c/examples/send-abort.c - qpid-proton - Git at Google

 /*
  *
  * Licensed to the Apache Software Foundation (ASF) under one
  * or more contributor license agreements.  See the NOTICE file
  * distributed with this work for additional information
  * regarding copyright ownership.  The ASF licenses this file
  * to you under the Apache License, Version 2.0 (the
  * "License"); you may not use this file except in compliance
  * with the License.  You may obtain a copy of the License at
  *
  *   http://www.apache.org/licenses/LICENSE-2.0
  *
  * Unless required by applicable law or agreed to in writing,
  * software distributed under the License is distributed on an
  * "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY
  * KIND, either express or implied.  See the License for the
  * specific language governing permissions and limitations
  * under the License.
  *
  */

 #include <proton/connection.h>
 #include <proton/condition.h>
 #include <proton/delivery.h>
 #include <proton/link.h>
 #include <proton/message.h>
 #include <proton/proactor.h>
 #include <proton/session.h>
 #include <proton/transport.h>

 #include <stdio.h>
 #include <stdlib.h>

 /*
  * Send aborted messages.
  *
  * An 80 Kbyte (MSG_SIZE) message is generated.
  * The size is chosen to be large enough so that some of the message
  * will go out on the wire before the abort is sent.
  *
  * 79 Kbytes (MSG_SIZE - HOLDBACK) are sent on one link flow event.
  * The message is aborted on the next link flow event.
  */

 #define MSG_SIZE 80000
 #define HOLDBACK  1000

 #if MSG_SIZE <= HOLDBACK
 #error "MSG_SIZE must be greater than HOLDBACK"
 #endif

 typedef struct app_data_t {
   const char *host, *port;
   const char *amqp_address;
   const char *container_id;
   int message_count;

   pn_proactor_t *proactor;
   pn_rwbytes_t message_buffer;
   int sent;
   int aborted;
   bool in_progress;
 } app_data_t;

 static int exit_code = 0;

 static void check_condition(pn_event_t *e, pn_condition_t *cond) {
   if (pn_condition_is_set(cond)) {
     fprintf(stderr, "%s: %s: %s\n", pn_event_type_name(pn_event_type(e)),
             pn_condition_get_name(cond), pn_condition_get_description(cond));
     pn_connection_close(pn_event_connection(e));
     exit_code = 1;
   }
 }

 /* Create a message with a map { "sequence" : number } encode it and return the encoded buffer. */
 static pn_bytes_t encode_message(app_data_t* app) {
   /* Construct a message with the map { "sequence": app.sent } */
   pn_message_t* message = pn_message();
   char data[MSG_SIZE + 11] = {0};
   pn_data_t* body;
   pn_data_put_int(pn_message_id(message), app->sent); /* Set the message_id also */
   body = pn_message_body(message);
   pn_data_enter(body);
   pn_data_put_string(body, pn_bytes(MSG_SIZE, data));
   pn_data_exit(body);

   /* encode the message, expanding the encode buffer as needed */
   if (app->message_buffer.start == NULL) {
     static const size_t initial_size = MSG_SIZE + 1000;
     app->message_buffer = pn_rwbytes(initial_size, (char*)malloc(initial_size));
   }
   /* app->message_buffer is the total buffer space available. */
   /* mbuf wil point at just the portion used by the encoded message */
   {
   pn_rwbytes_t mbuf = pn_rwbytes(app->message_buffer.size, app->message_buffer.start);
   int status = 0;
   while ((status = pn_message_encode(message, mbuf.start, &mbuf.size)) == PN_OVERFLOW) {
     app->message_buffer.size *= 2;
     app->message_buffer.start = (char*)realloc(app->message_buffer.start, app->message_buffer.size);
     mbuf.size = app->message_buffer.size;
   }
   if (status != 0) {
     fprintf(stderr, "error encoding message: %s\n", pn_error_text(pn_message_error(message)));
     exit(1);
   }
   pn_message_free(message);
   return pn_bytes(mbuf.size, mbuf.start);
   }
 }

