telegraf/metric/metric.go

586 lines
12 KiB
Go

package metric
import (
"bytes"
"fmt"
"hash/fnv"
"sort"
"strconv"
"time"
"github.com/influxdata/telegraf"
)
const MaxInt = int(^uint(0) >> 1)
func New(
name string,
tags map[string]string,
fields map[string]interface{},
t time.Time,
mType ...telegraf.ValueType,
) (telegraf.Metric, error) {
if len(fields) == 0 {
return nil, fmt.Errorf("Metric cannot be made without any fields")
}
if len(name) == 0 {
return nil, fmt.Errorf("Metric cannot be made with an empty name")
}
var thisType telegraf.ValueType
if len(mType) > 0 {
thisType = mType[0]
} else {
thisType = telegraf.Untyped
}
m := &metric{
name: []byte(escape(name, "name")),
t: []byte(fmt.Sprint(t.UnixNano())),
nsec: t.UnixNano(),
mType: thisType,
}
// pre-allocate exact size of the tags slice
taglen := 0
for k, v := range tags {
if len(k) == 0 || len(v) == 0 {
continue
}
taglen += 2 + len(escape(k, "tagkey")) + len(escape(v, "tagval"))
}
m.tags = make([]byte, taglen)
i := 0
for k, v := range tags {
if len(k) == 0 || len(v) == 0 {
continue
}
m.tags[i] = ','
i++
i += copy(m.tags[i:], escape(k, "tagkey"))
m.tags[i] = '='
i++
i += copy(m.tags[i:], escape(v, "tagval"))
}
// pre-allocate capacity of the fields slice
fieldlen := 0
for k, _ := range fields {
// 10 bytes is completely arbitrary, but will at least prevent some
// amount of allocations. There's a small possibility this will create
// slightly more allocations for a metric that has many short fields.
fieldlen += len(k) + 10
}
m.fields = make([]byte, 0, fieldlen)
i = 0
for k, v := range fields {
if i != 0 {
m.fields = append(m.fields, ',')
}
m.fields = appendField(m.fields, k, v)
i++
}
return m, nil
}
// indexUnescapedByte finds the index of the first byte equal to b in buf that
// is not escaped. Returns -1 if not found.
func indexUnescapedByte(buf []byte, b byte) int {
var keyi int
for {
i := bytes.IndexByte(buf[keyi:], b)
if i == -1 {
return -1
} else if i == 0 {
break
}
keyi += i
if countBackslashes(buf, keyi-1)%2 == 0 {
break
} else {
keyi++
}
}
return keyi
}
// countBackslashes counts the number of preceding backslashes starting at
// the 'start' index.
func countBackslashes(buf []byte, index int) int {
var count int
for {
if index < 0 {
return count
}
if buf[index] == '\\' {
count++
index--
} else {
break
}
}
return count
}
type metric struct {
name []byte
tags []byte
fields []byte
t []byte
mType telegraf.ValueType
aggregate bool
// cached values for reuse in "get" functions
hashID uint64
nsec int64
}
func (m *metric) String() string {
return string(m.name) + string(m.tags) + " " + string(m.fields) + " " + string(m.t) + "\n"
}
func (m *metric) SetAggregate(b bool) {
m.aggregate = b
}
func (m *metric) IsAggregate() bool {
return m.aggregate
}
func (m *metric) Type() telegraf.ValueType {
return m.mType
}
func (m *metric) Len() int {
// 3 is for 2 spaces surrounding the fields array + newline at the end.
return len(m.name) + len(m.tags) + len(m.fields) + len(m.t) + 3
}
func (m *metric) Serialize() []byte {
tmp := make([]byte, m.Len())
i := 0
i += copy(tmp[i:], m.name)
i += copy(tmp[i:], m.tags)
tmp[i] = ' '
i++
i += copy(tmp[i:], m.fields)
tmp[i] = ' '
i++
i += copy(tmp[i:], m.t)
tmp[i] = '\n'
return tmp
}
func (m *metric) SerializeTo(dst []byte) int {
i := 0
if i >= len(dst) {
return i
}
i += copy(dst[i:], m.name)
if i >= len(dst) {
return i
}
i += copy(dst[i:], m.tags)
if i >= len(dst) {
return i
}
dst[i] = ' '
i++
if i >= len(dst) {
return i
}
i += copy(dst[i:], m.fields)
if i >= len(dst) {
return i
}
dst[i] = ' '
i++
if i >= len(dst) {
return i
}
i += copy(dst[i:], m.t)
if i >= len(dst) {
return i
}
dst[i] = '\n'
return i + 1
}
func (m *metric) Split(maxSize int) []telegraf.Metric {
if m.Len() < maxSize {
return []telegraf.Metric{m}
}
var out []telegraf.Metric
// constant number of bytes for each metric (in addition to field bytes)
constant := len(m.name) + len(m.tags) + len(m.t) + 3
// currently selected fields
fields := make([]byte, 0, maxSize)
i := 0
for {
if i >= len(m.fields) {
// hit the end of the field byte slice
if len(fields) > 0 {
out = append(out, copyWith(m.name, m.tags, fields, m.t))
}
break
}
// find the end of the next field
j := indexUnescapedByte(m.fields[i:], ',')
if j == -1 {
j = len(m.fields)
} else {
j += i
}
// if true, then we need to create a metric _not_ including the currently
// selected field
if len(m.fields[i:j])+len(fields)+constant > maxSize {
// if false, then we'll create a metric including the currently
// selected field anyways. This means that the given maxSize is too
// small for a single field to fit.
