This is a fork of Semantic Versioning 2.0. The specific changes have to do with the format of pre-release and build labels, specifically to make them not confusing when co-existing with Linux distribution packaging and Python packaging. Inspiration for the format of the pre-release and build labels came from Python’s PEP440.
dev versions are defined. These are extremely useful when dealing with CI and CD systems when ‘every commit is a release’ is not feasible.
All versions have been made PEP-440 compatible, because of our deep roots in Python:
Pre-release versions are now separated by . not -, and use a/b/c rather than alpha/beta etc.
Alpha version are prefixed by a 0 such as: 2.0.0.0a1
instead of
2.0.0.a1
for version ‘2.0.0 alpha 1’. Please note dev version tag
does not have a leading 0, as is 2.0.0.0a2.dev1
.
Given a version number MAJOR.MINOR.PATCH, increment the:
MAJOR version when you make incompatible API changes,
MINOR version when you add functionality in a backwards-compatible manner, and
PATCH version when you make backwards-compatible bug fixes.
In the world of software management there exists a dread place called “dependency hell.” The bigger your system grows and the more packages you integrate into your software, the more likely you are to find yourself, one day, in this pit of despair.
In systems with many dependencies, releasing new package versions can quickly become a nightmare. If the dependency specifications are too tight, you are in danger of version lock (the inability to upgrade a package without having to release new versions of every dependent package). If dependencies are specified too loosely, you will inevitably be bitten by version promiscuity (assuming compatibility with more future versions than is reasonable). Dependency hell is where you are when version lock and/or version promiscuity prevent you from easily and safely moving your project forward.
As a solution to this problem, I propose a simple set of rules and requirements that dictate how version numbers are assigned and incremented. These rules are based on but not necessarily limited to pre-existing widespread common practices in use in both closed and open-source software. For this system to work, you first need to declare a public API. This may consist of documentation or be enforced by the code itself. Regardless, it is important that this API be clear and precise. Once you identify your public API, you communicate changes to it with specific increments to your version number. Consider a version format of X.Y.Z (Major.Minor.Patch). Bug fixes not affecting the API increment the patch version, backwards compatible API additions/changes increment the minor version, and backwards incompatible API changes increment the major version.
I call this system “Semantic Versioning.” Under this scheme, version numbers and the way they change convey meaning about the underlying code and what has been modified from one version to the next.
The key words “MUST”, “MUST NOT”, “REQUIRED”, “SHALL”, “SHALL NOT”, “SHOULD”, “SHOULD NOT”, “RECOMMENDED”, “MAY”, and “OPTIONAL” in this document are to be interpreted as described in RFC 2119.
Software using Semantic Versioning MUST declare a public API. This API could be declared in the code itself or exist strictly in documentation. However it is done, it should be precise and comprehensive.
A normal version number MUST take the form X.Y.Z where X, Y, and Z are non-negative integers, and MUST NOT contain leading zeroes. X is the major version, Y is the minor version, and Z is the patch version. Each element MUST increase numerically. For instance: 1.9.0 -> 1.10.0 -> 1.11.0.
Once a versioned package has been released, the contents of that version MUST NOT be modified. Any modifications MUST be released as a new version.
Major version zero (0.y.z) is for initial development. Anything may change at any time. The public API should not be considered stable.
Version 1.0.0 defines the public API. The way in which the version number is incremented after this release is dependent on this public API and how it changes.
Patch version Z (x.y.Z | x > 0) MUST be incremented if only backwards compatible bug fixes are introduced. A bug fix is defined as an internal change that fixes incorrect behavior.
Minor version Y (x.Y.z | x > 0) MUST be incremented if new, backwards compatible functionality is introduced to the public API. It MUST be incremented if any public API functionality is marked as deprecated. It MAY be incremented if substantial new functionality or improvements are introduced within the private code. It MAY include patch level changes. Patch version MUST be reset to 0 when minor version is incremented.
Major version X (X.y.z | X > 0) MUST be incremented if any backwards incompatible changes are introduced to the public API. It MAY also include minor and patch level changes. Patch and minor version MUST be reset to 0 when major version is incremented.
A pre-release version MAY be denoted by appending a dot separated identifier immediately following the patch version. The identifier MUST comprise only a, b, c followed by non-negative integer value. The identifier MUST NOT be empty. Pre-release versions have a lower precedence than the associated normal version. A pre-release version indicates that the version is unstable and might not satisfy the intended compatibility requirements as denoted by its associated normal version. Examples: 1.0.0.0a1, 1.0.0.0b99, 1.0.0.0c1000.
A development version MAY be denoted by appending a dot separated identifier immediately following the patch version. The identifier MUST comprise the string dev followed by non-negative integer value. The identifier MUST NOT be empty. Development versions have a lower precedence than the associated normal version or pre-release version. A development version is a completely unsupported and conveys no API promises when related to other versions. They are more useful as communication vehicles between developers of a community, whereas pre-releases, while potentially prone to break still, are intended for externally facing communication of not-yet-released ideas. Dev versions are not public artifacts and should never be placed in public repositories: they are intended as developer-local resources. Examples: 1.0.0.dev1, 1.0.0.0a1.dev1
git version metadata MAY be denoted by appending a dot separated identifier immediately following a development or pre-release version. The identifier MUST comprise the character g followed by a seven character git short-sha. The sha MUST NOT be empty. git version metadata MUST be ignored when determining version precedence. Thus two versions that differ only in the git version, have the same precedence. Example: 1.0.0.0a1.g95a9beb.
