//int PDQ_CreateNode(char *name, int device, int sched)
void PDQ_CreateNode(char *name, int device, int sched)
{
extern NODE_TYPE *node;
extern char s1[], s2[];
extern int nodes;
extern int PDQ_DEBUG;
char *p = "PDQ_CreateNode";
FILE* out_fd;
if (PDQ_DEBUG)
{
debug(p, "Entering");
out_fd = fopen("PDQ.out", "a");
fprintf(out_fd, "name : %s device : %d sched : %d\n", name, device, sched);
//PJP this really needed to be fclose
//close(out_fd);
fclose(out_fd);
}
if (k > MAXNODES) {
sprintf(s1, "Allocating \"%s\" exceeds %d max nodes",
name, MAXNODES);
errmsg(p, s1);
}
if (strlen(name) >= MAXCHARS) {
sprintf(s1, "Nodename \"%s\" is longer than %d characters",
name, MAXCHARS);
errmsg(p, s1);
}
strcpy(node[k].devname, name);
if (sched == MSQ && device < 0) {
// interpret node as multiserver and
// number of servers must be positive integer
sprintf(s1, "Must specify MSQ node with CEN equal to positive number of servers");
errmsg(p, s1);
}
node[k].devtype = device;
node[k].sched = sched;
if (PDQ_DEBUG) {
typetostr(s1, node[k].devtype);
typetostr(s2, node[k].sched);
PRINTF("\tNode[%d]: %s %s \"%s\"\n",
k, s1, s2, node[k].devname);
resets(s1);
resets(s2);
};
if (PDQ_DEBUG)
debug(p, "Exiting");
// update global node count
k = ++nodes;
} // PDQ_CreateNode
double
getjob_pop(int c)
{
extern char s1[], s2[];
char *p = "getjob_pop()";
if (PDQ_DEBUG)
debug(p, "Entering");
switch (job[c].should_be_class) {
case TERM:
if (PDQ_DEBUG)
debug(p, "Exiting");
return (job[c].term->pop);
break;
case BATCH:
if (PDQ_DEBUG)
debug(p, "Exiting");
return (job[c].batch->pop);
break;
default: /* error */
typetostr(s1, job[c].should_be_class);
sprintf(s2, "Stream %d. Unknown job type %s", c, s1);
errmsg(p, s2);
break;
}
return -1.0;
} /* getjob_pop */
void create_batch_stream(int net, char* label, double number)
{
extern JOB_TYPE *job;
extern char s1[];
extern int PDQ_DEBUG;
char *p = "create_batch_stream()";
if (PDQ_DEBUG)
debug(p, "Entering");
/***** using global value of n *****/
strcpy(job[c].batch->name, label);
job[c].should_be_class = BATCH;
job[c].network = net;
job[c].batch->pop = number;
if (PDQ_DEBUG) {
typetostr(s1, job[c].should_be_class);
PRINTF("\tStream[%d]: %s \"%s\"; N: %3.1f\n",
c, s1, job[c].batch->name, job[c].batch->pop);
resets(s1);
}
if (PDQ_DEBUG)
debug(p, "Exiting");
} // create_batch_stream
void create_term_stream(int circuit, char *label, double pop, double think)
{
extern JOB_TYPE *job;
extern char s1[];
extern int PDQ_DEBUG;
char *p = "create_term_stream()";
if (PDQ_DEBUG)
debug(p, "Entering");
strcpy(job[c].term->name, label);
job[c].should_be_class = TERM;
job[c].network = circuit;
job[c].term->think = think;
job[c].term->pop = pop;
if (PDQ_DEBUG) {
typetostr(s1, job[c].should_be_class);
PRINTF("\tStream[%d]: %s \"%s\"; N: %3.1f, Z: %3.2f\n",
c, s1,
job[c].term->name,
job[c].term->pop,
job[c].term->think
);
resets(s1);
}
if (PDQ_DEBUG)
debug(p, "Exiting");
} // create_term_stream
//-------------------------------------------------------------------------
// Subroutines
//-------------------------------------------------------------------------
