VictoriaMetrics/lib/metricsql/parser.go

1723 lines
41 KiB
Go

package metricsql
import (
"fmt"
"strconv"
"strings"
"sync"
)
// Parse parses MetricsQL query s.
//
// All the `WITH` expressions are expanded in the returned Expr.
//
// MetricsQL is backwards-compatible with PromQL.
func Parse(s string) (Expr, error) {
var p parser
p.lex.Init(s)
if err := p.lex.Next(); err != nil {
return nil, fmt.Errorf(`cannot find the first token: %s`, err)
}
e, err := p.parseExpr()
if err != nil {
return nil, fmt.Errorf(`%s; unparsed data: %q`, err, p.lex.Context())
}
if !isEOF(p.lex.Token) {
return nil, fmt.Errorf(`unparsed data left: %q`, p.lex.Context())
}
was := getDefaultWithArgExprs()
if e, err = expandWithExpr(was, e); err != nil {
return nil, fmt.Errorf(`cannot expand WITH expressions: %s`, err)
}
e = removeParensExpr(e)
e = simplifyConstants(e)
return e, nil
}
// Expr holds any of *Expr types.
type Expr interface {
// AppendString appends string representation of Expr to dst.
AppendString(dst []byte) []byte
}
func getDefaultWithArgExprs() []*withArgExpr {
defaultWithArgExprsOnce.Do(func() {
defaultWithArgExprs = prepareWithArgExprs([]string{
// ru - resource utilization
`ru(freev, maxv) = clamp_min(maxv - clamp_min(freev, 0), 0) / clamp_min(maxv, 0) * 100`,
// ttf - time to fuckup
`ttf(freev) = smooth_exponential(
clamp_max(clamp_max(-freev, 0) / clamp_max(deriv_fast(freev), 0), 365*24*3600),
clamp_max(step()/300, 1)
)`,
`median_over_time(m) = quantile_over_time(0.5, m)`,
`range_median(q) = range_quantile(0.5, q)`,
`alias(q, name) = label_set(q, "__name__", name)`,
})
})
return defaultWithArgExprs
}
var (
defaultWithArgExprs []*withArgExpr
defaultWithArgExprsOnce sync.Once
)
func prepareWithArgExprs(ss []string) []*withArgExpr {
was := make([]*withArgExpr, len(ss))
for i, s := range ss {
was[i] = mustParseWithArgExpr(s)
}
if err := checkDuplicateWithArgNames(was); err != nil {
panic(fmt.Errorf("BUG: %s", err))
}
return was
}
func checkDuplicateWithArgNames(was []*withArgExpr) error {
m := make(map[string]*withArgExpr, len(was))
for _, wa := range was {
if waOld := m[wa.Name]; waOld != nil {
return fmt.Errorf("duplicate `with` arg name for: %s; previous one: %s", wa, waOld.AppendString(nil))
}
m[wa.Name] = wa
}
return nil
}
func mustParseWithArgExpr(s string) *withArgExpr {
var p parser
p.lex.Init(s)
if err := p.lex.Next(); err != nil {
panic(fmt.Errorf("BUG: cannot find the first token in %q: %s", s, err))
}
wa, err := p.parseWithArgExpr()
if err != nil {
panic(fmt.Errorf("BUG: cannot parse %q: %s; unparsed data: %q", s, err, p.lex.Context()))
}
return wa
}
// removeParensExpr removes parensExpr for (Expr) case.
func removeParensExpr(e Expr) Expr {
if re, ok := e.(*RollupExpr); ok {
re.Expr = removeParensExpr(re.Expr)
return re
}
if be, ok := e.(*BinaryOpExpr); ok {
be.Left = removeParensExpr(be.Left)
be.Right = removeParensExpr(be.Right)
return be
}
if ae, ok := e.(*AggrFuncExpr); ok {
for i, arg := range ae.Args {
ae.Args[i] = removeParensExpr(arg)
}
return ae
}
if fe, ok := e.(*FuncExpr); ok {
for i, arg := range fe.Args {
fe.Args[i] = removeParensExpr(arg)
}
return fe
}
if pe, ok := e.(*parensExpr); ok {
args := *pe
for i, arg := range args {
args[i] = removeParensExpr(arg)
}
if len(*pe) == 1 {
return args[0]
}
// Treat parensExpr as a function with empty name, i.e. union()
fe := &FuncExpr{
Name: "",
Args: args,
}
return fe
}
return e
}
func simplifyConstants(e Expr) Expr {
if re, ok := e.(*RollupExpr); ok {
re.Expr = simplifyConstants(re.Expr)
return re
}
if ae, ok := e.(*AggrFuncExpr); ok {
simplifyConstantsInplace(ae.Args)
return ae
}
if fe, ok := e.(*FuncExpr); ok {
simplifyConstantsInplace(fe.Args)
return fe
}
if pe, ok := e.(*parensExpr); ok {
if len(*pe) == 1 {
return simplifyConstants((*pe)[0])
}
simplifyConstantsInplace(*pe)
return pe
}
be, ok := e.(*BinaryOpExpr)
if !ok {
return e
}
be.Left = simplifyConstants(be.Left)
be.Right = simplifyConstants(be.Right)
lne, ok := be.Left.(*NumberExpr)
if !ok {
return be
}
rne, ok := be.Right.(*NumberExpr)
if !ok {
return be
}
n := binaryOpEval(be.Op, lne.N, rne.N, be.Bool)
ne := &NumberExpr{
N: n,
}
return ne
}
func simplifyConstantsInplace(args []Expr) {
for i, arg := range args {
args[i] = simplifyConstants(arg)
}
}
// parser parses MetricsQL expression.
//
// preconditions for all parser.parse* funcs:
// - p.lex.Token should point to the first token to parse.
