VictoriaMetrics/lib/logstorage/parser.go
2024-05-20 04:08:30 +02:00

1560 lines
36 KiB
Go

package logstorage
import (
"fmt"
"math"
"regexp"
"strconv"
"strings"
"time"
"unicode"
"unicode/utf8"
"github.com/VictoriaMetrics/VictoriaMetrics/lib/logger"
"github.com/VictoriaMetrics/VictoriaMetrics/lib/promutils"
)
type lexer struct {
// s contains unparsed tail of sOrig
s string
// sOrig contains the original string
sOrig string
// token contains the current token
//
// an empty token means the end of s
token string
// rawToken contains raw token before unquoting
rawToken string
// prevToken contains the previously parsed token
prevToken string
// isSkippedSpace is set to true if there was a whitespace before the token in s
isSkippedSpace bool
// currentTimestamp is the current timestamp in nanoseconds
currentTimestamp int64
}
type lexerState struct {
lex lexer
}
func (lex *lexer) backupState() *lexerState {
return &lexerState{
lex: *lex,
}
}
func (lex *lexer) restoreState(ls *lexerState) {
*lex = ls.lex
}
// newLexer returns new lexer for the given s.
//
// The lex.token points to the first token in s.
func newLexer(s string) *lexer {
lex := &lexer{
s: s,
sOrig: s,
currentTimestamp: time.Now().UnixNano(),
}
lex.nextToken()
return lex
}
func (lex *lexer) isEnd() bool {
return len(lex.s) == 0 && len(lex.token) == 0 && len(lex.rawToken) == 0
}
func (lex *lexer) isQuotedToken() bool {
return lex.token != lex.rawToken
}
func (lex *lexer) isPrevToken(tokens ...string) bool {
for _, token := range tokens {
if token == lex.prevToken {
return true
}
}
return false
}
func (lex *lexer) isKeyword(keywords ...string) bool {
if lex.isQuotedToken() {
return false
}
tokenLower := strings.ToLower(lex.token)
for _, kw := range keywords {
if kw == tokenLower {
return true
}
}
return false
}
func (lex *lexer) context() string {
tail := lex.sOrig
tail = tail[:len(tail)-len(lex.s)]
if len(tail) > 50 {
tail = tail[len(tail)-50:]
}
return tail
}
func (lex *lexer) mustNextToken() bool {
lex.nextToken()
return !lex.isEnd()
}
func (lex *lexer) nextCharToken(s string, size int) {
lex.token = s[:size]
lex.rawToken = lex.token
lex.s = s[size:]
}
// nextToken updates lex.token to the next token.
func (lex *lexer) nextToken() {
s := lex.s
lex.prevToken = lex.token
lex.token = ""
lex.rawToken = ""
lex.isSkippedSpace = false
if len(s) == 0 {
return
}
r, size := utf8.DecodeRuneInString(s)
if r == utf8.RuneError {
lex.nextCharToken(s, size)
return
}
// Skip whitespace
for unicode.IsSpace(r) {
lex.isSkippedSpace = true
s = s[size:]
r, size = utf8.DecodeRuneInString(s)
}
// Try decoding simple token
tokenLen := 0
for isTokenRune(r) || r == '.' {
tokenLen += size
r, size = utf8.DecodeRuneInString(s[tokenLen:])
}
if tokenLen > 0 {
lex.nextCharToken(s, tokenLen)
return
}
switch r {
case '"', '`':
prefix, err := strconv.QuotedPrefix(s)
if err != nil {
lex.nextCharToken(s, 1)
return
}
token, err := strconv.Unquote(prefix)
if err != nil {
lex.nextCharToken(s, 1)
return
}
lex.token = token
lex.rawToken = prefix
lex.s = s[len(prefix):]
return
case '\'':
var b []byte
for !strings.HasPrefix(s[size:], "'") {
ch, _, newTail, err := strconv.UnquoteChar(s[size:], '\'')
if err != nil {
lex.nextCharToken(s, 1)
return
}
b = utf8.AppendRune(b, ch)
size += len(s[size:]) - len(newTail)
}
size++
lex.token = string(b)
lex.rawToken = string(s[:size])
lex.s = s[size:]
return
case '=':
if strings.HasPrefix(s[size:], "~") {
lex.nextCharToken(s, 2)
return
}
lex.nextCharToken(s, 1)
return
case '!':
if strings.HasPrefix(s[size:], "~") || strings.HasPrefix(s[size:], "=") {
lex.nextCharToken(s, 2)
return
}
lex.nextCharToken(s, 1)
return
default:
lex.nextCharToken(s, size)
return
}
}
// Query represents LogsQL query.
type Query struct {
f filter
pipes []pipe
}
// String returns string representation for q.
func (q *Query) String() string {
s := q.f.String()
for _, p := range q.pipes {
s += " | " + p.String()
}
return s
}
// AddCountByTimePipe adds '| stats by (_time:step offset off, field1, ..., fieldN) count() hits' to the end of q.
func (q *Query) AddCountByTimePipe(step, off int64, fields []string) {
{
// add 'stats by (_time:step offset off, fields) count() hits'
stepStr := string(marshalDuration(nil, step))
offsetStr := string(marshalDuration(nil, off))
byFieldsStr := "_time:" + stepStr + " offset " + offsetStr
for _, f := range fields {
byFieldsStr += ", " + quoteTokenIfNeeded(f)
}
s := fmt.Sprintf("stats by (%s) count() hits", byFieldsStr)
lex := newLexer(s)
ps, err := parsePipeStats(lex)
if err != nil {
logger.Panicf("BUG: unexpected error when parsing %q: %s", s, err)
}
q.pipes = append(q.pipes, ps)
}
{
// Add 'sort by (_time, fields)' in order to get consistent order of the results.