 /* Returns true to continue, false if finished */
 static bool handle(app_data_t* app, pn_event_t* event) {
   switch (pn_event_type(event)) {

    case PN_CONNECTION_INIT: {
      pn_connection_t* c = pn_event_connection(event);
      pn_session_t* s = pn_session(pn_event_connection(event));
      pn_connection_set_container(c, app->container_id);
      pn_connection_open(c);
      pn_session_open(s);
      {
      pn_link_t* l = pn_sender(s, "my_sender");
      pn_terminus_set_address(pn_link_target(l), app->amqp_address);
      pn_link_open(l);
      break;
      }
    }

    case PN_LINK_FLOW: {
      /* The peer has given us some credit, now we can send messages */
      pn_link_t *sender = pn_event_link(event);
      while (app->in_progress || (pn_link_credit(sender) > 0 && app->sent < app->message_count)) {
         if (!app->in_progress) {
           pn_bytes_t msgbuf = encode_message(app);
           /* Use sent counter as unique delivery tag. */
           pn_delivery(sender, pn_dtag((const char *)&app->sent, sizeof(app->sent)));
           pn_link_send(sender, msgbuf.start, msgbuf.size - HOLDBACK); /* Send some part of message */
           app->in_progress = true;
           /* Return from this link flow event and abort the message on next, */
           break;
         } else {
           pn_delivery_t * pnd = pn_link_current(sender);
           pn_delivery_abort(pnd);
           /* aborted delivery is presettled and never ack'd. */
           if (++app->aborted == app->message_count) {
             printf("%d messages started and aborted\n", app->aborted);
             pn_connection_close(pn_event_connection(event));
             /* Continue handling events till we receive TRANSPORT_CLOSED */
           }
           ++app->sent;
           app->in_progress = false;
         }
      }
      break;
    }

    case PN_DELIVERY: {
      /* We received acknowledgement from the peer that a message was delivered. */
      pn_delivery_t* d = pn_event_delivery(event);
      fprintf(stderr, "Aborted deliveries should not receive delivery events. Delivery state %d\n", (int)pn_delivery_remote_state(d));
      pn_connection_close(pn_event_connection(event));
      exit_code=1;
      break;
    }

    case PN_TRANSPORT_CLOSED:
     check_condition(event, pn_transport_condition(pn_event_transport(event)));
     break;

    case PN_CONNECTION_REMOTE_CLOSE:
     check_condition(event, pn_connection_remote_condition(pn_event_connection(event)));
     pn_connection_close(pn_event_connection(event));
     break;

    case PN_SESSION_REMOTE_CLOSE:
     check_condition(event, pn_session_remote_condition(pn_event_session(event)));
     pn_connection_close(pn_event_connection(event));
     break;

    case PN_LINK_REMOTE_CLOSE:
    case PN_LINK_REMOTE_DETACH:
     check_condition(event, pn_link_remote_condition(pn_event_link(event)));
     pn_connection_close(pn_event_connection(event));
     break;

    case PN_PROACTOR_INACTIVE:
     return false;

    default: break;
   }
   return true;
 }

 void run(app_data_t *app) {
   /* Loop and handle events */
   do {
     pn_event_batch_t *events = pn_proactor_wait(app->proactor);
     pn_event_t* e;
     for (e = pn_event_batch_next(events); e; e = pn_event_batch_next(events)) {
       if (!handle(app, e)) {
         return;
       }
     }
     pn_proactor_done(app->proactor, events);
   } while(true);
 }

 int main(int argc, char **argv) {
   struct app_data_t app = {0};
   char addr[PN_MAX_ADDR];

   app.container_id = argv[0];   /* Should be unique */
   app.host = (argc > 1) ? argv[1] : "";
   app.port = (argc > 2) ? argv[2] : "amqp";
   app.amqp_address = (argc > 3) ? argv[3] : "examples";
   app.message_count = (argc > 4) ? atoi(argv[4]) : 10;

