diff --git a/src/data/0.10.1.zig b/src/data/0.10.1.zig new file mode 100644 index 0000000..57745c2 --- /dev/null +++ b/src/data/0.10.1.zig @@ -0,0 +1,2066 @@ +//! DO NOT EDIT +//! If you want to update this file run: +//! `zig build gen -- --generate-version-data 0.10.1` (requires an internet connection) +//! GENERATED BY src/config_gen/config_gen.zig + +const Builtin = struct { + name: []const u8, + signature: []const u8, + snippet: []const u8, + documentation: []const u8, + arguments: []const []const u8, +}; + +pub const builtins = [_]Builtin{ + .{ + .name = "@addrSpaceCast", + .signature = "@addrSpaceCast(comptime addrspace: std.builtin.AddressSpace, ptr: anytype) anytype", + .snippet = "@addrSpaceCast(${1:comptime addrspace: std.builtin.AddressSpace}, ${2:ptr: anytype})", + .documentation = + \\Converts a pointer from one address space to another. Depending on the current target and address spaces, this cast may be a no-op, a complex operation, or illegal. If the cast is legal, then the resulting pointer points to the same memory location as the pointer operand. It is always valid to cast a pointer between the same address spaces. + , + .arguments = &.{ + "comptime addrspace: std.builtin.AddressSpace", + "ptr: anytype", + }, + }, + .{ + .name = "@addWithOverflow", + .signature = "@addWithOverflow(comptime T: type, a: T, b: T, result: *T) bool", + .snippet = "@addWithOverflow(${1:comptime T: type}, ${2:a: T}, ${3:b: T}, ${4:result: *T})", + .documentation = + \\Performs `result.* = a + b`. If overflow or underflow occurs, stores the overflowed bits in `result` and returns `true`. If no overflow or underflow occurs, returns `false`. + , + .arguments = &.{ + "comptime T: type", + "a: T", + "b: T", + "result: *T", + }, + }, + .{ + .name = "@alignCast", + .signature = "@alignCast(comptime alignment: u29, ptr: anytype) anytype", + .snippet = "@alignCast(${1:comptime alignment: u29}, ${2:ptr: anytype})", + .documentation = + \\`ptr` can be `*T`, `?*T`, or `[]T`. It returns the same type as `ptr` except with the alignment adjusted to the new value. + \\ + \\A [pointer alignment safety check](https://ziglang.org/documentation/0.10.1/#Incorrect-Pointer-Alignment) is added to the generated code to make sure the pointer is aligned as promised. + , + .arguments = &.{ + "comptime alignment: u29", + "ptr: anytype", + }, + }, + .{ + .name = "@alignOf", + .signature = "@alignOf(comptime T: type) comptime_int", + .snippet = "@alignOf(${1:comptime T: type})", + .documentation = + \\This function returns the number of bytes that this type should be aligned to for the current target to match the C ABI. When the child type of a pointer has this alignment, the alignment can be omitted from the type. + \\ + \\```zig + \\const assert = @import("std").debug.assert; + \\comptime { + \\ assert(*u32 == *align(@alignOf(u32)) u32); + \\} + \\``` + \\The result is a target-specific compile time constant. It is guaranteed to be less than or equal to [@sizeOf(T)](https://ziglang.org/documentation/0.10.1/#sizeOf). + , + .arguments = &.{ + "comptime T: type", + }, + }, + .{ + .name = "@as", + .signature = "@as(comptime T: type, expression) T", + .snippet = "@as(${1:comptime T: type}, ${2:expression})", + .documentation = + \\Performs [Type Coercion](https://ziglang.org/documentation/0.10.1/#Type-Coercion). This cast is allowed when the conversion is unambiguous and safe, and is the preferred way to convert between types, whenever possible. + , + .arguments = &.{ + "comptime T: type", + "expression", + }, + }, + .{ + .name = "@asyncCall", + .signature = "@asyncCall(frame_buffer: []align(@alignOf(@Frame(anyAsyncFunction))) u8, result_ptr, function_ptr, args: anytype) anyframe->T", + .snippet = "@asyncCall(${1:frame_buffer: []align(@alignOf(@Frame(anyAsyncFunction)})", + .documentation = + \\`@asyncCall` performs an `async` call on a function pointer, which may or may not be an [async function](https://ziglang.org/documentation/0.10.1/#Async-Functions). + \\ + \\The provided `frame_buffer` must be large enough to fit the entire function frame. This size can be determined with [@frameSize](https://ziglang.org/documentation/0.10.1/#frameSize). To provide a too-small buffer invokes safety-checked [Undefined Behavior](https://ziglang.org/documentation/0.10.1/#Undefined-Behavior). + \\ + \\`result_ptr` is optional ([null](https://ziglang.org/documentation/0.10.1/#null) may be provided). If provided, the function call will write its result directly to the result pointer, which will be available to read after [await](https://ziglang.org/documentation/0.10.1/#Async-and-Await) completes. Any result location provided to `await` will copy the result from `result_ptr`. + \\ + \\```zig + \\const std = @import("std"); + \\const expect = std.testing.expect; + \\test "async fn pointer in a struct field" { + \\ var data: i32 = 1; + \\ const Foo = struct { + \\ bar: fn (*i32) callconv(.Async) void, + \\ }; + \\ var foo = Foo{ .bar = func }; + \\ var bytes: [64]u8 align(@alignOf(@Frame(func))) = undefined; + \\ const f = @asyncCall(&bytes, {}, foo.bar, .{&data}); + \\ try expect(data == 2); + \\ resume f; + \\ try expect(data == 4); + \\} + \\fn func(y: *i32) void { + \\ defer y.* += 2; + \\ y.* += 1; + \\ suspend {} + \\} + \\``` + , + .arguments = &.{ + "frame_buffer: []align(@alignOf(@Frame(anyAsyncFunction)", + }, + }, + .{ + .name = "@atomicLoad", + .signature = "@atomicLoad(comptime T: type, ptr: *const T, comptime ordering: builtin.AtomicOrder) T", + .snippet = "@atomicLoad(${1:comptime T: type}, ${2:ptr: *const T}, ${3:comptime ordering: builtin.AtomicOrder})", + .documentation = + \\This builtin function atomically dereferences a pointer and returns the value. + \\ + \\`T` must be a pointer, a `bool`, a float, an integer or an enum. + , + .arguments = &.{ + "comptime T: type", + "ptr: *const T", + "comptime ordering: builtin.AtomicOrder", + }, + }, + .{ + .name = "@atomicRmw", + .signature = "@atomicRmw(comptime T: type, ptr: *T, comptime op: builtin.AtomicRmwOp, operand: T, comptime ordering: builtin.AtomicOrder) T", + .snippet = "@atomicRmw(${1:comptime T: type}, ${2:ptr: *T}, ${3:comptime op: builtin.AtomicRmwOp}, ${4:operand: T}, ${5:comptime ordering: builtin.AtomicOrder})", + .documentation = + \\This builtin function atomically modifies memory and then returns the previous value. + \\ + \\`T` must be a pointer, a `bool`, a float, an integer or an enum. + \\ + \\Supported operations: + \\ + \\ - `.Xchg` - stores the operand unmodified. Supports enums, integers and floats. + \\ - `.Add` - for integers, twos complement wraparound addition. Also supports [Floats](https://ziglang.org/documentation/0.10.1/#Floats). + \\ - `.Sub` - for integers, twos complement wraparound subtraction. Also supports [Floats](https://ziglang.org/documentation/0.10.1/#Floats). + \\ - `.And` - bitwise and + \\ - `.Nand` - bitwise nand + \\ - `.Or` - bitwise or + \\ - `.Xor` - bitwise xor + \\ - `.Max` - stores the operand if it is larger. Supports integers and floats. + \\ - `.Min` - stores the operand if it is smaller. Supports integers and floats. + , + .arguments = &.{ + "comptime T: type", + "ptr: *T", + "comptime op: builtin.AtomicRmwOp", + "operand: T", + "comptime ordering: builtin.AtomicOrder", + }, + }, + .{ + .name = "@atomicStore", + .signature = "@atomicStore(comptime T: type, ptr: *T, value: T, comptime ordering: builtin.AtomicOrder) void", + .snippet = "@atomicStore(${1:comptime T: type}, ${2:ptr: *T}, ${3:value: T}, ${4:comptime ordering: builtin.AtomicOrder})", + .documentation = + \\This builtin function atomically stores a value. + \\ + \\`T` must be a pointer, a `bool`, a float, an integer or an enum. + , + .arguments = &.{ + "comptime T: type", + "ptr: *T", + "value: T", + "comptime ordering: builtin.AtomicOrder", + }, + }, + .{ + .name = "@bitCast", + .signature = "@bitCast(comptime DestType: type, value: anytype) DestType", + .snippet = "@bitCast(${1:comptime DestType: type}, ${2:value: anytype})", + .documentation = + \\Converts a value of one type to another type. + \\ + \\Asserts that `@sizeOf(@TypeOf(value)) == @sizeOf(DestType)`. + \\ + \\Asserts that `@typeInfo(DestType) != .Pointer`. Use `@ptrCast` or `@intToPtr` if you need this. + \\ + \\Can be used for these things for example: + \\ + \\ - Convert `f32` to `u32` bits + \\ - Convert `i32` to `u32` preserving twos complement + \\Works at compile-time if `value` is known at compile time. It's a compile error to bitcast a value of undefined layout; this means that, besides the restriction from types which possess dedicated casting builtins (enums, pointers, error sets), bare structs, error unions, slices, optionals, and any other type without a well-defined memory layout, also cannot be used in this operation. + , + .arguments = &.{ + "comptime DestType: type", + "value: anytype", + }, + }, + .{ + .name = "@bitOffsetOf", + .signature = "@bitOffsetOf(comptime T: type, comptime field_name: []const u8) comptime_int", + .snippet = "@bitOffsetOf(${1:comptime T: type}, ${2:comptime field_name: []const u8})", + .documentation = + \\Returns the bit offset of a field relative to its containing struct. + \\ + \\For non [packed structs](https://ziglang.org/documentation/0.10.1/#packed-struct), this will always be divisible by `8`. For packed structs, non-byte-aligned fields will share a byte offset, but they will have different bit offsets. + , + .arguments = &.{ + "comptime T: type", + "comptime field_name: []const u8", + }, + }, + .{ + .name = "@boolToInt", + .signature = "@boolToInt(value: bool) u1", + .snippet = "@boolToInt(${1:value: bool})", + .documentation = + \\Converts `true` to `@as(u1, 1)` and `false` to `@as(u1, 0)`. + \\ + \\If the value is known at compile-time, the return type is `comptime_int` instead of `u1`. + , + .arguments = &.{ + "value: bool", + }, + }, + .{ + .name = "@bitSizeOf", + .signature = "@bitSizeOf(comptime T: type) comptime_int", + .snippet = "@bitSizeOf(${1:comptime T: type})", + .documentation = + \\This function returns the number of bits it takes to store `T` in memory if the type were a field in a packed struct/union. The result is a target-specific compile time constant. + \\ + \\This function measures the size at runtime. For types that are disallowed at runtime, such as `comptime_int` and `type`, the result is `0`. + , + .arguments = &.{ + "comptime T: type", + }, + }, + .{ + .name = "@breakpoint", + .signature = "@breakpoint()", + .snippet = "@breakpoint()", + .documentation = + \\This function inserts a platform-specific debug trap instruction which causes debuggers to break there. + \\ + \\This function is only valid within function scope. + , + .arguments = &.