sortFieldsStr := "_time"
for _, f := range fields {
sortFieldsStr += ", " + quoteTokenIfNeeded(f)
}
s := fmt.Sprintf("sort by (%s)", sortFieldsStr)
lex := newLexer(s)
ps, err := parsePipeSort(lex)
if err != nil {
logger.Panicf("BUG: unexpected error when parsing %q: %s", s, err)
}
q.pipes = append(q.pipes, ps)
}
}
// AddTimeFilter adds global filter _time:[start ... end] to q.
func (q *Query) AddTimeFilter(start, end int64) {
startStr := marshalTimestampRFC3339NanoString(nil, start)
endStr := marshalTimestampRFC3339NanoString(nil, end)
ft := &filterTime{
minTimestamp: start,
maxTimestamp: end,
stringRepr: fmt.Sprintf("[%s, %s]", startStr, endStr),
}
fa, ok := q.f.(*filterAnd)
if ok {
filters := make([]filter, len(fa.filters)+1)
filters[0] = ft
copy(filters[1:], fa.filters)
fa.filters = filters
} else {
q.f = &filterAnd{
filters: []filter{ft, q.f},
}
}
}
// AddPipeLimit adds `| limit n` pipe to q.
//
// See https://docs.victoriametrics.com/victorialogs/logsql/#limit-pipe
func (q *Query) AddPipeLimit(n uint64) {
q.pipes = append(q.pipes, &pipeLimit{
limit: n,
})
}
// Optimize tries optimizing the query.
func (q *Query) Optimize() {
q.pipes = optimizeSortOffsetPipes(q.pipes)
q.pipes = optimizeSortLimitPipes(q.pipes)
q.pipes = optimizeUniqLimitPipes(q.pipes)
q.pipes = optimizeFilterPipes(q.pipes)
// Merge `q | filter ...` into q.
if len(q.pipes) > 0 {
pf, ok := q.pipes[0].(*pipeFilter)
if ok {
q.f = mergeFiltersAnd(q.f, pf.f)
q.pipes = append(q.pipes[:0], q.pipes[1:]...)
}
}
// Optimize `q | field_names ...` by marking pipeFieldNames as first pipe.
if len(q.pipes) > 0 {
pf, ok := q.pipes[0].(*pipeFieldNames)
if ok {
pf.isFirstPipe = true
}
}
// Substitute '*' prefixFilter with filterNoop in order to avoid reading _msg data.
q.f = removeStarFilters(q.f)
// Call Optimize for queries from 'in(query)' filters.
optimizeFilterIn(q.f)
for _, p := range q.pipes {
switch t := p.(type) {
case *pipeStats:
for _, f := range t.funcs {
if f.iff != nil {
optimizeFilterIn(f.iff)
}
}
}
}
}
func removeStarFilters(f filter) filter {
visitFunc := func(f filter) bool {
fp, ok := f.(*filterPrefix)
return ok && isMsgFieldName(fp.fieldName) && fp.prefix == ""
}
copyFunc := func(_ filter) (filter, error) {
fn := &filterNoop{}
return fn, nil
}
f, err := copyFilter(f, visitFunc, copyFunc)
if err != nil {
logger.Fatalf("BUG: unexpected error: %s", err)
}
return f
}
func optimizeFilterIn(f filter) {
visitFunc := func(f filter) bool {
fi, ok := f.(*filterIn)
if ok && fi.q != nil {
fi.q.Optimize()
}
return false
}
_ = visitFilter(f, visitFunc)
}
func optimizeSortOffsetPipes(pipes []pipe) []pipe {
// Merge 'sort ... | offset ...' into 'sort ... offset ...'
i := 1
for i < len(pipes) {
po, ok := pipes[i].(*pipeOffset)
if !ok {
i++
continue
}
ps, ok := pipes[i-1].(*pipeSort)
if !ok {
i++
continue
}
if ps.offset == 0 && ps.limit == 0 {
ps.offset = po.offset
}
pipes = append(pipes[:i], pipes[i+1:]...)
}
return pipes
}
func optimizeSortLimitPipes(pipes []pipe) []pipe {
// Merge 'sort ... | limit ...' into 'sort ... limit ...'
i := 1
for i < len(pipes) {
pl, ok := pipes[i].(*pipeLimit)
if !ok {
i++
continue
}
ps, ok := pipes[i-1].(*pipeSort)
if !ok {
i++
continue
}
if ps.limit == 0 || pl.limit < ps.limit {
ps.limit = pl.limit
}
pipes = append(pipes[:i], pipes[i+1:]...)
}
return pipes
}
func optimizeUniqLimitPipes(pipes []pipe) []pipe {
// Merge 'uniq ... | limit ...' into 'uniq ... limit ...'
i := 1
for i < len(pipes) {
pl, ok := pipes[i].(*pipeLimit)
if !ok {
i++
continue
}
pu, ok := pipes[i-1].(*pipeUniq)
if !ok {
i++
continue
}
if pu.limit == 0 || pl.limit < pu.limit {
pu.limit = pl.limit
}
pipes = append(pipes[:i], pipes[i+1:]...)
