Go is a new language. Although it borrows ideas from existing languages, it has unusual properties that make effective Go programs different in character from programs written in its relatives. A straightforward translation of a C++ or Java program into Go is unlikely to produce a satisfactory result—Java programs are written in Java, not Go. On the other hand, thinking about the problem from a Go perspective could produce a successful but quite different program. In other words, to write Go well, it's important to understand its properties and idioms. It's also important to know the established conventions for programming in Go, such as naming, formatting, program construction, and so on, so that programs you write will be easy for other Go programmers to understand.
This document gives tips for writing clear, idiomatic Go code. It augments the language specification, the Tour of Go, and How to Write Go Code, all of which you should read first.
The Go package sources are intended to serve not only as the core library but also as examples of how to use the language. Moreover, many of the packages contain working, self-contained executable examples you can run directly from the golang.org web site, such as this one (if necessary, click on the word "Example" to open it up). If you have a question about how to approach a problem or how something might be implemented, the documentation, code and examples in the library can provide answers, ideas and background.
Formatting issues are the most contentious but the least consequential. People can adapt to different formatting styles but it's better if they don't have to, and less time is devoted to the topic if everyone adheres to the same style. The problem is how to approach this Utopia without a long prescriptive style guide.
With Go we take an unusual
approach and let the machine
take care of most formatting issues.
The gofmt
program
(also available as go fmt
, which
operates at the package level rather than source file level)
reads a Go program
and emits the source in a standard style of indentation
and vertical alignment, retaining and if necessary
reformatting comments.
If you want to know how to handle some new layout
situation, run gofmt
; if the answer doesn't
seem right, rearrange your program (or file a bug about gofmt
),
don't work around it.
As an example, there's no need to spend time lining up
the comments on the fields of a structure.
Gofmt
will do that for you. Given the
declaration
type T struct { name string // name of the object value int // its value }
gofmt
will line up the columns:
type T struct { name string // name of the object value int // its value }
All Go code in the standard packages has been formatted with gofmt
.
Some formatting details remain. Very briefly:
gofmt
emits them by default.
Use spaces only if you must.
if
,
for
, switch
) do not have parentheses in
their syntax.
Also, the operator precedence hierarchy is shorter and clearer, so
x<<8 + y<<16means what the spacing implies, unlike in the other languages.
Go provides C-style /* */
block comments
and C++-style //
line comments.
Line comments are the norm;
block comments appear mostly as package comments, but
are useful within an expression or to disable large swaths of code.
The program—and web server—godoc
processes
Go source files to extract documentation about the contents of the
package.
Comments that appear before top-level declarations, with no intervening newlines,
are extracted along with the declaration to serve as explanatory text for the item.
The nature and style of these comments determines the
quality of the documentation godoc
produces.
Every package should have a package comment, a block
comment preceding the package clause.
For multi-file packages, the package comment only needs to be
present in one file, and any one will do.
The package comment should introduce the package and
provide information relevant to the package as a whole.
It will appear first on the godoc
page and
should set up the detailed documentation that follows.
/* Package regexp implements a simple library for regular expressions. The syntax of the regular expressions accepted is: regexp: concatenation { '|' concatenation } concatenation: { closure } closure: term [ '*' | '+' | '?' ] term: '^' '$' '.' character '[' [ '^' ] character-ranges ']' '(' regexp ')' */ package regexp
If the package is simple, the package comment can be brief.
// Package path implements utility routines for // manipulating slash-separated filename paths.
Comments do not need extra formatting such as banners of stars.
The generated output may not even be presented in a fixed-width font, so don't depend
on spacing for alignment—godoc
, like gofmt
,
takes care of that.
The comments are uninterpreted plain text, so HTML and other
annotations such as _this_
will reproduce verbatim and should
not be used.
One adjustment godoc
does do is to display indented
text in a fixed-width font, suitable for program snippets.
The package comment for the
fmt
package uses this to good effect.
Depending on the context, godoc
might not even
reformat comments, so make sure they look good straight up:
use correct spelling, punctuation, and sentence structure,
fold long lines, and so on.
Inside a package, any comment immediately preceding a top-level declaration serves as a doc comment for that declaration. Every exported (capitalized) name in a program should have a doc comment.
Doc comments work best as complete sentences, which allow a wide variety of automated presentations. The first sentence should be a one-sentence summary that starts with the name being declared.
// Compile parses a regular expression and returns, if successful, // a Regexp that can be used to match against text. func Compile(str string) (*Regexp, error) {
If every doc comment begins with the name of the item it describes,
you can use the doc
subcommand of the go tool
and run the output through grep
.
Imagine you couldn't remember the name "Compile" but were looking for
the parsing function for regular expressions, so you ran
the command,
$ go doc -all regexp | grep -i parse
If all the doc comments in the package began, "This function...", grep
wouldn't help you remember the name. But because the package starts each
doc comment with the name, you'd see something like this,
which recalls the word you're looking for.
$ go doc -all regexp | grep -i parse Compile parses a regular expression and returns, if successful, a Regexp MustCompile is like Compile but panics if the expression cannot be parsed. parsed. It simplifies safe initialization of global variables holding $
Go's declaration syntax allows grouping of declarations. A single doc comment can introduce a group of related constants or variables. Since the whole declaration is presented, such a comment can often be perfunctory.
// Error codes returned by failures to parse an expression. var ( ErrInternal = errors.New("regexp: internal error") ErrUnmatchedLpar = errors.New("regexp: unmatched '('") ErrUnmatchedRpar = errors.New("regexp: unmatched ')'") ... )
Grouping can also indicate relationships between items, such as the fact that a set of variables is protected by a mutex.
var ( countLock sync.Mutex inputCount uint32 outputCount uint32 errorCount uint32 )
Names are as important in Go as in any other language. They even have semantic effect: the visibility of a name outside a package is determined by whether its first character is upper case. It's therefore worth spending a little time talking about naming conventions in Go programs.
When a package is imported, the package name becomes an accessor for the contents. After
import "bytes"
the importing package can talk about bytes.Buffer
. It's
helpful if everyone using the package can use the same name to refer to
its contents, which implies that the package name should be good:
short, concise, evocative. By convention, packages are given
lower case, single-word names; there should be no need for underscores
or mixedCaps.
Err on the side of brevity, since everyone using your
package will be typing that name.
And don't worry about collisions a priori.
The package name is only the default name for imports; it need not be unique
across all source code, and in the rare case of a collision the
importing package can choose a different name to use locally.
In any case, confusion is rare because the file name in the import
determines just which package is being used.
Another convention is that the package name is the base name of
its source directory;
the package in src/encoding/base64
is imported as "encoding/base64"
but has name base64
,
not encoding_base64
and not encodingBase64
.
The importer of a package will use the name to refer to its contents,
so exported names in the package can use that fact
to avoid stutter.
(Don't use the import .
notation, which can simplify
tests that must run outside the package they are testing, but should otherwise be avoided.)
For instance, the buffered reader type in the bufio
package is called Reader
,
not BufReader
, because users see it as bufio.Reader
,
which is a clear, concise name.
Moreover,
because imported entities are always addressed with their package name, bufio.Reader
does not conflict with io.Reader
.
Similarly, the function to make new instances of ring.Ring
—which
is the definition of a constructor in Go—would
normally be called NewRing
, but since
Ring
is the only type exported by the package, and since the
package is called ring
, it's called just New
,
which clients of the package see as ring.New
.
Use the package structure to help you choose good names.
Another short example is once.Do
;
once.Do(setup)
reads well and would not be improved by
writing once.DoOrWaitUntilDone(setup)
.
Long names don't automatically make things more readable.
A helpful doc comment can often be more valuable than an extra long name.
Go doesn't provide automatic support for getters and setters.
There's nothing wrong with providing getters and setters yourself,
and it's often appropriate to do so, but it's neither idiomatic nor necessary
to put Get
into the getter's name. If you have a field called
owner
(lower case, unexported), the getter method should be
called Owner
(upper case, exported), not GetOwner
.
The use of upper-case names for export provides the hook to discriminate
the field from the method.
A setter function, if needed, will likely be called SetOwner
.
Both names read well in practice:
owner := obj.Owner() if owner != user { obj.SetOwner(user) }
By convention, one-method interfaces are named by
the method name plus an -er suffix or similar modification
to construct an agent noun: Reader
,
Writer
, Formatter
,
CloseNotifier
etc.
There are a number of such names and it's productive to honor them and the function
names they capture.
Read
, Write
, Close
, Flush
,
String
and so on have
canonical signatures and meanings. To avoid confusion,
don't give your method one of those names unless it
has the same signature and meaning.
Conversely, if your type implements a method with the
same meaning as a method on a well-known type,
give it the same name and signature;
call your string-converter method String
not ToString
.
Finally, the convention in Go is to use MixedCaps
or mixedCaps
rather than underscores to write
multiword names.
Like C, Go's formal grammar uses semicolons to terminate statements, but unlike in C, those semicolons do not appear in the source. Instead the lexer uses a simple rule to insert semicolons automatically as it scans, so the input text is mostly free of them.
The rule is this. If the last token before a newline is an identifier
(which includes words like int
and float64
),
a basic literal such as a number or string constant, or one of the
tokens
break continue fallthrough return ++ -- ) }
the lexer always inserts a semicolon after the token. This could be summarized as, “if the newline comes after a token that could end a statement, insert a semicolon”.
A semicolon can also be omitted immediately before a closing brace, so a statement such as
go func() { for { dst <- <-src } }()
needs no semicolons.
Idiomatic Go programs have semicolons only in places such as
for
loop clauses, to separate the initializer, condition, and
continuation elements. They are also necessary to separate multiple
statements on a line, should you write code that way.
One consequence of the semicolon insertion rules
is that you cannot put the opening brace of a
control structure (if
, for
, switch
,
or select
) on the next line. If you do, a semicolon
will be inserted before the brace, which could cause unwanted
effects. Write them like this
if i < f() { g() }
not like this
if i < f() // wrong! { // wrong! g() }
The control structures of Go are related to those of C but differ
in important ways.