if len(fields) > 0 {
out = append(out, copyWith(m.name, m.tags, fields, m.t))
}
fields = make([]byte, 0, maxSize)
}
if len(fields) > 0 {
fields = append(fields, ',')
}
fields = append(fields, m.fields[i:j]...)
i = j + 1
}
return out
}
func (m *metric) Fields() map[string]interface{} {
fieldMap := map[string]interface{}{}
i := 0
for {
if i >= len(m.fields) {
break
}
// end index of field key
i1 := indexUnescapedByte(m.fields[i:], '=')
if i1 == -1 {
break
}
// start index of field value
i2 := i1 + 1
// end index of field value
var i3 int
if m.fields[i:][i2] == '"' {
i3 = indexUnescapedByte(m.fields[i:][i2+1:], '"')
if i3 == -1 {
i3 = len(m.fields[i:])
}
i3 += i2 + 2 // increment index to the comma
} else {
i3 = indexUnescapedByte(m.fields[i:], ',')
if i3 == -1 {
i3 = len(m.fields[i:])
}
}
switch m.fields[i:][i2] {
case '"':
// string field
fieldMap[unescape(string(m.fields[i:][0:i1]), "fieldkey")] = unescape(string(m.fields[i:][i2+1:i3-1]), "fieldval")
case '-', '0', '1', '2', '3', '4', '5', '6', '7', '8', '9':
// number field
switch m.fields[i:][i3-1] {
case 'i':
// integer field
n, err := parseIntBytes(m.fields[i:][i2:i3-1], 10, 64)
if err == nil {
fieldMap[unescape(string(m.fields[i:][0:i1]), "fieldkey")] = n
} else {
// TODO handle error or just ignore field silently?
}
default:
// float field
n, err := parseFloatBytes(m.fields[i:][i2:i3], 64)
if err == nil {
fieldMap[unescape(string(m.fields[i:][0:i1]), "fieldkey")] = n
} else {
// TODO handle error or just ignore field silently?
}
}
case 'T', 't':
fieldMap[unescape(string(m.fields[i:][0:i1]), "fieldkey")] = true
case 'F', 'f':
fieldMap[unescape(string(m.fields[i:][0:i1]), "fieldkey")] = false
default:
// TODO handle unsupported field type
}
i += i3 + 1
}
return fieldMap
}
func (m *metric) Tags() map[string]string {
tagMap := map[string]string{}
if len(m.tags) == 0 {
return tagMap
}
i := 0
for {
// start index of tag key
i0 := indexUnescapedByte(m.tags[i:], ',') + 1
if i0 == 0 {
// didn't find a tag start
break
}
// end index of tag key
i1 := indexUnescapedByte(m.tags[i:], '=')
// start index of tag value
i2 := i1 + 1
// end index of tag value (starting from i2)
i3 := indexUnescapedByte(m.tags[i+i2:], ',')
if i3 == -1 {
tagMap[unescape(string(m.tags[i:][i0:i1]), "tagkey")] = unescape(string(m.tags[i:][i2:]), "tagval")
break
}
tagMap[unescape(string(m.tags[i:][i0:i1]), "tagkey")] = unescape(string(m.tags[i:][i2:i2+i3]), "tagval")
// increment start index for the next tag
i += i2 + i3
}
return tagMap
}
func (m *metric) Name() string {
return unescape(string(m.name), "name")
}
func (m *metric) Time() time.Time {
// assume metric has been verified already and ignore error:
if m.nsec == 0 {
m.nsec, _ = parseIntBytes(m.t, 10, 64)
}
return time.Unix(0, m.nsec)
}
func (m *metric) UnixNano() int64 {
// assume metric has been verified already and ignore error:
if m.nsec == 0 {
m.nsec, _ = parseIntBytes(m.t, 10, 64)
}
return m.nsec
}
func (m *metric) SetName(name string) {
m.hashID = 0
m.name = []byte(nameEscaper.Replace(name))
}
func (m *metric) SetPrefix(prefix string) {
m.hashID = 0
m.name = append([]byte(nameEscaper.Replace(prefix)), m.name...)