}
return pipes
}
func optimizeFilterPipes(pipes []pipe) []pipe {
// Merge multiple `| filter ...` pipes into a single `filter ...` pipe
i := 1
for i < len(pipes) {
pf1, ok := pipes[i-1].(*pipeFilter)
if !ok {
i++
continue
}
pf2, ok := pipes[i].(*pipeFilter)
if !ok {
i++
continue
}
pf1.f = mergeFiltersAnd(pf1.f, pf2.f)
pipes = append(pipes[:i], pipes[i+1:]...)
}
return pipes
}
func mergeFiltersAnd(f1, f2 filter) filter {
fa1, ok := f1.(*filterAnd)
if ok {
fa1.filters = append(fa1.filters, f2)
return fa1
}
fa2, ok := f2.(*filterAnd)
if ok {
filters := make([]filter, len(fa2.filters)+1)
filters[0] = f1
copy(filters[1:], fa2.filters)
fa2.filters = filters
return fa2
}
return &filterAnd{
filters: []filter{f1, f2},
}
}
func (q *Query) getNeededColumns() ([]string, []string) {
neededFields := newFieldsSet()
neededFields.add("*")
unneededFields := newFieldsSet()
pipes := q.pipes
for i := len(pipes) - 1; i >= 0; i-- {
pipes[i].updateNeededFields(neededFields, unneededFields)
}
return neededFields.getAll(), unneededFields.getAll()
}
// ParseQuery parses s.
func ParseQuery(s string) (*Query, error) {
lex := newLexer(s)
q, err := parseQuery(lex)
if err != nil {
return nil, err
}
if !lex.isEnd() {
return nil, fmt.Errorf("unexpected unparsed tail after [%s]; context: [%s]; tail: [%s]", q, lex.context(), lex.s)
}
return q, nil
}
func parseQuery(lex *lexer) (*Query, error) {
f, err := parseFilter(lex)
if err != nil {
return nil, fmt.Errorf("%w; context: [%s]", err, lex.context())
}
q := &Query{
f: f,
}
pipes, err := parsePipes(lex)
if err != nil {
return nil, fmt.Errorf("%w; context: [%s]", err, lex.context())
}
q.pipes = pipes
return q, nil
}
func parseFilter(lex *lexer) (filter, error) {
if lex.isKeyword("|", "") {
return nil, fmt.Errorf("missing query")
}
fo, err := parseFilterOr(lex, "")
if err != nil {
return nil, err
}
return fo, nil
}
func parseFilterOr(lex *lexer, fieldName string) (filter, error) {
var filters []filter
for {
f, err := parseFilterAnd(lex, fieldName)
if err != nil {
return nil, err
}
filters = append(filters, f)
switch {
case lex.isKeyword("|", ")", ""):
if len(filters) == 1 {
return filters[0], nil
}
fo := &filterOr{
filters: filters,
}
return fo, nil
case lex.isKeyword("or"):
if !lex.mustNextToken() {
return nil, fmt.Errorf("missing filter after 'or'")
}
}
}
}
func parseFilterAnd(lex *lexer, fieldName string) (filter, error) {
var filters []filter
for {
f, err := parseGenericFilter(lex, fieldName)
if err != nil {
return nil, err
}
filters = append(filters, f)
switch {
case lex.isKeyword("or", "|", ")", ""):
if len(filters) == 1 {
return filters[0], nil
}
fa := &filterAnd{
filters: filters,
}
return fa, nil
case lex.isKeyword("and"):
if !lex.mustNextToken() {
return nil, fmt.Errorf("missing filter after 'and'")
}
}
}
}
func parseGenericFilter(lex *lexer, fieldName string) (filter, error) {
// Check for special keywords
switch {
case lex.isKeyword(":"):
if !lex.mustNextToken() {
return nil, fmt.Errorf("missing filter after ':'")
}
return parseGenericFilter(lex, fieldName)
case lex.isKeyword("*"):
lex.nextToken()
f := &filterPrefix{
fieldName: fieldName,
prefix: "",
}
return f, nil
case lex.isKeyword("("):
if !lex.isSkippedSpace && !lex.isPrevToken("", ":", "(", "!", "not") {
return nil, fmt.Errorf("missing whitespace before the search word %q", lex.prevToken)
}
return parseParensFilter(lex, fieldName)
case lex.isKeyword(">"):
return parseFilterGT(lex, fieldName)
case lex.isKeyword("<"):
return parseFilterLT(lex, fieldName)
case lex.isKeyword("not", "!"):
return parseFilterNot(lex, fieldName)
case lex.isKeyword("exact"):
return parseFilterExact(lex, fieldName)
case lex.isKeyword("i"):
return parseAnyCaseFilter(lex, fieldName)
case lex.isKeyword("in"):
return parseFilterIn(lex, fieldName)
case lex.isKeyword("ipv4_range"):
return parseFilterIPv4Range(lex, fieldName)
case lex.isKeyword("len_range"):
return parseFilterLenRange(lex, fieldName)
case lex.isKeyword("range"):
return parseFilterRange(lex, fieldName)
case lex.isKeyword("re"):
return parseFilterRegexp(lex, fieldName)
case lex.isKeyword("seq"):
return parseFilterSequence(lex, fieldName)
case lex.isKeyword("string_range"):
return parseFilterStringRange(lex, fieldName)
case lex.isKeyword(`"`, "'", "`"):
