/*****************************************************************************
* setup_pkt_channels
*****************************************************************************/
int setup_pkt_channels(int task_id)
{
mcapi_status_t status;
mcapi_request_t request;
size_t dummy;
/* create/ get endpoints */
if (setup_echo_endpoints(task_id) != 0) {
return -1;
}
/* connect the write channel only */
mcapi_pktchan_connect_i(local_endpts[task_id].endpts[WRITE_IDX],
remote_endpts[task_id],
&request, &status);
if (status != MCAPI_SUCCESS) {
th_log_error("Task id %d failed to initialize (1): %s\n",
task_id, mcapi_display_status(status,status_buff,sizeof(status_buff)));
return -1;
}
mcapi_wait(&request, &dummy, TIMEOUT,&status);
if (status != MCAPI_SUCCESS) {
th_log_error("Task id %d failed to initialize (2): %s\n",
task_id, mcapi_display_status(status,status_buff,sizeof(status_buff)));
return -1;
}
/* open the write channel */
mcapi_pktchan_send_open_i(&(pkt_hndls[task_id].send),
local_endpts[task_id].endpts[WRITE_IDX],
&request, &status);
if (status != MCAPI_SUCCESS) {
th_log_error("Task id %d failed to initialize (3) : %s\n",
task_id, mcapi_display_status(status,status_buff,sizeof(status_buff)));
return -1;
}
mcapi_wait(&request, &dummy, TIMEOUT,&status);
if (status != MCAPI_SUCCESS) {
th_log_error("Task id %d failed to initialize (4) : %s\n",
task_id, mcapi_display_status(status,status_buff,sizeof(status_buff)));
return -1;
}
/* open the read channel */
/* the read channel may not yet be connected */
mcapi_pktchan_recv_open_i(&(pkt_hndls[task_id].recv),
local_endpts[task_id].endpts[READ_IDX],
&request, &status);
mcapi_wait(&request, &dummy, TIMEOUT,&status);
if (status != MCAPI_SUCCESS) {
th_log_error("Task id %d failed to initialize (5) : %s\n",
task_id, mcapi_display_status(status,status_buff,sizeof(status_buff)));
return -1;
}
return 0;
}
int main(int argc, char *argv[])
{
//the endpoints used in message-oriented communication
mcapi_endpoint_t red_msg_point;
mcapi_endpoint_t yellow_msg_point;
mcapi_endpoint_t green_msg_point;
//the endpoints used in channel-oriented communication
mcapi_endpoint_t yellow_sin_chan;
mcapi_endpoint_t yellow_cos_chan;
mcapi_endpoint_t yellow_pkt_chan;
//status message received in almost all MCAPI-calls
mcapi_status_t status;
//info-struct received in initialization
mcapi_info_t info;
//buffer for incoming messages
char recv_buf[MAX_MSG_LEN];
//the status code converted to string
char status_msg[MCAPI_MAX_STATUS_MSG_LEN];
//size parameter required in some calls
size_t size = 1;
//an iterator used in loops
unsigned int i = 0;
//request handle is used to operate wait-calls
mcapi_request_t request;
//a second request handle! just so that we see it works :)
mcapi_request_t request2;
//sandles used in channel-messaging
mcapi_sclchan_recv_hndl_t sin_handle;
mcapi_sclchan_recv_hndl_t cos_handle;
mcapi_pktchan_send_hndl_t pkt_handle;
//how many scalars we are expecting
char count = 0;
//buffer of data sent in messages
unsigned char* send_buf;
printf(COLOR "here\n");
//We are yellow! initialize accordingly
mcapi_initialize( THE_DOMAIN, YELLOW_NODE, 0, 0, &info, &status );
check( MCAPI_SUCCESS, status );
//create our side of messaging
yellow_msg_point = mcapi_endpoint_create( YELLOW_MSG, &status );
check( MCAPI_SUCCESS, status );
//obtain the red message point
