closes #272
20 KiB
Language Reference
Grammar
Root = many(TopLevelItem) "EOF"
TopLevelItem = ErrorValueDecl | CompTimeExpression | TopLevelDecl | TestDecl
TestDecl = "test" String Block
TopLevelDecl = option(VisibleMod) (FnDef | ExternDecl | GlobalVarDecl | TypeDecl | UseDecl)
TypeDecl = "type" Symbol "=" TypeExpr ";"
ErrorValueDecl = "error" Symbol ";"
GlobalVarDecl = VariableDeclaration ";"
VariableDeclaration = option("comptime") ("var" | "const") Symbol option(":" TypeExpr) "=" Expression
ContainerMember = (ContainerField | FnDef | GlobalVarDecl)
ContainerField = Symbol option(":" Expression) ",")
UseDecl = "use" Expression ";"
ExternDecl = "extern" (FnProto | VariableDeclaration) ";"
FnProto = option("coldcc" | "nakedcc") "fn" option(Symbol) ParamDeclList option("->" TypeExpr)
VisibleMod = "pub" | "export"
FnDef = option("inline" | "extern") FnProto Block
ParamDeclList = "(" list(ParamDecl, ",") ")"
ParamDecl = option("noalias" | "comptime") option(Symbol ":") (TypeExpr | "...")
Block = "{" list(option(Statement), ";") "}"
Statement = Label | VariableDeclaration ";" | Defer ";" | NonBlockExpression ";" | BlockExpression
Label = Symbol ":"
Expression = BlockExpression | NonBlockExpression
TypeExpr = PrefixOpExpression | "var"
NonBlockExpression = ReturnExpression | AssignmentExpression
AsmExpression = "asm" option("volatile") "(" String option(AsmOutput) ")"
AsmOutput = ":" list(AsmOutputItem, ",") option(AsmInput)
AsmInput = ":" list(AsmInputItem, ",") option(AsmClobbers)
AsmOutputItem = "[" Symbol "]" String "(" (Symbol | "->" TypeExpr) ")"
AsmInputItem = "[" Symbol "]" String "(" Expression ")"
AsmClobbers= ":" list(String, ",")
UnwrapExpression = BoolOrExpression (UnwrapMaybe | UnwrapError) | BoolOrExpression
UnwrapMaybe = "??" Expression
UnwrapError = "%%" option("|" Symbol "|") Expression
AssignmentExpression = UnwrapExpression AssignmentOperator UnwrapExpression | UnwrapExpression
AssignmentOperator = "=" | "*=" | "/=" | "%=" | "+=" | "-=" | "<<=" | ">>=" | "&=" | "^=" | "|=" | "*%=" | "+%=" | "-%=" | "<<%="
BlockExpression = IfExpression | Block | WhileExpression | ForExpression | SwitchExpression | CompTimeExpression | TryExpression
CompTimeExpression = option("comptime") Expression
SwitchExpression = "switch" "(" Expression ")" "{" many(SwitchProng) "}"
SwitchProng = (list(SwitchItem, ",") | "else") "=>" option("|" option("*") Symbol "|") Expression ","
SwitchItem = Expression | (Expression "..." Expression)
WhileExpression = option("inline") "while" "(" Expression option(";" Expression) ")" Expression
ForExpression = option("inline") "for" "(" Expression ")" option("|" option("*") Symbol option("," Symbol) "|") Expression
BoolOrExpression = BoolAndExpression "or" BoolOrExpression | BoolAndExpression
ReturnExpression = option("%" | "?") "return" option(Expression)
Defer = option("%" | "?") "defer" Expression
IfExpression = IfVarExpression | IfBoolExpression
IfBoolExpression = "if" "(" Expression ")" Expression option(Else)
TryExpression = "try" "(" option(("const" | "var") option("*") Symbol "=") Expression ")" Expression option("else" option("|" Symbol "|") Expression)
IfVarExpression = "if" "(" ("const" | "var") option("*") Symbol option(":" TypeExpr) "?=" Expression ")" Expression Option(Else)
Else = "else" Expression
BoolAndExpression = ComparisonExpression "and" BoolAndExpression | ComparisonExpression
ComparisonExpression = BinaryOrExpression ComparisonOperator BinaryOrExpression | BinaryOrExpression
ComparisonOperator = "==" | "!=" | "<" | ">" | "<=" | ">="
BinaryOrExpression = BinaryXorExpression "|" BinaryOrExpression | BinaryXorExpression
BinaryXorExpression = BinaryAndExpression "^" BinaryXorExpression | BinaryAndExpression
BinaryAndExpression = BitShiftExpression "&" BinaryAndExpression | BitShiftExpression
BitShiftExpression = AdditionExpression BitShiftOperator BitShiftExpression | AdditionExpression
