From cdd7ad020e165fe680703b6d3319b908b682fb7a Mon Sep 17 00:00:00 2001 From: Andrew Dolgov Date: Fri, 20 Oct 2023 17:12:29 +0300 Subject: jaeger-client -> opentelemetry --- .../Metrics/V1/ExponentialHistogramDataPoint.php | 718 +++++++++++++++++++++ 1 file changed, 718 insertions(+) create mode 100644 vendor/open-telemetry/gen-otlp-protobuf/Opentelemetry/Proto/Metrics/V1/ExponentialHistogramDataPoint.php (limited to 'vendor/open-telemetry/gen-otlp-protobuf/Opentelemetry/Proto/Metrics/V1/ExponentialHistogramDataPoint.php') diff --git a/vendor/open-telemetry/gen-otlp-protobuf/Opentelemetry/Proto/Metrics/V1/ExponentialHistogramDataPoint.php b/vendor/open-telemetry/gen-otlp-protobuf/Opentelemetry/Proto/Metrics/V1/ExponentialHistogramDataPoint.php new file mode 100644 index 000000000..62cb6f5d6 --- /dev/null +++ b/vendor/open-telemetry/gen-otlp-protobuf/Opentelemetry/Proto/Metrics/V1/ExponentialHistogramDataPoint.php @@ -0,0 +1,718 @@ +opentelemetry.proto.metrics.v1.ExponentialHistogramDataPoint + */ +class ExponentialHistogramDataPoint extends \Google\Protobuf\Internal\Message +{ + /** + * The set of key/value pairs that uniquely identify the timeseries from + * where this point belongs. The list may be empty (may contain 0 elements). + * Attribute keys MUST be unique (it is not allowed to have more than one + * attribute with the same key). + * + * Generated from protobuf field repeated .opentelemetry.proto.common.v1.KeyValue attributes = 1; + */ + private $attributes; + /** + * StartTimeUnixNano is optional but strongly encouraged, see the + * the detailed comments above Metric. + * Value is UNIX Epoch time in nanoseconds since 00:00:00 UTC on 1 January + * 1970. + * + * Generated from protobuf field fixed64 start_time_unix_nano = 2; + */ + protected $start_time_unix_nano = 0; + /** + * TimeUnixNano is required, see the detailed comments above Metric. + * Value is UNIX Epoch time in nanoseconds since 00:00:00 UTC on 1 January + * 1970. + * + * Generated from protobuf field fixed64 time_unix_nano = 3; + */ + protected $time_unix_nano = 0; + /** + * count is the number of values in the population. Must be + * non-negative. This value must be equal to the sum of the "bucket_counts" + * values in the positive and negative Buckets plus the "zero_count" field. + * + * Generated from protobuf field fixed64 count = 4; + */ + protected $count = 0; + /** + * sum of the values in the population. If count is zero then this field + * must be zero. + * Note: Sum should only be filled out when measuring non-negative discrete + * events, and is assumed to be monotonic over the values of these events. + * Negative events *can* be recorded, but sum should not be filled out when + * doing so. This is specifically to enforce compatibility w/ OpenMetrics, + * see: https://github.com/OpenObservability/OpenMetrics/blob/main/specification/OpenMetrics.md#histogram + * + * Generated from protobuf field optional double sum = 5; + */ + protected $sum = null; + /** + * scale describes the resolution of the histogram. Boundaries are + * located at powers of the base, where: + * base = (2^(2^-scale)) + * The histogram bucket identified by `index`, a signed integer, + * contains values that are greater than (base^index) and + * less than or equal to (base^(index+1)). + * The positive and negative ranges of the histogram are expressed + * separately. Negative values are mapped by their absolute value + * into the negative range using the same scale as the positive range. + * scale is not restricted by the protocol, as the permissible + * values depend on the range of the data. + * + * Generated from protobuf field sint32 scale = 6; + */ + protected $scale = 0; + /** + * zero_count is the count of values that are either exactly zero or + * within the region considered zero by the instrumentation at the + * tolerated degree of precision. This bucket stores values that + * cannot be expressed using the standard exponential formula as + * well as values that have been rounded to zero. + * Implementations MAY consider the zero bucket to have probability + * mass equal to (zero_count / count). + * + * Generated from protobuf field fixed64 zero_count = 7; + */ + protected $zero_count = 0; + /** + * positive carries the positive range of exponential bucket counts. + * + * Generated from protobuf field .opentelemetry.proto.metrics.v1.ExponentialHistogramDataPoint.Buckets positive = 8; + */ + protected $positive = null; + /** + * negative carries the negative range of exponential bucket counts. + * + * Generated from protobuf field .opentelemetry.proto.metrics.v1.ExponentialHistogramDataPoint.Buckets negative = 9; + */ + protected $negative = null; + /** + * Flags that apply to this specific data point. See DataPointFlags + * for the available flags and their