2007-01-25 07:40:21 +01:00
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/*
|
MAPI IV. This iteration leverages the C++11 standardized RTTI.
* Simplifies the export declarations for module developers. While
MAPI III utilized a flexible key-value vector to eliminate positional
arguments in a header initializer, now the developer simply makes
a list of pointers to what they want to export for injection into
IRCd. Example:
mapi::header IRCD_MODULE
{
"mymod",
"My module adds a command, a hook, and a CLICAP",
&my_cmdtab,
&some_hook,
&clicaptab
};
* Distributes the handlers for items passed to the above vector.
Anyone can add a type-handler to the module system from anywhere in IRCd
(and other modules?) When your type is encountered a handler is called
providing the symbol name to read out of the module. Example in parser.cc:
mods::add_loader<Message>([]
(mod &loading, const std::string &symbol)
{
auto &msg(get<Message>(loading, symbol));
add_command(msg.name, msg);
});
2016-08-29 21:09:59 +02:00
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* IRCd (Charybdis): Pushing the envelope since '88
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2007-01-25 07:40:21 +01:00
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* modules.h: A header for the modules functions.
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*
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* Copyright (C) 1990 Jarkko Oikarinen and University of Oulu, Co Center
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* Copyright (C) 1996-2002 Hybrid Development Team
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* Copyright (C) 2002-2004 ircd-ratbox development team
|
MAPI IV. This iteration leverages the C++11 standardized RTTI.
* Simplifies the export declarations for module developers. While
MAPI III utilized a flexible key-value vector to eliminate positional
arguments in a header initializer, now the developer simply makes
a list of pointers to what they want to export for injection into
IRCd. Example:
mapi::header IRCD_MODULE
{
"mymod",
"My module adds a command, a hook, and a CLICAP",
&my_cmdtab,
&some_hook,
&clicaptab
};
* Distributes the handlers for items passed to the above vector.
Anyone can add a type-handler to the module system from anywhere in IRCd
(and other modules?) When your type is encountered a handler is called
providing the symbol name to read out of the module. Example in parser.cc:
mods::add_loader<Message>([]
(mod &loading, const std::string &symbol)
{
auto &msg(get<Message>(loading, symbol));
add_command(msg.name, msg);
});
2016-08-29 21:09:59 +02:00
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* Copyright (C) 2016 Charybdis Development Team
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* Copyright (C) 2016 Jason Volk <jason@zemos.net>
|
2007-01-25 07:40:21 +01:00
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*
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* This program is free software; you can redistribute it and/or modify
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* it under the terms of the GNU General Public License as published by
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* the Free Software Foundation; either version 2 of the License, or
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* (at your option) any later version.
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*
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* This program is distributed in the hope that it will be useful,
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* but WITHOUT ANY WARRANTY; without even the implied warranty of
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* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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* GNU General Public License for more details.
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*
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|
* You should have received a copy of the GNU General Public License
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* along with this program; if not, write to the Free Software
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* Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307
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* USA
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*/
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2016-08-13 05:05:54 +02:00
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|
#pragma once
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#define HAVE_IRCD_MODULES_H
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#ifdef __cplusplus
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|
namespace ircd {
|
MAPI IV. This iteration leverages the C++11 standardized RTTI.
* Simplifies the export declarations for module developers. While
MAPI III utilized a flexible key-value vector to eliminate positional
arguments in a header initializer, now the developer simply makes
a list of pointers to what they want to export for injection into
IRCd. Example:
mapi::header IRCD_MODULE
{
"mymod",
"My module adds a command, a hook, and a CLICAP",
&my_cmdtab,
&some_hook,
&clicaptab
};
* Distributes the handlers for items passed to the above vector.