//
// postconditions for all parser.parse* funcs:
// - p.lex.Token should point to the next token after the parsed token.
type parser struct {
lex lexer
}
func isWith(s string) bool {
s = strings.ToLower(s)
return s == "with"
}
// parseWithExpr parses `WITH (withArgExpr...) expr`.
func (p *parser) parseWithExpr() (*withExpr, error) {
var we withExpr
if !isWith(p.lex.Token) {
return nil, fmt.Errorf("withExpr: unexpected token %q; want `WITH`", p.lex.Token)
}
if err := p.lex.Next(); err != nil {
return nil, err
}
if p.lex.Token != "(" {
return nil, fmt.Errorf(`withExpr: unexpected token %q; want "("`, p.lex.Token)
}
for {
if err := p.lex.Next(); err != nil {
return nil, err
}
if p.lex.Token == ")" {
goto end
}
wa, err := p.parseWithArgExpr()
if err != nil {
return nil, err
}
we.Was = append(we.Was, wa)
switch p.lex.Token {
case ",":
continue
case ")":
goto end
default:
return nil, fmt.Errorf(`withExpr: unexpected token %q; want ",", ")"`, p.lex.Token)
}
}
end:
if err := checkDuplicateWithArgNames(we.Was); err != nil {
return nil, err
}
if err := p.lex.Next(); err != nil {
return nil, err
}
e, err := p.parseExpr()
if err != nil {
return nil, err
}
we.Expr = e
return &we, nil
}
func (p *parser) parseWithArgExpr() (*withArgExpr, error) {
var wa withArgExpr
if !isIdentPrefix(p.lex.Token) {
return nil, fmt.Errorf(`withArgExpr: unexpected token %q; want "ident"`, p.lex.Token)
}
wa.Name = p.lex.Token
if isAggrFunc(wa.Name) || IsRollupFunc(wa.Name) || IsTransformFunc(wa.Name) || isWith(wa.Name) {
return nil, fmt.Errorf(`withArgExpr: cannot use reserved name %q`, wa.Name)
}
if err := p.lex.Next(); err != nil {
return nil, err
}
if p.lex.Token == "(" {
// Parse func args.
args, err := p.parseIdentList()
if err != nil {
return nil, fmt.Errorf(`withArgExpr: cannot parse args for %q: %s`, wa.Name, err)
}
// Make sure all the args have different names
m := make(map[string]bool, len(args))
for _, arg := range args {
if m[arg] {
return nil, fmt.Errorf(`withArgExpr: duplicate func arg found in %q: %q`, wa.Name, arg)
}
m[arg] = true
}
wa.Args = args
}
if p.lex.Token != "=" {
return nil, fmt.Errorf(`withArgExpr: unexpected token %q; want "="`, p.lex.Token)
}
if err := p.lex.Next(); err != nil {
return nil, err
}
e, err := p.parseExpr()
if err != nil {
return nil, fmt.Errorf(`withArgExpr: cannot parse %q: %s`, wa.Name, err)
}
wa.Expr = e
return &wa, nil
}
func (p *parser) parseExpr() (Expr, error) {
e, err := p.parseSingleExpr()
if err != nil {
return nil, err
}
for {
if !isBinaryOp(p.lex.Token) {
return e, nil
}
var be BinaryOpExpr
be.Op = strings.ToLower(p.lex.Token)
be.Left = e
if err := p.lex.Next(); err != nil {
return nil, err
}
if isBinaryOpBoolModifier(p.lex.Token) {
if !IsBinaryOpCmp(be.Op) {
return nil, fmt.Errorf(`bool modifier cannot be applied to %q`, be.Op)
}
be.Bool = true
if err := p.lex.Next(); err != nil {
return nil, err
}
}
if isBinaryOpGroupModifier(p.lex.Token) {
if err := p.parseModifierExpr(&be.GroupModifier); err != nil {
return nil, err
}
if isBinaryOpJoinModifier(p.lex.Token) {
if isBinaryOpLogicalSet(be.Op) {
return nil, fmt.Errorf(`modifier %q cannot be applied to %q`, p.lex.Token, be.Op)
}
if err := p.parseModifierExpr(&be.JoinModifier); err != nil {
return nil, err
}
}
}
e2, err := p.parseSingleExpr()
if err != nil {
return nil, err
}
be.Right = e2
e = balanceBinaryOp(&be)
}
}
func balanceBinaryOp(be *BinaryOpExpr) Expr {
bel, ok := be.Left.(*BinaryOpExpr)
if !ok {
return be
}
lp := binaryOpPriority(bel.Op)
rp := binaryOpPriority(be.Op)
if rp < lp {
return be
}
if rp == lp && !isRightAssociativeBinaryOp(be.Op) {
return be
}
be.Left = bel.Right
bel.Right = balanceBinaryOp(be)
return bel
}
// parseSingleExpr parses non-binaryOp expressions.
func (p *parser) parseSingleExpr() (Expr, error) {
if isWith(p.lex.Token) {
err := p.lex.Next()
nextToken := p.lex.Token
p.lex.Prev()
if err == nil && nextToken == "(" {
return p.parseWithExpr()
}
}
e, err := p.parseSingleExprWithoutRollupSuffix()
if err != nil {
return nil, err
}
if p.lex.Token != "[" && !isOffset(p.lex.Token) {
// There is no rollup expression.
