op-geth/vendor/github.com/influxdata/influxdb/models/points.go

2338 lines
57 KiB
Go

// Package models implements basic objects used throughout the TICK stack.
package models // import "github.com/influxdata/influxdb/models"
import (
"bytes"
"encoding/binary"
"errors"
"fmt"
"io"
"math"
"sort"
"strconv"
"strings"
"time"
"github.com/influxdata/influxdb/pkg/escape"
)
var (
measurementEscapeCodes = map[byte][]byte{
',': []byte(`\,`),
' ': []byte(`\ `),
}
tagEscapeCodes = map[byte][]byte{
',': []byte(`\,`),
' ': []byte(`\ `),
'=': []byte(`\=`),
}
// ErrPointMustHaveAField is returned when operating on a point that does not have any fields.
ErrPointMustHaveAField = errors.New("point without fields is unsupported")
// ErrInvalidNumber is returned when a number is expected but not provided.
ErrInvalidNumber = errors.New("invalid number")
// ErrInvalidPoint is returned when a point cannot be parsed correctly.
ErrInvalidPoint = errors.New("point is invalid")
)
const (
// MaxKeyLength is the largest allowed size of the combined measurement and tag keys.
MaxKeyLength = 65535
)
// enableUint64Support will enable uint64 support if set to true.
var enableUint64Support = false
// EnableUintSupport manually enables uint support for the point parser.
// This function will be removed in the future and only exists for unit tests during the
// transition.
func EnableUintSupport() {
enableUint64Support = true
}
// Point defines the values that will be written to the database.
type Point interface {
// Name return the measurement name for the point.
Name() []byte
// SetName updates the measurement name for the point.
SetName(string)
// Tags returns the tag set for the point.
Tags() Tags
// AddTag adds or replaces a tag value for a point.
AddTag(key, value string)
// SetTags replaces the tags for the point.
SetTags(tags Tags)
// HasTag returns true if the tag exists for the point.
HasTag(tag []byte) bool
// Fields returns the fields for the point.
Fields() (Fields, error)
// Time return the timestamp for the point.
Time() time.Time
// SetTime updates the timestamp for the point.
SetTime(t time.Time)
// UnixNano returns the timestamp of the point as nanoseconds since Unix epoch.
UnixNano() int64
// HashID returns a non-cryptographic checksum of the point's key.
HashID() uint64
// Key returns the key (measurement joined with tags) of the point.
Key() []byte
// String returns a string representation of the point. If there is a
// timestamp associated with the point then it will be specified with the default
// precision of nanoseconds.
String() string
// MarshalBinary returns a binary representation of the point.
MarshalBinary() ([]byte, error)
// PrecisionString returns a string representation of the point. If there
// is a timestamp associated with the point then it will be specified in the
// given unit.
PrecisionString(precision string) string
// RoundedString returns a string representation of the point. If there
// is a timestamp associated with the point, then it will be rounded to the
// given duration.
RoundedString(d time.Duration) string
// Split will attempt to return multiple points with the same timestamp whose
// string representations are no longer than size. Points with a single field or
// a point without a timestamp may exceed the requested size.
Split(size int) []Point
// Round will round the timestamp of the point to the given duration.
Round(d time.Duration)
// StringSize returns the length of the string that would be returned by String().
StringSize() int
// AppendString appends the result of String() to the provided buffer and returns
// the result, potentially reducing string allocations.
AppendString(buf []byte) []byte
// FieldIterator retuns a FieldIterator that can be used to traverse the
// fields of a point without constructing the in-memory map.
FieldIterator() FieldIterator
}
// FieldType represents the type of a field.
type FieldType int
const (
// Integer indicates the field's type is integer.
Integer FieldType = iota
// Float indicates the field's type is float.
Float
// Boolean indicates the field's type is boolean.
Boolean
// String indicates the field's type is string.
String
// Empty is used to indicate that there is no field.
Empty
// Unsigned indicates the field's type is an unsigned integer.
Unsigned
)
// FieldIterator provides a low-allocation interface to iterate through a point's fields.
type FieldIterator interface {
// Next indicates whether there any fields remaining.
Next() bool
// FieldKey returns the key of the current field.
FieldKey() []byte
// Type returns the FieldType of the current field.
Type() FieldType
// StringValue returns the string value of the current field.
StringValue() string
// IntegerValue returns the integer value of the current field.
IntegerValue() (int64, error)
// UnsignedValue returns the unsigned value of the current field.
UnsignedValue() (uint64, error)
// BooleanValue returns the boolean value of the current field.
BooleanValue() (bool, error)
// FloatValue returns the float value of the current field.
FloatValue() (float64, error)
// Reset resets the iterator to its initial state.
Reset()
}
// Points represents a sortable list of points by timestamp.
type Points []Point
// Len implements sort.Interface.
func (a Points) Len() int { return len(a) }
// Less implements sort.Interface.
func (a Points) Less(i, j int) bool { return a[i].Time().Before(a[j].Time()) }
// Swap implements sort.Interface.
func (a Points) Swap(i, j int) { a[i], a[j] = a[j], a[i] }
// point is the default implementation of Point.
type point struct {
time time.Time
// text encoding of measurement and tags
// key must always be stored sorted by tags, if the original line was not sorted,
// we need to resort it
key []byte
// text encoding of field data
fields []byte
// text encoding of timestamp
ts []byte
// cached version of parsed fields from data
cachedFields map[string]interface{}
// cached version of parsed name from key
cachedName string
// cached version of parsed tags
cachedTags Tags
it fieldIterator
}
// type assertions
var (
_ Point = (*point)(nil)
_ FieldIterator = (*point)(nil)
)
const (
// the number of characters for the largest possible int64 (9223372036854775807)
maxInt64Digits = 19
// the number of characters for the smallest possible int64 (-9223372036854775808)
minInt64Digits = 20
// the number of characters for the largest possible uint64 (18446744073709551615)
maxUint64Digits = 20
// the number of characters required for the largest float64 before a range check
// would occur during parsing
maxFloat64Digits = 25
// the number of characters required for smallest float64 before a range check occur
// would occur during parsing
minFloat64Digits = 27
)
// ParsePoints returns a slice of Points from a text representation of a point
// with each point separated by newlines. If any points fail to parse, a non-nil error
// will be returned in addition to the points that parsed successfully.
func ParsePoints(buf []byte) ([]Point, error) {
return ParsePointsWithPrecision(buf, time.Now().UTC(), "n")
}
// ParsePointsString is identical to ParsePoints but accepts a string.
func ParsePointsString(buf string) ([]Point, error) {
return ParsePoints([]byte(buf))
}
// ParseKey returns the measurement name and tags from a point.
//
// NOTE: to minimize heap allocations, the returned Tags will refer to subslices of buf.
// This can have the unintended effect preventing buf from being garbage collected.
func ParseKey(buf []byte) (string, Tags) {
meas, tags := ParseKeyBytes(buf)
return string(meas), tags
}
func ParseKeyBytes(buf []byte) ([]byte, Tags) {
// Ignore the error because scanMeasurement returns "missing fields" which we ignore
// when just parsing a key
state, i, _ := scanMeasurement(buf, 0)
var tags Tags
if state == tagKeyState {
tags = parseTags(buf)
// scanMeasurement returns the location of the comma if there are tags, strip that off
return buf[:i-1], tags
}
return buf[:i], tags
}
func ParseTags(buf []byte) Tags {
return parseTags(buf)
}
func ParseName(buf []byte) ([]byte, error) {
// Ignore the error because scanMeasurement returns "missing fields" which we ignore
// when just parsing a key
state, i, _ := scanMeasurement(buf, 0)
if state == tagKeyState {
return buf[:i-1], nil
}
return buf[:i], nil
}
// ParsePointsWithPrecision is similar to ParsePoints, but allows the
// caller to provide a precision for time.
