| # Toward Go 2 |
| 13 Jul 2017 |
| Tags: community |
| Summary: How we will all work together toward Go 2. |
| |
| Russ Cox |
| |
| ## Introduction |
| |
| [This is the text of |
| [my talk today](https://www.youtube.com/watch?v=0Zbh_vmAKvk) |
| at Gophercon 2017, asking for the entire Go community's |
| help as we discuss and plan Go 2.] |
| |
| On September 25, 2007, after Rob Pike, Robert Griesemer, and Ken |
| Thompson had been discussing a new programming language for a few |
| days, Rob suggested the name “Go.” |
| |
| <div style="margin-left: 2em;"> |
| .image toward-go2/mail.png _ 446 |
| </div> |
| |
| The next year, Ian Lance Taylor and I joined the team, and together |
| the five of us built two compilers and a standard library, leading up |
| to the [open-source release](https://opensource.googleblog.com/2009/11/hey-ho-lets-go.html) on November 10, 2009. |
| |
| <div style="margin-left: 2em;"> |
| .image toward-go2/tweet.png _ 467 |
| </div> |
| |
| For the next two years, with the help of the new Go open source |
| community, we experimented with changes large and small, refining Go |
| and leading to the [plan for Go 1](https://blog.golang.org/preview-of-go-version-1), proposed on October 5, 2011. |
| |
| <div style="margin-left: 2em;"> |
| .image toward-go2/go1-preview.png _ 560 |
| </div> |
| |
| With more help from the Go community, we revised and implemented that |
| plan, eventually [releasing Go 1](https://blog.golang.org/go-version-1-is-released) on March 28, 2012. |
| |
| <div style="margin-left: 2em;"> |
| .image toward-go2/go1-release.png _ 556 |
| </div> |
| |
| The release of Go 1 marked the culmination of nearly five years of |
| creative, frenetic effort that took us from a name and a list of ideas |
| to a stable, production language. It also marked an explicit shift |
| from change and churn to stability. |
| |
| In the years leading to Go 1, we changed Go and broke everyone's Go |
| programs nearly every week. We understood that this was keeping Go |
| from use in production settings, where programs could not be rewritten |
| weekly to keep up with language changes. |
| As the [blog post announcing Go 1](https://blog.golang.org/go-version-1-is-released) says, the driving motivation was to provide a stable foundation |
| for creating reliable products, projects, and publications (blogs, |
| tutorials, conference talks, and books), to make users confident that |
| their programs would continue to compile and run without change for |
| years to come. |
| |
| After Go 1 was released, we knew that we needed to spend time using Go |
| in the production environments it was designed for. We shifted |
| explicitly away from making language changes toward using Go in our |
| own projects and improving the implementation: we ported Go to many |
| new systems, we rewrote nearly every performance-critical piece to |
| make Go run more efficiently, and we added key tools like the |
| [race detector](https://blog.golang.org/race-detector). |
| |
| Now we have five years of experience using Go to build large, |
| production-quality systems. We have developed a sense of what works |
| and what does not. Now it is time to begin the next step in Go's |
| evolution and growth, to plan the future of Go. I'm here today to ask |
| all of you in the Go community, whether you're in the audience at |
| GopherCon or watching on video or reading the Go blog later today, to |
| work with us as we plan and implement Go 2. |
| |
| In the rest of this talk, I'm going to explain our goals for Go 2; our |
| constraints and limitations; the overall process; the importance of |
| writing about our experiences using Go, especially as they relate to |
| problems we might try to solve; the possible kinds of solutions; how |
| we will deliver Go 2; and how all of you can help. |
| |
| ## Goals |
| |
| The goals we have for Go today are the same as in 2007. We want to |
| make programmers more effective at managing two kinds of scale: |
| production scale, especially concurrent systems interacting with many |
| other servers, exemplified today by cloud software; and development |
| scale, especially large codebases worked on by many engineers |
| coordinating only loosely, exemplified today by modern open-source |
| development. |
| |
| These kinds of scale show up at companies of all sizes. Even a |
| five-person startup may use large cloud-based API services provided by |