return nil, fmt.Errorf("improperly quoted string")
case lex.isKeyword(",", ")", "[", "]"):
return nil, fmt.Errorf("unexpected token %q", lex.token)
}
phrase, err := getCompoundPhrase(lex, fieldName != "")
if err != nil {
return nil, err
}
return parseFilterForPhrase(lex, phrase, fieldName)
}
func getCompoundPhrase(lex *lexer, allowColon bool) (string, error) {
stopTokens := []string{"*", ",", "(", ")", "[", "]", "|", ""}
if lex.isKeyword(stopTokens...) {
return "", fmt.Errorf("compound phrase cannot start with '%s'", lex.token)
}
phrase := lex.token
rawPhrase := lex.rawToken
lex.nextToken()
suffix := getCompoundSuffix(lex, allowColon)
if suffix == "" {
return phrase, nil
}
return rawPhrase + suffix, nil
}
func getCompoundSuffix(lex *lexer, allowColon bool) string {
s := ""
stopTokens := []string{"*", ",", "(", ")", "[", "]", "|", ""}
if !allowColon {
stopTokens = append(stopTokens, ":")
}
for !lex.isSkippedSpace && !lex.isKeyword(stopTokens...) {
s += lex.rawToken
lex.nextToken()
}
return s
}
func getCompoundToken(lex *lexer) (string, error) {
stopTokens := []string{",", "(", ")", "[", "]", "|", ""}
if lex.isKeyword(stopTokens...) {
return "", fmt.Errorf("compound token cannot start with '%s'", lex.token)
}
s := lex.token
rawS := lex.rawToken
lex.nextToken()
suffix := ""
for !lex.isSkippedSpace && !lex.isKeyword(stopTokens...) {
s += lex.token
lex.nextToken()
}
if suffix == "" {
return s, nil
}
return rawS + suffix, nil
}
func getCompoundFuncArg(lex *lexer) string {
if lex.isKeyword("*") {
return ""
}
arg := lex.token
rawArg := lex.rawToken
lex.nextToken()
suffix := ""
for !lex.isSkippedSpace && !lex.isKeyword("*", ",", "(", ")", "|", "") {
suffix += lex.rawToken
lex.nextToken()
}
if suffix == "" {
return arg
}
return rawArg + suffix
}
func parseFilterForPhrase(lex *lexer, phrase, fieldName string) (filter, error) {
if fieldName != "" || !lex.isKeyword(":") {
// The phrase is either a search phrase or a search prefix.
if lex.isKeyword("*") && !lex.isSkippedSpace {
// The phrase is a search prefix in the form `foo*`.
lex.nextToken()
f := &filterPrefix{
fieldName: fieldName,
prefix: phrase,
}
return f, nil
}
// The phrase is a search phrase.
f := &filterPhrase{
fieldName: fieldName,
phrase: phrase,
}
return f, nil
}
// The phrase contains the field name.
fieldName = phrase
if !lex.mustNextToken() {
return nil, fmt.Errorf("missing filter after field name %s", quoteTokenIfNeeded(fieldName))
}
switch fieldName {
case "_time":
return parseFilterTimeWithOffset(lex)
case "_stream":
return parseFilterStream(lex)
default:
return parseGenericFilter(lex, fieldName)
}
}
func parseParensFilter(lex *lexer, fieldName string) (filter, error) {
if !lex.mustNextToken() {
return nil, fmt.Errorf("missing filter after '('")
}
f, err := parseFilterOr(lex, fieldName)
if err != nil {
return nil, err
}
if !lex.isKeyword(")") {
return nil, fmt.Errorf("unexpected token %q instead of ')'", lex.token)
}
lex.nextToken()
return f, nil
}
func parseFilterNot(lex *lexer, fieldName string) (filter, error) {
notKeyword := lex.token
if !lex.mustNextToken() {
return nil, fmt.Errorf("missing filters after '%s'", notKeyword)
}
f, err := parseGenericFilter(lex, fieldName)
if err != nil {
return nil, err
}
fn, ok := f.(*filterNot)
if ok {
return fn.f, nil
}
fn = &filterNot{
f: f,
}
return fn, nil
}
func parseAnyCaseFilter(lex *lexer, fieldName string) (filter, error) {
return parseFuncArgMaybePrefix(lex, "i", fieldName, func(phrase string, isFilterPrefix bool) (filter, error) {
if isFilterPrefix {
f := &filterAnyCasePrefix{
fieldName: fieldName,
prefix: phrase,
}
return f, nil
}
f := &filterAnyCasePhrase{
fieldName: fieldName,
phrase: phrase,
}
return f, nil
})
}
func parseFuncArgMaybePrefix(lex *lexer, funcName, fieldName string, callback func(arg string, isPrefiFilter bool) (filter, error)) (filter, error) {
phrase := lex.token
lex.nextToken()
if !lex.isKeyword("(") {
phrase += getCompoundSuffix(lex, fieldName != "")
return parseFilterForPhrase(lex, phrase, fieldName)
}
if !lex.mustNextToken() {
return nil, fmt.Errorf("missing arg for %s()", funcName)
}
phrase = getCompoundFuncArg(lex)
isFilterPrefix := false
if lex.isKeyword("*") && !lex.isSkippedSpace {
isFilterPrefix = true
if !lex.mustNextToken() {