Anyone can add a type-handler to the module system from anywhere in IRCd
(and other modules?) When your type is encountered a handler is called
providing the symbol name to read out of the module. Example in parser.cc:
mods::add_loader<Message>([]
(mod &loading, const std::string &symbol)
{
auto &msg(get<Message>(loading, symbol));
add_command(msg.name, msg);
});
2016-08-29 21:09:59 +02:00
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|
namespace mapi {
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using magic_t = uint16_t;
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using version_t = uint16_t;
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struct header;
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} // namespace mapi
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namespace mods {
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using mapi::magic_t;
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using mapi::version_t;
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|
IRCD_EXCEPTION(ircd::error, error)
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IRCD_EXCEPTION(error, filesystem_error)
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IRCD_EXCEPTION(error, invalid_export)
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struct mod;
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bool has(const mod &mod, const std::string &symbol);
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const uint8_t *ptr(const mod &mod, const std::string &symbol);
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uint8_t *ptr(mod &mod, const std::string &symbol);
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template<class T> const T *ptr(const mod &mod, const std::string &symbol);
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template<class T> const T &get(const mod &mod, const std::string &symbol);
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template<class T> T *ptr(mod &mod, const std::string &symbol);
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template<class T> T &get(mod &mod, const std::string &symbol);
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const mapi::header &header(const mod &);
|
2016-09-13 10:29:50 +02:00
|
|
|
const std::string &meta(const mod &, const std::string &key);
|
MAPI IV. This iteration leverages the C++11 standardized RTTI.
* Simplifies the export declarations for module developers. While
MAPI III utilized a flexible key-value vector to eliminate positional
arguments in a header initializer, now the developer simply makes
a list of pointers to what they want to export for injection into
IRCd. Example:
mapi::header IRCD_MODULE
{
"mymod",
"My module adds a command, a hook, and a CLICAP",
&my_cmdtab,
&some_hook,
&clicaptab
};
* Distributes the handlers for items passed to the above vector.
Anyone can add a type-handler to the module system from anywhere in IRCd
(and other modules?) When your type is encountered a handler is called
providing the symbol name to read out of the module. Example in parser.cc:
mods::add_loader<Message>([]
(mod &loading, const std::string &symbol)
{
auto &msg(get<Message>(loading, symbol));
add_command(msg.name, msg);
});
2016-08-29 21:09:59 +02:00
|
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|
const version_t &version(const mod &);
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|
const int64_t ×tamp(const mod &);
|
2016-09-13 10:29:50 +02:00
|
|
|
const std::string &desc(const mod &);
|
MAPI IV. This iteration leverages the C++11 standardized RTTI.
* Simplifies the export declarations for module developers. While
MAPI III utilized a flexible key-value vector to eliminate positional
arguments in a header initializer, now the developer simply makes
a list of pointers to what they want to export for injection into
IRCd. Example:
mapi::header IRCD_MODULE
{
"mymod",
"My module adds a command, a hook, and a CLICAP",
&my_cmdtab,
&some_hook,
&clicaptab
};
* Distributes the handlers for items passed to the above vector.
Anyone can add a type-handler to the module system from anywhere in IRCd
(and other modules?) When your type is encountered a handler is called
providing the symbol name to read out of the module. Example in parser.cc:
mods::add_loader<Message>([]
(mod &loading, const std::string &symbol)
{
auto &msg(get<Message>(loading, symbol));
add_command(msg.name, msg);
});
2016-08-29 21:09:59 +02:00
|
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|
std::string location(const mod &);
|
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std::string name(const mod &);
|
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|
|
// Symbol handlers
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|
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|
|
struct type_handlers
|
2007-01-25 07:40:21 +01:00
|
|
|
{
|
MAPI IV. This iteration leverages the C++11 standardized RTTI.
* Simplifies the export declarations for module developers. While
MAPI III utilized a flexible key-value vector to eliminate positional
arguments in a header initializer, now the developer simply makes
a list of pointers to what they want to export for injection into
IRCd. Example:
mapi::header IRCD_MODULE
{
"mymod",
"My module adds a command, a hook, and a CLICAP",
&my_cmdtab,
&some_hook,
&clicaptab
};
* Distributes the handlers for items passed to the above vector.
Anyone can add a type-handler to the module system from anywhere in IRCd
(and other modules?) When your type is encountered a handler is called
providing the symbol name to read out of the module. Example in parser.cc:
mods::add_loader<Message>([]
(mod &loading, const std::string &symbol)
{
auto &msg(get<Message>(loading, symbol));
add_command(msg.name, msg);
});
2016-08-29 21:09:59 +02:00
|
|
|
std::function<void (mod &, const std::string &sym)> loader;
|
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|
std::function<void (mod &, const std::string &sym)> unloader;
|
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|
|
|
std::function<void (mod &, const std::string &sym)> reloader;
|
2007-01-25 07:40:21 +01:00
|
|
|
};
|
MAPI IV. This iteration leverages the C++11 standardized RTTI.