//
// NOTE: to minimize heap allocations, the returned Points will refer to subslices of buf.
// This can have the unintended effect preventing buf from being garbage collected.
func ParsePointsWithPrecision(buf []byte, defaultTime time.Time, precision string) ([]Point, error) {
points := make([]Point, 0, bytes.Count(buf, []byte{'\n'})+1)
var (
pos int
block []byte
failed []string
)
for pos < len(buf) {
pos, block = scanLine(buf, pos)
pos++
if len(block) == 0 {
continue
}
// lines which start with '#' are comments
start := skipWhitespace(block, 0)
// If line is all whitespace, just skip it
if start >= len(block) {
continue
}
if block[start] == '#' {
continue
}
// strip the newline if one is present
if block[len(block)-1] == '\n' {
block = block[:len(block)-1]
}
pt, err := parsePoint(block[start:], defaultTime, precision)
if err != nil {
failed = append(failed, fmt.Sprintf("unable to parse '%s': %v", string(block[start:]), err))
} else {
points = append(points, pt)
}
}
if len(failed) > 0 {
return points, fmt.Errorf("%s", strings.Join(failed, "\n"))
}
return points, nil
}
func parsePoint(buf []byte, defaultTime time.Time, precision string) (Point, error) {
// scan the first block which is measurement[,tag1=value1,tag2=value=2...]
pos, key, err := scanKey(buf, 0)
if err != nil {
return nil, err
}
// measurement name is required
if len(key) == 0 {
return nil, fmt.Errorf("missing measurement")
}
if len(key) > MaxKeyLength {
return nil, fmt.Errorf("max key length exceeded: %v > %v", len(key), MaxKeyLength)
}
// scan the second block is which is field1=value1[,field2=value2,...]
pos, fields, err := scanFields(buf, pos)
if err != nil {
return nil, err
}
// at least one field is required
if len(fields) == 0 {
return nil, fmt.Errorf("missing fields")
}
var maxKeyErr error
walkFields(fields, func(k, v []byte) bool {
if sz := seriesKeySize(key, k); sz > MaxKeyLength {
maxKeyErr = fmt.Errorf("max key length exceeded: %v > %v", sz, MaxKeyLength)
return false
}
return true
})
if maxKeyErr != nil {
return nil, maxKeyErr
}
// scan the last block which is an optional integer timestamp
pos, ts, err := scanTime(buf, pos)
if err != nil {
return nil, err
}
pt := &point{
key: key,
fields: fields,
ts: ts,
}
if len(ts) == 0 {
pt.time = defaultTime
pt.SetPrecision(precision)
} else {
ts, err := parseIntBytes(ts, 10, 64)
if err != nil {
return nil, err
}
pt.time, err = SafeCalcTime(ts, precision)
if err != nil {
return nil, err
}
// Determine if there are illegal non-whitespace characters after the
// timestamp block.
for pos < len(buf) {
if buf[pos] != ' ' {
return nil, ErrInvalidPoint
}
pos++
}
}
return pt, nil
}
// GetPrecisionMultiplier will return a multiplier for the precision specified.
func GetPrecisionMultiplier(precision string) int64 {
d := time.Nanosecond
switch precision {
case "u":
d = time.Microsecond
case "ms":
d = time.Millisecond
case "s":
d = time.Second
case "m":
d = time.Minute
case "h":
d = time.Hour
}
return int64(d)
}
// scanKey scans buf starting at i for the measurement and tag portion of the point.
// It returns the ending position and the byte slice of key within buf. If there
// are tags, they will be sorted if they are not already.
func scanKey(buf []byte, i int) (int, []byte, error) {
start := skipWhitespace(buf, i)
i = start
// Determines whether the tags are sort, assume they are
sorted := true
// indices holds the indexes within buf of the start of each tag. For example,
// a buf of 'cpu,host=a,region=b,zone=c' would have indices slice of [4,11,20]
// which indicates that the first tag starts at buf[4], seconds at buf[11], and
// last at buf[20]
indices := make([]int, 100)
// tracks how many commas we've seen so we know how many values are indices.
// Since indices is an arbitrarily large slice,
// we need to know how many values in the buffer are in use.
commas := 0
// First scan the Point's measurement.
state, i, err := scanMeasurement(buf, i)
if err != nil {
return i, buf[start:i], err
}
// Optionally scan tags if needed.
if state == tagKeyState {
i, commas, indices, err = scanTags(buf, i, indices)
if err != nil {
return i, buf[start:i], err
}
}
// Now we know where the key region is within buf, and the location of tags, we
// need to determine if duplicate tags exist and if the tags are sorted. This iterates
// over the list comparing each tag in the sequence with each other.
for j := 0; j < commas-1; j++ {
// get the left and right tags
_, left := scanTo(buf[indices[j]:indices[j+1]-1], 0, '=')
_, right := scanTo(buf[indices[j+1]:indices[j+2]-1], 0, '=')
// If left is greater than right, the tags are not sorted. We do not have to
// continue because the short path no longer works.
// If the tags are equal, then there are duplicate tags, and we should abort.
// If the tags are not sorted, this pass may not find duplicate tags and we
// need to do a more exhaustive search later.
if cmp := bytes.Compare(left, right); cmp > 0 {
sorted = false
break
} else if cmp == 0 {
return i, buf[start:i], fmt.Errorf("duplicate tags")
}
}
// If the tags are not sorted, then sort them. This sort is inline and
// uses the tag indices we created earlier. The actual buffer is not sorted, the
// indices are using the buffer for value comparison. After the indices are sorted,
// the buffer is reconstructed from the sorted indices.
if !sorted && commas > 0 {
// Get the measurement name for later
measurement := buf[start : indices[0]-1]
// Sort the indices
indices := indices[:commas]
insertionSort(0, commas, buf, indices)
// Create a new key using the measurement and sorted indices
b := make([]byte, len(buf[start:i]))
pos := copy(b, measurement)
for _, i := range indices {
b[pos] = ','
pos++
_, v := scanToSpaceOr(buf, i, ',')
pos += copy(b[pos:], v)
}
// Check again for duplicate tags now that the tags are sorted.
for j := 0; j < commas-1; j++ {
// get the left and right tags
_, left := scanTo(buf[indices[j]:], 0, '=')
_, right := scanTo(buf[indices[j+1]:], 0, '=')
// If the tags are equal, then there are duplicate tags, and we should abort.
// If the tags are not sorted, this pass may not find duplicate tags and we
// need to do a more exhaustive search later.
if bytes.Equal(left, right) {
return i, b, fmt.Errorf("duplicate tags")
}
}
return i, b, nil
}
return i, buf[start:i], nil
}
// The following constants allow us to specify which state to move to
// next, when scanning sections of a Point.
const (
tagKeyState = iota
tagValueState
fieldsState
)
// scanMeasurement examines the measurement part of a Point, returning
// the next state to move to, and the current location in the buffer.
func scanMeasurement(buf []byte, i int) (int, int, error) {
// Check first byte of measurement, anything except a comma is fine.
