A proposal discussion in mid-2020 on #37196 decided to change time.Timer and time.Ticker so that their Stop and Reset methods guarantee that no old value (corresponding to the previous configuration of the Timer or Ticker) will be received after the method returns. The trivial way to do this is to make the Timer/Ticker channels unbuffered, create a goroutine per Timer/Ticker feeding the channel, and then coordinate with that goroutine during Stop/Reset. Since Stop/Reset coordinate with the goroutine and the channel is unbuffered, there is no possibility of a stale value being sent after Stop/Reset returns. Of course, we do not want an extra goroutine per Timer/Ticker, but that's still a good semantic model: behave like the channels are unbuffered and fed by a coordinating goroutine. The actual implementation is more effort but behaves like the model. Specifically, the timer channel has a 1-element buffer like it always has, but len(t.C) and cap(t.C) are special-cased to return 0 anyway, so user code cannot see what's in the buffer except with a receive. Stop/Reset lock out any stale sends and then clear any pending send from the buffer. Some programs will change behavior. For example: package main import "time" func main() { t := time.NewTimer(2 * time.Second) time.Sleep(3 * time.Second) if t.Reset(2*time.Second) != false { panic("expected timer to have fired") } <-t.C <-t.C } This program (from #11513) sleeps 3s after setting a 2s timer, resets the timer, and expects Reset to return false: the Reset is too late and the send has already occurred. It then expects to receive two values: the one from before the Reset, and the one from after the Reset. With an unbuffered timer channel, it should be clear that no value can be sent during the time.Sleep, so the time.Reset returns true, indicating that the Reset stopped the timer from going off. Then there is only one value to receive from t.C: the one from after the Reset. In 2015, I used the above example as an argument against this change. Note that a correct version of the program would be: func main() { t := time.NewTimer(2 * time.Second) time.Sleep(3 * time.Second) if !t.Reset(2*time.Second) { <-t.C } <-t.C } This works with either semantics, by heeding t.Reset's result. The change should not affect correct programs. However, one way that the change would be visible is when programs use len(t.C) (instead of a non-blocking receive) to poll whether the timer has triggered already. We might legitimately worry about breaking such programs. In 2020, discussing #37196, Bryan Mills and I surveyed programs using len on timer channels. These are exceedingly rare to start with; nearly all the uses are buggy; and all the buggy programs would be fixed by the new semantics. The details are at [1]. To further reduce the impact of this change, this CL adds a temporary GODEBUG setting, which we didn't know about yet in 2015 and 2020. Specifically, asynctimerchan=1 disables the change and is the default for main programs in modules that use a Go version before 1.23. We hope to be able to retire this setting after the minimum 2-year window. Setting asynctimerchan=1 also disables the garbage collection change from CL 568341, although users shouldn't need to know that since it is not a semantically visible change (unless we have bugs!). As an undocumented bonus that we do not officially support, asynctimerchan=2 disables the channel buffer change but keeps the garbage collection change. This may help while we are shaking out bugs in either of them. Fixes #37196. [1] https://github.com/golang/go/issues/37196#issuecomment-641698749 Change-Id: I8925d3fb2b86b2ae87fd2acd055011cbf7bd5916 Reviewed-on: https://go-review.googlesource.com/c/go/+/568341 Reviewed-by: Austin Clements <austin@google.com> Auto-Submit: Russ Cox <rsc@golang.org> LUCI-TryBot-Result: Go LUCI <golang-scoped@luci-project-accounts.iam.gserviceaccount.com>
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Go, Backwards Compatibility, and GODEBUG | article |
Introduction
Go's emphasis on backwards compatibility is one of its key strengths. There are, however, times when we cannot maintain complete compatibility. If code depends on buggy (including insecure) behavior, then fixing the bug will break that code. New features can also have similar impacts: enabling the HTTP/2 use by the HTTP client broke programs connecting to servers with buggy HTTP/2 implementations. These kinds of changes are unavoidable and permitted by the Go 1 compatibility rules. Even so, Go provides a mechanism called GODEBUG to reduce the impact such changes have on Go developers using newer toolchains to compile old code.
A GODEBUG setting is a key=value
pair
that controls the execution of certain parts of a Go program.
The environment variable GODEBUG
can hold a comma-separated list of these settings.
For example, if a Go program is running in an environment that contains
GODEBUG=http2client=0,http2server=0
then that Go program will disable the use of HTTP/2 by default in both
the HTTP client and the HTTP server.
It is also possible to set the default GODEBUG
for a given program
(discussed below).
When preparing any change that is permitted by Go 1 compatibility but may nonetheless break some existing programs, we first engineer the change to keep as many existing programs working as possible. For the remaining programs, we define a new GODEBUG setting that allows individual programs to opt back in to the old behavior. A GODEBUG setting may not be added if doing so is infeasible, but that should be extremely rare.
