NAME | C SYNOPSIS | DESCRIPTION | EXAMPLE | UNUSUAL SITUATIONS | DIAGNOSTICS | SEE ALSO | COLOPHON |
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PMFETCHGROUP(3) Library Functions Manual PMFETCHGROUP(3)
pmCreateFetchGroup, pmExtendFetchGroup_item, pmExtendFetchGroup_indom, pmExtendFetchGroup_event, pmExtendFetchGroup_timestamp, pmExtendFetchGroup_timespec, pmExtendFetchGroup_timeval, pmFetchGroup, pmGetFetchGroupContext, pmClearFetchGroup, pmDestroyFetchGroup - simplified performance metrics value fetch and conversion
#include <pcp/pmapi.h> int pmCreateFetchGroup(pmFG *ptr, int type, const char *name); int pmExtendFetchGroup_item(pmFG pmfg, const char *metric, const char *instance, const char *scale, pmAtomValue *out_value, int out_type, int out_sts); int pmExtendFetchGroup_indom(pmFG pmfg, const char *metric, const char *scale, int out_inst_codes[], char *out_inst_names[], pmAtomValue out_values[], int out_type, int out_stss[], unsigned int out_maxnum, unsigned int *out_num, int *out_sts); int pmExtendFetchGroup_event(pmFG pmfg, const char *metric, const char *instance, const char *field, const char *scale, struct timespec out_times[], pmAtomValue out_values[], int out_type, int out_stss[], unsigned int out_maxnum, unsigned int *out_num, int *out_sts); int pmExtendFetchGroup_timestamp(pmFG pmfg, struct timeval *out_value); int pmExtendFetchGroup_timespec(pmFG pmfg, struct timespec *out_value); int pmExtendFetchGroup_timeval(pmFG pmfg, struct timeval *out_value); int pmGetFetchGroupContext(pmFG pmfg); int pmFetchGroup(pmFG pmfg); int pmClearFetchGroup(pmFG pmfg); int pmDestroyFetchGroup(pmFG pmfg); cc ... -lpcp
The fetchgroup functions implement a registration-based mechanism to fetch groups of performance metrics, including automation for general unit, rate and type conversions as well as convenient in‐ stance and value encodings. They constitute a powerful and com‐ pact alternative to the classic Performance Metrics Application Programming Interface (PMAPI(3)) sequence of separate lookup, check, fetch, iterate, extract and convert functions. The general idea consists of two stages. In the setup stage, the application identifies metrics of interest by name and with de‐ sired conversions, and register a unique pmAtomValue output loca‐ tion where the fetchgroup system is to later deposit the result. It is also possible to identify a metric with an instance domain, and register a unique vector of pmAtomValue objects for them. In the operation stage, one simple pmFetchGroup function fetches, decodes, converts, and stores all metrics to their destinations, where the application can read them directly. This function may be called repeatedly, and each time new pmAtomValue values will be stored in the same destinations. Rate conversions between consecutive samples may be requested. Each fetchgroup is associated with a private PMAPI context, so it can manipulate instance profiles and other such state without disrupting other contexts. The instance profile is manipulated to optimize fetches of individual items, even if some are derived metrics. This private PMAPI context belongs to the fetchgroup, is used for all of its internal operations, and will be de‐ stroyed. Multiple fetchgroups may be used concurrently, independently. An opaque type pmFG is used to identify a fetchgroup, which is passed to all related function calls. Creating a fetchgroup int pmCreateFetchGroup(pmFG *ptr, int type, const char *name); This function creates a new fetchgroup, associated with a new PMAPI context. The type and name parameters are relayed to pmNewContext(3) for creation of the context. The fetchgroup identifier is returned upon success through the ptr pointer. This object is later used as a parameter to all other fetchgroup functions. The private PMAPI context may be accessed with pmGet‐ FetchGroupContext, if required. The normal function return code is zero, and ptr is set. This function may fail in case of pmNewContext or memory allocation errors. Those are indicated with a negative return code and a cleared ptr value. Getting the private PMAPI context int pmGetFetchGroupContext(pmFG pmfg); This function returns the private PMAPI context used by the given fetchgroup. It may be safely used to adjust some configuration parameters of the context, such as via pmSetMode(3), before fetchgroup extension and fetching begins. However, mutation of this context by PMAPI functions after this time may disrupt fetchgroup functionality. For example, a pmSet‐ Mode call could invalidate one rate-conversion time-step. The normal function return code is the context number. Extending a fetchgroup with a metric instance of interest int pmExtendFetchGroup_item(pmFG pmfg, const char *metric, const char *instance, const char *scale, pmAtomValue *out_value, int out_type, int *out_sts); This function registers interest in a single metric and optional instance. The metric name is given in the mandatory metric para‐ meter, which is checked immediately via pmLookupName(3) and other calls. If and only if the metric has an instance domain, the specific instance of interest may be named by the instance para‐ meter, which is checked immediately via pmNameInDom(3); otherwise pass NULL. If the fetchgroup context is a set of archives, it is possible that the metric / instance pair is not yet defined at the current time origin. Therefore, this function may attempt to seek to the end of the current set of archives temporarily to retry the metric / instance lookup. The optional scale parameter specifies desired