Since the release of Go version 1.1 in April, 2013, the release schedule has been shortened to make the release process more efficient. This release, Go version 1.2 or Go 1.2 for short, arrives roughly six months after 1.1, while 1.1 took over a year to appear after 1.0. Because of the shorter time scale, 1.2 is a smaller delta than the step from 1.0 to 1.1, but it still has some significant developments, including a better scheduler and one new language feature. Of course, Go 1.2 keeps the promise of compatibility. The overwhelming majority of programs built with Go 1.1 (or 1.0 for that matter) will run without any changes whatsoever when moved to 1.2, although the introduction of one restriction to a corner of the language may expose already-incorrect code (see the discussion of the use of nil).
In the interest of firming up the specification, one corner case has been clarified, with consequences for programs. There is also one new language feature.
The language now specifies that, for safety reasons, certain uses of nil pointers are guaranteed to trigger a run-time panic. For instance, in Go 1.0, given code like
type T struct { X [1<<24]byte Field int32 } func main() { var x *T ... }
the nil
pointer x
could be used to access memory incorrectly:
the expression x.Field
could access memory at address 1<<24
.
To prevent such unsafe behavior, in Go 1.2 the compilers now guarantee that any indirection through
a nil pointer, such as illustrated here but also in nil pointers to arrays, nil interface values,
nil slices, and so on, will either panic or return a correct, safe non-nil value.
In short, any expression that explicitly or implicitly requires evaluation of a nil address is an error.
The implementation may inject extra tests into the compiled program to enforce this behavior.
Further details are in the design document.
Updating: Most code that depended on the old behavior is erroneous and will fail when run. Such programs will need to be updated by hand.
Go 1.2 adds the ability to specify the capacity as well as the length when using a slicing operation on an existing array or slice. A slicing operation creates a new slice by describing a contiguous section of an already-created array or slice:
var array [10]int slice := array[2:4]
The capacity of the slice is the maximum number of elements that the slice may hold, even after reslicing;
it reflects the size of the underlying array.
In this example, the capacity of the slice
variable is 8.
Go 1.2 adds new syntax to allow a slicing operation to specify the capacity as well as the length. A second colon introduces the capacity value, which must be less than or equal to the capacity of the source slice or array, adjusted for the origin. For instance,
slice = array[2:4:7]
sets the slice to have the same length as in the earlier example but its capacity is now only 5 elements (7-2). It is impossible to use this new slice value to access the last three elements of the original array.
In this three-index notation, a missing first index ([:i:j]
) defaults to zero but the other
two indices must always be specified explicitly.
It is possible that future releases of Go may introduce default values for these indices.
Further details are in the design document.
Updating: This is a backwards-compatible change that affects no existing programs.
In prior releases, a goroutine that was looping forever could starve out other goroutines on the same thread, a serious problem when GOMAXPROCS provided only one user thread. In Go 1.2, this is partially addressed: The scheduler is invoked occasionally upon entry to a function. This means that any loop that includes a (non-inlined) function call can be pre-empted, allowing other goroutines to run on the same thread.
Go 1.2 introduces a configurable limit (default 10,000) to the total number of threads a single program may have in its address space, to avoid resource starvation issues in some environments. Note that goroutines are multiplexed onto threads so this limit does not directly limit the number of goroutines, only the number that may be simultaneously blocked in a system call. In practice, the limit is hard to reach.
The new SetMaxThreads
function in the
runtime/debug
package controls the thread count limit.
Updating:
Few functions will be affected by the limit, but if a program dies because it hits the
limit, it could be modified to call SetMaxThreads
to set a higher count.
Even better would be to refactor the program to need fewer threads, reducing consumption
of kernel resources.
In Go 1.2, the minimum size of the stack when a goroutine is created has been lifted from 4KB to 8KB. Many programs were suffering performance problems with the old size, which had a tendency to introduce expensive stack-segment switching in performance-critical sections. The new number was determined by empirical testing.