meaning. + * + * Generated from protobuf field uint32 flags = 10; + */ + protected $flags = 0; + /** + * (Optional) List of exemplars collected from + * measurements that were used to form the data point + * + * Generated from protobuf field repeated .opentelemetry.proto.metrics.v1.Exemplar exemplars = 11; + */ + private $exemplars; + /** + * min is the minimum value over (start_time, end_time]. + * + * Generated from protobuf field optional double min = 12; + */ + protected $min = null; + /** + * max is the maximum value over (start_time, end_time]. + * + * Generated from protobuf field optional double max = 13; + */ + protected $max = null; + /** + * ZeroThreshold may be optionally set to convey the width of the zero + * region. Where the zero region is defined as the closed interval + * [-ZeroThreshold, ZeroThreshold]. + * When ZeroThreshold is 0, zero count bucket stores values that cannot be + * expressed using the standard exponential formula as well as values that + * have been rounded to zero. + * + * Generated from protobuf field double zero_threshold = 14; + */ + protected $zero_threshold = 0.0; + + /** + * Constructor. + * + * @param array $data { + * Optional. Data for populating the Message object. + * + * @type \Opentelemetry\Proto\Common\V1\KeyValue[]|\Google\Protobuf\Internal\RepeatedField $attributes + * The set of key/value pairs that uniquely identify the timeseries from + * where this point belongs. The list may be empty (may contain 0 elements). + * Attribute keys MUST be unique (it is not allowed to have more than one + * attribute with the same key). + * @type int|string $start_time_unix_nano + * StartTimeUnixNano is optional but strongly encouraged, see the + * the detailed comments above Metric. + * Value is UNIX Epoch time in nanoseconds since 00:00:00 UTC on 1 January + * 1970. + * @type int|string $time_unix_nano + * TimeUnixNano is required, see the detailed comments above Metric. + * Value is UNIX Epoch time in nanoseconds since 00:00:00 UTC on 1 January + * 1970. + * @type int|string $count + * count is the number of values in the population. Must be + * non-negative. This value must be equal to the sum of the "bucket_counts" + * values in the positive and negative Buckets plus the "zero_count" field. + * @type float $sum + * sum of the values in the population. If count is zero then this field + * must be zero. + * Note: Sum should only be filled out when measuring non-negative discrete + * events, and is assumed to be monotonic over the values of these events. + * Negative events *can* be recorded, but sum should not be filled out when + * doing so. This is specifically to enforce compatibility w/ OpenMetrics, + * see: https://github.com/OpenObservability/OpenMetrics/blob/main/specification/OpenMetrics.md#histogram + * @type int $scale + * scale describes the resolution of the histogram. Boundaries are + * located at powers of the base, where: + * base = (2^(2^-scale)) + * The histogram bucket identified by `index`, a signed integer, + * contains values that are greater than (base^index) and + * less than or equal to (base^(index+1)). + * The positive and negative ranges of the histogram are expressed + * separately. Negative values are mapped by their absolute value + * into the negative range using the same scale as the positive range. + * scale is not restricted by the protocol, as the permissible + * values depend on the range of the data. + * @type int|string $zero_count + * zero_count is the count of values that are either exactly zero or + * within the region considered zero by the instrumentation at the + * tolerated degree of precision. This bucket stores values that + * cannot be expressed using the standard exponential formula as + * well as values that have been rounded to zero. + * Implementations MAY consider the zero bucket to have probability + * mass equal to (zero_count / count). + * @type \Opentelemetry\Proto\Metrics\V1\ExponentialHistogramDataPoint\Buckets $positive + * positive carries the positive range of exponential bucket counts. + * @type \Opentelemetry\Proto\Metrics\V1\ExponentialHistogramDataPoint\Buckets $negative + * negative carries the negative range of exponential bucket counts. + * @type int $flags + * Flags that apply to this specific data point. See DataPointFlags + * for the available flags and their meaning. + * @type \Opentelemetry\Proto\Metrics\V1\Exemplar[]|\Google\Protobuf\Internal\RepeatedField $exemplars + * (Optional) List of exemplars collected from + * measurements that were used to form the data point + * @type float $min + * min is the minimum value over (start_time, end_time]. + * @type float $max + * max is the maximum value over (start_time, end_time]. + * @type float $zero_threshold + * ZeroThreshold may be optionally set to convey the width of the