unit/scale/rate conversions for the metric value. It can take the following val‐ ues: NULL No unit/scale conversion. If metric has PM_SEM_COUNTER se‐ mantics, perform rate conversion. rate Perform rate conversion regardless of semantics, and no unit/scale conversion. instant Perform no rate conversion regardless of semantics, and no unit/scale conversion. EXPRESSION Perform unit/scale/rate conversion as specified by the EX‐ PRESSION, which is parsed by pmParseUnitsStr(3). This may be useful to assert a canonical scaling for the resulting metric value, independent of PCP version or configuration. Dimen‐ sionality must match the metric, except if rate conversion is requested, in which case the time dimension must be one smaller than the metric's time dimension. Note that the type of rate conversion performed here matches the rate(x) func‐ tion in derived metric expressions, in that it is calculated as the naive difference between previous and current values of a metric, divided by elapsed time. For example, if a counter wraps around, or a non-counter value decreases, a negative output rate may be computed. The optional but usual out_value parameter specifies the pmAtom‐ Value where the converted result should later be stored. If the value is NULL, fetching and conversions will be attempted, and possible errors reported, but the result tossed away. The manda‐ tory out_type parameter specifes the PM_TYPE_* requested for the output value. It need not match the metric's native type, as the fetchgroup facility is capable of casting between all supported types (including to and from strings). Any errors subsequently encountered during fetching, unit/scale/rate conversion, or casting, will result in the as‐ signment of a sentinel value to the output pmAtomValue (see the ``UNUSUAL SITUATIONS'' section below). In addition, if the op‐ tional out_sts parameter is specified, an appropriate PMAPI error code will be stored there. As a review, only the pmfg, metric, and out_type parameters are mandatory. Others may be NULL to indicate application disinter‐ est. The normal function return code is zero. This function may fail in case of various lookup, type- and conversion- checking errors. Those are indicated with a negative return code. Extending a fetchgroup with a metric instance domain of interest int pmExtendFetchGroup_indom(pmFG pmfg, const char* metric, const char *scale, int out_inst_codes[], char *out_inst_names[], pmAtomValue out_values[], int out_type, int out_stss[], unsigned int out_maxnum, unsigned int *out_num, int *out_sts); This function generalizes the pmExtendFetchGroup_item function by registering interest in a whole instance domain. Therefore, the function registers preallocated vectors for output variables (in‐ stead of a singleton). Instances will be stored in sorted order in elements of those vectors. The concepts are otherwise the same. The metric name is specified by the mandatory metric parameter. Note that it may refer to a metric without an instance domain, in which case the single output value will appear as one unnamed in‐ stance. The optional scale parameter specifies desired unit/scale/rate conversions for the metric value, same as above. The optional out_inst_codes parameter specifies a vector of inte‐ gers, where the raw instance number of the fetched metrics should later be stored. The optional out_inst_names parameter specifies a vector of strings, where the instance names of the fetched metrics should later be stored. If an instance does not have a corresponding name, a NULL pointer is stored instead. The application must not modify or free(3) strings in that vector. The optional out_values parameter specifies a vector of pmAtom‐ Value objects where the converted result should later be stored. The mandatory out_type parameter specifies the PM_TYPE_* request‐ ed for the all output values, same as above. The optional out_stss parameter specifies a vector of integers where per-instance error codes should be stored. The mandatory out_maxnum parameter specifies the number of ele‐ ments of the vectors above. In other words, it tells the fetch‐ group the maximum number of instances which are expected. The optional out_num parameter specifies an integer where the actual number of instances should later be stored. It will range be‐ tween 0 and out_maxnum. It is initialized to 0 by this function. Finally, the optional out_sts parameter specifies a single loca‐ tion where an integer status code for the overall fetch for this metric should be stored. Normally, this will be zero. Other than a severe fetch error, one may see a PM_ERR_TOOBIG here if the number of instances actually encountered was larger than out_maxnum. Any errors subsequently encountered during fetching, unit/scale/rate conversion, or casting, will result in the as‐ signment of a sentinel value to the appropriate output pmAtomVal‐ ue (see the ``UNUSUAL SITUATIONS'' section below). In addition, if the optional out_stss parameter was specified, a PMAPI error code will be stored in the appropriate position. As a review, only the pmfg, metric, out_type, and out_maxnum pa‐ rameters are mandatory. Others may be NULL to indicate applica‐ tion disinterest. The normal function return code is zero. This function may fail in case of various lookup, type- and conversion- checking errors. Those are indicated with a negative return code. Extending a fetchgroup with an event field int pmExtendFetchGroup_event(pmFG pmfg, const char *metric, const char *instance, const char *field, const char *scale, struct timespec