| other companies and use more open-source software than software they |
| write themselves. Production scale and development scale are just as |
| relevant at that startup as they are at Google. |
| |
| Our goal for Go 2 is to fix the most significant ways Go fails to |
| scale. |
| |
| (For more about these goals, see |
| Rob Pike's 2012 article “[Go at Google: Language Design in the Service of Software Engineering](https://talks.golang.org/2012/splash.article)” |
| and my GopherCon 2015 talk “[Go, Open Source, Community](https://blog.golang.org/open-source).”) |
| |
| ## Constraints |
| |
| The goals for Go have not changed since the beginning, but the |
| constraints on Go certainly have. The most important constraint is |
| existing Go usage. We estimate that there are at least |
| [half a million Go developers worldwide](https://research.swtch.com/gophercount), |
| which means there are millions of Go source files and at |
| least a billion of lines of Go code. Those programmers and that source |
| code represent Go's success, but they are also the main constraint on |
| Go 2. |
| |
| Go 2 must bring along all those developers. We must ask them to |
| unlearn old habits and learn new ones only when the reward is great. |
| For example, before Go 1, the method implemented by error types was |
| named `String`. In Go 1, we renamed it `Error`, to distinguish error types |
| from other types that can format themselves. The other day I was |
| implementing an error type, and without thinking I named its method |
| `String` instead of `Error`, which of course did not compile. After five |
| years I still have not completely unlearned the old way. That kind of |
| clarifying renaming was an important change to make in Go 1 but would |
| be too disruptive for Go 2 without a very good reason. |
| |
| Go 2 must also bring along all the existing Go 1 source code. We must |
| not split the Go ecosystem. Mixed programs, in which packages written |
| in Go 2 import packages written in Go 1 and vice versa, must work |
| effortlessly during a transition period of multiple years. We'll have |
| to figure out exactly how to do that; automated tooling like go fix |
| will certainly play a part. |
| |
| To minimize disruption, each change will require careful thought, |
| planning, and tooling, which in turn limits the number of changes we |
| can make. Maybe we can do two or three, certainly not more than five. |
| |
| I'm not counting minor housekeeping changes like maybe allowing identifiers |
| in more spoken languages or adding binary integer literals. Minor |
| changes like these are also important, but they are easier to get |
| right. I'm focusing today on possible major changes, such as |
| additional support for error handling, or introducing immutable or |
| read-only values, or adding some form of generics, or other important |
| topics not yet suggested. We can do only a few of those major changes. |
| We will have to choose carefully. |
| |
| ## Process |
| |
| That raises an important question. What is the process for developing |
| Go? |
| |
| In the early days of Go, when there were just five of us, we worked in |
| a pair of adjacent shared offices separated by a glass wall. It was |
| easy to pull everyone into one office to discuss some problem and then |
| go back to our desks to implement a solution. When some wrinkle arose |
| during the implementation, it was easy to gather everyone again. Rob |
| and Robert's office had a small couch and a whiteboard, so typically |
| one of us went in and started writing an example on the board. Usually |
| by the time the example was up, everyone else had reached a good |
| stopping point in their own work and was ready to sit down and discuss |
| it. That informality obviously doesn't scale to the global Go |
| community of today. |
| |
| Part of the work since the open-source release of Go has been porting |
| our informal process into the more formal world of mailing lists and |
| issue trackers and half a million users, but I don't think we've ever |
| explicitly described our overall process. It's possible we never |
| consciously thought about it. Looking back, though, I think this is |
| the basic outline of our work on Go, the process we've been following |
| since the first prototype was running. |
| |
| <div style="margin-left: 2em;"> |
| .image toward-go2/process.png _ 410 |
| </div> |
| |
