npm install --save semver
As a node module:
const semver = require('semver') semver.valid('1.2.3') // '1.2.3' semver.valid('a.b.c') // null semver.clean(' =v1.2.3 ') // '1.2.3' semver.satisfies('1.2.3', '1.x || >=2.5.0 || 5.0.0 - 7.2.3') // true semver.gt('1.2.3', '9.8.7') // false semver.lt('1.2.3', '9.8.7') // true
As a command-line utility:
$ semver -h SemVer 5.3.0 A JavaScript implementation of the http://semver.org/ specification Copyright Isaac Z. Schlueter Usage: semver [options] <version> [<version> [...]] Prints valid versions sorted by SemVer precedence Options: -r --range <range> Print versions that match the specified range. -i --increment [<level>] Increment a version by the specified level. Level can be one of: major, minor, patch, premajor, preminor, prepatch, or prerelease. Default level is 'patch'. Only one version may be specified. --preid <identifier> Identifier to be used to prefix premajor, preminor, prepatch or prerelease version increments. -l --loose Interpret versions and ranges loosely Program exits successfully if any valid version satisfies all supplied ranges, and prints all satisfying versions. If no satisfying versions are found, then exits failure. Versions are printed in ascending order, so supplying multiple versions to the utility will just sort them.
A “version” is described by the v2.0.0
specification found at http://semver.org/.
A leading "="
or "v"
character is stripped off and ignored.
A version range
is a set of comparators
which specify versions that satisfy the range.
A comparator
is composed of an operator
and a version
. The set of primitive operators
is:
<
Less than<=
Less than or equal to>
Greater than>=
Greater than or equal to=
Equal. If no operator is specified, then equality is assumed, so this operator is optional, but MAY be included.For example, the comparator >=1.2.7
would match the versions 1.2.7
, 1.2.8
, 2.5.3
, and 1.3.9
, but not the versions 1.2.6
or 1.1.0
.
Comparators can be joined by whitespace to form a comparator set
, which is satisfied by the intersection of all of the comparators it includes.
A range is composed of one or more comparator sets, joined by ||
. A version matches a range if and only if every comparator in at least one of the ||
-separated comparator sets is satisfied by the version.
For example, the range >=1.2.7 <1.3.0
would match the versions 1.2.7
, 1.2.8
, and 1.2.99
, but not the versions 1.2.6
, 1.3.0
, or 1.1.0
.
The range 1.2.7 || >=1.2.9 <2.0.0
would match the versions 1.2.7
, 1.2.9
, and 1.4.6
, but not the versions 1.2.8
or 2.0.0
.
If a version has a prerelease tag (for example, 1.2.3-alpha.3
) then it will only be allowed to satisfy comparator sets if at least one comparator with the same [major, minor, patch]
tuple also has a prerelease tag.
For example, the range >1.2.3-alpha.3
would be allowed to match the version 1.2.3-alpha.7
, but it would not be satisfied by 3.4.5-alpha.9
, even though 3.4.5-alpha.9
is technically “greater than” 1.2.3-alpha.3
according to the SemVer sort rules. The version range only accepts prerelease tags on the 1.2.3
version. The version 3.4.5
would satisfy the range, because it does not have a prerelease flag, and 3.4.5
is greater than 1.2.3-alpha.7
.
The purpose for this behavior is twofold. First, prerelease versions frequently are updated very quickly, and contain many breaking changes that are (by the author's design) not yet fit for public consumption. Therefore, by default, they are excluded from range matching semantics.
Second, a user who has opted into using a prerelease version has clearly indicated the intent to use that specific set of alpha/beta/rc versions. By including a prerelease tag in the range, the user is indicating that they are aware of the risk. However, it is still not appropriate to assume that they have opted into taking a similar risk on the next set of prerelease versions.
The method .inc
takes an additional identifier
string argument that will append the value of the string as a prerelease identifier:
semver.inc('1.2.3', 'prerelease', 'beta') // '1.2.4-beta.0'
command-line example:
$ semver 1.2.3 -i prerelease --preid beta 1.2.4-beta.0
Which then can be used to increment further:
$ semver 1.2.4-beta.0 -i prerelease 1.2.4-beta.1
Advanced range syntax desugars to primitive comparators in deterministic ways.
Advanced ranges may be combined in the same way as primitive comparators using white space or ||
.