return nil, fmt.Errorf("missing ')' after %s()", funcName)
}
}
if !lex.isKeyword(")") {
return nil, fmt.Errorf("unexpected token %q instead of ')' in %s()", lex.token, funcName)
}
lex.nextToken()
return callback(phrase, isFilterPrefix)
}
func parseFilterLenRange(lex *lexer, fieldName string) (filter, error) {
funcName := lex.token
return parseFuncArgs(lex, fieldName, func(args []string) (filter, error) {
if len(args) != 2 {
return nil, fmt.Errorf("unexpected number of args for %s(); got %d; want 2", funcName, len(args))
}
minLen, err := parseUint(args[0])
if err != nil {
return nil, fmt.Errorf("cannot parse minLen at %s(): %w", funcName, err)
}
maxLen, err := parseUint(args[1])
if err != nil {
return nil, fmt.Errorf("cannot parse maxLen at %s(): %w", funcName, err)
}
stringRepr := "(" + args[0] + ", " + args[1] + ")"
fr := &filterLenRange{
fieldName: fieldName,
minLen: minLen,
maxLen: maxLen,
stringRepr: stringRepr,
}
return fr, nil
})
}
func parseFilterStringRange(lex *lexer, fieldName string) (filter, error) {
funcName := lex.token
return parseFuncArgs(lex, fieldName, func(args []string) (filter, error) {
if len(args) != 2 {
return nil, fmt.Errorf("unexpected number of args for %s(); got %d; want 2", funcName, len(args))
}
fr := &filterStringRange{
fieldName: fieldName,
minValue: args[0],
maxValue: args[1],
}
return fr, nil
})
}
func parseFilterIPv4Range(lex *lexer, fieldName string) (filter, error) {
funcName := lex.token
return parseFuncArgs(lex, fieldName, func(args []string) (filter, error) {
if len(args) == 1 {
minValue, maxValue, ok := tryParseIPv4CIDR(args[0])
if !ok {
return nil, fmt.Errorf("cannot parse IPv4 address or IPv4 CIDR %q at %s()", args[0], funcName)
}
fr := &filterIPv4Range{
fieldName: fieldName,
minValue: minValue,
maxValue: maxValue,
}
return fr, nil
}
if len(args) != 2 {
return nil, fmt.Errorf("unexpected number of args for %s(); got %d; want 2", funcName, len(args))
}
minValue, ok := tryParseIPv4(args[0])
if !ok {
return nil, fmt.Errorf("cannot parse lower bound ip %q in %s()", funcName, args[0])
}
maxValue, ok := tryParseIPv4(args[1])
if !ok {
return nil, fmt.Errorf("cannot parse upper bound ip %q in %s()", funcName, args[1])
}
fr := &filterIPv4Range{
fieldName: fieldName,
minValue: minValue,
maxValue: maxValue,
}
return fr, nil
})
}
func tryParseIPv4CIDR(s string) (uint32, uint32, bool) {
n := strings.IndexByte(s, '/')
if n < 0 {
n, ok := tryParseIPv4(s)
return n, n, ok
}
ip, ok := tryParseIPv4(s[:n])
if !ok {
return 0, 0, false
}
maskBits, ok := tryParseUint64(s[n+1:])
if !ok || maskBits > 32 {
return 0, 0, false
}
mask := uint32((1 << (32 - maskBits)) - 1)
minValue := ip &^ mask
maxValue := ip | mask
return minValue, maxValue, true
}
func parseFilterIn(lex *lexer, fieldName string) (filter, error) {
if !lex.isKeyword("in") {
return nil, fmt.Errorf("expecting 'in' keyword")
}
// Try parsing in(arg1, ..., argN) at first
lexState := lex.backupState()
fi, err := parseFuncArgs(lex, fieldName, func(args []string) (filter, error) {
fi := &filterIn{
fieldName: fieldName,
values: args,
}
return fi, nil
})
if err == nil {
return fi, nil
}
// Parse in(query | fields someField) then
lex.restoreState(lexState)
lex.nextToken()
if !lex.isKeyword("(") {
return nil, fmt.Errorf("missing '(' after 'in'")
}
lex.nextToken()
q, err := parseQuery(lex)
if err != nil {
return nil, fmt.Errorf("cannot parse query inside 'in(...)': %w", err)
}
if !lex.isKeyword(")") {
return nil, fmt.Errorf("missing ')' after 'in(%s)'", q)
}
lex.nextToken()
qFieldName, err := getFieldNameFromPipes(q.pipes)
if err != nil {
return nil, fmt.Errorf("cannot determine field name for values in 'in(%s)': %w", q, err)
}
fi = &filterIn{
fieldName: fieldName,
needExecuteQuery: true,
q: q,
qFieldName: qFieldName,
}
return fi, nil
}
func getFieldNameFromPipes(pipes []pipe) (string, error) {
if len(pipes) == 0 {
return "", fmt.Errorf("missing 'fields' or 'uniq' pipes at the end of query")
}
switch t := pipes[len(pipes)-1].(type) {
case *pipeFields:
if t.containsStar || len(t.fields) != 1 {
return "", fmt.Errorf("'%s' pipe must contain only a single non-star field name", t)
}
return t.fields[0], nil
case *pipeUniq:
if len(t.byFields) != 1 {
return "", fmt.Errorf("'%s' pipe must contain only a single non-star field name", t)