{}, + }, + .{ + .name = "@mulAdd", + .signature = "@mulAdd(comptime T: type, a: T, b: T, c: T) T", + .snippet = "@mulAdd(${1:comptime T: type}, ${2:a: T}, ${3:b: T}, ${4:c: T})", + .documentation = + \\Fused multiply-add, similar to `(a * b) + c`, except only rounds once, and is thus more accurate. + \\ + \\Supports [Floats](https://ziglang.org/documentation/0.10.1/#Floats) and [Vectors](https://ziglang.org/documentation/0.10.1/#Vectors) of floats. + , + .arguments = &.{ + "comptime T: type", + "a: T", + "b: T", + "c: T", + }, + }, + .{ + .name = "@byteSwap", + .signature = "@byteSwap(operand: anytype) T", + .snippet = "@byteSwap(${1:operand: anytype})", + .documentation = + \\`@TypeOf(operand)` must be an integer type or an integer vector type with bit count evenly divisible by 8. + \\ + \\`operand` may be an [integer](https://ziglang.org/documentation/0.10.1/#Integers) or [vector](https://ziglang.org/documentation/0.10.1/#Vectors). + \\ + \\Swaps the byte order of the integer. This converts a big endian integer to a little endian integer, and converts a little endian integer to a big endian integer. + \\ + \\Note that for the purposes of memory layout with respect to endianness, the integer type should be related to the number of bytes reported by [@sizeOf](https://ziglang.org/documentation/0.10.1/#sizeOf) bytes. This is demonstrated with `u24`. `@sizeOf(u24) == 4`, which means that a `u24` stored in memory takes 4 bytes, and those 4 bytes are what are swapped on a little vs big endian system. On the other hand, if `T` is specified to be `u24`, then only 3 bytes are reversed. + , + .arguments = &.{ + "operand: anytype", + }, + }, + .{ + .name = "@bitReverse", + .signature = "@bitReverse(integer: anytype) T", + .snippet = "@bitReverse(${1:integer: anytype})", + .documentation = + \\`@TypeOf(anytype)` accepts any integer type or integer vector type. + \\ + \\Reverses the bitpattern of an integer value, including the sign bit if applicable. + \\ + \\For example 0b10110110 (`u8 = 182`, `i8 = -74`) becomes 0b01101101 (`u8 = 109`, `i8 = 109`). + , + .arguments = &.{ + "integer: anytype", + }, + }, + .{ + .name = "@offsetOf", + .signature = "@offsetOf(comptime T: type, comptime field_name: []const u8) comptime_int", + .snippet = "@offsetOf(${1:comptime T: type}, ${2:comptime field_name: []const u8})", + .documentation = + \\Returns the byte offset of a field relative to its containing struct. + , + .arguments = &.{ + "comptime T: type", + "comptime field_name: []const u8", + }, + }, + .{ + .name = "@call", + .signature = "@call(options: std.builtin.CallOptions, function: anytype, args: anytype) anytype", + .snippet = "@call(${1:options: std.builtin.CallOptions}, ${2:function: anytype}, ${3:args: anytype})", + .documentation = + \\Calls a function, in the same way that invoking an expression with parentheses does: + \\ + \\```zig + \\const expect = @import("std").testing.expect; + \\test "noinline function call" { + \\ try expect(@call(.{}, add, .{3, 9}) == 12); + \\} + \\fn add(a: i32, b: i32) i32 { + \\ return a + b; + \\} + \\``` + \\`@call` allows more flexibility than normal function call syntax does. The `CallOptions` struct is reproduced here: + \\ + \\```zig + \\pub const CallOptions = struct { + \\ modifier: Modifier = .auto, + \\ /// Only valid when `Modifier` is `Modifier.async_kw`. + \\ stack: ?[]align(std.Target.stack_align) u8 = null, + \\ pub const Modifier = enum { + \\ /// Equivalent to function call syntax. + \\ auto, + \\ /// Equivalent to async keyword used with function call syntax. + \\ async_kw, + \\ /// Prevents tail call optimization. This guarantees that the return + \\ /// address will point to the callsite, as opposed to the callsite's + \\ /// callsite. If the call is otherwise required to be tail-called + \\ /// or inlined, a compile error is emitted instead. + \\ never_tail, + \\ /// Guarantees that the call will not be inlined. If the call is + \\ /// otherwise required to be inlined, a compile error is emitted instead. + \\ never_inline, + \\ /// Asserts that the function call will not suspend. This allows a + \\ /// non-async function to call an async function. + \\ no_async, + \\ /// Guarantees that the call will be generated with tail call optimization. + \\ /// If this is not possible, a compile error is emitted instead. + \\ always_tail, + \\ /// Guarantees that the call will inlined at the callsite. + \\ /// If this is not possible, a compile error is emitted instead. + \\ always_inline, + \\ /// Evaluates the call at compile-time. If the call cannot be completed at + \\ /// compile-time, a compile error is emitted instead. + \\ compile_time, + \\ }; + \\}; + \\``` + , + .arguments = &.{ + "options: std.builtin.CallOptions", + "function: anytype", + "args: anytype", + }, + }, + .{ + .name = "@cDefine", + .signature = "@cDefine(comptime name: []u8, value)", + .snippet = "@cDefine(${1:comptime name: []u8}, ${2:value})", + .documentation = + \\This function can only occur inside `@cImport`. + \\ + \\This appends + \\`#define $name $value`to the `@cImport` temporary buffer. + \\ + \\To define without a value, like this: + \\ + \\`#define _GNU_SOURCE`Use the void value, like this: + \\ + \\`@cDefine("_GNU_SOURCE", {})` + , + .arguments = &.{ + "comptime name: []u8", + "value", + }, + }, + .{ + .name = "@cImport", + .signature = "@cImport(expression) type", + .snippet = "@cImport(${1:expression})", + .documentation = + \\This function parses C code and imports the functions, types, variables, and compatible macro definitions into a new empty struct type, and then returns that type. + \\ + \\`expression` is interpreted at compile time. The builtin functions `@cInclude`, `@cDefine`, and `@cUndef` work within this expression, appending to a temporary buffer which is then parsed as C code. + \\ + \\Usually you should only have one `@cImport` in your entire application, because it saves the compiler from invoking clang multiple times, and prevents inline functions from being duplicated. + \\ + \\Reasons for having multiple `@cImport` expressions would be: + \\ + \\ - To avoid a symbol collision, for example if foo.h and bar.h both + \\`#define CONNECTION_COUNT` - To analyze the C code with different preprocessor defines + , + .arguments = &.{ + "expression", + }, + }, + .{ + .name = "@cInclude", + .signature = "@cInclude(comptime path: []u8)", + .snippet = "@cInclude(${1:comptime path: []u8})", + .documentation = + \\This function can only occur inside `@cImport`. + \\ + \\This appends + \\`#include <$path>\n`to the `c_import` temporary buffer. + , + .arguments = &.{ + "comptime path: []u8", + }, + }, + .{ + .name = "@clz", + .signature = "@clz(operand: anytype)", + .snippet = "@clz(${1:operand: anytype})", + .documentation = + \\`@TypeOf(operand)` must be an integer type or an integer vector type. + \\ + \\`operand` may be an [integer](https://ziglang.org/documentation/0.10.1/#Integers) or [vector](https://ziglang.org/documentation/0.10.1/#Vectors). + \\ + \\This function counts the number of most-significant (leading in a big-Endian sense) zeroes in an integer. + \\ + \\If `operand` is a [comptime](https://ziglang.org/documentation/0.10.1/#comptime)-known integer, the return type is `comptime_int`. Otherwise, the return type is an unsigned integer or vector of unsigned integers with the minimum number of bits that can represent the bit count of the integer type. + \\ + \\If `operand` is zero, `@clz` returns the bit width of integer type `T`. + , + .arguments = &.{ + "operand: anytype", + }, + }, + .{ + .name = "@cmpxchgStrong", + .signature = "@cmpxchgStrong(comptime T: type, ptr: *T, expected_value: T, new_value: T, success_order: AtomicOrder, fail_order: AtomicOrder) ?T", + .snippet = "@cmpxchgStrong(${1:comptime T: type}, ${2:ptr: *T}, ${3:expected_value: T}, ${4:new_value: T}, ${5:success_order: AtomicOrder}, ${6:fail_order: AtomicOrder})", + .documentation = + \\This function performs a strong atomic compare exchange operation. It's the equivalent of this code, except atomic: + \\ + \\```zig + \\fn cmpxchgStrongButNotAtomic(comptime T: type, ptr: *T, expected_value: T, new_value: T) ?T { + \\ const old_value = ptr.*; + \\ if (old_value == expected_value) { + \\ ptr.* = new_value; + \\ return null; + \\ } else { + \\ return old_value; + \\ } + \\} + \\``` + \\If you are using cmpxchg in a loop, [@cmpxchgWeak](https://ziglang.org/documentation/0.10.1/#cmpxchgWeak) is the better choice, because it can be implemented more efficiently in machine instructions. + \\ + \\`T` must be a pointer, a `bool`, a float, an integer or an enum. + \\ + \\`@typeInfo(@TypeOf(ptr)).Pointer.alignment` must be `>= @sizeOf(T).` + , + .arguments = &.{ + "comptime T: type", + "ptr: *T", + "expected_value: T", + "new_value: T", + "success_order: AtomicOrder", + "fail_order: AtomicOrder", + }, + }, + .{ + .name = "@cmpxchgWeak", + .signature = "@cmpxchgWeak(comptime T: type, ptr: *T, expected_value: T, new_value: T, success_order: AtomicOrder, fail_order: AtomicOrder) ?T", + .snippet = "@cmpxchgWeak(${1:comptime T: type}, ${2:ptr: *T}, ${3:expected_value: T}, ${4:new_value: T}, ${5:success_order: AtomicOrder}, ${6:fail_order: AtomicOrder})", + .documentation = + \\This function performs a weak atomic compare exchange operation. It's the equivalent of this code, except atomic: + \\ + \\```zig + \\fn cmpxchgWeakButNotAtomic(comptime T: type, ptr: *T, expected_value: T, new_value: T) ?T { + \\ const old_value = ptr.*; + \\ if (old_value == expected_value and usuallyTrueButSometimesFalse()) { + \\ ptr.* = new_value; + \\ return null; + \\ } else { + \\ return old_value; + \\ } + \\} + \\``` + \\If you are using cmpxchg in a loop, the sporadic failure will be no problem, and `cmpxchgWeak` is the better choice, because it can be implemented more efficiently in machine instructions. However if you need a stronger guarantee, use [@cmpxchgStrong](https://ziglang.org/documentation/0.10.1/#cmpxchgStrong). + \\ + \\`T` must be a pointer, a `bool`, a float, an integer or an enum. + \\ + \\`@typeInfo(@TypeOf(ptr)).Pointer.alignment` must be `>= @sizeOf(T).` + , + .arguments = &.{ + "comptime T: type", + "ptr: *T", + "expected_value: T", + "new_value: T", + "success_order: AtomicOrder", + "fail_order: AtomicOrder", + }, + }, + .{ + .name = "@compileError", + .signature = "@compileError(comptime msg: []u8)", + .snippet = "@compileError(${1:comptime msg: []u8})", + .documentation = + \\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. + , + .arguments = &.{ + "comptime msg: []u8", + }, + }, + .