// It can't be a space, since whitespace is stripped prior to this
// function call.
if i >= len(buf) || buf[i] == ',' {
return -1, i, fmt.Errorf("missing measurement")
}
for {
i++
if i >= len(buf) {
// cpu
return -1, i, fmt.Errorf("missing fields")
}
if buf[i-1] == '\\' {
// Skip character (it's escaped).
continue
}
// Unescaped comma; move onto scanning the tags.
if buf[i] == ',' {
return tagKeyState, i + 1, nil
}
// Unescaped space; move onto scanning the fields.
if buf[i] == ' ' {
// cpu value=1.0
return fieldsState, i, nil
}
}
}
// scanTags examines all the tags in a Point, keeping track of and
// returning the updated indices slice, number of commas and location
// in buf where to start examining the Point fields.
func scanTags(buf []byte, i int, indices []int) (int, int, []int, error) {
var (
err error
commas int
state = tagKeyState
)
for {
switch state {
case tagKeyState:
// Grow our indices slice if we have too many tags.
if commas >= len(indices) {
newIndics := make([]int, cap(indices)*2)
copy(newIndics, indices)
indices = newIndics
}
indices[commas] = i
commas++
i, err = scanTagsKey(buf, i)
state = tagValueState // tag value always follows a tag key
case tagValueState:
state, i, err = scanTagsValue(buf, i)
case fieldsState:
indices[commas] = i + 1
return i, commas, indices, nil
}
if err != nil {
return i, commas, indices, err
}
}
}
// scanTagsKey scans each character in a tag key.
func scanTagsKey(buf []byte, i int) (int, error) {
// First character of the key.
if i >= len(buf) || buf[i] == ' ' || buf[i] == ',' || buf[i] == '=' {
// cpu,{'', ' ', ',', '='}
return i, fmt.Errorf("missing tag key")
}
// Examine each character in the tag key until we hit an unescaped
// equals (the tag value), or we hit an error (i.e., unescaped
// space or comma).
for {
i++
// Either we reached the end of the buffer or we hit an
// unescaped comma or space.
if i >= len(buf) ||
((buf[i] == ' ' || buf[i] == ',') && buf[i-1] != '\\') {
// cpu,tag{'', ' ', ','}
return i, fmt.Errorf("missing tag value")
}
if buf[i] == '=' && buf[i-1] != '\\' {
// cpu,tag=
return i + 1, nil
}
}
}
// scanTagsValue scans each character in a tag value.
func scanTagsValue(buf []byte, i int) (int, int, error) {
// Tag value cannot be empty.
if i >= len(buf) || buf[i] == ',' || buf[i] == ' ' {
// cpu,tag={',', ' '}
return -1, i, fmt.Errorf("missing tag value")
}
// Examine each character in the tag value until we hit an unescaped
// comma (move onto next tag key), an unescaped space (move onto
// fields), or we error out.
for {
i++
if i >= len(buf) {
// cpu,tag=value
return -1, i, fmt.Errorf("missing fields")
}
// An unescaped equals sign is an invalid tag value.
if buf[i] == '=' && buf[i-1] != '\\' {
// cpu,tag={'=', 'fo=o'}
return -1, i, fmt.Errorf("invalid tag format")
}
if buf[i] == ',' && buf[i-1] != '\\' {
// cpu,tag=foo,
return tagKeyState, i + 1, nil
}
// cpu,tag=foo value=1.0
// cpu, tag=foo\= value=1.0
if buf[i] == ' ' && buf[i-1] != '\\' {
return fieldsState, i, nil
}
}
}
func insertionSort(l, r int, buf []byte, indices []int) {
for i := l + 1; i < r; i++ {
for j := i; j > l && less(buf, indices, j, j-1); j-- {
indices[j], indices[j-1] = indices[j-1], indices[j]
}
}
}
func less(buf []byte, indices []int, i, j int) bool {
// This grabs the tag names for i & j, it ignores the values
_, a := scanTo(buf, indices[i], '=')
_, b := scanTo(buf, indices[j], '=')
return bytes.Compare(a, b) < 0
}
// scanFields scans buf, starting at i for the fields section of a point. It returns
// the ending position and the byte slice of the fields within buf.
func scanFields(buf []byte, i int) (int, []byte, error) {
start := skipWhitespace(buf, i)
i = start
quoted := false
// tracks how many '=' we've seen
equals := 0
// tracks how many commas we've seen
commas := 0
for {
// reached the end of buf?
if i >= len(buf) {
break
}
// escaped characters?
if buf[i] == '\\' && i+1 < len(buf) {
i += 2
continue
}
// If the value is quoted, scan until we get to the end quote
// Only quote values in the field value since quotes are not significant
// in the field key
if buf[i] == '"' && equals > commas {
quoted = !quoted
i++
continue
}
// If we see an =, ensure that there is at least on char before and after it
if buf[i] == '=' && !quoted {
equals++
// check for "... =123" but allow "a\ =123"
if buf[i-1] == ' ' && buf[i-2] != '\\' {
return i, buf[start:i], fmt.Errorf("missing field key")
}
// check for "...a=123,=456" but allow "a=123,a\,=456"
if buf[i-1] == ',' && buf[i-2] != '\\' {
return i, buf[start:i], fmt.Errorf("missing field key")
}
// check for "... value="
if i+1 >= len(buf) {
return i, buf[start:i], fmt.Errorf("missing field value")
}
// check for "... value=,value2=..."
if buf[i+1] == ',' || buf[i+1] == ' ' {
return i, buf[start:i], fmt.Errorf("missing field value")
}
if isNumeric(buf[i+1]) || buf[i+1] == '-' || buf[i+1] == 'N' || buf[i+1] == 'n' {
var err error
i, err = scanNumber(buf, i+1)
if err != nil {
return i, buf[start:i], err
}
continue
}
// If next byte is not a double-quote, the value must be a boolean
if buf[i+1] != '"' {
var err error
i, _, err = scanBoolean(buf, i+1)
if err != nil {
return i, buf[start:i], err
}
continue
}
}
if buf[i] == ',' && !quoted {
commas++
}
// reached end of block?
if buf[i] == ' ' && !quoted {
break
}
i++
}
if quoted {
return i, buf[start:i], fmt.Errorf("unbalanced quotes")
}
// check that all field sections had key and values (e.g. prevent "a=1,b"
if equals == 0 || commas != equals-1 {
return i, buf[start:i], fmt.Errorf("invalid field format")
}
return i, buf[start:i], nil
}
// scanTime scans buf, starting at i for the time section of a point. It
// returns the ending position and the byte slice of the timestamp within buf
// and and error if the timestamp is not in the correct numeric format.
func scanTime(buf []byte, i int) (int, []byte, error) {
start := skipWhitespace(buf, i)
i = start
for {
// reached the end of buf?
if i >= len(buf) {
break
}
// Reached end of block or trailing whitespace?
if buf[i] == '\n' || buf[i] == ' ' {
break
}
// Handle negative timestamps
if i == start && buf[i] == '-' {
i++
continue
}
// Timestamps should be integers, make sure they are so we don't need
// to actually parse the timestamp until needed.
if buf[i] < '0' || buf[i] > '9' {
return i, buf[start:i], fmt.Errorf("bad timestamp")
}
i++
}
return i, buf[start:i], nil
}
func isNumeric(b byte) bool {
return (b >= '0' && b <= '9') || b == '.'