| Step 1 is to use Go, to accumulate experience with it. |
| |
| Step 2 is to identify a problem with Go that might need solving and to |
| articulate it, to explain it to others, to write it down. |
| |
| Step 3 is to propose a solution to that problem, discuss it with |
| others, and revise the solution based on that discussion. |
| |
| Step 4 is to implement the solution, evaluate it, and refine it based |
| on that evaluation. |
| |
| Finally, step 5 is to ship the solution, adding it to the language, or |
| the library, or the set of tools that people use from day to day. |
| |
| The same person does not have to do all these steps for a particular |
| change. In fact, usually many people collaborate on any given step, |
| and many solutions may be proposed for a single problem. Also, at any |
| point we may realize we don’t want to go further with a particular |
| idea and circle back to an earlier step. |
| |
| Although I don't believe we've ever talked about this process as a |
| whole, we have explained parts of it. In 2012, when we released Go 1 |
| and said that it was time now to use Go and stop changing it, we were |
| explaining step 1. In 2015, when we introduced the Go change proposal |
| process, we were explaining steps 3, 4, and 5. But we've never |
| explained step 2 in detail, so I'd like to do that now. |
| |
| (For more about the development of Go 1 and the shift away from |
| language changes, see Rob Pike and Andrew Gerrand's |
| OSCON 2012 talk “[The Path to Go 1](https://blog.golang.org/the-path-to-go-1).” |
| For more about the proposal process, see |
| Andrew Gerrand's GopherCon 2015 talk “[How Go was Made](https://www.youtube.com/watch?v=0ht89TxZZnk)” and the |
| [proposal process documentation](https://golang.org/s/proposal).) |
| |
| ## Explaining Problems |
| |
| <div style="margin-left: 2em;"> |
| .image toward-go2/process2.png _ 410 |
| </div> |
| |
| There are two parts to explaining a problem. The first part—the easier |
| part—is stating exactly what the problem is. We developers are |
| decently good at this. After all, every test we write is a statement |
| of a problem to be solved, in language so precise that even a computer |
| can understand it. The second part—the harder part—is describing the |
| significance of the problem well enough that everyone can understand |
| why we should spend time solving it and maintaining a solution. In |
| contrast to stating a problem precisely, we don't need to describe a |
| problem's significance very often, and we're not nearly as good at it. |
| Computers never ask us “why is this test case important? Are you sure |
| this is the problem you need to solve? Is solving this problem the |
| most important thing you can be doing?” Maybe they will someday, but |
| not today. |
| |
| Let's look at an old example from 2011. Here is what I wrote about |
| renaming os.Error to error.Value while we were planning Go 1. |
| |
| <div style="margin-left: 2em;"> |
| .image toward-go2/error.png _ 495 |
| </div> |
| |
| It begins with a precise, one-line statement of the problem: in very |
| low-level libraries everything imports "os" for os.Error. Then there |
| are five lines, which I've underlined here, devoted to describing the |
| significance of the problem: the packages that "os" uses cannot |
| themselves present errors in their APIs, and other packages depend on |
| "os" for reasons having nothing to do with operating system services. |
| |
| Do these five lines convince _you_ that this problem is significant? |
| It depends on how well you can fill in the context I've left out: |
| being understood requires anticipating what others need to know. For |
| my audience at the time—the ten other people on the Go team at Google |
| who were reading that document—those fifty words were enough. To |
| present the same problem to the audience at GothamGo last fall—an |
| audience with much more varied backgrounds and areas of expertise—I |
| needed to provide more context, and I used about two hundred words, |
| along with real code examples and a diagram. It is a fact of today's |
| worldwide Go community that describing the significance of any problem |
| requires adding context, especially illustrated by concrete examples, |
| that you would leave out when talking to coworkers. |
| |
| Convincing others that a problem is significant is an essential step. |
| When a problem appears insignificant, almost every solution will seem |