{ + .name = "@compileLog", + .signature = "@compileLog(args: ...)", + .snippet = "@compileLog(${1:args: ...})", + .documentation = + \\This function prints the arguments passed to it at compile-time. + \\ + \\To prevent accidentally leaving compile log statements in a codebase, a compilation error is added to the build, pointing to the compile log statement. This error prevents code from being generated, but does not otherwise interfere with analysis. + \\ + \\This function can be used to do "printf debugging" on compile-time executing code. + \\ + \\```zig + \\const print = @import("std").debug.print; + \\const num1 = blk: { + \\ var val1: i32 = 99; + \\ @compileLog("comptime val1 = ", val1); + \\ val1 = val1 + 1; + \\ break :blk val1; + \\}; + \\test "main" { + \\ @compileLog("comptime in main"); + \\ print("Runtime in main, num1 = {}.\n", .{num1}); + \\} + \\``` + \\If all `@compileLog` calls are removed or not encountered by analysis, the program compiles successfully and the generated executable prints: + \\ + \\```zig + \\const print = @import("std").debug.print; + \\const num1 = blk: { + \\ var val1: i32 = 99; + \\ val1 = val1 + 1; + \\ break :blk val1; + \\}; + \\test "main" { + \\ print("Runtime in main, num1 = {}.\n", .{num1}); + \\} + \\``` + , + .arguments = &.{ + "args: ...", + }, + }, + .{ + .name = "@ctz", + .signature = "@ctz(operand: anytype)", + .snippet = "@ctz(${1:operand: anytype})", + .documentation = + \\`@TypeOf(operand)` must be an integer type or an integer vector type. + \\ + \\`operand` may be an [integer](https://ziglang.org/documentation/0.10.1/#Integers) or [vector](https://ziglang.org/documentation/0.10.1/#Vectors). + \\ + \\This function counts the number of least-significant (trailing in a big-Endian sense) zeroes in an integer. + \\ + \\If `operand` is a [comptime](https://ziglang.org/documentation/0.10.1/#comptime)-known integer, the return type is `comptime_int`. Otherwise, the return type is an unsigned integer or vector of unsigned integers with the minimum number of bits that can represent the bit count of the integer type. + \\ + \\If `operand` is zero, `@ctz` returns the bit width of integer type `T`. + , + .arguments = &.{ + "operand: anytype", + }, + }, + .{ + .name = "@cUndef", + .signature = "@cUndef(comptime name: []u8)", + .snippet = "@cUndef(${1:comptime name: []u8})", + .documentation = + \\This function can only occur inside `@cImport`. + \\ + \\This appends + \\`#undef $name`to the `@cImport` temporary buffer. + , + .arguments = &.{ + "comptime name: []u8", + }, + }, + .{ + .name = "@divExact", + .signature = "@divExact(numerator: T, denominator: T) T", + .snippet = "@divExact(${1:numerator: T}, ${2:denominator: T})", + .documentation = + \\Exact division. Caller guarantees `denominator != 0` and `@divTrunc(numerator, denominator) * denominator == numerator`. + \\ + \\ - `@divExact(6, 3) == 2` + \\ - `@divExact(a, b) * b == a` + \\For a function that returns a possible error code, use `@import("std").math.divExact`. + , + .arguments = &.{ + "numerator: T", + "denominator: T", + }, + }, + .{ + .name = "@divFloor", + .signature = "@divFloor(numerator: T, denominator: T) T", + .snippet = "@divFloor(${1:numerator: T}, ${2:denominator: T})", + .documentation = + \\Floored division. Rounds toward negative infinity. For unsigned integers it is the same as `numerator / denominator`. Caller guarantees `denominator != 0` and `!(@typeInfo(T) == .Int and T.is_signed and numerator == std.math.minInt(T) and denominator == -1)`. + \\ + \\ - `@divFloor(-5, 3) == -2` + \\ - `(@divFloor(a, b) * b) + @mod(a, b) == a` + \\For a function that returns a possible error code, use `@import("std").math.divFloor`. + , + .arguments = &.{ + "numerator: T", + "denominator: T", + }, + }, + .{ + .name = "@divTrunc", + .signature = "@divTrunc(numerator: T, denominator: T) T", + .snippet = "@divTrunc(${1:numerator: T}, ${2:denominator: T})", + .documentation = + \\Truncated division. Rounds toward zero. For unsigned integers it is the same as `numerator / denominator`. Caller guarantees `denominator != 0` and `!(@typeInfo(T) == .Int and T.is_signed and numerator == std.math.minInt(T) and denominator == -1)`. + \\ + \\ - `@divTrunc(-5, 3) == -1` + \\ - `(@divTrunc(a, b) * b) + @rem(a, b) == a` + \\For a function that returns a possible error code, use `@import("std").math.divTrunc`. + , + .arguments = &.{ + "numerator: T", + "denominator: T", + }, + }, + .{ + .name = "@embedFile", + .signature = "@embedFile(comptime path: []const u8) *const [N:0]u8", + .snippet = "@embedFile(${1:comptime path: []const u8})", + .documentation = + \\This function returns a compile time constant pointer to null-terminated, 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. This is equivalent to a [string literal](https://ziglang.org/documentation/0.10.1/#String-Literals-and-Unicode-Code-Point-Literals) with the file contents. + \\ + \\`path` is absolute or relative to the current file, just like `@import`. + , + .arguments = &.{ + "comptime path: []const u8", + }, + }, + .{ + .name = "@enumToInt", + .signature = "@enumToInt(enum_or_tagged_union: anytype) anytype", + .snippet = "@enumToInt(${1:enum_or_tagged_union: anytype})", + .documentation = + \\Converts an enumeration value into its integer tag type. When a tagged union is passed, the tag value is used as the enumeration value. + \\ + \\If there is only one possible enum value, the result is a `comptime_int` known at [comptime](https://ziglang.org/documentation/0.10.1/#comptime). + , + .arguments = &.{ + "enum_or_tagged_union: anytype", + }, + }, + .{ + .name = "@errorName", + .signature = "@errorName(err: anyerror) [:0]const u8", + .snippet = "@errorName(${1:err: anyerror})", + .documentation = + \\This function returns the string representation of an error. The string representation of `error.OutOfMem` is `"OutOfMem"`. + \\ + \\If there are no calls to `@errorName` in an entire application, or all calls have a compile-time known value for `err`, then no error name table will be generated. + , + .arguments = &.{ + "err: anyerror", + }, + }, + .{ + .name = "@errorReturnTrace", + .signature = "@errorReturnTrace() ?*builtin.StackTrace", + .snippet = "@errorReturnTrace()", + .documentation = + \\If the binary is built with error return tracing, and this function is invoked in a function that calls a function with an error or error union return type, returns a stack trace object. Otherwise returns [null](https://ziglang.org/documentation/0.10.1/#null). + , + .arguments = &.{}, + }, + .{ + .name = "@errorToInt", + .signature = "@errorToInt(err: anytype) std.meta.Int(.unsigned, @sizeOf(anyerror) * 8)", + .snippet = "@errorToInt(${1:err: anytype})", + .documentation = + \\Supports the following types: + \\ + \\ - [The Global Error Set](https://ziglang.org/documentation/0.10.1/#The-Global-Error-Set) + \\ - [Error Set Type](https://ziglang.org/documentation/0.10.1/#Error-Set-Type) + \\ - [Error Union Type](https://ziglang.org/documentation/0.10.1/#Error-Union-Type) + \\Converts an error to the integer representation of an error. + \\ + \\It is generally recommended to avoid this cast, as the integer representation of an error is not stable across source code changes. + , + .arguments = &.{ + "err: anytype", + }, + }, + .{ + .name = "@errSetCast", + .signature = "@errSetCast(comptime T: DestType, value: anytype) DestType", + .snippet = "@errSetCast(${1:comptime T: DestType}, ${2:value: anytype})", + .documentation = + \\Converts an error value from one error set to another error set. Attempting to convert an error which is not in the destination error set results in safety-protected [Undefined Behavior](https://ziglang.org/documentation/0.10.1/#Undefined-Behavior). + , + .arguments = &.{ + "comptime T: DestType", + "value: anytype", + }, + }, + .{ + .name = "@export", + .signature = "@export(declaration, comptime options: std.builtin.ExportOptions) void", + .snippet = "@export(${1:declaration}, ${2:comptime options: std.builtin.ExportOptions})", + .documentation = + \\Creates a symbol in the output object file. + \\ + \\`declaration`must be one of two things: + \\ + \\ - An identifier (`x`) identifying a [function](https://ziglang.org/documentation/0.10.1/#Functions) or a [variable](https://ziglang.org/documentation/0.10.1/#Container-Level-Variables). + \\ - Field access (`x.y`) looking up a [function](https://ziglang.org/documentation/0.10.1/#Functions) or a [variable](https://ziglang.org/documentation/0.10.1/#Container-Level-Variables). + \\This builtin can be called from a [comptime](https://ziglang.org/documentation/0.10.1/#comptime) block to conditionally export symbols. When + \\`declaration`is a function with the C calling convention and `options.linkage` is `Strong`, this is equivalent to the `export` keyword used on a function: + \\ + \\```zig + \\comptime { + \\ @export(internalName, .{ .name = "foo", .linkage = .Strong }); + \\} + \\fn internalName() callconv(.C) void {} + \\``` + \\This is equivalent to: + \\ + \\`export fn foo() void {}` + \\Note that even when using `export`, the `@"foo"` syntax for [identifiers](https://ziglang.org/documentation/0.10.1/#Identifiers) can be used to choose any string for the symbol name: + \\ + \\`export fn @"A function name that is a complete sentence."() void {}` + \\When looking at the resulting object, you can see the symbol is used verbatim: + \\ + \\`00000000000001f0 T A function name that is a complete sentence.` + , + .arguments = &.{ + "declaration", + "comptime options: std.builtin.ExportOptions", + }, + }, + .{ + .name = "@extern", + .signature = "@extern(T: type, comptime options: std.builtin.ExternOptions) *T", + .snippet = "@extern(${1:T: type}, ${2:comptime options: std.builtin.ExternOptions})", + .documentation = + \\Creates a reference to an external symbol in the output object file. + , + .arguments = &.{ + "T: type", + "comptime options: std.builtin.ExternOptions", + }, + }, + .{ + .name = "@fence", + .signature = "@fence(order: AtomicOrder)", + .snippet = "@fence(${1:order: AtomicOrder})", + .documentation = + \\The `fence` function is used to introduce happens-before edges between operations. + \\ + \\`AtomicOrder` can be found with `@import("std").builtin.AtomicOrder`. + , + .arguments = &.{ + "order: AtomicOrder", + }, + }, + .