return e, nil
}
return p.parseRollupExpr(e)
}
func (p *parser) parseSingleExprWithoutRollupSuffix() (Expr, error) {
if isPositiveNumberPrefix(p.lex.Token) || isInfOrNaN(p.lex.Token) {
return p.parsePositiveNumberExpr()
}
if isStringPrefix(p.lex.Token) {
return p.parseStringExpr()
}
if isIdentPrefix(p.lex.Token) {
return p.parseIdentExpr()
}
switch p.lex.Token {
case "(":
return p.parseParensExpr()
case "{":
return p.parseMetricExpr()
case "-":
// Unary minus. Substitute -expr with (0 - expr)
if err := p.lex.Next(); err != nil {
return nil, err
}
e, err := p.parseSingleExpr()
if err != nil {
return nil, err
}
be := &BinaryOpExpr{
Op: "-",
Left: &NumberExpr{
N: 0,
},
Right: e,
}
pe := parensExpr{be}
return &pe, nil
case "+":
// Unary plus
if err := p.lex.Next(); err != nil {
return nil, err
}
return p.parseSingleExpr()
default:
return nil, fmt.Errorf(`singleExpr: unexpected token %q; want "(", "{", "-", "+"`, p.lex.Token)
}
}
func (p *parser) parsePositiveNumberExpr() (*NumberExpr, error) {
if !isPositiveNumberPrefix(p.lex.Token) && !isInfOrNaN(p.lex.Token) {
return nil, fmt.Errorf(`positiveNumberExpr: unexpected token %q; want "number"`, p.lex.Token)
}
n, err := strconv.ParseFloat(p.lex.Token, 64)
if err != nil {
return nil, fmt.Errorf(`positiveNumberExpr: cannot parse %q: %s`, p.lex.Token, err)
}
if err := p.lex.Next(); err != nil {
return nil, err
}
ne := &NumberExpr{
N: n,
}
return ne, nil
}
func (p *parser) parseStringExpr() (*StringExpr, error) {
var se StringExpr
for {
switch {
case isStringPrefix(p.lex.Token) || isIdentPrefix(p.lex.Token):
se.tokens = append(se.tokens, p.lex.Token)
default:
return nil, fmt.Errorf(`StringExpr: unexpected token %q; want "string"`, p.lex.Token)
}
if err := p.lex.Next(); err != nil {
return nil, err
}
if p.lex.Token != "+" {
return &se, nil
}
// composite StringExpr like `"s1" + "s2"`, `"s" + m()` or `"s" + m{}` or `"s" + unknownToken`.
if err := p.lex.Next(); err != nil {
return nil, err
}
if isStringPrefix(p.lex.Token) {
// "s1" + "s2"
continue
}
if !isIdentPrefix(p.lex.Token) {
// "s" + unknownToken
p.lex.Prev()
return &se, nil
}
// Look after ident
if err := p.lex.Next(); err != nil {
return nil, err
}
if p.lex.Token == "(" || p.lex.Token == "{" {
// `"s" + m(` or `"s" + m{`
p.lex.Prev()
p.lex.Prev()
return &se, nil
}
// "s" + ident
p.lex.Prev()
}
}
func (p *parser) parseParensExpr() (*parensExpr, error) {
if p.lex.Token != "(" {
return nil, fmt.Errorf(`parensExpr: unexpected token %q; want "("`, p.lex.Token)
}
var exprs []Expr
for {
if err := p.lex.Next(); err != nil {
return nil, err
}
if p.lex.Token == ")" {
break
}
expr, err := p.parseExpr()
if err != nil {
return nil, err
}
exprs = append(exprs, expr)
if p.lex.Token == "," {
continue
}
if p.lex.Token == ")" {
break
}
return nil, fmt.Errorf(`parensExpr: unexpected token %q; want "," or ")"`, p.lex.Token)
}
if err := p.lex.Next(); err != nil {
return nil, err
}
pe := parensExpr(exprs)
return &pe, nil
}
func (p *parser) parseAggrFuncExpr() (*AggrFuncExpr, error) {
if !isAggrFunc(p.lex.Token) {
return nil, fmt.Errorf(`AggrFuncExpr: unexpected token %q; want aggregate func`, p.lex.Token)
}
var ae AggrFuncExpr
ae.Name = strings.ToLower(p.lex.Token)
if err := p.lex.Next(); err != nil {
return nil, err
}
if isIdentPrefix(p.lex.Token) {
goto funcPrefixLabel
}
switch p.lex.Token {
case "(":
goto funcArgsLabel
default:
return nil, fmt.Errorf(`AggrFuncExpr: unexpected token %q; want "("`, p.lex.Token)
}
funcPrefixLabel:
{
if !isAggrFuncModifier(p.lex.Token) {
return nil, fmt.Errorf(`AggrFuncExpr: unexpected token %q; want aggregate func modifier`, p.lex.Token)
}
if err := p.parseModifierExpr(&ae.Modifier); err != nil {
return nil, err
}
goto funcArgsLabel
}
funcArgsLabel:
{
args, err := p.parseArgListExpr()
if err != nil {
return nil, err
}
ae.Args = args
// Verify whether func suffix exists.
if ae.Modifier.Op != "" || !isAggrFuncModifier(p.lex.Token) {
return &ae, nil
}
if err := p.parseModifierExpr(&ae.Modifier); err != nil {
return nil, err
}
return &ae, nil
}
}
func expandWithExpr(was []*withArgExpr, e Expr) (Expr, error) {
switch t := e.(type) {
case *BinaryOpExpr:
left, err := expandWithExpr(was, t.Left)
if err != nil {
return nil, err
}
right, err := expandWithExpr(was, t.Right)
if err != nil {
return nil, err
}
groupModifierArgs, err := expandModifierArgs(was, t.GroupModifier.Args)
if err != nil {
return nil, err
}
joinModifierArgs, err := expandModifierArgs(was, t.JoinModifier.Args)
if err != nil {
return nil, err
}
if t.Op == "+" {
lse, lok := left.(*StringExpr)
rse, rok := right.(*StringExpr)
if lok && rok {
se := &StringExpr{
S: lse.S + rse.S,
}
return se, nil
}
}
be := &BinaryOpExpr{
Op: t.Op,
Bool: t.Bool,
GroupModifier: t.GroupModifier,
JoinModifier: t.JoinModifier,
Left: left,
Right: right,
}
be.GroupModifier.Args = groupModifierArgs
be.JoinModifier.Args = joinModifierArgs
pe := parensExpr{be}
return &pe, nil
case *FuncExpr:
args, err := expandWithArgs(was, t.Args)
if err != nil {
return nil, err
}
wa := getWithArgExpr(was, t.Name)
if wa == nil {
fe := &FuncExpr{
Name: t.Name,
Args: args,
}
return fe, nil
}
return expandWithExprExt(was, wa, args)
case *AggrFuncExpr:
args, err := expandWithArgs(was, t.Args)
if err != nil {
return nil, err
}
modifierArgs, err := expandModifierArgs(was, t.Modifier.Args)
if err != nil {
return nil, err
}
ae := &AggrFuncExpr{
Name: t.Name,
Args: args,
Modifier: t.Modifier,
}
ae.Modifier.Args = modifierArgs
return ae, nil
case *parensExpr:
exprs, err := expandWithArgs(was, *t)
if err != nil {
return nil, err
}
pe := parensExpr(exprs)
return &pe, nil
case *StringExpr:
if len(t.S) > 0 {
// Already expanded.
