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prometheus/rules/ast/printer.go

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12 KiB

// Copyright 2013 The Prometheus Authors
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
package ast
import (
"encoding/json"
"errors"
"fmt"
"reflect"
"sort"
"strings"
clientmodel "github.com/prometheus/client_golang/model"
"github.com/prometheus/prometheus/stats"
"github.com/prometheus/prometheus/storage/local"
"github.com/prometheus/prometheus/utility"
)
// OutputFormat is an enum for the possible output formats.
type OutputFormat int
// Possible output formats.
const (
Text OutputFormat = iota
JSON
)
const jsonFormatVersion = 1
func (opType BinOpType) String() string {
opTypeMap := map[BinOpType]string{
Add: "+",
Sub: "-",
Mul: "*",
Div: "/",
Mod: "%",
GT: ">",
LT: "<",
EQ: "==",
NE: "!=",
GE: ">=",
LE: "<=",
And: "AND",
Or: "OR",
}
return opTypeMap[opType]
}
func (aggrType AggrType) String() string {
aggrTypeMap := map[AggrType]string{
Sum: "SUM",
Avg: "AVG",
Min: "MIN",
Max: "MAX",
Count: "COUNT",
}
return aggrTypeMap[aggrType]
}
func (exprType ExprType) String() string {
exprTypeMap := map[ExprType]string{
ScalarType: "scalar",
VectorType: "vector",
MatrixType: "matrix",
StringType: "string",
}
return exprTypeMap[exprType]
}
func (vector Vector) String() string {
metricStrings := make([]string, 0, len(vector))
for _, sample := range vector {
metricStrings = append(metricStrings,
fmt.Sprintf("%s => %v @[%v]",
sample.Metric,
sample.Value, sample.Timestamp))
}
return strings.Join(metricStrings, "\n")
}
func (matrix Matrix) String() string {
metricStrings := make([]string, 0, len(matrix))
for _, sampleStream := range matrix {
metricName, hasName := sampleStream.Metric.Metric[clientmodel.MetricNameLabel]
numLabels := len(sampleStream.Metric.Metric)
if hasName {
numLabels--
}
labelStrings := make([]string, 0, numLabels)
for label, value := range sampleStream.Metric.Metric {
if label != clientmodel.MetricNameLabel {
labelStrings = append(labelStrings, fmt.Sprintf("%s=%q", label, value))
}
}
sort.Strings(labelStrings)
valueStrings := make([]string, 0, len(sampleStream.Values))
for _, value := range sampleStream.Values {
valueStrings = append(valueStrings,
fmt.Sprintf("\n%v @[%v]", value.Value, value.Timestamp))
}
metricStrings = append(metricStrings,
fmt.Sprintf("%s{%s} => %s",
metricName,
strings.Join(labelStrings, ", "),
strings.Join(valueStrings, ", ")))
}
sort.Strings(metricStrings)
return strings.Join(metricStrings, "\n")
}
// ErrorToJSON converts the given error into JSON.
func ErrorToJSON(err error) string {
errorStruct := struct {
Type string `json:"type"`
Value string `json:"value"`
Version int `json:"version"`
}{
Type: "error",
Value: err.Error(),
Version: jsonFormatVersion,
}
errorJSON, err := json.Marshal(errorStruct)
if err != nil {
return ""
}
return string(errorJSON)
}
// TypedValueToJSON converts the given data of type 'scalar',
// 'vector', or 'matrix' into its JSON representation.
func TypedValueToJSON(data interface{}, typeStr string) string {
dataStruct := struct {
Type string `json:"type"`
Value interface{} `json:"value"`
Version int `json:"version"`
}{
Type: typeStr,
Value: data,
Version: jsonFormatVersion,
}
dataJSON, err := json.Marshal(dataStruct)
if err != nil {
return ErrorToJSON(err)
}
return string(dataJSON)
}
// EvalToString evaluates the given node into a string of the given format.