}
// scanNumber returns the end position within buf, start at i after
// scanning over buf for an integer, or float. It returns an
// error if a invalid number is scanned.
func scanNumber(buf []byte, i int) (int, error) {
start := i
var isInt, isUnsigned bool
// Is negative number?
if i < len(buf) && buf[i] == '-' {
i++
// There must be more characters now, as just '-' is illegal.
if i == len(buf) {
return i, ErrInvalidNumber
}
}
// how many decimal points we've see
decimal := false
// indicates the number is float in scientific notation
scientific := false
for {
if i >= len(buf) {
break
}
if buf[i] == ',' || buf[i] == ' ' {
break
}
if buf[i] == 'i' && i > start && !(isInt || isUnsigned) {
isInt = true
i++
continue
} else if buf[i] == 'u' && i > start && !(isInt || isUnsigned) {
isUnsigned = true
i++
continue
}
if buf[i] == '.' {
// Can't have more than 1 decimal (e.g. 1.1.1 should fail)
if decimal {
return i, ErrInvalidNumber
}
decimal = true
}
// `e` is valid for floats but not as the first char
if i > start && (buf[i] == 'e' || buf[i] == 'E') {
scientific = true
i++
continue
}
// + and - are only valid at this point if they follow an e (scientific notation)
if (buf[i] == '+' || buf[i] == '-') && (buf[i-1] == 'e' || buf[i-1] == 'E') {
i++
continue
}
// NaN is an unsupported value
if i+2 < len(buf) && (buf[i] == 'N' || buf[i] == 'n') {
return i, ErrInvalidNumber
}
if !isNumeric(buf[i]) {
return i, ErrInvalidNumber
}
i++
}
if (isInt || isUnsigned) && (decimal || scientific) {
return i, ErrInvalidNumber
}
numericDigits := i - start
if isInt {
numericDigits--
}
if decimal {
numericDigits--
}
if buf[start] == '-' {
numericDigits--
}
if numericDigits == 0 {
return i, ErrInvalidNumber
}
// It's more common that numbers will be within min/max range for their type but we need to prevent
// out or range numbers from being parsed successfully. This uses some simple heuristics to decide
// if we should parse the number to the actual type. It does not do it all the time because it incurs
// extra allocations and we end up converting the type again when writing points to disk.
if isInt {
// Make sure the last char is an 'i' for integers (e.g. 9i10 is not valid)
if buf[i-1] != 'i' {
return i, ErrInvalidNumber
}
// Parse the int to check bounds the number of digits could be larger than the max range
// We subtract 1 from the index to remove the `i` from our tests
if len(buf[start:i-1]) >= maxInt64Digits || len(buf[start:i-1]) >= minInt64Digits {
if _, err := parseIntBytes(buf[start:i-1], 10, 64); err != nil {
return i, fmt.Errorf("unable to parse integer %s: %s", buf[start:i-1], err)
}
}
} else if isUnsigned {
// Return an error if uint64 support has not been enabled.
if !enableUint64Support {
return i, ErrInvalidNumber
}
// Make sure the last char is a 'u' for unsigned
if buf[i-1] != 'u' {
return i, ErrInvalidNumber
}
// Make sure the first char is not a '-' for unsigned
if buf[start] == '-' {
return i, ErrInvalidNumber
}
// Parse the uint to check bounds the number of digits could be larger than the max range
// We subtract 1 from the index to remove the `u` from our tests
if len(buf[start:i-1]) >= maxUint64Digits {
if _, err := parseUintBytes(buf[start:i-1], 10, 64); err != nil {
return i, fmt.Errorf("unable to parse unsigned %s: %s", buf[start:i-1], err)
}
}
} else {
// Parse the float to check bounds if it's scientific or the number of digits could be larger than the max range
if scientific || len(buf[start:i]) >= maxFloat64Digits || len(buf[start:i]) >= minFloat64Digits {
if _, err := parseFloatBytes(buf[start:i], 10); err != nil {
return i, fmt.Errorf("invalid float")
}
}
}
return i, nil
}
// scanBoolean returns the end position within buf, start at i after
// scanning over buf for boolean. Valid values for a boolean are
// t, T, true, TRUE, f, F, false, FALSE. It returns an error if a invalid boolean
// is scanned.
func scanBoolean(buf []byte, i int) (int, []byte, error) {
start := i
if i < len(buf) && (buf[i] != 't' && buf[i] != 'f' && buf[i] != 'T' && buf[i] != 'F') {
return i, buf[start:i], fmt.Errorf("invalid boolean")
}
i++
for {
if i >= len(buf) {
break
}
if buf[i] == ',' || buf[i] == ' ' {
break
}
i++
}
// Single char bool (t, T, f, F) is ok
if i-start == 1 {
return i, buf[start:i], nil
}
// length must be 4 for true or TRUE
if (buf[start] == 't' || buf[start] == 'T') && i-start != 4 {
return i, buf[start:i], fmt.Errorf("invalid boolean")
}
// length must be 5 for false or FALSE
if (buf[start] == 'f' || buf[start] == 'F') && i-start != 5 {
return i, buf[start:i], fmt.Errorf("invalid boolean")
}
// Otherwise
valid := false
switch buf[start] {
case 't':
valid = bytes.Equal(buf[start:i], []byte("true"))
case 'f':
valid = bytes.Equal(buf[start:i], []byte("false"))
case 'T':
valid = bytes.Equal(buf[start:i], []byte("TRUE")) || bytes.Equal(buf[start:i], []byte("True"))
case 'F':
valid = bytes.Equal(buf[start:i], []byte("FALSE")) || bytes.Equal(buf[start:i], []byte("False"))
}
if !valid {
return i, buf[start:i], fmt.Errorf("invalid boolean")
}
return i, buf[start:i], nil
}
// skipWhitespace returns the end position within buf, starting at i after
// scanning over spaces in tags.
func skipWhitespace(buf []byte, i int) int {
for i < len(buf) {
if buf[i] != ' ' && buf[i] != '\t' && buf[i] != 0 {
break
}
i++
}
return i
}
// scanLine returns the end position in buf and the next line found within
// buf.
func scanLine(buf []byte, i int) (int, []byte) {
start := i
quoted := false
fields := false
// tracks how many '=' and commas we've seen
// this duplicates some of the functionality in scanFields
equals := 0
commas := 0
for {
// reached the end of buf?
if i >= len(buf) {
break
}
// skip past escaped characters
if buf[i] == '\\' && i+2 < len(buf) {
i += 2
continue
}
if buf[i] == ' ' {
fields = true
}
// If we see a double quote, makes sure it is not escaped
if fields {
if !quoted && buf[i] == '=' {
i++
equals++
continue
} else if !quoted && buf[i] == ',' {
i++
commas++
continue
} else if buf[i] == '"' && equals > commas {
i++
quoted = !quoted
continue
}
}
if buf[i] == '\n' && !quoted {
break
}
i++
}
return i, buf[start:i]
}
// scanTo returns the end position in buf and the next consecutive block
// of bytes, starting from i and ending with stop byte, where stop byte
// has not been escaped.
