/******************************************************************************* (c) 2005-2014 Copyright, Real-Time Innovations, Inc. All rights reserved. RTI grants Licensee a license to use, modify, compile, and create derivative works of the Software. Licensee has the right to distribute object form only for use with RTI products. The Software is provided "as is", with no warranty of any type, including any warranty for fitness for any purpose. RTI is under no obligation to maintain or support the Software. RTI shall not be liable for any incidental or consequential damages arising out of the use or inability to use the software. ******************************************************************************/ /* keys_publisher.c A publication of data of type keys This file is derived from code automatically generated by the rtiddsgen command: rtiddsgen -language C -example keys.idl Example publication of type keys automatically generated by 'rtiddsgen'. To test them follow these steps: (1) Compile this file and the example subscription. (2) Start the subscription with the command objs//keys_subscriber (3) Start the publication with the command objs//keys_publisher (4) [Optional] Specify the list of discovery initial peers and multicast receive addresses via an environment variable or a file (in the current working directory) called NDDS_DISCOVERY_PEERS. You can run any number of publishers and subscribers programs, and can add and remove them dynamically from the domain. Example: To run the example application on domain : On Unix: objs//keys_publisher objs//keys_subscriber On Windows: objs\\keys_publisher objs\\keys_subscriber modification history ------------ ------- */ #include "keys.h" #include "keysSupport.h" #include "ndds/ndds_c.h" #include #include /* Delete all entities */ static int publisher_shutdown(DDS_DomainParticipant *participant) { DDS_ReturnCode_t retcode; int status = 0; if (participant != NULL) { retcode = DDS_DomainParticipant_delete_contained_entities(participant); if (retcode != DDS_RETCODE_OK) { printf("delete_contained_entities error %d\n", retcode); status = -1; } retcode = DDS_DomainParticipantFactory_delete_participant( DDS_TheParticipantFactory, participant); if (retcode != DDS_RETCODE_OK) { printf("delete_participant error %d\n", retcode); status = -1; } } /* RTI Connext provides finalize_instance() method on domain participant factory for people who want to release memory used by the participant factory. Uncomment the following block of code for clean destruction of the singleton. */ /* retcode = DDS_DomainParticipantFactory_finalize_instance(); if (retcode != DDS_RETCODE_OK) { printf("finalize_instance error %d\n", retcode); status = -1; } */ return status; } static int publisher_main(int domainId, int sample_count) { DDS_DomainParticipant *participant = NULL; DDS_Publisher *publisher = NULL; DDS_Topic *topic = NULL; DDS_DataWriter *writer = NULL; DDS_DataWriter *writer2 = NULL; keysDataWriter *keys_writer = NULL; keysDataWriter *keys_writer2 = NULL; DDS_ReturnCode_t retcode; /* Creates three instances */ keys *instance[3] = { NULL, NULL, NULL }; /* Creates three handles for managing the registrations */ DDS_InstanceHandle_t handle[3]; /* Make variables for the instance for the second datawriter to use. Note that it actually refers to the same logical instance, but because we're running both datawriters in the same thread, we to create separate variables so they don't clobber each other. */ keys *instance_dw2 = NULL; DDS_InstanceHandle_t handle_dw2 = DDS_HANDLE_NIL; /* We only will send data over the instances marked as active */ int active[3] = { 1, 0, 0 }; int active_dw2 = 1; /* We are going to load different QoS profiles for the two DWs */ struct DDS_DataWriterQos datawriter_qos = DDS_DataWriterQos_INITIALIZER; const char *type_name = NULL; int count = 0; struct DDS_Duration_t send_period = { 1, 0 }; int i = 0; /* To customize participant QoS, use the configuration file USER_QOS_PROFILES.xml */ participant = DDS_DomainParticipantFactory_create_participant( DDS_TheParticipantFactory, domainId, &DDS_PARTICIPANT_QOS_DEFAULT, NULL /* listener */, DDS_STATUS_MASK_NONE); if (participant == NULL) { printf("create_participant error\n"); publisher_shutdown(participant); return -1; } /* To customize publisher QoS, use the configuration file USER_QOS_PROFILES.xml */ publisher = DDS_DomainParticipant_create_publisher( participant, &DDS_PUBLISHER_QOS_DEFAULT, NULL /* listener */, DDS_STATUS_MASK_NONE); if (publisher == NULL) { printf("create_publisher error\n"); publisher_shutdown(participant); return -1; } /* Register type before creating topic */ type_name = keysTypeSupport_get_type_name(); retcode = keysTypeSupport_register_type(participant, type_name); if (retcode != DDS_RETCODE_OK) { printf("register_type error %d\n", retcode); publisher_shutdown(participant); return -1; } /* To customize topic QoS, use the configuration file USER_QOS_PROFILES.xml */ topic = DDS_DomainParticipant_create_topic( participant, "Example keys", type_name, &DDS_TOPIC_QOS_DEFAULT, NULL /* listener */, DDS_STATUS_MASK_NONE); if (topic == NULL) { printf("create_topic error\n"); publisher_shutdown(participant); return -1; } /* To customize data writer QoS, use the configuration file USER_QOS_PROFILES.xml */ writer = DDS_Publisher_create_datawriter( publisher, topic, &DDS_DATAWRITER_QOS_DEFAULT, NULL /* listener */, DDS_STATUS_MASK_NONE); retcode = DDS_DomainParticipantFactory_get_datawriter_qos_from_profile( DDS_TheParticipantFactory, &datawriter_qos, "keys_Library", "keys_Profile_dw2"); if (retcode != DDS_RETCODE_OK) { printf("get_datawriter_qos_from_profile error\n"); return -1; } /* If you want to set the writer_data_lifecycle QoS settings * programmatically rather than using the XML, you will need to add * the following lines to your code and comment out the create_datawriter * and get_datawriter_qos_from_profile calls above. */ /* retcode = DDS_Publisher_get_default_datawriter_qos(publisher, &datawriter_qos); if (retcode != DDS_RETCODE_OK) { printf("get_default_datawriter_qos error\n"); return -1; } datawriter_qos.writer_data_lifecycle.autodispose_unregistered_instances = DDS_BOOLEAN_FALSE; datawriter_qos.ownership.kind = DDS_EXCLUSIVE_OWNERSHIP_QOS; datawriter_qos.ownership_strength.value = 10; writer = DDS_Publisher_create_datawriter( publisher, topic, &datawriter_qos, NULL, DDS_STATUS_MASK_NONE); datawriter_qos.ownership_strength.value = 5; */ writer2 = DDS_Publisher_create_datawriter( publisher, topic, &datawriter_qos, NULL, DDS_STATUS_MASK_NONE); if (writer == NULL) { printf("create_datawriter1 error\n"); publisher_shutdown(participant); return -1; } if (writer2 == NULL) { printf("create_datawriter2 error\n"); publisher_shutdown(participant); return -1; } keys_writer = keysDataWriter_narrow(writer); if (keys_writer == NULL) { printf("DataWriter narrow error\n"); publisher_shutdown(participant); return -1; } keys_writer2 = keysDataWriter_narrow(writer2); if (keys_writer2 == NULL) { printf("DataWriter narrow error\n"); publisher_shutdown(participant); return -1; } /* Create data sample for writing */ instance[0] = keysTypeSupport_create_data_ex(DDS_BOOLEAN_TRUE); instance[1] = keysTypeSupport_create_data_ex(DDS_BOOLEAN_TRUE); instance[2] = keysTypeSupport_create_data_ex(DDS_BOOLEAN_TRUE); if (instance[0] == NULL || instance[1] == NULL || instance[2] == NULL) { printf("keysTypeSupport_create_data error\n"); publisher_shutdown(participant); return -1; } /* RTI Connext could examine the key fields each time it needs to determine * which data-instance is being modified. * However, for performance and semantic reasons, it is better * for your application to declare all the data-instances it intends to * modify prior to actually writing any samples. This is known as * registration. */ /* In order to register the instances, we must set their associated keys * first */ instance[0]->code = 0; instance[1]->code = 1; instance[2]->code = 2; handle[0] = DDS_HANDLE_NIL; handle[1] = DDS_HANDLE_NIL; handle[2] = DDS_HANDLE_NIL; /* The keys must have been set before making this call */ printf("Registering instance %d\n", instance[0]->code); handle[0] = keysDataWriter_register_instance(keys_writer, instance[0]); /* Modify the data to be sent here */ instance[0]->x = 1; instance[1]->x = 1; instance[2]->x = 1; /* Make variables for the instance for the second datawriter to use. Note that it actually refers to the same logical instance, but because we're running both datawriters in the same thread, we to create separate variables so they don't clobber each other. */ instance_dw2 = keysTypeSupport_create_data_ex(DDS_BOOLEAN_TRUE); if (instance_dw2 == NULL) { printf("keysTypeSupport_create_data error\n"); publisher_shutdown(participant); return -1; } /* instance_dw2 and instance[1] have the same key, and thus will write to the same instance (ins1). */ instance_dw2->code = instance[1]->code; instance_dw2->x = 2; handle_dw2 = keysDataWriter_register_instance(keys_writer2, instance_dw2); /* Main loop */ for (count = 0; (sample_count == 0) || (count < sample_count); ++count) { NDDS_Utility_sleep(&send_period); /* Modify the data to be sent here */ instance[0]->y = count; instance[1]->y = count + 1000; instance[2]->y = count + 2000; instance_dw2->y = -count - 1000; /* We