BitShiftOperator = "<<" | ">>" | "<<%"
AdditionExpression = MultiplyExpression AdditionOperator AdditionExpression | MultiplyExpression
AdditionOperator = "+" | "-" | "++" | "+%" | "-%"
MultiplyExpression = CurlySuffixExpression MultiplyOperator MultiplyExpression | CurlySuffixExpression
CurlySuffixExpression = TypeExpr option(ContainerInitExpression)
MultiplyOperator = "*" | "/" | "%" | "**" | "*%"
PrefixOpExpression = PrefixOp PrefixOpExpression | SuffixOpExpression
SuffixOpExpression = PrimaryExpression option(FnCallExpression | ArrayAccessExpression | FieldAccessExpression | SliceExpression)
FieldAccessExpression = "." Symbol
FnCallExpression = "(" list(Expression, ",") ")"
ArrayAccessExpression = "[" Expression "]"
SliceExpression = "[" Expression "..." option(Expression) "]" option("const")
ContainerInitExpression = "{" ContainerInitBody "}"
ContainerInitBody = list(StructLiteralField, ",") | list(Expression, ",")
StructLiteralField = "." Symbol "=" Expression
PrefixOp = "!" | "-" | "~" | "*" | ("&" option("const") option("volatile")) | "?" | "%" | "%%" | "??" | "-%"
PrimaryExpression = Number | String | CharLiteral | KeywordLiteral | GroupedExpression | GotoExpression | BlockExpression | Symbol | ("@" Symbol FnCallExpression) | ArrayType | (option("extern") FnProto) | AsmExpression | ("error" "." Symbol) | ContainerDecl
ArrayType = "[" option(Expression) "]" option("const") TypeExpr
GotoExpression = "goto" Symbol
GroupedExpression = "(" Expression ")"
KeywordLiteral = "true" | "false" | "null" | "break" | "continue" | "undefined" | "error" | "type" | "this" | "unreachable"
ContainerDecl = option("extern" | "packed") ("struct" | "enum" | "union") "{" many(ContainerMember) "}"
Operator Precedence
x() x[] x.y
!x -x ~x *x &x ?x %x %%x
x{}
* / %
+ - ++
<< >>
&
^
|
== != < > <= >=
&&
||
?? %%
= *= /= %= += -= <<= >>= &= ^= |= &&= ||=
Types
Numeric Types
Type name C equivalent Description
i8 int8_t signed 8-bit integer
u8 uint8_t unsigned 8-bit integer
i16 int16_t signed 16-bit integer
u16 uint16_t unsigned 16-bit integer
i32 int32_t signed 32-bit integer
u32 uint32_t unsigned 32-bit integer
i64 int64_t signed 64-bit integer
u64 uint64_t unsigned 64-bit integer
isize intptr_t signed pointer sized integer
usize uintptr_t unsigned pointer sized integer
c_short short for ABI compatibility with C
c_ushort unsigned short for ABI compatibility with C
c_int int for ABI compatibility with C
c_uint unsigned int for ABI compatibility with C
c_long long for ABI compatibility with C
c_ulong unsigned long for ABI compatibility with C
c_longlong long long for ABI compatibility with C
c_ulonglong unsigned long long for ABI compatibility with C
c_long_double long double for ABI compatibility with C
c_void void for ABI compatibility with C
f32 float 32-bit floating point
f64 double 64-bit floating point
Expressions
Literals
Character and String Literals
Literal Example Characters Escapes Null Term Type
Byte 'H' All ASCII Byte No u8
UTF-8 Bytes "hello" All Unicode Byte & Unicode No [5]u8
UTF-8 C string c"hello" All Unicode Byte & Unicode Yes &const u8
Escapes
Escape | Name |
---|---|
\n | Newline |
\r | Carriage Return |
\t | Tab |
\ | Backslash |
' | Single Quote |
" | Double Quote |
\xNN | hexadecimal 8-bit character code (2 digits) |
\uNNNN | hexadecimal 16-bit Unicode character code UTF-8 encoded (4 digits) |
\UNNNNNN | hexadecimal 24-bit Unicode character code UTF-8 encoded (6 digits) |
Note that the maximum valid Unicode point is 0x10ffff.
Multiline String Literals
Multiline string literals have no escapes and can span across multiple lines.
To start a multiline string literal, use the \\
token. Just like a comment,
the string literal goes until the end of the line. The end of the line is not
included in the string literal.
However, if the next line begins with \\
then a newline is appended and
the string literal continues.