out_times[], pmAtomValue out_values[], int out_type, int out_stss[], unsigned int out_maxnum, unsigned int *out_num, int *out_sts); This function registers interest in all instances of one field of all records of an event metric. Since event metrics may return multiple records per fetch, and each record may have multiple fields of a given field metric type, this function registers pre‐ allocated vectors for output variables, similarly to pmExtend‐ FetchGroup_indom. They are filled in temporal/sequential order. The metric name is specified by the mandatory metric parameter. It must be of PM_TYPE_EVENT. If the metric has an instance do‐ main, the instance parameter is mandatory to identify the in‐ stance of interest. The field to extract from event records is specified by the mandatory field parameter, which is a metric name of normal scalar type. As is typical for event field metrics, it should not have an instance domain. The optional scale parameter speci‐ fies desired unit/scale conversions on this metric value. Rate conversions are not available, because of ambiguity about which previous value to compute rates from. The optional out_times parameter specifies a vector of timespec structs, which will receive a copy of the timestamp of the event record where each particular field was found. The optional out_values parameter specifies a vector of pmAtom‐ Value objects where the converted result should later be stored. The mandatory out_type parameter specifies the PM_TYPE_* request‐ ed for the output values. The optional out_stss parameter specifies a vector of integers where per-field error codes should be stored. The mandatory out_maxnum parameter specifies the number of ele‐ ments of the vectors above. In other words, it tells the fetch‐ group the maximum number of instances which are expected. The optional out_num parameter specifies an integer where the the ac‐ tual number of instances should later be stored. It will range between zero and out_maxnum. It is initialized to zero by this function. Finally, the optional out_sts parameter specifies a single loca‐ tion where an integer status code for the overall fetch for this metric should be stored. Normally, this will be zero, even if no event field values were found (out_num would then be zero). Oth‐ er than a severe fetch error, one may see a PM_ERR_TOOBIG here if the number of fields actually encountered was larger than out_maxnum. Any errors subsequently encountered during fetching, unit/scale conversion, or casting, will result in the assignment of a sen‐ tinel value to the appropriate output pmAtomValue (see the ``UN‐ USUAL SITUATIONS'' section below). In addition, if the optional out_stss parameter was specified, a PMAPI error code will be stored in the appropriate position. As a review, only the pmfg, metric, field, out_type, and out_maxnum parameters are mandatory. Others may be NULL to indi‐ cate application disinterest. The normal function return code is zero. This function may fail in case of various lookup, type- and conversion- checking errors. Those are indicated with a negative return code. Extending a fetchgroup with the fetch timestamp int pmExtendFetchGroup_timestamp(pmFG pmfg, struct timeval *out_value); int pmExtendFetchGroup_timespec(pmFG pmfg, struct timespec *out_value); int pmExtendFetchGroup_timeval(pmFG pmfg, struct timeval *out_value); These functions register interest in the pmHighResResult time‐ stamp. If the out_value pointer is non-NULL, at every future pm‐ FetchGroup call, the corresponding result timestamp will be copied there. Fetching all metrics in a fetchgroup int pmFetchGroup(pmFG pmfg); This function performs one pmFetch on its private PMAPI context, including all the metrics that were registered via prior pmEx‐ tendFetchGroup_* calls. It runs all the data extraction and con‐ version operations necessary to populate all the requested output variables. The normal function return code is zero or positive, as per the underlying pmFetch function. This function may fail in case of severe fetch errors, which are indicated with a negative return code. In the case of per-metric availability or conversion errors, or severe fetch errors, output variables are reset to sentinel val‐ ues and individual error codes are set. PM_ERR_AGAIN signals rate-conversion failure due to lack of a previous value. However, temporarily absent metrics with discrete semantics are exempt from some sentinel/error processing: if a pmFetchGroup fails to collect a result for a discrete metric (pmHighResResult pmValueSet.numval==0), then the last seen valid value (if any) is retained. This is intended to ease the processing of sets of archives with a mixture of once- and repeatedly-sampled metrics. Clearing a fetchgroup int pmClearFetchGroup(pmFG pmfg); When the current fetch state of a fetchgroup is no longer needed, it may be explicitly reset with this function. It releases any dynamically stored state but keeps the private PMAPI context in‐ tact for subsequent use (i.e. no change to the context is made at all and the context remains at the current fetch offset). It frees any pointers such as indom instance names or strings that may have been stored in output variables. Destroying a fetchgroup int pmDestroyFetchGroup(pmFG pmfg); When the fetchgroup is no longer needed, it may be explicitly freed with this function. It releases any dynamically stored state, as well as the private PMAPI context. It clears frees any pointers such as indom instance names or strings that may have been stored in output variables.
