3 /* messaging - high level communication (send/receive messages) */
4 /* module's public interface exported to end user. */
6 /* Copyright (c) 2003, 2004 Martin Quinson. All rights reserved. */
8 /* This program is free software; you can redistribute it and/or modify it
9 * under the terms of the license (GNU LGPL) which comes with this package. */
11 #ifndef GRAS_MESSAGES_H
12 #define GRAS_MESSAGES_H
15 #include "gras/transport.h"
16 #include "gras/datadesc.h"
20 /** @addtogroup GRAS_msg
21 * @brief Defining messages and callbacks, and exchanging messages
23 * There is two way to receive messages in GRAS. The first one is to
24 * register a given function as callback to a given type of messages (see
25 * \ref gras_cb_register and associated section). But you can also
26 * explicitely wait for a given message with the \ref gras_msg_wait
29 * Usually, both ways are not intended to be mixed of a given type of
30 * messages. But if you do so, it shouldn't trigger any issue. If the
31 * message arrives when gras_msg_wait is blocked, then it will be routed to
32 * it. If it arrives when before or after \ref gras_msg_wait, it will be
33 * passed to the callback.
35 * For an example of use, please refer to \ref GRAS_ex_ping. The archive
36 * contains much more examples, but their are not properly integrated into
37 * this documentation yet.
40 /** @defgroup GRAS_msg_decl Message declaration and retrival
43 * GRAS messages can only accept one type of payload. See \ref GRAS_dd for
44 * more information on how to describe data in GRAS.
46 * If you absolutely want use a message able to convey several datatypes,
47 * you can always say that it conveys a generic reference (see
48 * \ref gras_datadesc_ref_generic).
50 * In order to ease the upgrade of GRAS applications, it is possible to \e
51 * version the messages, ie to add a version number to the message (by
52 * default, the version is set to 0). Any messages of the wrong version will
53 * be ignored by the applications not providing any specific callback for
56 * This mechanism (stolen from the dynamic loader one) should ensure you to
57 * change the semantic of a given message while still understanding the old
61 /** \brief Opaque type */
62 typedef struct s_gras_msgtype *gras_msgtype_t;
64 XBT_PUBLIC(void) gras_msgtype_declare (const char *name,
65 gras_datadesc_type_t payload);
66 XBT_PUBLIC(void) gras_msgtype_declare_v(const char *name,
68 gras_datadesc_type_t payload);
70 XBT_PUBLIC(gras_msgtype_t) gras_msgtype_by_name (const char *name);
71 XBT_PUBLIC(gras_msgtype_t) gras_msgtype_by_name_or_null (const char *name);
72 XBT_PUBLIC(gras_msgtype_t) gras_msgtype_by_namev(const char *name, short int version);
73 XBT_PUBLIC(gras_msgtype_t) gras_msgtype_by_id(int id);
75 XBT_PUBLIC(void) gras_msgtype_dumpall(void);
79 /** @defgroup GRAS_msg_cb Callback declaration and use
83 * This is how to register a given function so that it gets called when a
84 * given type of message arrives.
86 * You can register several callbacks to the same kind of messages, and
87 * they will get stacked. The lastly added callback gets the message first.
88 * If it consumes the message, it should return a true value when done. If
89 * not, it should return 0, and the message will be passed to the second
90 * callback of the stack, if any.
95 /** \brief Context of callbacks (opaque structure, created by the middleware only, never by user) */
96 typedef struct s_gras_msg_cb_ctx *gras_msg_cb_ctx_t;
98 XBT_PUBLIC(void) gras_msg_cb_ctx_free(gras_msg_cb_ctx_t ctx) ;
99 XBT_PUBLIC(gras_socket_t) gras_msg_cb_ctx_from(gras_msg_cb_ctx_t ctx);
101 /** \brief Type of message callback functions.
103 * \param expeditor: a socket to contact who sent this message
104 * \param payload: the message itself
106 * \return true if the message was consumed by the callback,
107 * false if the message was refused by the callback (and should be
108 * passed to the next callback of the stack for this message)
110 * Once a such a function is registered to handle messages of a given
111 * type with \ref gras_cb_register(), it will be called each time such
112 * a message arrives (unless a gras_msg_wait() intercepts it on arrival).