void create_transaction(int net, char* label, double lambda)
{
extern JOB_TYPE *job;
extern char s1[];
extern int PDQ_DEBUG;
strcpy(job[c].trans->name, label);
job[c].should_be_class = TRANS;
job[c].network = net;
job[c].trans->arrival_rate = lambda;
if (PDQ_DEBUG) {
typetostr(s1, job[c].should_be_class);
PRINTF("\tStream[%d]: %s\t\"%s\";\tLambda: %3.1f\n",
c, s1, job[c].trans->name, job[c].trans->arrival_rate);
resets(s1);
}
} // create_transaction
static ssize_t show_type(struct device *dev, struct device_attribute *attr, char *buf)
{
struct hci_dev *hdev = dev_get_drvdata(dev);
return sprintf(buf, "%s\n", typetostr(hdev->type));
}
void PDQ_CreateMultiserverClosed(int servers, char *name, int device, int sched) {
extern NODE_TYPE *node;
extern char s1[], s2[];
extern int nodes;
extern int PDQ_DEBUG;
FILE* out_fd;
char *p = "PDQ_CreateMultiserverClosed";
// hack to force FESC node type
//sched = FESC;
//device = servers;
if (PDQ_DEBUG)
{
debug(p, "Entering");
out_fd = fopen("PDQ.out", "a");
fprintf(out_fd, "name : %s device : %d sched : %d\n", name, device, sched);
//The following should really be fclose
// close(out_fd);
fclose(out_fd);
}
if (streams > 1) {
sprintf(s1, "Only single workload allowed with CreateMultiserverClosed()\n");
errmsg(p, s1);
}
if (k > 1) {
sprintf(s1, "Allocating \"%s\" exceeds %d max nodes", name, MAXNODES);
errmsg(p, s1);
}
if (strlen(name) >= MAXCHARS) {
sprintf(s1, "Nodename \"%s\" is longer than %d characters",
name, MAXCHARS);
errmsg(p, s1);
}
strcpy(node[k].devname, name);
if (servers <= 0) {
// number of servers must be positive integer
sprintf(s1, "Must specify a positive number of servers");
errmsg(p, s1);
}
// Added by NJG on Dec 29, 2018
node[k].devtype = device;
node[k].sched = sched;
node[k].servers = servers;
if (PDQ_DEBUG) {
typetostr(s1, node[k].devtype);
typetostr(s2, node[k].sched);
PRINTF("\tNode[%d]: %s %s \"%s\"\n",
k, s1, s2, node[k].devname);
resets(s1);
resets(s2);
};
if (PDQ_DEBUG)
debug(p, "Exiting");
// update global node count
k = ++nodes;
} // PDQ_CreateMultiserverClosed
void approx(void)
{
extern int PDQ_DEBUG, iterations, streams, nodes;
extern char s1[], s2[], s3[], s4[];
extern double tolerance;
extern JOB_TYPE *job;
extern NODE_TYPE *node;
extern void typetostr();
extern void getjob_name();
int k, c;
int should_be_class;
double sumQ();
double sumR[MAXSTREAMS];
double delta = 2 * TOL;
int iterate;
char jobname[MAXBUF];
NODE_TYPE *last;
char *p = "approx()";
if (PDQ_DEBUG)
debug(p, "Entering");
if (nodes == 0 || streams == 0)
errmsg(p, "Network nodes and streams not defined.");
#ifndef __R_PDQ
if ((last = (NODE_TYPE *) calloc(sizeof(NODE_TYPE), nodes)) == NULL)
#else
if ((last = (NODE_TYPE *) Calloc((size_t) nodes, NODE_TYPE )) == NULL)
#endif
errmsg(p, "Node (last) allocation failed!\n");
iterations = 0;
if (PDQ_DEBUG) {
sprintf(s1, "\nIteration: %d", iterations);
debug(p, s1);
resets(s1);
}
/* initialize all queues */
for (c = 0; c < streams; c++) {
should_be_class = job[c].should_be_class;
for (k = 0; k < nodes; k++) {
switch (should_be_class) {
case TERM:
last[k].qsize[c] = node[k].qsize[c] = job[c].term->pop / nodes;
break;
case BATCH:
last[k].qsize[c] = node[k].qsize[c] = job[c].batch->pop / nodes;
break;
default:
break;
}
if (PDQ_DEBUG) {
getjob_name(jobname, c);
sprintf(s2, "Que[%s][%s]: %3.4f (D=%f)",
node[k].devname,
jobname,
node[k].qsize[c],
delta);
debug(p, s2);
resets(s2);
resets(jobname);
}
} /* over k */
} /* over c */
do {
iterations++;
if (PDQ_DEBUG) {
sprintf(s1, "\nIteration: %d", iterations);
debug(p, s1);
resets(s1);
}
for (c = 0; c < streams; c++) {
getjob_name(jobname, c);
sumR[c] = 0.0;
if (PDQ_DEBUG) {
sprintf(s1, "\nStream: %s", jobname);
debug(p, s1);
resets(s1);
}
should_be_class = job[c].should_be_class;
for (k = 0; k < nodes; k++) {
if (PDQ_DEBUG) {
sprintf(s2, "Que[%s][%s]: %3.4f (D=%1.5f)",
node[k].devname,
jobname,
node[k].qsize[c],
delta);
debug(p, s2);
resets(s1);
}
/* approximate avg queue length */
switch (should_be_class) {
double N;
case TERM:
N = job[c].term->pop;
node[k].avqsize[c] = sumQ(k, c) +
(node[k].qsize[c] * (N - 1.0) / N);
break;
case BATCH:
N = job[c].batch->pop;
node[k].avqsize[c] =
sumQ(k, c) + (node[k].qsize[c] * (N - 1.0) / N);
break;
default:
typetostr(s1, should_be_class);
sprintf(s2, "Unknown should_be_class: %s", s1);
errmsg(p, s2);
resets(s2);
break;
}
if (PDQ_DEBUG) {
sprintf(s2, "<Q>[%s][%s]: %3.4f (D=%1.5f)",
node[k].devname,
jobname,
node[k].avqsize[c],
delta
);
debug(p, s2);
resets(s2);
}
/* residence times */
switch (node[k].sched) {
case FCFS:
case PSHR:
case LCFS:
node[k].resit[c] =
node[k].demand[c] * (node[k].avqsize[c] + 1.0);
break;
case ISRV:
node[k].resit[c] = node[k].demand[c];
break;
default:
typetostr(s1, node[k].sched);
sprintf(s2, "Unknown queue type: %s", s1);
errmsg(p, s2);
break;
}
sumR[c] += node[k].resit[c];
if (PDQ_DEBUG) {
PRINTF("\tTot ResTime[%s] = %3.4f\n", jobname, sumR[c]);
PRINTF("\tnode[%s].qsize[%s] = %3.4f\n",
node[k].devname,
jobname,
node[k].qsize[c]
);
PRINTF("\tnode[%s].demand[%s] = %3.4f\n",
node[k].devname,
jobname,
node[k].demand[c]
);
PRINTF("\tnode[%s].resit[%s] = %3.4f\n",
node[k].devname,
jobname,
node[k].resit[c]
);
}
} /* over k */
/* system throughput, residency & response-time */
switch (should_be_class) {
case TERM:
job[c].term->sys->thruput =
(job[c].term->pop / (sumR[c] + job[c].term->think));
job[c].term->sys->response =
(job[c].term->pop / job[c].term->sys->thruput) - job[c].term->think;
job[c].term->sys->residency =
job[c].term->pop - (job[c].term->sys->thruput * job[c].term->think);
if (PDQ_DEBUG) {
sprintf(s2, "\tTERM<X>[%s]: %5.4f",
jobname, job[c].term->sys->thruput);
debug(p, s2);
resets(s2);
sprintf(s2, "\tTERM<R>[%s]: %5.4f",
jobname, job[c].term->sys->response);
debug(p, s2);
resets(s2);
}
break;
case BATCH:
job[c].batch->sys->thruput = job[c].batch->pop / sumR[c];
job[c].batch->sys->response =
(job[c].batch->pop / job[c].batch->sys->thruput);
job[c].batch->sys->residency = job[c].batch->pop;
if (PDQ_DEBUG) {
sprintf(s2, "\t<X>[%s]: %3.4f",
jobname, job[c].batch->sys->thruput);
debug(p, s2);
resets(s2);
sprintf(s2, "\t<R>[%s]: %3.4f",
jobname, job[c].batch->sys->response);
debug(p, s2);
resets(s2);
}
