST_THROW_EXCEPTION(std::invalid_argument("Too few arguments for function")); return MacroProcessor::ResolveArguments(args[0], args[1], resolvers, cr, resolvedMacros, useResolvedMacros, recursionLevel); } Value MacroProcessor::EvaluateFunction(const Function::Ptr& func, const ResolverList& resolvers, const CheckResult::Ptr& cr, const MacroProcessor::EscapeCallback& escapeFn, const Dictionary::Ptr& resolvedMacros, bool useResolvedMacros, int recursionLevel) { Dictionary::Ptr resolvers_this = new Dictionary(); BOOST_FOREACH(const ResolverSpec& resolver, resolvers) { resolvers_this->Set(resolver.first, resolver.second); } resolvers_this->Set("macro", new Function(boost::bind(&MacroProcessor::InternalResolveMacrosShim, _1, boost::cref(resolvers), cr, MacroProcessor::EscapeCallback(), resolvedMacros, useResolvedMacros, recursionLevel + 1))); resolvers_this->Set("resolve_arguments", new Function(boost::bind(&MacroProcessor::InternalResolveArgumentsShim, _1, boost::cref(resolvers), cr, resolvedMacros, useResolvedMacros, recursionLevel + 1))); ScriptFrame frame(resolvers_this); return func->Invoke(); } Value MacroProcessor::InternalResolveMacros(const String& str, const ResolverList& resolvers, const CheckResult::Ptr& cr, String *missingMacro, const MacroProcessor::EscapeCallback& escapeFn, const Dictionary::Ptr& resolvedMacros, bool useResolvedMacros, int recursionLevel) { CONTEXT("Resolving macros for string '" + str + "'"); if (recursionLevel > 15) BOOST_THROW_EXCEPTION(std::runtime_error("Infinite recursion detected while resolving macros")); size_t offset, pos_first, pos_second; offset = 0; Dictionary::Ptr resolvers_this; String result = str; while ((pos_first = result.FindFirstOf("$", offset)) != String::NPos) { pos_second = result.FindFirstOf("$", pos_first + 1); if (pos_second == String::NPos) BOOST_THROW_EXCEPTION(std::runtime_error("Closing $ not found in macro format string.")); String name = result.SubStr(pos_first + 1, pos_second - pos_first - 1); Value resolved_macro; bool recursive_macro; bool found; if (useResolvedMacros) { recursive_macro = false; found = resolvedMacros->Contains(name); if (found) resolved_macro = resolvedMacros->Get(name); } else found = ResolveMacro(name, resolvers, cr, &resolved_macro, &recursive_macro); /* $$ is an escape sequence for $. */ if (name.IsEmpty()) { resolved_macro = "$"; found = true; } if (resolved_macro.IsObjectType()) { resolved_macro = EvaluateFunction(resolved_macro, resolvers, cr, escapeFn, resolvedMacros, useResolvedMacros, recursionLevel + 1); } if (!found) { if (!missingMacro) Log(LogWarning, "MacroProcessor") << "Macro '" << name << "' is not defined."; else *missingMacro = name; } /* recursively resolve macros in the macro if it was a user macro */ if (recursive_macro) { if (resolved_macro.IsObjectType()) { Array::Ptr arr = resolved_macro; Array::Ptr resolved_arr = new Array(); ObjectLock olock(arr); BOOST_FOREACH(const Value& value, arr) { if (value.IsScalar()) { resolved_arr->Add(InternalResolveMacros(value, resolvers, cr, missingMacro, EscapeCallback(), Dictionary::Ptr(), false, recursionLevel + 1)); } else resolved_arr->Add(value); } resolved_macro = resolved_arr; } else if (resolved_macro.IsString()) { resolved_macro = InternalResolveMacros(resolved_macro, resolvers, cr, missingMacro, EscapeCallback(), Dictionary::Ptr(), false, recursionLevel + 1); } } if (!useResolvedMacros && found && resolvedMacros) resolvedMacros->Set(name, resolved_macro); if (escapeFn) resolved_macro = escapeFn(resolved_macro); /* we're done if this is the only macro and there are no other non-macro parts in the string */ if (pos_first == 0 && pos_second == str.GetLength() - 1) return resolved_macro; else if (resolved_macro.IsObjectType()) BOOST_THROW_EXCEPTION(std::invalid_argument("Mixing both strings and non-strings in macros is not allowed.")); if (resolved_macro.IsObjectType()) { /* don't allow mixing strings and arrays in macro strings */ if (pos_first != 0 || pos_second != str.GetLength() - 1) BOOST_THROW_EXCEPTION(std::invalid_argument("Mixing both strings and non-strings in macros is not allowed.")); return resolved_macro; } String resolved_macro_str = resolved_macro; result.Replace(pos_first, pos_second - pos_first + 1, resolved_macro_str); offset = pos_first + resolved_macro_str.GetLength(); } return result; } bool MacroProcessor::ValidateMacroString(const String& macro) { if (macro.IsEmpty()) return true; size_t pos_first, pos_second, offset; offset = 0; while ((pos_first = macro.FindFirstOf("$", offset)) != String::NPos) { pos_second = macro.FindFirstOf("$", pos_first + 1); if (pos_second == String::NPos) return false; offset = pos_second + 1; } return true; } void MacroProcessor::AddArgumentHelper(const Array::Ptr& args, const String& key, const String& value, bool add_key, bool add_value) { if (add_key) args->Add(key); if (add_value) args->Add(value); } Value MacroProcessor::EscapeMacroShellArg(const Value& value) { String result; if (value.IsObjectType()) { Array::Ptr arr = value; ObjectLock olock(arr); BOOST_FOREACH(const Value& arg, arr) { if (result.GetLength() > 0) result += " "; result += Utility::EscapeShellArg(arg); } } else result = Utility::EscapeShellArg(value); return result; } struct CommandArgument { int Order; bool SkipKey; bool RepeatKey; bool SkipValue; String Key; Value AValue; CommandArgument(void) : Order(0), SkipKey(false), RepeatKey(true), SkipValue(false) { } bool operator<(const CommandArgument& rhs) const { return Order < rhs.Order; } }; Value MacroProcessor::ResolveArguments(const Value& command, const Dictionary::Ptr& arguments, const MacroProcessor::ResolverList& resolvers, const CheckResult::Ptr& cr, const Dictionary::Ptr& resolvedMacros, bool useResolvedMacros, int recursionLevel) { Value resolvedCommand; if (!arguments || command.IsObjectType() || command.IsObjectType()) resolvedCommand = MacroProcessor::ResolveMacros(command, resolvers, cr, NULL, EscapeMacroShellArg, resolvedMacros, useResolvedMacros, recursionLevel + 1); else { Array::Ptr arr = new Array(); arr->Add(command); resolvedCommand = arr; } if (arguments) { std::vector args; ObjectLock olock(arguments); BOOST_FOREACH(const Dictionary::Pair& kv, arguments) { const Value& arginfo = kv.second; CommandArgument arg; arg.Key = kv.first; bool required = false; Value argval; if (arginfo.IsObjectType()) { Dictionary::Ptr argdict = arginfo; if (argdict->Contains("key")) arg.Key = argdict->Get("key"); argval = argdict->Get("value"); if (argdict->Contains("required")) required = argdict->Get("required"); arg.SkipKey = argdict->Get("skip_key"); if (argdict->Contains("repeat_key")) arg.RepeatKey = argdict->Get("repeat_key"); arg.Order = argdict->Get("order"); Value set_if = argdict->Get("set_if"); if (!set_if.IsEmpty()) { String missingMacro; Value set_if_resolved = MacroProcessor::ResolveMacros(set_if, resolvers, cr, &missingMacro, MacroProcessor::EscapeCallback(), resolvedMacros, useResolvedMacros, recursionLevel + 1); if (!missingMacro.IsEmpty()) continue; int value; if (set_if_resolved == "true") value = 1; else if (set_if_resolved == "false") value = 0; else { try { value = Convert::ToLong(set_if_resolved); } catch (const std::exception& ex) { /* tried to convert a string */ Log(LogWarning, "PluginUtility") << "Error evaluating set_if value '" << set_if_resolved << "': " << ex.what(); continue; } } if (!value) continue; } } else argval = arginfo; if (argval.IsEmpty()) arg.SkipValue = true; String missingMacro; arg.AValue = MacroProcessor::ResolveMacros(argval, resolvers, cr, &missingMacro, MacroProcessor::EscapeCallback(), resolvedMacros, useResolvedMacros, recursionLevel + 1); if (!missingMacro.IsEmpty()) { if (required) { BOOST_THROW_EXCEPTION(ScriptError("Non-optional macro '" + missingMacro + "' used in argument '" + arg.Key + "' is missing.")); } continue; } args.push_back(arg); } std::sort(args.begin(), args.end()); Array::Ptr command_arr = resolvedCommand; BOOST_FOREACH(const CommandArgument& arg, args) { if (arg.AValue.IsObjectType()) { Log(LogWarning, "PluginUtility", "Tried to use dictionary in argument"); continue; } else if (arg.AValue.IsObjectType()) { bool first = true; Array::Ptr arr = static_cast(arg.AValue); ObjectLock olock(arr); BOOST_FOREACH(const Value& value, arr) { bool add_key; if (first) { first = false; add_key = !arg.SkipKey; } else add_key = !arg.SkipKey && arg.RepeatKey; AddArgumentHelper(command_arr, arg.Key, value, add_key, !arg.SkipValue); } } else AddArgumentHelper(command_arr, arg.Key, arg.AValue, !arg.SkipKey, !arg.SkipValue); } } return resolvedCommand; }