There is no do
or while
loop, only a
slightly generalized
for
;
switch
is more flexible;
if
and switch
accept an optional
initialization statement like that of for
;
break
and continue
statements
take an optional label to identify what to break or continue;
and there are new control structures including a type switch and a
multiway communications multiplexer, select
.
The syntax is also slightly different:
there are no parentheses
and the bodies must always be brace-delimited.
In Go a simple if
looks like this:
if x > 0 { return y }
Mandatory braces encourage writing simple if
statements
on multiple lines. It's good style to do so anyway,
especially when the body contains a control statement such as a
return
or break
.
Since if
and switch
accept an initialization
statement, it's common to see one used to set up a local variable.
if err := file.Chmod(0664); err != nil { log.Print(err) return err }
In the Go libraries, you'll find that
when an if
statement doesn't flow into the next statement—that is,
the body ends in break
, continue
,
goto
, or return
—the unnecessary
else
is omitted.
f, err := os.Open(name) if err != nil { return err } codeUsing(f)
This is an example of a common situation where code must guard against a
sequence of error conditions. The code reads well if the
successful flow of control runs down the page, eliminating error cases
as they arise. Since error cases tend to end in return
statements, the resulting code needs no else
statements.
f, err := os.Open(name) if err != nil { return err } d, err := f.Stat() if err != nil { f.Close() return err } codeUsing(f, d)
An aside: The last example in the previous section demonstrates a detail of how the
:=
short declaration form works.
The declaration that calls os.Open
reads,
f, err := os.Open(name)
This statement declares two variables, f
and err
.
A few lines later, the call to f.Stat
reads,
d, err := f.Stat()
which looks as if it declares d
and err
.
Notice, though, that err
appears in both statements.
This duplication is legal: err
is declared by the first statement,
but only re-assigned in the second.
This means that the call to f.Stat
uses the existing
err
variable declared above, and just gives it a new value.
In a :=
declaration a variable v
may appear even
if it has already been declared, provided:
v
(if v
is already declared in an outer scope, the declaration will create a new variable §),v
, and
This unusual property is pure pragmatism,
making it easy to use a single err
value, for example,
in a long if-else
chain.
You'll see it used often.
§ It's worth noting here that in Go the scope of function parameters and return values is the same as the function body, even though they appear lexically outside the braces that enclose the body.
The Go for
loop is similar to—but not the same as—C's.
It unifies for
and while
and there is no do-while
.
There are three forms, only one of which has semicolons.
// Like a C for for init; condition; post { } // Like a C while for condition { } // Like a C for(;;) for { }
Short declarations make it easy to declare the index variable right in the loop.
sum := 0 for i := 0; i < 10; i++ { sum += i }
If you're looping over an array, slice, string, or map,
or reading from a channel, a range
clause can
manage the loop.
for key, value := range oldMap { newMap[key] = value }
If you only need the first item in the range (the key or index), drop the second:
for key := range m { if key.expired() { delete(m, key) } }
If you only need the second item in the range (the value), use the blank identifier, an underscore, to discard the first:
sum := 0 for _, value := range array { sum += value }
The blank identifier has many uses, as described in a later section.
For strings, the range
does more work for you, breaking out individual
Unicode code points by parsing the UTF-8.
Erroneous encodings consume one byte and produce the
replacement rune U+FFFD.
(The name (with associated builtin type) rune
is Go terminology for a
single Unicode code point.
See the language specification
for details.)
The loop
for pos, char := range "日本\x80語" { // \x80 is an illegal UTF-8 encoding fmt.Printf("character %#U starts at byte position %d\n", char, pos) }
prints
character U+65E5 '日' starts at byte position 0 character U+672C '本' starts at byte position 3 character U+FFFD '�' starts at byte position 6 character U+8A9E '語' starts at byte position 7
Finally, Go has no comma operator and ++
and --
are statements not expressions.
Thus if you want to run multiple variables in a for
you should use parallel assignment (although that precludes ++
and --
).
// Reverse a for i, j := 0, len(a)-1; i < j; i, j = i+1, j-1 { a[i], a[j] = a[j], a[i] }
Go's switch
is more general than C's.
The expressions need not be constants or even integers,
the cases are evaluated top to bottom until a match is found,
and if the switch
has no expression it switches on
true
.
It's therefore possible—and idiomatic—to write an
if
-else
-if
-else
chain as a switch
.
func unhex(c byte) byte { switch { case '0' <= c && c <= '9': return c - '0' case 'a' <= c && c <= 'f': return c - 'a' + 10 case 'A' <= c && c <= 'F': return c - 'A' + 10 } return 0 }
There is no automatic fall through, but cases can be presented in comma-separated lists.
func shouldEscape(c byte) bool { switch c { case ' ', '?', '&', '=', '#', '+', '%': return true } return false }
Although they are not nearly as common in Go as some other C-like
languages, break
statements can be used to terminate
a switch
early.
Sometimes, though, it's necessary to break out of a surrounding loop,
not the switch, and in Go that can be accomplished by putting a label
on the loop and "breaking" to that label.
This example shows both uses.
Loop: for n := 0; n < len(src); n += size { switch { case src[n] < sizeOne: if validateOnly { break } size = 1 update(src[n]) case src[n] < sizeTwo: if n+1 >= len(src) { err = errShortInput break Loop } if validateOnly { break } size = 2 update(src[n] + src[n+1]<<shift) } }
Of course, the continue
statement also accepts an optional label
but it applies only to loops.
To close this section, here's a comparison routine for byte slices that uses two
switch
statements:
// Compare returns an integer comparing the two byte slices, // lexicographically. // The result will be 0 if a == b, -1 if a < b, and +1 if a > b func Compare(a, b []byte) int { for i := 0; i < len(a) && i < len(b); i++ { switch { case a[i] > b[i]: return 1 case a[i] < b[i]: return -1 } } switch { case len(a) > len(b): return 1 case len(a) < len(b): return -1 } return 0 }
A switch can also be used to discover the dynamic type of an interface
variable. Such a type switch uses the syntax of a type
assertion with the keyword type
inside the parentheses.
If the switch declares a variable in the expression, the variable will
have the corresponding type in each clause.
It's also idiomatic to reuse the name in such cases, in effect declaring
a new variable with the same name but a different type in each case.
var t interface{} t = functionOfSomeType() switch t := t.(type) { default: fmt.Printf("unexpected type %T\n", t) // %T prints whatever type t has case bool: fmt.Printf("boolean %t\n", t) // t has type bool case int: fmt.Printf("integer %d\n", t) // t has type int case *bool: fmt.Printf("pointer to boolean %t\n", *t) // t has type *bool case *int: fmt.Printf("pointer to integer %d\n", *t) // t has type *int }
One of Go's unusual features is that functions and methods
can return multiple values. This form can be used to
improve on a couple of clumsy idioms in C programs: in-band
error returns such as -1
for EOF
and modifying an argument passed by address.
In C, a write error is signaled by a negative count with the
error code secreted away in a volatile location.
In Go, Write
can return a count and an error: “Yes, you wrote some
bytes but not all of them because you filled the device”.
The signature of the Write
method on files from
package os
is:
func (file *File) Write(b []byte) (n int, err error)
and as the documentation says, it returns the number of bytes
written and a non-nil error
when n
!=
len(b)
.
This is a common style; see the section on error handling for more examples.
A similar approach obviates the need to pass a pointer to a return value to simulate a reference parameter. Here's a simple-minded function to grab a number from a position in a byte slice, returning the number and the next position.
func nextInt(b []byte, i int) (int, int) { for ; i < len(b) && !isDigit(b[i]); i++ { } x := 0 for ; i < len(b) && isDigit(b[i]); i++ { x = x*10 + int(b[i]) - '0' } return x, i }
You could use it to scan the numbers in an input slice b
like this:
for i := 0; i < len(b); { x, i = nextInt(b, i) fmt.Println(x) }
The return or result "parameters" of a Go function can be given names and
used as regular variables, just like the incoming parameters.
When named, they are initialized to the zero values for their types when
the function begins; if the function executes a return
statement
with no arguments, the current values of the result parameters are
used as the returned values.
The names are not mandatory but they can make code shorter and clearer:
they're documentation.
If we name the results of nextInt
it becomes
obvious which returned int
is which.
func nextInt(b []byte, pos int) (value, nextPos int) {
Because named results are initialized and tied to an unadorned return, they can simplify
as well as clarify. Here's a version
of io.ReadFull
that uses them well:
func ReadFull(r Reader, buf []byte) (n int, err error) { for len(buf) > 0 && err == nil { var nr int nr, err = r.Read(buf) n += nr buf = buf[nr:] } return }
Go's defer
statement schedules a function call (the
deferred function) to be run immediately before the function
executing the defer
returns. It's an unusual but
effective way to deal with situations such as resources that must be
released regardless of which path a function takes to return. The
canonical examples are unlocking a mutex or closing a file.
// Contents returns the file's contents as a string. func Contents(filename string) (string, error) { f, err := os.Open(filename) if err != nil { return "", err } defer f.Close() // f.Close will run when we're finished. var result []byte buf := make([]byte, 100) for { n, err := f.Read(buf[0:]) result = append(result, buf[0:n]...) // append is discussed later. if err != nil { if err == io.EOF { break } return "", err // f will be closed if we return here. } } return string(result), nil // f will be closed if we return here. }
Deferring a call to a function such as Close
has two advantages. First, it
guarantees that you will never forget to close the file, a mistake
that's easy to make if you later edit the function to add a new return
path. Second, it means that the close sits near the open,
which is much clearer than placing it at the end of the function.