return t, nil
}
var b []byte
for _, token := range t.tokens {
if isStringPrefix(token) {
s, err := extractStringValue(token)
if err != nil {
return nil, err
}
b = append(b, s...)
continue
}
wa := getWithArgExpr(was, token)
if wa == nil {
return nil, fmt.Errorf("missing %q value inside StringExpr", token)
}
eNew, err := expandWithExprExt(was, wa, nil)
if err != nil {
return nil, err
}
seSrc, ok := eNew.(*StringExpr)
if !ok {
return nil, fmt.Errorf("%q must be string expression; got %q", token, eNew.AppendString(nil))
}
if len(seSrc.tokens) > 0 {
panic(fmt.Errorf("BUG: seSrc.tokens must be empty; got %q", seSrc.tokens))
}
b = append(b, seSrc.S...)
}
se := &StringExpr{
S: string(b),
}
return se, nil
case *RollupExpr:
eNew, err := expandWithExpr(was, t.Expr)
if err != nil {
return nil, err
}
re := *t
re.Expr = eNew
return &re, nil
case *withExpr:
wasNew := make([]*withArgExpr, 0, len(was)+len(t.Was))
wasNew = append(wasNew, was...)
wasNew = append(wasNew, t.Was...)
eNew, err := expandWithExpr(wasNew, t.Expr)
if err != nil {
return nil, err
}
return eNew, nil
case *MetricExpr:
if len(t.LabelFilters) > 0 {
// Already expanded.
return t, nil
}
{
var me MetricExpr
// Populate me.LabelFilters
for _, lfe := range t.labelFilters {
if lfe.Value == nil {
// Expand lfe.Label into []LabelFilter.
wa := getWithArgExpr(was, lfe.Label)
if wa == nil {
return nil, fmt.Errorf("missing %q value inside %q", lfe.Label, t.AppendString(nil))
}
eNew, err := expandWithExprExt(was, wa, nil)
if err != nil {
return nil, err
}
wme, ok := eNew.(*MetricExpr)
if !ok || wme.hasNonEmptyMetricGroup() {
return nil, fmt.Errorf("%q must be filters expression inside %q; got %q", lfe.Label, t.AppendString(nil), eNew.AppendString(nil))
}
if len(wme.labelFilters) > 0 {
panic(fmt.Errorf("BUG: wme.labelFilters must be empty; got %s", wme.labelFilters))
}
me.LabelFilters = append(me.LabelFilters, wme.LabelFilters...)
continue
}
// convert lfe to LabelFilter.
se, err := expandWithExpr(was, lfe.Value)
if err != nil {
return nil, err
}
var lfeNew labelFilterExpr
lfeNew.Label = lfe.Label
lfeNew.Value = se.(*StringExpr)
lfeNew.IsNegative = lfe.IsNegative
lfeNew.IsRegexp = lfe.IsRegexp
lf, err := lfeNew.toLabelFilter()
if err != nil {
return nil, err
}
me.LabelFilters = append(me.LabelFilters, *lf)
}
me.LabelFilters = removeDuplicateLabelFilters(me.LabelFilters)
t = &me
}
if !t.hasNonEmptyMetricGroup() {
return t, nil
}
k := string(appendEscapedIdent(nil, t.LabelFilters[0].Value))
wa := getWithArgExpr(was, k)
if wa == nil {
return t, nil
}
eNew, err := expandWithExprExt(was, wa, nil)
if err != nil {
return nil, err
}
var wme *MetricExpr
re, _ := eNew.(*RollupExpr)
if re != nil {
wme, _ = re.Expr.(*MetricExpr)
} else {
wme, _ = eNew.(*MetricExpr)
}
if wme == nil {
if !t.isOnlyMetricGroup() {
return nil, fmt.Errorf("cannot expand %q to non-metric expression %q", t.AppendString(nil), eNew.AppendString(nil))
}
return eNew, nil
}
if len(wme.labelFilters) > 0 {
panic(fmt.Errorf("BUG: wme.labelFilters must be empty; got %s", wme.labelFilters))
}
var me MetricExpr
me.LabelFilters = append(me.LabelFilters, wme.LabelFilters...)
me.LabelFilters = append(me.LabelFilters, t.LabelFilters[1:]...)
me.LabelFilters = removeDuplicateLabelFilters(me.LabelFilters)
if re == nil {
return &me, nil
}
reNew := *re
reNew.Expr = &me
return &reNew, nil
default:
return e, nil
}
}
func expandWithArgs(was []*withArgExpr, args []Expr) ([]Expr, error) {
dstArgs := make([]Expr, len(args))
for i, arg := range args {
dstArg, err := expandWithExpr(was, arg)
if err != nil {
return nil, err
}
dstArgs[i] = dstArg
}
return dstArgs, nil
}
func expandModifierArgs(was []*withArgExpr, args []string) ([]string, error) {
if len(args) == 0 {
return nil, nil
}
dstArgs := make([]string, 0, len(args))
for _, arg := range args {
wa := getWithArgExpr(was, arg)
if wa == nil {
// Leave the arg as is.
dstArgs = append(dstArgs, arg)
continue
}
if len(wa.Args) > 0 {
// Template funcs cannot be used inside modifier list. Leave the arg as is.