* Simplifies the export declarations for module developers. While
MAPI III utilized a flexible key-value vector to eliminate positional
arguments in a header initializer, now the developer simply makes
a list of pointers to what they want to export for injection into
IRCd. Example:
mapi::header IRCD_MODULE
{
"mymod",
"My module adds a command, a hook, and a CLICAP",
&my_cmdtab,
&some_hook,
&clicaptab
};
* Distributes the handlers for items passed to the above vector.
Anyone can add a type-handler to the module system from anywhere in IRCd
(and other modules?) When your type is encountered a handler is called
providing the symbol name to read out of the module. Example in parser.cc:
mods::add_loader<Message>([]
(mod &loading, const std::string &symbol)
{
auto &msg(get<Message>(loading, symbol));
add_command(msg.name, msg);
});
2016-08-29 21:09:59 +02:00
|
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|
template<class T> std::type_index make_index();
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bool add(const std::type_index &, const type_handlers &handlers);
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bool del(const std::type_index &);
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bool has(const std::type_index &);
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template<class T, class... type_handlers> bool add(type_handlers&&... handlers);
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template<class T> bool del();
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template<class T> bool has();
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// The search path vector
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std::vector<std::string> paths();
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bool path_added(const std::string &dir);
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void path_del(const std::string &dir);
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bool path_add(const std::string &dir, std::nothrow_t); // logs errors and returns false
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bool path_add(const std::string &dir); // false if exists, throws other errors
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void path_clear();
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// Dump object data
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std::vector<std::string> symbols(const std::string &fullpath, const std::string §ion);
|
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std::vector<std::string> symbols(const std::string &fullpath);
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std::vector<std::string> sections(const std::string &fullpath);
|
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// Checks if loadable module containing a mapi header (does not verify the magic)
|
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bool is_module(const std::string &fullpath, std::string &why);
|
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bool is_module(const std::string &fullpath, std::nothrow_t);
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bool is_module(const std::string &fullpath);
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// returns dir/name of first dir containing 'name' (and this will be a loadable module)
|
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|
// Unlike libltdl, the reason each individual candidate failed is presented in a vector.
|
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|
std::string search(const std::string &name, std::vector<std::string> &why);
|
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std::string search(const std::string &name);
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|
// Potential modules available to load
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|
std::forward_list<std::string> available();
|
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bool available(const std::string &name);
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|
// Find module names where symbol resides
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|
bool has_symbol(const std::string &name, const std::string &symbol);
|
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std::vector<std::string> find_symbol(const std::string &symbol);
|
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|
// Modules currently loaded
|
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|
const std::map<std::string, std::unique_ptr<mod>> &loaded();
|
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|
bool loaded(const std::string &name);
|
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|
mod &get(const std::string &name);
|
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bool reload(const std::string name);
|
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|
bool unload(const std::string name);
|
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|
bool load(const std::string &name);
|
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|
|
void autoload();
|
2016-09-10 01:14:29 +02:00
|
|
|
void unload();
|
MAPI IV. This iteration leverages the C++11 standardized RTTI.
* Simplifies the export declarations for module developers. While
MAPI III utilized a flexible key-value vector to eliminate positional
arguments in a header initializer, now the developer simply makes
a list of pointers to what they want to export for injection into
IRCd. Example:
mapi::header IRCD_MODULE
{
"mymod",
"My module adds a command, a hook, and a CLICAP",
&my_cmdtab,
&some_hook,
&clicaptab
};
* Distributes the handlers for items passed to the above vector.
Anyone can add a type-handler to the module system from anywhere in IRCd
(and other modules?) When your type is encountered a handler is called
providing the symbol name to read out of the module. Example in parser.cc:
mods::add_loader<Message>([]
(mod &loading, const std::string &symbol)
{
auto &msg(get<Message>(loading, symbol));
add_command(msg.name, msg);
});
2016-08-29 21:09:59 +02:00
|
|
|
|
2016-09-25 04:45:37 +02:00
|
|
|
extern struct log::log log;
|
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|
|
|
extern bool static_destruction;
|
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|
|
|
2016-09-23 08:53:31 +02:00
|
|
|
// Initialization and destruction singleton held by ircd::main()
|
|
|
|
|
struct init
|
|
|
|
|
{
|
|
|
|
|
init();
|
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|
|
|
~init() noexcept;
|
|
|
|
|
};
|
|
|
|
|
|
MAPI IV. This iteration leverages the C++11 standardized RTTI.