| too expensive. But for a significant problem, there are usually many |
| solutions of reasonable cost. When we disagree about whether to adopt |
| a particular solution, we're often actually disagreeing about the |
| significance of the problem being solved. This is so important that I |
| want to look at two recent examples that show this clearly, at least |
| in hindsight. |
| |
| ### Example: Leap seconds |
| |
| My first example is about time. |
| |
| Suppose you want to time how long an event takes. You write down the |
| start time, run the event, write down the end time, and then subtract |
| the start time from the end time. If the event took ten milliseconds, |
| the subtraction gives a result of ten milliseconds, perhaps plus or |
| minus a small measurement error. |
| |
| start := time.Now() // 3:04:05.000 |
| event() |
| end := time.Now() // 3:04:05.010 |
| |
| elapsed := end.Sub(start) // 10 ms |
| |
| This obvious procedure can fail during a [leap second](https://en.wikipedia.org/wiki/Leap_second). When our clocks |
| are not quite in sync with the daily rotation of the Earth, a leap |
| second—officially 11:59pm and 60 seconds—is inserted just before |
| midnight. Unlike leap years, leap seconds follow no predictable |
| pattern, which makes them hard to fit into programs and APIs. Instead |
| of trying to represent the occasional 61-second minute, operating |
| systems typically implement a leap second by turning the clock back |
| one second just before what would have been midnight, so that 11:59pm |
| and 59 seconds happens twice. This clock reset makes time appear to |
| move backward, so that our ten-millisecond event might be timed as |
| taking negative 990 milliseconds. |
| |
| start := time.Now() // 11:59:59.995 |
| event() |
| end := time.Now() // 11:59:59.005 (really 11:59:60.005) |
| |
| elapsed := end.Sub(start) // –990 ms |
| |
| Because the time-of-day clock is inaccurate for timing events across |
| clock resets like this, operating systems now provide a second clock, |
| the monotonic clock, which has no absolute meaning but counts seconds |
| and is never reset. |
| |
| Except during the odd clock reset, the monotonic clock is no better |
| than the time-of-day clock, and the time-of-day clock has the added |
| benefit of being useful for telling time, so for simplicity Go 1’s |
| time APIs expose only the time-of-day clock. |
| |
| In October 2015, a [bug report](https://golang.org/issue/12914) noted that Go programs could not time |
| events correctly across clock resets, especially a typical leap second. |
| The suggested fix was also the original issue title: “add a new API to access a |
| monotonic clock source.” I argued that this problem was not |
| significant enough to justify new API. A few months earlier, for the |
| mid-2015 leap second, Akamai, Amazon, and Google had slowed their |
| clocks a tiny amount for the entire day, absorbing the extra second |
| without turning their clocks backward. It seemed like eventual |
| widespread adoption of this “[leap smear](https://developers.google.com/time/smear)” approach would eliminate |
| leap-second clock resets as a problem on production systems. In |
| contrast, adding new API to Go would add new problems: we would have |
| to explain the two kinds of clocks, educate users about when to use |
| each, and convert many lines of existing code, all for an issue that |
| rarely occurred and might plausibly go away on its own. |
| |
| We did what we always do when there's a problem without a clear |
| solution: we waited. Waiting gives us more time to add experience and |
| understanding of the problem and also more time to find a good |
| solution. In this case, waiting added to our understanding of the |
| significance of the problem, in the form of a thankfully |
| [minor outage at Cloudflare](https://www.theregister.co.uk/2017/01/04/cloudflare_trips_over_leap_second/). |
| Their Go code timed DNS requests during the end-of-2016 |
| leap second as taking around negative 990 milliseconds, which caused |
| simultaneous panics across their servers, breaking 0.2% of DNS queries |
| at peak. |
| |
| Cloudflare is exactly the kind of cloud system Go was intended for, |
| and they had a production outage based on Go not being able to time |
| events correctly. Then, and this is the key point, Cloudflare reported |
| their experience in a blog post by John Graham-Cumming titled |