}
func (m *metric) SetSuffix(suffix string) {
m.hashID = 0
m.name = append(m.name, []byte(nameEscaper.Replace(suffix))...)
}
func (m *metric) AddTag(key, value string) {
m.RemoveTag(key)
m.tags = append(m.tags, []byte(","+escape(key, "tagkey")+"="+escape(value, "tagval"))...)
}
func (m *metric) HasTag(key string) bool {
i := bytes.Index(m.tags, []byte(escape(key, "tagkey")+"="))
if i == -1 {
return false
}
return true
}
func (m *metric) RemoveTag(key string) {
m.hashID = 0
i := bytes.Index(m.tags, []byte(escape(key, "tagkey")+"="))
if i == -1 {
return
}
tmp := m.tags[0 : i-1]
j := indexUnescapedByte(m.tags[i:], ',')
if j != -1 {
tmp = append(tmp, m.tags[i+j:]...)
}
m.tags = tmp
return
}
func (m *metric) AddField(key string, value interface{}) {
m.fields = append(m.fields, ',')
m.fields = appendField(m.fields, key, value)
}
func (m *metric) HasField(key string) bool {
i := bytes.Index(m.fields, []byte(escape(key, "tagkey")+"="))
if i == -1 {
return false
}
return true
}
func (m *metric) RemoveField(key string) error {
i := bytes.Index(m.fields, []byte(escape(key, "tagkey")+"="))
if i == -1 {
return nil
}
var tmp []byte
if i != 0 {
tmp = m.fields[0 : i-1]
}
j := indexUnescapedByte(m.fields[i:], ',')
if j != -1 {
tmp = append(tmp, m.fields[i+j:]...)
}
if len(tmp) == 0 {
return fmt.Errorf("Metric cannot remove final field: %s", m.fields)
}
m.fields = tmp
return nil
}
func (m *metric) Copy() telegraf.Metric {
return copyWith(m.name, m.tags, m.fields, m.t)
}
func copyWith(name, tags, fields, t []byte) telegraf.Metric {
out := metric{
name: make([]byte, len(name)),
tags: make([]byte, len(tags)),
fields: make([]byte, len(fields)),
t: make([]byte, len(t)),
}
copy(out.name, name)
copy(out.tags, tags)
copy(out.fields, fields)
copy(out.t, t)
return &out
}
func (m *metric) HashID() uint64 {
if m.hashID == 0 {
h := fnv.New64a()
h.Write(m.name)
tags := m.Tags()
tmp := make([]string, len(tags))
i := 0
for k, v := range tags {
tmp[i] = k + v
i++
}
sort.Strings(tmp)
for _, s := range tmp {
h.Write([]byte(s))
}
m.hashID = h.Sum64()
}
return m.hashID
}
func appendField(b []byte, k string, v interface{}) []byte {
if v == nil {
return b
}
b = append(b, []byte(escape(k, "tagkey")+"=")...)
// check popular types first
switch v := v.(type) {
case float64:
b = strconv.AppendFloat(b, v, 'f', -1, 64)
case int64:
b = strconv.AppendInt(b, v, 10)
b = append(b, 'i')
case string:
b = append(b, '"')
b = append(b, []byte(escape(v, "fieldval"))...)
b = append(b, '"')
case bool:
b = strconv.AppendBool(b, v)
case int32:
b = strconv.AppendInt(b, int64(v), 10)
b = append(b, 'i')
case int16:
b = strconv.AppendInt(b, int64(v), 10)
b = append(b, 'i')
case int8:
b = strconv.AppendInt(b, int64(v), 10)
b = append(b, 'i')
case int:
b = strconv.AppendInt(b, int64(v), 10)
b = append(b, 'i')
case uint64:
// Cap uints above the maximum int value
var intv int64
if v <= uint64(MaxInt) {
intv = int64(v)
} else {
intv = int64(MaxInt)
}
b = strconv.AppendInt(b, intv, 10)
b = append(b, 'i')
case uint32:
b = strconv.AppendInt(b, int64(v), 10)
b = append(b, 'i')
case uint16:
b = strconv.AppendInt(b, int64(v), 10)
b = append(b, 'i')
case uint8:
b = strconv.AppendInt(b, int64(v), 10)
b = append(b, 'i')
case uint:
// Cap uints above the maximum int value
var intv int64
if v <= uint(MaxInt) {
intv = int64(v)
} else {
intv = int64(MaxInt)
}
b = strconv.AppendInt(b, intv, 10)
b = append(b, 'i')
case float32:
b = strconv.AppendFloat(b, float64(v), 'f', -1, 32)
case []byte:
b = append(b, v...)
default:
// Can't determine the type, so convert to string
b = append(b, '"')
b = append(b, []byte(escape(fmt.Sprintf("%v", v), "fieldval"))...)
b = append(b, '"')
}
return b
}