* Simplifies the export declarations for module developers. While
MAPI III utilized a flexible key-value vector to eliminate positional
arguments in a header initializer, now the developer simply makes
a list of pointers to what they want to export for injection into
IRCd. Example:
mapi::header IRCD_MODULE
{
"mymod",
"My module adds a command, a hook, and a CLICAP",
&my_cmdtab,
&some_hook,
&clicaptab
};
* Distributes the handlers for items passed to the above vector.
Anyone can add a type-handler to the module system from anywhere in IRCd
(and other modules?) When your type is encountered a handler is called
providing the symbol name to read out of the module. Example in parser.cc:
mods::add_loader<Message>([]
(mod &loading, const std::string &symbol)
{
auto &msg(get<Message>(loading, symbol));
add_command(msg.name, msg);
});
2016-08-29 21:09:59 +02:00
|
|
|
|
|
|
|
|
template<class T>
|
|
|
|
|
bool
|
|
|
|
|
has()
|
2007-01-25 07:40:21 +01:00
|
|
|
{
|
MAPI IV. This iteration leverages the C++11 standardized RTTI.
* Simplifies the export declarations for module developers. While
MAPI III utilized a flexible key-value vector to eliminate positional
arguments in a header initializer, now the developer simply makes
a list of pointers to what they want to export for injection into
IRCd. Example:
mapi::header IRCD_MODULE
{
"mymod",
"My module adds a command, a hook, and a CLICAP",
&my_cmdtab,
&some_hook,
&clicaptab
};
* Distributes the handlers for items passed to the above vector.
Anyone can add a type-handler to the module system from anywhere in IRCd
(and other modules?) When your type is encountered a handler is called
providing the symbol name to read out of the module. Example in parser.cc:
mods::add_loader<Message>([]
(mod &loading, const std::string &symbol)
{
auto &msg(get<Message>(loading, symbol));
add_command(msg.name, msg);
});
2016-08-29 21:09:59 +02:00
|
|
|
return has(make_index<T>());
|
|
|
|
|
}
|
2007-01-25 07:40:21 +01:00
|
|
|
|
MAPI IV. This iteration leverages the C++11 standardized RTTI.
* Simplifies the export declarations for module developers. While
MAPI III utilized a flexible key-value vector to eliminate positional
arguments in a header initializer, now the developer simply makes
a list of pointers to what they want to export for injection into
IRCd. Example:
mapi::header IRCD_MODULE
{
"mymod",
"My module adds a command, a hook, and a CLICAP",
&my_cmdtab,
&some_hook,
&clicaptab
};
* Distributes the handlers for items passed to the above vector.
Anyone can add a type-handler to the module system from anywhere in IRCd
(and other modules?) When your type is encountered a handler is called
providing the symbol name to read out of the module. Example in parser.cc:
mods::add_loader<Message>([]
(mod &loading, const std::string &symbol)
{
auto &msg(get<Message>(loading, symbol));
add_command(msg.name, msg);
});
2016-08-29 21:09:59 +02:00
|
|
|
template<class T>
|
|
|
|
|
bool
|
|
|
|
|
del()
|
2007-01-25 07:40:21 +01:00
|
|
|
{
|
MAPI IV. This iteration leverages the C++11 standardized RTTI.
* Simplifies the export declarations for module developers. While
MAPI III utilized a flexible key-value vector to eliminate positional
arguments in a header initializer, now the developer simply makes
a list of pointers to what they want to export for injection into
IRCd. Example:
mapi::header IRCD_MODULE
{
"mymod",
"My module adds a command, a hook, and a CLICAP",
&my_cmdtab,
&some_hook,
&clicaptab
};
* Distributes the handlers for items passed to the above vector.
Anyone can add a type-handler to the module system from anywhere in IRCd
(and other modules?) When your type is encountered a handler is called
providing the symbol name to read out of the module. Example in parser.cc:
mods::add_loader<Message>([]
(mod &loading, const std::string &symbol)
{
auto &msg(get<Message>(loading, symbol));
add_command(msg.name, msg);
});
2016-08-29 21:09:59 +02:00
|
|
|
return del(make_index<T>());
|
|
|
|
|
}
|
2016-03-06 23:53:03 +01:00
|
|
|
|
MAPI IV. This iteration leverages the C++11 standardized RTTI.