At the other end, the new function SetMaxStack
in the runtime/debug
package controls
the maximum size of a single goroutine's stack.
The default is 1GB on 64-bit systems and 250MB on 32-bit systems.
Before Go 1.2, it was too easy for a runaway recursion to consume all the memory on a machine.
Updating: The increased minimum stack size may cause programs with many goroutines to use more memory. There is no workaround, but plans for future releases include new stack management technology that should address the problem better.
The cgo
command will now invoke the C++
compiler to build any pieces of the linked-to library that are written in C++;
the documentation has more detail.
Both binaries are still included with the distribution, but the source code for the godoc and vet commands has moved to the go.tools subrepository.
Also, the core of the godoc program has been split into a library, while the command itself is in a separate directory. The move allows the code to be updated easily and the separation into a library and command makes it easier to construct custom binaries for local sites and different deployment methods.
Updating: Since godoc and vet are not part of the library, no client Go code depends on the their source and no updating is required.
The binary distributions available from golang.org include these binaries, so users of these distributions are unaffected.
When building from source, users must use "go get" to install godoc and vet.
(The binaries will continue to be installed in their usual locations, not
$GOPATH/bin
.)
$ go get code.google.com/p/go.tools/cmd/godoc $ go get code.google.com/p/go.tools/cmd/vet
We expect the future GCC 4.9 release to include gccgo with full support for Go 1.2. In the current (4.8.2) release of GCC, gccgo implements Go 1.1.2.
Go 1.2 has several semantic changes to the workings of the gc compiler suite. Most users will be unaffected by them.
The cgo
command now
works when C++ is included in the library being linked against.
See the cgo
documentation
for details.
The gc compiler displayed a vestigial detail of its origins when
a program had no package
clause: it assumed
the file was in package main
.
The past has been erased, and a missing package
clause
is now an error.
On the ARM, the toolchain supports "external linking", which is a step towards being able to build shared libraries with the gc toolchain and to provide dynamic linking support for environments in which that is necessary.
In the runtime for the ARM, with 5a
, it used to be possible to refer
to the runtime-internal m
(machine) and g
(goroutine) variables using R9
and R10
directly.
It is now necessary to refer to them by their proper names.
Also on the ARM, the 5l
linker (sic) now defines the
MOVBS
and MOVHS
instructions
as synonyms of MOVB
and MOVH
,
to make clearer the separation between signed and unsigned
sub-word moves; the unsigned versions already existed with a
U
suffix.
One major new feature of go test
is
that it can now compute and, with help from a new, separately installed
"go tool cover" program, display test coverage results.
The cover tool is part of the
go.tools
subrepository.
It can be installed by running
$ go get code.google.com/p/go.tools/cmd/cover
The cover tool does two things.
First, when "go test" is given the -cover
flag, it is run automatically
to rewrite the source for the package and insert instrumentation statements.
The test is then compiled and run as usual, and basic coverage statistics are reported:
$ go test -cover fmt ok fmt 0.060s coverage: 91.4% of statements $
Second, for more detailed reports, different flags to "go test" can create a coverage profile file, which the cover program, invoked with "go tool cover", can then analyze.
Details on how to generate and analyze coverage statistics can be found by running the commands
$ go help testflag $ go tool cover -help
The "go doc" command is deleted.
Note that the godoc
tool itself is not deleted,
just the wrapping of it by the go
command.
All it did was show the documents for a package by package path,
which godoc itself already does with more flexibility.
It has therefore been deleted to reduce the number of documentation tools and,
as part of the restructuring of godoc, encourage better options in future.
Updating: For those who still need the precise functionality of running
$ go doc
in a directory, the behavior is identical to running
$ godoc .
The go get
command
now has a -t
flag that causes it to download the dependencies
of the tests run by the package, not just those of the package itself.
By default, as before, dependencies of the tests are not downloaded.