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 [0-9A-Za-z]. Identifiers MUST NOT be empty. Build metadata MUST be ignored when determining version precedence. Thus two versions that differ only in the build metadata, have the same precedence. Examples: 1.0.0.0a1+001, 1.0.0+20130313144700, 1.0.0.0b1+exp.sha.5114f85.
Precedence refers to how versions are compared to each other when ordered. Precedence MUST be calculated by separating the version into major, minor, patch, pre-release, and development identifiers in that order (Build metadata does not figure into precedence). Precedence is determined by the first difference when comparing each of these identifiers from left to right as follows: Major, minor, and patch versions are always compared numerically. Example: 1.0.0 < 2.0.0 < 2.1.0 < 2.1.1. When major, minor, and patch are equal, a pre-release version has lower precedence than a normal version. Example: 1.0.0.0a1 < 1.0.0. When major, minor, patch and pre-release are equal, a development version has a lower precedence than a normal version and of a pre-release version. Example: 1.0.0.dev1 < 1.0.0 and 1.0.0.dev9 < 1.0.0.0a1 and 1.0.0.0a1 < 1.0.0.0a2.dev4. Precedence for two pre-release versions with the same major, minor, and patch version MUST be determined by comparing the identifier to the right of the patch version as follows: if the alpha portion matches, the numeric portion is compared in numerical sort order. If the alpha portion does not match, the sort order is dev < a < b < c. Example: 1.0.0.dev8 < 1.0.0.dev9 < 1.0.0.0a1.dev3 < 1.0.0.0a1 < 1.0.0.0b2 < 1.0.0.0c1 < 1.0.0. Precedence for dev versions if all other components are equal is done by comparing their numeric component. If all other components are not equal, predence is determined by comparing the other components.
This is not a new or revolutionary idea. In fact, you probably do something close to this already. The problem is that “close” isn’t good enough. Without compliance to some sort of formal specification, version numbers are essentially useless for dependency management. By giving a name and clear definition to the above ideas, it becomes easy to communicate your intentions to the users of your software. Once these intentions are clear, flexible (but not too flexible) dependency specifications can finally be made.
A simple example will demonstrate how Semantic Versioning can make dependency hell a thing of the past. Consider a library called “Firetruck.” It requires a Semantically Versioned package named “Ladder.” At the time that Firetruck is created, Ladder is at version 3.1.0. Since Firetruck uses some functionality that was first introduced in 3.1.0, you can safely specify the Ladder dependency as greater than or equal to 3.1.0 but less than 4.0.0. Now, when Ladder version 3.1.1 and 3.2.0 become available, you can release them to your package management system and know that they will be compatible with existing dependent software.
As a responsible developer you will, of course, want to verify that any package upgrades function as advertised. The real world is a messy place; there’s nothing we can do about that but be vigilant. What you can do is let Semantic Versioning provide you with a sane way to release and upgrade packages without having to roll new versions of dependent packages, saving you time and hassle.
If all of this sounds desirable, all you need to do to start using Semantic Versioning is to declare that you are doing so and then follow the rules. Link to this website from your README so others know the rules and can benefit from them.
The simplest thing to do is start your initial development release at 0.1.0 and then increment the minor version for each subsequent release.
If your software is being used in production, it should probably already be 1.0.0. If you have a stable API on which users have come to depend, you should be 1.0.0. If you’re worrying a lot about backwards compatibility, you should probably already be 1.0.0.
Major version zero is all about rapid development. If you’re changing the API every day you should either still be in version 0.y.z or on a separate development branch working on the next major version.
This is a question of responsible development and foresight. Incompatible changes should not be introduced lightly to software that has a lot of dependent code. The cost that must be incurred to upgrade can be significant. Having to bump major versions to release incompatible changes means you’ll think through the impact of your changes, and evaluate the cost/benefit ratio involved.
It is your responsibility as a professional developer to properly document software that is intended for use by others. Managing software complexity is a hugely important part of keeping a project efficient, and that’s hard to do if nobody knows how to use your software, or what methods are safe to call. In the long run, Semantic Versioning, and the insistence on a well defined public API can keep everyone and everything running smoothly.
As soon as you realize that you’ve broken the Semantic Versioning spec, fix the problem and release a new minor version that corrects the problem and restores backwards compatibility. Even under this circumstance, it is unacceptable to modify versioned releases. If it’s appropriate, document the offending version and inform your users of the problem so that they are aware of the offending version.
That would be considered compatible since it does not affect the public API. Software that explicitly depends on the same dependencies as your package should have their own dependency specifications and the author will notice any conflicts. Determining whether the change is a patch level or minor level modification depends on whether you updated your dependencies in order to fix a bug or introduce new functionality. I would usually expect additional code for the latter instance, in which case it’s obviously a minor level increment.
Use your best judgment. If you have a huge audience that will be drastically impacted by changing the behavior back to what the public API intended, then it may be best to perform a major version release, even though the fix could strictly be considered a patch release. Remember, Semantic Versioning is all about conveying meaning by how the version number changes. If these changes are important to your users, use the version number to inform them.
Deprecating existing functionality is a normal part of software development and is often required to make forward progress. When you deprecate part of your public API, you should do two things: (1) update your documentation to let users know about the change, (2) issue a new minor release with the deprecation in place. Before you completely remove the functionality in a new major release there should be at least one minor release that contains the deprecation so that users can smoothly transition to the new API.
No, but use good judgment. A 255 character version string is probably overkill, for example. Also, specific systems may impose their own limits on the size of the string.
The Linux/Python Compatible Semantic Versioning specification is maintained by the OpenStack project.
It is based on The Semantic Versioning specification, which was authored by Tom Preston-Werner, with inputs from PEP 440
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