The arguments to the deferred function (which include the receiver if the function is a method) are evaluated when the defer executes, not when the call executes. Besides avoiding worries about variables changing values as the function executes, this means that a single deferred call site can defer multiple function executions. Here's a silly example.
for i := 0; i < 5; i++ { defer fmt.Printf("%d ", i) }
Deferred functions are executed in LIFO order, so this code will cause
4 3 2 1 0
to be printed when the function returns. A
more plausible example is a simple way to trace function execution
through the program. We could write a couple of simple tracing
routines like this:
func trace(s string) { fmt.Println("entering:", s) } func untrace(s string) { fmt.Println("leaving:", s) } // Use them like this: func a() { trace("a") defer untrace("a") // do something.... }
We can do better by exploiting the fact that arguments to deferred
functions are evaluated when the defer
executes. The
tracing routine can set up the argument to the untracing routine.
This example:
func trace(s string) string { fmt.Println("entering:", s) return s } func un(s string) { fmt.Println("leaving:", s) } func a() { defer un(trace("a")) fmt.Println("in a") } func b() { defer un(trace("b")) fmt.Println("in b") a() } func main() { b() }
prints
entering: b in b entering: a in a leaving: a leaving: b
For programmers accustomed to block-level resource management from
other languages, defer
may seem peculiar, but its most
interesting and powerful applications come precisely from the fact
that it's not block-based but function-based. In the section on
panic
and recover
we'll see another
example of its possibilities.
new
Go has two allocation primitives, the built-in functions
new
and make
.
They do different things and apply to different types, which can be confusing,
but the rules are simple.
Let's talk about new
first.
It's a built-in function that allocates memory, but unlike its namesakes
in some other languages it does not initialize the memory,
it only zeros it.
That is,
new(T)
allocates zeroed storage for a new item of type
T
and returns its address, a value of type *T
.
In Go terminology, it returns a pointer to a newly allocated zero value of type
T
.
Since the memory returned by new
is zeroed, it's helpful to arrange
when designing your data structures that the
zero value of each type can be used without further initialization. This means a user of
the data structure can create one with new
and get right to
work.
For example, the documentation for bytes.Buffer
states that
"the zero value for Buffer
is an empty buffer ready to use."
Similarly, sync.Mutex
does not
have an explicit constructor or Init
method.
Instead, the zero value for a sync.Mutex
is defined to be an unlocked mutex.
The zero-value-is-useful property works transitively. Consider this type declaration.
type SyncedBuffer struct { lock sync.Mutex buffer bytes.Buffer }
Values of type SyncedBuffer
are also ready to use immediately upon allocation
or just declaration. In the next snippet, both p
and v
will work
correctly without further arrangement.
p := new(SyncedBuffer) // type *SyncedBuffer var v SyncedBuffer // type SyncedBuffer
Sometimes the zero value isn't good enough and an initializing
constructor is necessary, as in this example derived from
package os
.
func NewFile(fd int, name string) *File { if fd < 0 { return nil } f := new(File) f.fd = fd f.name = name f.dirinfo = nil f.nepipe = 0 return f }
There's a lot of boiler plate in there. We can simplify it using a composite literal, which is an expression that creates a new instance each time it is evaluated.
func NewFile(fd int, name string) *File { if fd < 0 { return nil } f := File{fd, name, nil, 0} return &f }
Note that, unlike in C, it's perfectly OK to return the address of a local variable; the storage associated with the variable survives after the function returns. In fact, taking the address of a composite literal allocates a fresh instance each time it is evaluated, so we can combine these last two lines.
return &File{fd, name, nil, 0}
The fields of a composite literal are laid out in order and must all be present.
However, by labeling the elements explicitly as field:
value
pairs, the initializers can appear in any
order, with the missing ones left as their respective zero values. Thus we could say
return &File{fd: fd, name: name}
As a limiting case, if a composite literal contains no fields at all, it creates
a zero value for the type. The expressions new(File)
and &File{}
are equivalent.
Composite literals can also be created for arrays, slices, and maps,
with the field labels being indices or map keys as appropriate.
In these examples, the initializations work regardless of the values of Enone
,
Eio
, and Einval
, as long as they are distinct.
a := [...]string {Enone: "no error", Eio: "Eio", Einval: "invalid argument"} s := []string {Enone: "no error", Eio: "Eio", Einval: "invalid argument"} m := map[int]string{Enone: "no error", Eio: "Eio", Einval: "invalid argument"}
make
Back to allocation.
The built-in function make(T,
args)
serves
a purpose different from new(T)
.
It creates slices, maps, and channels only, and it returns an initialized
(not zeroed)
value of type T
(not *T
).
The reason for the distinction
is that these three types represent, under the covers, references to data structures that
must be initialized before use.
A slice, for example, is a three-item descriptor
containing a pointer to the data (inside an array), the length, and the
capacity, and until those items are initialized, the slice is nil
.
For slices, maps, and channels,
make
initializes the internal data structure and prepares
the value for use.
For instance,
make([]int, 10, 100)
allocates an array of 100 ints and then creates a slice
structure with length 10 and a capacity of 100 pointing at the first
10 elements of the array.
(When making a slice, the capacity can be omitted; see the section on slices
for more information.)
In contrast, new([]int)
returns a pointer to a newly allocated, zeroed slice
structure, that is, a pointer to a nil
slice value.
These examples illustrate the difference between new
and
make
.
var p *[]int = new([]int) // allocates slice structure; *p == nil; rarely useful var v []int = make([]int, 100) // the slice v now refers to a new array of 100 ints // Unnecessarily complex: var p *[]int = new([]int) *p = make([]int, 100, 100) // Idiomatic: v := make([]int, 100)
Remember that make
applies only to maps, slices and channels
and does not return a pointer.
To obtain an explicit pointer allocate with new
or take the address
of a variable explicitly.
Arrays are useful when planning the detailed layout of memory and sometimes can help avoid allocation, but primarily they are a building block for slices, the subject of the next section. To lay the foundation for that topic, here are a few words about arrays.
There are major differences between the ways arrays work in Go and C. In Go,
[10]int
and [20]int
are distinct.
The value property can be useful but also expensive; if you want C-like behavior and efficiency, you can pass a pointer to the array.
func Sum(a *[3]float64) (sum float64) { for _, v := range *a { sum += v } return } array := [...]float64{7.0, 8.5, 9.1} x := Sum(&array) // Note the explicit address-of operator
But even this style isn't idiomatic Go. Use slices instead.
Slices wrap arrays to give a more general, powerful, and convenient interface to sequences of data. Except for items with explicit dimension such as transformation matrices, most array programming in Go is done with slices rather than simple arrays.
Slices hold references to an underlying array, and if you assign one
slice to another, both refer to the same array.
If a function takes a slice argument, changes it makes to
the elements of the slice will be visible to the caller, analogous to
passing a pointer to the underlying array. A Read
function can therefore accept a slice argument rather than a pointer
and a count; the length within the slice sets an upper
limit of how much data to read. Here is the signature of the
Read
method of the File
type in package
os
:
func (f *File) Read(buf []byte) (n int, err error)
The method returns the number of bytes read and an error value, if
any.
To read into the first 32 bytes of a larger buffer
buf
, slice (here used as a verb) the buffer.
n, err := f.Read(buf[0:32])
Such slicing is common and efficient. In fact, leaving efficiency aside for the moment, the following snippet would also read the first 32 bytes of the buffer.
var n int var err error for i := 0; i < 32; i++ { nbytes, e := f.Read(buf[i:i+1]) // Read one byte. n += nbytes if nbytes == 0 || e != nil { err = e break } }
The length of a slice may be changed as long as it still fits within
the limits of the underlying array; just assign it to a slice of
itself. The capacity of a slice, accessible by the built-in
function cap
, reports the maximum length the slice may
assume. Here is a function to append data to a slice. If the data
exceeds the capacity, the slice is reallocated. The
resulting slice is returned. The function uses the fact that
len
and cap
are legal when applied to the
nil
slice, and return 0.
func Append(slice, data []byte) []byte { l := len(slice) if l + len(data) > cap(slice) { // reallocate // Allocate double what's needed, for future growth. newSlice := make([]byte, (l+len(data))*2) // The copy function is predeclared and works for any slice type. copy(newSlice, slice) slice = newSlice } slice = slice[0:l+len(data)] copy(slice[l:], data) return slice }
We must return the slice afterwards because, although Append
can modify the elements of slice
, the slice itself (the run-time data
structure holding the pointer, length, and capacity) is passed by value.
The idea of appending to a slice is so useful it's captured by the
append
built-in function. To understand that function's
design, though, we need a little more information, so we'll return
to it later.
Go's arrays and slices are one-dimensional. To create the equivalent of a 2D array or slice, it is necessary to define an array-of-arrays or slice-of-slices, like this:
type Transform [3][3]float64 // A 3x3 array, really an array of arrays. type LinesOfText [][]byte // A slice of byte slices.
Because slices are variable-length, it is possible to have each inner
slice be a different length.
That can be a common situation, as in our LinesOfText
example: each line has an independent length.
text := LinesOfText{ []byte("Now is the time"), []byte("for all good gophers"), []byte("to bring some fun to the party."), }
Sometimes it's necessary to allocate a 2D slice, a situation that can arise when processing scan lines of pixels, for instance. There are two ways to achieve this. One is to allocate each slice independently; the other is to allocate a single array and point the individual slices into it. Which to use depends on your application. If the slices might grow or shrink, they should be allocated independently to avoid overwriting the next line; if not, it can be more efficient to construct the object with a single allocation. For reference, here are sketches of the two methods. First, a line at a time:
// Allocate the top-level slice. picture := make([][]uint8, YSize) // One row per unit of y. // Loop over the rows, allocating the slice for each row. for i := range picture { picture[i] = make([]uint8, XSize) }
And now as one allocation, sliced into lines:
// Allocate the top-level slice, the same as before. picture := make([][]uint8, YSize) // One row per unit of y. // Allocate one large slice to hold all the pixels. pixels := make([]uint8, XSize*YSize) // Has type []uint8 even though picture is [][]uint8. // Loop over the rows, slicing each row from the front of the remaining pixels slice. for i := range picture { picture[i], pixels = pixels[:XSize], pixels[XSize:] }
Maps are a convenient and powerful built-in data structure that associate values of one type (the key) with values of another type (the element or value). The key can be of any type for which the equality operator is defined, such as integers, floating point and complex numbers, strings, pointers, interfaces (as long as the dynamic type supports equality), structs and arrays. Slices cannot be used as map keys, because equality is not defined on them. Like slices, maps hold references to an underlying data structure. If you pass a map to a function that changes the contents of the map, the changes will be visible in the caller.