* Simplifies the export declarations for module developers. While
MAPI III utilized a flexible key-value vector to eliminate positional
arguments in a header initializer, now the developer simply makes
a list of pointers to what they want to export for injection into
IRCd. Example:
mapi::header IRCD_MODULE
{
"mymod",
"My module adds a command, a hook, and a CLICAP",
&my_cmdtab,
&some_hook,
&clicaptab
};
* Distributes the handlers for items passed to the above vector.
Anyone can add a type-handler to the module system from anywhere in IRCd
(and other modules?) When your type is encountered a handler is called
providing the symbol name to read out of the module. Example in parser.cc:
mods::add_loader<Message>([]
(mod &loading, const std::string &symbol)
{
auto &msg(get<Message>(loading, symbol));
add_command(msg.name, msg);
});
2016-08-29 21:09:59 +02:00
|
|
|
template<class T,
|
|
|
|
|
class... type_handlers>
|
|
|
|
|
bool
|
|
|
|
|
add(type_handlers&&... handlers)
|
2016-03-06 23:53:03 +01:00
|
|
|
{
|
MAPI IV. This iteration leverages the C++11 standardized RTTI.
* Simplifies the export declarations for module developers. While
MAPI III utilized a flexible key-value vector to eliminate positional
arguments in a header initializer, now the developer simply makes
a list of pointers to what they want to export for injection into
IRCd. Example:
mapi::header IRCD_MODULE
{
"mymod",
"My module adds a command, a hook, and a CLICAP",
&my_cmdtab,
&some_hook,
&clicaptab
};
* Distributes the handlers for items passed to the above vector.
Anyone can add a type-handler to the module system from anywhere in IRCd
(and other modules?) When your type is encountered a handler is called
providing the symbol name to read out of the module. Example in parser.cc:
mods::add_loader<Message>([]
(mod &loading, const std::string &symbol)
{
auto &msg(get<Message>(loading, symbol));
add_command(msg.name, msg);
});
2016-08-29 21:09:59 +02:00
|
|
|
return add(make_index<T>(), {std::forward<type_handlers>(handlers)...});
|
|
|
|
|
}
|
2016-03-06 23:53:03 +01:00
|
|
|
|
MAPI IV. This iteration leverages the C++11 standardized RTTI.
* Simplifies the export declarations for module developers. While
MAPI III utilized a flexible key-value vector to eliminate positional
arguments in a header initializer, now the developer simply makes
a list of pointers to what they want to export for injection into
IRCd. Example:
mapi::header IRCD_MODULE
{
"mymod",
"My module adds a command, a hook, and a CLICAP",
&my_cmdtab,
&some_hook,
&clicaptab
};
* Distributes the handlers for items passed to the above vector.
Anyone can add a type-handler to the module system from anywhere in IRCd
(and other modules?) When your type is encountered a handler is called
providing the symbol name to read out of the module. Example in parser.cc:
mods::add_loader<Message>([]
(mod &loading, const std::string &symbol)
{
auto &msg(get<Message>(loading, symbol));
add_command(msg.name, msg);
});
2016-08-29 21:09:59 +02:00
|
|
|
template<class T>
|
|
|
|
|
std::type_index
|
|
|
|
|
make_index()
|
2007-01-25 07:40:21 +01:00
|
|
|
{
|
MAPI IV. This iteration leverages the C++11 standardized RTTI.
* Simplifies the export declarations for module developers. While
MAPI III utilized a flexible key-value vector to eliminate positional
arguments in a header initializer, now the developer simply makes
a list of pointers to what they want to export for injection into
IRCd. Example:
mapi::header IRCD_MODULE
{
"mymod",
"My module adds a command, a hook, and a CLICAP",
&my_cmdtab,
&some_hook,
&clicaptab
};
* Distributes the handlers for items passed to the above vector.
Anyone can add a type-handler to the module system from anywhere in IRCd
(and other modules?) When your type is encountered a handler is called
providing the symbol name to read out of the module. Example in parser.cc:
mods::add_loader<Message>([]
(mod &loading, const std::string &symbol)
{
auto &msg(get<Message>(loading, symbol));
add_command(msg.name, msg);
});
2016-08-29 21:09:59 +02:00
|
|
|
return typeid(typename std::add_pointer<T>::type);
|
|
|
|
|
}
|
2007-01-25 07:40:21 +01:00
|
|
|
|
MAPI IV. This iteration leverages the C++11 standardized RTTI.