func EvalToString(node Node, timestamp clientmodel.Timestamp, format OutputFormat, storage local.Storage, queryStats *stats.TimerGroup) string {
totalEvalTimer := queryStats.GetTimer(stats.TotalEvalTime).Start()
defer totalEvalTimer.Stop()
prepareTimer := queryStats.GetTimer(stats.TotalQueryPreparationTime).Start()
closer, err := prepareInstantQuery(node, timestamp, storage, queryStats)
prepareTimer.Stop()
if err != nil {
panic(err)
}
defer closer.Close()
evalTimer := queryStats.GetTimer(stats.InnerEvalTime).Start()
switch node.Type() {
case ScalarType:
scalar := node.(ScalarNode).Eval(timestamp)
evalTimer.Stop()
switch format {
case Text:
return fmt.Sprintf("scalar: %v @[%v]", scalar, timestamp)
case JSON:
return TypedValueToJSON(scalar, "scalar")
}
case VectorType:
vector := node.(VectorNode).Eval(timestamp)
evalTimer.Stop()
switch format {
case Text:
return vector.String()
case JSON:
return TypedValueToJSON(vector, "vector")
}
case MatrixType:
matrix := node.(MatrixNode).Eval(timestamp)
evalTimer.Stop()
switch format {
case Text:
return matrix.String()
case JSON:
return TypedValueToJSON(matrix, "matrix")
}
case StringType:
str := node.(StringNode).Eval(timestamp)
evalTimer.Stop()
switch format {
case Text:
return str
case JSON:
return TypedValueToJSON(str, "string")
}
}
panic("Switch didn't cover all node types")
}
// EvalToVector evaluates the given node into a Vector. Matrices aren't supported.
func EvalToVector(node Node, timestamp clientmodel.Timestamp, storage local.Storage, queryStats *stats.TimerGroup) (Vector, error) {
totalEvalTimer := queryStats.GetTimer(stats.TotalEvalTime).Start()
defer totalEvalTimer.Stop()
prepareTimer := queryStats.GetTimer(stats.TotalQueryPreparationTime).Start()
closer, err := prepareInstantQuery(node, timestamp, storage, queryStats)
prepareTimer.Stop()
if err != nil {
panic(err)
}
defer closer.Close()
evalTimer := queryStats.GetTimer(stats.InnerEvalTime).Start()
switch node.Type() {
case ScalarType:
scalar := node.(ScalarNode).Eval(timestamp)
evalTimer.Stop()
return Vector{&Sample{Value: scalar}}, nil
case VectorType:
vector := node.(VectorNode).Eval(timestamp)
evalTimer.Stop()
return vector, nil
case MatrixType:
return nil, errors.New("matrices not supported by EvalToVector")
case StringType:
str := node.(StringNode).Eval(timestamp)
evalTimer.Stop()
return Vector{
&Sample{
Metric: clientmodel.COWMetric{
Metric: clientmodel.Metric{
"__value__": clientmodel.LabelValue(str),
},
Copied: true,
},
},
}, nil
}
panic("Switch didn't cover all node types")
}
// NodeTreeToDotGraph returns a DOT representation of the scalar
// literal.
func (node *ScalarLiteral) NodeTreeToDotGraph() string {
return fmt.Sprintf("%#p[label=\"%v\"];\n", node, node.value)
}
func functionArgsToDotGraph(node Node, args []Node) string {
graph := ""
for _, arg := range args {
graph += fmt.Sprintf("%x -> %x;\n", reflect.ValueOf(node).Pointer(), reflect.ValueOf(arg).Pointer())
}
for _, arg := range args {
graph += arg.NodeTreeToDotGraph()
}
return graph
}
// NodeTreeToDotGraph returns a DOT representation of the function
// call.
func (node *ScalarFunctionCall) NodeTreeToDotGraph() string {
graph := fmt.Sprintf("%#p[label=\"%s\"];\n", node, node.function.name)
graph += functionArgsToDotGraph(node, node.args)
return graph
}
// NodeTreeToDotGraph returns a DOT representation of the expression.
func (node *ScalarArithExpr) NodeTreeToDotGraph() string {
nodeAddr := reflect.ValueOf(node).Pointer()
graph := fmt.Sprintf(
`
%x[label="%s"];
%x -> %x;
%x -> %x;
%s
%s
}`,
nodeAddr, node.opType,
nodeAddr, reflect.ValueOf(node.lhs).Pointer(),
nodeAddr, reflect.ValueOf(node.rhs).Pointer(),
node.lhs.NodeTreeToDotGraph(),
node.rhs.NodeTreeToDotGraph(),
)
return graph
}
// NodeTreeToDotGraph returns a DOT representation of the vector selector.
func (node *VectorSelector) NodeTreeToDotGraph() string {
return fmt.Sprintf("%#p[label=\"%s\"];\n", node, node)
}
// NodeTreeToDotGraph returns a DOT representation of the function
// call.