break;
default:
sprintf(s1, "Unknown should_be_class: %s", should_be_class);
errmsg(p, s1);
break;
}
resets(jobname);
} /* over c */
/* update queue sizes */
for (c = 0; c < streams; c++) {
getjob_name(jobname, c);
should_be_class = job[c].should_be_class;
iterate = FALSE;
if (PDQ_DEBUG) {
sprintf(s1, "Updating queues of \"%s\"", jobname);
PRINTF("\n");
debug(p, s1);
resets(s1);
}
for (k = 0; k < nodes; k++) {
switch (should_be_class) {
case TERM:
node[k].qsize[c] = job[c].term->sys->thruput * node[k].resit[c];
break;
case BATCH:
node[k].qsize[c] = job[c].batch->sys->thruput * node[k].resit[c];
break;
default:
sprintf(s1, "Unknown should_be_class: %s", should_be_class);
errmsg(p, s1);
break;
}
/* check convergence */
delta = fabs((double) (last[k].qsize[c] - node[k].qsize[c]));
if (delta > tolerance) /* for any node */
iterate = TRUE; /* but complete all queue updates */
last[k].qsize[c] = node[k].qsize[c];
if (PDQ_DEBUG) {
sprintf(s2, "Que[%s][%s]: %3.4f (D=%1.5f)",
node[k].devname,
jobname,
node[k].qsize[c],
delta);
debug(p, s2);
resets(s2);
}
} /* over k */
resets(jobname);
} /* over c */
if (PDQ_DEBUG)
debug(p, "Update complete");
} while (iterate);
/* cleanup */
if (last) {
PDQ_FREE(last);
last = NULL;
}
if (PDQ_DEBUG)
debug(p, "Exiting");
} /* approx */
void canonical(void)
{
extern int PDQ_DEBUG, streams, nodes;
extern char s1[], s2[], s3[], s4[];
extern JOB_TYPE *job;
extern NODE_TYPE *node;
extern double ErlangR(double arrivrate, double servtime, int servers); // ANSI
int k;
int m; // servers in MSQ case
int c = 0;
double X;
double Xsat;
double Dsat = 0.0;
double Ddev;
double sumR[MAXSTREAMS];
double devU;
double sumU();
char jobname[MAXBUF];
char satname[MAXBUF];
char *p = "canonical()";
if (PDQ_DEBUG)
debug(p, "Entering");
for (c = 0; c < streams; c++) {
sumR[c] = 0.0;
Dsat = 0.0; // Fix submitted by James Newsom, 23 Feb 2011
//Otherwise, stream index can be compared to wrong (old) device index
X = job[c].trans->arrival_rate;
// find bottleneck node (== largest service demand)
for (k = 0; k < nodes; k++) {
// Hope to remove single class restriction eventually
if (node[k].sched == MSQ && streams > 1) {
sprintf(s1, "Only single PDQ stream allowed with MSQ nodes.");
errmsg(p, s1);
}
Ddev = node[k].demand[c];
if (node[k].sched == MSQ) { // multiserver case
m = node[k].devtype; // contains number of servers > 0
Ddev /= m;
}
if (Ddev > Dsat) {
Dsat = Ddev;
//Since we're about to fall out this k-loop
//keep device name in case of error msg
sprintf(satname, "%s", node[k].devname);
}
} // end of k-loop
Xsat = 1.0 / Dsat;
job[c].trans->saturation_rate = Xsat;
if (Dsat == 0) {
sprintf(s1, "Dsat = %3.3f", Dsat);
errmsg(p, s1);
}
if (X > Xsat) {
getjob_name(jobname, c);
sprintf(s1,
"\nArrival rate %3.3f for stream \'%s\' exceeds saturation thruput %3.3f of node \'%s\' with demand %3.3f",
X, jobname, Xsat, satname, Dsat
);
errmsg(p, s1);
}
for (k = 0; k < nodes; k++) {
node[k].utiliz[c] = X * node[k].demand[c];
if (node[k].sched == MSQ) { // multiserver case
m = node[k].devtype; // recompute m in every k-loop
node[k].utiliz[c] /= m; // per server