{ + .name = "@field", + .signature = "@field(lhs: anytype, comptime field_name: []const u8) (field)", + .snippet = "@field(${1:lhs: anytype}, ${2:comptime field_name: []const u8})", + .documentation = + \\Performs field access by a compile-time string. Works on both fields and declarations. + \\ + \\```zig + \\const std = @import("std"); + \\const Point = struct { + \\ x: u32, + \\ y: u32, + \\ pub var z: u32 = 1; + \\}; + \\test "field access by string" { + \\ const expect = std.testing.expect; + \\ var p = Point{ .x = 0, .y = 0 }; + \\ @field(p, "x") = 4; + \\ @field(p, "y") = @field(p, "x") + 1; + \\ try expect(@field(p, "x") == 4); + \\ try expect(@field(p, "y") == 5); + \\} + \\test "decl access by string" { + \\ const expect = std.testing.expect; + \\ try expect(@field(Point, "z") == 1); + \\ @field(Point, "z") = 2; + \\ try expect(@field(Point, "z") == 2); + \\} + \\``` + , + .arguments = &.{ + "lhs: anytype", + "comptime field_name: []const u8", + }, + }, + .{ + .name = "@fieldParentPtr", + .signature = "@fieldParentPtr(comptime ParentType: type, comptime field_name: []const u8, field_ptr: *T) *ParentType", + .snippet = "@fieldParentPtr(${1:comptime ParentType: type}, ${2:comptime field_name: []const u8}, ${3:field_ptr: *T})", + .documentation = + \\Given a pointer to a field, returns the base pointer of a struct. + , + .arguments = &.{ + "comptime ParentType: type", + "comptime field_name: []const u8", + "field_ptr: *T", + }, + }, + .{ + .name = "@floatCast", + .signature = "@floatCast(comptime DestType: type, value: anytype) DestType", + .snippet = "@floatCast(${1:comptime DestType: type}, ${2:value: anytype})", + .documentation = + \\Convert from one float type to another. This cast is safe, but may cause the numeric value to lose precision. + , + .arguments = &.{ + "comptime DestType: type", + "value: anytype", + }, + }, + .{ + .name = "@floatToInt", + .signature = "@floatToInt(comptime DestType: type, float: anytype) DestType", + .snippet = "@floatToInt(${1:comptime DestType: type}, ${2:float: anytype})", + .documentation = + \\Converts the integer part of a floating point number to the destination type. + \\ + \\If the integer part of the floating point number cannot fit in the destination type, it invokes safety-checked [Undefined Behavior](https://ziglang.org/documentation/0.10.1/#Undefined-Behavior). + , + .arguments = &.{ + "comptime DestType: type", + "float: anytype", + }, + }, + .{ + .name = "@frame", + .signature = "@frame() *@Frame(func)", + .snippet = "@frame()", + .documentation = + \\This function returns a pointer to the frame for a given function. This type can be [coerced](https://ziglang.org/documentation/0.10.1/#Type-Coercion) to `anyframe->T` and to `anyframe`, where `T` is the return type of the function in scope. + \\ + \\This function does not mark a suspension point, but it does cause the function in scope to become an [async function](https://ziglang.org/documentation/0.10.1/#Async-Functions). + , + .arguments = &.{}, + }, + .{ + .name = "@Frame", + .signature = "@Frame(func: anytype) type", + .snippet = "@Frame(${1:func: anytype})", + .documentation = + \\This function returns the frame type of a function. This works for [Async Functions](https://ziglang.org/documentation/0.10.1/#Async-Functions) as well as any function without a specific calling convention. + \\ + \\This type is suitable to be used as the return type of [async](https://ziglang.org/documentation/0.10.1/#Async-and-Await) which allows one to, for example, heap-allocate an async function frame: + \\ + \\```zig + \\const std = @import("std"); + \\test "heap allocated frame" { + \\ const frame = try std.heap.page_allocator.create(@Frame(func)); + \\ frame.* = async func(); + \\} + \\fn func() void { + \\ suspend {} + \\} + \\``` + , + .arguments = &.{ + "func: anytype", + }, + }, + .{ + .name = "@frameAddress", + .signature = "@frameAddress() usize", + .snippet = "@frameAddress()", + .documentation = + \\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. + , + .arguments = &.{}, + }, + .{ + .name = "@frameSize", + .signature = "@frameSize(func: anytype) usize", + .snippet = "@frameSize(${1:func: anytype})", + .documentation = + \\This is the same as `@sizeOf(@Frame(func))`, where `func` may be runtime-known. + \\ + \\This function is typically used in conjunction with [@asyncCall](https://ziglang.org/documentation/0.10.1/#asyncCall). + , + .arguments = &.{ + "func: anytype", + }, + }, + .{ + .name = "@hasDecl", + .signature = "@hasDecl(comptime Container: type, comptime name: []const u8) bool", + .snippet = "@hasDecl(${1:comptime Container: type}, ${2:comptime name: []const u8})", + .documentation = + \\Returns whether or not a [container](https://ziglang.org/documentation/0.10.1/#Containers) has a declaration matching `name`. + \\ + \\```zig + \\const std = @import("std"); + \\const expect = std.testing.expect; + \\const Foo = struct { + \\ nope: i32, + \\ pub var blah = "xxx"; + \\ const hi = 1; + \\}; + \\test "@hasDecl" { + \\ try expect(@hasDecl(Foo, "blah")); + \\ // Even though `hi` is private, @hasDecl returns true because this test is + \\ // in the same file scope as Foo. It would return false if Foo was declared + \\ // in a different file. + \\ try expect(@hasDecl(Foo, "hi")); + \\ // @hasDecl is for declarations; not fields. + \\ try expect(!@hasDecl(Foo, "nope")); + \\ try expect(!@hasDecl(Foo, "nope1234")); + \\} + \\``` + , + .arguments = &.{ + "comptime Container: type", + "comptime name: []const u8", + }, + }, + .{ + .name = "@hasField", + .signature = "@hasField(comptime Container: type, comptime name: []const u8) bool", + .snippet = "@hasField(${1:comptime Container: type}, ${2:comptime name: []const u8})", + .documentation = + \\Returns whether the field name of a struct, union, or enum exists. + \\ + \\The result is a compile time constant. + \\ + \\It does not include functions, variables, or constants. + , + .arguments = &.{ + "comptime Container: type", + "comptime name: []const u8", + }, + }, + .{ + .name = "@import", + .signature = "@import(comptime path: []u8) type", + .snippet = "@import(${1:comptime path: []u8})", + .documentation = + \\This function finds a zig file corresponding to `path` and adds it to the build, if it is not already added. + \\ + \\Zig source files are implicitly structs, with a name equal to the file's basename with the extension truncated. `@import` returns the struct type corresponding to the file. + \\ + \\Declarations which have the `pub` keyword may be referenced from a different source file than the one they are declared in. + \\ + \\`path` can be a relative path or it can be the name of a package. If it is a relative path, it is relative to the file that contains the `@import` function call. + \\ + \\The following packages are always available: + \\ + \\ - `@import("std")` - Zig Standard Library + \\ - `@import("builtin")` - Target-specific information. The command + \\`zig build-exe --show-builtin`outputs the source to stdout for reference. + \\ - `@import("root")` - Points to the root source file. This is usually + \\`src/main.zig`but it depends on what file is chosen to be built. + , + .arguments = &.{ + "comptime path: []u8", + }, + }, + .{ + .name = "@intCast", + .signature = "@intCast(comptime DestType: type, int: anytype) DestType", + .snippet = "@intCast(${1:comptime DestType: type}, ${2:int: anytype})", + .documentation = + \\Converts an integer to another integer while keeping the same numerical value. Attempting to convert a number which is out of range of the destination type results in safety-protected [Undefined Behavior](https://ziglang.org/documentation/0.10.1/#Undefined-Behavior). + \\ + \\```zig + \\test "integer cast panic" { + \\ var a: u16 = 0xabcd; + \\ var b: u8 = @intCast(u8, a); + \\ _ = b; + \\} + \\``` + \\To truncate the significant bits of a number out of range of the destination type, use [@truncate](https://ziglang.org/documentation/0.10.1/#truncate). + \\ + \\If `T` is `comptime_int`, then this is semantically equivalent to [Type Coercion](https://ziglang.org/documentation/0.10.1/#Type-Coercion). + , + .arguments = &.{ + "comptime DestType: type", + "int: anytype", + }, + }, + .{ + .name = "@intToEnum", + .signature = "@intToEnum(comptime DestType: type, integer: anytype) DestType", + .snippet = "@intToEnum(${1:comptime DestType: type}, ${2:integer: anytype})", + .documentation = + \\Converts an integer into an [enum](https://ziglang.org/documentation/0.10.1/#enum) value. + \\ + \\Attempting to convert an integer which represents no value in the chosen enum type invokes safety-checked [Undefined Behavior](https://ziglang.org/documentation/0.10.1/#Undefined-Behavior). + , + .arguments = &.{ + "comptime DestType: type", + "integer: anytype", + }, + }, + .{ + .name = "@intToError", + .signature = "@intToError(value: std.meta.Int(.unsigned, @sizeOf(anyerror) * 8)) anyerror", + .snippet = "@intToError(${1:value: std.meta.Int(.unsigned, @sizeOf(anyerror) * 8})", + .documentation = + \\Converts from the integer representation of an error into [The Global Error Set](https://ziglang.org/documentation/0.10.1/#The-Global-Error-Set) type. + \\ + \\It is generally recommended to avoid this cast, as the integer representation of an error is not stable across source code changes. + \\ + \\Attempting to convert an integer that does not correspond to any error results in safety-protected [Undefined Behavior](https://ziglang.org/documentation/0.10.1/#Undefined-Behavior). + , + .arguments = &.{ + "value: std.meta.Int(.unsigned, @sizeOf(anyerror) * 8", + }, + }, + .{ + .name = "@intToFloat", + .signature = "@intToFloat(comptime DestType: type, int: anytype) DestType", + .snippet = "@intToFloat(${1:comptime DestType: type}, ${2:int: anytype})", + .documentation = + \\Converts an integer to the closest floating point representation. To convert the other way, use [@floatToInt](https://ziglang.org/documentation/0.10.1/#floatToInt). This cast is always safe. + , + .arguments = &.{ + "comptime DestType: type", + "int: anytype", + }, + }, + .{ + .name = "@intToPtr", + .signature = "@intToPtr(comptime DestType: type, address: usize) DestType", + .snippet = "@intToPtr(${1:comptime DestType: type}, ${2:address: usize})", + .documentation = + \\Converts an integer to a [pointer](https://ziglang.org/documentation/0.10.1/#Pointers). To convert the other way, use [@ptrToInt](https://ziglang.org/documentation/0.10.1/#ptrToInt). Casting an address of 0 to a destination type which in not [optional](https://ziglang.org/documentation/0.10.1/#Optional-Pointers) and does not have the `allowzero` attribute will result in a [Pointer Cast Invalid Null](https://ziglang.org/documentation/0.10.1/#Pointer-Cast-Invalid-Null) panic when runtime safety checks are enabled. + \\ + \\If the destination pointer type does not allow address zero and `address` is zero, this invokes safety-checked [Undefined Behavior](https://ziglang.org/documentation/0.10.1/#Undefined-Behavior). + , + .arguments = &.