/* +------------------------------------+ * | Inspire Internet Relay Chat Daemon | * +------------------------------------+ * * InspIRCd: (C) 2002-2009 InspIRCd Development Team * See: http://wiki.inspircd.org/Credits * * This program is free but copyrighted software; see * the file COPYING for details. * * --------------------------------------------------- */ #ifndef INSPIRCD_SQLAPI_2 #define INSPIRCD_SQLAPI_2 #include #include #include #include "modules.h" /** Identifiers used to identify Request types */ #define SQLREQID "SQLv2 Request" #define SQLRESID "SQLv2 Result" #define SQLSUCCESS "You shouldn't be reading this (success)" /** Defines the error types which SQLerror may be set to */ enum SQLerrorNum { SQL_NO_ERROR, SQL_BAD_DBID, SQL_BAD_CONN, SQL_QSEND_FAIL, SQL_QREPLY_FAIL }; /** A list of format parameters for an SQLquery object. */ typedef std::deque ParamL; /** The base class of SQL exceptions */ class SQLexception : public ModuleException { public: SQLexception(const std::string &reason) : ModuleException(reason) { } SQLexception() : ModuleException("SQLv2: Undefined exception") { } }; /** An exception thrown when a bad column or row name or id is requested */ class SQLbadColName : public SQLexception { public: SQLbadColName() : SQLexception("SQLv2: Bad column name") { } }; /** SQLerror holds the error state of any SQLrequest or SQLresult. * The error string varies from database software to database software * and should be used to display informational error messages to users. */ class SQLerror { /** The error id */ SQLerrorNum id; /** The error string */ std::string str; public: /** Initialize an SQLerror * @param i The error ID to set * @param s The (optional) error string to set */ SQLerror(SQLerrorNum i = SQL_NO_ERROR, const std::string &s = "") : id(i), str(s) { } /** Return the ID of the error */ SQLerrorNum Id() { return id; } /** Set the ID of an error * @param i The new error ID to set * @return the ID which was set */ SQLerrorNum Id(SQLerrorNum i) { id = i; return id; } /** Set the error string for an error * @param s The new error string to set */ void Str(const std::string &s) { str = s; } /** Return the error string for an error */ const char* Str() { if(str.length()) return str.c_str(); switch(id) { case SQL_NO_ERROR: return "No error"; case SQL_BAD_DBID: return "Invalid database ID"; case SQL_BAD_CONN: return "Invalid connection"; case SQL_QSEND_FAIL: return "Sending query failed"; case SQL_QREPLY_FAIL: return "Getting query result failed"; default: return "Unknown error"; } } }; /** SQLquery provides a way to represent a query string, and its parameters in a type-safe way. * C++ has no native type-safe way of having a variable number of arguments to a function, * the workaround for this isn't easy to describe simply, but in a nutshell what's really * happening when - from the above example - you do this: * * SQLrequest foo = SQLrequest(this, target, "databaseid", SQLquery("SELECT (foo, bar) FROM rawr WHERE foo = '?' AND bar = ?", "Hello", "42")); * * what's actually happening is functionally this: * * SQLrequest foo = SQLrequest(this, target, "databaseid", query("SELECT (foo, bar) FROM rawr WHERE foo = '?' AND bar = ?").addparam("Hello").addparam("42")); * * with 'query()' returning a reference to an object with a 'addparam()' member function which * in turn returns a reference to that object. There are actually four ways you can create a * SQLrequest..all have their disadvantages and advantages. In the real implementations the * 'query()' function is replaced by the constructor of another class 'SQLquery' which holds * the query string and a ParamL (std::deque) of query parameters. * This is essentially the same as the above example except 'addparam()' is replaced by operator,(). The full syntax for this method is: * * SQLrequest foo = SQLrequest(this, target, "databaseid", (SQLquery("SELECT.. ?"), parameter, parameter)); */ class SQLquery { public: /** The query 'format string' */ std::string q; /** The query parameter list * There should be one parameter for every ? character * within the format string shown above. */ ParamL p; /** Initialize an SQLquery with a given format string only */ SQLquery(const std::string &query) : q(query) { } /** Initialize an SQLquery with a format string and parameters. * If you provide parameters, you must initialize the list yourself * if you choose to do it via this method, using std::deque::push_back(). */ SQLquery(const std::string &query, const ParamL ¶ms) : q(query), p(params) { } /** An overloaded operator for pushing parameters onto the parameter list */ template SQLquery& operator,(const T &foo) { p.push_back(ConvToStr(foo)); return *this; } /** An overloaded operator for pushing parameters onto the parameter list. * This has higher precedence than 'operator,' and can save on parenthesis. */ template SQLquery& operator%(const T &foo) { p.push_back(ConvToStr(foo)); return *this; } }; /** SQLrequest is sent to the SQL API to command it to run a query and return the result. * You must instantiate this object with a valid SQLquery object and its parameters, then * send it using its Send() method to the module providing the 'SQL' feature. To find this * module, use Server::FindFeature(). */ class SQLrequest : public Request { public: /** The fully