X.Y.Z - A.B.C
Specifies an inclusive set.
1.2.3 - 2.3.4
:= >=1.2.3 <=2.3.4
If a partial version is provided as the first version in the inclusive range, then the missing pieces are replaced with zeroes.
1.2 - 2.3.4
:= >=1.2.0 <=2.3.4
If a partial version is provided as the second version in the inclusive range, then all versions that start with the supplied parts of the tuple are accepted, but nothing that would be greater than the provided tuple parts.
1.2.3 - 2.3
:= >=1.2.3 <2.4.0
1.2.3 - 2
:= >=1.2.3 <3.0.0
1.2.x
1.X
1.2.*
*
Any of X
, x
, or *
may be used to “stand in” for one of the numeric values in the [major, minor, patch]
tuple.
*
:= >=0.0.0
(Any version satisfies)1.x
:= >=1.0.0 <2.0.0
(Matching major version)1.2.x
:= >=1.2.0 <1.3.0
(Matching major and minor versions)A partial version range is treated as an X-Range, so the special character is in fact optional.
""
(empty string) := *
:= >=0.0.0
1
:= 1.x.x
:= >=1.0.0 <2.0.0
1.2
:= 1.2.x
:= >=1.2.0 <1.3.0
~1.2.3
~1.2
~1
Allows patch-level changes if a minor version is specified on the comparator. Allows minor-level changes if not.
~1.2.3
:= >=1.2.3 <1.(2+1).0
:= >=1.2.3 <1.3.0
~1.2
:= >=1.2.0 <1.(2+1).0
:= >=1.2.0 <1.3.0
(Same as 1.2.x
)~1
:= >=1.0.0 <(1+1).0.0
:= >=1.0.0 <2.0.0
(Same as 1.x
)~0.2.3
:= >=0.2.3 <0.(2+1).0
:= >=0.2.3 <0.3.0
~0.2
:= >=0.2.0 <0.(2+1).0
:= >=0.2.0 <0.3.0
(Same as 0.2.x
)~0
:= >=0.0.0 <(0+1).0.0
:= >=0.0.0 <1.0.0
(Same as 0.x
)~1.2.3-beta.2
:= >=1.2.3-beta.2 <1.3.0
Note that prereleases in the 1.2.3
version will be allowed, if they are greater than or equal to beta.2
. So, 1.2.3-beta.4
would be allowed, but 1.2.4-beta.2
would not, because it is a prerelease of a different [major, minor, patch]
tuple.^1.2.3
^0.2.5
^0.0.4
Allows changes that do not modify the left-most non-zero digit in the [major, minor, patch]
tuple. In other words, this allows patch and minor updates for versions 1.0.0
and above, patch updates for versions 0.X >=0.1.0
, and no updates for versions 0.0.X
.
Many authors treat a 0.x
version as if the x
were the major “breaking-change” indicator.
Caret ranges are ideal when an author may make breaking changes between 0.2.4
and 0.3.0
releases, which is a common practice. However, it presumes that there will not be breaking changes between 0.2.4
and 0.2.5
. It allows for changes that are presumed to be additive (but non-breaking), according to commonly observed practices.
^1.2.3
:= >=1.2.3 <2.0.0
^0.2.3
:= >=0.2.3 <0.3.0
^0.0.3
:= >=0.0.3 <0.0.4
^1.2.3-beta.2
:= >=1.2.3-beta.2 <2.0.0
Note that prereleases in the 1.2.3
version will be allowed, if they are greater than or equal to beta.2
. So, 1.2.3-beta.4
would be allowed, but 1.2.4-beta.2
would not, because it is a prerelease of a different [major, minor, patch]
tuple.^0.0.3-beta
:= >=0.0.3-beta <0.0.4
Note that prereleases in the 0.0.3
version only will be allowed, if they are greater than or equal to beta
. So, 0.0.3-pr.2
would be allowed.When parsing caret ranges, a missing patch
value desugars to the number 0
, but will allow flexibility within that value, even if the major and minor versions are both 0
.
^1.2.x
:= >=1.2.0 <2.0.0
^0.0.x
:= >=0.0.0 <0.1.0
^0.0
:= >=0.0.0 <0.1.0
A missing minor
and patch
values will desugar to zero, but also allow flexibility within those values, even if the major version is zero.
