GoToSocial/vendor/github.com/Masterminds/semver/v3/version.go

640 lines
16 KiB
Go

package semver
import (
"bytes"
"database/sql/driver"
"encoding/json"
"errors"
"fmt"
"regexp"
"strconv"
"strings"
)
// The compiled version of the regex created at init() is cached here so it
// only needs to be created once.
var versionRegex *regexp.Regexp
var (
// ErrInvalidSemVer is returned a version is found to be invalid when
// being parsed.
ErrInvalidSemVer = errors.New("Invalid Semantic Version")
// ErrEmptyString is returned when an empty string is passed in for parsing.
ErrEmptyString = errors.New("Version string empty")
// ErrInvalidCharacters is returned when invalid characters are found as
// part of a version
ErrInvalidCharacters = errors.New("Invalid characters in version")
// ErrSegmentStartsZero is returned when a version segment starts with 0.
// This is invalid in SemVer.
ErrSegmentStartsZero = errors.New("Version segment starts with 0")
// ErrInvalidMetadata is returned when the metadata is an invalid format
ErrInvalidMetadata = errors.New("Invalid Metadata string")
// ErrInvalidPrerelease is returned when the pre-release is an invalid format
ErrInvalidPrerelease = errors.New("Invalid Prerelease string")
)
// semVerRegex is the regular expression used to parse a semantic version.
const semVerRegex string = `v?([0-9]+)(\.[0-9]+)?(\.[0-9]+)?` +
`(-([0-9A-Za-z\-]+(\.[0-9A-Za-z\-]+)*))?` +
`(\+([0-9A-Za-z\-]+(\.[0-9A-Za-z\-]+)*))?`
// Version represents a single semantic version.
type Version struct {
major, minor, patch uint64
pre string
metadata string
original string
}
func init() {
versionRegex = regexp.MustCompile("^" + semVerRegex + "$")
}
const (
num string = "0123456789"
allowed string = "abcdefghijklmnopqrstuvwxyzABCDEFGHIJKLMNOPQRSTUVWXYZ-" + num
)
// StrictNewVersion parses a given version and returns an instance of Version or
// an error if unable to parse the version. Only parses valid semantic versions.
// Performs checking that can find errors within the version.
// If you want to coerce a version such as 1 or 1.2 and parse it as the 1.x
// releases of semver did, use the NewVersion() function.
func StrictNewVersion(v string) (*Version, error) {
// Parsing here does not use RegEx in order to increase performance and reduce
// allocations.
if len(v) == 0 {
return nil, ErrEmptyString
}
// Split the parts into [0]major, [1]minor, and [2]patch,prerelease,build
parts := strings.SplitN(v, ".", 3)
if len(parts) != 3 {
return nil, ErrInvalidSemVer
}
sv := &Version{
original: v,
}
// check for prerelease or build metadata
var extra []string
if strings.ContainsAny(parts[2], "-+") {
// Start with the build metadata first as it needs to be on the right
extra = strings.SplitN(parts[2], "+", 2)
if len(extra) > 1 {
// build metadata found
sv.metadata = extra[1]
parts[2] = extra[0]
}
extra = strings.SplitN(parts[2], "-", 2)
if len(extra) > 1 {
// prerelease found
sv.pre = extra[1]
parts[2] = extra[0]
}
}
// Validate the number segments are valid. This includes only having positive
// numbers and no leading 0's.
for _, p := range parts {
if !containsOnly(p, num) {
return nil, ErrInvalidCharacters
}
if len(p) > 1 && p[0] == '0' {
return nil, ErrSegmentStartsZero
}
}
// Extract the major, minor, and patch elements onto the returned Version
var err error
sv.major, err = strconv.ParseUint(parts[0], 10, 64)
if err != nil {
return nil, err
}
sv.minor, err = strconv.ParseUint(parts[1], 10, 64)
if err != nil {
return nil, err
}
sv.patch, err = strconv.ParseUint(parts[2], 10, 64)
if err != nil {
return nil, err
}
// No prerelease or build metadata found so returning now as a fastpath.