* Simplifies the export declarations for module developers. While
MAPI III utilized a flexible key-value vector to eliminate positional
arguments in a header initializer, now the developer simply makes
a list of pointers to what they want to export for injection into
IRCd. Example:
mapi::header IRCD_MODULE
{
"mymod",
"My module adds a command, a hook, and a CLICAP",
&my_cmdtab,
&some_hook,
&clicaptab
};
* Distributes the handlers for items passed to the above vector.
Anyone can add a type-handler to the module system from anywhere in IRCd
(and other modules?) When your type is encountered a handler is called
providing the symbol name to read out of the module. Example in parser.cc:
mods::add_loader<Message>([]
(mod &loading, const std::string &symbol)
{
auto &msg(get<Message>(loading, symbol));
add_command(msg.name, msg);
});
2016-08-29 21:09:59 +02:00
|
|
|
template<class T>
|
|
|
|
|
T &
|
|
|
|
|
get(mod &mod,
|
|
|
|
|
const std::string &symbol)
|
2016-03-06 23:53:03 +01:00
|
|
|
{
|
MAPI IV. This iteration leverages the C++11 standardized RTTI.
* Simplifies the export declarations for module developers. While
MAPI III utilized a flexible key-value vector to eliminate positional
arguments in a header initializer, now the developer simply makes
a list of pointers to what they want to export for injection into
IRCd. Example:
mapi::header IRCD_MODULE
{
"mymod",
"My module adds a command, a hook, and a CLICAP",
&my_cmdtab,
&some_hook,
&clicaptab
};
* Distributes the handlers for items passed to the above vector.
Anyone can add a type-handler to the module system from anywhere in IRCd
(and other modules?) When your type is encountered a handler is called
providing the symbol name to read out of the module. Example in parser.cc:
mods::add_loader<Message>([]
(mod &loading, const std::string &symbol)
{
auto &msg(get<Message>(loading, symbol));
add_command(msg.name, msg);
});
2016-08-29 21:09:59 +02:00
|
|
|
return *reinterpret_cast<T *>(ptr(mod, symbol));
|
|
|
|
|
}
|
MAPI Version 3
This version leverages a flexible, cleaner key-value strategy
reducing the need to design entire new headers for every feature
addition, change, etc.
* A friendly declaration for the module authors, with minimal
requirements to fill in, and explicit labels of what the fields are.
* Repetition of keys, removing references to (and the requirement to
build) a clist, hlist and hfnlist and caplist and whatever the future
holds.
* Safe deterministic loading and unloading. Keys are evaluated in
order, errors can be recognized, and unloading occurs in reverse
order.
ircd: Refactor internal half of modules.c, with some V3 additions.
Provides better delegation for versions, a cleaner stack with better
error handling, and some functionality deduping. V1 and V2 handlers
are still somewhat unaltered, just factored in.
2016-06-23 03:30:05 +02:00
|
|
|
|
MAPI IV. This iteration leverages the C++11 standardized RTTI.
* Simplifies the export declarations for module developers. While
MAPI III utilized a flexible key-value vector to eliminate positional
arguments in a header initializer, now the developer simply makes
a list of pointers to what they want to export for injection into
IRCd. Example:
mapi::header IRCD_MODULE
{
"mymod",
"My module adds a command, a hook, and a CLICAP",
&my_cmdtab,
&some_hook,
&clicaptab
};
* Distributes the handlers for items passed to the above vector.
Anyone can add a type-handler to the module system from anywhere in IRCd
(and other modules?) When your type is encountered a handler is called
providing the symbol name to read out of the module. Example in parser.cc:
mods::add_loader<Message>([]
(mod &loading, const std::string &symbol)
{
auto &msg(get<Message>(loading, symbol));
add_command(msg.name, msg);
});
2016-08-29 21:09:59 +02:00
|
|
|
template<class T>
|
|
|
|
|
T *
|
|
|
|
|
ptr(mod &mod,
|
|
|
|
|
const std::string &symbol)
|
MAPI Version 3
This version leverages a flexible, cleaner key-value strategy
reducing the need to design entire new headers for every feature
addition, change, etc.