Maps can be constructed using the usual composite literal syntax with colon-separated key-value pairs, so it's easy to build them during initialization.
var timeZone = map[string]int{ "UTC": 0*60*60, "EST": -5*60*60, "CST": -6*60*60, "MST": -7*60*60, "PST": -8*60*60, }
Assigning and fetching map values looks syntactically just like doing the same for arrays and slices except that the index doesn't need to be an integer.
offset := timeZone["EST"]
An attempt to fetch a map value with a key that
is not present in the map will return the zero value for the type
of the entries
in the map. For instance, if the map contains integers, looking
up a non-existent key will return 0
.
A set can be implemented as a map with value type bool
.
Set the map entry to true
to put the value in the set, and then
test it by simple indexing.
attended := map[string]bool{ "Ann": true, "Joe": true, ... } if attended[person] { // will be false if person is not in the map fmt.Println(person, "was at the meeting") }
Sometimes you need to distinguish a missing entry from
a zero value. Is there an entry for "UTC"
or is that 0 because it's not in the map at all?
You can discriminate with a form of multiple assignment.
var seconds int var ok bool seconds, ok = timeZone[tz]
For obvious reasons this is called the “comma ok” idiom.
In this example, if tz
is present, seconds
will be set appropriately and ok
will be true; if not,
seconds
will be set to zero and ok
will
be false.
Here's a function that puts it together with a nice error report:
func offset(tz string) int { if seconds, ok := timeZone[tz]; ok { return seconds } log.Println("unknown time zone:", tz) return 0 }
To test for presence in the map without worrying about the actual value,
you can use the blank identifier (_
)
in place of the usual variable for the value.
_, present := timeZone[tz]
To delete a map entry, use the delete
built-in function, whose arguments are the map and the key to be deleted.
It's safe to do this even if the key is already absent
from the map.
delete(timeZone, "PDT") // Now on Standard Time
Formatted printing in Go uses a style similar to C's printf
family but is richer and more general. The functions live in the fmt
package and have capitalized names: fmt.Printf
, fmt.Fprintf
,
fmt.Sprintf
and so on. The string functions (Sprintf
etc.)
return a string rather than filling in a provided buffer.
You don't need to provide a format string. For each of Printf
,
Fprintf
and Sprintf
there is another pair
of functions, for instance Print
and Println
.
These functions do not take a format string but instead generate a default
format for each argument. The Println
versions also insert a blank
between arguments and append a newline to the output while
the Print
versions add blanks only if the operand on neither side is a string.
In this example each line produces the same output.
fmt.Printf("Hello %d\n", 23) fmt.Fprint(os.Stdout, "Hello ", 23, "\n") fmt.Println("Hello", 23) fmt.Println(fmt.Sprint("Hello ", 23))
The formatted print functions fmt.Fprint
and friends take as a first argument any object
that implements the io.Writer
interface; the variables os.Stdout
and os.Stderr
are familiar instances.
Here things start to diverge from C. First, the numeric formats such as %d
do not take flags for signedness or size; instead, the printing routines use the
type of the argument to decide these properties.
var x uint64 = 1<<64 - 1 fmt.Printf("%d %x; %d %x\n", x, x, int64(x), int64(x))
prints
18446744073709551615 ffffffffffffffff; -1 -1
If you just want the default conversion, such as decimal for integers, you can use
the catchall format %v
(for “value”); the result is exactly
what Print
and Println
would produce.
Moreover, that format can print any value, even arrays, slices, structs, and
maps. Here is a print statement for the time zone map defined in the previous section.
fmt.Printf("%v\n", timeZone) // or just fmt.Println(timeZone)
which gives output
map[CST:-21600 PST:-28800 EST:-18000 UTC:0 MST:-25200]
For maps the keys may be output in any order, of course.
When printing a struct, the modified format %+v
annotates the
fields of the structure with their names, and for any value the alternate
format %#v
prints the value in full Go syntax.
type T struct { a int b float64 c string } t := &T{ 7, -2.35, "abc\tdef" } fmt.Printf("%v\n", t) fmt.Printf("%+v\n", t) fmt.Printf("%#v\n", t) fmt.Printf("%#v\n", timeZone)
prints
&{7 -2.35 abc def} &{a:7 b:-2.35 c:abc def} &main.T{a:7, b:-2.35, c:"abc\tdef"} map[string] int{"CST":-21600, "PST":-28800, "EST":-18000, "UTC":0, "MST":-25200}
(Note the ampersands.)
That quoted string format is also available through %q
when
applied to a value of type string
or []byte
.
The alternate format %#q
will use backquotes instead if possible.
(The %q
format also applies to integers and runes, producing a
single-quoted rune constant.)
Also, %x
works on strings, byte arrays and byte slices as well as
on integers, generating a long hexadecimal string, and with
a space in the format (% x
) it puts spaces between the bytes.
Another handy format is %T
, which prints the type of a value.
fmt.Printf("%T\n", timeZone)
prints
map[string] int
If you want to control the default format for a custom type, all that's required is to define
a method with the signature String() string
on the type.
For our simple type T
, that might look like this.
func (t *T) String() string { return fmt.Sprintf("%d/%g/%q", t.a, t.b, t.c) } fmt.Printf("%v\n", t)
to print in the format
7/-2.35/"abc\tdef"
(If you need to print values of type T
as well as pointers to T
,
the receiver for String
must be of value type; this example used a pointer because
that's more efficient and idiomatic for struct types.
See the section below on pointers vs. value receivers for more information.)
Our String
method is able to call Sprintf
because the
print routines are fully reentrant and can be wrapped this way.
There is one important detail to understand about this approach,
however: don't construct a String
method by calling
Sprintf
in a way that will recur into your String
method indefinitely. This can happen if the Sprintf
call attempts to print the receiver directly as a string, which in
turn will invoke the method again. It's a common and easy mistake
to make, as this example shows.
type MyString string func (m MyString) String() string { return fmt.Sprintf("MyString=%s", m) // Error: will recur forever. }
It's also easy to fix: convert the argument to the basic string type, which does not have the method.
type MyString string func (m MyString) String() string { return fmt.Sprintf("MyString=%s", string(m)) // OK: note conversion. }
In the initialization section we'll see another technique that avoids this recursion.
Another printing technique is to pass a print routine's arguments directly to another such routine.
The signature of Printf
uses the type ...interface{}
for its final argument to specify that an arbitrary number of parameters (of arbitrary type)
can appear after the format.
func Printf(format string, v ...interface{}) (n int, err error) {
Within the function Printf
, v
acts like a variable of type
[]interface{}
but if it is passed to another variadic function, it acts like
a regular list of arguments.
Here is the implementation of the
function log.Println
we used above. It passes its arguments directly to
fmt.Sprintln
for the actual formatting.
// Println prints to the standard logger in the manner of fmt.Println. func Println(v ...interface{}) { std.Output(2, fmt.Sprintln(v...)) // Output takes parameters (int, string) }
We write ...
after v
in the nested call to Sprintln
to tell the
compiler to treat v
as a list of arguments; otherwise it would just pass
v
as a single slice argument.
There's even more to printing than we've covered here. See the godoc
documentation
for package fmt
for the details.
By the way, a ...
parameter can be of a specific type, for instance ...int
for a min function that chooses the least of a list of integers:
func Min(a ...int) int { min := int(^uint(0) >> 1) // largest int for _, i := range a { if i < min { min = i } } return min }
Now we have the missing piece we needed to explain the design of
the append
built-in function. The signature of append
is different from our custom Append
function above.
Schematically, it's like this:
func append(slice []T, elements ...T) []T
where T is a placeholder for any given type. You can't
actually write a function in Go where the type T
is determined by the caller.
That's why append
is built in: it needs support from the
compiler.
What append
does is append the elements to the end of
the slice and return the result. The result needs to be returned
because, as with our hand-written Append
, the underlying
array may change. This simple example
x := []int{1,2,3} x = append(x, 4, 5, 6) fmt.Println(x)
prints [1 2 3 4 5 6]
. So append
works a
little like Printf
, collecting an arbitrary number of
arguments.
But what if we wanted to do what our Append
does and
append a slice to a slice? Easy: use ...
at the call
site, just as we did in the call to Output
above. This
snippet produces identical output to the one above.
x := []int{1,2,3} y := []int{4,5,6} x = append(x, y...) fmt.Println(x)
Without that ...
, it wouldn't compile because the types
would be wrong; y
is not of type int
.
Although it doesn't look superficially very different from initialization in C or C++, initialization in Go is more powerful. Complex structures can be built during initialization and the ordering issues among initialized objects, even among different packages, are handled correctly.
Constants in Go are just that—constant.
They are created at compile time, even when defined as
locals in functions,
and can only be numbers, characters (runes), strings or booleans.
Because of the compile-time restriction, the expressions
that define them must be constant expressions,
evaluatable by the compiler. For instance,
1<<3
is a constant expression, while
math.Sin(math.Pi/4)
is not because
the function call to math.Sin
needs
to happen at run time.
In Go, enumerated constants are created using the iota
enumerator. Since iota
can be part of an expression and
expressions can be implicitly repeated, it is easy to build intricate
sets of values.
The ability to attach a method such as String
to any
user-defined type makes it possible for arbitrary values to format themselves
automatically for printing.
Although you'll see it most often applied to structs, this technique is also useful for
scalar types such as floating-point types like ByteSize
.
The expression YB
prints as 1.00YB
,
while ByteSize(1e13)
prints as 9.09TB
.
The use here of Sprintf
to implement ByteSize
's String
method is safe
(avoids recurring indefinitely) not because of a conversion but
because it calls Sprintf
with %f
,
which is not a string format: Sprintf
will only call
the String
method when it wants a string, and %f
wants a floating-point value.