}
return t.byFields[0], nil
default:
return "", fmt.Errorf("missing 'fields' or 'uniq' pipe at the end of query")
}
}
func parseFilterSequence(lex *lexer, fieldName string) (filter, error) {
return parseFuncArgs(lex, fieldName, func(args []string) (filter, error) {
fs := &filterSequence{
fieldName: fieldName,
phrases: args,
}
return fs, nil
})
}
func parseFilterExact(lex *lexer, fieldName string) (filter, error) {
return parseFuncArgMaybePrefix(lex, "exact", fieldName, func(phrase string, isFilterPrefix bool) (filter, error) {
if isFilterPrefix {
f := &filterExactPrefix{
fieldName: fieldName,
prefix: phrase,
}
return f, nil
}
f := &filterExact{
fieldName: fieldName,
value: phrase,
}
return f, nil
})
}
func parseFilterRegexp(lex *lexer, fieldName string) (filter, error) {
funcName := lex.token
return parseFuncArg(lex, fieldName, func(arg string) (filter, error) {
re, err := regexp.Compile(arg)
if err != nil {
return nil, fmt.Errorf("invalid regexp %q for %s(): %w", arg, funcName, err)
}
fr := &filterRegexp{
fieldName: fieldName,
re: re,
}
return fr, nil
})
}
func parseFilterGT(lex *lexer, fieldName string) (filter, error) {
if fieldName == "" {
return nil, fmt.Errorf("'>' and '>=' must be prefixed with the field name")
}
lex.nextToken()
includeMinValue := false
op := ">"
if lex.isKeyword("=") {
lex.nextToken()
includeMinValue = true
op = ">="
}
minValue, fStr, err := parseFloat64(lex)
if err != nil {
return nil, fmt.Errorf("cannot parse number after '%s': %w", op, err)
}
if !includeMinValue {
minValue = nextafter(minValue, inf)
}
fr := &filterRange{
fieldName: fieldName,
minValue: minValue,
maxValue: inf,
stringRepr: op + fStr,
}
return fr, nil
}
func parseFilterLT(lex *lexer, fieldName string) (filter, error) {
if fieldName == "" {
return nil, fmt.Errorf("'<' and '<=' must be prefixed with the field name")
}
lex.nextToken()
includeMaxValue := false
op := "<"
if lex.isKeyword("=") {
lex.nextToken()
includeMaxValue = true
op = "<="
}
maxValue, fStr, err := parseFloat64(lex)
if err != nil {
return nil, fmt.Errorf("cannot parse number after '%s': %w", op, err)
}
if !includeMaxValue {
maxValue = nextafter(maxValue, -inf)
}
fr := &filterRange{
fieldName: fieldName,
minValue: -inf,
maxValue: maxValue,
stringRepr: op + fStr,
}
return fr, nil
}
func parseFilterRange(lex *lexer, fieldName string) (filter, error) {
funcName := lex.token
lex.nextToken()
// Parse minValue
includeMinValue := false
switch {
case lex.isKeyword("("):
includeMinValue = false
case lex.isKeyword("["):
includeMinValue = true
default:
phrase := funcName + getCompoundSuffix(lex, fieldName != "")
return parseFilterForPhrase(lex, phrase, fieldName)
}
if !lex.mustNextToken() {
return nil, fmt.Errorf("missing args for %s()", funcName)
}
minValue, minValueStr, err := parseFloat64(lex)
if err != nil {
return nil, fmt.Errorf("cannot parse minValue in %s(): %w", funcName, err)
}
// Parse comma
if !lex.isKeyword(",") {
return nil, fmt.Errorf("unexpected token %q ater %q in %s(); want ','", lex.token, minValueStr, funcName)
}
if !lex.mustNextToken() {
return nil, fmt.Errorf("missing maxValue in %s()", funcName)
}
// Parse maxValue
maxValue, maxValueStr, err := parseFloat64(lex)
if err != nil {
return nil, fmt.Errorf("cannot parse maxValue in %s(): %w", funcName, err)
}
includeMaxValue := false
switch {
case lex.isKeyword(")"):
includeMaxValue = false
case lex.isKeyword("]"):
includeMaxValue = true
default:
return nil, fmt.Errorf("unexpected closing token %q in %s(); want ')' or ']'", lex.token, funcName)
}
lex.nextToken()
stringRepr := "range"
if includeMinValue {
stringRepr += "["
} else {
stringRepr += "("
minValue = nextafter(minValue, inf)
}
stringRepr += minValueStr + ", " + maxValueStr
if includeMaxValue {
stringRepr += "]"
} else {
stringRepr += ")"
maxValue = nextafter(maxValue, -inf)
}
fr := &filterRange{
fieldName: fieldName,
minValue: minValue,
maxValue: maxValue,
stringRepr: stringRepr,
}
return fr, nil
}
func parseFloat64(lex *lexer) (float64, string, error) {
s, err := getCompoundToken(lex)
if err != nil {
return 0, "", fmt.Errorf("cannot parse float64: %w", err)
}
f, err := strconv.ParseFloat(s, 64)
if err == nil {
return f, s, nil
}
// Try parsing s as integer.