}
devU = sumU(k); // sum all workload classes
if (devU > 1.0) {
sprintf(s1, "\nTotal utilization of node \"%s\" is %2.2f%% (> 100%%)",
node[k].devname,
devU * 100
);
errmsg(p, s1);
}
if (PDQ_DEBUG)
printf("Tot Util: %3.4f for %s\n", devU, node[k].devname);
switch (node[k].sched) {
case FCFS:
case PSHR:
case LCFS:
node[k].resit[c] = node[k].demand[c] / (1.0 - devU);
node[k].qsize[c] = X * node[k].resit[c];
break;
case MSQ: // Added by NJG on Mon, Apr 2, 2007
node[k].resit[c] = ErlangR(X, node[k].demand[c], m);
node[k].qsize[c] = X * node[k].resit[c];
break;
case ISRV:
node[k].resit[c] = node[k].demand[c];
node[k].qsize[c] = node[k].utiliz[c];
break;
default:
typetostr(s1, node[k].sched);
sprintf(s2, "Unknown queue type: %s", s1);
errmsg(p, s2);
break;
}
sumR[c] += node[k].resit[c];
} // end of k-loop
job[c].trans->sys->thruput = X; // system throughput
job[c].trans->sys->response = sumR[c]; // system response time
job[c].trans->sys->residency = X * sumR[c]; // total number in system
if (PDQ_DEBUG) {
getjob_name(jobname, c);
printf("\tX[%s]: %3.4f\n", jobname, job[c].trans->sys->thruput);
printf("\tR[%s]: %3.4f\n", jobname, job[c].trans->sys->response);
printf("\tN[%s]: %3.4f\n", jobname, job[c].trans->sys->residency);
}
} // end of c-loop
if (PDQ_DEBUG)
debug(p, "Exiting");
} // canonical
int main(int argc, char *argv[]){
int err;
int i, j, k;
char err_msg[ME_ERROR_MSG_MAX_COUNT] = {0};
char description[ME_DEVICE_DESCRIPTION_MAX_COUNT] = {0};
char name_device[ME_DEVICE_NAME_MAX_COUNT] = {0};
char name_driver[ME_DEVICE_DRIVER_NAME_MAX_COUNT] = {0};
int d_version;
int l_version;
int n_devices;
int n_subdevices;
int n_channels;
int n_ranges;
int unit;
double min;
double max;
int max_data;
int type;
int subtype;
//Initialization of ME-iDS
err = meOpen(ME_OPEN_NO_FLAGS);
if (err){
meErrorGetMessage(err, err_msg, sizeof(err_msg));
fprintf(stderr, "In meOpen(): %s\n", err_msg);
return 1;
}
//Get library version
err = meQueryVersionLibrary(&l_version);
if (err){
meErrorGetMessage(err, err_msg, sizeof(err_msg));
fprintf(stderr, "In meQueryLibraryVersion(): %s\n", err_msg);
return 1;
}
printf("Library version is 0x%X\n", l_version);
//Get number of registered devices
err = meQueryNumberDevices(&n_devices);
if (err){
meErrorGetMessage(err, err_msg, sizeof(err_msg));
fprintf(stderr, "In meQueryNumberDevices(): %s\n", err_msg);
return 1;
}
if (n_devices >0)
{
//Get main driver version
err = meQueryVersionMainDriver(&d_version);
if (err){
meErrorGetMessage(err, err_msg, sizeof(err_msg));
fprintf(stderr, "In meQueryDriverVersion(): %s\n", err_msg);
return 1;
}
printf("Main driver version is 0x%X\n", d_version);
}
printf("%d devices detected by driver system\n", n_devices);
for(i = 0; i < n_devices; i++)
{
// For each device get:
// - device name
// - device description
// - driver name
// - driver version
// - number sub-devices
printf("\n");
printf("Device %d:\n", i);
printf("=========\n");
err = meQueryNameDevice(i, name_device, sizeof(name_device));
if (err)
{
meErrorGetMessage(err, err_msg, sizeof(err_msg));
fprintf(stderr, "In meQueryDeviceName(): %s\n", err_msg);