   app.proactor = pn_proactor();
   pn_proactor_addr(addr, sizeof(addr), app.host, app.port);
   pn_proactor_connect2(app.proactor, NULL, NULL, addr);
   run(&app);
   pn_proactor_free(app.proactor);
   free(app.message_buffer.start);
   return exit_code;
 }
	/*
	*
	* Licensed to the Apache Software Foundation (ASF) under one
	* or more contributor license agreements. See the NOTICE file
	* distributed with this work for additional information
	* regarding copyright ownership. The ASF licenses this file
	* to you under the Apache License, Version 2.0 (the
	* "License"); you may not use this file except in compliance
	* with the License. You may obtain a copy of the License at
	*
	* http://www.apache.org/licenses/LICENSE-2.0
	*
	* Unless required by applicable law or agreed to in writing,
	* software distributed under the License is distributed on an
	* "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY
	* KIND, either express or implied. See the License for the
	* specific language governing permissions and limitations
	* under the License.
	*
	*/

	#include <proton/connection.h>
	#include <proton/condition.h>
	#include <proton/delivery.h>
	#include <proton/link.h>
	#include <proton/message.h>
	#include <proton/proactor.h>
	#include <proton/session.h>
	#include <proton/transport.h>

	#include <stdio.h>
	#include <stdlib.h>

	/*
	* Send aborted messages.
	*
	* An 80 Kbyte (MSG_SIZE) message is generated.
	* The size is chosen to be large enough so that some of the message
	* will go out on the wire before the abort is sent.
	*
	* 79 Kbytes (MSG_SIZE - HOLDBACK) are sent on one link flow event.
	* The message is aborted on the next link flow event.
	*/

	#define MSG_SIZE 80000
	#define HOLDBACK 1000

	#if MSG_SIZE <= HOLDBACK
	#error "MSG_SIZE must be greater than HOLDBACK"
	#endif

	typedef struct app_data_t {
	const char host, port;
	const char *amqp_address;
	const char *container_id;
	int message_count;

	pn_proactor_t *proactor;
	pn_rwbytes_t message_buffer;
	int sent;
	int aborted;
	bool in_progress;
	} app_data_t;

	static int exit_code = 0;

	static void check_condition(pn_event_t e, pn_condition_t cond) {
	if (pn_condition_is_set(cond)) {
	fprintf(stderr, "%s: %s: %s\n", pn_event_type_name(pn_event_type(e)),
	pn_condition_get_name(cond), pn_condition_get_description(cond));
	pn_connection_close(pn_event_connection(e));
	exit_code = 1;
	}
	}

	/* Create a message with a map { "sequence" : number } encode it and return the encoded buffer. */
	static pn_bytes_t encode_message(app_data_t* app) {
	/* Construct a message with the map { "sequence": app.sent } */
	pn_message_t* message = pn_message();
	char data[MSG_SIZE + 11] = {0};
	pn_data_t* body;
	pn_data_put_int(pn_message_id(message), app->sent); /* Set the message_id also */
	body = pn_message_body(message);
	pn_data_enter(body);
	pn_data_put_string(body, pn_bytes(MSG_SIZE, data));
	pn_data_exit(body);

	/* encode the message, expanding the encode buffer as needed */
	if (app->message_buffer.start == NULL) {
	static const size_t initial_size = MSG_SIZE + 1000;
	app->message_buffer = pn_rwbytes(initial_size, (char*)malloc(initial_size));
	}
	/* app->message_buffer is the total buffer space available. */
	/* mbuf wil point at just the portion used by the encoded message */
	{
	pn_rwbytes_t mbuf = pn_rwbytes(app->message_buffer.size, app->message_buffer.start);
	int status = 0;
	while ((status = pn_message_encode(message, mbuf.start, &mbuf.size)) == PN_OVERFLOW) {
	app->message_buffer.size *= 2;
	app->message_buffer.start = (char*)realloc(app->message_buffer.start, app->message_buffer.size);
	mbuf.size = app->message_buffer.size;
	}
	if (status != 0) {
	fprintf(stderr, "error encoding message: %s\n", pn_error_text(pn_message_error(message)));
	exit(1);
	}
	pn_message_free(message);
	return pn_bytes(mbuf.size, mbuf.start);
	}
	}