114 * If the callback accepts the message, it should free it after use.
116 typedef int (*gras_msg_cb_t)(gras_msg_cb_ctx_t ctx,
119 XBT_PUBLIC(void) gras_cb_register (gras_msgtype_t msgtype, gras_msg_cb_t cb);
120 XBT_PUBLIC(void) gras_cb_unregister(gras_msgtype_t msgtype, gras_msg_cb_t cb);
124 /** @defgroup GRAS_msg_exchange Message exchange
131 XBT_PUBLIC(void) gras_msg_send(gras_socket_t sock,
132 gras_msgtype_t msgtype,
134 XBT_PUBLIC(void) gras_msg_wait(double timeout,
135 gras_msgtype_t msgt_want,
136 gras_socket_t *expeditor,
138 XBT_PUBLIC(void) gras_msg_handleall(double period);
139 XBT_PUBLIC(void) gras_msg_handle(double timeOut);
143 /** @defgroup GRAS_msg_rpc RPC specific functions
146 * Remote Procedure Call (RPC) are a classical mecanism to request a service
147 * from a remote host. Using this set of functions, you let GRAS doing most of
148 * the work of sending the request, wait for an answer, make sure it is the
149 * right answer from the right host and so on. Any exception raised on the
150 * server is also passed over the network to the client.
152 * Callbacks are attached to RPC incomming messages the regular way using
153 * \ref gras_cb_register.
155 * For an example of use, check the examples/gras/rpc directory of the distribution.
160 XBT_PUBLIC(void) gras_msgtype_declare_rpc(const char *name,
161 gras_datadesc_type_t payload_request,
162 gras_datadesc_type_t payload_answer);
164 XBT_PUBLIC(void) gras_msgtype_declare_rpc_v(const char *name,
166 gras_datadesc_type_t payload_request,
167 gras_datadesc_type_t payload_answer);
170 XBT_PUBLIC(void) gras_msg_rpccall(gras_socket_t server,
172 gras_msgtype_t msgtype,
173 void *request, void *answer);
174 XBT_PUBLIC(gras_msg_cb_ctx_t)
175 gras_msg_rpc_async_call(gras_socket_t server,
177 gras_msgtype_t msgtype,
179 XBT_PUBLIC(void) gras_msg_rpc_async_wait(gras_msg_cb_ctx_t ctx,
183 XBT_PUBLIC(void) gras_msg_rpcreturn(double timeOut, gras_msg_cb_ctx_t ctx,void *answer);
188 /** @defgroup GRAS_msg_exchangeadv Message exchange (advanced interface)
194 /** @brief Message kind (internal enum) */
196 e_gras_msg_kind_unknown = 0,
198 e_gras_msg_kind_oneway=1, /**< good old regular messages */
200 e_gras_msg_kind_rpccall=2, /**< RPC request */
201 /* HACK: e_gras_msg_kind_rpccall also designate RPC message *type* in
202 msgtype_t, not only in msg_t*/
203 e_gras_msg_kind_rpcanswer=3, /**< RPC successful answer */
204 e_gras_msg_kind_rpcerror=4, /**< RPC failure on server (payload=exception); should not leak to user-space */
207 call cancel, and others
209 forwarding request and other application level routing stuff
213 e_gras_msg_kind_count=5 /* sentinel, dont mess with */
217 /** @brief Message instance (internal struct) */
220 e_gras_msg_kind_t kind;
222 unsigned long int ID;
225 } s_gras_msg_t, *gras_msg_t;
227 typedef int (*gras_msg_filter_t)(gras_msg_t msg,void *ctx);
229 XBT_PUBLIC(void) gras_msg_wait_ext(double timeout,
230 gras_msgtype_t msgt_want,
231 gras_socket_t expe_want,
232 gras_msg_filter_t filter,
236 XBT_PUBLIC(void) gras_msg_wait_or(double timeout,
237 xbt_dynar_t msgt_want,
238 gras_msg_cb_ctx_t *ctx,
247 #endif /* GRAS_MSG_H */