1// Copyright 2011 The Go Authors. All rights reserved.
2// Use of this source code is governed by a BSD-style
3// license that can be found in the LICENSE file.
4
5/*
6	Package builtin provides documentation for Go's predeclared identifiers.
7	The items documented here are not actually in package builtin
8	but their descriptions here allow godoc to present documentation
9	for the language's special identifiers.
10*/
11package builtin
12
13// bool is the set of boolean values, true and false.
14type bool bool
15
16// true and false are the two untyped boolean values.
17const (
18	true  = 0 == 0 // Untyped bool.
19	false = 0 != 0 // Untyped bool.
20)
21
22// uint8 is the set of all unsigned 8-bit integers.
23// Range: 0 through 255.
24type uint8 uint8
25
26// uint16 is the set of all unsigned 16-bit integers.
27// Range: 0 through 65535.
28type uint16 uint16
29
30// uint32 is the set of all unsigned 32-bit integers.
31// Range: 0 through 4294967295.
32type uint32 uint32
33
34// uint64 is the set of all unsigned 64-bit integers.
35// Range: 0 through 18446744073709551615.
36type uint64 uint64
37
38// int8 is the set of all signed 8-bit integers.
39// Range: -128 through 127.
40type int8 int8
41
42// int16 is the set of all signed 16-bit integers.
43// Range: -32768 through 32767.
44type int16 int16
45
46// int32 is the set of all signed 32-bit integers.
47// Range: -2147483648 through 2147483647.
48type int32 int32
49
50// int64 is the set of all signed 64-bit integers.
51// Range: -9223372036854775808 through 9223372036854775807.
52type int64 int64
53
54// float32 is the set of all IEEE-754 32-bit floating-point numbers.
55type float32 float32
56
57// float64 is the set of all IEEE-754 64-bit floating-point numbers.
58type float64 float64
59
60// complex64 is the set of all complex numbers with float32 real and
61// imaginary parts.
62type complex64 complex64
63
64// complex128 is the set of all complex numbers with float64 real and
65// imaginary parts.
66type complex128 complex128
67
68// string is the set of all strings of 8-bit bytes, conventionally but not
69// necessarily representing UTF-8-encoded text. A string may be empty, but
70// not nil. Values of string type are immutable.
71type string string
72
73// int is a signed integer type that is at least 32 bits in size. It is a
74// distinct type, however, and not an alias for, say, int32.
75type int int
76
77// uint is an unsigned integer type that is at least 32 bits in size. It is a
78// distinct type, however, and not an alias for, say, uint32.
79type uint uint
80
81// uintptr is an integer type that is large enough to hold the bit pattern of
82// any pointer.
83type uintptr uintptr
84
85// byte is an alias for uint8 and is equivalent to uint8 in all ways. It is
86// used, by convention, to distinguish byte values from 8-bit unsigned
87// integer values.
88type byte = uint8
89
90// rune is an alias for int32 and is equivalent to int32 in all ways. It is
91// used, by convention, to distinguish character values from integer values.
92type rune = int32
93
94// iota is a predeclared identifier representing the untyped integer ordinal
95// number of the current const specification in a (usually parenthesized)
96// const declaration. It is zero-indexed.
97const iota = 0 // Untyped int.
98
99// nil is a predeclared identifier representing the zero value for a
100// pointer, channel, func, interface, map, or slice type.
101var nil Type // Type must be a pointer, channel, func, interface, map, or slice type
102
103// Type is here for the purposes of documentation only. It is a stand-in
104// for any Go type, but represents the same type for any given function
105// invocation.
106type Type int
107
108// Type1 is here for the purposes of documentation only. It is a stand-in
109// for any Go type, but represents the same type for any given function
110// invocation.
111type Type1 int
112
113// IntegerType is here for the purposes of documentation only. It is a stand-in
114// for any integer type: int, uint, int8 etc.
115type IntegerType int
116
117// FloatType is here for the purposes of documentation only. It is a stand-in
118// for either float type: float32 or float64.
119type FloatType float32
120
121// ComplexType is here for the purposes of documentation only. It is a
122// stand-in for either complex type: complex64 or complex128.
123type ComplexType complex64
124
125// The append built-in function appends elements to the end of a slice. If
126// it has sufficient capacity, the destination is resliced to accommodate the
127// new elements. If it does not, a new underlying array will be allocated.
128// Append returns the updated slice. It is therefore necessary to store the
129// result of append, often in the variable holding the slice itself:
130//	slice = append(slice, elem1, elem2)
131//	slice = append(slice, anotherSlice...)
132// As a special case, it is legal to append a string to a byte slice, like this:
133//	slice = append([]byte("hello "), "world"...)
134func append(slice []Type, elems ...Type) []Type
135
136// The copy built-in function copies elements from a source slice into a
137// destination slice. (As a special case, it also will copy bytes from a
138// string to a slice of bytes.) The source and destination may overlap. Copy
139// returns the number of elements copied, which will be the minimum of
140// len(src) and len(dst).
141func copy(dst, src []Type) int
142
143// The delete built-in function deletes the element with the specified key
144// (m[key]) from the map. If m is nil or there is no such element, delete
145// is a no-op.