dstArgs = append(dstArgs, arg)
continue
}
me, ok := wa.Expr.(*MetricExpr)
if ok {
if !me.isOnlyMetricGroup() {
return nil, fmt.Errorf("cannot use %q instead of %q in %s", me.AppendString(nil), arg, args)
}
dstArg := me.LabelFilters[0].Value
dstArgs = append(dstArgs, dstArg)
continue
}
pe, ok := wa.Expr.(*parensExpr)
if ok {
for _, pArg := range *pe {
me, ok := pArg.(*MetricExpr)
if !ok || !me.isOnlyMetricGroup() {
return nil, fmt.Errorf("cannot use %q instead of %q in %s", pe.AppendString(nil), arg, args)
}
dstArg := me.LabelFilters[0].Value
dstArgs = append(dstArgs, dstArg)
}
continue
}
return nil, fmt.Errorf("cannot use %q instead of %q in %s", wa.Expr.AppendString(nil), arg, args)
}
// Remove duplicate args from dstArgs
m := make(map[string]bool, len(dstArgs))
filteredArgs := dstArgs[:0]
for _, arg := range dstArgs {
if !m[arg] {
filteredArgs = append(filteredArgs, arg)
m[arg] = true
}
}
return filteredArgs, nil
}
func expandWithExprExt(was []*withArgExpr, wa *withArgExpr, args []Expr) (Expr, error) {
if len(wa.Args) != len(args) {
if args == nil {
// Just return MetricExpr with the wa.Name name.
return newMetricExpr(wa.Name), nil
}
return nil, fmt.Errorf("invalid number of args for %q; got %d; want %d", wa.Name, len(args), len(wa.Args))
}
wasNew := make([]*withArgExpr, 0, len(was)+len(args))
for _, waTmp := range was {
if waTmp == wa {
break
}
wasNew = append(wasNew, waTmp)
}
for i, arg := range args {
wasNew = append(wasNew, &withArgExpr{
Name: wa.Args[i],
Expr: arg,
})
}
return expandWithExpr(wasNew, wa.Expr)
}
func newMetricExpr(name string) *MetricExpr {
return &MetricExpr{
LabelFilters: []LabelFilter{{
Label: "__name__",
Value: name,
}},
}
}
func extractStringValue(token string) (string, error) {
if !isStringPrefix(token) {
return "", fmt.Errorf(`StringExpr must contain only string literals; got %q`, token)
}
// See https://prometheus.io/docs/prometheus/latest/querying/basics/#string-literals
if token[0] == '\'' {
if len(token) < 2 || token[len(token)-1] != '\'' {
return "", fmt.Errorf(`string literal contains unexpected trailing char; got %q`, token)
}
token = token[1 : len(token)-1]
token = strings.Replace(token, "\\'", "'", -1)
token = strings.Replace(token, `"`, `\"`, -1)
token = `"` + token + `"`
}
s, err := strconv.Unquote(token)
if err != nil {
return "", fmt.Errorf(`cannot parse string literal %q: %s`, token, err)
}
return s, nil
}
func removeDuplicateLabelFilters(lfs []LabelFilter) []LabelFilter {
lfsm := make(map[string]bool, len(lfs))
lfsNew := lfs[:0]
var buf []byte
for i := range lfs {
lf := &lfs[i]
buf = lf.AppendString(buf[:0])
if lfsm[string(buf)] {
continue
}
lfsm[string(buf)] = true
lfsNew = append(lfsNew, *lf)
}
return lfsNew
}
func (p *parser) parseFuncExpr() (*FuncExpr, error) {
if !isIdentPrefix(p.lex.Token) {
return nil, fmt.Errorf(`FuncExpr: unexpected token %q; want "ident"`, p.lex.Token)
}
var fe FuncExpr
fe.Name = p.lex.Token
if err := p.lex.Next(); err != nil {
return nil, err
}
if p.lex.Token != "(" {
return nil, fmt.Errorf(`FuncExpr; unexpected token %q; want "("`, p.lex.Token)
}
args, err := p.parseArgListExpr()
if err != nil {
return nil, err
}
fe.Args = args
return &fe, nil
}
func (p *parser) parseModifierExpr(me *ModifierExpr) error {
if !isIdentPrefix(p.lex.Token) {
return fmt.Errorf(`ModifierExpr: unexpected token %q; want "ident"`, p.lex.Token)
}
me.Op = strings.ToLower(p.lex.Token)
if err := p.lex.Next(); err != nil {
return err
}
if isBinaryOpJoinModifier(me.Op) && p.lex.Token != "(" {
// join modifier may miss ident list.
return nil
}
args, err := p.parseIdentList()
if err != nil {
return err
}
me.Args = args
return nil
}
func (p *parser) parseIdentList() ([]string, error) {
if p.lex.Token != "(" {
return nil, fmt.Errorf(`identList: unexpected token %q; want "("`, p.lex.Token)
}
var idents []string
for {
if err := p.lex.Next(); err != nil {
return nil, err
}
if p.lex.Token == ")" {
goto closeParensLabel
}
if !isIdentPrefix(p.lex.Token) {
return nil, fmt.Errorf(`identList: unexpected token %q; want "ident"`, p.lex.Token)
}
idents = append(idents, p.lex.Token)
if err := p.lex.Next(); err != nil {
return nil, err
}
switch p.lex.Token {
case ",":
continue
case ")":
goto closeParensLabel
default:
return nil, fmt.Errorf(`identList: unexpected token %q; want ",", ")"`, p.lex.Token)
}
}
closeParensLabel:
if err := p.lex.Next(); err != nil {
return nil, err
}
return idents, nil
}
func (p *parser) parseArgListExpr() ([]Expr, error) {
if p.lex.Token != "(" {
return nil, fmt.Errorf(`argList: unexpected token %q; want "("`, p.lex.Token)
}
var args []Expr
for {
if err := p.lex.Next(); err != nil {
return nil, err
}
if p.lex.Token == ")" {
goto closeParensLabel
}
expr, err := p.parseExpr()
if err != nil {
return nil, err
}
args = append(args, expr)
switch p.lex.Token {
case ",":
continue
case ")":
goto closeParensLabel
default:
return nil, fmt.Errorf(`argList: unexpected token %q; want ",", ")"`, p.lex.Token)
}
}
closeParensLabel:
if err := p.lex.Next(); err != nil {
return nil, err
}
return args, nil
}
func getWithArgExpr(was []*withArgExpr, name string) *withArgExpr {
// Scan wes backwards, since certain expressions may override
// previously defined expressions
for i := len(was) - 1; i >= 0; i-- {
wa := was[i]
if wa.Name == name {
return wa
}
}
return nil
}
func (p *parser) parseLabelFilters() ([]*labelFilterExpr, error) {
if p.lex.Token != "{" {
return nil, fmt.Errorf(`labelFilters: unexpected token %q; want "{"`, p.lex.Token)
}
var lfes []*labelFilterExpr
for {
if err := p.lex.Next(); err != nil {
return nil, err
}
if p.lex.Token == "}" {
goto closeBracesLabel
}
lfe, err := p.parseLabelFilterExpr()
if err != nil {
return nil, err
}
lfes = append(lfes, lfe)
switch p.lex.Token {
case ",":
continue
case "}":
goto closeBracesLabel
default:
return nil, fmt.Errorf(`labelFilters: unexpected token %q; want ",", "}"`, p.lex.Token)
}
}
closeBracesLabel:
if err := p.lex.Next(); err != nil {
return nil, err
}
return lfes, nil
}
func (p *parser) parseLabelFilterExpr() (*labelFilterExpr, error) {
if !isIdentPrefix(p.lex.Token) {
return nil, fmt.Errorf(`labelFilterExpr: unexpected token %q; want "ident"`, p.lex.Token)
}
var lfe labelFilterExpr
lfe.Label = p.lex.Token
if err := p.lex.Next(); err != nil {
return nil, err
}
switch p.lex.Token {
case "=":
// Nothing to do.