The following program demonstrates fetchgroup usage. Run it with different $PCP_DISK_UNITS environment variables to see different unit/rate conversion in effect. #include <pcp/pmapi.h> #include <stdio.h> #define pcpassert(sts) \ while (sts<0) { fprintf(stderr, "%s\n", pmErrStr(sts)); exit(42); } int main() { pmFG fg; pmAtomValue v, v2; enum { v3_maxnum = 100 }; pmAtomValue v3_values[v3_maxnum]; char *v3_names[v3_maxnum]; int v3_stss[v3_maxnum]; unsigned int v3_num; int sts, i; char *diskunits = getenv("PCP_DISK_UNITS"); struct timeval t; sts = pmCreateFetchGroup(&fg, PM_CONTEXT_HOST, "local:"); pcpassert(sts); sts = pmExtendFetchGroup_item(fg, "kernel.all.load", "1 minute", NULL, &v, PM_TYPE_FLOAT, NULL); pcpassert(sts); sts = pmExtendFetchGroup_item(fg, "kernel.all.idletime", NULL, "hour", &v2, PM_TYPE_DOUBLE, NULL); pcpassert(sts); sts = pmExtendFetchGroup_indom(fg, "disk.dev.total", diskunits, NULL, v3_names, v3_values, PM_TYPE_STRING, v3_stss, v3_maxnum, &v3_num, NULL); pcpassert(sts); sts = pmExtendFetchGroup_timestamp(fg, &t); pcpassert(sts); for (i=0; i < 10; i++) { unsigned int j; char stamp[28]; sts = pmFetchGroup(fg); pcpassert(sts); printf("%s", pmCtime(&t.tv_sec, stamp)); printf("1-minute load: %f; idletime: %f h\n", v.f, v2.d); for (j=0; j < v3_num; j++) { if (v3_stss[j] == 0) printf("disk %s i/o operations (%s): %s\n", v3_names[j] ? v3_names[j] : "?", diskunits ? diskunits : "-", v3_values[j].cp); } sleep(1); } sts = pmDestroyFetchGroup(fg); pcpassert(sts); return 0; }
The fetchgroup API supports only the numeric, string and event metric types. Aggregates are rejected during pmExtendFetch‐ Group_*. Any strings supplied by the fetchgroup API to the application are "owned" by the API. The application should consider them read- only, so it should not modify them nor free them. Error codes are always negative integers, whether returned from fetchgroup functions as return value, or stored in out_sts type variables. Normal result codes are always zero. Because of the unique ways in which extracted data is shared be‐ tween the application and a fetchgroup, the functions in this API are not protected by the multi-threading mutexes conventional in other parts of PMAPI. Specifically, for any given pmFG, it is not safe to concurrently call two or more fetchgroup API func‐ tions, nor to traverse the registered output variables while calling one of the functions. Instead, the calling application must ensure that only one thread at a time uses these calls and the registered output variables. On the other hand, concurrency between different pmFG instances is unrestricted, because they share no global data. Any pointers passed to a successful pmFetchGroupExtent_* call must stay valid throughout the lifetime of the fetchgroup, since future pmFetchGroup calls may write into them.
The fetchgroup API offers several options for collecting diagnos‐ tics. Negative integer error codes may be returned from each function for serious conditions. In addition, each output pmAtomValue may have a corresponding in‐ teger variable, where pmFetchGroup can store per-metric per-in‐ stance error codes. As an alternative, per-metric per-instance error conditions are also signalled by setting the corresponding pmAtomValue to a sen‐ tinel value. If unambiguous and precise error detection is not required, this may be sufficient. The sentinel value is negative one for all integers (including unsigned integers - i.e. all bits are set), NaN for floating point types, a NULL pointer for strings, and 0.0s for the timestamp. The fetchgroup API guaran‐ tees that once an output pmAtomValue is registered (during a suc‐ cessful pmExtendFetchGroup_* call), it will be cleared to the sentinel value or to a valid converted metric value, from the time of registration until the pmDestroyFetchGroup call.
PMAPI(3), pmLookupName(3), pmFetchHighRes(3), pmParseUnitsStr(3), pmUseContext(3), pmRegisterDerived(3) and pmExtractValue(3).
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Pages that refer to this page: pmclient(1), pmapi(3), pmextractvalue(3), pmfetch(3)