| “[How and why the leap second affected Cloudflare DNS](https://blog.cloudflare.com/how-and-why-the-leap-second-affected-cloudflare-dns/).” By sharing concrete |
| details of their experience with Go in production, John and Cloudflare helped us |
| understand that the problem of accurate timing across leap second |
| clock resets was too significant to leave unfixed. Two months after |
| that article was published, we had designed and implemented a solution |
| that will [ship in Go 1.9](https://beta.golang.org/doc/go1.9#monotonic-time) |
| (and in fact we did it with [no new API](https://golang.org/design/12914-monotonic)). |
| |
| ### Example: Alias declarations |
| |
| My second example is support for alias declarations in Go. |
| |
| Over the past few years, Google has established a team focused on |
| large-scale code changes, meaning API migration and bug fixes applied |
| across our |
| [codebase of millions of source files and billions of lines of code](http://cacm.acm.org/magazines/2016/7/204032-why-google-stores-billions-of-lines-of-code-in-a-single-repository/pdf) |
| written in C++, Go, Java, Python, and other languages. One |
| thing I've learned from that team's work is the importance, when |
| changing an API from using one name to another, of being able to |
| update client code in multiple steps, not all at once. To do this, it |
| must be possible to write a declaration forwarding uses of the old |
| name to the new name. C++ has #define, typedef, and using declarations |
| to enable this forwarding, but Go has nothing. Of course, one of Go's |
| goals is to scale well to large codebases, and as the amount of Go |
| code at Google grew, it became clear both that we needed some kind of |
| forwarding mechanism and also that other projects and companies would |
| run into this problem as their Go codebases grew. |
| |
| In March 2016, I started talking with Robert Griesemer and Rob Pike |
| about how Go might handle gradual codebase updates, and we arrived at |
| alias declarations, which are exactly the needed forwarding mechanism. |
| At this point, I felt very good about the way Go was evolving. We'd |
| talked about aliases since the early days of Go—in fact, the first |
| spec draft has [an example using alias declarations](https://go.googlesource.com/go/+/18c5b488a3b2e218c0e0cf2a7d4820d9da93a554/doc/go_spec#1182)—but each time we'd |
| discussed aliases, and later type aliases, we had no clear use case |
| for them, so we left them out. Now we were proposing to add aliases |
| not because they were an elegant concept but because they solved a |
| significant practical problem with Go meeting its goal of scalable |
| software development. I hoped this would serve as a model for future |
| changes to Go. |
| |
| Later in the spring, Robert and Rob wrote [a proposal](https://golang.org/design/16339-alias-decls), |
| and Robert presented it in a [Gophercon 2016 lightning talk](https://www.youtube.com/watch?v=t-w6MyI2qlU). The next few months |
| did not go smoothly, and they were definitely not a model for future |
| changes to Go. One of the many lessons we learned was the importance |
| of describing the significance of a problem. |
| |
| A minute ago, I explained the problem to you, giving some background |
| about how it can arise and why, but with no concrete examples that |
| might help you evaluate whether the problem might affect you at some |
| point. Last summer’s proposal and the lightning talk gave an abstract |
| example, involving packages C, L, L1, and C1 through Cn, but no |
| concrete examples that developers could relate to. As a result, most |
| of the feedback from the community was based on the idea that aliases |
| only solved a problem for Google, not for everyone else. |
| |
| Just as we at Google did not at first understand the significance of |
| handling leap second time resets correctly, we did not effectively |
| convey to the broader Go community the significance of handling |
| gradual code migration and repair during large-scale changes. |
| |
| In the fall we started over. I gave a [talk](https://www.youtube.com/watch?v=h6Cw9iCDVcU) and wrote |
| [an article presenting the problem](https://talks.golang.org/2016/refactor.article) |
| using multiple concrete examples drawn from |
| open source codebases, showing how this problem arises everywhere, not |
| just inside Google. Now that more people understood the problem and |