GODEBUG settings added for compatibility will be maintained
for a minimum of two years (four Go releases).
Some, such as http2client
and http2server
,
will be maintained much longer, even indefinitely.
When possible, each GODEBUG setting has an associated
runtime/metrics counter
named /godebug/non-default-behavior/<name>:events
that counts the number of times a particular program's
behavior has changed based on a non-default value
for that setting.
For example, when GODEBUG=http2client=0
is set,
/godebug/non-default-behavior/http2client:events
counts the number of HTTP transports that the program
has configured without HTTP/2 support.
Default GODEBUG Values
When a GODEBUG setting is not listed in the environment variable,
its value is derived from three sources:
the defaults for the Go toolchain used to build the program,
amended to match the Go version listed in go.mod
,
and then overridden by explicit //go:debug
lines in the program.
The GODEBUG History gives the exact defaults for each Go toolchain version.
For example, Go 1.21 introduces the panicnil
setting,
controlling whether panic(nil)
is allowed;
it defaults to panicnil=0
, making panic(nil)
a run-time error.
Using panicnil=1
restores the behavior of Go 1.20 and earlier.
When compiling a work module or workspace that declares
an older Go version, the Go toolchain amends its defaults
to match that older Go version as closely as possible.
For example, when a Go 1.21 toolchain compiles a program,
if the work module's go.mod
or the workspace's go.work
says go
1.20
, then the program defaults to panicnil=1
,
matching Go 1.20 instead of Go 1.21.
Because this method of setting GODEBUG defaults was introduced only in Go 1.21, programs listing versions of Go earlier than Go 1.20 are configured to match Go 1.20, not the older version.
To override these defaults, a main package's source files
can include one or more //go:debug
directives at the top of the file
(preceding the package
statement).
Continuing the panicnil
example, if the module or workspace is updated
to say go
1.21
, the program can opt back into the old panic(nil)
behavior by including this directive:
//go:debug panicnil=1
Starting in Go 1.21, the Go toolchain treats a //go:debug
directive
with an unrecognized GODEBUG setting as an invalid program.
Programs with more than one //go:debug
line for a given setting
are also treated as invalid.
(Older toolchains ignore //go:debug
directives entirely.)
The defaults that will be compiled into a main package are reported by the command:
{{raw go list -f '{{.DefaultGODEBUG}}' my/main/package
}}
Only differences from the base Go toolchain defaults are reported.
When testing a package, //go:debug
lines in the *_test.go
files are treated as directives for the test's main package.
In any other context, //go:debug
lines are ignored by the toolchain;
go
vet
reports such lines as misplaced.
GODEBUG History
This section documents the GODEBUG settings introduced and removed in each major Go release for compatibility reasons. Packages or programs may define additional settings for internal debugging purposes; for example, see the runtime documentation and the go command documentation.
Go 1.23
Go 1.23 changed the channels created by package time to be unbuffered
(synchronous), which makes correct use of the Timer.Stop
and Timer.Reset
method results much easier.
The asynctimerchan
setting disables this change.
There are no runtime metrics for this change,
This setting may be removed in a future release, Go 1.27 at the earliest.
Go 1.23 changed the mode bits reported by os.Lstat
and os.Stat
for reparse points, which can be controlled with the winsymlink
setting.
As of Go 1.23 (winsymlink=1
), mount points no longer have os.ModeSymlink
set, and reparse points that are not symlinks, Unix sockets, or dedup files now
always have os.ModeIrregular
set. As a result of these changes,
filepath.EvalSymlinks
no longer evaluates
mount points, which was a source of many inconsistencies and bugs.
At previous versions (winsymlink=0
), mount points are treated as symlinks,
and other reparse points with non-default os.ModeType
bits
(such as os.ModeDir
) do not have the ModeIrregular
bit set.
Go 1.23 changed os.Readlink
and filepath.EvalSymlinks
to avoid trying to normalize volumes to drive letters, which was not always even possible.
This behavior is controlled by the winreadlinkvolume
setting.
For Go 1.23, it defaults to winreadlinkvolume=1
.
Previous versions default to winreadlinkvolume=0
.
Go 1.22
Go 1.22 adds a configurable limit to control the maximum acceptable RSA key size
that can be used in TLS handshakes, controlled by the tlsmaxrsasize
setting.
The default is tlsmaxrsasize=8192, limiting RSA to 8192-bit keys. To avoid
denial of service attacks, this setting and default was backported to Go
1.19.13, Go 1.20.8, and Go 1.21.1.
Go 1.22 made it an error for a request or response read by a net/http
client or server to have an empty Content-Length header.
This behavior is controlled by the httplaxcontentlength
setting.
Go 1.22 changed the behavior of ServeMux to accept extended
patterns and unescape both patterns and request paths by segment.