red_msg_point = mcapi_endpoint_get( THE_DOMAIN,
RED_NODE, RED_MSG, TIMEOUT, &status );
check( MCAPI_SUCCESS, status );
printf(COLOR "start-up messaging\n");
//wait for the amount to come
mcapi_msg_recv( yellow_msg_point, recv_buf, MAX_MSG_LEN, &size,
&status );
check( MCAPI_SUCCESS, status );
//read the count from first byte
count = recv_buf[0];
//surprise! this process reserves the buffer with malloc
send_buf = (char*)malloc(count*2);
//send ack
send_buf[0] = 'a';
mcapi_msg_send( yellow_msg_point, red_msg_point, send_buf, 1,
0, &status );
check( MCAPI_SUCCESS, status );
printf(COLOR "start-up messaged with %u bytes. expecting %u scalars\n",
size, count );
//open our channel endpoint to sin
yellow_sin_chan = mcapi_endpoint_create( YELLOW_SIN, &status );
check( MCAPI_SUCCESS, status );
//open our channel endpoint to cos
yellow_cos_chan = mcapi_endpoint_create( YELLOW_COS, &status );
check( MCAPI_SUCCESS, status );
//open our ends, let senders form connection
mcapi_sclchan_recv_open_i( &sin_handle, yellow_sin_chan, &request,
&status );
check( MCAPI_PENDING, status );
mcapi_sclchan_recv_open_i( &cos_handle, yellow_cos_chan, &request2,
&status );
check( MCAPI_PENDING, status );
//wait for it to happen
mcapi_wait( &request, &size, TIMEOUT, &status );
check( MCAPI_SUCCESS, status );
mcapi_wait( &request2, &size, TIMEOUT, &status );
check( MCAPI_SUCCESS, status );
printf(COLOR "beginning the receive value\n");
for ( i = 0; i < 15000; ++i )
{
//an iterator used in loops
unsigned int j = 0;
//start to receveive stuff
//i+=2 because our values are two bytes while buf is one byte
for ( j = 0; j < count; ++j )
{
//receive cos scalar
short cval = mcapi_sclchan_recv_uint16( cos_handle, &status );
check( MCAPI_SUCCESS, status );
//receive sin scalar
short sval = mcapi_sclchan_recv_uint16( sin_handle, &status );
check( MCAPI_SUCCESS, status );
//addition
short sumval = sval + cval;
//put to buf
send_buf[j*2] = sumval;
send_buf[j*2+1] = sumval >> 8;
//printf( COLOR "%hX %hhX %hhX\n", sumval, send_buf[j*2],
//send_buf[j*2+1] );
}
}
printf(COLOR "receiving done, closing scalar channels\n");
//close our ends
mcapi_sclchan_recv_close_i( sin_handle, &request, &status );
check( MCAPI_PENDING, status );
mcapi_sclchan_recv_close_i( cos_handle, &request2, &status );
check( MCAPI_PENDING, status );
//wait for it to happen
mcapi_wait( &request, &size, TIMEOUT, &status );
check( MCAPI_SUCCESS, status );
mcapi_wait( &request2, &size, TIMEOUT, &status );
check( MCAPI_SUCCESS, status );
printf(COLOR "closed, informing green\n");
//obtain their endpoint
green_msg_point = mcapi_endpoint_get( THE_DOMAIN,
GREEN_NODE, GREEN_MSG, TIMEOUT, &status );
check( MCAPI_SUCCESS, status );
//send the message
mcapi_msg_send( yellow_msg_point, green_msg_point, send_buf, 1,
0, &status );
check( MCAPI_SUCCESS, status );
printf(COLOR "informed, opening packet channel\n");
//open our channel endpoint to green
yellow_pkt_chan = mcapi_endpoint_create( YELLOW_PKT, &status );
check( MCAPI_SUCCESS, status );
//open our end, let receiver form connection
mcapi_pktchan_send_open_i( &pkt_handle, yellow_pkt_chan, &request,
&status );
check( MCAPI_PENDING, status );
//wait for it to happen
mcapi_wait( &request, &size, TIMEOUT, &status );
check( MCAPI_SUCCESS, status );
//now send
printf(COLOR "sending the packet\n");