//
// If there are leading spaces, they are skipped.
func scanTo(buf []byte, i int, stop byte) (int, []byte) {
start := i
for {
// reached the end of buf?
if i >= len(buf) {
break
}
// Reached unescaped stop value?
if buf[i] == stop && (i == 0 || buf[i-1] != '\\') {
break
}
i++
}
return i, buf[start:i]
}
// scanTo returns the end position in buf and the next consecutive block
// of bytes, starting from i and ending with stop byte. If there are leading
// spaces, they are skipped.
func scanToSpaceOr(buf []byte, i int, stop byte) (int, []byte) {
start := i
if buf[i] == stop || buf[i] == ' ' {
return i, buf[start:i]
}
for {
i++
if buf[i-1] == '\\' {
continue
}
// reached the end of buf?
if i >= len(buf) {
return i, buf[start:i]
}
// reached end of block?
if buf[i] == stop || buf[i] == ' ' {
return i, buf[start:i]
}
}
}
func scanTagValue(buf []byte, i int) (int, []byte) {
start := i
for {
if i >= len(buf) {
break
}
if buf[i] == ',' && buf[i-1] != '\\' {
break
}
i++
}
if i > len(buf) {
return i, nil
}
return i, buf[start:i]
}
func scanFieldValue(buf []byte, i int) (int, []byte) {
start := i
quoted := false
for i < len(buf) {
// Only escape char for a field value is a double-quote and backslash
if buf[i] == '\\' && i+1 < len(buf) && (buf[i+1] == '"' || buf[i+1] == '\\') {
i += 2
continue
}
// Quoted value? (e.g. string)
if buf[i] == '"' {
i++
quoted = !quoted
continue
}
if buf[i] == ',' && !quoted {
break
}
i++
}
return i, buf[start:i]
}
func EscapeMeasurement(in []byte) []byte {
for b, esc := range measurementEscapeCodes {
in = bytes.Replace(in, []byte{b}, esc, -1)
}
return in
}
func unescapeMeasurement(in []byte) []byte {
for b, esc := range measurementEscapeCodes {
in = bytes.Replace(in, esc, []byte{b}, -1)
}
return in
}
func escapeTag(in []byte) []byte {
for b, esc := range tagEscapeCodes {
if bytes.IndexByte(in, b) != -1 {
in = bytes.Replace(in, []byte{b}, esc, -1)
}
}
return in
}
func unescapeTag(in []byte) []byte {
if bytes.IndexByte(in, '\\') == -1 {
return in
}
for b, esc := range tagEscapeCodes {
if bytes.IndexByte(in, b) != -1 {
in = bytes.Replace(in, esc, []byte{b}, -1)
}
}
return in
}
// escapeStringFieldReplacer replaces double quotes and backslashes
// with the same character preceded by a backslash.
// As of Go 1.7 this benchmarked better in allocations and CPU time
// compared to iterating through a string byte-by-byte and appending to a new byte slice,
// calling strings.Replace twice, and better than (*Regex).ReplaceAllString.
var escapeStringFieldReplacer = strings.NewReplacer(`"`, `\"`, `\`, `\\`)
// EscapeStringField returns a copy of in with any double quotes or
// backslashes with escaped values.
func EscapeStringField(in string) string {
return escapeStringFieldReplacer.Replace(in)
}
// unescapeStringField returns a copy of in with any escaped double-quotes
// or backslashes unescaped.
func unescapeStringField(in string) string {
if strings.IndexByte(in, '\\') == -1 {
return in
}
var out []byte
i := 0
for {
if i >= len(in) {
break
}
// unescape backslashes
if in[i] == '\\' && i+1 < len(in) && in[i+1] == '\\' {
out = append(out, '\\')
i += 2
continue
}
// unescape double-quotes
if in[i] == '\\' && i+1 < len(in) && in[i+1] == '"' {
out = append(out, '"')
i += 2
continue
}
out = append(out, in[i])
i++
}
return string(out)
}
// NewPoint returns a new point with the given measurement name, tags, fields and timestamp. If
// an unsupported field value (NaN) or out of range time is passed, this function returns an error.
func NewPoint(name string, tags Tags, fields Fields, t time.Time) (Point, error) {
key, err := pointKey(name, tags, fields, t)
if err != nil {
return nil, err
}
return &point{
key: key,
time: t,
fields: fields.MarshalBinary(),
}, nil
}
// pointKey checks some basic requirements for valid points, and returns the
// key, along with an possible error.
func pointKey(measurement string, tags Tags, fields Fields, t time.Time) ([]byte, error) {
if len(fields) == 0 {
return nil, ErrPointMustHaveAField
}
if !t.IsZero() {
if err := CheckTime(t); err != nil {
return nil, err
}
}
for key, value := range fields {
switch value := value.(type) {
case float64:
// Ensure the caller validates and handles invalid field values
if math.IsNaN(value) {
return nil, fmt.Errorf("NaN is an unsupported value for field %s", key)
}
case float32:
// Ensure the caller validates and handles invalid field values
if math.IsNaN(float64(value)) {
return nil, fmt.Errorf("NaN is an unsupported value for field %s", key)
}
}
if len(key) == 0 {
return nil, fmt.Errorf("all fields must have non-empty names")
}
}
key := MakeKey([]byte(measurement), tags)
for field := range fields {
sz := seriesKeySize(key, []byte(field))
if sz > MaxKeyLength {
return nil, fmt.Errorf("max key length exceeded: %v > %v", sz, MaxKeyLength)
}
}
return key, nil
}
func seriesKeySize(key, field []byte) int {
// 4 is the length of the tsm1.fieldKeySeparator constant. It's inlined here to avoid a circular
// dependency.
return len(key) + 4 + len(field)
}
// NewPointFromBytes returns a new Point from a marshalled Point.
func NewPointFromBytes(b []byte) (Point, error) {
p := &point{}
if err := p.UnmarshalBinary(b); err != nil {
return nil, err
}
// This does some basic validation to ensure there are fields and they
// can be unmarshalled as well.
iter := p.FieldIterator()
var hasField bool
for iter.Next() {
if len(iter.FieldKey()) == 0 {
continue
}
hasField = true
switch iter.Type() {
case Float:
_, err := iter.FloatValue()
if err != nil {
return nil, fmt.Errorf("unable to unmarshal field %s: %s", string(iter.FieldKey()), err)
}
case Integer:
_, err := iter.IntegerValue()
if err != nil {
return nil, fmt.Errorf("unable to unmarshal field %s: %s", string(iter.FieldKey()), err)
}
case Unsigned:
_, err := iter.UnsignedValue()
if err != nil {
return nil, fmt.Errorf("unable to unmarshal field %s: %s", string(iter.FieldKey()), err)
}
case String:
// Skip since this won't return an error
case Boolean:
_, err := iter.BooleanValue()
if err != nil {
return nil, fmt.Errorf("unable to unmarshal field %s: %s", string(iter.FieldKey()), err)
}
}
}
if !hasField {
return nil, ErrPointMustHaveAField
}
return p, nil
}
// MustNewPoint returns a new point with the given measurement name, tags, fields and timestamp. If
// an unsupported field value (NaN) is passed, this function panics.
func MustNewPoint(name string, tags Tags, fields Fields, time time.Time) Point {
pt, err := NewPoint(name, tags, fields, time)
if err != nil {
panic(err.Error())
}
return pt
}
// Key returns the key (measurement joined with tags) of the point.
func (p *point) Key() []byte {
return p.key
}
func (p *point) name() []byte {
_, name := scanTo(p.key, 0, ',')
return name
}
func (p *point) Name() []byte {
return escape.Unescape(p.name())
}
// SetName updates the measurement name for the point.
func (p *point) SetName(name string) {
p.cachedName = ""
p.key = MakeKey([]byte(name), p.Tags())
}
// Time return the timestamp for the point.
func (p *point) Time() time.Time {
return p.time
}
// SetTime updates the timestamp for the point.
func (p *point) SetTime(t time.Time) {
p.time = t
}
// Round will round the timestamp of the point to the given duration.
func (p *point) Round(d time.Duration) {
p.time = p.time.Round(d)
}
// Tags returns the tag set for the point.