if sv.pre == "" && sv.metadata == "" {
return sv, nil
}
if sv.pre != "" {
if err = validatePrerelease(sv.pre); err != nil {
return nil, err
}
}
if sv.metadata != "" {
if err = validateMetadata(sv.metadata); err != nil {
return nil, err
}
}
return sv, nil
}
// NewVersion parses a given version and returns an instance of Version or
// an error if unable to parse the version. If the version is SemVer-ish it
// attempts to convert it to SemVer. If you want to validate it was a strict
// semantic version at parse time see StrictNewVersion().
func NewVersion(v string) (*Version, error) {
m := versionRegex.FindStringSubmatch(v)
if m == nil {
return nil, ErrInvalidSemVer
}
sv := &Version{
metadata: m[8],
pre: m[5],
original: v,
}
var err error
sv.major, err = strconv.ParseUint(m[1], 10, 64)
if err != nil {
return nil, fmt.Errorf("Error parsing version segment: %s", err)
}
if m[2] != "" {
sv.minor, err = strconv.ParseUint(strings.TrimPrefix(m[2], "."), 10, 64)
if err != nil {
return nil, fmt.Errorf("Error parsing version segment: %s", err)
}
} else {
sv.minor = 0
}
if m[3] != "" {
sv.patch, err = strconv.ParseUint(strings.TrimPrefix(m[3], "."), 10, 64)
if err != nil {
return nil, fmt.Errorf("Error parsing version segment: %s", err)
}
} else {
sv.patch = 0
}
// Perform some basic due diligence on the extra parts to ensure they are
// valid.
if sv.pre != "" {
if err = validatePrerelease(sv.pre); err != nil {
return nil, err
}
}
if sv.metadata != "" {
if err = validateMetadata(sv.metadata); err != nil {
return nil, err
}
}
return sv, nil
}
// New creates a new instance of Version with each of the parts passed in as
// arguments instead of parsing a version string.
func New(major, minor, patch uint64, pre, metadata string) *Version {
v := Version{
major: major,
minor: minor,
patch: patch,
pre: pre,
metadata: metadata,
original: "",
}
v.original = v.String()
return &v
}
// MustParse parses a given version and panics on error.
func MustParse(v string) *Version {
sv, err := NewVersion(v)
if err != nil {
panic(err)
}
return sv
}
// String converts a Version object to a string.
// Note, if the original version contained a leading v this version will not.
// See the Original() method to retrieve the original value. Semantic Versions
// don't contain a leading v per the spec. Instead it's optional on
// implementation.
func (v Version) String() string {
var buf bytes.Buffer
fmt.Fprintf(&buf, "%d.%d.%d", v.major, v.minor, v.patch)
if v.pre != "" {
fmt.Fprintf(&buf, "-%s", v.pre)
}
if v.metadata != "" {
fmt.Fprintf(&buf, "+%s", v.metadata)
}
return buf.String()
}
// Original returns the original value passed in to be parsed.
func (v *Version) Original() string {
return v.original
}
// Major returns the major version.
func (v Version) Major() uint64 {
return v.major
}
// Minor returns the minor version.
func (v Version) Minor() uint64 {
return v.minor
}
// Patch returns the patch version.
func (v Version) Patch() uint64 {
return v.patch
}
// Prerelease returns the pre-release version.
func (v Version) Prerelease() string {
return v.pre
}
// Metadata returns the metadata on the version.
func (v Version) Metadata() string {
return v.metadata
}
// originalVPrefix returns the original 'v' prefix if any.
func (v Version) originalVPrefix() string {
// Note, only lowercase v is supported as a prefix by the parser.
if v.original != "" && v.original[:1] == "v" {
return v.original[:1]
}
return ""
}
// IncPatch produces the next patch version.
// If the current version does not have prerelease/metadata information,
// it unsets metadata and prerelease values, increments patch number.
// If the current version has any of prerelease or metadata information,
// it unsets both values and keeps current patch value
func (v Version) IncPatch() Version {
vNext := v
// according to http://semver.org/#spec-item-9
// Pre-release versions have a lower precedence than the associated normal version.