// This handles 0x..., 0b... and 0... prefixes, alongside '_' delimiters.
n, err := parseInt(s)
if err == nil {
return float64(n), s, nil
}
return 0, "", fmt.Errorf("cannot parse %q as float64: %w", lex.token, err)
}
func parseFuncArg(lex *lexer, fieldName string, callback func(args string) (filter, error)) (filter, error) {
funcName := lex.token
return parseFuncArgs(lex, fieldName, func(args []string) (filter, error) {
if len(args) != 1 {
return nil, fmt.Errorf("unexpected number of args for %s(); got %d; want 1", funcName, len(args))
}
return callback(args[0])
})
}
func parseFuncArgs(lex *lexer, fieldName string, callback func(args []string) (filter, error)) (filter, error) {
funcName := lex.token
lex.nextToken()
if !lex.isKeyword("(") {
phrase := funcName + getCompoundSuffix(lex, fieldName != "")
return parseFilterForPhrase(lex, phrase, fieldName)
}
if !lex.mustNextToken() {
return nil, fmt.Errorf("missing args for %s()", funcName)
}
var args []string
for !lex.isKeyword(")") {
if lex.isKeyword(",") {
return nil, fmt.Errorf("unexpected ',' - missing arg in %s()", funcName)
}
if lex.isKeyword("(") {
return nil, fmt.Errorf("unexpected '(' - missing arg in %s()", funcName)
}
arg := getCompoundFuncArg(lex)
args = append(args, arg)
if lex.isKeyword(")") {
break
}
if !lex.isKeyword(",") {
return nil, fmt.Errorf("missing ',' after %q in %s()", arg, funcName)
}
if !lex.mustNextToken() {
return nil, fmt.Errorf("missing the next arg after %q in %s()", arg, funcName)
}
}
lex.nextToken()
return callback(args)
}
// startsWithYear returns true if s starts from YYYY
func startsWithYear(s string) bool {
if len(s) < 4 {
return false
}
for i := 0; i < 4; i++ {
c := s[i]
if c < '0' || c > '9' {
return false
}
}
s = s[4:]
if len(s) == 0 {
return true
}
c := s[0]
return c == '-' || c == '+' || c == 'Z' || c == 'z'
}
func parseFilterTimeWithOffset(lex *lexer) (*filterTime, error) {
ft, err := parseFilterTime(lex)
if err != nil {
return nil, err
}
if !lex.isKeyword("offset") {
return ft, nil
}
lex.nextToken()
s, err := getCompoundToken(lex)
if err != nil {
return nil, fmt.Errorf("cannot parse offset in _time filter: %w", err)
}
d, ok := tryParseDuration(s)
if !ok {
return nil, fmt.Errorf("cannot parse offset %q for _time filter %s", s, ft)
}
offset := int64(d)
ft.minTimestamp -= offset
ft.maxTimestamp -= offset
ft.stringRepr += " offset " + s
return ft, nil
}
func parseFilterTime(lex *lexer) (*filterTime, error) {
startTimeInclude := false
switch {
case lex.isKeyword("["):
startTimeInclude = true
case lex.isKeyword("("):
startTimeInclude = false
default:
s, err := getCompoundToken(lex)
if err != nil {
return nil, fmt.Errorf("cannot parse _time filter: %w", err)
}
sLower := strings.ToLower(s)
if sLower == "now" || startsWithYear(s) {
// Parse '_time:YYYY-MM-DD', which transforms to '_time:[YYYY-MM-DD, YYYY-MM-DD+1)'
t, err := promutils.ParseTimeAt(s, float64(lex.currentTimestamp)/1e9)
if err != nil {
return nil, fmt.Errorf("cannot parse _time filter: %w", err)
}
startTime := int64(t * 1e9)
endTime := getMatchingEndTime(startTime, s)
ft := &filterTime{
minTimestamp: startTime,
maxTimestamp: endTime,
stringRepr: s,
}
return ft, nil
}
// Parse _time:duration, which transforms to '_time:(now-duration, now]'
d, ok := tryParseDuration(s)
if !ok {
return nil, fmt.Errorf("cannot parse duration %q in _time filter", s)
}
if d < 0 {
d = -d
}
ft := &filterTime{
minTimestamp: lex.currentTimestamp - int64(d),
maxTimestamp: lex.currentTimestamp,
stringRepr: s,
}
return ft, nil
}
if !lex.mustNextToken() {
return nil, fmt.Errorf("missing start time in _time filter")
}
// Parse start time
startTime, startTimeString, err := parseTime(lex)
if err != nil {
return nil, fmt.Errorf("cannot parse start time in _time filter: %w", err)
}
if !lex.isKeyword(",") {
return nil, fmt.Errorf("unexpected token after start time in _time filter: %q; want ','", lex.token)
}
if !lex.mustNextToken() {
return nil, fmt.Errorf("missing end time in _time filter")
}
// Parse end time
endTime, endTimeString, err := parseTime(lex)
if err != nil {
return nil, fmt.Errorf("cannot parse end time in _time filter: %w", err)
}
endTimeInclude := false
switch {
case lex.isKeyword("]"):
endTimeInclude = true
case lex.isKeyword(")"):
endTimeInclude = false
default:
return nil, fmt.Errorf("_time filter ends with unexpected token %q; it must end with ']' or ')'", lex.token)