Example:
const hello_world_in_c =
\\#include <stdio.h>
\\
\\int main(int argc, char **argv) {
\\ printf("hello world\n");
\\ return 0;
\\}
;
For a multiline C string literal, prepend c
to each \\
. Example:
const c_string_literal =
c\\#include <stdio.h>
c\\
c\\int main(int argc, char **argv) {
c\\ printf("hello world\n");
c\\ return 0;
c\\}
;
In this example the variable c_string_literal
has type &const char
and
has a terminating null byte.
Number Literals
Number literals | Example | Exponentiation |
---|---|---|
Decimal integer | 98222 | N/A |
Hex integer | 0xff | N/A |
Octal integer | 0o77 | N/A |
Binary integer | 0b11110000 | N/A |
Floating point | 123.0E+77 | Optional |
Hex floating point | 0x103.70p-5 | Optional |
Built-in Functions
Built-in functions are prefixed with @
. Remember that the comptime
keyword on
a parameter means that the parameter must be known at compile time.
@alloca(comptime T: type, count: usize) -> []T
Allocates memory in the stack frame of the caller. This temporary space is automatically freed when the function that called alloca returns to its caller, just like other stack variables.
When using this function to allocate memory, you should know the upper bound
of count
. Consider putting a constant array on the stack with the upper bound
instead of using alloca. If you do use alloca it is to save a few bytes off
the memory size given that you didn't actually hit your upper bound.
The allocated memory contents are undefined.
@typeOf(expression) -> type
This function returns a compile-time constant, which is the type of the expression passed as an argument. The expression is not evaluated.
@sizeOf(comptime T: type) -> (number literal)
This function returns the number of bytes it takes to store T in memory.
The result is a target-specific compile time constant.
@alignOf(comptime T: type) -> (number literal)
This function returns the number of bytes that this type should be aligned to for the current target.
The result is a target-specific compile time constant.
Overflow Arithmetic
These functions take an integer type, two variables of the specified type, and a pointer to memory of the specified type where the result is stored.
The functions return a boolean value: true if overflow or underflow occurred, false otherwise.
Function Operation
@addWithOverflow(comptime T: type, a: T, b: T, result: &T) -> bool *x = a + b
@subWithOverflow(comptime T: type, a: T, b: T, result: &T) -> bool *x = a - b
@mulWithOverflow(comptime T: type, a: T, b: T, result: &T) -> bool *x = a * b
@shlWithOverflow(comptime T: type, a: T, b: T, result: &T) -> bool *x = a << b
@memset(dest: &u8, c: u8, byte_count: usize)
This function sets a region of memory to c
. dest
is a pointer.
This function is a low level intrinsic with no safety mechanisms. Most higher level code will not use this function, instead using something like this:
for (destSlice) |*b| *b = c;
The optimizer is intelligent enough to turn the above snippet into a memset.
@memcpy(noalias dest: &u8, noalias source: &const u8, byte_count: usize)
This function copies bytes from one region of memory to another. dest
and
source
are both pointers and must not overlap.
This function is a low level intrinsic with no safety mechanisms. Most higher level code will not use this function, instead using something like this:
const mem = @import("std").mem;
mem.copy(destSlice, sourceSlice);
The optimizer is intelligent enough to turn the above snippet into a memcpy.
@breakpoint()
This function inserts a platform-specific debug trap instruction which causes debuggers to break there.
This function is only valid within function scope.
@returnAddress()
This function returns a pointer to the return address of the current stack frame.
The implications of this are target specific and not consistent across all platforms.
This function is only valid within function scope.
@frameAddress()
This function returns the base pointer of the current stack frame.
The implications of this are target specific and not consistent across all platforms. The frame address may not be available in release mode due to aggressive optimizations.
This function is only valid within function scope.
@maxValue(comptime T: type) -> (number literal)
This function returns the maximum integer value of the integer type T.
The result is a compile time constant. For some types such as c_long
, the
result is marked as depending on a compile variable.
@minValue(comptime T: type) -> (number literal)
This function returns the minimum integer value of the integer type T.
The result is a compile time constant. For some types such as c_long
, the
result is marked as depending on a compile variable.
@memberCount(comptime T: type) -> (number literal)
This function returns the number of enum values in an enum type.
The result is a compile time constant.
@import(comptime path: []u8) -> (namespace)
This function finds a zig file corresponding to path
and imports all the
public top level declarations into the resulting namespace.
path
can be a relative or absolute path, or it can be the name of a package,
such as "std".
This function is only valid at top level scope.
@cImport(expression) -> (namespace)
This function parses C code and imports the functions, types, variables, and compatible macro definitions into the result namespace.
expression
is interpreted at compile time. The builtin functions
@c_include
, @c_define
, and @c_undef
work within this expression,
appending to a temporary buffer which is then parsed as C code.