return 1;
}
printf("Device name is %s\n", name_device);
err = meQueryNameDeviceDriver(i, name_driver, sizeof(name_driver));
if (err)
{
meErrorGetMessage(err, err_msg, sizeof(err_msg));
fprintf(stderr, "In meQueryNameDeviceDriver(): %s\n", err_msg);
return 1;
}
printf("Driver name is %s\n", name_driver);
err = meQueryDescriptionDevice(i, description, sizeof(description));
if (err)
{
meErrorGetMessage(err, err_msg, sizeof(err_msg));
fprintf(stderr, "In meQueryDescriptionDevice(): %s\n", err_msg);
return 1;
}
printf("Device description: %s\n", description);
err = meQueryVersionDeviceDriver(i, &d_version);
if (err)
{
meErrorGetMessage(err, err_msg, sizeof(err_msg));
fprintf(stderr, "In meQueryDriverName(): %s\n", err_msg);
return 1;
}
printf("Device driver version is 0x%X\n", d_version);
err = meQueryNumberSubdevices(i, &n_subdevices);
if (err)
{
meErrorGetMessage(err, err_msg, sizeof(err_msg));
fprintf(stderr, "In meQueryNumberSubdevices(): %s\n", err_msg);
return 1;
}
printf("%d subdevices available:\n", n_subdevices);
for(j = 0; j < n_subdevices; j++)
{
// For each sub-device get:
// - type
// - sub-type
err = meQuerySubdeviceType(i, j, &type, &subtype);
if (err)
{
meErrorGetMessage(err, err_msg, sizeof(err_msg));
fprintf(stderr, "In meQuerySubdeviceType(): %s\n", err_msg);
return 1;
}
printf("\tSubdevice %d is of type %s (0x%X) and subtype %s (0x%X)\n", j, typetostr(type), type , subtypetostr(subtype), subtype);
err = meQueryNumberChannels(i, j, &n_channels);
if (err)
{
meErrorGetMessage(err, err_msg, sizeof(err_msg));
fprintf(stderr, "In meQueryNumberChannels(): %s\n", err_msg);
return 1;
}
printf("\t\tSubdevice %d has %d channels\n", j, n_channels);
if (type == ME_TYPE_AI || type == ME_TYPE_AO)
{
//For AI and AO sub-device get number ranges
err = meQueryNumberRanges(i, j, ME_UNIT_ANY, &n_ranges);
if (err)
{
meErrorGetMessage(err, err_msg, sizeof(err_msg));
fprintf(stderr, "In meQueryNumberRanges(): %s\n", err_msg);
return 1;
}
printf("\t\t\tSubdevice %d has %d ranges:\n", j, n_ranges);
for(k = 0; k < n_ranges; k++)
{
err = meQueryRangeInfo(
i,
j,
k,
&unit,
&min,
&max,
&max_data);
if (err)
{
meErrorGetMessage(err, err_msg, sizeof(err_msg));
fprintf(stderr, "In meQueryNumberRanges(): %s\n", err_msg);
return 1;
}
printf("\t\t\t\tRange %d: Unit = 0x%X, Min = %lf, Max = %lf, Max Data = %d\n", k, unit, min, max, max_data);
}
}
}
}
//Close ME-iDS
err = meClose(ME_CLOSE_NO_FLAGS);
if (err)
{
meErrorGetMessage(err, err_msg, sizeof(err_msg));
fprintf(stderr, "In meClose(): %s\n", err_msg);
return 1;
}
return 0;
}
int main(int argc, char *argv[]){
int err;
int i, j, k;
char err_msg[ME_ERROR_MSG_MAX_COUNT] = {0};
char description[ME_DEVICE_DESCRIPTION_MAX_COUNT] = {0};
char name_device[ME_DEVICE_NAME_MAX_COUNT] = {0};
char name_driver[ME_DEVICE_DRIVER_NAME_MAX_COUNT] = {0};
int d_version;
int l_version;
int n_devices;
int n_subdevices;
int n_channels;
int n_ranges;
int unit;
double min;
double max;
int max_data;
int type;
int subtype;
///@NOTE Due to internal synchronization delays timeouts shorter than 150ms can generate ambiguous response.