// according to http://semver.org/#spec-item-10
// Build metadata SHOULD be ignored when determining version precedence.
if v.pre != "" {
vNext.metadata = ""
vNext.pre = ""
} else {
vNext.metadata = ""
vNext.pre = ""
vNext.patch = v.patch + 1
}
vNext.original = v.originalVPrefix() + "" + vNext.String()
return vNext
}
// IncMinor produces the next minor version.
// Sets patch to 0.
// Increments minor number.
// Unsets metadata.
// Unsets prerelease status.
func (v Version) IncMinor() Version {
vNext := v
vNext.metadata = ""
vNext.pre = ""
vNext.patch = 0
vNext.minor = v.minor + 1
vNext.original = v.originalVPrefix() + "" + vNext.String()
return vNext
}
// IncMajor produces the next major version.
// Sets patch to 0.
// Sets minor to 0.
// Increments major number.
// Unsets metadata.
// Unsets prerelease status.
func (v Version) IncMajor() Version {
vNext := v
vNext.metadata = ""
vNext.pre = ""
vNext.patch = 0
vNext.minor = 0
vNext.major = v.major + 1
vNext.original = v.originalVPrefix() + "" + vNext.String()
return vNext
}
// SetPrerelease defines the prerelease value.
// Value must not include the required 'hyphen' prefix.
func (v Version) SetPrerelease(prerelease string) (Version, error) {
vNext := v
if len(prerelease) > 0 {
if err := validatePrerelease(prerelease); err != nil {
return vNext, err
}
}
vNext.pre = prerelease
vNext.original = v.originalVPrefix() + "" + vNext.String()
return vNext, nil
}
// SetMetadata defines metadata value.
// Value must not include the required 'plus' prefix.
func (v Version) SetMetadata(metadata string) (Version, error) {
vNext := v
if len(metadata) > 0 {
if err := validateMetadata(metadata); err != nil {
return vNext, err
}
}
vNext.metadata = metadata
vNext.original = v.originalVPrefix() + "" + vNext.String()
return vNext, nil
}
// LessThan tests if one version is less than another one.
func (v *Version) LessThan(o *Version) bool {
return v.Compare(o) < 0
}
// GreaterThan tests if one version is greater than another one.
func (v *Version) GreaterThan(o *Version) bool {
return v.Compare(o) > 0
}
// Equal tests if two versions are equal to each other.
// Note, versions can be equal with different metadata since metadata
// is not considered part of the comparable version.
func (v *Version) Equal(o *Version) bool {
return v.Compare(o) == 0
}
// Compare compares this version to another one. It returns -1, 0, or 1 if
// the version smaller, equal, or larger than the other version.
//
// Versions are compared by X.Y.Z. Build metadata is ignored. Prerelease is
// lower than the version without a prerelease. Compare always takes into account
// prereleases. If you want to work with ranges using typical range syntaxes that
// skip prereleases if the range is not looking for them use constraints.
func (v *Version) Compare(o *Version) int {
// Compare the major, minor, and patch version for differences. If a
// difference is found return the comparison.
if d := compareSegment(v.Major(), o.Major()); d != 0 {
return d
}
if d := compareSegment(v.Minor(), o.Minor()); d != 0 {
return d
}
if d := compareSegment(v.Patch(), o.Patch()); d != 0 {
return d
}
// At this point the major, minor, and patch versions are the same.
ps := v.pre
po := o.Prerelease()
if ps == "" && po == "" {
return 0
}
if ps == "" {
return 1
}
if po == "" {
return -1
}
return comparePrerelease(ps, po)
}
// UnmarshalJSON implements JSON.Unmarshaler interface.
func (v *Version) UnmarshalJSON(b []byte) error {
var s string
if err := json.Unmarshal(b, &s); err != nil {
return err
}
temp, err := NewVersion(s)
if err != nil {
return err
}
v.major = temp.major
v.minor = temp.minor
v.patch = temp.patch
v.pre = temp.pre
v.metadata = temp.metadata
v.original = temp.original
return nil
}
// MarshalJSON implements JSON.Marshaler interface.
func (v Version) MarshalJSON() ([]byte, error) {
return json.Marshal(v.String())
}
// UnmarshalText implements the encoding.TextUnmarshaler interface.