{ + "comptime DestType: type", + "address: usize", + }, + }, + .{ + .name = "@max", + .signature = "@max(a: T, b: T) T", + .snippet = "@max(${1:a: T}, ${2:b: T})", + .documentation = + \\Returns the maximum value of `a` and `b`. This builtin accepts integers, floats, and vectors of either. In the latter case, the operation is performed element wise. + \\ + \\NaNs are handled as follows: if one of the operands of a (pairwise) operation is NaN, the other operand is returned. If both operands are NaN, NaN is returned. + , + .arguments = &.{ + "a: T", + "b: T", + }, + }, + .{ + .name = "@memcpy", + .signature = "@memcpy(noalias dest: [*]u8, noalias source: [*]const u8, byte_count: usize)", + .snippet = "@memcpy(${1:noalias dest: [*]u8}, ${2:noalias source: [*]const u8}, ${3:byte_count: usize})", + .documentation = + \\This function copies bytes from one region of memory to another. `dest` and `source` are both pointers and must not overlap. + \\ + \\This function is a low level intrinsic with no safety mechanisms. Most code should not use this function, instead using something like this: + \\ + \\`for (source[0..byte_count]) |b, i| dest[i] = b;` + \\The optimizer is intelligent enough to turn the above snippet into a memcpy. + \\ + \\There is also a standard library function for this: + \\ + \\```zig + \\const mem = @import("std").mem; + \\mem.copy(u8, dest[0..byte_count], source[0..byte_count]); + \\``` + , + .arguments = &.{ + "noalias dest: [*]u8", + "noalias source: [*]const u8", + "byte_count: usize", + }, + }, + .{ + .name = "@memset", + .signature = "@memset(dest: [*]u8, c: u8, byte_count: usize)", + .snippet = "@memset(${1:dest: [*]u8}, ${2:c: u8}, ${3:byte_count: usize})", + .documentation = + \\This function sets a region of memory to `c`. `dest` is a pointer. + \\ + \\This function is a low level intrinsic with no safety mechanisms. Most code should not use this function, instead using something like this: + \\ + \\`for (dest[0..byte_count]) |*b| b.* = c;` + \\The optimizer is intelligent enough to turn the above snippet into a memset. + \\ + \\There is also a standard library function for this: + \\ + \\```zig + \\const mem = @import("std").mem; + \\mem.set(u8, dest, c); + \\``` + , + .arguments = &.{ + "dest: [*]u8", + "c: u8", + "byte_count: usize", + }, + }, + .{ + .name = "@min", + .signature = "@min(a: T, b: T) T", + .snippet = "@min(${1:a: T}, ${2:b: T})", + .documentation = + \\Returns the minimum value of `a` and `b`. This builtin accepts integers, floats, and vectors of either. In the latter case, the operation is performed element wise. + \\ + \\NaNs are handled as follows: if one of the operands of a (pairwise) operation is NaN, the other operand is returned. If both operands are NaN, NaN is returned. + , + .arguments = &.{ + "a: T", + "b: T", + }, + }, + .{ + .name = "@wasmMemorySize", + .signature = "@wasmMemorySize(index: u32) u32", + .snippet = "@wasmMemorySize(${1:index: u32})", + .documentation = + \\This function returns the size of the Wasm memory identified by `index` as an unsigned value in units of Wasm pages. Note that each Wasm page is 64KB in size. + \\ + \\This function is a low level intrinsic with no safety mechanisms usually useful for allocator designers targeting Wasm. So unless you are writing a new allocator from scratch, you should use something like `@import("std").heap.WasmPageAllocator`. + , + .arguments = &.{ + "index: u32", + }, + }, + .{ + .name = "@wasmMemoryGrow", + .signature = "@wasmMemoryGrow(index: u32, delta: u32) i32", + .snippet = "@wasmMemoryGrow(${1:index: u32}, ${2:delta: u32})", + .documentation = + \\This function increases the size of the Wasm memory identified by `index` by `delta` in units of unsigned number of Wasm pages. Note that each Wasm page is 64KB in size. On success, returns previous memory size; on failure, if the allocation fails, returns -1. + \\ + \\This function is a low level intrinsic with no safety mechanisms usually useful for allocator designers targeting Wasm. So unless you are writing a new allocator from scratch, you should use something like `@import("std").heap.WasmPageAllocator`. + \\ + \\```zig + \\const std = @import("std"); + \\const native_arch = @import("builtin").target.cpu.arch; + \\const expect = std.testing.expect; + \\test "@wasmMemoryGrow" { + \\ if (native_arch != .wasm32) return error.SkipZigTest; + \\ var prev = @wasmMemorySize(0); + \\ try expect(prev == @wasmMemoryGrow(0, 1)); + \\ try expect(prev + 1 == @wasmMemorySize(0)); + \\} + \\``` + , + .arguments = &.{ + "index: u32", + "delta: u32", + }, + }, + .{ + .name = "@mod", + .signature = "@mod(numerator: T, denominator: T) T", + .snippet = "@mod(${1:numerator: T}, ${2:denominator: T})", + .documentation = + \\Modulus division. For unsigned integers this is the same as `numerator % denominator`. Caller guarantees `denominator > 0`, otherwise the operation will result in a [Remainder Division by Zero](https://ziglang.org/documentation/0.10.1/#Remainder-Division-by-Zero) when runtime safety checks are enabled. + \\ + \\ - `@mod(-5, 3) == 1` + \\ - `(@divFloor(a, b) * b) + @mod(a, b) == a` + \\For a function that returns an error code, see `@import("std").math.mod`. + , + .arguments = &.{ + "numerator: T", + "denominator: T", + }, + }, + .{ + .name = "@mulWithOverflow", + .signature = "@mulWithOverflow(comptime T: type, a: T, b: T, result: *T) bool", + .snippet = "@mulWithOverflow(${1:comptime T: type}, ${2:a: T}, ${3:b: T}, ${4:result: *T})", + .documentation = + \\Performs `result.* = a * b`. If overflow or underflow occurs, stores the overflowed bits in `result` and returns `true`. If no overflow or underflow occurs, returns `false`. + , + .arguments = &.{ + "comptime T: type", + "a: T", + "b: T", + "result: *T", + }, + }, + .{ + .name = "@panic", + .signature = "@panic(message: []const u8) noreturn", + .snippet = "@panic(${1:message: []const u8})", + .documentation = + \\Invokes the panic handler function. By default the panic handler function calls the public `panic` function exposed in the root source file, or if there is not one specified, the `std.builtin.default_panic` function from `std/builtin.zig`. + \\ + \\Generally it is better to use `@import("std").debug.panic`. However, `@panic` can be useful for 2 scenarios: + \\ + \\ - From library code, calling the programmer's panic function if they exposed one in the root source file. + \\ - When mixing C and Zig code, calling the canonical panic implementation across multiple .o files. + , + .arguments = &.{ + "message: []const u8", + }, + }, + .{ + .name = "@popCount", + .signature = "@popCount(operand: anytype)", + .snippet = "@popCount(${1:operand: anytype})", + .documentation = + \\`@TypeOf(operand)` must be an integer type. + \\ + \\`operand` may be an [integer](https://ziglang.org/documentation/0.10.1/#Integers) or [vector](https://ziglang.org/documentation/0.10.1/#Vectors). + \\ + \\Counts the number of bits set in an integer. + \\ + \\If `operand` is a [comptime](https://ziglang.org/documentation/0.10.1/#comptime)-known integer, the return type is `comptime_int`. Otherwise, the return type is an unsigned integer or vector of unsigned integers with the minimum number of bits that can represent the bit count of the integer type. + , + .arguments = &.{ + "operand: anytype", + }, + }, + .{ + .name = "@prefetch", + .signature = "@prefetch(ptr: anytype, comptime options: std.builtin.PrefetchOptions)", + .snippet = "@prefetch(${1:ptr: anytype}, ${2:comptime options: std.builtin.PrefetchOptions})", + .documentation = + \\This builtin tells the compiler to emit a prefetch instruction if supported by the target CPU. If the target CPU does not support the requested prefetch instruction, this builtin is a no-op. This function has no effect on the behavior of the program, only on the performance characteristics. + \\ + \\The `ptr` argument may be any pointer type and determines the memory address to prefetch. This function does not dereference the pointer, it is perfectly legal to pass a pointer to invalid memory to this function and no illegal behavior will result. + \\ + \\The `options` argument is the following struct: + \\ + \\```zig + \\/// This data structure is used by the Zig language code generation and + \\/// therefore must be kept in sync with the compiler implementation. + \\pub const PrefetchOptions = struct { + \\ /// Whether the prefetch should prepare for a read or a write. + \\ rw: Rw = .read, + \\ /// 0 means no temporal locality. That is, the data can be immediately + \\ /// dropped from the cache after it is accessed. + \\ /// + \\ /// 3 means high temporal locality. That is, the data should be kept in + \\ /// the cache as it is likely to be accessed again soon. + \\ locality: u2 = 3, + \\ /// The cache that the prefetch should be preformed on. + \\ cache: Cache = .data, + \\ pub const Rw = enum { + \\ read, + \\ write, + \\ }; + \\ pub const Cache = enum { + \\ instruction, + \\ data, + \\ }; + \\}; + \\``` + , + .arguments = &.{ + "ptr: anytype", + "comptime options: std.builtin.PrefetchOptions", + }, + }, + .{ + .name = "@ptrCast", + .signature = "@ptrCast(comptime DestType: type, value: anytype) DestType", + .snippet = "@ptrCast(${1:comptime DestType: type}, ${2:value: anytype})", + .documentation = + \\Converts a pointer of one type to a pointer of another type. + \\ + \\[Optional Pointers](https://ziglang.org/documentation/0.10.1/#Optional-Pointers) are allowed. Casting an optional pointer which is [null](https://ziglang.org/documentation/0.10.1/#null) to a non-optional pointer invokes safety-checked [Undefined Behavior](https://ziglang.org/documentation/0.10.1/#Undefined-Behavior). + , + .arguments = &.{ + "comptime DestType: type", + "value: anytype", + }, + }, + .{ + .name = "@ptrToInt", + .signature = "@ptrToInt(value: anytype) usize", + .snippet = "@ptrToInt(${1:value: anytype})", + .documentation = + \\Converts `value` to a `usize` which is the address of the pointer. `value` can be `*T` or `?*T`. + \\ + \\To convert the other way, use [@intToPtr](https://ziglang.org/documentation/0.10.1/#intToPtr) + , + .arguments = &.{ + "value: anytype", + }, + }, + .{ + .name = "@rem", + .signature = "@rem(numerator: T, denominator: T) T", + .snippet = "@rem(${1:numerator: T}, ${2:denominator: T})", + .documentation = + \\Remainder division. For unsigned integers this is the same as `numerator % denominator`. Caller guarantees `denominator > 0`, otherwise the operation will result in a [Remainder Division by Zero](https://ziglang.org/documentation/0.10.1/#Remainder-Division-by-Zero) when runtime safety checks are enabled. + \\ + \\ - `@rem(-5, 3) == -2` + \\ - `(@divTrunc(a, b) * b) + @rem(a, b) == a` + \\For a function that returns an error code, see `@import("std").math.rem`. + , + .arguments = &.