Variables can be initialized just like constants but the initializer can be a general expression computed at run time.
var ( home = os.Getenv("HOME") user = os.Getenv("USER") gopath = os.Getenv("GOPATH") )
Finally, each source file can define its own niladic init
function to
set up whatever state is required. (Actually each file can have multiple
init
functions.)
And finally means finally: init
is called after all the
variable declarations in the package have evaluated their initializers,
and those are evaluated only after all the imported packages have been
initialized.
Besides initializations that cannot be expressed as declarations,
a common use of init
functions is to verify or repair
correctness of the program state before real execution begins.
func init() { if user == "" { log.Fatal("$USER not set") } if home == "" { home = "/home/" + user } if gopath == "" { gopath = home + "/go" } // gopath may be overridden by --gopath flag on command line. flag.StringVar(&gopath, "gopath", gopath, "override default GOPATH") }
As we saw with ByteSize
,
methods can be defined for any named type (except a pointer or an interface);
the receiver does not have to be a struct.
In the discussion of slices above, we wrote an Append
function. We can define it as a method on slices instead. To do
this, we first declare a named type to which we can bind the method, and
then make the receiver for the method a value of that type.
type ByteSlice []byte func (slice ByteSlice) Append(data []byte) []byte { // Body exactly the same as the Append function defined above. }
This still requires the method to return the updated slice. We can
eliminate that clumsiness by redefining the method to take a
pointer to a ByteSlice
as its receiver, so the
method can overwrite the caller's slice.
func (p *ByteSlice) Append(data []byte) { slice := *p // Body as above, without the return. *p = slice }
In fact, we can do even better. If we modify our function so it looks
like a standard Write
method, like this,
func (p *ByteSlice) Write(data []byte) (n int, err error) { slice := *p // Again as above. *p = slice return len(data), nil }
then the type *ByteSlice
satisfies the standard interface
io.Writer
, which is handy. For instance, we can
print into one.
var b ByteSlice fmt.Fprintf(&b, "This hour has %d days\n", 7)
We pass the address of a ByteSlice
because only *ByteSlice
satisfies io.Writer
.
The rule about pointers vs. values for receivers is that value methods
can be invoked on pointers and values, but pointer methods can only be
invoked on pointers.
This rule arises because pointer methods can modify the receiver; invoking
them on a value would cause the method to receive a copy of the value, so
any modifications would be discarded.
The language therefore disallows this mistake.
There is a handy exception, though. When the value is addressable, the
language takes care of the common case of invoking a pointer method on a
value by inserting the address operator automatically.
In our example, the variable b
is addressable, so we can call
its Write
method with just b.Write
. The compiler
will rewrite that to (&b).Write
for us.
By the way, the idea of using Write
on a slice of bytes
is central to the implementation of bytes.Buffer
.
Interfaces in Go provide a way to specify the behavior of an
object: if something can do this, then it can be used
here. We've seen a couple of simple examples already;
custom printers can be implemented by a String
method
while Fprintf
can generate output to anything
with a Write
method.
Interfaces with only one or two methods are common in Go code, and are
usually given a name derived from the method, such as io.Writer
for something that implements Write
.
A type can implement multiple interfaces.
For instance, a collection can be sorted
by the routines in package sort
if it implements
sort.Interface
, which contains Len()
,
Less(i, j int) bool
, and Swap(i, j int)
,
and it could also have a custom formatter.
In this contrived example Sequence
satisfies both.
The String
method of Sequence
is recreating the
work that Sprint
already does for slices.
(It also has complexity O(N²), which is poor.) We can share the
effort (and also speed it up) if we convert the Sequence
to a plain
[]int
before calling Sprint
.
func (s Sequence) String() string { s = s.Copy() sort.Sort(s) return fmt.Sprint([]int(s)) }
This method is another example of the conversion technique for calling
Sprintf
safely from a String
method.
Because the two types (Sequence
and []int
)
are the same if we ignore the type name, it's legal to convert between them.
The conversion doesn't create a new value, it just temporarily acts
as though the existing value has a new type.
(There are other legal conversions, such as from integer to floating point, that
do create a new value.)
It's an idiom in Go programs to convert the
type of an expression to access a different
set of methods. As an example, we could use the existing
type sort.IntSlice
to reduce the entire example
to this:
type Sequence []int // Method for printing - sorts the elements before printing func (s Sequence) String() string { s = s.Copy() sort.IntSlice(s).Sort() return fmt.Sprint([]int(s)) }
Now, instead of having Sequence
implement multiple
interfaces (sorting and printing), we're using the ability of a data item to be
converted to multiple types (Sequence
, sort.IntSlice
and []int
), each of which does some part of the job.
That's more unusual in practice but can be effective.
Type switches are a form of conversion: they take an interface and, for
each case in the switch, in a sense convert it to the type of that case.
Here's a simplified version of how the code under fmt.Printf
turns a value into
a string using a type switch.
If it's already a string, we want the actual string value held by the interface, while if it has a
String
method we want the result of calling the method.
type Stringer interface { String() string } var value interface{} // Value provided by caller. switch str := value.(type) { case string: return str case Stringer: return str.String() }
The first case finds a concrete value; the second converts the interface into another interface. It's perfectly fine to mix types this way.
What if there's only one type we care about? If we know the value holds a string
and we just want to extract it?
A one-case type switch would do, but so would a type assertion.
A type assertion takes an interface value and extracts from it a value of the specified explicit type.
The syntax borrows from the clause opening a type switch, but with an explicit
type rather than the type
keyword:
value.(typeName)
and the result is a new value with the static type typeName
.
That type must either be the concrete type held by the interface, or a second interface
type that the value can be converted to.
To extract the string we know is in the value, we could write:
str := value.(string)
But if it turns out that the value does not contain a string, the program will crash with a run-time error. To guard against that, use the "comma, ok" idiom to test, safely, whether the value is a string:
str, ok := value.(string) if ok { fmt.Printf("string value is: %q\n", str) } else { fmt.Printf("value is not a string\n") }
If the type assertion fails, str
will still exist and be of type string, but it will have
the zero value, an empty string.
As an illustration of the capability, here's an if
-else
statement that's equivalent to the type switch that opened this section.
if str, ok := value.(string); ok { return str } else if str, ok := value.(Stringer); ok { return str.String() }
If a type exists only to implement an interface and will never have exported methods beyond that interface, there is no need to export the type itself. Exporting just the interface makes it clear the value has no interesting behavior beyond what is described in the interface. It also avoids the need to repeat the documentation on every instance of a common method.
In such cases, the constructor should return an interface value
rather than the implementing type.
As an example, in the hash libraries
both crc32.NewIEEE
and adler32.New
return the interface type hash.Hash32
.
Substituting the CRC-32 algorithm for Adler-32 in a Go program
requires only changing the constructor call;
the rest of the code is unaffected by the change of algorithm.
A similar approach allows the streaming cipher algorithms
in the various crypto
packages to be
separated from the block ciphers they chain together.
The Block
interface
in the crypto/cipher
package specifies the
behavior of a block cipher, which provides encryption
of a single block of data.
Then, by analogy with the bufio
package,
cipher packages that implement this interface
can be used to construct streaming ciphers, represented
by the Stream
interface, without
knowing the details of the block encryption.
The crypto/cipher
interfaces look like this:
type Block interface { BlockSize() int Encrypt(src, dst []byte) Decrypt(src, dst []byte) } type Stream interface { XORKeyStream(dst, src []byte) }
Here's the definition of the counter mode (CTR) stream, which turns a block cipher into a streaming cipher; notice that the block cipher's details are abstracted away:
// NewCTR returns a Stream that encrypts/decrypts using the given Block in // counter mode. The length of iv must be the same as the Block's block size. func NewCTR(block Block, iv []byte) Stream
NewCTR
applies not
just to one specific encryption algorithm and data source but to any
implementation of the Block
interface and any
Stream
. Because they return
interface values, replacing CTR
encryption with other encryption modes is a localized change. The constructor
calls must be edited, but because the surrounding code must treat the result only
as a Stream
, it won't notice the difference.
Since almost anything can have methods attached, almost anything can
satisfy an interface. One illustrative example is in the http
package, which defines the Handler
interface. Any object
that implements Handler
can serve HTTP requests.
type Handler interface { ServeHTTP(ResponseWriter, *Request) }
ResponseWriter
is itself an interface that provides access
to the methods needed to return the response to the client.
Those methods include the standard Write
method, so an
http.ResponseWriter
can be used wherever an io.Writer
can be used.
Request
is a struct containing a parsed representation
of the request from the client.
For brevity, let's ignore POSTs and assume HTTP requests are always GETs; that simplification does not affect the way the handlers are set up. Here's a trivial but complete implementation of a handler to count the number of times the page is visited.
// Simple counter server. type Counter struct { n int } func (ctr *Counter) ServeHTTP(w http.ResponseWriter, req *http.Request) { ctr.n++ fmt.Fprintf(w, "counter = %d\n", ctr.n) }
(Keeping with our theme, note how Fprintf
can print to an
http.ResponseWriter
.)
For reference, here's how to attach such a server to a node on the URL tree.
import "net/http" ... ctr := new(Counter) http.Handle("/counter", ctr)
But why make Counter
a struct? An integer is all that's needed.
(The receiver needs to be a pointer so the increment is visible to the caller.)
// Simpler counter server. type Counter int func (ctr *Counter) ServeHTTP(w http.ResponseWriter, req *http.Request) { *ctr++ fmt.Fprintf(w, "counter = %d\n", *ctr) }
What if your program has some internal state that needs to be notified that a page has been visited? Tie a channel to the web page.
// A channel that sends a notification on each visit. // (Probably want the channel to be buffered.) type Chan chan *http.Request func (ch Chan) ServeHTTP(w http.ResponseWriter, req *http.Request) { ch <- req fmt.Fprint(w, "notification sent") }
Finally, let's say we wanted to present on /args
the arguments
used when invoking the server binary.