mcapi_pktchan_send( pkt_handle, send_buf, count, &status );
//and now close
printf(COLOR "sent the packet, closing\n");
mcapi_pktchan_send_close_i( pkt_handle, &request, &status );
check( MCAPI_PENDING, status );
mcapi_wait( &request, &size, TIMEOUT, &status );
check( MCAPI_SUCCESS, status );
printf(COLOR "closed, shutdown\n");
//free buf
free( send_buf );
//shut-down
mcapi_finalize( &status );
check( MCAPI_SUCCESS, status );
return EXIT_SUCCESS;
}
int main(int argc, char** argv) {
mcapi_boolean_t recv_done = MCAPI_FALSE;
mcapi_boolean_t send_done = MCAPI_FALSE;
mca_status_t status;
mcapi_request_t request;
size_t size;
int num_sends,num_recvs,order,i;
struct timeval tv;
unsigned int seed;
mcapi_endpoint_t recv_endpt;
mcapi_endpoint_t send_endpt;
int rc = 0;
mcapi_param_t parms;
mcapi_info_t version;
mcapi_set_debug_level(6);
memset(&send_requests,0,sizeof(send_requests));
memset(&recv_requests,0,sizeof(recv_requests));
/* initialize the random number generator with a seed */
if (argc == 2) {
seed = atoi(argv[1]);
} else {
gettimeofday(&tv,0);
seed = tv.tv_sec + tv.tv_usec;
}
printf("Using seed:[%u]\n",seed);
srand(seed);
/* create a node */
mcapi_initialize(DOMAIN,NODE,NULL,&parms,&version,&status);
if (status != MCAPI_SUCCESS) {
fprintf(stderr,"\nERROR: Failed to initialize (0): %s\n",mcapi_display_status(status,status_buff,sizeof(status_buff)));
rc++;
mcapi_finalize(&status);
return rc;
}
/* create the endpoints */
send_endpt = mcapi_endpoint_create(1,&status);
recv_endpt = mcapi_endpoint_create(2,&status);
/*************************** connect the channels *********************/
do {
mcapi_pktchan_connect_i(send_endpt,recv_endpt,&request,&status);
//retry if all request handles are in-use
} while (status == MCAPI_ERR_REQUEST_LIMIT);
while (!mcapi_test(&request,&size,&status)) {}
if (status != MCAPI_SUCCESS) {
fprintf(stderr,"\nERROR: Failed to initialize (1): %s\n",mcapi_display_status(status,status_buff,sizeof(status_buff)));
rc++;
mcapi_finalize(&status);
return rc;
}
/*************************** open the channels *********************/
do {
mcapi_pktchan_recv_open_i(&r1 /*recv_handle*/,recv_endpt, &request, &status);
//retry if all request handles are in-use
} while (status == MCAPI_ERR_REQUEST_LIMIT);
while (!mcapi_test(&request,&size,&status)) {}
if (status != MCAPI_SUCCESS) {
fprintf(stderr,"\nERROR: Failed to initialize (2): %s\n",mcapi_display_status(status,status_buff,sizeof(status_buff)));
rc++;
mcapi_finalize(&status);
return rc;
}
do {
mcapi_pktchan_send_open_i(&s1 /*send_handle*/,send_endpt, &request, &status);
//retry if all request handles are in-use
} while (status == MCAPI_ERR_REQUEST_LIMIT);
while (!mcapi_test(&request,&size,&status)) {}
if (status != MCAPI_SUCCESS) {
fprintf(stderr,"\nERROR: Failed to initialize (3): %s\n",mcapi_display_status(status,status_buff,sizeof(status_buff)));
rc++;
mcapi_finalize(&status);
return rc;
}
/* randomly issue sends and receives */
printf("sending and receiving num_msgs=%d\n",NUM_MSGS);
while (!(recv_done && send_done)) {
if (send_done) { order = 1; }
else if (recv_done) { order = 0; }
else { order = get_random(); }
if (order % 2) {
/* do some receives */
num_recvs = get_random();
printf("issuing %i receives...\n",num_recvs);
for (i = 0; i < num_recvs; i++) {
recv_done = receiver();
}
} else {
/* do some sends */