case "!=":
lfe.IsNegative = true
case "=~":
lfe.IsRegexp = true
case "!~":
lfe.IsNegative = true
lfe.IsRegexp = true
case ",", "}":
return &lfe, nil
default:
return nil, fmt.Errorf(`labelFilterExpr: unexpected token %q; want "=", "!=", "=~", "!~", ",", "}"`, p.lex.Token)
}
if err := p.lex.Next(); err != nil {
return nil, err
}
se, err := p.parseStringExpr()
if err != nil {
return nil, err
}
lfe.Value = se
return &lfe, nil
}
// labelFilterExpr represents `foo <op> "bar"` expression, where <op> is `=`, `!=`, `=~` or `!~`.
//
// This type isn't exported.
type labelFilterExpr struct {
Label string
Value *StringExpr
IsRegexp bool
IsNegative bool
}
func (lfe *labelFilterExpr) String() string {
return fmt.Sprintf("[label=%q, value=%+v, isRegexp=%v, isNegative=%v]", lfe.Label, lfe.Value, lfe.IsRegexp, lfe.IsNegative)
}
func (lfe *labelFilterExpr) toLabelFilter() (*LabelFilter, error) {
if lfe.Value == nil || len(lfe.Value.tokens) > 0 {
panic(fmt.Errorf("BUG: lfe.Value must be already expanded; got %v", lfe.Value))
}
var lf LabelFilter
lf.Label = unescapeIdent(lfe.Label)
if lf.Label == "__name__" {
lf.Value = unescapeIdent(lfe.Value.S)
} else {
lf.Value = lfe.Value.S
}
lf.IsRegexp = lfe.IsRegexp
lf.IsNegative = lfe.IsNegative
if !lf.IsRegexp {
return &lf, nil
}
// Verify regexp.
if _, err := CompileRegexpAnchored(lfe.Value.S); err != nil {
return nil, fmt.Errorf("invalid regexp in %s=%q: %s", lf.Label, lf.Value, err)
}
return &lf, nil
}
func (p *parser) parseWindowAndStep() (string, string, bool, error) {
if p.lex.Token != "[" {
return "", "", false, fmt.Errorf(`windowAndStep: unexpected token %q; want "["`, p.lex.Token)
}
err := p.lex.Next()
if err != nil {
return "", "", false, err
}
var window string
if !strings.HasPrefix(p.lex.Token, ":") {
window, err = p.parsePositiveDuration()
if err != nil {
return "", "", false, err
}
}
var step string
inheritStep := false
if strings.HasPrefix(p.lex.Token, ":") {
// Parse step
p.lex.Token = p.lex.Token[1:]
if p.lex.Token == "" {
if err := p.lex.Next(); err != nil {
return "", "", false, err
}
if p.lex.Token == "]" {
inheritStep = true
}
}
if p.lex.Token != "]" {
step, err = p.parsePositiveDuration()
if err != nil {
return "", "", false, err
}
}
}
if p.lex.Token != "]" {
return "", "", false, fmt.Errorf(`windowAndStep: unexpected token %q; want "]"`, p.lex.Token)
}
if err := p.lex.Next(); err != nil {
return "", "", false, err
}
return window, step, inheritStep, nil
}
func (p *parser) parseOffset() (string, error) {
if !isOffset(p.lex.Token) {
return "", fmt.Errorf(`offset: unexpected token %q; want "offset"`, p.lex.Token)
}
if err := p.lex.Next(); err != nil {
return "", err
}
d, err := p.parseDuration()
if err != nil {
return "", err
}
return d, nil
}
func (p *parser) parseDuration() (string, error) {
isNegative := false
if p.lex.Token == "-" {
isNegative = true
if err := p.lex.Next(); err != nil {
return "", err
}
}
if !isPositiveDuration(p.lex.Token) {
return "", fmt.Errorf(`duration: unexpected token %q; want "duration"`, p.lex.Token)
}
d := p.lex.Token
if err := p.lex.Next(); err != nil {
return "", err
}
if isNegative {
d = "-" + d
}
return d, nil
}
func (p *parser) parsePositiveDuration() (string, error) {
d, err := p.parseDuration()
if err != nil {
return "", err
}
if strings.HasPrefix(d, "-") {
return "", fmt.Errorf("positiveDuration: expecting positive duration; got %q", d)
}
return d, nil
}
// parseIdentExpr parses expressions starting with `ident` token.
func (p *parser) parseIdentExpr() (Expr, error) {
// Look into the next-next token in order to determine how to parse
// the current expression.