parsed and expanded query string * This is initialized from the SQLquery parameter given in the constructor. */ SQLquery query; /** The database ID to apply the request to */ std::string dbid; /** True if this is a priority query. * Priority queries may 'queue jump' in the request queue. */ bool pri; /** True if this query has been cancelled; send no response */ bool cancel; /** The query ID, assigned by the SQL api. * After your request is processed, this will * be initialized for you by the API to a valid request ID, * except in the case of an error. */ unsigned long id; /** If an error occured, error.id will be any other value than SQL_NO_ERROR. */ SQLerror error; /** Initialize an SQLrequest. * For example: * * SQLrequest req = SQLrequest(MyMod, SQLModule, dbid, SQLquery("INSERT INTO ircd_log_actors VALUES('','?')" % nick)); * * @param s A pointer to the sending module, where the result should be routed * @param d A pointer to the receiving module, identified as implementing the 'SQL' feature * @param databaseid The database ID to perform the query on. This must match a valid * database ID from the configuration of the SQL module. * @param q A properly initialized SQLquery object. */ SQLrequest(Module* s, Module* d, const std::string &databaseid, const SQLquery &q) : Request(s, d, SQLREQID), query(q), dbid(databaseid), pri(false), id(0) { } // Copy constructor - XXX probably shouldn't be needed SQLrequest(const SQLrequest& o) : Request(o.source, o.dest, SQLREQID), query(o.query), dbid(o.dbid), pri(o.pri), cancel(o.cancel), id(o.id), error(o.error) {} /** Set the priority of a request. */ void Priority(bool p = true) { pri = p; } }; /** * This class contains a field's data plus a way to determine if the field * is NULL or not without having to mess around with NULL pointers. */ class SQLfield { public: /** * The data itself */ std::string d; /** * If the field was null */ bool null; /** Initialize an SQLfield */ SQLfield(const std::string &data = "", bool n = false) : d(data), null(n) { } }; /** A list of items which make up a row of a result or table (tuple) * This does not include field names. */ typedef std::vector SQLfieldList; /** A list of items which make up a row of a result or table (tuple) * This also includes the field names. */ typedef std::map SQLfieldMap; /** SQLresult is a reply to a previous query. * If you send a query to the SQL api, the response will arrive at your * OnRequest method of your module at some later time, depending on the * congestion of the SQL server and complexity of the query. The ID of * this result will match the ID assigned to your original request. * SQLresult contains its own internal cursor (row counter) which is * incremented with each method call which retrieves a single row. */ class SQLresult : public Request { public: /** The original query string passed initially to the SQL API */ std::string query; /** The database ID the query was executed on */ std::string dbid; /** * The error (if any) which occured. * If an error occured the value of error.id will be any * other value than SQL_NO_ERROR. */ SQLerror error; /** * This will match query ID you were given when sending * the request at an earlier time. */ unsigned long id; /** Used by the SQL API to instantiate an SQLrequest */ SQLresult(Module* s, Module* d, unsigned long i) : Request(s, d, SQLRESID), id(i) { } /** * Return the number of rows in the result * Note that if you have perfomed an INSERT * or UPDATE query or other query which will * not return rows, this will return the * number of affected rows, and SQLresult::Cols() * will contain 0. In this case you SHOULD NEVER * access any of the result set rows, as there arent any! * @returns Number of rows in the result set. */ virtual int Rows() = 0; /** * Return the number of columns in the result. * If you performed an UPDATE or INSERT which * does not return a dataset, this value will * be 0. * @returns Number of columns in the result set. */ virtual int Cols() = 0; /** * Get a string name of the column by an index number * @param column The id number of a column * @returns The column name associated with the given ID */ virtual std::string ColName(int column) = 0; /** * Get an index number for a column from a string name. * An exception of type SQLbadColName will be thrown if * the name given is invalid. * @param column The column name to get the ID of * @returns The ID number of the column provided */ virtual int ColNum(const std::string &column) = 0; /** * Get a string value in a given row and column * This does not effect the internal cursor. * @returns The value stored at [row,column] in the table */ virtual SQLfield GetValue(int row, int column) = 0; /** * Return a list of values in a row, this should * increment an internal counter so you can repeatedly * call it until it returns an empty vector. * This returns a reference to an internal object, * the same object is used for all calls to this function * and therefore the return value is only valid until * you call this function again. It is also invalid if * the SQLresult object is destroyed. * The internal cursor (row counter) is incremented by one. * @returns A reference to the current row's SQLfieldList */ virtual SQLfieldList& GetRow() = 0; /** * As above, but return a map indexed by key name. * The