func (p *point) Tags() Tags {
if p.cachedTags != nil {
return p.cachedTags
}
p.cachedTags = parseTags(p.key)
return p.cachedTags
}
func (p *point) HasTag(tag []byte) bool {
if len(p.key) == 0 {
return false
}
var exists bool
walkTags(p.key, func(key, value []byte) bool {
if bytes.Equal(tag, key) {
exists = true
return false
}
return true
})
return exists
}
func walkTags(buf []byte, fn func(key, value []byte) bool) {
if len(buf) == 0 {
return
}
pos, name := scanTo(buf, 0, ',')
// it's an empty key, so there are no tags
if len(name) == 0 {
return
}
hasEscape := bytes.IndexByte(buf, '\\') != -1
i := pos + 1
var key, value []byte
for {
if i >= len(buf) {
break
}
i, key = scanTo(buf, i, '=')
i, value = scanTagValue(buf, i+1)
if len(value) == 0 {
continue
}
if hasEscape {
if !fn(unescapeTag(key), unescapeTag(value)) {
return
}
} else {
if !fn(key, value) {
return
}
}
i++
}
}
// walkFields walks each field key and value via fn. If fn returns false, the iteration
// is stopped. The values are the raw byte slices and not the converted types.
func walkFields(buf []byte, fn func(key, value []byte) bool) {
var i int
var key, val []byte
for len(buf) > 0 {
i, key = scanTo(buf, 0, '=')
buf = buf[i+1:]
i, val = scanFieldValue(buf, 0)
buf = buf[i:]
if !fn(key, val) {
break
}
// slice off comma
if len(buf) > 0 {
buf = buf[1:]
}
}
}
func parseTags(buf []byte) Tags {
if len(buf) == 0 {
return nil
}
tags := make(Tags, bytes.Count(buf, []byte(",")))
p := 0
walkTags(buf, func(key, value []byte) bool {
tags[p].Key = key
tags[p].Value = value
p++
return true
})
return tags
}
// MakeKey creates a key for a set of tags.
func MakeKey(name []byte, tags Tags) []byte {
// unescape the name and then re-escape it to avoid double escaping.
// The key should always be stored in escaped form.
return append(EscapeMeasurement(unescapeMeasurement(name)), tags.HashKey()...)
}
// SetTags replaces the tags for the point.
func (p *point) SetTags(tags Tags) {
p.key = MakeKey(p.Name(), tags)
p.cachedTags = tags
}
// AddTag adds or replaces a tag value for a point.
func (p *point) AddTag(key, value string) {
tags := p.Tags()
tags = append(tags, Tag{Key: []byte(key), Value: []byte(value)})
sort.Sort(tags)
p.cachedTags = tags
p.key = MakeKey(p.Name(), tags)
}
// Fields returns the fields for the point.
func (p *point) Fields() (Fields, error) {
if p.cachedFields != nil {
return p.cachedFields, nil
}
cf, err := p.unmarshalBinary()
if err != nil {
return nil, err
}
p.cachedFields = cf
return p.cachedFields, nil
}
// SetPrecision will round a time to the specified precision.
func (p *point) SetPrecision(precision string) {
switch precision {
case "n":
case "u":
p.SetTime(p.Time().Truncate(time.Microsecond))
case "ms":
p.SetTime(p.Time().Truncate(time.Millisecond))
case "s":
p.SetTime(p.Time().Truncate(time.Second))
case "m":
p.SetTime(p.Time().Truncate(time.Minute))
case "h":
p.SetTime(p.Time().Truncate(time.Hour))
}
}
// String returns the string representation of the point.
func (p *point) String() string {
if p.Time().IsZero() {
return string(p.Key()) + " " + string(p.fields)
}
return string(p.Key()) + " " + string(p.fields) + " " + strconv.FormatInt(p.UnixNano(), 10)
}
// AppendString appends the string representation of the point to buf.
func (p *point) AppendString(buf []byte) []byte {
buf = append(buf, p.key...)
buf = append(buf, ' ')
buf = append(buf, p.fields...)
if !p.time.IsZero() {
buf = append(buf, ' ')
buf = strconv.AppendInt(buf, p.UnixNano(), 10)
}
return buf
}
// StringSize returns the length of the string that would be returned by String().
func (p *point) StringSize() int {
size := len(p.key) + len(p.fields) + 1
if !p.time.IsZero() {
digits := 1 // even "0" has one digit
t := p.UnixNano()
if t < 0 {
// account for negative sign, then negate
digits++
t = -t
}
for t > 9 { // already accounted for one digit
digits++
t /= 10
}
size += digits + 1 // digits and a space
}
return size
}
// MarshalBinary returns a binary representation of the point.
func (p *point) MarshalBinary() ([]byte, error) {
if len(p.fields) == 0 {
return nil, ErrPointMustHaveAField
}
tb, err := p.time.MarshalBinary()
if err != nil {
return nil, err
}
b := make([]byte, 8+len(p.key)+len(p.fields)+len(tb))
i := 0
binary.BigEndian.PutUint32(b[i:], uint32(len(p.key)))
i += 4
i += copy(b[i:], p.key)
binary.BigEndian.PutUint32(b[i:i+4], uint32(len(p.fields)))
i += 4
i += copy(b[i:], p.fields)
copy(b[i:], tb)
return b, nil
}
// UnmarshalBinary decodes a binary representation of the point into a point struct.
func (p *point) UnmarshalBinary(b []byte) error {
var n int
// Read key length.
if len(b) < 4 {
return io.ErrShortBuffer
}
n, b = int(binary.BigEndian.Uint32(b[:4])), b[4:]
// Read key.
if len(b) < n {
return io.ErrShortBuffer
}
p.key, b = b[:n], b[n:]
// Read fields length.
if len(b) < 4 {
return io.ErrShortBuffer
}
n, b = int(binary.BigEndian.Uint32(b[:4])), b[4:]
// Read fields.
if len(b) < n {
return io.ErrShortBuffer
}
p.fields, b = b[:n], b[n:]
// Read timestamp.
if err := p.time.UnmarshalBinary(b); err != nil {
return err
}
return nil
}
// PrecisionString returns a string representation of the point. If there
// is a timestamp associated with the point then it will be specified in the
// given unit.
func (p *point) PrecisionString(precision string) string {
if p.Time().IsZero() {
return fmt.Sprintf("%s %s", p.Key(), string(p.fields))
}
return fmt.Sprintf("%s %s %d", p.Key(), string(p.fields),
p.UnixNano()/GetPrecisionMultiplier(precision))
}
// RoundedString returns a string representation of the point. If there
// is a timestamp associated with the point, then it will be rounded to the
// given duration.