zero + * region. Where the zero region is defined as the closed interval + * [-ZeroThreshold, ZeroThreshold]. + * When ZeroThreshold is 0, zero count bucket stores values that cannot be + * expressed using the standard exponential formula as well as values that + * have been rounded to zero. + * } + */ + public function __construct($data = NULL) { + \GPBMetadata\Opentelemetry\Proto\Metrics\V1\Metrics::initOnce(); + parent::__construct($data); + } + + /** + * The set of key/value pairs that uniquely identify the timeseries from + * where this point belongs. The list may be empty (may contain 0 elements). + * Attribute keys MUST be unique (it is not allowed to have more than one + * attribute with the same key). + * + * Generated from protobuf field repeated .opentelemetry.proto.common.v1.KeyValue attributes = 1; + * @return \Google\Protobuf\Internal\RepeatedField + */ + public function getAttributes() + { + return $this->attributes; + } + + /** + * The set of key/value pairs that uniquely identify the timeseries from + * where this point belongs. The list may be empty (may contain 0 elements). + * Attribute keys MUST be unique (it is not allowed to have more than one + * attribute with the same key). + * + * Generated from protobuf field repeated .opentelemetry.proto.common.v1.KeyValue attributes = 1; + * @param \Opentelemetry\Proto\Common\V1\KeyValue[]|\Google\Protobuf\Internal\RepeatedField $var + * @return $this + */ + public function setAttributes($var) + { + $arr = GPBUtil::checkRepeatedField($var, \Google\Protobuf\Internal\GPBType::MESSAGE, \Opentelemetry\Proto\Common\V1\KeyValue::class); + $this->attributes = $arr; + + return $this; + } + + /** + * StartTimeUnixNano is optional but strongly encouraged, see the + * the detailed comments above Metric. + * Value is UNIX Epoch time in nanoseconds since 00:00:00 UTC on 1 January + * 1970. + * + * Generated from protobuf field fixed64 start_time_unix_nano = 2; + * @return int|string + */ + public function getStartTimeUnixNano() + { + return $this->start_time_unix_nano; + } + + /** + * StartTimeUnixNano is optional but strongly encouraged, see the + * the detailed comments above Metric. + * Value is UNIX Epoch time in nanoseconds since 00:00:00 UTC on 1 January + * 1970. + * + * Generated from protobuf field fixed64 start_time_unix_nano = 2; + * @param int|string $var + * @return $this + */ + public function setStartTimeUnixNano($var) + { + GPBUtil::checkUint64($var); + $this->start_time_unix_nano = $var; + + return $this; + } + + /** + * TimeUnixNano is required, see the detailed comments above Metric. + * Value is UNIX Epoch time in nanoseconds since 00:00:00 UTC on 1 January + * 1970. + * + * Generated from protobuf field fixed64 time_unix_nano = 3; + * @return int|string + */ + public function getTimeUnixNano() + { + return $this->time_unix_nano; + } + + /** + * TimeUnixNano is required, see the detailed comments above Metric. + * Value is UNIX Epoch time in nanoseconds since 00:00:00 UTC on 1 January + * 1970. + * + * Generated from protobuf field fixed64 time_unix_nano = 3; + * @param int|string $var + * @return $this + */ + public function setTimeUnixNano($var) + { + GPBUtil::checkUint64($var); + $this->time_unix_nano = $var; + + return $this; + } + + /** + * count is the number of values in the population. Must be + * non-negative. This value must be equal to the sum of the "bucket_counts" + * values in the positive and negative Buckets plus the "zero_count" field. + * + * Generated from protobuf field fixed64 count = 4; + * @return int|string + */ + public function getCount() + { + return $this->count; + } + + /** + * count is the number of values in the population. Must be + * non-negative. This value must be equal to the sum of the "bucket_counts" + * values in the positive and negative Buckets plus the "zero_count" field. + * + * Generated from protobuf field fixed64 count = 4; + * @param int|string $var + * @return $this + */ + public function setCount($var) + { + GPBUtil::checkUint64($var); + $this->count = $var; + + return $this; + } + + /** + * sum of the values in the population. If count is zero then this field + * must be zero. + * Note: Sum should only be filled out when measuring non-negative discrete + * events, and is assumed to be monotonic over the values of these events. + * Negative events *can* be recorded, but sum should not be filled out when + * doing so. This is specifically to enforce compatibility w/ OpenMetrics, + * see: https://github.com/OpenObservability/OpenMetrics/blob/main/specification/OpenMetrics.md#histogram + * + * Generated from protobuf field optional double sum = 5; + * @return float + */ + public function getSum() + { + return isset($this->sum) ? $this->sum : 0.0; + } + + public function hasSum() + { + return isset($this->sum); + } + + public