	/* Returns true to continue, false if finished */
	static bool handle(app_data_t* app, pn_event_t* event) {
	switch (pn_event_type(event)) {

	case PN_CONNECTION_INIT: {
	pn_connection_t* c = pn_event_connection(event);
	pn_session_t* s = pn_session(pn_event_connection(event));
	pn_connection_set_container(c, app->container_id);
	pn_connection_open(c);
	pn_session_open(s);
	{
	pn_link_t* l = pn_sender(s, "my_sender");
	pn_terminus_set_address(pn_link_target(l), app->amqp_address);
	pn_link_open(l);
	break;
	}
	}

	case PN_LINK_FLOW: {
	/* The peer has given us some credit, now we can send messages */
	pn_link_t *sender = pn_event_link(event);
	while (app->in_progress \|\| (pn_link_credit(sender) > 0 && app->sent < app->message_count)) {
	if (!app->in_progress) {
	pn_bytes_t msgbuf = encode_message(app);
	/* Use sent counter as unique delivery tag. */
	pn_delivery(sender, pn_dtag((const char *)&app->sent, sizeof(app->sent)));
	pn_link_send(sender, msgbuf.start, msgbuf.size - HOLDBACK); /* Send some part of message */
	app->in_progress = true;
	/* Return from this link flow event and abort the message on next, */
	break;
	} else {
	pn_delivery_t * pnd = pn_link_current(sender);
	pn_delivery_abort(pnd);
	/* aborted delivery is presettled and never ack'd. */
	if (++app->aborted == app->message_count) {
	printf("%d messages started and aborted\n", app->aborted);
	pn_connection_close(pn_event_connection(event));
	/* Continue handling events till we receive TRANSPORT_CLOSED */
	}
	++app->sent;
	app->in_progress = false;
	}
	}
	break;
	}

	case PN_DELIVERY: {
	/* We received acknowledgement from the peer that a message was delivered. */
	pn_delivery_t* d = pn_event_delivery(event);
	fprintf(stderr, "Aborted deliveries should not receive delivery events. Delivery state %d\n", (int)pn_delivery_remote_state(d));
	pn_connection_close(pn_event_connection(event));
	exit_code=1;
	break;
	}

	case PN_TRANSPORT_CLOSED:
	check_condition(event, pn_transport_condition(pn_event_transport(event)));
	break;

	case PN_CONNECTION_REMOTE_CLOSE:
	check_condition(event, pn_connection_remote_condition(pn_event_connection(event)));
	pn_connection_close(pn_event_connection(event));
	break;

	case PN_SESSION_REMOTE_CLOSE:
	check_condition(event, pn_session_remote_condition(pn_event_session(event)));
	pn_connection_close(pn_event_connection(event));
	break;

	case PN_LINK_REMOTE_CLOSE:
	case PN_LINK_REMOTE_DETACH:
	check_condition(event, pn_link_remote_condition(pn_event_link(event)));
	pn_connection_close(pn_event_connection(event));
	break;

	case PN_PROACTOR_INACTIVE:
	return false;

	default: break;
	}
	return true;
	}

	void run(app_data_t *app) {
	/* Loop and handle events */
	do {
	pn_event_batch_t *events = pn_proactor_wait(app->proactor);
	pn_event_t* e;
	for (e = pn_event_batch_next(events); e; e = pn_event_batch_next(events)) {
	if (!handle(app, e)) {
	return;
	}
	}
	pn_proactor_done(app->proactor, events);
	} while(true);
	}

	int main(int argc, char **argv) {
	struct app_data_t app = {0};
	char addr[PN_MAX_ADDR];

	app.container_id = argv[0]; /* Should be unique */
	app.host = (argc > 1) ? argv[1] : "";
	app.port = (argc > 2) ? argv[2] : "amqp";
	app.amqp_address = (argc > 3) ? argv[3] : "examples";
	app.message_count = (argc > 4) ? atoi(argv[4]) : 10;

	app.proactor = pn_proactor();
	pn_proactor_addr(addr, sizeof(addr), app.host, app.port);
	pn_proactor_connect2(app.proactor, NULL, NULL, addr);
	run(&app);
	pn_proactor_free(app.proactor);
	free(app.message_buffer.start);
	return exit_code;
	}