func (p *point) RoundedString(d time.Duration) string {
if p.Time().IsZero() {
return fmt.Sprintf("%s %s", p.Key(), string(p.fields))
}
return fmt.Sprintf("%s %s %d", p.Key(), string(p.fields),
p.time.Round(d).UnixNano())
}
func (p *point) unmarshalBinary() (Fields, error) {
iter := p.FieldIterator()
fields := make(Fields, 8)
for iter.Next() {
if len(iter.FieldKey()) == 0 {
continue
}
switch iter.Type() {
case Float:
v, err := iter.FloatValue()
if err != nil {
return nil, fmt.Errorf("unable to unmarshal field %s: %s", string(iter.FieldKey()), err)
}
fields[string(iter.FieldKey())] = v
case Integer:
v, err := iter.IntegerValue()
if err != nil {
return nil, fmt.Errorf("unable to unmarshal field %s: %s", string(iter.FieldKey()), err)
}
fields[string(iter.FieldKey())] = v
case Unsigned:
v, err := iter.UnsignedValue()
if err != nil {
return nil, fmt.Errorf("unable to unmarshal field %s: %s", string(iter.FieldKey()), err)
}
fields[string(iter.FieldKey())] = v
case String:
fields[string(iter.FieldKey())] = iter.StringValue()
case Boolean:
v, err := iter.BooleanValue()
if err != nil {
return nil, fmt.Errorf("unable to unmarshal field %s: %s", string(iter.FieldKey()), err)
}
fields[string(iter.FieldKey())] = v
}
}
return fields, nil
}
// HashID returns a non-cryptographic checksum of the point's key.
func (p *point) HashID() uint64 {
h := NewInlineFNV64a()
h.Write(p.key)
sum := h.Sum64()
return sum
}
// UnixNano returns the timestamp of the point as nanoseconds since Unix epoch.
func (p *point) UnixNano() int64 {
return p.Time().UnixNano()
}
// Split will attempt to return multiple points with the same timestamp whose
// string representations are no longer than size. Points with a single field or
// a point without a timestamp may exceed the requested size.
func (p *point) Split(size int) []Point {
if p.time.IsZero() || p.StringSize() <= size {
return []Point{p}
}
// key string, timestamp string, spaces
size -= len(p.key) + len(strconv.FormatInt(p.time.UnixNano(), 10)) + 2
var points []Point
var start, cur int
for cur < len(p.fields) {
end, _ := scanTo(p.fields, cur, '=')
end, _ = scanFieldValue(p.fields, end+1)
if cur > start && end-start > size {
points = append(points, &point{
key: p.key,
time: p.time,
fields: p.fields[start : cur-1],
})
start = cur
}
cur = end + 1
}
points = append(points, &point{
key: p.key,
time: p.time,
fields: p.fields[start:],
})
return points
}
// Tag represents a single key/value tag pair.
type Tag struct {
Key []byte
Value []byte
}
// NewTag returns a new Tag.
func NewTag(key, value []byte) Tag {
return Tag{
Key: key,
Value: value,
}
}
// Size returns the size of the key and value.
func (t Tag) Size() int { return len(t.Key) + len(t.Value) }
// Clone returns a shallow copy of Tag.
//
// Tags associated with a Point created by ParsePointsWithPrecision will hold references to the byte slice that was parsed.
// Use Clone to create a Tag with new byte slices that do not refer to the argument to ParsePointsWithPrecision.
func (t Tag) Clone() Tag {
other := Tag{
Key: make([]byte, len(t.Key)),
Value: make([]byte, len(t.Value)),
}
copy(other.Key, t.Key)
copy(other.Value, t.Value)
return other
}
// String returns the string reprsentation of the tag.
func (t *Tag) String() string {
var buf bytes.Buffer
buf.WriteByte('{')
buf.WriteString(string(t.Key))
buf.WriteByte(' ')
buf.WriteString(string(t.Value))
buf.WriteByte('}')
return buf.String()
}
// Tags represents a sorted list of tags.
type Tags []Tag
// NewTags returns a new Tags from a map.
func NewTags(m map[string]string) Tags {
if len(m) == 0 {
return nil
}
a := make(Tags, 0, len(m))
for k, v := range m {
a = append(a, NewTag([]byte(k), []byte(v)))
}
sort.Sort(a)
return a
}
// Keys returns the list of keys for a tag set.
func (a Tags) Keys() []string {
if len(a) == 0 {
return nil
}
keys := make([]string, len(a))
for i, tag := range a {
keys[i] = string(tag.Key)
}
return keys
}
// Values returns the list of values for a tag set.
func (a Tags) Values() []string {
if len(a) == 0 {
return nil
}
values := make([]string, len(a))
for i, tag := range a {
values[i] = string(tag.Value)
}
return values
}
// String returns the string representation of the tags.
func (a Tags) String() string {
var buf bytes.Buffer
buf.WriteByte('[')
for i := range a {
buf.WriteString(a[i].String())
if i < len(a)-1 {
buf.WriteByte(' ')
}
}
buf.WriteByte(']')
return buf.String()
}
// Size returns the number of bytes needed to store all tags. Note, this is
// the number of bytes needed to store all keys and values and does not account
// for data structures or delimiters for example.
func (a Tags) Size() int {
var total int
for _, t := range a {
total += t.Size()
}
return total
}
// Clone returns a copy of the slice where the elements are a result of calling `Clone` on the original elements
//
// Tags associated with a Point created by ParsePointsWithPrecision will hold references to the byte slice that was parsed.
// Use Clone to create Tags with new byte slices that do not refer to the argument to ParsePointsWithPrecision.
func (a Tags) Clone() Tags {
if len(a) == 0 {
return nil
}
others := make(Tags, len(a))
for i := range a {
others[i] = a[i].Clone()
}
return others
}
func (a Tags) Len() int { return len(a) }
func (a Tags) Less(i, j int) bool { return bytes.Compare(a[i].Key, a[j].Key) == -1 }
func (a Tags) Swap(i, j int) { a[i], a[j] = a[j], a[i] }
// Equal returns true if a equals other.
func (a Tags) Equal(other Tags) bool {
if len(a) != len(other) {
return false
}
for i := range a {
if !bytes.Equal(a[i].Key, other[i].Key) || !bytes.Equal(a[i].Value, other[i].Value) {
return false
}
}
return true
}
// CompareTags returns -1 if a < b, 1 if a > b, and 0 if a == b.
func CompareTags(a, b Tags) int {
// Compare each key & value until a mismatch.
for i := 0; i < len(a) && i < len(b); i++ {
if cmp := bytes.Compare(a[i].Key, b[i].Key); cmp != 0 {
return cmp
}
if cmp := bytes.Compare(a[i].Value, b[i].Value); cmp != 0 {
return cmp
}
}
// If all tags are equal up to this point then return shorter tagset.
if len(a) < len(b) {
return -1
} else if len(a) > len(b) {
return 1
}
// All tags are equal.
return 0
}
// Get returns the value for a key.
func (a Tags) Get(key []byte) []byte {
// OPTIMIZE: Use sort.Search if tagset is large.
for _, t := range a {
if bytes.Equal(t.Key, key) {
return t.Value
}
}
return nil
}
// GetString returns the string value for a string key.
func (a Tags) GetString(key string) string {
return string(a.Get([]byte(key)))
}
// Set sets the value for a key.
func (a *Tags) Set(key, value []byte) {
for i, t := range *a {
if bytes.Equal(t.Key, key) {
(*a)[i].Value = value
return
}
}
*a = append(*a, Tag{Key: key, Value: value})
sort.Sort(*a)
}
// SetString sets the string value for a string key.
func (a *Tags) SetString(key, value string) {
a.Set([]byte(key), []byte(value))
}
// Delete removes a tag by key.
func (a *Tags) Delete(key []byte) {
for i, t := range *a {
if bytes.Equal(t.Key, key) {
copy((*a)[i:], (*a)[i+1:])
(*a)[len(*a)-1] = Tag{}
*a = (*a)[:len(*a)-1]
return
}
}
}
// Map returns a map representation of the tags.
func (a Tags) Map() map[string]string {
m := make(map[string]string, len(a))
for _, t := range a {
m[string(t.Key)] = string(t.Value)
}
return m
}
// Merge merges the tags combining the two. If both define a tag with the
// same key, the merged value overwrites the old value.