if err := p.lex.Next(); err != nil {
return nil, err
}
if isEOF(p.lex.Token) || isOffset(p.lex.Token) {
p.lex.Prev()
return p.parseMetricExpr()
}
if isIdentPrefix(p.lex.Token) {
p.lex.Prev()
if isAggrFunc(p.lex.Token) {
return p.parseAggrFuncExpr()
}
return p.parseMetricExpr()
}
if isBinaryOp(p.lex.Token) {
p.lex.Prev()
return p.parseMetricExpr()
}
switch p.lex.Token {
case "(":
p.lex.Prev()
if isAggrFunc(p.lex.Token) {
return p.parseAggrFuncExpr()
}
return p.parseFuncExpr()
case "{", "[", ")", ",":
p.lex.Prev()
return p.parseMetricExpr()
default:
return nil, fmt.Errorf(`identExpr: unexpected token %q; want "(", "{", "[", ")", ","`, p.lex.Token)
}
}
func (p *parser) parseMetricExpr() (*MetricExpr, error) {
var me MetricExpr
if isIdentPrefix(p.lex.Token) {
var lfe labelFilterExpr
lfe.Label = "__name__"
lfe.Value = &StringExpr{
tokens: []string{strconv.Quote(p.lex.Token)},
}
me.labelFilters = append(me.labelFilters[:0], &lfe)
if err := p.lex.Next(); err != nil {
return nil, err
}
if p.lex.Token != "{" {
return &me, nil
}
}
lfes, err := p.parseLabelFilters()
if err != nil {
return nil, err
}
me.labelFilters = append(me.labelFilters, lfes...)
return &me, nil
}
func (p *parser) parseRollupExpr(arg Expr) (Expr, error) {
var re RollupExpr
re.Expr = arg
if p.lex.Token == "[" {
window, step, inheritStep, err := p.parseWindowAndStep()
if err != nil {
return nil, err
}
re.Window = window
re.Step = step
re.InheritStep = inheritStep
if !isOffset(p.lex.Token) {
return &re, nil
}
}
offset, err := p.parseOffset()
if err != nil {
return nil, err
}
re.Offset = offset
return &re, nil
}
// StringExpr represents string expression.
type StringExpr struct {
// S contains unquoted value for string expression.
S string
// Composite string has non-empty tokens.
// They must be converted into S by expandWithExpr.
tokens []string
}
// AppendString appends string representation of se to dst and returns the result.
func (se *StringExpr) AppendString(dst []byte) []byte {
return strconv.AppendQuote(dst, se.S)
}
// NumberExpr represents number expression.
type NumberExpr struct {
// N is the parsed number, i.e. `1.23`, `-234`, etc.
N float64
}
// AppendString appends string representation of ne to dst and returns the result.
func (ne *NumberExpr) AppendString(dst []byte) []byte {
return strconv.AppendFloat(dst, ne.N, 'g', -1, 64)
}
// parensExpr represents `(...)`.
//
// It isn't exported.
type parensExpr []Expr
// AppendString appends string representation of pe to dst and returns the result.
func (pe parensExpr) AppendString(dst []byte) []byte {
return appendStringArgListExpr(dst, pe)
}
// BinaryOpExpr represents binary operation.
type BinaryOpExpr struct {
// Op is the operation itself, i.e. `+`, `-`, `*`, etc.
Op string
// Bool indicates whether `bool` modifier is present.
// For example, `foo >bool bar`.
Bool bool
// GroupModifier contains modifier such as "on" or "ignoring".
GroupModifier ModifierExpr
// JoinModifier contains modifier such as "group_left" or "group_right".
JoinModifier ModifierExpr
// Left contains left arg for the `left op right` expression.
Left Expr
// Right contains right arg for the `left op right` epxression.
Right Expr
}
// AppendString appends string representation of be to dst and returns the result.
func (be *BinaryOpExpr) AppendString(dst []byte) []byte {
if _, ok := be.Left.(*BinaryOpExpr); ok {
dst = append(dst, '(')
dst = be.Left.AppendString(dst)
dst = append(dst, ')')
} else {
dst = be.Left.AppendString(dst)
}
dst = append(dst, ' ')
dst = append(dst, be.Op...)
if be.Bool {
dst = append(dst, " bool"...)
}
if be.GroupModifier.Op != "" {
dst = append(dst, ' ')
dst = be.GroupModifier.AppendString(dst)
}
if be.JoinModifier.Op != "" {
dst = append(dst, ' ')
dst = be.JoinModifier.AppendString(dst)
}
dst = append(dst, ' ')
if _, ok := be.Right.(*BinaryOpExpr); ok {
dst = append(dst, '(')
dst = be.Right.AppendString(dst)
dst = append(dst, ')')
} else {
dst = be.Right.AppendString(dst)
}
return dst
}
// ModifierExpr represents MetricsQL modifier such as `<op> (...)`
type ModifierExpr struct {
// Op is modifier operation.
Op string
// Args contains modifier args from parens.
Args []string
}
// AppendString appends string representation of me to dst and returns the result.
func (me *ModifierExpr) AppendString(dst []byte) []byte {
dst = append(dst, me.Op...)
dst = append(dst, " ("...)
for i, arg := range me.Args {
dst = append(dst, arg...)
if i+1 < len(me.Args) {
dst = append(dst, ", "...)
}
}
dst = append(dst, ')')
return dst
}
func appendStringArgListExpr(dst []byte, args []Expr) []byte {
dst = append(dst, '(')
for i, arg := range args {
dst = arg.AppendString(dst)
if i+1 < len(args) {
dst = append(dst, ", "...)
}
}
dst = append(dst, ')')
return dst
}
// FuncExpr represetns MetricsQL function such as `foo(...)`
type FuncExpr struct {
// Name is function name.
Name string
// Args contains function args.
Args []Expr
}
// AppendString appends string representation of fe to dst and returns the result.
func (fe *FuncExpr) AppendString(dst []byte) []byte {
dst = append(dst, fe.Name...)
dst = appendStringArgListExpr(dst, fe.Args)
return dst
}
// AggrFuncExpr represents aggregate function such as `sum(...) by (...)`
type AggrFuncExpr struct {
// Name is the function name.
Name string
// Args is the function args.
Args []Expr
// Modifier is optional modifier such as `by (...)` or `without (...)`.