{ + "numerator: T", + "denominator: T", + }, + }, + .{ + .name = "@returnAddress", + .signature = "@returnAddress() usize", + .snippet = "@returnAddress()", + .documentation = + \\This function returns the address of the next machine code instruction that will be executed when the current function returns. + \\ + \\The implications of this are target-specific and not consistent across all platforms. + \\ + \\This function is only valid within function scope. If the function gets inlined into a calling function, the returned address will apply to the calling function. + , + .arguments = &.{}, + }, + .{ + .name = "@select", + .signature = "@select(comptime T: type, pred: @Vector(len, bool), a: @Vector(len, T), b: @Vector(len, T)) @Vector(len, T)", + .snippet = "@select(${1:comptime T: type}, ${2:pred: @Vector(len, bool)}, ${3:a: @Vector(len, T)}, ${4:b: @Vector(len, T)})", + .documentation = + \\Selects values element-wise from `a` or `b` based on `pred`. If `pred[i]` is `true`, the corresponding element in the result will be `a[i]` and otherwise `b[i]`. + , + .arguments = &.{ + "comptime T: type", + "pred: @Vector(len, bool)", + "a: @Vector(len, T)", + "b: @Vector(len, T)", + }, + }, + .{ + .name = "@setAlignStack", + .signature = "@setAlignStack(comptime alignment: u29)", + .snippet = "@setAlignStack(${1:comptime alignment: u29})", + .documentation = + \\Ensures that a function will have a stack alignment of at least `alignment` bytes. + , + .arguments = &.{ + "comptime alignment: u29", + }, + }, + .{ + .name = "@setCold", + .signature = "@setCold(comptime is_cold: bool)", + .snippet = "@setCold(${1:comptime is_cold: bool})", + .documentation = + \\Tells the optimizer that a function is rarely called. + , + .arguments = &.{ + "comptime is_cold: bool", + }, + }, + .{ + .name = "@setEvalBranchQuota", + .signature = "@setEvalBranchQuota(comptime new_quota: u32)", + .snippet = "@setEvalBranchQuota(${1:comptime new_quota: u32})", + .documentation = + \\Changes the maximum number of backwards branches that compile-time code execution can use before giving up and making a compile error. + \\ + \\If the `new_quota` is smaller than the default quota (`1000`) or a previously explicitly set quota, it is ignored. + \\ + \\Example: + \\ + \\1001) : (i += 1) {} + \\ } + \\} + \\``` + \\Now we use `@setEvalBranchQuota`: + \\ + \\1001) : (i += 1) {} + \\ } + \\} + \\``` + , + .arguments = &.{ + "comptime new_quota: u32", + }, + }, + .{ + .name = "@setFloatMode", + .signature = "@setFloatMode(comptime mode: @import(\"std\").builtin.FloatMode)", + .snippet = "@setFloatMode(${1:comptime mode: @import(\"std\").builtin.FloatMode})", + .documentation = + \\Sets the floating point mode of the current scope. Possible values are: + \\ + \\```zig + \\pub const FloatMode = enum { + \\ Strict, + \\ Optimized, + \\}; + \\``` + \\ - `Strict` (default) - Floating point operations follow strict IEEE compliance. + \\ - `Optimized` - Floating point operations may do all of the following: + \\ - Assume the arguments and result are not NaN. Optimizations are required to retain defined behavior over NaNs, but the value of the result is undefined. + \\ - Assume the arguments and result are not +/-Inf. Optimizations are required to retain defined behavior over +/-Inf, but the value of the result is undefined. + \\ - Treat the sign of a zero argument or result as insignificant. + \\ - Use the reciprocal of an argument rather than perform division. + \\ - Perform floating-point contraction (e.g. fusing a multiply followed by an addition into a fused multiply-add). + \\ - Perform algebraically equivalent transformations that may change results in floating point (e.g. reassociate). + \\This is equivalent to + \\`-ffast-math`in GCC. + \\The floating point mode is inherited by child scopes, and can be overridden in any scope. You can set the floating point mode in a struct or module scope by using a comptime block. + , + .arguments = &.{ + "comptime mode: @import(\"std\").builtin.FloatMode", + }, + }, + .{ + .name = "@setRuntimeSafety", + .signature = "@setRuntimeSafety(comptime safety_on: bool) void", + .snippet = "@setRuntimeSafety(${1:comptime safety_on: bool})", + .documentation = + \\Sets whether runtime safety checks are enabled for the scope that contains the function call. + \\ + \\```zig + \\test "@setRuntimeSafety" { + \\ // The builtin applies to the scope that it is called in. So here, integer overflow + \\ // will not be caught in ReleaseFast and ReleaseSmall modes: + \\ // var x: u8 = 255; + \\ // x += 1; // undefined behavior in ReleaseFast/ReleaseSmall modes. + \\ { + \\ // However this block has safety enabled, so safety checks happen here, + \\ // even in ReleaseFast and ReleaseSmall modes. + \\ @setRuntimeSafety(true); + \\ var x: u8 = 255; + \\ x += 1; + \\ { + \\ // The value can be overridden at any scope. So here integer overflow + \\ // would not be caught in any build mode. + \\ @setRuntimeSafety(false); + \\ // var x: u8 = 255; + \\ // x += 1; // undefined behavior in all build modes. + \\ } + \\ } + \\} + \\``` + \\Note: it is + \\[planned](https://github.com/ziglang/zig/issues/978)to replace `@setRuntimeSafety` with + \\`@optimizeFor` + , + .arguments = &.{ + "comptime safety_on: bool", + }, + }, + .{ + .name = "@shlExact", + .signature = "@shlExact(value: T, shift_amt: Log2T) T", + .snippet = "@shlExact(${1:value: T}, ${2:shift_amt: Log2T})", + .documentation = + \\`). For unsigned integers, the result is [undefined](https://ziglang.org/documentation/0.10.1/#undefined) if any 1 bits are shifted out. For signed integers, the result is [undefined](https://ziglang.org/documentation/0.10.1/#undefined) if any bits that disagree with the resultant sign bit are shifted out. + \\ + \\The type of `shift_amt` is an unsigned integer with `log2(@typeInfo(T).Int.bits)` bits. This is because `shift_amt >= @typeInfo(T).Int.bits` is undefined behavior. + , + .arguments = &.{ + "value: T", + "shift_amt: Log2T", + }, + }, + .{ + .name = "@shlWithOverflow", + .signature = "@shlWithOverflow(comptime T: type, a: T, shift_amt: Log2T, result: *T) bool", + .snippet = "@shlWithOverflow(${1:comptime T: type}, ${2:a: T}, ${3:shift_amt: Log2T}, ${4:result: *T})", + .documentation = + \\b`. If overflow or underflow occurs, stores the overflowed bits in `result` and returns `true`. If no overflow or underflow occurs, returns `false`. + \\ + \\The type of `shift_amt` is an unsigned integer with `log2(@typeInfo(T).Int.bits)` bits. This is because `shift_amt >= @typeInfo(T).Int.bits` is undefined behavior. + , + .arguments = &.{ + "comptime T: type", + "a: T", + "shift_amt: Log2T", + "result: *T", + }, + }, + .{ + .name = "@shrExact", + .signature = "@shrExact(value: T, shift_amt: Log2T) T", + .snippet = "@shrExact(${1:value: T}, ${2:shift_amt: Log2T})", + .documentation = + \\Performs the right shift operation (`>>`). Caller guarantees that the shift will not shift any 1 bits out. + \\ + \\The type of `shift_amt` is an unsigned integer with `log2(@typeInfo(T).Int.bits)` bits. This is because `shift_amt >= @typeInfo(T).Int.bits` is undefined behavior. + , + .arguments = &.{ + "value: T", + "shift_amt: Log2T", + }, + }, + .{ + .name = "@shuffle", + .signature = "@shuffle(comptime E: type, a: @Vector(a_len, E), b: @Vector(b_len, E), comptime mask: @Vector(mask_len, i32)) @Vector(mask_len, E)", + .snippet = "@shuffle(${1:comptime E: type}, ${2:a: @Vector(a_len, E)}, ${3:b: @Vector(b_len, E)}, ${4:comptime mask: @Vector(mask_len, i32)})", + .documentation = + \\Constructs a new [vector](https://ziglang.org/documentation/0.10.1/#Vectors) by selecting elements from `a` and `b` based on `mask`. + \\ + \\Each element in `mask` selects an element from either `a` or `b`. Positive numbers select from `a` starting at 0. Negative values select from `b`, starting at `-1` and going down. It is recommended to use the `~` operator for indexes from `b` so that both indexes can start from `0` (i.e. `~@as(i32, 0)` is `-1`). + \\ + \\For each element of `mask`, if it or the selected value from `a` or `b` is `undefined`, then the resulting element is `undefined`. + \\ + \\`a_len` and `b_len` may differ in length. Out-of-bounds element indexes in `mask` result in compile errors. + \\ + \\If `a` or `b` is `undefined`, it is equivalent to a vector of all `undefined` with the same length as the other vector. If both vectors are `undefined`, `@shuffle` returns a vector with all elements `undefined`. + \\ + \\`E` must be an [integer](https://ziglang.org/documentation/0.10.1/#Integers), [float](https://ziglang.org/documentation/0.10.1/#Floats), [pointer](https://ziglang.org/documentation/0.10.1/#Pointers), or `bool`. The mask may be any vector length, and its length determines the result length. + \\ + \\```zig + \\const std = @import("std"); + \\const expect = std.testing.expect; + \\test "vector @shuffle" { + \\ const a = @Vector(7, u8){ 'o', 'l', 'h', 'e', 'r', 'z', 'w' }; + \\ const b = @Vector(4, u8){ 'w', 'd', '!', 'x' }; + \\ // To shuffle within a single vector, pass undefined as the second argument. + \\ // Notice that we can re-order, duplicate, or omit elements of the input vector + \\ const mask1 = @Vector(5, i32){ 2, 3, 1, 1, 0 }; + \\ const res1: @Vector(5, u8) = @shuffle(u8, a, undefined, mask1); + \\ try expect(std.mem.eql(u8, &@as([5]u8, res1), "hello")); + \\ // Combining two vectors + \\ const mask2 = @Vector(6, i32){ -1, 0, 4, 1, -2, -3 }; + \\ const res2: @Vector(6, u8) = @shuffle(u8, a, b, mask2); + \\ try expect(std.mem.eql(u8, &@as([6]u8, res2), "world!")); + \\} + \\``` + , + .arguments = &.{ + "comptime E: type", + "a: @Vector(a_len, E)", + "b: @Vector(b_len, E)", + "comptime mask: @Vector(mask_len, i32)", + }, + }, + .{ + .name = "@sizeOf", + .signature = "@sizeOf(comptime T: type) comptime_int", + .snippet = "@sizeOf(${1:comptime T: type})", + .documentation = + \\This function returns the number of bytes it takes to store `T` in memory. The result is a target-specific compile time constant. + \\ + \\This size may contain padding bytes. If there were two consecutive T in memory, this would be the offset in bytes between element at index 0 and the element at index 1. For [integer](https://ziglang.org/documentation/0.10.1/#Integers), consider whether you want to use `@sizeOf(T)` or `@typeInfo(T).Int.bits`. + \\ + \\This function measures the size at runtime. For types that are disallowed at runtime, such as `comptime_int` and `type`, the result is `0`. + , + .arguments = &.