* A friendly declaration for the module authors, with minimal
requirements to fill in, and explicit labels of what the fields are.
* Repetition of keys, removing references to (and the requirement to
build) a clist, hlist and hfnlist and caplist and whatever the future
holds.
* Safe deterministic loading and unloading. Keys are evaluated in
order, errors can be recognized, and unloading occurs in reverse
order.
ircd: Refactor internal half of modules.c, with some V3 additions.
Provides better delegation for versions, a cleaner stack with better
error handling, and some functionality deduping. V1 and V2 handlers
are still somewhat unaltered, just factored in.
2016-06-23 03:30:05 +02:00
|
|
|
{
|
MAPI IV. This iteration leverages the C++11 standardized RTTI.
* Simplifies the export declarations for module developers. While
MAPI III utilized a flexible key-value vector to eliminate positional
arguments in a header initializer, now the developer simply makes
a list of pointers to what they want to export for injection into
IRCd. Example:
mapi::header IRCD_MODULE
{
"mymod",
"My module adds a command, a hook, and a CLICAP",
&my_cmdtab,
&some_hook,
&clicaptab
};
* Distributes the handlers for items passed to the above vector.
Anyone can add a type-handler to the module system from anywhere in IRCd
(and other modules?) When your type is encountered a handler is called
providing the symbol name to read out of the module. Example in parser.cc:
mods::add_loader<Message>([]
(mod &loading, const std::string &symbol)
{
auto &msg(get<Message>(loading, symbol));
add_command(msg.name, msg);
});
2016-08-29 21:09:59 +02:00
|
|
|
return reinterpret_cast<T *>(ptr(mod, symbol));
|
|
|
|
|
}
|
MAPI Version 3
This version leverages a flexible, cleaner key-value strategy
reducing the need to design entire new headers for every feature
addition, change, etc.
* A friendly declaration for the module authors, with minimal
requirements to fill in, and explicit labels of what the fields are.
* Repetition of keys, removing references to (and the requirement to
build) a clist, hlist and hfnlist and caplist and whatever the future
holds.
* Safe deterministic loading and unloading. Keys are evaluated in
order, errors can be recognized, and unloading occurs in reverse
order.
ircd: Refactor internal half of modules.c, with some V3 additions.
Provides better delegation for versions, a cleaner stack with better
error handling, and some functionality deduping. V1 and V2 handlers
are still somewhat unaltered, just factored in.
2016-06-23 03:30:05 +02:00
|
|
|
|
MAPI IV. This iteration leverages the C++11 standardized RTTI.
* Simplifies the export declarations for module developers. While
MAPI III utilized a flexible key-value vector to eliminate positional
arguments in a header initializer, now the developer simply makes
a list of pointers to what they want to export for injection into
IRCd. Example:
mapi::header IRCD_MODULE
{
"mymod",
"My module adds a command, a hook, and a CLICAP",
&my_cmdtab,
&some_hook,
&clicaptab
};
* Distributes the handlers for items passed to the above vector.
Anyone can add a type-handler to the module system from anywhere in IRCd
(and other modules?) When your type is encountered a handler is called
providing the symbol name to read out of the module. Example in parser.cc:
mods::add_loader<Message>([]
(mod &loading, const std::string &symbol)
{
auto &msg(get<Message>(loading, symbol));
add_command(msg.name, msg);
});
2016-08-29 21:09:59 +02:00
|
|
|
template<class T>
|
|
|
|
|
const T &
|
|
|
|
|
get(const mod &mod,
|
|
|
|
|
const std::string &symbol)
|
MAPI Version 3
This version leverages a flexible, cleaner key-value strategy
reducing the need to design entire new headers for every feature
addition, change, etc.
* A friendly declaration for the module authors, with minimal
requirements to fill in, and explicit labels of what the fields are.
* Repetition of keys, removing references to (and the requirement to
build) a clist, hlist and hfnlist and caplist and whatever the future
holds.
* Safe deterministic loading and unloading. Keys are evaluated in
order, errors can be recognized, and unloading occurs in reverse
order.
ircd: Refactor internal half of modules.c, with some V3 additions.
Provides better delegation for versions, a cleaner stack with better
error handling, and some functionality deduping. V1 and V2 handlers
are still somewhat unaltered, just factored in.