There are a number of significant performance improvements in the standard library; here are a few of them.
compress/bzip2
decompresses about 30% faster.
crypto/des
package
is about five times faster.
encoding/json
package
encodes about 30% faster.
The
archive/tar
and
archive/zip
packages have had a change to their semantics that may break existing programs.
The issue is that they both provided an implementation of the
os.FileInfo
interface that was not compliant with the specification for that interface.
In particular, their Name
method returned the full
path name of the entry, but the interface specification requires that
the method return only the base name (final path element).
Updating: Since this behavior was newly implemented and a bit obscure, it is possible that no code depends on the broken behavior. If there are programs that do depend on it, they will need to be identified and fixed manually.
There is a new package, encoding
,
that defines a set of standard encoding interfaces that may be used to
build custom marshalers and unmarshalers for packages such as
encoding/xml
,
encoding/json
,
and
encoding/binary
.
These new interfaces have been used to tidy up some implementations in
the standard library.
The new interfaces are called
BinaryMarshaler
,
BinaryUnmarshaler
,
TextMarshaler
,
and
TextUnmarshaler
.
Full details are in the documentation for the package
and a separate design document.
The fmt
package's formatted print
routines such as Printf
now allow the data items to be printed to be accessed in arbitrary order
by using an indexing operation in the formatting specifications.
Wherever an argument is to be fetched from the argument list for formatting,
either as the value to be formatted or as a width or specification integer,
a new optional indexing notation [
n]
fetches argument n instead.
The value of n is 1-indexed.
After such an indexing operating, the next argument to be fetched by normal
processing will be n+1.
For example, the normal Printf
call
fmt.Sprintf("%c %c %c\n", 'a', 'b', 'c')
would create the string "a b c"
, but with indexing operations like this,
fmt.Sprintf("%[3]c %[1]c %c\n", 'a', 'b', 'c')
the result is ""c a b"
. The [3]
index accesses the third formatting
argument, which is 'c'
, [1]
accesses the first, 'a'
,
and then the next fetch accesses the argument following that one, 'b'
.
The motivation for this feature is programmable format statements to access the arguments in different order for localization, but it has other uses:
log.Printf("trace: value %v of type %[1]T\n", expensiveFunction(a.b[c]))
Updating: The change to the syntax of format specifications is strictly backwards compatible, so it affects no working programs.
The
text/template
package
has a couple of changes in Go 1.2, both of which are also mirrored in the
html/template
package.
First, there are new default functions for comparing basic types. The functions are listed in this table, which shows their names and the associated familiar comparison operator.
Name | Operator | |
---|---|---|
eq | == |
|
ne | != |
|
lt | < |
|
le | <= |
|
gt | > |
|
ge | >= |
These functions behave slightly differently from the corresponding Go operators.
First, they operate only on basic types (bool
, int
,
float64
, string
, etc.).
(Go allows comparison of arrays and structs as well, under some circumstances.)
Second, values can be compared as long as they are the same sort of value:
any signed integer value can be compared to any other signed integer value for example. (Go
does not permit comparing an int8
and an int16
).
Finally, the eq
function (only) allows comparison of the first
argument with one or more following arguments. The template in this example,
{{"{{"}}if eq .A 1 2 3 {{"}}"}} equal {{"{{"}}else{{"}}"}} not equal {{"{{"}}end{{"}}"}}
reports "equal" if .A
is equal to any of 1, 2, or 3.
The second change is that a small addition to the grammar makes "if else if" chains easier to write. Instead of writing,
{{"{{"}}if eq .A 1{{"}}"}} X {{"{{"}}else{{"}}"}} {{"{{"}}if eq .A 2{{"}}"}} Y {{"{{"}}end{{"}}"}} {{"{{"}}end{{"}}"}}
one can fold the second "if" into the "else" and have only one "end", like this:
{{"{{"}}if eq .A 1{{"}}"}} X {{"{{"}}else if eq .A 2{{"}}"}} Y {{"{{"}}end{{"}}"}}
The two forms are identical in effect; the difference is just in the syntax.