It's easy to write a function to print the arguments.
func ArgServer() { fmt.Println(os.Args) }
How do we turn that into an HTTP server? We could make ArgServer
a method of some type whose value we ignore, but there's a cleaner way.
Since we can define a method for any type except pointers and interfaces,
we can write a method for a function.
The http
package contains this code:
// The HandlerFunc type is an adapter to allow the use of // ordinary functions as HTTP handlers. If f is a function // with the appropriate signature, HandlerFunc(f) is a // Handler object that calls f. type HandlerFunc func(ResponseWriter, *Request) // ServeHTTP calls f(w, req). func (f HandlerFunc) ServeHTTP(w ResponseWriter, req *Request) { f(w, req) }
HandlerFunc
is a type with a method, ServeHTTP
,
so values of that type can serve HTTP requests. Look at the implementation
of the method: the receiver is a function, f
, and the method
calls f
. That may seem odd but it's not that different from, say,
the receiver being a channel and the method sending on the channel.
To make ArgServer
into an HTTP server, we first modify it
to have the right signature.
// Argument server. func ArgServer(w http.ResponseWriter, req *http.Request) { fmt.Fprintln(w, os.Args) }
ArgServer
now has same signature as HandlerFunc
,
so it can be converted to that type to access its methods,
just as we converted Sequence
to IntSlice
to access IntSlice.Sort
.
The code to set it up is concise:
http.Handle("/args", http.HandlerFunc(ArgServer))
When someone visits the page /args
,
the handler installed at that page has value ArgServer
and type HandlerFunc
.
The HTTP server will invoke the method ServeHTTP
of that type, with ArgServer
as the receiver, which will in turn call
ArgServer
(via the invocation f(w, req)
inside HandlerFunc.ServeHTTP
).
The arguments will then be displayed.
In this section we have made an HTTP server from a struct, an integer, a channel, and a function, all because interfaces are just sets of methods, which can be defined for (almost) any type.
We've mentioned the blank identifier a couple of times now, in the context of
for
range
loops
and maps.
The blank identifier can be assigned or declared with any value of any type, with the
value discarded harmlessly.
It's a bit like writing to the Unix /dev/null
file:
it represents a write-only value
to be used as a place-holder
where a variable is needed but the actual value is irrelevant.
It has uses beyond those we've seen already.
The use of a blank identifier in a for
range
loop is a
special case of a general situation: multiple assignment.
If an assignment requires multiple values on the left side, but one of the values will not be used by the program, a blank identifier on the left-hand-side of the assignment avoids the need to create a dummy variable and makes it clear that the value is to be discarded. For instance, when calling a function that returns a value and an error, but only the error is important, use the blank identifier to discard the irrelevant value.
if _, err := os.Stat(path); os.IsNotExist(err) { fmt.Printf("%s does not exist\n", path) }
Occasionally you'll see code that discards the error value in order to ignore the error; this is terrible practice. Always check error returns; they're provided for a reason.
// Bad! This code will crash if path does not exist. fi, _ := os.Stat(path) if fi.IsDir() { fmt.Printf("%s is a directory\n", path) }
It is an error to import a package or to declare a variable without using it. Unused imports bloat the program and slow compilation, while a variable that is initialized but not used is at least a wasted computation and perhaps indicative of a larger bug. When a program is under active development, however, unused imports and variables often arise and it can be annoying to delete them just to have the compilation proceed, only to have them be needed again later. The blank identifier provides a workaround.
This half-written program has two unused imports
(fmt
and io
)
and an unused variable (fd
),
so it will not compile, but it would be nice to see if the
code so far is correct.
To silence complaints about the unused imports, use a
blank identifier to refer to a symbol from the imported package.
Similarly, assigning the unused variable fd
to the blank identifier will silence the unused variable error.
This version of the program does compile.
By convention, the global declarations to silence import errors should come right after the imports and be commented, both to make them easy to find and as a reminder to clean things up later.
An unused import like fmt
or io
in the
previous example should eventually be used or removed:
blank assignments identify code as a work in progress.
But sometimes it is useful to import a package only for its
side effects, without any explicit use.
For example, during its init
function,
the net/http/pprof
package registers HTTP handlers that provide
debugging information. It has an exported API, but
most clients need only the handler registration and
access the data through a web page.
To import the package only for its side effects, rename the package
to the blank identifier:
import _ "net/http/pprof"
This form of import makes clear that the package is being imported for its side effects, because there is no other possible use of the package: in this file, it doesn't have a name. (If it did, and we didn't use that name, the compiler would reject the program.)
As we saw in the discussion of interfaces above,
a type need not declare explicitly that it implements an interface.
Instead, a type implements the interface just by implementing the interface's methods.
In practice, most interface conversions are static and therefore checked at compile time.
For example, passing an *os.File
to a function
expecting an io.Reader
will not compile unless
*os.File
implements the io.Reader
interface.
Some interface checks do happen at run-time, though.
One instance is in the encoding/json
package, which defines a Marshaler
interface. When the JSON encoder receives a value that implements that interface,
the encoder invokes the value's marshaling method to convert it to JSON
instead of doing the standard conversion.
The encoder checks this property at run time with a type assertion like:
m, ok := val.(json.Marshaler)
If it's necessary only to ask whether a type implements an interface, without actually using the interface itself, perhaps as part of an error check, use the blank identifier to ignore the type-asserted value:
if _, ok := val.(json.Marshaler); ok { fmt.Printf("value %v of type %T implements json.Marshaler\n", val, val) }
One place this situation arises is when it is necessary to guarantee within the package implementing the type that
it actually satisfies the interface.
If a type—for example,
json.RawMessage
—needs
a custom JSON representation, it should implement
json.Marshaler
, but there are no static conversions that would
cause the compiler to verify this automatically.
If the type inadvertently fails to satisfy the interface, the JSON encoder will still work,
but will not use the custom implementation.
To guarantee that the implementation is correct,
a global declaration using the blank identifier can be used in the package:
var _ json.Marshaler = (*RawMessage)(nil)
In this declaration, the assignment involving a conversion of a
*RawMessage
to a Marshaler
requires that *RawMessage
implements Marshaler
,
and that property will be checked at compile time.
Should the json.Marshaler
interface change, this package
will no longer compile and we will be on notice that it needs to be updated.
The appearance of the blank identifier in this construct indicates that the declaration exists only for the type checking, not to create a variable. Don't do this for every type that satisfies an interface, though. By convention, such declarations are only used when there are no static conversions already present in the code, which is a rare event.
Go does not provide the typical, type-driven notion of subclassing, but it does have the ability to “borrow” pieces of an implementation by embedding types within a struct or interface.
Interface embedding is very simple.
We've mentioned the io.Reader
and io.Writer
interfaces before;
here are their definitions.
type Reader interface { Read(p []byte) (n int, err error) } type Writer interface { Write(p []byte) (n int, err error) }
The io
package also exports several other interfaces
that specify objects that can implement several such methods.
For instance, there is io.ReadWriter
, an interface
containing both Read
and Write
.
We could specify io.ReadWriter
by listing the
two methods explicitly, but it's easier and more evocative
to embed the two interfaces to form the new one, like this:
// ReadWriter is the interface that combines the Reader and Writer interfaces. type ReadWriter interface { Reader Writer }
This says just what it looks like: A ReadWriter
can do
what a Reader
does and what a Writer
does; it is a union of the embedded interfaces (which must be disjoint
sets of methods).
Only interfaces can be embedded within interfaces.
The same basic idea applies to structs, but with more far-reaching
implications. The bufio
package has two struct types,
bufio.Reader
and bufio.Writer
, each of
which of course implements the analogous interfaces from package
io
.
And bufio
also implements a buffered reader/writer,
which it does by combining a reader and a writer into one struct
using embedding: it lists the types within the struct
but does not give them field names.
// ReadWriter stores pointers to a Reader and a Writer. // It implements io.ReadWriter. type ReadWriter struct { *Reader // *bufio.Reader *Writer // *bufio.Writer }
The embedded elements are pointers to structs and of course
must be initialized to point to valid structs before they
can be used.
The ReadWriter
struct could be written as
type ReadWriter struct { reader *Reader writer *Writer }
but then to promote the methods of the fields and to
satisfy the io
interfaces, we would also need
to provide forwarding methods, like this:
func (rw *ReadWriter) Read(p []byte) (n int, err error) { return rw.reader.Read(p) }
By embedding the structs directly, we avoid this bookkeeping.
The methods of embedded types come along for free, which means that bufio.ReadWriter
not only has the methods of bufio.Reader
and bufio.Writer
,
it also satisfies all three interfaces:
io.Reader
,
io.Writer
, and
io.ReadWriter
.
There's an important way in which embedding differs from subclassing. When we embed a type,
the methods of that type become methods of the outer type,
but when they are invoked the receiver of the method is the inner type, not the outer one.
In our example, when the Read
method of a bufio.ReadWriter
is
invoked, it has exactly the same effect as the forwarding method written out above;
the receiver is the reader
field of the ReadWriter
, not the
ReadWriter
itself.
Embedding can also be a simple convenience. This example shows an embedded field alongside a regular, named field.
type Job struct { Command string *log.Logger }
The Job
type now has the Print
, Printf
, Println
and other
methods of *log.Logger
. We could have given the Logger
a field name, of course, but it's not necessary to do so. And now, once
initialized, we can
log to the Job
:
job.Println("starting now...")
The Logger
is a regular field of the Job
struct,
so we can initialize it in the usual way inside the constructor for Job
, like this,
func NewJob(command string, logger *log.Logger) *Job { return &Job{command, logger} }
or with a composite literal,
job := &Job{command, log.New(os.Stderr, "Job: ", log.Ldate)}
If we need to refer to an embedded field directly, the type name of the field,
ignoring the package qualifier, serves as a field name, as it did
in the Read
method of our ReadWriter
struct.