func (node *VectorFunctionCall) NodeTreeToDotGraph() string {
graph := fmt.Sprintf("%#p[label=\"%s\"];\n", node, node.function.name)
graph += functionArgsToDotGraph(node, node.args)
return graph
}
// NodeTreeToDotGraph returns a DOT representation of the vector
// aggregation.
func (node *VectorAggregation) NodeTreeToDotGraph() string {
groupByStrings := make([]string, 0, len(node.groupBy))
for _, label := range node.groupBy {
groupByStrings = append(groupByStrings, string(label))
}
graph := fmt.Sprintf("%#p[label=\"%s BY (%s)\"]\n",
node,
node.aggrType,
strings.Join(groupByStrings, ", "))
graph += fmt.Sprintf("%#p -> %x;\n", node, reflect.ValueOf(node.vector).Pointer())
graph += node.vector.NodeTreeToDotGraph()
return graph
}
// NodeTreeToDotGraph returns a DOT representation of the expression.
func (node *VectorArithExpr) NodeTreeToDotGraph() string {
nodeAddr := reflect.ValueOf(node).Pointer()
graph := fmt.Sprintf(
`
%x[label="%s"];
%x -> %x;
%x -> %x;
%s
%s
}`,
nodeAddr, node.opType,
nodeAddr, reflect.ValueOf(node.lhs).Pointer(),
nodeAddr, reflect.ValueOf(node.rhs).Pointer(),
node.lhs.NodeTreeToDotGraph(),
node.rhs.NodeTreeToDotGraph(),
)
return graph
}
// NodeTreeToDotGraph returns a DOT representation of the matrix
// selector.
func (node *MatrixSelector) NodeTreeToDotGraph() string {
return fmt.Sprintf("%#p[label=\"%s\"];\n", node, node)
}
// NodeTreeToDotGraph returns a DOT representation of the string
// literal.
func (node *StringLiteral) NodeTreeToDotGraph() string {
return fmt.Sprintf("%#p[label=\"'%q'\"];\n", node, node.str)
}
// NodeTreeToDotGraph returns a DOT representation of the function
// call.
func (node *StringFunctionCall) NodeTreeToDotGraph() string {
graph := fmt.Sprintf("%#p[label=\"%s\"];\n", node, node.function.name)
graph += functionArgsToDotGraph(node, node.args)
return graph
}
func (nodes Nodes) String() string {
nodeStrings := make([]string, 0, len(nodes))
for _, node := range nodes {
nodeStrings = append(nodeStrings, node.String())
}
return strings.Join(nodeStrings, ", ")
}
func (node *ScalarLiteral) String() string {
return fmt.Sprint(node.value)
}
func (node *ScalarFunctionCall) String() string {
return fmt.Sprintf("%s(%s)", node.function.name, node.args)
}
func (node *ScalarArithExpr) String() string {
return fmt.Sprintf("(%s %s %s)", node.lhs, node.opType, node.rhs)
}
func (node *VectorSelector) String() string {
labelStrings := make([]string, 0, len(node.labelMatchers)-1)
var metricName clientmodel.LabelValue
for _, matcher := range node.labelMatchers {
if matcher.Name != clientmodel.MetricNameLabel {
labelStrings = append(labelStrings, fmt.Sprintf("%s%s%q", matcher.Name, matcher.Type, matcher.Value))
} else {
metricName = matcher.Value
}
}
switch len(labelStrings) {
case 0:
return string(metricName)
default:
sort.Strings(labelStrings)
return fmt.Sprintf("%s{%s}", metricName, strings.Join(labelStrings, ","))
}
}
func (node *VectorFunctionCall) String() string {
return fmt.Sprintf("%s(%s)", node.function.name, node.args)
}
func (node *VectorAggregation) String() string {
aggrString := fmt.Sprintf("%s(%s)", node.aggrType, node.vector)
if len(node.groupBy) > 0 {
return fmt.Sprintf("%s BY (%s)", aggrString, node.groupBy)
}
return aggrString
}
func (node *VectorArithExpr) String() string {
return fmt.Sprintf("(%s %s %s)", node.lhs, node.opType, node.rhs)
}
func (node *MatrixSelector) String() string {
vectorString := (&VectorSelector{labelMatchers: node.labelMatchers}).String()
intervalString := fmt.Sprintf("[%s]", utility.DurationToString(node.interval))
return vectorString + intervalString
}
func (node *StringLiteral) String() string {
return fmt.Sprintf("%q", node.str)
}
func (node *StringFunctionCall) String() string {
return fmt.Sprintf("%s(%s)", node.function.name, node.args)
}