Updating: Neither the "else if" change nor the comparison functions
affect existing programs. Those that
already define functions called eq
and so on through a function
map are unaffected because the associated function map will override the new
default function definitions.
There are two new packages.
encoding
package is
described above.
image/color/palette
package
provides standard color palettes.
The following list summarizes a number of minor changes to the library, mostly additions. See the relevant package documentation for more information about each change.
archive/zip
package
adds the
DataOffset
accessor
to return the offset of a file's (possibly compressed) data within the archive.
bufio
package
adds Reset
methods to Reader
and
Writer
.
These methods allow the Readers
and Writers
to be re-used on new input and output readers and writers, saving
allocation overhead.
compress/bzip2
can now decompress concatenated archives.
compress/flate
package adds a Reset
method on the Writer
,
to make it possible to reduce allocation when, for instance, constructing an
archive to hold multiple compressed files.
compress/gzip
package's
Writer
type adds a
Reset
so it may be reused.
compress/zlib
package's
Writer
type adds a
Reset
so it may be reused.
container/heap
package
adds a Fix
method to provide a more efficient way to update an item's position in the heap.
container/list
package
adds the MoveBefore
and
MoveAfter
methods, which implement the obvious rearrangement.
crypto/cipher
package
adds the a new GCM mode (Galois Counter Mode), which is almost always
used with AES encryption.
crypto/md5
package
adds a new Sum
function
to simplify hashing without sacrificing performance.
crypto/sha1
package
adds a new Sum
function.
crypto/sha256
package
adds Sum256
and Sum224
functions.
crypto/sha512
package
adds Sum512
and
Sum384
functions.
crypto/x509
package
adds support for reading and writing arbitrary extensions.
crypto/tls
package adds
support for TLS 1.1, 1.2 and AES-GCM.
database/sql
package adds a
SetMaxOpenConns
method on DB
to limit the
number of open connections to the database.
encoding/csv
package
now always allows trailing commas on fields.
encoding/gob
package
now treats channel and function fields of structures as if they were unexported,
even if they are not. That is, it ignores them completely. Previously they would
trigger an error, which could cause unexpected compatibility problems if an
embedded structure added such a field.
The package also now supports the generic BinaryMarshaler
and
BinaryUnmarshaler
interfaces of the
encoding
package
described above.
encoding/json
package
now will always escape ampersands as "\u0026" when printing strings.
It will now accept but correct invalid UTF-8 in
Marshal
(such input was previously rejected).
Finally, it now supports the generic encoding interfaces of the
encoding
package
described above.
encoding/xml
package
now allows attributes stored in pointers to be marshaled.
It also supports the generic encoding interfaces of the
encoding
package
described above through the new
Marshaler
,
Unmarshaler
,
and related
MarshalerAttr
and
UnmarshalerAttr
interfaces.
The package also adds a
Flush
method
to the
Encoder
type for use by custom encoders. See the documentation for
EncodeToken
to see how to use it.
flag
package now
has a Getter
interface
to allow the value of a flag to be retrieved. Due to the
Go 1 compatibility guidelines, this method cannot be added to the existing
Value
interface, but all the existing standard flag types implement it.
The package also now exports the CommandLine
flag set, which holds the flags from the command line.
go/ast
package's
SliceExpr
struct
has a new boolean field, Slice3
, which is set to true
when representing a slice expression with three indices (two colons).
The default is false, representing the usual two-index form.
go/build
package adds
the AllTags
field
to the Package
type,
to make it easier to process build tags.
image/draw
package now
exports an interface, Drawer
,
that wraps the standard Draw
method.
The Porter-Duff operators now implement this interface, in effect binding an operation to
the draw operator rather than providing it explicitly.