Here, if we needed to access the
*log.Logger
of a Job
variable job
,
we would write job.Logger
,
which would be useful if we wanted to refine the methods of Logger
.
func (job *Job) Printf(format string, args ...interface{}) { job.Logger.Printf("%q: %s", job.Command, fmt.Sprintf(format, args...)) }
Embedding types introduces the problem of name conflicts but the rules to resolve
them are simple.
First, a field or method X
hides any other item X
in a more deeply
nested part of the type.
If log.Logger
contained a field or method called Command
, the Command
field
of Job
would dominate it.
Second, if the same name appears at the same nesting level, it is usually an error;
it would be erroneous to embed log.Logger
if the Job
struct
contained another field or method called Logger
.
However, if the duplicate name is never mentioned in the program outside the type definition, it is OK.
This qualification provides some protection against changes made to types embedded from outside; there
is no problem if a field is added that conflicts with another field in another subtype if neither field
is ever used.
Concurrent programming is a large topic and there is space only for some Go-specific highlights here.
Concurrent programming in many environments is made difficult by the subtleties required to implement correct access to shared variables. Go encourages a different approach in which shared values are passed around on channels and, in fact, never actively shared by separate threads of execution. Only one goroutine has access to the value at any given time. Data races cannot occur, by design. To encourage this way of thinking we have reduced it to a slogan:
Do not communicate by sharing memory; instead, share memory by communicating.
This approach can be taken too far. Reference counts may be best done by putting a mutex around an integer variable, for instance. But as a high-level approach, using channels to control access makes it easier to write clear, correct programs.
One way to think about this model is to consider a typical single-threaded program running on one CPU. It has no need for synchronization primitives. Now run another such instance; it too needs no synchronization. Now let those two communicate; if the communication is the synchronizer, there's still no need for other synchronization. Unix pipelines, for example, fit this model perfectly. Although Go's approach to concurrency originates in Hoare's Communicating Sequential Processes (CSP), it can also be seen as a type-safe generalization of Unix pipes.
They're called goroutines because the existing terms—threads, coroutines, processes, and so on—convey inaccurate connotations. A goroutine has a simple model: it is a function executing concurrently with other goroutines in the same address space. It is lightweight, costing little more than the allocation of stack space. And the stacks start small, so they are cheap, and grow by allocating (and freeing) heap storage as required.
Goroutines are multiplexed onto multiple OS threads so if one should block, such as while waiting for I/O, others continue to run. Their design hides many of the complexities of thread creation and management.
Prefix a function or method call with the go
keyword to run the call in a new goroutine.
When the call completes, the goroutine
exits, silently. (The effect is similar to the Unix shell's
&
notation for running a command in the
background.)
go list.Sort() // run list.Sort concurrently; don't wait for it.
A function literal can be handy in a goroutine invocation.
func Announce(message string, delay time.Duration) { go func() { time.Sleep(delay) fmt.Println(message) }() // Note the parentheses - must call the function. }
In Go, function literals are closures: the implementation makes sure the variables referred to by the function survive as long as they are active.
These examples aren't too practical because the functions have no way of signaling completion. For that, we need channels.
Like maps, channels are allocated with make
, and
the resulting value acts as a reference to an underlying data structure.
If an optional integer parameter is provided, it sets the buffer size for the channel.
The default is zero, for an unbuffered or synchronous channel.
ci := make(chan int) // unbuffered channel of integers cj := make(chan int, 0) // unbuffered channel of integers cs := make(chan *os.File, 100) // buffered channel of pointers to Files
Unbuffered channels combine communication—the exchange of a value—with synchronization—guaranteeing that two calculations (goroutines) are in a known state.
There are lots of nice idioms using channels. Here's one to get us started. In the previous section we launched a sort in the background. A channel can allow the launching goroutine to wait for the sort to complete.
c := make(chan int) // Allocate a channel. // Start the sort in a goroutine; when it completes, signal on the channel. go func() { list.Sort() c <- 1 // Send a signal; value does not matter. }() doSomethingForAWhile() <-c // Wait for sort to finish; discard sent value.
Receivers always block until there is data to receive. If the channel is unbuffered, the sender blocks until the receiver has received the value. If the channel has a buffer, the sender blocks only until the value has been copied to the buffer; if the buffer is full, this means waiting until some receiver has retrieved a value.
A buffered channel can be used like a semaphore, for instance to
limit throughput. In this example, incoming requests are passed
to handle
, which sends a value into the channel, processes
the request, and then receives a value from the channel
to ready the “semaphore” for the next consumer.
The capacity of the channel buffer limits the number of
simultaneous calls to process
.
var sem = make(chan int, MaxOutstanding) func handle(r *Request) { sem <- 1 // Wait for active queue to drain. process(r) // May take a long time. <-sem // Done; enable next request to run. } func Serve(queue chan *Request) { for { req := <-queue go handle(req) // Don't wait for handle to finish. } }
Once MaxOutstanding
handlers are executing process
,
any more will block trying to send into the filled channel buffer,
until one of the existing handlers finishes and receives from the buffer.
This design has a problem, though: Serve
creates a new goroutine for
every incoming request, even though only MaxOutstanding
of them can run at any moment.
As a result, the program can consume unlimited resources if the requests come in too fast.
We can address that deficiency by changing Serve
to
gate the creation of the goroutines.
Here's an obvious solution, but beware it has a bug we'll fix subsequently:
func Serve(queue chan *Request) { for req := range queue { sem <- 1 go func() { process(req) // Buggy; see explanation below. <-sem }() } }
The bug is that in a Go for
loop, the loop variable
is reused for each iteration, so the req
variable is shared across all goroutines.
That's not what we want.
We need to make sure that req
is unique for each goroutine.
Here's one way to do that, passing the value of req
as an argument
to the closure in the goroutine:
func Serve(queue chan *Request) { for req := range queue { sem <- 1 go func(req *Request) { process(req) <-sem }(req) } }
Compare this version with the previous to see the difference in how the closure is declared and run. Another solution is just to create a new variable with the same name, as in this example:
func Serve(queue chan *Request) { for req := range queue { req := req // Create new instance of req for the goroutine. sem <- 1 go func() { process(req) <-sem }() } }
It may seem odd to write
req := req
but it's legal and idiomatic in Go to do this. You get a fresh version of the variable with the same name, deliberately shadowing the loop variable locally but unique to each goroutine.
Going back to the general problem of writing the server,
another approach that manages resources well is to start a fixed
number of handle
goroutines all reading from the request
channel.
The number of goroutines limits the number of simultaneous
calls to process
.
This Serve
function also accepts a channel on which
it will be told to exit; after launching the goroutines it blocks
receiving from that channel.
func handle(queue chan *Request) { for r := range queue { process(r) } } func Serve(clientRequests chan *Request, quit chan bool) { // Start handlers for i := 0; i < MaxOutstanding; i++ { go handle(clientRequests) } <-quit // Wait to be told to exit. }
One of the most important properties of Go is that a channel is a first-class value that can be allocated and passed around like any other. A common use of this property is to implement safe, parallel demultiplexing.
In the example in the previous section, handle
was
an idealized handler for a request but we didn't define the
type it was handling. If that type includes a channel on which
to reply, each client can provide its own path for the answer.
Here's a schematic definition of type Request
.
type Request struct { args []int f func([]int) int resultChan chan int }
The client provides a function and its arguments, as well as a channel inside the request object on which to receive the answer.
func sum(a []int) (s int) { for _, v := range a { s += v } return } request := &Request{[]int{3, 4, 5}, sum, make(chan int)} // Send request clientRequests <- request // Wait for response. fmt.Printf("answer: %d\n", <-request.resultChan)
On the server side, the handler function is the only thing that changes.
func handle(queue chan *Request) { for req := range queue { req.resultChan <- req.f(req.args) } }
There's clearly a lot more to do to make it realistic, but this code is a framework for a rate-limited, parallel, non-blocking RPC system, and there's not a mutex in sight.
Another application of these ideas is to parallelize a calculation across multiple CPU cores. If the calculation can be broken into separate pieces that can execute independently, it can be parallelized, with a channel to signal when each piece completes.
Let's say we have an expensive operation to perform on a vector of items, and that the value of the operation on each item is independent, as in this idealized example.
type Vector []float64 // Apply the operation to v[i], v[i+1] ... up to v[n-1]. func (v Vector) DoSome(i, n int, u Vector, c chan int) { for ; i < n; i++ { v[i] += u.Op(v[i]) } c <- 1 // signal that this piece is done }
We launch the pieces independently in a loop, one per CPU. They can complete in any order but it doesn't matter; we just count the completion signals by draining the channel after launching all the goroutines.
const numCPU = 4 // number of CPU cores func (v Vector) DoAll(u Vector) { c := make(chan int, numCPU) // Buffering optional but sensible. for i := 0; i < numCPU; i++ { go v.DoSome(i*len(v)/numCPU, (i+1)*len(v)/numCPU, u, c) } // Drain the channel. for i := 0; i < numCPU; i++ { <-c // wait for one task to complete } // All done. }
Rather than create a constant value for numCPU, we can ask the runtime what
value is appropriate.
The function runtime.NumCPU
returns the number of hardware CPU cores in the machine, so we could write
var numCPU = runtime.NumCPU()
There is also a function
runtime.GOMAXPROCS
,
which reports (or sets)
the user-specified number of cores that a Go program can have running
simultaneously.
It defaults to the value of runtime.NumCPU
but can be
overridden by setting the similarly named shell environment variable
or by calling the function with a positive number. Calling it with
zero just queries the value.
Therefore if we want to honor the user's resource request, we should write
var numCPU = runtime.GOMAXPROCS(0)
Be sure not to confuse the ideas of concurrency—structuring a program as independently executing components—and parallelism—executing calculations in parallel for efficiency on multiple CPUs. Although the concurrency features of Go can make some problems easy to structure as parallel computations, Go is a concurrent language, not a parallel one, and not all parallelization problems fit Go's model. For a discussion of the distinction, see the talk cited in this blog post.
