// Copyright 2017 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. //go:generate go get -u modernc.org/golex //go:generate golex -o=promlex.l.go promlex.l package textparse import ( "errors" "fmt" "io" "math" "strconv" "strings" "unicode/utf8" "unsafe" "github.com/prometheus/prometheus/model/exemplar" "github.com/prometheus/prometheus/model/histogram" "github.com/prometheus/prometheus/model/labels" "github.com/prometheus/prometheus/model/value" ) type promlexer struct { b []byte i int start int err error state int } type token int const ( tInvalid token = -1 tEOF token = 0 tLinebreak token = iota tWhitespace tHelp tType tUnit tEOFWord tText tComment tBlank tMName tBraceOpen tBraceClose tLName tLValue tComma tEqual tTimestamp tValue ) func (t token) String() string { switch t { case tInvalid: return "INVALID" case tEOF: return "EOF" case tLinebreak: return "LINEBREAK" case tWhitespace: return "WHITESPACE" case tHelp: return "HELP" case tType: return "TYPE" case tUnit: return "UNIT" case tEOFWord: return "EOFWORD" case tText: return "TEXT" case tComment: return "COMMENT" case tBlank: return "BLANK" case tMName: return "MNAME" case tBraceOpen: return "BOPEN" case tBraceClose: return "BCLOSE" case tLName: return "LNAME" case tLValue: return "LVALUE" case tEqual: return "EQUAL" case tComma: return "COMMA" case tTimestamp: return "TIMESTAMP" case tValue: return "VALUE" } return fmt.Sprintf("", t) } // buf returns the buffer of the current token. func (l *promlexer) buf() []byte { return l.b[l.start:l.i] } func (l *promlexer) cur() byte { return l.b[l.i] } // next advances the promlexer to the next character. func (l *promlexer) next() byte { l.i++ if l.i >= len(l.b) { l.err = io.EOF return byte(tEOF) } // Lex struggles with null bytes. If we are in a label value or help string, where // they are allowed, consume them here immediately. for l.b[l.i] == 0 && (l.state == sLValue || l.state == sMeta2 || l.state == sComment) { l.i++ } return l.b[l.i] } func (l *promlexer) Error(es string) { l.err = errors.New(es) } // PromParser parses samples from a byte slice of samples in the official // Prometheus text exposition format. type PromParser struct { l *promlexer builder labels.ScratchBuilder series []byte text []byte mtype MetricType val float64 ts int64 hasTS bool start int offsets []int } // NewPromParser returns a new parser of the byte slice. func NewPromParser(b []byte) Parser { return &PromParser{l: &promlexer{b: append(b, '\n')}} } // Series returns the bytes of the series, the timestamp if set, and the value // of the current sample. func (p *PromParser) Series() ([]byte, *int64, float64) { if p.hasTS { return p.series, &p.ts, p.val } return p.series, nil, p.val } // Histogram returns (nil, nil, nil, nil) for now because the Prometheus text // format does not support sparse histograms yet. func (p *PromParser) Histogram() ([]byte, *int64, *histogram.Histogram, *histogram.FloatHistogram) { return nil, nil, nil, nil } // Help returns the metric name and help text in the current entry. // Must only be called after Next returned a help entry. // The returned byte slices become invalid after the next call to Next. func (p *PromParser) Help() ([]byte, []byte) { m := p.l.b[p.offsets[0]:p.offsets[1]] // Replacer causes allocations. Replace only when necessary. if strings.IndexByte(yoloString(p.text), byte('\\')) >= 0 { return m, []byte(helpReplacer.Replace(string(p.text))) } return m, p.text } // Type returns the metric name and type in the current entry. // Must only be called after Next returned a type entry. // The returned byte slices become invalid after the next call to Next. func (p *PromParser) Type() ([]byte, MetricType) { return p.l.b[p.offsets[0]:p.offsets[1]], p.mtype } // Unit returns the metric name and unit in the current entry. // Must only be called after Next returned a unit entry. // The returned byte slices become invalid after the next call to Next. func (p *PromParser) Unit() ([]byte, []byte) { // The Prometheus format does not have units. return nil, nil } // Comment returns the text of the current comment. // Must only be called after Next returned a comment entry. // The returned byte slice becomes invalid after the next call to Next. func (p *PromParser) Comment() []byte { return p.text } // Metric writes the labels of the current sample into the passed labels. // It returns the string from which the metric was parsed. func (p *PromParser) Metric(l *labels.Labels) string { // Copy the buffer to a string: this is only necessary for the return value. s := string(p.series) p.builder.Reset() p.builder.Add(labels.MetricName, s[:p.offsets[0]-p.start]) for i := 1; i < len(p.offsets); i += 4 { a := p.offsets[i] - p.start b := p.offsets[i+1] - p.start c := p.offsets[i+2] - p.start d := p.offsets[i+3] - p.start value := s[c:d] // Replacer