Given a paletted image as its destination, the new
FloydSteinberg
implementation of the
Drawer
interface will use the Floyd-Steinberg error diffusion algorithm to draw the image.
To create palettes suitable for such processing, the new
Quantizer
interface
represents implementations of quantization algorithms that choose a palette
given a full-color image.
There are no implementations of this interface in the library.
image/gif
package
can now create GIF files using the new
Encode
and EncodeAll
functions.
Their options argument allows specification of an image
Quantizer
to use;
if it is nil
, the generated GIF will use the
Plan9
color map (palette) defined in the new
image/color/palette
package.
The options also specify a
Drawer
to use to create the output image;
if it is nil
, Floyd-Steinberg error diffusion is used.
Copy
method of the
io
package now prioritizes its
arguments differently.
If one argument implements WriterTo
and the other implements ReaderFrom
,
Copy
will now invoke
WriterTo
to do the work,
so that less intermediate buffering is required in general.
net
package requires cgo by default
because the host operating system must in general mediate network call setup.
On some systems, though, it is possible to use the network without cgo, and useful
to do so, for instance to avoid dynamic linking.
The new build tag netgo
(off by default) allows the construction of a
net
package in pure Go on those systems where it is possible.
net
package adds a new field
DualStack
to the Dialer
struct for TCP connection setup using a dual IP stack as described in
RFC 6555.
net/http
package will no longer
transmit cookies that are incorrect according to
RFC 6265.
It just logs an error and sends nothing.
Also,
the net/http
package's
ReadResponse
function now permits the *Request
parameter to be nil
,
whereupon it assumes a GET request.
Finally, an HTTP server will now serve HEAD
requests transparently, without the need for special casing in handler code.
While serving a HEAD request, writes to a
Handler
's
ResponseWriter
are absorbed by the
Server
and the client receives an empty body as required by the HTTP specification.
os/exec
package's
Cmd.StdinPipe
method
returns an io.WriteCloser
, but has changed its concrete
implementation from *os.File
to an unexported type that embeds
*os.File
, and it is now safe to close the returned value.
Before Go 1.2, there was an unavoidable race that this change fixes.
Code that needs access to the methods of *os.File
can use an
interface type assertion, such as wc.(interface{ Sync() error })
.
runtime
package relaxes
the constraints on finalizer functions in
SetFinalizer
: the
actual argument can now be any type that is assignable to the formal type of
the function, as is the case for any normal function call in Go.
sort
package has a new
Stable
function that implements
stable sorting. It is less efficient than the normal sort algorithm, however.
strings
package adds
an IndexByte
function for consistency with the bytes
package.
sync/atomic
package
adds a new set of swap functions that atomically exchange the argument with the
value stored in the pointer, returning the old value.
The functions are
SwapInt32
,
SwapInt64
,
SwapUint32
,
SwapUint64
,
SwapUintptr
,
and
SwapPointer
,
which swaps an unsafe.Pointer
.
syscall
package now implements
Sendfile
for Darwin.
testing
package
now exports the TB
interface.
It records the methods in common with the
T
and
B
types,
to make it easier to share code between tests and benchmarks.
Also, the
AllocsPerRun
function now quantizes the return value to an integer (although it
still has type float64
), to round off any error caused by
initialization and make the result more repeatable.
text/template
package
now automatically dereferences pointer values when evaluating the arguments
to "escape" functions such as "html", to bring the behavior of such functions
in agreement with that of other printing functions such as "printf".
time
package, the
Parse
function
and
Format
method
now handle time zone offsets with seconds, such as in the historical
date "1871-01-01T05:33:02+00:34:08".
Also, pattern matching in the formats for those routines is stricter: a non-lowercase letter
must now follow the standard words such as "Jan" and "Mon".
unicode
package
adds In
,
a nicer-to-use but equivalent version of the original
IsOneOf
,
to see whether a character is a member of a Unicode category.