num_sends = get_random();
printf("issuing %i sends...\n",num_sends);
for (i = 0; i < num_sends; i++) {
send_done = sender();
}
}
}
rc =check_results();
mcapi_finalize(&status);
if (status != MCAPI_SUCCESS) {
fprintf(stderr,"\nERROR: Failed to finalize: %s\n",mcapi_display_status(status,status_buff,sizeof(status_buff)));
rc++;
}
if (rc == 0) {
printf(" Test PASSED\n");
} else {
printf(" Test FAILED\n");
}
return rc;
}
int main () {
size_t size;
mcapi_endpoint_t ep1,ep2;
mcapi_pktchan_send_hndl_t s1; /* s1 = ep1->ep2 */
mcapi_pktchan_recv_hndl_t r1; /* r1 = ep1->ep2 */
int i = 0;
int rc = 1;
mca_status_t status;
mcapi_request_t request;
mcapi_param_t parms;
mcapi_info_t version;
mcapi_set_debug_level(6);
/* create a node */
mcapi_initialize(DOMAIN,NODE,NULL,&parms,&version,&status);
if (status != MCAPI_SUCCESS) { WRONG }
/* create endpoints */
ep1 = mcapi_endpoint_create(PORT_NUM1,&status);
if (status != MCAPI_SUCCESS) { WRONG }
ep2 = mcapi_endpoint_create(PORT_NUM2,&status);
if (status != MCAPI_SUCCESS) { WRONG }
/*************************** connect the channels *********************/
do {
mcapi_pktchan_connect_i(ep1,ep2,&request,&status);
//retry if all request handles are in-use
} while (status == MCAPI_ERR_REQUEST_LIMIT);
while (!mcapi_test(&request,&size,&status)) {}
if (status != MCAPI_SUCCESS) { WRONG }
/*************************** open the channels *********************/
do {
mcapi_pktchan_recv_open_i(&r1 /*recv_handle*/,ep2, &request, &status);
//retry if all request handles are in-use
} while (status == MCAPI_ERR_REQUEST_LIMIT);
while (!mcapi_test(&request,&size,&status)) {}
if (status != MCAPI_SUCCESS) { WRONG }
do {
mcapi_pktchan_send_open_i(&s1 /*send_handle*/,ep1, &request, &status);
//retry if all request handles are in-use
} while (status == MCAPI_ERR_REQUEST_LIMIT);
while (!mcapi_test(&request,&size,&status)) {}
if (status != MCAPI_SUCCESS) { WRONG }
/* tests: recv send send recv obeys FIFO */
do {
mcapi_pktchan_recv_i(r1,(void **)((void*)&requests[i].buffer),&requests[i].request,&requests[i].status);
//retry if all request handles are in-use
} while (status == MCAPI_ERR_REQUEST_LIMIT);
i++;
do {
mcapi_pktchan_send_i(s1,"one",sizeof("one"),&requests[i].request,&requests[i].status);
//retry if all request handles are in-use
} while (status == MCAPI_ERR_REQUEST_LIMIT);
i++;
do {
mcapi_pktchan_send_i(s1,"two",sizeof("two"),&requests[i].request,&requests[i].status);
//retry if all request handles are in-use
} while (status == MCAPI_ERR_REQUEST_LIMIT);
i++;
do {
mcapi_pktchan_recv_i(r1,(void **)((void*)&requests[i].buffer),&requests[i].request,&requests[i].status);
//retry if all request handles are in-use
} while (status == MCAPI_ERR_REQUEST_LIMIT);
i++;
rc = check_results();
/* close the channels */
do {
mcapi_pktchan_recv_close_i(r1,&request,&status);
//retry if all request handles are in-use
} while (status == MCAPI_ERR_REQUEST_LIMIT);
while (!mcapi_test(&request,&size,&status)) {}
if (status != MCAPI_SUCCESS) { WRONG }
do {
mcapi_pktchan_send_close_i(s1,&request,&status);
//retry if all request handles are in-use
} while (status == MCAPI_ERR_REQUEST_LIMIT);
while (!mcapi_test(&request,&size,&status)) {}
if (status != MCAPI_SUCCESS) { WRONG }
mcapi_finalize(&status);
if (rc == 0) {
printf(" Test PASSED\n");
} else {
printf(" Test FAILED\n");
}
return rc;
}