func (v *Version) UnmarshalText(text []byte) error {
temp, err := NewVersion(string(text))
if err != nil {
return err
}
*v = *temp
return nil
}
// MarshalText implements the encoding.TextMarshaler interface.
func (v Version) MarshalText() ([]byte, error) {
return []byte(v.String()), nil
}
// Scan implements the SQL.Scanner interface.
func (v *Version) Scan(value interface{}) error {
var s string
s, _ = value.(string)
temp, err := NewVersion(s)
if err != nil {
return err
}
v.major = temp.major
v.minor = temp.minor
v.patch = temp.patch
v.pre = temp.pre
v.metadata = temp.metadata
v.original = temp.original
return nil
}
// Value implements the Driver.Valuer interface.
func (v Version) Value() (driver.Value, error) {
return v.String(), nil
}
func compareSegment(v, o uint64) int {
if v < o {
return -1
}
if v > o {
return 1
}
return 0
}
func comparePrerelease(v, o string) int {
// split the prelease versions by their part. The separator, per the spec,
// is a .
sparts := strings.Split(v, ".")
oparts := strings.Split(o, ".")
// Find the longer length of the parts to know how many loop iterations to
// go through.
slen := len(sparts)
olen := len(oparts)
l := slen
if olen > slen {
l = olen
}
// Iterate over each part of the prereleases to compare the differences.
for i := 0; i < l; i++ {
// Since the lentgh of the parts can be different we need to create
// a placeholder. This is to avoid out of bounds issues.
stemp := ""
if i < slen {
stemp = sparts[i]
}
otemp := ""
if i < olen {
otemp = oparts[i]
}
d := comparePrePart(stemp, otemp)
if d != 0 {
return d
}
}
// Reaching here means two versions are of equal value but have different
// metadata (the part following a +). They are not identical in string form
// but the version comparison finds them to be equal.
return 0
}
func comparePrePart(s, o string) int {
// Fastpath if they are equal
if s == o {
return 0
}
// When s or o are empty we can use the other in an attempt to determine
// the response.
if s == "" {
if o != "" {
return -1
}
return 1
}
if o == "" {
if s != "" {
return 1
}
return -1
}
// When comparing strings "99" is greater than "103". To handle
// cases like this we need to detect numbers and compare them. According
// to the semver spec, numbers are always positive. If there is a - at the
// start like -99 this is to be evaluated as an alphanum. numbers always
// have precedence over alphanum. Parsing as Uints because negative numbers
// are ignored.
oi, n1 := strconv.ParseUint(o, 10, 64)
si, n2 := strconv.ParseUint(s, 10, 64)
// The case where both are strings compare the strings
if n1 != nil && n2 != nil {
if s > o {
return 1
}
return -1
} else if n1 != nil {
// o is a string and s is a number
return -1
} else if n2 != nil {
// s is a string and o is a number
return 1
}
// Both are numbers
if si > oi {
return 1
}
return -1
}
// Like strings.ContainsAny but does an only instead of any.
func containsOnly(s string, comp string) bool {
return strings.IndexFunc(s, func(r rune) bool {
return !strings.ContainsRune(comp, r)
}) == -1
}
// From the spec, "Identifiers MUST comprise only
// ASCII alphanumerics and hyphen [0-9A-Za-z-]. Identifiers MUST NOT be empty.
// Numeric identifiers MUST NOT include leading zeroes.". These segments can
// be dot separated.
func validatePrerelease(p string) error {
eparts := strings.Split(p, ".")
for _, p := range eparts {
if containsOnly(p, num) {
if len(p) > 1 && p[0] == '0' {
return ErrSegmentStartsZero
}
} else if !containsOnly(p, allowed) {
return ErrInvalidPrerelease
}
}
return nil
}
// From the spec, "Build metadata MAY be denoted by
// appending a plus sign and a series of dot separated identifiers immediately
// following the patch or pre-release version. Identifiers MUST comprise only
// ASCII alphanumerics and hyphen [0-9A-Za-z-]. Identifiers MUST NOT be empty."
func validateMetadata(m string) error {
eparts := strings.Split(m, ".")
for _, p := range eparts {
if !containsOnly(p, allowed) {
return ErrInvalidMetadata
}
}
return nil
}