// A new map is returned.
func (a Tags) Merge(other map[string]string) Tags {
merged := make(map[string]string, len(a)+len(other))
for _, t := range a {
merged[string(t.Key)] = string(t.Value)
}
for k, v := range other {
merged[k] = v
}
return NewTags(merged)
}
// HashKey hashes all of a tag's keys.
func (a Tags) HashKey() []byte {
// Empty maps marshal to empty bytes.
if len(a) == 0 {
return nil
}
// Type invariant: Tags are sorted
escaped := make(Tags, 0, len(a))
sz := 0
for _, t := range a {
ek := escapeTag(t.Key)
ev := escapeTag(t.Value)
if len(ev) > 0 {
escaped = append(escaped, Tag{Key: ek, Value: ev})
sz += len(ek) + len(ev)
}
}
sz += len(escaped) + (len(escaped) * 2) // separators
// Generate marshaled bytes.
b := make([]byte, sz)
buf := b
idx := 0
for _, k := range escaped {
buf[idx] = ','
idx++
copy(buf[idx:idx+len(k.Key)], k.Key)
idx += len(k.Key)
buf[idx] = '='
idx++
copy(buf[idx:idx+len(k.Value)], k.Value)
idx += len(k.Value)
}
return b[:idx]
}
// CopyTags returns a shallow copy of tags.
func CopyTags(a Tags) Tags {
other := make(Tags, len(a))
copy(other, a)
return other
}
// DeepCopyTags returns a deep copy of tags.
func DeepCopyTags(a Tags) Tags {
// Calculate size of keys/values in bytes.
var n int
for _, t := range a {
n += len(t.Key) + len(t.Value)
}
// Build single allocation for all key/values.
buf := make([]byte, n)
// Copy tags to new set.
other := make(Tags, len(a))
for i, t := range a {
copy(buf, t.Key)
other[i].Key, buf = buf[:len(t.Key)], buf[len(t.Key):]
copy(buf, t.Value)
other[i].Value, buf = buf[:len(t.Value)], buf[len(t.Value):]
}
return other
}
// Fields represents a mapping between a Point's field names and their
// values.
type Fields map[string]interface{}
// FieldIterator retuns a FieldIterator that can be used to traverse the
// fields of a point without constructing the in-memory map.
func (p *point) FieldIterator() FieldIterator {
p.Reset()
return p
}
type fieldIterator struct {
start, end int
key, keybuf []byte
valueBuf []byte
fieldType FieldType
}
// Next indicates whether there any fields remaining.
func (p *point) Next() bool {
p.it.start = p.it.end
if p.it.start >= len(p.fields) {
return false
}
p.it.end, p.it.key = scanTo(p.fields, p.it.start, '=')
if escape.IsEscaped(p.it.key) {
p.it.keybuf = escape.AppendUnescaped(p.it.keybuf[:0], p.it.key)
p.it.key = p.it.keybuf
}
p.it.end, p.it.valueBuf = scanFieldValue(p.fields, p.it.end+1)
p.it.end++
if len(p.it.valueBuf) == 0 {
p.it.fieldType = Empty
return true
}
c := p.it.valueBuf[0]
if c == '"' {
p.it.fieldType = String
return true
}
if strings.IndexByte(`0123456789-.nNiIu`, c) >= 0 {
if p.it.valueBuf[len(p.it.valueBuf)-1] == 'i' {
p.it.fieldType = Integer
p.it.valueBuf = p.it.valueBuf[:len(p.it.valueBuf)-1]
} else if p.it.valueBuf[len(p.it.valueBuf)-1] == 'u' {
p.it.fieldType = Unsigned
p.it.valueBuf = p.it.valueBuf[:len(p.it.valueBuf)-1]
} else {
p.it.fieldType = Float
}
return true
}
// to keep the same behavior that currently exists, default to boolean
p.it.fieldType = Boolean
return true
}
// FieldKey returns the key of the current field.
func (p *point) FieldKey() []byte {
return p.it.key
}
// Type returns the FieldType of the current field.
func (p *point) Type() FieldType {
return p.it.fieldType
}
// StringValue returns the string value of the current field.
func (p *point) StringValue() string {
return unescapeStringField(string(p.it.valueBuf[1 : len(p.it.valueBuf)-1]))
}
// IntegerValue returns the integer value of the current field.
func (p *point) IntegerValue() (int64, error) {
n, err := parseIntBytes(p.it.valueBuf, 10, 64)
if err != nil {
return 0, fmt.Errorf("unable to parse integer value %q: %v", p.it.valueBuf, err)
}
return n, nil
}
// UnsignedValue returns the unsigned value of the current field.
func (p *point) UnsignedValue() (uint64, error) {
n, err := parseUintBytes(p.it.valueBuf, 10, 64)
if err != nil {
return 0, fmt.Errorf("unable to parse unsigned value %q: %v", p.it.valueBuf, err)
}
return n, nil
}
// BooleanValue returns the boolean value of the current field.
func (p *point) BooleanValue() (bool, error) {
b, err := parseBoolBytes(p.it.valueBuf)
if err != nil {
return false, fmt.Errorf("unable to parse bool value %q: %v", p.it.valueBuf, err)
}
return b, nil
}
// FloatValue returns the float value of the current field.
func (p *point) FloatValue() (float64, error) {
f, err := parseFloatBytes(p.it.valueBuf, 64)
if err != nil {
return 0, fmt.Errorf("unable to parse floating point value %q: %v", p.it.valueBuf, err)
}
return f, nil
}
// Reset resets the iterator to its initial state.
func (p *point) Reset() {
p.it.fieldType = Empty
p.it.key = nil
p.it.valueBuf = nil
p.it.start = 0
p.it.end = 0
}
// MarshalBinary encodes all the fields to their proper type and returns the binary
// represenation
// NOTE: uint64 is specifically not supported due to potential overflow when we decode
// again later to an int64
// NOTE2: uint is accepted, and may be 64 bits, and is for some reason accepted...
func (p Fields) MarshalBinary() []byte {
var b []byte
keys := make([]string, 0, len(p))
for k := range p {
keys = append(keys, k)
}
// Not really necessary, can probably be removed.
sort.Strings(keys)
for i, k := range keys {
if i > 0 {
b = append(b, ',')
}
b = appendField(b, k, p[k])
}
return b
}
func appendField(b []byte, k string, v interface{}) []byte {
b = append(b, []byte(escape.String(k))...)
b = append(b, '=')
// 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(EscapeStringField(v))...)
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:
b = strconv.AppendUint(b, v, 10)
b = append(b, 'u')
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:
// TODO: 'uint' should be converted to writing as an unsigned integer,
// but we cannot since that would break backwards compatibility.
b = strconv.AppendInt(b, int64(v), 10)
b = append(b, 'i')
case float32:
b = strconv.AppendFloat(b, float64(v), 'f', -1, 32)
case []byte:
b = append(b, v...)
case nil:
// skip
default:
// Can't determine the type, so convert to string
b = append(b, '"')
b = append(b, []byte(EscapeStringField(fmt.Sprintf("%v", v)))...)
b = append(b, '"')
}
return b
}
type byteSlices [][]byte
func (a byteSlices) Len() int { return len(a) }
func (a byteSlices) Less(i, j int) bool { return bytes.Compare(a[i], a[j]) == -1 }
func (a byteSlices) Swap(i, j int) { a[i], a[j] = a[j], a[i] }