package semver import ( "errors" "fmt" "regexp" "strings" ) // Constraints is one or more constraint that a semantic version can be // checked against. type Constraints struct { constraints [][]*constraint } // NewConstraint returns a Constraints instance that a Version instance can // be checked against. If there is a parse error it will be returned. func NewConstraint(c string) (*Constraints, error) { // Rewrite - ranges into a comparison operation. c = rewriteRange(c) ors := strings.Split(c, "||") or := make([][]*constraint, len(ors)) for k, v := range ors { cs := strings.Split(v, ",") result := make([]*constraint, len(cs)) for i, s := range cs { pc, err := parseConstraint(s) if err != nil { return nil, err } result[i] = pc } or[k] = result } o := &Constraints{constraints: or} return o, nil } // Check tests if a version satisfies the constraints. func (cs Constraints) Check(v *Version) bool { // loop over the ORs and check the inner ANDs for _, o := range cs.constraints { joy := true for _, c := range o { if !c.check(v) { joy = false break } } if joy { return true } } return false } // Validate checks if a version satisfies a constraint. If not a slice of // reasons for the failure are returned in addition to a bool. func (cs Constraints) Validate(v *Version) (bool, []error) { // loop over the ORs and check the inner ANDs var e []error // Capture the prerelease message only once. When it happens the first time // this var is marked var prerelesase bool for _, o := range cs.constraints { joy := true for _, c := range o { // Before running the check handle the case there the version is // a prerelease and the check is not searching for prereleases. if c.con.pre == "" && v.pre != "" { if !prerelesase { em := fmt.Errorf("%s is a prerelease version and the constraint is only looking for release versions", v) e = append(e, em) prerelesase = true } joy = false } else { if !c.check(v) { em := fmt.Errorf(c.msg, v, c.orig) e = append(e, em) joy = false } } } if joy { return true, []error{} } } return false, e } var constraintOps map[string]cfunc var constraintMsg map[string]string var constraintRegex *regexp.Regexp func init() { constraintOps = map[string]cfunc{ "": constraintTildeOrEqual, "=": constraintTildeOrEqual, "!=": constraintNotEqual, ">": constraintGreaterThan, "<": constraintLessThan, ">=": constraintGreaterThanEqual, "=>": constraintGreaterThanEqual, "<=": constraintLessThanEqual, "=<": constraintLessThanEqual, "~": constraintTilde, "~>": constraintTilde, "^": constraintCaret, } constraintMsg = map[string]string{ "": "%s is not equal to %s", "=": "%s is not equal to %s", "!=": "%s is equal to %s", ">": "%s is less than or equal to %s", "<": "%s is greater than or equal to %s", ">=": "%s is less than %s", "=>": "%s is less than %s", "<=": "%s is greater than %s", "=<": "%s is greater than %s", "~": "%s does not have same major and minor version as %s", "~>": "%s does not have same major and minor version as %s", "^": "%s does not have same major version as %s", } ops := make([]string, 0, len(constraintOps)) for k := range constraintOps { ops = append(ops, regexp.QuoteMeta(k)) } constraintRegex = regexp.MustCompile(fmt.Sprintf( `^\s*(%s)\s*(%s)\s*$`, strings.Join(ops, "|"), cvRegex)) constraintRangeRegex = regexp.MustCompile(fmt.Sprintf( `\s*(%s)\s+-\s+(%s)\s*`, cvRegex, cvRegex)) } // An individual constraint type constraint struct { // The callback function for the restraint. It performs the logic for // the constraint. function cfunc msg string // The version used in the constraint check. For example, if a constraint // is '<= 2.0.0' the con a version instance representing 2.0.0. con *Version // The original parsed version (e.g., 4.x from != 4.x) orig string // When an x is used as part of the version (e.g., 1.x) minorDirty bool dirty bool patchDirty bool } // Check if a version meets the constraint func (c *constraint) check(v *Version) bool { return c.function(v, c) } type cfunc func(v *Version, c *constraint) bool func parseConstraint(c string) (*constraint, error) { m := constraintRegex.FindStringSubmatch(c) if m == nil { return nil, fmt.Errorf("improper constraint: %s", c) } ver := m[2] orig := ver minorDirty := false patchDirty := false dirty := false if isX(m[3]) { ver = "0.0.0" dirty = true } else if isX(strings.TrimPrefix(m[4], ".")) || m[4] == "" { minorDirty = true dirty = true ver = fmt.Sprintf("%s.0.0%s", m[3], m[6]) } else if isX(strings.TrimPrefix(m[5], ".")) { dirty = true patchDirty = true ver = fmt.Sprintf("%s%s.0%s", m[3], m[4], m[6]) } con, err := NewVersion(ver) if err != nil { // The constraintRegex should catch any regex parsing errors. So, // we should never get here. return nil, errors.New("constraint Parser Error") } cs := &constraint{ function: constraintOps[m[1]], msg: constraintMsg[m[1]], con: con, orig: orig, minorDirty: minorDirty, patchDirty: patchDirty, dirty: dirty, } return cs, nil } // Constraint functions func constraintNotEqual(v *Version, c *constraint) bool { if c.dirty { // If there is a pre-release on the version but the constraint isn't looking // for them assume that pre-releases are not compatible. See issue 21 for // more details. if v.Prerelease() != "" && c.con.Prerelease() == "" { return false } if c.con.Major() != v.Major() { return true } if c.con.Minor() != v.Minor() && !c.minorDirty { return true } else if c.minorDirty { return false } return false } return !v.Equal(c.con) } func constraintGreaterThan(v *Version, c *constraint) bool { // If there is a pre-release on the version but the constraint isn't looking // for them assume that pre-releases are not compatible. See issue 21 for // more details. if v.Prerelease() != "" && c.con.Prerelease() == "" { return false } return v.Compare(c.con) == 1 } func constraintLessThan(v *Version, c *constraint) bool { // If there is a pre-release on the version but the constraint isn't looking // for them assume that pre-releases are not compatible. See issue 21 for // more details. if v.Prerelease() != "" && c.con.Prerelease() == "" { return false } if !c.dirty { return v.Compare(c.con) < 0 } if v.Major() > c.con.Major() { return false } else if v.Minor() > c.con.Minor() && !c.minorDirty { return false } return true } func constraintGreaterThanEqual(v *Version, c *constraint) bool { // If there is a pre-release on the version but the constraint isn't looking // for them assume that pre-releases are not compatible. See issue 21 for // more details. if v.Prerelease() != "" && c.con.Prerelease() == "" { return false } return v.Compare(c.con) >= 0 } func constraintLessThanEqual(v *Version, c *constraint) bool { // If there is a pre-release on the version but the constraint isn't looking // for them assume that pre-releases are not compatible. See issue 21 for // more details. if v.Prerelease() != "" && c.con.Prerelease() == "" { return false } if !c.dirty { return v.Compare(c.con) <= 0 } if v.Major() > c.con.Major() { return false } else if v.Minor() > c.con.Minor() && !c.minorDirty { return false } return true } // ~*, ~>* --> >= 0.0.0 (any) // ~2, ~2.x, ~2.x.x, ~>2, ~>2.x ~>2.x.x --> >=2.0.0, <3.0.0 // ~2.0, ~2.0.x, ~>2.0, ~>2.0.x --> >=2.0.0, <2.1.0 // ~1.2, ~1.2.x, ~>1.2, ~>1.2.x --> >=1.2.0, <1.3.0 // ~1.2.3, ~>1.2.3 --> >=1.2.3, <1.3.0 // ~1.2.0, ~>1.2.0 --> >=1.2.0, <1.3.0 func constraintTilde(v *Version, c *constraint) bool { // If there is a pre-release on the version but the constraint isn't looking // for them assume that pre-releases are not compatible. See issue 21 for // more details. if v.Prerelease() != "" && c.con.Prerelease() == "" { return false } if v.LessThan(c.con) { return false } // ~0.0.0 is a special case where all constraints are accepted. It's // equivalent to >= 0.0.0. if c.con.Major() == 0 && c.con.Minor() == 0 && c.con.Patch() == 0 && !c.minorDirty && !c.patchDirty { return true } if v.Major() != c.con.Major() { return false } if v.Minor() != c.con.Minor() && !c.minorDirty { return false } return true } // When there is a .x (dirty) status it automatically opts in to ~. Otherwise // it's a straight = func constraintTildeOrEqual(v *Version, c *constraint) bool { // If there is a pre-release on the version but the constraint isn't looking // for them assume that pre-releases are not compatible. See issue 21 for // more details. if v.Prerelease() != "" && c.con.Prerelease() == "" { return false } if c.dirty { c.msg = constraintMsg["~"] return constraintTilde(v, c) } return v.Equal(c.con) } // ^* --> (any) // ^2, ^2.x, ^2.x.x --> >=2.0.0, <3.0.0 // ^2.0, ^2.0.x --> >=2.0.0, <3.0.0 // ^1.2, ^1.2.x --> >=1.2.0, <2.0.0 // ^1.2.3 --> >=1.2.3, <2.0.0 // ^1.2.0 --> >=1.2.0, <2.0.0 func constraintCaret(v *Version, c *constraint) bool { // If there is a pre-release on the version but the constraint isn't looking // for them assume that pre-releases are not compatible. See issue 21 for // more details. if v.Prerelease() != "" && c.con.Prerelease() == "" { return false } if v.LessThan(c.con) { return false } if v.Major() != c.con.Major() { return false } return true } var constraintRangeRegex *regexp.Regexp const cvRegex string = `v?([0-9|x|X|\*]+)(\.[0-9|x|X|\*]+)?(\.[0-9|x|X|\*]+)?` + `(-([0-9A-Za-z\-]+(\.[0-9A-Za-z\-]+)*))?` + `(\+([0-9A-Za-z\-]+(\.[0-9A-Za-z\-]+)*))?` func isX(x string) bool { switch x { case "x", "*", "X": return true default: return false } } func rewriteRange(i string) string { m := constraintRangeRegex.FindAllStringSubmatch(i, -1) if m == nil { return i } o := i for _, v := range m { t := fmt.Sprintf(">= %s, <= %s", v[1], v[11]) o = strings.Replace(o, v[0], t, 1) } return o }