}
lex.nextToken()
stringRepr := ""
if startTimeInclude {
stringRepr += "["
} else {
stringRepr += "("
startTime++
}
stringRepr += startTimeString + "," + endTimeString
if endTimeInclude {
stringRepr += "]"
endTime = getMatchingEndTime(endTime, endTimeString)
} else {
stringRepr += ")"
endTime--
}
ft := &filterTime{
minTimestamp: startTime,
maxTimestamp: endTime,
stringRepr: stringRepr,
}
return ft, nil
}
func getMatchingEndTime(startTime int64, stringRepr string) int64 {
tStart := time.Unix(0, startTime).UTC()
tEnd := tStart
timeStr := stripTimezoneSuffix(stringRepr)
switch {
case len(timeStr) == len("YYYY"):
y, m, d := tStart.Date()
nsec := startTime % (24 * 3600 * 1e9)
tEnd = time.Date(y+1, m, d, 0, 0, int(nsec/1e9), int(nsec%1e9), time.UTC)
case len(timeStr) == len("YYYY-MM") && timeStr[len("YYYY")] == '-':
y, m, d := tStart.Date()
nsec := startTime % (24 * 3600 * 1e9)
if d != 1 {
d = 0
m++
}
tEnd = time.Date(y, m+1, d, 0, 0, int(nsec/1e9), int(nsec%1e9), time.UTC)
case len(timeStr) == len("YYYY-MM-DD") && timeStr[len("YYYY")] == '-':
tEnd = tStart.Add(24 * time.Hour)
case len(timeStr) == len("YYYY-MM-DDThh") && timeStr[len("YYYY")] == '-':
tEnd = tStart.Add(time.Hour)
case len(timeStr) == len("YYYY-MM-DDThh:mm") && timeStr[len("YYYY")] == '-':
tEnd = tStart.Add(time.Minute)
case len(timeStr) == len("YYYY-MM-DDThh:mm:ss") && timeStr[len("YYYY")] == '-':
tEnd = tStart.Add(time.Second)
default:
tEnd = tStart.Add(time.Nanosecond)
}
return tEnd.UnixNano() - 1
}
func stripTimezoneSuffix(s string) string {
if strings.HasSuffix(s, "Z") {
return s[:len(s)-1]
}
if len(s) < 6 {
return s
}
tz := s[len(s)-6:]
if tz[0] != '-' && tz[0] != '+' {
return s
}
if tz[3] != ':' {
return s
}
return s[:len(s)-len(tz)]
}
func parseFilterStream(lex *lexer) (*filterStream, error) {
sf, err := parseStreamFilter(lex)
if err != nil {
return nil, err
}
fs := &filterStream{
f: sf,
}
return fs, nil
}
func parseTime(lex *lexer) (int64, string, error) {
s, err := getCompoundToken(lex)
if err != nil {
return 0, "", err
}
t, err := promutils.ParseTimeAt(s, float64(lex.currentTimestamp)/1e9)
if err != nil {
return 0, "", err
}
return int64(t * 1e9), s, nil
}
func quoteTokenIfNeeded(s string) string {
if !needQuoteToken(s) {
return s
}
return strconv.Quote(s)
}
func needQuoteToken(s string) bool {
sLower := strings.ToLower(s)
if _, ok := reservedKeywords[sLower]; ok {
return true
}
for _, r := range s {
if !isTokenRune(r) && r != '.' && r != '-' {
return true
}
}
return false
}
var reservedKeywords = func() map[string]struct{} {
kws := []string{
// An empty keyword means end of parsed string
"",
// boolean operator tokens for 'foo and bar or baz not xxx'
"and",
"or",
"not",
"!", // synonym for "not"
// parens for '(foo or bar) and baz'
"(",
")",
// stream filter tokens for '_stream:{foo=~"bar", baz="a"}'
"{",
"}",
"=",
"!=",
"=~",
"!~",
",",
// delimiter between query parts:
// 'foo and bar | extract "<*> foo <time>" | filter x:y | ...'
"|",
// delimiter between field name and query in filter: 'foo:bar'
":",
// prefix search: 'foo*'
"*",
// keywords for _time filter: '_time:(now-1h, now]'
"[",
"]",
"now",
"offset",
"-",
// functions
"exact",
"i",
"in",
"ipv4_range",
"len_range",
"range",
"re",
"seq",
"string_range",
}
m := make(map[string]struct{}, len(kws))
for _, kw := range kws {
m[kw] = struct{}{}
}
return m
}()
func parseUint(s string) (uint64, error) {
if strings.EqualFold(s, "inf") || strings.EqualFold(s, "+inf") {
return math.MaxUint64, nil
}
n, err := strconv.ParseUint(s, 0, 64)
if err == nil {
return n, nil
}
nn, ok := tryParseBytes(s)
if !ok {
nn, ok = tryParseDuration(s)
if !ok {
return 0, fmt.Errorf("cannot parse %q as unsigned integer: %w", s, err)
}
if nn < 0 {
return 0, fmt.Errorf("cannot parse negative value %q as unsigned integer", s)
}
}
return uint64(nn), nil
}
func parseInt(s string) (int64, error) {
switch {
case strings.EqualFold(s, "inf"), strings.EqualFold(s, "+inf"):
return math.MaxInt64, nil
case strings.EqualFold(s, "-inf"):
return math.MinInt64, nil
}
n, err := strconv.ParseInt(s, 0, 64)
if err == nil {
return n, nil
}
nn, ok := tryParseBytes(s)
if !ok {
nn, ok = tryParseDuration(s)
if !ok {
return 0, fmt.Errorf("cannot parse %q as integer: %w", s, err)
}
}
return nn, nil
}
func nextafter(f, xInf float64) float64 {
if math.IsInf(f, 0) {
return f
}
return math.Nextafter(f, xInf)
}