control two datawriters via a state machine here rather than introducing separate threads. */ /* Control first DataWriter */ switch (count) { case 4: { /* Start sending the second (ins1) and third instances (ins2) */ printf("----DW1 registering instance %d\n", instance[1]->code); printf("----DW1 registering instance %d\n", instance[2]->code); handle[1] = keysDataWriter_register_instance(keys_writer, instance[1]); handle[2] = keysDataWriter_register_instance(keys_writer, instance[2]); active[1] = 1; active[2] = 1; } break; case 8: { /* Dispose the second instance (ins1) */ printf("----DW1 disposing instance %d\n", instance[1]->code); retcode = keysDataWriter_dispose( keys_writer, instance[1], &handle[1]); if (retcode != DDS_RETCODE_OK) { printf("dispose instance error %d\n", retcode); return -1; } active[1] = 0; } break; case 10: { /* Unregister the second instance (ins1) */ printf("----DW1 unregistering instance %d\n", instance[1]->code); retcode = keysDataWriter_unregister_instance( keys_writer, instance[1], &handle[1]); if (retcode != DDS_RETCODE_OK) { printf("unregister instance error %d\n", retcode); return -1; } active[1] = 0; } break; case 12: { /* Unregister the third instance (ins2) */ printf("----DW1 unregistering instance %d\n", instance[2]->code); retcode = keysDataWriter_unregister_instance( keys_writer, instance[2], &handle[2]); if (retcode != DDS_RETCODE_OK) { printf("dispose instance error %d\n", retcode); return -1; } active[2] = 0; /* Re-register the second instance (ins1) */ printf("----DW1 re-registering instance %d\n", instance[1]->code); handle[1] = keysDataWriter_register_instance(keys_writer, instance[1]); active[1] = 1; } break; case 16: { /* Re-register the third instance (ins2) */ printf("----DW1 re-registering instance %d\n", instance[2]->code); handle[2] = keysDataWriter_register_instance(keys_writer, instance[2]); active[2] = 1; } break; } for (i = 0; i < 3; ++i) { if (active[i]) { printf("DW1 write; code: %d, x: %d, y: %d\n", instance[i]->code, instance[i]->x, instance[i]->y); retcode = keysDataWriter_write( keys_writer, instance[i], &handle[i]); if (retcode != DDS_RETCODE_OK) { printf("write error %d\n", retcode); return -1; } } } /* Control second datawriter */ switch (count) { case 16: { /* Dispose the instance (ins1). Since it has lower ownership strength, this does nothing */ printf("----DW2 disposing instance %d\n", instance_dw2->code); retcode = keysDataWriter_dispose( keys_writer2, instance_dw2, &handle_dw2); if (retcode != DDS_RETCODE_OK) { printf("DW2 dispose instance error %d\n", retcode); } active_dw2 = 0; } break; } if (active_dw2) { printf("DW2 write; code: %d, x: %d, y: %d\n", instance_dw2->code, instance_dw2->x, instance_dw2->y); retcode = keysDataWriter_write( keys_writer2, instance_dw2, &handle_dw2); if (retcode != DDS_RETCODE_OK) { printf("write error %d\n", retcode); return -1; } } } /* Delete data samples */ for (i = 0; i < 3; ++i) { retcode = keysTypeSupport_delete_data(instance[i]); if (retcode != DDS_RETCODE_OK) { printf("keysTypeSupport::delete_data error %d\n", retcode); } } retcode = keysTypeSupport_delete_data(instance_dw2); if (retcode != DDS_RETCODE_OK) { printf("keysTypeSupport::delete_data error %d\n", retcode); } /* Cleanup and delete delete all entities */ return publisher_shutdown(participant); } #if defined(RTI_WINCE) int wmain(int argc, wchar_t **argv) { int domainId = 0; int sample_count = 0; /* infinite loop */ if (argc >= 2) { domainId = _wtoi(argv[1]); } if (argc >= 3) { sample_count = _wtoi(argv[2]); } /* Uncomment this to turn on additional logging NDDS_Config_Logger_set_verbosity_by_category( NDDS_Config_Logger_get_instance(), NDDS_CONFIG_LOG_CATEGORY_API, NDDS_CONFIG_LOG_VERBOSITY_STATUS_ALL); */ return publisher_main(domainId, sample_count); } #elif !(defined(RTI_VXWORKS) && !defined(__RTP__)) && !defined(RTI_PSOS) int main(int argc, char *argv[]) { int domainId = 0; int sample_count = 0; /* infinite loop */ if (argc >= 2) { domainId = atoi(argv[1]); } if (argc >= 3) { sample_count = atoi(argv[2]); } /* Uncomment this to turn on additional logging NDDS_Config_Logger_set_verbosity_by_category( NDDS_Config_Logger_get_instance(), NDDS_CONFIG_LOG_CATEGORY_API, NDDS_CONFIG_LOG_VERBOSITY_STATUS_ALL); */ return publisher_main(domainId, sample_count); } #endif #ifdef RTI_VX653 const unsigned char *__ctype = NULL; void usrAppInit() { #ifdef USER_APPL_INIT USER_APPL_INIT; /* for backwards compatibility */ #endif /* add application specific code here */ taskSpawn( "pub", RTI_OSAPI_THREAD_PRIORITY_NORMAL, 0x8, 0x150000, (FUNCPTR) publisher_main, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0); } #endif