causes allocations. Replace only when necessary. if strings.IndexByte(s[c:d], byte('\\')) >= 0 { value = lvalReplacer.Replace(value) } p.builder.Add(s[a:b], value) } p.builder.Sort() *l = p.builder.Labels() return s } // Exemplar implements the Parser interface. However, since the classic // Prometheus text format does not support exemplars, this implementation simply // returns false and does nothing else. func (p *PromParser) Exemplar(*exemplar.Exemplar) bool { return false } // nextToken returns the next token from the promlexer. It skips over tabs // and spaces. func (p *PromParser) nextToken() token { for { if tok := p.l.Lex(); tok != tWhitespace { return tok } } } func (p *PromParser) parseError(exp string, got token) error { e := p.l.i + 1 if len(p.l.b) < e { e = len(p.l.b) } return fmt.Errorf("%s, got %q (%q) while parsing: %q", exp, p.l.b[p.l.start:e], got, p.l.b[p.start:e]) } // Next advances the parser to the next sample. It returns false if no // more samples were read or an error occurred. func (p *PromParser) Next() (Entry, error) { var err error p.start = p.l.i p.offsets = p.offsets[:0] switch t := p.nextToken(); t { case tEOF: return EntryInvalid, io.EOF case tLinebreak: // Allow full blank lines. return p.Next() case tHelp, tType: switch t2 := p.nextToken(); t2 { case tMName: p.offsets = append(p.offsets, p.l.start, p.l.i) default: return EntryInvalid, p.parseError("expected metric name after "+t.String(), t2) } switch t2 := p.nextToken(); t2 { case tText: if len(p.l.buf()) > 1 { p.text = p.l.buf()[1:] } else { p.text = []byte{} } default: return EntryInvalid, fmt.Errorf("expected text in %s", t.String()) } switch t { case tType: switch s := yoloString(p.text); s { case "counter": p.mtype = MetricTypeCounter case "gauge": p.mtype = MetricTypeGauge case "histogram": p.mtype = MetricTypeHistogram case "summary": p.mtype = MetricTypeSummary case "untyped": p.mtype = MetricTypeUnknown default: return EntryInvalid, fmt.Errorf("invalid metric type %q", s) } case tHelp: if !utf8.Valid(p.text) { return EntryInvalid, fmt.Errorf("help text %q is not a valid utf8 string", p.text) } } if t := p.nextToken(); t != tLinebreak { return EntryInvalid, p.parseError("linebreak expected after metadata", t) } switch t { case tHelp: return EntryHelp, nil case tType: return EntryType, nil } case tComment: p.text = p.l.buf() if t := p.nextToken(); t != tLinebreak { return EntryInvalid, p.parseError("linebreak expected after comment", t) } return EntryComment, nil case tMName: p.offsets = append(p.offsets, p.l.i) p.series = p.l.b[p.start:p.l.i] t2 := p.nextToken() if t2 == tBraceOpen { if err := p.parseLVals(); err != nil { return EntryInvalid, err } p.series = p.l.b[p.start:p.l.i] t2 = p.nextToken() } if t2 != tValue { return EntryInvalid, p.parseError("expected value after metric", t2) } if p.val, err = parseFloat(yoloString(p.l.buf())); err != nil { return EntryInvalid, fmt.Errorf("%w while parsing: %q", err, p.l.b[p.start:p.l.i]) } // Ensure canonical NaN value. if math.IsNaN(p.val) { p.val = math.Float64frombits(value.NormalNaN) } p.hasTS = false switch t := p.nextToken(); t { case tLinebreak: break case tTimestamp: p.hasTS = true if p.ts, err = strconv.ParseInt(yoloString(p.l.buf()), 10, 64); err != nil { return EntryInvalid, fmt.Errorf("%w while parsing: %q", err, p.l.b[p.start:p.l.i]) } if t2 := p.nextToken(); t2 != tLinebreak { return EntryInvalid, p.parseError("expected next entry after timestamp", t2) } default: return EntryInvalid, p.parseError("expected timestamp or new record", t) } return EntrySeries, nil default: err = p.parseError("expected a valid start token", t) } return EntryInvalid, err } func (p *PromParser) parseLVals() error { t := p.nextToken() for { switch t { case tBraceClose: return nil case tLName: default: return p.parseError("expected label name", t) } p.offsets = append(p.offsets, p.l.start, p.l.i) if t := p.nextToken(); t != tEqual { return p.parseError("expected equal", t) } if t := p.nextToken(); t != tLValue { return p.parseError("expected label value", t) } if !utf8.Valid(p.l.buf()) { return fmt.Errorf("invalid UTF-8 label value: %q", p.l.buf()) } // The promlexer ensures the value string is quoted. Strip first // and last character. p.offsets = append(p.offsets, p.l.start+1, p.l.i-1) // Free trailing commas are allowed. if t = p.nextToken(); t == tComma { t = p.nextToken() } } } var lvalReplacer = strings.NewReplacer( `\"`, "\"", `\\`, "\\", `\n`, "\n", ) var helpReplacer = strings.NewReplacer( `\\`, "\\", `\n`, "\n", ) func yoloString(b []byte) string { return *((*string)(unsafe.Pointer(&b))) } func parseFloat(s string) (float64, error) { // Keep to pre-Go 1.13 float formats. if strings.ContainsAny(s, "pP_") { return 0, fmt.Errorf("unsupported character in float") } return strconv.ParseFloat(s, 64) }