| could see its significance, we had a [productive discussion](https://golang.org/issue/18130) about what |
| kind of solution would be best. The outcome is that [type aliases](https://golang.org/design/18130-type-alias) will |
| be [included in Go 1.9](https://beta.golang.org/doc/go1.9#language) and will help Go scale to ever-larger codebases. |
| |
| ### Experience reports |
| |
| The lesson here is that it is difficult but essential to describe the |
| significance of a problem in a way that someone working in a different |
| environment can understand. To discuss major changes to Go as a |
| community, we will need to pay particular attention to describing the |
| significance of any problem we want to solve. The clearest way to do |
| that is by showing how the problem affects real programs and real |
| production systems, like in |
| [Cloudflare's blog post](https://blog.cloudflare.com/how-and-why-the-leap-second-affected-cloudflare-dns/) and in |
| [my refactoring article](https://talks.golang.org/2016/refactor.article). |
| |
| Experience reports like these turn an abstract problem into a concrete |
| one and help us understand its significance. They also serve as test |
| cases: any proposed solution can be evaluated by examining its effect |
| on the actual, real-world problems the reports describe. |
| |
| For example, I've been examining generics recently, but I don't have |
| in my mind a clear picture of the detailed, concrete problems that Go |
| users need generics to solve. As a result, I can't answer a design |
| question like whether to support generic methods, which is to say |
| methods that are parameterized separately from the receiver. If we had |
| a large set of real-world use cases, we could begin to answer a |
| question like this by examining the significant ones. |
| |
| As another example, I’ve seen proposals to extend the error interface |
| in various ways, but I haven't seen any experience reports showing how |
| large Go programs attempt to understand and handle errors at all, much |
| less showing how the current error interface hinders those attempts. |
| These reports would help us all better understand the details and |
| significance of the problem, which we must do before solving it. |
| |
| I could go on. Every major potential change to Go should be motivated |
| by one or more experience reports documenting how people use Go today |
| and why that's not working well enough. For the obvious major changes |
| we might consider for Go, I'm not aware of many such reports, |
| especially not reports illustrated with real-world examples. |
| |
| These reports are the raw material for the Go 2 proposal process, and |
| we need all of you to write them, to help us understand your |
| experiences with Go. There are half a million of you, working in a |
| broad range of environments, and not that many of us. |
| Write a post on your own blog, |
| or write a [Medium](https://www.medium.com/) post, |
| or write a [Github Gist](https://gist.github.com/) (add a `.md` file extension for Markdown), |
| or write a [Google doc](https://docs.google.com/), |
| or use any other publishing mechanism you like. |
| After you've posted, please add the post to our new wiki page, |
| [golang.org/wiki/ExperienceReports](https://golang.org/wiki/ExperienceReports). |
| |
| ## Solutions |
| |
| <div style="margin-left: 2em;"> |
| .image toward-go2/process34.png _ 410 |
| </div> |
| |
| Now that we know how we're going to identify and explain problems that |
| need to be solved, I want to note briefly that not all problems are |
| best solved by language changes, and that's fine. |
| |
| One problem we might want to solve is that computers can often compute |
| additional results during basic arithmetic operations, but Go does not |
| provide direct access to those results. In 2013, Robert proposed that |
| we might extend the idea of two-result (“comma-ok”) expressions to |
| basic arithmetic. For example, if x and y are, say, uint32 values, |
| `lo, hi = x * y` |
| would return not only the usual low 32 bits but also the high 32 bits |
| of the product. This problem didn't seem particularly significant, so |
| we [recorded the potential solution](https://golang.org/issue/6815) but didn't implement it. We waited. |
| |
| More recently, we designed for Go 1.9 a [math/bits package](https://beta.golang.org/doc/go1.9#math-bits) that |