146func delete(m map[Type]Type1, key Type)
147
148// The len built-in function returns the length of v, according to its type:
149//	Array: the number of elements in v.
150//	Pointer to array: the number of elements in *v (even if v is nil).
151//	Slice, or map: the number of elements in v; if v is nil, len(v) is zero.
152//	String: the number of bytes in v.
153//	Channel: the number of elements queued (unread) in the channel buffer;
154//	         if v is nil, len(v) is zero.
155// For some arguments, such as a string literal or a simple array expression, the
156// result can be a constant. See the Go language specification's "Length and
157// capacity" section for details.
158func len(v Type) int
159
160// The cap built-in function returns the capacity of v, according to its type:
161//	Array: the number of elements in v (same as len(v)).
162//	Pointer to array: the number of elements in *v (same as len(v)).
163//	Slice: the maximum length the slice can reach when resliced;
164//	if v is nil, cap(v) is zero.
165//	Channel: the channel buffer capacity, in units of elements;
166//	if v is nil, cap(v) is zero.
167// For some arguments, such as a simple array expression, the result can be a
168// constant. See the Go language specification's "Length and capacity" section for
169// details.
170func cap(v Type) int
171
172// The make built-in function allocates and initializes an object of type
173// slice, map, or chan (only). Like new, the first argument is a type, not a
174// value. Unlike new, make's return type is the same as the type of its
175// argument, not a pointer to it. The specification of the result depends on
176// the type:
177//	Slice: The size specifies the length. The capacity of the slice is
178//	equal to its length. A second integer argument may be provided to
179//	specify a different capacity; it must be no smaller than the
180//	length. For example, make([]int, 0, 10) allocates an underlying array
181//	of size 10 and returns a slice of length 0 and capacity 10 that is
182//	backed by this underlying array.
183//	Map: An empty map is allocated with enough space to hold the
184//	specified number of elements. The size may be omitted, in which case
185//	a small starting size is allocated.
186//	Channel: The channel's buffer is initialized with the specified
187//	buffer capacity. If zero, or the size is omitted, the channel is
188//	unbuffered.
189func make(t Type, size ...IntegerType) Type
190
191// The new built-in function allocates memory. The first argument is a type,
192// not a value, and the value returned is a pointer to a newly
193// allocated zero value of that type.
194func new(Type) *Type
195
196// The complex built-in function constructs a complex value from two
197// floating-point values. The real and imaginary parts must be of the same
198// size, either float32 or float64 (or assignable to them), and the return
199// value will be the corresponding complex type (complex64 for float32,
200// complex128 for float64).
201func complex(r, i FloatType) ComplexType
202
203// The real built-in function returns the real part of the complex number c.
204// The return value will be floating point type corresponding to the type of c.
205func real(c ComplexType) FloatType
206
207// The imag built-in function returns the imaginary part of the complex
208// number c. The return value will be floating point type corresponding to
209// the type of c.
210func imag(c ComplexType) FloatType
211
212// The close built-in function closes a channel, which must be either
213// bidirectional or send-only. It should be executed only by the sender,
214// never the receiver, and has the effect of shutting down the channel after
215// the last sent value is received. After the last value has been received
216// from a closed channel c, any receive from c will succeed without
217// blocking, returning the zero value for the channel element. The form
218//	x, ok := <-c
219// will also set ok to false for a closed channel.
220func close(c chan<- Type)
221
222// The panic built-in function stops normal execution of the current
223// goroutine. When a function F calls panic, normal execution of F stops
224// immediately. Any functions whose execution was deferred by F are run in
225// the usual way, and then F returns to its caller. To the caller G, the
226// invocation of F then behaves like a call to panic, terminating G's
227// execution and running any deferred functions. This continues until all
228// functions in the executing goroutine have stopped, in reverse order. At
229// that point, the program is terminated with a non-zero exit code. This
230// termination sequence is called panicking and can be controlled by the
231// built-in function recover.
232func panic(v interface{})
233
234// The recover built-in function allows a program to manage behavior of a
235// panicking goroutine. Executing a call to recover inside a deferred
236// function (but not any function called by it) stops the panicking sequence
237// by restoring normal execution and retrieves the error value passed to the
238// call of panic. If recover is called outside the deferred function it will
239// not stop a panicking sequence. In this case, or when the goroutine is not
240// panicking, or if the argument supplied to panic was nil, recover returns
241// nil. Thus the return value from recover reports whether the goroutine is
242// panicking.
243func recover() interface{}
244
245// The print built-in function formats its arguments in an
246// implementation-specific way and writes the result to standard error.
247// Print is useful for bootstrapping and debugging; it is not guaranteed
248// to stay in the language.
249func print(args ...Type)
250
251// The println built-in function formats its arguments in an
252// implementation-specific way and writes the result to standard error.
253// Spaces are always added between arguments and a newline is appended.
254// Println is useful for bootstrapping and debugging; it is not guaranteed
255// to stay in the language.
256func println(args ...Type)
257
258// The error built-in interface type is the conventional interface for
259// representing an error condition, with the nil value representing no error.
260type error interface {
261	Error() string
262}
263