^1.x
:= >=1.0.0 <2.0.0
^0.x
:= >=0.0.0 <1.0.0
Putting all this together, here is a Backus-Naur grammar for ranges, for the benefit of parser authors:
range-set ::= range ( logical-or range ) * logical-or ::= ( ' ' ) * '||' ( ' ' ) * range ::= hyphen | simple ( ' ' simple ) * | '' hyphen ::= partial ' - ' partial simple ::= primitive | partial | tilde | caret primitive ::= ( '<' | '>' | '>=' | '<=' | '=' | ) partial partial ::= xr ( '.' xr ( '.' xr qualifier ? )? )? xr ::= 'x' | 'X' | '*' | nr nr ::= '0' | ['1'-'9'] ( ['0'-'9'] ) * tilde ::= '~' partial caret ::= '^' partial qualifier ::= ( '-' pre )? ( '+' build )? pre ::= parts build ::= parts parts ::= part ( '.' part ) * part ::= nr | [-0-9A-Za-z]+
All methods and classes take a final loose
boolean argument that, if true, will be more forgiving about not-quite-valid semver strings. The resulting output will always be 100% strict, of course.
Strict-mode Comparators and Ranges will be strict about the SemVer strings that they parse.
valid(v)
: Return the parsed version, or null if it's not valid.inc(v, release)
: Return the version incremented by the release type (major
, premajor
, minor
, preminor
, patch
, prepatch
, or prerelease
), or null if it's not validpremajor
in one call will bump the version up to the next major version and down to a prerelease of that major version. preminor
, and prepatch
work the same way.prerelease
will work the same as prepatch
. It increments the patch version, then makes a prerelease. If the input version is already a prerelease it simply increments it.prerelease(v)
: Returns an array of prerelease components, or null if none exist. Example: prerelease('1.2.3-alpha.1') -> ['alpha', 1]
major(v)
: Return the major version number.minor(v)
: Return the minor version number.patch(v)
: Return the patch version number.intersects(r1, r2, loose)
: Return true if the two supplied ranges or comparators intersect.gt(v1, v2)
: v1 > v2
gte(v1, v2)
: v1 >= v2
lt(v1, v2)
: v1 < v2
lte(v1, v2)
: v1 <= v2
eq(v1, v2)
: v1 == v2
This is true if they‘re logically equivalent, even if they’re not the exact same string. You already know how to compare strings.neq(v1, v2)
: v1 != v2
The opposite of eq
.cmp(v1, comparator, v2)
: Pass in a comparison string, and it'll call the corresponding function above. "==="
and "!=="
do simple string comparison, but are included for completeness. Throws if an invalid comparison string is provided.compare(v1, v2)
: Return 0
if v1 == v2
, or 1
if v1
is greater, or -1
if v2
is greater. Sorts in ascending order if passed to Array.sort()
.rcompare(v1, v2)
: The reverse of compare. Sorts an array of versions in descending order when passed to Array.sort()
.diff(v1, v2)
: Returns difference between two versions by the release type (major
, premajor
, minor
, preminor
, patch
, prepatch
, or prerelease
), or null if the versions are the same.intersects(comparator)
: Return true if the comparators intersectvalidRange(range)
: Return the valid range or null if it's not validsatisfies(version, range)
: Return true if the version satisfies the range.maxSatisfying(versions, range)
: Return the highest version in the list that satisfies the range, or null
if none of them do.minSatisfying(versions, range)
: Return the lowest version in the list that satisfies the range, or null
if none of them do.gtr(version, range)
: Return true
if version is greater than all the versions possible in the range.ltr(version, range)
: Return true
if version is less than all the versions possible in the range.outside(version, range, hilo)
: Return true if the version is outside the bounds of the range in either the high or low direction. The hilo
argument must be either the string '>'
or '<'
. (This is the function called by gtr
and ltr
.)intersects(range)
: Return true if any of the ranges comparators intersectNote that, since ranges may be non-contiguous, a version might not be greater than a range, less than a range, or satisfy a range! For example, the range 1.2 <1.2.9 || >2.0.0
would have a hole from 1.2.9
until 2.0.0
, so the version 1.2.10
would not be greater than the range (because 2.0.1
satisfies, which is higher), nor less than the range (since 1.2.8
satisfies, which is lower), and it also does not satisfy the range.
If you want to know if a version satisfies or does not satisfy a range, use the satisfies(version, range)
function.