{ + "comptime T: type", + }, + }, + .{ + .name = "@splat", + .signature = "@splat(comptime len: u32, scalar: anytype) @Vector(len, @TypeOf(scalar))", + .snippet = "@splat(${1:comptime len: u32}, ${2:scalar: anytype})", + .documentation = + \\Produces a vector of length `len` where each element is the value `scalar`: + \\ + \\```zig + \\const std = @import("std"); + \\const expect = std.testing.expect; + \\test "vector @splat" { + \\ const scalar: u32 = 5; + \\ const result = @splat(4, scalar); + \\ comptime try expect(@TypeOf(result) == @Vector(4, u32)); + \\ try expect(std.mem.eql(u32, &@as([4]u32, result), &[_]u32{ 5, 5, 5, 5 })); + \\} + \\``` + \\`scalar` must be an [integer](https://ziglang.org/documentation/0.10.1/#Integers), [bool](https://ziglang.org/documentation/0.10.1/#Primitive-Types), [float](https://ziglang.org/documentation/0.10.1/#Floats), or [pointer](https://ziglang.org/documentation/0.10.1/#Pointers). + , + .arguments = &.{ + "comptime len: u32", + "scalar: anytype", + }, + }, + .{ + .name = "@reduce", + .signature = "@reduce(comptime op: std.builtin.ReduceOp, value: anytype) E", + .snippet = "@reduce(${1:comptime op: std.builtin.ReduceOp}, ${2:value: anytype})", + .documentation = + \\Transforms a [vector](https://ziglang.org/documentation/0.10.1/#Vectors) into a scalar value (of type + \\`E`) by performing a sequential horizontal reduction of its elements using the specified operator `op`. + \\ + \\Not every operator is available for every vector element type: + \\ + \\ - Every operator is available for [integer](https://ziglang.org/documentation/0.10.1/#Integers) vectors. + \\ - `.And`, `.Or`, `.Xor` are additionally available for `bool` vectors, + \\ - `.Min`, `.Max`, `.Add`, `.Mul` are additionally available for [floating point](https://ziglang.org/documentation/0.10.1/#Floats) vectors, + \\Note that `.Add` and `.Mul` reductions on integral types are wrapping; when applied on floating point types the operation associativity is preserved, unless the float mode is set to `Optimized`. + \\ + \\```zig + \\const std = @import("std"); + \\const expect = std.testing.expect; + \\test "vector @reduce" { + \\ const value = @Vector(4, i32){ 1, -1, 1, -1 }; + \\ const result = value > @splat(4, @as(i32, 0)); + \\ // result is { true, false, true, false }; + \\ comptime try expect(@TypeOf(result) == @Vector(4, bool)); + \\ const is_all_true = @reduce(.And, result); + \\ comptime try expect(@TypeOf(is_all_true) == bool); + \\ try expect(is_all_true == false); + \\} + \\``` + , + .arguments = &.{ + "comptime op: std.builtin.ReduceOp", + "value: anytype", + }, + }, + .{ + .name = "@src", + .signature = "@src() std.builtin.SourceLocation", + .snippet = "@src()", + .documentation = + \\Returns a `SourceLocation` struct representing the function's name and location in the source code. This must be called in a function. + \\ + \\```zig + \\const std = @import("std"); + \\const expect = std.testing.expect; + \\test "@src" { + \\ try doTheTest(); + \\} + \\fn doTheTest() !void { + \\ const src = @src(); + \\ try expect(src.line == 9); + \\ try expect(src.column == 17); + \\ try expect(std.mem.endsWith(u8, src.fn_name, "doTheTest")); + \\ try expect(std.mem.endsWith(u8, src.file, "source_location.zig")); + \\} + \\``` + , + .arguments = &.{}, + }, + .{ + .name = "@sqrt", + .signature = "@sqrt(value: anytype) @TypeOf(value)", + .snippet = "@sqrt(${1:value: anytype})", + .documentation = + \\Performs the square root of a floating point number. Uses a dedicated hardware instruction when available. + \\ + \\Supports [Floats](https://ziglang.org/documentation/0.10.1/#Floats) and [Vectors](https://ziglang.org/documentation/0.10.1/#Vectors) of floats, with the caveat that + \\[some float operations are not yet implemented for all float types](https://github.com/ziglang/zig/issues/4026). + , + .arguments = &.{ + "value: anytype", + }, + }, + .{ + .name = "@sin", + .signature = "@sin(value: anytype) @TypeOf(value)", + .snippet = "@sin(${1:value: anytype})", + .documentation = + \\Sine trigonometric function on a floating point number. Uses a dedicated hardware instruction when available. + \\ + \\Supports [Floats](https://ziglang.org/documentation/0.10.1/#Floats) and [Vectors](https://ziglang.org/documentation/0.10.1/#Vectors) of floats, with the caveat that + \\[some float operations are not yet implemented for all float types](https://github.com/ziglang/zig/issues/4026). + , + .arguments = &.{ + "value: anytype", + }, + }, + .{ + .name = "@cos", + .signature = "@cos(value: anytype) @TypeOf(value)", + .snippet = "@cos(${1:value: anytype})", + .documentation = + \\Cosine trigonometric function on a floating point number. Uses a dedicated hardware instruction when available. + \\ + \\Supports [Floats](https://ziglang.org/documentation/0.10.1/#Floats) and [Vectors](https://ziglang.org/documentation/0.10.1/#Vectors) of floats, with the caveat that + \\[some float operations are not yet implemented for all float types](https://github.com/ziglang/zig/issues/4026). + , + .arguments = &.{ + "value: anytype", + }, + }, + .{ + .name = "@tan", + .signature = "@tan(value: anytype) @TypeOf(value)", + .snippet = "@tan(${1:value: anytype})", + .documentation = + \\Tangent trigonometric function on a floating point number. Uses a dedicated hardware instruction when available. + \\ + \\Supports [Floats](https://ziglang.org/documentation/0.10.1/#Floats) and [Vectors](https://ziglang.org/documentation/0.10.1/#Vectors) of floats, with the caveat that + \\[some float operations are not yet implemented for all float types](https://github.com/ziglang/zig/issues/4026). + , + .arguments = &.{ + "value: anytype", + }, + }, + .{ + .name = "@exp", + .signature = "@exp(value: anytype) @TypeOf(value)", + .snippet = "@exp(${1:value: anytype})", + .documentation = + \\Base-e exponential function on a floating point number. Uses a dedicated hardware instruction when available. + \\ + \\Supports [Floats](https://ziglang.org/documentation/0.10.1/#Floats) and [Vectors](https://ziglang.org/documentation/0.10.1/#Vectors) of floats, with the caveat that + \\[some float operations are not yet implemented for all float types](https://github.com/ziglang/zig/issues/4026). + , + .arguments = &.{ + "value: anytype", + }, + }, + .{ + .name = "@exp2", + .signature = "@exp2(value: anytype) @TypeOf(value)", + .snippet = "@exp2(${1:value: anytype})", + .documentation = + \\Base-2 exponential function on a floating point number. Uses a dedicated hardware instruction when available. + \\ + \\Supports [Floats](https://ziglang.org/documentation/0.10.1/#Floats) and [Vectors](https://ziglang.org/documentation/0.10.1/#Vectors) of floats, with the caveat that + \\[some float operations are not yet implemented for all float types](https://github.com/ziglang/zig/issues/4026). + , + .arguments = &.{ + "value: anytype", + }, + }, + .{ + .name = "@log", + .signature = "@log(value: anytype) @TypeOf(value)", + .snippet = "@log(${1:value: anytype})", + .documentation = + \\Returns the natural logarithm of a floating point number. Uses a dedicated hardware instruction when available. + \\ + \\Supports [Floats](https://ziglang.org/documentation/0.10.1/#Floats) and [Vectors](https://ziglang.org/documentation/0.10.1/#Vectors) of floats, with the caveat that + \\[some float operations are not yet implemented for all float types](https://github.com/ziglang/zig/issues/4026). + , + .arguments = &.{ + "value: anytype", + }, + }, + .{ + .name = "@log2", + .signature = "@log2(value: anytype) @TypeOf(value)", + .snippet = "@log2(${1:value: anytype})", + .documentation = + \\Returns the logarithm to the base 2 of a floating point number. Uses a dedicated hardware instruction when available. + \\ + \\Supports [Floats](https://ziglang.org/documentation/0.10.1/#Floats) and [Vectors](https://ziglang.org/documentation/0.10.1/#Vectors) of floats, with the caveat that + \\[some float operations are not yet implemented for all float types](https://github.com/ziglang/zig/issues/4026). + , + .arguments = &.{ + "value: anytype", + }, + }, + .{ + .name = "@log10", + .signature = "@log10(value: anytype) @TypeOf(value)", + .snippet = "@log10(${1:value: anytype})", + .documentation = + \\Returns the logarithm to the base 10 of a floating point number. Uses a dedicated hardware instruction when available. + \\ + \\Supports [Floats](https://ziglang.org/documentation/0.10.1/#Floats) and [Vectors](https://ziglang.org/documentation/0.10.1/#Vectors) of floats, with the caveat that + \\[some float operations are not yet implemented for all float types](https://github.com/ziglang/zig/issues/4026). + , + .arguments = &.{ + "value: anytype", + }, + }, + .{ + .name = "@fabs", + .signature = "@fabs(value: anytype) @TypeOf(value)", + .snippet = "@fabs(${1:value: anytype})", + .documentation = + \\Returns the absolute value of a floating point number. Uses a dedicated hardware instruction when available. + \\ + \\Supports [Floats](https://ziglang.org/documentation/0.10.1/#Floats) and [Vectors](https://ziglang.org/documentation/0.10.1/#Vectors) of floats, with the caveat that + \\[some float operations are not yet implemented for all float types](https://github.com/ziglang/zig/issues/4026). + , + .arguments = &.{ + "value: anytype", + }, + }, + .{ + .name = "@floor", + .signature = "@floor(value: anytype) @TypeOf(value)", + .snippet = "@floor(${1:value: anytype})", + .documentation = + \\Returns the largest integral value not greater than the given floating point number. Uses a dedicated hardware instruction when available. + \\ + \\Supports [Floats](https://ziglang.org/documentation/0.10.1/#Floats) and [Vectors](https://ziglang.org/documentation/0.10.1/#Vectors) of floats, with the caveat that + \\[some float operations are not yet implemented for all float types](https://github.com/ziglang/zig/issues/4026). + , + .arguments = &.{ + "value: anytype", + }, + }, + .{ + .name = "@ceil", + .signature = "@ceil(value: anytype) @TypeOf(value)", + .snippet = "@ceil(${1:value: anytype})", + .documentation = + \\Returns the smallest integral value not less than the given floating point number. Uses a dedicated hardware instruction when available. + \\ + \\Supports [Floats](https://ziglang.org/documentation/0.10.1/#Floats) and [Vectors](https://ziglang.org/documentation/0.10.1/#Vectors) of floats, with the caveat that + \\[some float operations are not yet implemented for all float types](https://github.com/ziglang/zig/issues/4026). + , + .arguments = &.{ + "value: anytype", + }, + }, + .