The tools of concurrent programming can even make non-concurrent
ideas easier to express. Here's an example abstracted from an RPC
package. The client goroutine loops receiving data from some source,
perhaps a network. To avoid allocating and freeing buffers, it keeps
a free list, and uses a buffered channel to represent it. If the
channel is empty, a new buffer gets allocated.
Once the message buffer is ready, it's sent to the server on
serverChan
.
var freeList = make(chan *Buffer, 100) var serverChan = make(chan *Buffer) func client() { for { var b *Buffer // Grab a buffer if available; allocate if not. select { case b = <-freeList: // Got one; nothing more to do. default: // None free, so allocate a new one. b = new(Buffer) } load(b) // Read next message from the net. serverChan <- b // Send to server. } }
The server loop receives each message from the client, processes it, and returns the buffer to the free list.
func server() { for { b := <-serverChan // Wait for work. process(b) // Reuse buffer if there's room. select { case freeList <- b: // Buffer on free list; nothing more to do. default: // Free list full, just carry on. } } }
The client attempts to retrieve a buffer from freeList
;
if none is available, it allocates a fresh one.
The server's send to freeList
puts b
back
on the free list unless the list is full, in which case the
buffer is dropped on the floor to be reclaimed by
the garbage collector.
(The default
clauses in the select
statements execute when no other case is ready,
meaning that the selects
never block.)
This implementation builds a leaky bucket free list
in just a few lines, relying on the buffered channel and
the garbage collector for bookkeeping.
Library routines must often return some sort of error indication to
the caller.
As mentioned earlier, Go's multivalue return makes it
easy to return a detailed error description alongside the normal
return value.
It is good style to use this feature to provide detailed error information.
For example, as we'll see, os.Open
doesn't
just return a nil
pointer on failure, it also returns an
error value that describes what went wrong.
By convention, errors have type error
,
a simple built-in interface.
type error interface { Error() string }
A library writer is free to implement this interface with a
richer model under the covers, making it possible not only
to see the error but also to provide some context.
As mentioned, alongside the usual *os.File
return value, os.Open
also returns an
error value.
If the file is opened successfully, the error will be nil
,
but when there is a problem, it will hold an
os.PathError
:
// PathError records an error and the operation and // file path that caused it. type PathError struct { Op string // "open", "unlink", etc. Path string // The associated file. Err error // Returned by the system call. } func (e *PathError) Error() string { return e.Op + " " + e.Path + ": " + e.Err.Error() }
PathError
's Error
generates
a string like this:
open /etc/passwx: no such file or directory
Such an error, which includes the problematic file name, the operation, and the operating system error it triggered, is useful even if printed far from the call that caused it; it is much more informative than the plain "no such file or directory".
When feasible, error strings should identify their origin, such as by having
a prefix naming the operation or package that generated the error. For example, in package
image
, the string representation for a decoding error due to an
unknown format is "image: unknown format".
Callers that care about the precise error details can
use a type switch or a type assertion to look for specific
errors and extract details. For PathErrors
this might include examining the internal Err
field for recoverable failures.
for try := 0; try < 2; try++ { file, err = os.Create(filename) if err == nil { return } if e, ok := err.(*os.PathError); ok && e.Err == syscall.ENOSPC { deleteTempFiles() // Recover some space. continue } return }
The second if
statement here is another type assertion.
If it fails, ok
will be false, and e
will be nil
.
If it succeeds, ok
will be true, which means the
error was of type *os.PathError
, and then so is e
,
which we can examine for more information about the error.
The usual way to report an error to a caller is to return an
error
as an extra return value. The canonical
Read
method is a well-known instance; it returns a byte
count and an error
. But what if the error is
unrecoverable? Sometimes the program simply cannot continue.
For this purpose, there is a built-in function panic
that in effect creates a run-time error that will stop the program
(but see the next section). The function takes a single argument
of arbitrary type—often a string—to be printed as the
program dies. It's also a way to indicate that something impossible has
happened, such as exiting an infinite loop.
// A toy implementation of cube root using Newton's method. func CubeRoot(x float64) float64 { z := x/3 // Arbitrary initial value for i := 0; i < 1e6; i++ { prevz := z z -= (z*z*z-x) / (3*z*z) if veryClose(z, prevz) { return z } } // A million iterations has not converged; something is wrong. panic(fmt.Sprintf("CubeRoot(%g) did not converge", x)) }
This is only an example but real library functions should
avoid panic
. If the problem can be masked or worked
around, it's always better to let things continue to run rather
than taking down the whole program. One possible counterexample
is during initialization: if the library truly cannot set itself up,
it might be reasonable to panic, so to speak.
var user = os.Getenv("USER") func init() { if user == "" { panic("no value for $USER") } }
When panic
is called, including implicitly for run-time
errors such as indexing a slice out of bounds or failing a type
assertion, it immediately stops execution of the current function
and begins unwinding the stack of the goroutine, running any deferred
functions along the way. If that unwinding reaches the top of the
goroutine's stack, the program dies. However, it is possible to
use the built-in function recover
to regain control
of the goroutine and resume normal execution.
A call to recover
stops the unwinding and returns the
argument passed to panic
. Because the only code that
runs while unwinding is inside deferred functions, recover
is only useful inside deferred functions.
One application of recover
is to shut down a failing goroutine
inside a server without killing the other executing goroutines.
func server(workChan <-chan *Work) { for work := range workChan { go safelyDo(work) } } func safelyDo(work *Work) { defer func() { if err := recover(); err != nil { log.Println("work failed:", err) } }() do(work) }
In this example, if do(work)
panics, the result will be
logged and the goroutine will exit cleanly without disturbing the
others. There's no need to do anything else in the deferred closure;
calling recover
handles the condition completely.
Because recover
always returns nil
unless called directly
from a deferred function, deferred code can call library routines that themselves
use panic
and recover
without failing. As an example,
the deferred function in safelyDo
might call a logging function before
calling recover
, and that logging code would run unaffected
by the panicking state.
With our recovery pattern in place, the do
function (and anything it calls) can get out of any bad situation
cleanly by calling panic
. We can use that idea to
simplify error handling in complex software. Let's look at an
idealized version of a regexp
package, which reports
parsing errors by calling panic
with a local
error type. Here's the definition of Error
,
an error
method, and the Compile
function.
// Error is the type of a parse error; it satisfies the error interface. type Error string func (e Error) Error() string { return string(e) } // error is a method of *Regexp that reports parsing errors by // panicking with an Error. func (regexp *Regexp) error(err string) { panic(Error(err)) } // Compile returns a parsed representation of the regular expression. func Compile(str string) (regexp *Regexp, err error) { regexp = new(Regexp) // doParse will panic if there is a parse error. defer func() { if e := recover(); e != nil { regexp = nil // Clear return value. err = e.(Error) // Will re-panic if not a parse error. } }() return regexp.doParse(str), nil }
If doParse
panics, the recovery block will set the
return value to nil
—deferred functions can modify
named return values. It will then check, in the assignment
to err
, that the problem was a parse error by asserting
that it has the local type Error
.
If it does not, the type assertion will fail, causing a run-time error
that continues the stack unwinding as though nothing had interrupted
it.
This check means that if something unexpected happens, such
as an index out of bounds, the code will fail even though we
are using panic
and recover
to handle
parse errors.
With error handling in place, the error
method (because it's a
method bound to a type, it's fine, even natural, for it to have the same name
as the builtin error
type)
makes it easy to report parse errors without worrying about unwinding
the parse stack by hand:
if pos == 0 { re.error("'*' illegal at start of expression") }
Useful though this pattern is, it should be used only within a package.
Parse
turns its internal panic
calls into
error
values; it does not expose panics
to its client. That is a good rule to follow.
By the way, this re-panic idiom changes the panic value if an actual error occurs. However, both the original and new failures will be presented in the crash report, so the root cause of the problem will still be visible. Thus this simple re-panic approach is usually sufficient—it's a crash after all—but if you want to display only the original value, you can write a little more code to filter unexpected problems and re-panic with the original error. That's left as an exercise for the reader.
Let's finish with a complete Go program, a web server.
This one is actually a kind of web re-server.
Google provides a service at chart.apis.google.com
that does automatic formatting of data into charts and graphs.
It's hard to use interactively, though,
because you need to put the data into the URL as a query.
The program here provides a nicer interface to one form of data: given a short piece of text,
it calls on the chart server to produce a QR code, a matrix of boxes that encode the
text.
That image can be grabbed with your cell phone's camera and interpreted as,
for instance, a URL, saving you typing the URL into the phone's tiny keyboard.
Here's the complete program. An explanation follows.
{{code "/doc/progs/eff_qr.go" `/package/` `$`}}
The pieces up to main
should be easy to follow.
The one flag sets a default HTTP port for our server. The template
variable templ
is where the fun happens. It builds an HTML template
that will be executed by the server to display the page; more about
that in a moment.
The main
function parses the flags and, using the mechanism
we talked about above, binds the function QR
to the root path
for the server. Then http.ListenAndServe
is called to start the
server; it blocks while the server runs.
QR
just receives the request, which contains form data, and
executes the template on the data in the form value named s
.
The template package html/template
is powerful;
this program just touches on its capabilities.
In essence, it rewrites a piece of HTML text on the fly by substituting elements derived
from data items passed to templ.Execute
, in this case the
form value.
Within the template text (templateStr
),
double-brace-delimited pieces denote template actions.
The piece from {{html "{{if .}}"}}
to {{html "{{end}}"}}
executes only if the value of the current data item, called .
(dot),
is non-empty.
That is, when the string is empty, this piece of the template is suppressed.
The two snippets {{html "{{.}}"}}
say to show the data presented to
the template—the query string—on the web page.
The HTML template package automatically provides appropriate escaping so the
text is safe to display.
The rest of the template string is just the HTML to show when the page loads. If this is too quick an explanation, see the documentation for the template package for a more thorough discussion.
And there you have it: a useful web server in a few lines of code plus some data-driven HTML text. Go is powerful enough to make a lot happen in a few lines.