2016-06-23 03:30:05 +02:00
|
|
|
{
|
MAPI IV. This iteration leverages the C++11 standardized RTTI.
* Simplifies the export declarations for module developers. While
MAPI III utilized a flexible key-value vector to eliminate positional
arguments in a header initializer, now the developer simply makes
a list of pointers to what they want to export for injection into
IRCd. Example:
mapi::header IRCD_MODULE
{
"mymod",
"My module adds a command, a hook, and a CLICAP",
&my_cmdtab,
&some_hook,
&clicaptab
};
* Distributes the handlers for items passed to the above vector.
Anyone can add a type-handler to the module system from anywhere in IRCd
(and other modules?) When your type is encountered a handler is called
providing the symbol name to read out of the module. Example in parser.cc:
mods::add_loader<Message>([]
(mod &loading, const std::string &symbol)
{
auto &msg(get<Message>(loading, symbol));
add_command(msg.name, msg);
});
2016-08-29 21:09:59 +02:00
|
|
|
return *reinterpret_cast<const T *>(ptr(mod, symbol));
|
|
|
|
|
}
|
MAPI Version 3
This version leverages a flexible, cleaner key-value strategy
reducing the need to design entire new headers for every feature
addition, change, etc.
* A friendly declaration for the module authors, with minimal
requirements to fill in, and explicit labels of what the fields are.
* Repetition of keys, removing references to (and the requirement to
build) a clist, hlist and hfnlist and caplist and whatever the future
holds.
* Safe deterministic loading and unloading. Keys are evaluated in
order, errors can be recognized, and unloading occurs in reverse
order.
ircd: Refactor internal half of modules.c, with some V3 additions.
Provides better delegation for versions, a cleaner stack with better
error handling, and some functionality deduping. V1 and V2 handlers
are still somewhat unaltered, just factored in.
2016-06-23 03:30:05 +02:00
|
|
|
|
MAPI IV. This iteration leverages the C++11 standardized RTTI.
* Simplifies the export declarations for module developers. While
MAPI III utilized a flexible key-value vector to eliminate positional
arguments in a header initializer, now the developer simply makes
a list of pointers to what they want to export for injection into
IRCd. Example:
mapi::header IRCD_MODULE
{
"mymod",
"My module adds a command, a hook, and a CLICAP",
&my_cmdtab,
&some_hook,
&clicaptab
};
* Distributes the handlers for items passed to the above vector.
Anyone can add a type-handler to the module system from anywhere in IRCd
(and other modules?) When your type is encountered a handler is called
providing the symbol name to read out of the module. Example in parser.cc:
mods::add_loader<Message>([]
(mod &loading, const std::string &symbol)
{
auto &msg(get<Message>(loading, symbol));
add_command(msg.name, msg);
});
2016-08-29 21:09:59 +02:00
|
|
|
template<class T>
|
|
|
|
|
const T *
|
|
|
|
|
ptr(const mod &mod,
|
|
|
|
|
const std::string &symbol)
|
|
|
|
|
{
|
|
|
|
|
return reinterpret_cast<const T *>(ptr(mod, symbol));
|
|
|
|
|
}
|
2016-04-07 11:00:25 +02:00
|
|
|
|
MAPI IV. This iteration leverages the C++11 standardized RTTI.
* Simplifies the export declarations for module developers. While
MAPI III utilized a flexible key-value vector to eliminate positional
arguments in a header initializer, now the developer simply makes
a list of pointers to what they want to export for injection into
IRCd. Example:
mapi::header IRCD_MODULE
{
"mymod",
"My module adds a command, a hook, and a CLICAP",
&my_cmdtab,
&some_hook,
&clicaptab
};
* Distributes the handlers for items passed to the above vector.
Anyone can add a type-handler to the module system from anywhere in IRCd
(and other modules?) When your type is encountered a handler is called
providing the symbol name to read out of the module. Example in parser.cc:
mods::add_loader<Message>([]
(mod &loading, const std::string &symbol)
{
auto &msg(get<Message>(loading, symbol));
add_command(msg.name, msg);
});
2016-08-29 21:09:59 +02:00
|
|
|
} // namespace mods
|
2016-08-13 05:05:54 +02:00
|
|
|
} // namespace ircd
|
|
|
|
|
#endif // __cplusplus
|