internal cursor (row counter) is incremented by one. * @returns A reference to the current row's SQLfieldMap */ virtual SQLfieldMap& GetRowMap() = 0; /** * Like GetRow(), but returns a pointer to a dynamically * allocated object which must be explicitly freed. For * portability reasons this must be freed with SQLresult::Free() * The internal cursor (row counter) is incremented by one. * @returns A newly-allocated SQLfieldList */ virtual SQLfieldList* GetRowPtr() = 0; /** * As above, but return a map indexed by key name * The internal cursor (row counter) is incremented by one. * @returns A newly-allocated SQLfieldMap */ virtual SQLfieldMap* GetRowMapPtr() = 0; /** * Overloaded function for freeing the lists and maps * returned by GetRowPtr or GetRowMapPtr. * @param fm The SQLfieldMap to free */ virtual void Free(SQLfieldMap* fm) = 0; /** * Overloaded function for freeing the lists and maps * returned by GetRowPtr or GetRowMapPtr. * @param fl The SQLfieldList to free */ virtual void Free(SQLfieldList* fl) = 0; }; /** SQLHost represents a config line and is useful * for storing in a map and iterating on rehash to see which * tags was added/removed/unchanged. */ class SQLhost { public: std::string id; /* Database handle id */ std::string host; /* Database server hostname */ std::string ip; /* resolved IP, needed for at least pgsql.so */ unsigned int port; /* Database server port */ std::string name; /* Database name */ std::string user; /* Database username */ std::string pass; /* Database password */ bool ssl; /* If we should require SSL */ SQLhost() : id(""), host(""), ip(""), port(0), name(""), user(""), pass(""), ssl(0) { } SQLhost(const std::string& i, const std::string& h, unsigned int p, const std::string& n, const std::string& u, const std::string& pa, bool s) : id(i), host(h), ip(""), port(p), name(n), user(u), pass(pa), ssl(s) { } /** Overload this to return a correct Data source Name (DSN) for * the current SQL module. */ std::string GetDSN(); }; /** Overload operator== for two SQLhost objects for easy comparison. */ inline bool operator== (const SQLhost& l, const SQLhost& r) { return (l.id == r.id && l.host == r.host && l.port == r.port && l.name == r.name && l.user == r.user && l.pass == r.pass && l.ssl == r.ssl); } /** Overload operator!= for two SQLhost objects for easy comparison. */ inline bool operator!= (const SQLhost& l, const SQLhost& r) { return (l.id != r.id || l.host != r.host || l.port != r.port || l.name != r.name || l.user != r.user || l.pass != r.pass || l.ssl != r.ssl); } /** QueryQueue, a queue of queries waiting to be executed. * This maintains two queues internally, one for 'priority' * queries and one for less important ones. Each queue has * new queries appended to it and ones to execute are popped * off the front. This keeps them flowing round nicely and no * query should ever get 'stuck' for too long. If there are * queries in the priority queue they will be executed first, * 'unimportant' queries will only be executed when the * priority queue is empty. * * We store lists of SQLrequest's here, by value as we want to avoid storing * any data allocated inside the client module (in case that module is unloaded * while the query is in progress). * * Because we want to work on the current SQLrequest in-situ, we need a way * of accessing the request we are currently processing, QueryQueue::front(), * but that call needs to always return the same request until that request * is removed from the queue, this is what the 'which' variable is. New queries are * always added to the back of one of the two queues, but if when front() * is first called then the priority queue is empty then front() will return * a query from the normal queue, but if a query is then added to the priority * queue then front() must continue to return the front of the *normal* queue * until pop() is called. */ class QueryQueue { private: typedef std::deque ReqDeque; ReqDeque priority; /* The priority queue */ ReqDeque normal; /* The 'normal' queue */ enum { PRI, NOR, NON } which; /* Which queue the currently active element is at the front of */ public: QueryQueue() : which(NON) { } void push(SQLrequest *q) { if(q->pri) priority.push_back(q); else normal.push_back(q); } void pop() { if((which == PRI) && priority.size()) { priority.pop_front(); } else if((which == NOR) && normal.size()) { normal.pop_front(); } /* Reset this */ which = NON; /* Silently do nothing if there was no element to pop() */ } SQLrequest* front() { switch(which) { case PRI: return priority.front(); case NOR: return normal.front(); default: if(priority.size()) { which = PRI; return priority.front(); } if(normal.size()) { which = NOR; return normal.front(); } } return NULL; } std::pair size() { return std::make_pair(priority.size(), normal.size()); } int totalsize() { return priority.size() + normal.size(); } void PurgeModule(Module* mod) { DoPurgeModule(mod, priority); DoPurgeModule(mod, normal); } private: void DoPurgeModule(Module* mod, ReqDeque& q) { ReqDeque::iterator iter = q.begin(); while (iter != q.end()) { if((**iter).source == mod) { if (*iter == front()) { /* It's the currently active query.. :x */ (**iter).cancel = true; iter++; } else { /* It hasn't been executed yet..just remove it */ iter = q.erase(iter); } } else iter++; } } }; #endif