{ + .name = "@trunc", + .signature = "@trunc(value: anytype) @TypeOf(value)", + .snippet = "@trunc(${1:value: anytype})", + .documentation = + \\Rounds the given floating point number to an integer, towards zero. Uses a dedicated hardware instruction when available. + \\ + \\Supports [Floats](https://ziglang.org/documentation/0.10.1/#Floats) and [Vectors](https://ziglang.org/documentation/0.10.1/#Vectors) of floats, with the caveat that + \\[some float operations are not yet implemented for all float types](https://github.com/ziglang/zig/issues/4026). + , + .arguments = &.{ + "value: anytype", + }, + }, + .{ + .name = "@round", + .signature = "@round(value: anytype) @TypeOf(value)", + .snippet = "@round(${1:value: anytype})", + .documentation = + \\Rounds the given floating point number to an integer, away from zero. Uses a dedicated hardware instruction when available. + \\ + \\Supports [Floats](https://ziglang.org/documentation/0.10.1/#Floats) and [Vectors](https://ziglang.org/documentation/0.10.1/#Vectors) of floats, with the caveat that + \\[some float operations are not yet implemented for all float types](https://github.com/ziglang/zig/issues/4026). + , + .arguments = &.{ + "value: anytype", + }, + }, + .{ + .name = "@subWithOverflow", + .signature = "@subWithOverflow(comptime T: type, a: T, b: T, result: *T) bool", + .snippet = "@subWithOverflow(${1:comptime T: type}, ${2:a: T}, ${3:b: T}, ${4:result: *T})", + .documentation = + \\Performs `result.* = a - b`. If overflow or underflow occurs, stores the overflowed bits in `result` and returns `true`. If no overflow or underflow occurs, returns `false`. + , + .arguments = &.{ + "comptime T: type", + "a: T", + "b: T", + "result: *T", + }, + }, + .{ + .name = "@tagName", + .signature = "@tagName(value: anytype) [:0]const u8", + .snippet = "@tagName(${1:value: anytype})", + .documentation = + \\Converts an enum value or union value to a string literal representing the name. + \\ + \\If the enum is non-exhaustive and the tag value does not map to a name, it invokes safety-checked [Undefined Behavior](https://ziglang.org/documentation/0.10.1/#Undefined-Behavior). + , + .arguments = &.{ + "value: anytype", + }, + }, + .{ + .name = "@This", + .signature = "@This() type", + .snippet = "@This()", + .documentation = + \\Returns the innermost struct, enum, or union that this function call is inside. This can be useful for an anonymous struct that needs to refer to itself: + \\ + \\```zig + \\const std = @import("std"); + \\const expect = std.testing.expect; + \\test "@This()" { + \\ var items = [_]i32{ 1, 2, 3, 4 }; + \\ const list = List(i32){ .items = items[0..] }; + \\ try expect(list.length() == 4); + \\} + \\fn List(comptime T: type) type { + \\ return struct { + \\ const Self = @This(); + \\ items: []T, + \\ fn length(self: Self) usize { + \\ return self.items.len; + \\ } + \\ }; + \\} + \\``` + \\When `@This()` is used at file scope, it returns a reference to the struct that corresponds to the current file. + , + .arguments = &.{}, + }, + .{ + .name = "@truncate", + .signature = "@truncate(comptime T: type, integer: anytype) T", + .snippet = "@truncate(${1:comptime T: type}, ${2:integer: anytype})", + .documentation = + \\This function truncates bits from an integer type, resulting in a smaller or same-sized integer type. + \\ + \\This function always truncates the significant bits of the integer, regardless of endianness on the target platform. + \\ + \\Calling `@truncate` on a number out of range of the destination type is well defined and working code: + \\ + \\```zig + \\const std = @import("std"); + \\const expect = std.testing.expect; + \\test "integer truncation" { + \\ var a: u16 = 0xabcd; + \\ var b: u8 = @truncate(u8, a); + \\ try expect(b == 0xcd); + \\} + \\``` + \\Use [@intCast](https://ziglang.org/documentation/0.10.1/#intCast) to convert numbers guaranteed to fit the destination type. + , + .arguments = &.{ + "comptime T: type", + "integer: anytype", + }, + }, + .{ + .name = "@Type", + .signature = "@Type(comptime info: std.builtin.Type) type", + .snippet = "@Type(${1:comptime info: std.builtin.Type})", + .documentation = + \\This function is the inverse of [@typeInfo](https://ziglang.org/documentation/0.10.1/#typeInfo). It reifies type information into a `type`. + \\ + \\It is available for the following types: + \\ + \\ - `type` + \\ - `noreturn` + \\ - `void` + \\ - `bool` + \\ - [Integers](https://ziglang.org/documentation/0.10.1/#Integers) - The maximum bit count for an integer type is `65535`. + \\ - [Floats](https://ziglang.org/documentation/0.10.1/#Floats) + \\ - [Pointers](https://ziglang.org/documentation/0.10.1/#Pointers) + \\ - `comptime_int` + \\ - `comptime_float` + \\ - `@TypeOf(undefined)` + \\ - `@TypeOf(null)` + \\ - [Arrays](https://ziglang.org/documentation/0.10.1/#Arrays) + \\ - [Optionals](https://ziglang.org/documentation/0.10.1/#Optionals) + \\ - [Error Set Type](https://ziglang.org/documentation/0.10.1/#Error-Set-Type) + \\ - [Error Union Type](https://ziglang.org/documentation/0.10.1/#Error-Union-Type) + \\ - [Vectors](https://ziglang.org/documentation/0.10.1/#Vectors) + \\ - [opaque](https://ziglang.org/documentation/0.10.1/#opaque) + \\ - [@Frame](https://ziglang.org/documentation/0.10.1/#Frame) + \\ - `anyframe` + \\ - [struct](https://ziglang.org/documentation/0.10.1/#struct) + \\ - [enum](https://ziglang.org/documentation/0.10.1/#enum) + \\ - [Enum Literals](https://ziglang.org/documentation/0.10.1/#Enum-Literals) + \\ - [union](https://ziglang.org/documentation/0.10.1/#union) + \\For these types, `@Type` is not available: + \\ + \\ - [Functions](https://ziglang.org/documentation/0.10.1/#Functions) + \\ - BoundFn + , + .arguments = &.{ + "comptime info: std.builtin.Type", + }, + }, + .{ + .name = "@typeInfo", + .signature = "@typeInfo(comptime T: type) std.builtin.Type", + .snippet = "@typeInfo(${1:comptime T: type})", + .documentation = + \\Provides type reflection. + \\ + \\Type information of [structs](https://ziglang.org/documentation/0.10.1/#struct), [unions](https://ziglang.org/documentation/0.10.1/#union), [enums](https://ziglang.org/documentation/0.10.1/#enum), and [error sets](https://ziglang.org/documentation/0.10.1/#Error-Set-Type) has fields which are guaranteed to be in the same order as appearance in the source file. + \\ + \\Type information of [structs](https://ziglang.org/documentation/0.10.1/#struct), [unions](https://ziglang.org/documentation/0.10.1/#union), [enums](https://ziglang.org/documentation/0.10.1/#enum), and [opaques](https://ziglang.org/documentation/0.10.1/#opaque) has declarations, which are also guaranteed to be in the same order as appearance in the source file. + , + .arguments = &.{ + "comptime T: type", + }, + }, + .{ + .name = "@typeName", + .signature = "@typeName(T: type) *const [N:0]u8", + .snippet = "@typeName(${1:T: type})", + .documentation = + \\This function returns the string representation of a type, as an array. It is equivalent to a string literal of the type name. The returned type name is fully qualified with the parent namespace included as part of the type name with a series of dots. + , + .arguments = &.{ + "T: type", + }, + }, + .{ + .name = "@TypeOf", + .signature = "@TypeOf(...) type", + .snippet = "@TypeOf(${1:...})", + .documentation = + \\`@TypeOf` is a special builtin function that takes any (nonzero) number of expressions as parameters and returns the type of the result, using [Peer Type Resolution](https://ziglang.org/documentation/0.10.1/#Peer-Type-Resolution). + \\ + \\The expressions are evaluated, however they are guaranteed to have no + \\**runtime** side-effects: + \\ + \\```zig + \\const std = @import("std"); + \\const expect = std.testing.expect; + \\test "no runtime side effects" { + \\ var data: i32 = 0; + \\ const T = @TypeOf(foo(i32, &data)); + \\ comptime try expect(T == i32); + \\ try expect(data == 0); + \\} + \\fn foo(comptime T: type, ptr: *T) T { + \\ ptr.* += 1; + \\ return ptr.*; + \\} + \\``` + , + .arguments = &.{ + "...", + }, + }, + .{ + .name = "@unionInit", + .signature = "@unionInit(comptime Union: type, comptime active_field_name: []const u8, init_expr) Union", + .snippet = "@unionInit(${1:comptime Union: type}, ${2:comptime active_field_name: []const u8}, ${3:init_expr})", + .documentation = + \\This is the same thing as [union](https://ziglang.org/documentation/0.10.1/#union) initialization syntax, except that the field name is a [comptime](https://ziglang.org/documentation/0.10.1/#comptime)-known value rather than an identifier token. + \\ + \\`@unionInit` forwards its [result location](https://ziglang.org/documentation/0.10.1/#Result-Location-Semantics) to `init_expr`. + , + .arguments = &.{ + "comptime Union: type", + "comptime active_field_name: []const u8", + "init_expr", + }, + }, + .{ + .name = "@Vector", + .signature = "@Vector(len: comptime_int, Element: type) type", + .snippet = "@Vector(${1:len: comptime_int}, ${2:Element: type})", + .documentation = + \\Creates [Vectors](https://ziglang.org/documentation/0.10.1/#Vectors). + , + .arguments = &.{ + "len: comptime_int", + "Element: type", + }, + }, +}; + +// DO NOT EDIT diff --git a/src/data/data.zig b/src/data/data.zig index 21257bf..dc445f3 100644 --- a/src/data/data.zig +++ b/src/data/data.zig @@ -9,4 +9,5 @@ pub usingnamespace switch (build_options.data_version) { .@"0.9.0" => @import("0.9.0.zig"), .@"0.9.1" => @import("0.9.1.zig"), .@"0.10.0" => @import("0.10.0.zig"), + .@"0.10.1" => @import("0.10.1.zig"), }; diff --git a/src/data/master.zig b/src/data/master.zig index cc7d3e8..2a57da3 100644 --- a/src/data/master.zig +++ b/src/data/master.zig @@ -1600,7 +1600,7 @@ pub const builtins = [_]Builtin{ \\ try expect(src.line == 9); \\ try expect(src.column == 17); \\ try expect(std.mem.endsWith(u8, src.fn_name, "doTheTest")); - \\ try expect(std.mem.endsWith(u8, src.file, "source_location.zig")); + \\ try expect(std.mem.endsWith(u8, src.file, "test_src_builtin.zig")); \\} \\``` , @@ -1914,7 +1914,7 @@ pub const builtins = [_]Builtin{ \\ - [enum](https://ziglang.org/documentation/master/#enum) \\ - [Enum Literals](https://ziglang.org/documentation/master/#Enum-Literals) \\ - [union](https://ziglang.org/documentation/master/#union) - \\`@Type` is not available for [Functions](https://ziglang.org/documentation/master/#Functions). + \\ - [Functions](https://ziglang.org/documentation/master/#Functions) , .arguments = &.{ "comptime info: std.builtin.Type", diff --git a/src/shared.zig b/src/shared.zig index fac7994..bdf4646 100644 --- a/src/shared.zig +++ b/src/shared.zig @@ -9,4 +9,5 @@ pub const ZigVersion = enum { @"0.9.0", @"0.9.1", @"0.10.0", + @"0.10.1", };