int timeout = 200;
SetMeRemoteDetectionTimeout(timeout);
err = meOpen(0);
if(err){
meErrorGetMessage(err, err_msg, sizeof(err_msg));
fprintf(stderr, "In meOpen(): %s\n", err_msg);
return 1;
}
err = meQueryVersionLibrary(&l_version);
if(err){
meErrorGetMessage(err, err_msg, sizeof(err_msg));
fprintf(stderr, "In meQueryLibraryVersion(): %s\n", err_msg);
return 1;
}
printf("Library version is 0x%X\n", l_version);
err = meQueryNumberDevices(&n_devices);
if(err){
meErrorGetMessage(err, err_msg, sizeof(err_msg));
fprintf(stderr, "In meQueryNumberDevices(): %s\n", err_msg);
return 1;
}
if (n_devices >0)
{
err = meQueryVersionMainDriver(&d_version);
if(err){
meErrorGetMessage(err, err_msg, sizeof(err_msg));
fprintf(stderr, "In meQueryDriverVersion(): %s\n", err_msg);
return 1;
}
printf("Main driver version is 0x%X\n", d_version);
}
printf("%d devices detected by driver system\n", n_devices);
for(i = 0; i < n_devices; i++){
printf("\n");
printf("Device %d:\n", i);
printf("=========\n");
err = meQueryNameDevice(i, name_device, sizeof(name_device));
if(err){
meErrorGetMessage(err, err_msg, sizeof(err_msg));
fprintf(stderr, "In meQueryDeviceName(): %s\n", err_msg);
return 1;
}
printf("Device name is %s\n", name_device);
err = meQueryNameDeviceDriver(i, name_driver, sizeof(name_driver));
if(err){
meErrorGetMessage(err, err_msg, sizeof(err_msg));
fprintf(stderr, "In meQueryNameDeviceDriver(): %s\n", err_msg);
return 1;
}
printf("Driver name is %s\n", name_driver);
err = meQueryDescriptionDevice(i, description, sizeof(description));
if(err){
meErrorGetMessage(err, err_msg, sizeof(err_msg));
fprintf(stderr, "In meQueryDescriptionDevice(): %s\n", err_msg);
return 1;
}
printf("Device description: %s\n", description);
err = meQueryVersionDeviceDriver(i, &d_version);
if(err){
meErrorGetMessage(err, err_msg, sizeof(err_msg));
fprintf(stderr, "In meQueryDriverName(): %s\n", err_msg);
return 1;
}
printf("Device driver version is 0x%X\n", d_version);
err = meQueryNumberSubdevices(i, &n_subdevices);
if(err){
meErrorGetMessage(err, err_msg, sizeof(err_msg));
fprintf(stderr, "In meQueryNumberSubdevices(): %s\n", err_msg);
return 1;
}
printf("%d subdevices available:\n", n_subdevices);
for(j = 0; j < n_subdevices; j++){
err = meQuerySubdeviceType(i, j, &type, &subtype);
if(err){
meErrorGetMessage(err, err_msg, sizeof(err_msg));
fprintf(stderr, "In meQuerySubdeviceType(): %s\n", err_msg);
return 1;
}
printf("\tSubdevice %d is of type %s (0x%X) and subtype %s (0x%X)\n", j, typetostr(type), type , subtypetostr(subtype), subtype);
err = meQueryNumberChannels(i, j, &n_channels);
if(err){
meErrorGetMessage(err, err_msg, sizeof(err_msg));
fprintf(stderr, "In meQueryNumberChannels(): %s\n", err_msg);
return 1;
}
printf("\t\tSubdevice %d has %d channels\n", j, n_channels);
if(type == ME_TYPE_AI || type == ME_TYPE_AO){
err = meQueryNumberRanges(i, j, ME_UNIT_ANY, &n_ranges);
if(err){
meErrorGetMessage(err, err_msg, sizeof(err_msg));
fprintf(stderr, "In meQueryNumberRanges(): %s\n", err_msg);
return 1;
}
printf("\t\t\tSubdevice %d has %d ranges:\n", j, n_ranges);
for(k = 0; k < n_ranges; k++){
err = meQueryRangeInfo(
i,
j,
k,
&unit,
&min,
&max,
&max_data);
if(err){
meErrorGetMessage(err, err_msg, sizeof(err_msg));
fprintf(stderr, "In meQueryNumberRanges(): %s\n", err_msg);
return 1;
}
printf("\t\t\t\tRange %d: Unit = 0x%X, Min = %lf, Max = %lf, Max Data = %d\n", k, unit, min, max, max_data);
}
}
}
}
err = meClose(0);
if(err){
meErrorGetMessage(err, err_msg, sizeof(err_msg));
fprintf(stderr, "In meClose(): %s\n", err_msg);
return 1;
}
return 0;
}