Modifier ModifierExpr
}
// AppendString appends string representation of ae to dst and returns the result.
func (ae *AggrFuncExpr) AppendString(dst []byte) []byte {
dst = append(dst, ae.Name...)
dst = appendStringArgListExpr(dst, ae.Args)
if ae.Modifier.Op != "" {
dst = append(dst, ' ')
dst = ae.Modifier.AppendString(dst)
}
return dst
}
// withExpr represents `with (...)` extension from MetricsQL.
//
// It isn't exported.
type withExpr struct {
Was []*withArgExpr
Expr Expr
}
// AppendString appends string representation of we to dst and returns the result.
func (we *withExpr) AppendString(dst []byte) []byte {
dst = append(dst, "WITH ("...)
for i, wa := range we.Was {
dst = wa.AppendString(dst)
if i+1 < len(we.Was) {
dst = append(dst, ',')
}
}
dst = append(dst, ") "...)
dst = we.Expr.AppendString(dst)
return dst
}
// withArgExpr represents a single entry from WITH expression.
//
// It isn't exported.
type withArgExpr struct {
Name string
Args []string
Expr Expr
}
// AppendString appends string representation of wa to dst and returns the result.
func (wa *withArgExpr) AppendString(dst []byte) []byte {
dst = append(dst, wa.Name...)
if len(wa.Args) > 0 {
dst = append(dst, '(')
for i, arg := range wa.Args {
dst = append(dst, arg...)
if i+1 < len(wa.Args) {
dst = append(dst, ',')
}
}
dst = append(dst, ')')
}
dst = append(dst, " = "...)
dst = wa.Expr.AppendString(dst)
return dst
}
// RollupExpr represents MetricsQL expression, which contains at least `offset` or `[...]` part.
type RollupExpr struct {
// The expression for the rollup. Usually it is MetricExpr, but may be arbitrary expr
// if subquery is used. https://prometheus.io/blog/2019/01/28/subquery-support/
Expr Expr
// Window contains optional window value from square brackets
//
// For example, `http_requests_total[5m]` will have Window value `5m`.
Window string
// Offset contains optional value from `offset` part.
//
// For example, `foobar{baz="aa"} offset 5m` will have Offset value `5m`.
Offset string
// Step contains optional step value from square brackets.
//
// For example, `foobar[1h:3m]` will have Step value '3m'.
Step string
// If set to true, then `foo[1h:]` would print the same
// instead of `foo[1h]`.
InheritStep bool
}
// ForSubquery returns true if re represents subquery.
func (re *RollupExpr) ForSubquery() bool {
return len(re.Step) > 0 || re.InheritStep
}
// AppendString appends string representation of re to dst and returns the result.
func (re *RollupExpr) AppendString(dst []byte) []byte {
needParens := func() bool {
if _, ok := re.Expr.(*RollupExpr); ok {
return true
}
if _, ok := re.Expr.(*BinaryOpExpr); ok {
return true
}
if ae, ok := re.Expr.(*AggrFuncExpr); ok && ae.Modifier.Op != "" {
return true
}
return false
}()
if needParens {
dst = append(dst, '(')
}
dst = re.Expr.AppendString(dst)
if needParens {
dst = append(dst, ')')
}
if len(re.Window) > 0 || re.InheritStep || len(re.Step) > 0 {
dst = append(dst, '[')
if len(re.Window) > 0 {
dst = append(dst, re.Window...)
}
if len(re.Step) > 0 {
dst = append(dst, ':')
dst = append(dst, re.Step...)
} else if re.InheritStep {
dst = append(dst, ':')
}
dst = append(dst, ']')
}
if len(re.Offset) > 0 {
dst = append(dst, " offset "...)
dst = append(dst, re.Offset...)
}
return dst
}
// LabelFilter represents MetricsQL label filter like `foo="bar"`.
type LabelFilter struct {
// Label contains label name for the filter.
Label string
// Value contains unquoted value for the filter.
Value string
// IsNegative reperesents whether the filter is negative, i.e. '!=' or '!~'.
IsNegative bool
// IsRegexp represents whether the filter is regesp, i.e. `=~` or `!~`.
IsRegexp bool
}
// AppendString appends string representation of me to dst and returns the result.
func (lf *LabelFilter) AppendString(dst []byte) []byte {
dst = appendEscapedIdent(dst, lf.Label)
var op string
if lf.IsNegative {
if lf.IsRegexp {
op = "!~"
} else {
op = "!="
}
} else {
if lf.IsRegexp {
op = "=~"
} else {
op = "="
}
}
dst = append(dst, op...)
dst = strconv.AppendQuote(dst, lf.Value)
return dst
}
// MetricExpr represents MetricsQL metric with optional filters, i.e. `foo{...}`.
type MetricExpr struct {
// LabelFilters contains a list of label filters from curly braces.
// Metric name if present must be the first.
LabelFilters []LabelFilter
// labelFilters must be expanded to LabelFilters by expandWithExpr.
labelFilters []*labelFilterExpr
}
// AppendString appends string representation of me to dst and returns the result.
func (me *MetricExpr) AppendString(dst []byte) []byte {
lfs := me.LabelFilters
if len(lfs) > 0 {
lf := &lfs[0]
if lf.Label == "__name__" && !lf.IsNegative && !lf.IsRegexp {
dst = appendEscapedIdent(dst, lf.Value)
lfs = lfs[1:]
}
}
if len(lfs) > 0 {
dst = append(dst, '{')
for i := range lfs {
dst = lfs[i].AppendString(dst)
if i+1 < len(lfs) {
dst = append(dst, ", "...)
}
}
dst = append(dst, '}')
} else if len(me.LabelFilters) == 0 {
dst = append(dst, "{}"...)
}
return dst
}
// IsEmpty returns true of me equals to `{}`.
func (me *MetricExpr) IsEmpty() bool {
return len(me.LabelFilters) == 0
}
func (me *MetricExpr) isOnlyMetricGroup() bool {
if !me.hasNonEmptyMetricGroup() {
return false
}
return len(me.LabelFilters) == 1
}
func (me *MetricExpr) hasNonEmptyMetricGroup() bool {
if len(me.LabelFilters) == 0 {
return false
}
lf := &me.LabelFilters[0]
return lf.Label == "__name__" && !lf.IsNegative && !lf.IsRegexp
}