This behavior can be controlled by the
httpmuxgo121
setting.
Go 1.22 added the Alias type to go/types
for the explicit representation of type aliases.
Whether the type checker produces Alias
types or not is controlled by the
gotypesalias
setting.
For Go 1.22 it defaults to gotypesalias=0
.
For Go 1.23, gotypesalias=1
will become the default.
This setting will be removed in a future release, Go 1.24 at the earliest.
Go 1.22 changed the default minimum TLS version supported by both servers
and clients to TLS 1.2. The default can be reverted to TLS 1.0 using the
tls10server
setting.
Go 1.22 changed the default TLS cipher suites used by clients and servers when
not explicitly configured, removing the cipher suites which used RSA based key
exchange. The default can be revert using the tlsrsakex
setting.
Go 1.22 disabled
ConnectionState.ExportKeyingMaterial
when the connection supports neither TLS 1.3 nor Extended Master Secret
(implemented in Go 1.21). It can be reenabled with the tlsunsafeekm
setting.
Go 1.22 changed how the runtime interacts with transparent huge pages on Linux.
In particular, a common default Linux kernel configuration can result in
significant memory overheads, and Go 1.22 no longer works around this default.
To work around this issue without adjusting kernel settings, transparent huge
pages can be disabled for Go memory with the
disablethp
setting.
This behavior was backported to Go 1.21.1, but the setting is only available
starting with Go 1.21.6.
This setting may be removed in a future release, and users impacted by this issue
should adjust their Linux configuration according to the recommendations in the
GC guide, or switch to a Linux
distribution that disables transparent huge pages altogether.
Go 1.22 added contention on runtime-internal locks to the mutex
profile. Contention on these locks is always
reported at runtime._LostContendedRuntimeLock
. Complete stack traces of
runtime locks can be enabled with the runtimecontentionstacks
setting. These stack traces have
non-standard semantics, see setting documentation for details.
Go 1.22 added a new crypto/x509.Certificate
field, Policies
, which supports
certificate policy OIDs with components larger than 31 bits. By default this
field is only used during parsing, when it is populated with policy OIDs, but
not used during marshaling. It can be used to marshal these larger OIDs, instead
of the existing PolicyIdentifiers field, by using the
x509usepolicies
setting..
Go 1.21
Go 1.21 made it a run-time error to call panic
with a nil interface value,
controlled by the panicnil
setting.
Go 1.21 made it an error for html/template actions to appear inside of an ECMAScript 6
template literal, controlled by the
jstmpllitinterp
setting.
This behavior was backported to Go 1.19.8+ and Go 1.20.3+.
Go 1.21 introduced a limit on the maximum number of MIME headers and multipart
forms, controlled by the
multipartmaxheaders
and multipartmaxparts
settings
respectively.
This behavior was backported to Go 1.19.8+ and Go 1.20.3+.
Go 1.21 adds the support of Multipath TCP but it is only used if the application
explicitly asked for it. This behavior can be controlled by the
multipathtcp
setting.
There is no plan to remove any of these settings.
Go 1.20
Go 1.20 introduced support for rejecting insecure paths in tar and zip archives,
controlled by the tarinsecurepath
setting
and the zipinsecurepath
setting.
These default to tarinsecurepath=1
and zipinsecurepath=1
,
preserving the behavior of earlier versions of Go.
A future version of Go may change the defaults to
tarinsecurepath=0
and zipinsecurepath=0
.
Go 1.20 introduced automatic seeding of the
math/rand
global random number generator,
controlled by the randautoseed
setting.
Go 1.20 introduced the concept of fallback roots for use during certificate verification,
controlled by the x509usefallbackroots
setting.
Go 1.20 removed the preinstalled .a
files for the standard library
from the Go distribution.
Installations now build and cache the standard library like
packages in other modules.
The installgoroot
setting
restores the installation and use of preinstalled .a
files.
There is no plan to remove any of these settings.
Go 1.19
Go 1.19 made it an error for path lookups to resolve to binaries in the current directory,
controlled by the execerrdot
setting.
There is no plan to remove this setting.
Go 1.18
Go 1.18 removed support for SHA1 in most X.509 certificates,
controlled by the x509sha1
setting.
This setting will be removed in a future release, Go 1.22 at the earliest.
Go 1.10
Go 1.10 changed how build caching worked and added test caching, along
with the gocacheverify
, gocachehash
, and gocachetest
settings.
There is no plan to remove these settings.
Go 1.6
Go 1.6 introduced transparent support for HTTP/2,
controlled by the http2client
, http2server
, and http2debug
settings.
There is no plan to remove these settings.
Go 1.5
Go 1.5 introduced a pure Go DNS resolver,
controlled by the netdns
setting.
There is no plan to remove this setting.