| contains various bit manipulation functions: |
| |
| package bits // import "math/bits" |
| |
| func LeadingZeros32(x uint32) int |
| func Len32(x uint32) int |
| func OnesCount32(x uint32) int |
| func Reverse32(x uint32) uint32 |
| func ReverseBytes32(x uint32) uint32 |
| func RotateLeft32(x uint32, k int) uint32 |
| func TrailingZeros32(x uint32) int |
| ... |
| |
| The package has good Go |
| implementations of each function, but the compilers also substitute |
| special hardware instructions when available. Based on this experience |
| with math/bits, both Robert and I now believe that making the |
| additional arithmetic results available by changing the language is |
| unwise, and that instead we should define appropriate functions in a |
| package like math/bits. Here the best solution is a library change, |
| not a language change. |
| |
| A different problem we might have wanted to solve, after Go 1.0, was |
| the fact that goroutines and shared memory make it too easy to |
| introduce races into Go programs, causing crashes and other |
| misbehavior in production. The language-based solution would have been |
| to find some way to disallow data races, to make it impossible to |
| write or at least to compile a program with a data race. How to fit |
| that into a language like Go is still an open question in the |
| programming language world. Instead we added a tool to the main |
| distribution and made it trivial to use: that tool, the [race detector](https://blog.golang.org/race-detector), has become |
| an indispensible part of the Go experience. Here the best solution was |
| a runtime and tooling change, not a language change. |
| |
| There will be language changes as well, of course, but not all |
| problems are best solved in the language. |
| |
| ## Shipping Go 2 |
| |
| <div style="margin-left: 2em;"> |
| .image toward-go2/process5.png _ 410 |
| </div> |
| |
| Finally, how will we ship and deliver Go 2? |
| |
| I think the best plan would be to ship the [backwards-compatible parts](https://golang.org/doc/go1compat) |
| of Go 2 incrementally, feature by feature, as part of the Go 1 release |
| sequence. This has a few important properties. First, it keeps the Go |
| 1 releases on the [usual schedule](https://golang.org/wiki/Go-Release-Cycle), to continue the timely bug fixes and |
| improvements that users now depend on. Second, it avoids splitting |
| development effort between Go 1 and Go 2. Third, it avoids divergence |
| between Go 1 and Go 2, to ease everyone's eventual migration. Fourth, |
| it allows us to focus on and deliver one change at a time, which |
| should help maintain quality. Fifth, it will encourage us to design |
| features to be backwards-compatible. |
| |
| We will need time to discuss and plan before any changes start landing in |
| Go 1 releases, but it seems plausible to me that we might start seeing |
| minor changes about a year from now, for Go 1.12 or so. That also |
| gives us time to land package management support first. |
| |
| Once all the backwards-compatible work is done, say in Go 1.20, then |
| we can make the backwards-incompatible changes in Go 2.0. If there |
| turn out to be no backwards-incompatible changes, maybe we just |
| declare that Go 1.20 _is_ Go 2.0. Either way, at that point we will |
| transition from working on the Go 1.X release sequence to working on |
| the Go 2.X sequence, perhaps with an extended support window for the |
| final Go 1.X release. |
| |
| This is all a bit speculative, and the specific release numbers |
| I just mentioned are placeholders for ballpark estimates, |
| but I want to make clear that we're not |
| abandoning Go 1, and that in fact we will bring Go 1 along to the |
| greatest extent possible. |
| |
| ## Help Wanted |
| |
| **We need your help.** |
| |
| The conversation for Go 2 starts today, and it's one that will happen |
| in the open, in public forums like the mailing list and the issue |
| tracker. Please help us at every step along the way. |
| |
| Today, what we need most is experience reports. Please tell us how Go |
| is working for you, and more importantly not working for you. Write a |
| blog post, include real examples, concrete detail, and real |
| experience. And link it on our [wiki page](https://golang.org/wiki/ExperienceReports). |
| That's how we'll start talking about what we, the Go community, |
| might want to change about Go. |
| |
| Thank you. |