function clearSum() + { + unset($this->sum); + } + + /** + * sum of the values in the population. If count is zero then this field + * must be zero. + * Note: Sum should only be filled out when measuring non-negative discrete + * events, and is assumed to be monotonic over the values of these events. + * Negative events *can* be recorded, but sum should not be filled out when + * doing so. This is specifically to enforce compatibility w/ OpenMetrics, + * see: https://github.com/OpenObservability/OpenMetrics/blob/main/specification/OpenMetrics.md#histogram + * + * Generated from protobuf field optional double sum = 5; + * @param float $var + * @return $this + */ + public function setSum($var) + { + GPBUtil::checkDouble($var); + $this->sum = $var; + + return $this; + } + + /** + * scale describes the resolution of the histogram. Boundaries are + * located at powers of the base, where: + * base = (2^(2^-scale)) + * The histogram bucket identified by `index`, a signed integer, + * contains values that are greater than (base^index) and + * less than or equal to (base^(index+1)). + * The positive and negative ranges of the histogram are expressed + * separately. Negative values are mapped by their absolute value + * into the negative range using the same scale as the positive range. + * scale is not restricted by the protocol, as the permissible + * values depend on the range of the data. + * + * Generated from protobuf field sint32 scale = 6; + * @return int + */ + public function getScale() + { + return $this->scale; + } + + /** + * scale describes the resolution of the histogram. Boundaries are + * located at powers of the base, where: + * base = (2^(2^-scale)) + * The histogram bucket identified by `index`, a signed integer, + * contains values that are greater than (base^index) and + * less than or equal to (base^(index+1)). + * The positive and negative ranges of the histogram are expressed + * separately. Negative values are mapped by their absolute value + * into the negative range using the same scale as the positive range. + * scale is not restricted by the protocol, as the permissible + * values depend on the range of the data. + * + * Generated from protobuf field sint32 scale = 6; + * @param int $var + * @return $this + */ + public function setScale($var) + { + GPBUtil::checkInt32($var); + $this->scale = $var; + + return $this; + } + + /** + * zero_count is the count of values that are either exactly zero or + * within the region considered zero by the instrumentation at the + * tolerated degree of precision. This bucket stores values that + * cannot be expressed using the standard exponential formula as + * well as values that have been rounded to zero. + * Implementations MAY consider the zero bucket to have probability + * mass equal to (zero_count / count). + * + * Generated from protobuf field fixed64 zero_count = 7; + * @return int|string + */ + public function getZeroCount() + { + return $this->zero_count; + } + + /** + * zero_count is the count of values that are either exactly zero or + * within the region considered zero by the instrumentation at the + * tolerated degree of precision. This bucket stores values that + * cannot be expressed using the standard exponential formula as + * well as values that have been rounded to zero. + * Implementations MAY consider the zero bucket to have probability + * mass equal to (zero_count / count). + * + * Generated from protobuf field fixed64 zero_count = 7; + * @param int|string $var + * @return $this + */ + public function setZeroCount($var) + { + GPBUtil::checkUint64($var); + $this->zero_count = $var; + + return $this; + } + + /** + * positive carries the positive range of exponential bucket counts. + * + * Generated from protobuf field .opentelemetry.proto.metrics.v1.ExponentialHistogramDataPoint.Buckets positive = 8; + * @return \Opentelemetry\Proto\Metrics\V1\ExponentialHistogramDataPoint\Buckets|null + */ + public function getPositive() + { + return $this->positive; + } + + public function hasPositive() + { + return isset($this->positive); + } + + public function clearPositive() + { + unset($this->positive); + } + + /** + * positive carries the positive range of exponential bucket counts. + * + * Generated from protobuf field .opentelemetry.proto.metrics.v1.ExponentialHistogramDataPoint.Buckets positive = 8; + * @param \Opentelemetry\Proto\Metrics\V1\ExponentialHistogramDataPoint\Buckets $var + * @return $this + */ + public function setPositive($var) + { + GPBUtil::checkMessage($var, \Opentelemetry\Proto\Metrics\V1\ExponentialHistogramDataPoint\Buckets::class); + $this->positive = $var; + + return $this; + } + + /** + * negative carries the negative range of exponential bucket counts. + * + * Generated from protobuf field .opentelemetry.proto.metrics.v1.ExponentialHistogramDataPoint.Buckets negative = 9; + * @return \Opentelemetry\Proto\Metrics\V1\ExponentialHistogramDataPoint\Buckets|null + */ + public function getNegative() + { + return $this->negative; + } + + public function hasNegative() + { + return isset($this->negative); + } + + public function clearNegative() + { + unset($this->negative); + } + + /** + * negative carries the negative range of exponential bucket counts. + * + * Generated from protobuf field .opentelemetry.proto.metrics.v1.ExponentialHistogramDataPoint.Buckets negative = 9; + * @param \Opentelemetry\Proto\Metrics\V1\ExponentialHistogramDataPoint\Buckets $var + * @return $this + */ + public function setNegative($var) + { + GPBUtil::checkMessage($var, \Opentelemetry\Proto\Metrics\V1\ExponentialHistogramDataPoint\Buckets::class); + $this->negative = $var; + + return $this; + } + + /** + * Flags that apply to this specific data point. See DataPointFlags + * for the available flags and their meaning. + * + * Generated from protobuf field uint32 flags = 10; + * @return int + */ + public function getFlags() + { + return $this->flags; + } + + /** + * Flags that apply to this specific data point. See DataPointFlags + * for the available flags and their meaning. + * + * Generated from protobuf field uint32 flags = 10; + * @param int $var + * @return $this + */ + public function setFlags($var) + { + GPBUtil::checkUint32($var); + $this->flags = $var; + + return $this; + } + + /** + * (Optional) List of exemplars collected from + * measurements that were used to form the data point + * + * Generated from protobuf field repeated .opentelemetry.proto.metrics.v1.Exemplar exemplars = 11; + * @return \Google\Protobuf\Internal\RepeatedField + */ + public function getExemplars() + { + return $this->exemplars; + } + + /** + * (Optional) List of exemplars collected from + * measurements that were used to form the data point + * + * Generated from protobuf field repeated .opentelemetry.proto.metrics.v1.Exemplar exemplars = 11; + * @param \Opentelemetry\Proto\Metrics\V1\Exemplar[]|\Google\Protobuf\Internal\RepeatedField $var + * @return $this + */ + public function setExemplars($var) + { + $arr = GPBUtil::checkRepeatedField($var, \Google\Protobuf\Internal\GPBType::MESSAGE, \Opentelemetry\Proto\Metrics\V1\Exemplar::class); + $this->exemplars = $arr; + + return $this; + } + + /** + * min is the minimum value over (start_time, end_time]. + * + * Generated from protobuf field optional double min = 12; + * @return float + */ + public function getMin() + { + return isset($this->min) ? $this->min : 0.0; + } + + public function hasMin() + { + return isset($this->min); + } + + public function clearMin() + { + unset($this->min); + } + + /** + * min is the minimum value over (start_time, end_time]. + * + * Generated from protobuf field optional double min = 12; + * @param float $var + * @return $this + */ + public function setMin($var) + { + GPBUtil::checkDouble($var); + $this->min = $var; + + return $this; + } + + /** + * max is the maximum value over (start_time, end_time]. + * + * Generated from protobuf field optional double max = 13; + * @return float + */ + public function getMax() + { + return isset($this->max) ? $this->max : 0.0; + } + + public function hasMax() + { + return isset($this->max); + } + + public function clearMax() + { + unset($this->max); + } + + /** + * max is the maximum value over (start_time, end_time]. + * + * Generated from protobuf field optional double max = 13; + * @param float $var + * @return $this + */ + public function setMax($var) + { + GPBUtil::checkDouble($var); + $this->max = $var; + + return $this; + } + + /** + * ZeroThreshold may be optionally set to convey the width of the zero + * region. Where the zero region is defined as the closed interval + * [-ZeroThreshold, ZeroThreshold]. + * When ZeroThreshold is 0, zero count bucket stores values that cannot be + * expressed using the standard exponential formula as well as values that + * have been rounded to zero. + * + * Generated from protobuf field double zero_threshold = 14; + * @return float + */ + public function getZeroThreshold() + { + return $this->zero_threshold; + } + + /** + * ZeroThreshold may be optionally set to convey the width of the zero + * region. Where the zero region is defined as the closed interval + * [-ZeroThreshold, ZeroThreshold]. + * When ZeroThreshold is 0, zero count bucket stores values that cannot be + * expressed using the standard exponential formula as well as values that + * have been rounded to zero. + * + * Generated from protobuf field double zero_threshold = 14; + * @param float $var + * @return $this + */ + public function setZeroThreshold($var) + { + GPBUtil::checkDouble($var); + $this->zero_threshold = $var; + + return $this; + } + +} + -- cgit v1.2.3