This function is only valid at top level scope.
@cInclude(comptime path: []u8)
This function can only occur inside @c_import
.
This appends #include <$path>\n
to the c_import
temporary buffer.
@cDefine(comptime name: []u8, value)
This function can only occur inside @c_import
.
This appends #define $name $value
to the c_import
temporary buffer.
@cUndef(comptime name: []u8)
This function can only occur inside @c_import
.
This appends #undef $name
to the c_import
temporary buffer.
@compileVar(comptime name: []u8) -> (varying type)
This function returns a compile-time variable. There are built in compile variables:
- "is_big_endian"
bool
- eithertrue
for big endian orfalse
for little endian. - "is_release"
bool
- eithertrue
for release mode builds orfalse
for debug mode builds. - "is_test"
bool
- eithertrue
for test builds orfalse
otherwise. - "os"
Os
- usezig targets
to see what enum values are possible here. - "arch"
Arch
- usezig targets
to see what enum values are possible here. - "environ"
Environ
- usezig targets
to see what enum values are possible here.
Build scripts can set additional compile variables of any name and type.
The result of this function is a compile time constant that is marked as depending on a compile variable.
@generatedCode(expression) -> @typeOf(expression)
This function wraps an expression and returns the result of the expression unmodified.
Inside the expression, code is considered generated, which means that the following compile errors are disabled:
- unnecessary if statement error
The result of the expression is marked as depending on a compile variable.
@ctz(x: T) -> T
This function counts the number of trailing zeroes in x which is an integer type T.
@clz(x: T) -> T
This function counts the number of leading zeroes in x which is an integer type T.
@errorName(err: error) -> []u8
This function returns the string representation of an error. If an error declaration is:
error OutOfMem;
Then the string representation is "OutOfMem".
If there are no calls to @errorName
in an entire application, then no error
name table will be generated.
@typeName(T: type) -> []u8
This function returns the string representation of a type.
@embedFile(comptime path: []u8) -> [X]u8
This function returns a compile time constant fixed-size array with length
equal to the byte count of the file given by path
. The contents of the array
are the contents of the file.
@cmpxchg(ptr: &T, cmp: T, new: T, success_order: MemoryOrder, fail_order: MemoryOrder) -> bool
This function performs an atomic compare exchange operation.
@fence(order: MemoryOrder)
The fence
function is used to introduce happens-before edges between operations.
@divExact(a: T, b: T) -> T
This function performs integer division a / b
and returns the result.
The caller guarantees that this operation will have no remainder.
In debug mode, a remainder causes a panic. In release mode, a remainder is undefined behavior.
@truncate(comptime T: type, integer) -> T
This function truncates bits from an integer type, resulting in a smaller integer type.
The following produces a crash in debug mode and undefined behavior in release mode:
const a: u16 = 0xabcd;
const b: u8 = u8(a);
However this is well defined and working code:
const a: u16 = 0xabcd;
const b: u8 = @truncate(u8, a);
// b is now 0xcd
This function always truncates the significant bits of the integer, regardless of endianness on the target platform.
This function also performs a twos complement cast. For example, the following produces a crash in debug mode and undefined behavior in release mode:
const a = i16(-1);
const b = u16(a);
However this is well defined and working code:
const a = i16(-1);
const b = @truncate(u16, a);
// b is now 0xffff
@compileError(comptime msg: []u8)
This function, when semantically analyzed, causes a compile error with the
message msg
.
There are several ways that code avoids being semantically checked, such as
using if
or switch
with compile time constants, and comptime functions.
@compileLog(args: ...)
This function, when semantically analyzed, causes a compile error, but it does not prevent compile-time code from continuing to run, and it otherwise does not interfere with analysis.
Each of the arguments will be serialized to a printable debug value and output to stderr, and then a newline at the end.
This function can be used to do "printf debugging" on compile-time executing code.
@intType(comptime is_signed: bool, comptime bit_count: u8) -> type
This function returns an integer type with the given signness and bit count.
@setDebugSafety(scope, safety_on: bool)
Sets a whether we want debug safety checks on for a given scope.
@isInteger(comptime T: type) -> bool
Returns whether a given type is an integer.
@isFloat(comptime T: type) -> bool
Returns whether a given type is a float.
@canImplicitCast(comptime T: type, value) -> bool
Returns whether a value can be implicitly casted to a given type.
@setGlobalAlign(global_variable_name, byte_count: usize) -> bool
Sets the alignment property of a global variable.
@setGlobalSection(global_variable_name, section_name: []u8) -> bool
Puts the global variable in the specified section.