mirror of
https://github.com/ziglang/zig.git
synced 2024-12-03 18:38:45 +00:00
341 lines
13 KiB
Zig
341 lines
13 KiB
Zig
const std = @import("std.zig");
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const builtin = @import("builtin");
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const assert = std.debug.assert;
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const testing = std.testing;
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const os = std.os;
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const math = std.math;
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pub const epoch = @import("time/epoch.zig");
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/// Spurious wakeups are possible and no precision of timing is guaranteed.
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pub fn sleep(nanoseconds: u64) void {
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// TODO: opting out of async sleeping?
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if (std.io.is_async) {
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return std.event.Loop.instance.?.sleep(nanoseconds);
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}
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if (builtin.os.tag == .windows) {
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const big_ms_from_ns = nanoseconds / ns_per_ms;
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const ms = math.cast(os.windows.DWORD, big_ms_from_ns) orelse math.maxInt(os.windows.DWORD);
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os.windows.kernel32.Sleep(ms);
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return;
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}
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if (builtin.os.tag == .wasi) {
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const w = std.os.wasi;
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const userdata: w.userdata_t = 0x0123_45678;
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const clock = w.subscription_clock_t{
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.id = w.CLOCK.MONOTONIC,
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.timeout = nanoseconds,
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.precision = 0,
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.flags = 0,
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};
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const in = w.subscription_t{
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.userdata = userdata,
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.u = w.subscription_u_t{
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.tag = w.EVENTTYPE_CLOCK,
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.u = w.subscription_u_u_t{
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.clock = clock,
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},
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},
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};
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var event: w.event_t = undefined;
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var nevents: usize = undefined;
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_ = w.poll_oneoff(&in, &event, 1, &nevents);
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return;
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}
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if (builtin.os.tag == .uefi) {
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const boot_services = os.uefi.system_table.boot_services.?;
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const us_from_ns = nanoseconds / ns_per_us;
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const us = math.cast(usize, us_from_ns) orelse math.maxInt(usize);
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_ = boot_services.stall(us);
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return;
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}
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const s = nanoseconds / ns_per_s;
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const ns = nanoseconds % ns_per_s;
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std.os.nanosleep(s, ns);
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}
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test "sleep" {
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sleep(1);
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}
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/// Get a calendar timestamp, in seconds, relative to UTC 1970-01-01.
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/// Precision of timing depends on the hardware and operating system.
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/// The return value is signed because it is possible to have a date that is
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/// before the epoch.
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/// See `std.os.clock_gettime` for a POSIX timestamp.
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pub fn timestamp() i64 {
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return @divFloor(milliTimestamp(), ms_per_s);
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}
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/// Get a calendar timestamp, in milliseconds, relative to UTC 1970-01-01.
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/// Precision of timing depends on the hardware and operating system.
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/// The return value is signed because it is possible to have a date that is
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/// before the epoch.
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/// See `std.os.clock_gettime` for a POSIX timestamp.
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pub fn milliTimestamp() i64 {
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return @as(i64, @intCast(@divFloor(nanoTimestamp(), ns_per_ms)));
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}
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/// Get a calendar timestamp, in microseconds, relative to UTC 1970-01-01.
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/// Precision of timing depends on the hardware and operating system.
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/// The return value is signed because it is possible to have a date that is
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/// before the epoch.
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/// See `std.os.clock_gettime` for a POSIX timestamp.
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pub fn microTimestamp() i64 {
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return @as(i64, @intCast(@divFloor(nanoTimestamp(), ns_per_us)));
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}
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/// Get a calendar timestamp, in nanoseconds, relative to UTC 1970-01-01.
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/// Precision of timing depends on the hardware and operating system.
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/// On Windows this has a maximum granularity of 100 nanoseconds.
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/// The return value is signed because it is possible to have a date that is
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/// before the epoch.
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/// See `std.os.clock_gettime` for a POSIX timestamp.
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pub fn nanoTimestamp() i128 {
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if (builtin.os.tag == .windows) {
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// FileTime has a granularity of 100 nanoseconds and uses the NTFS/Windows epoch,
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// which is 1601-01-01.
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const epoch_adj = epoch.windows * (ns_per_s / 100);
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var ft: os.windows.FILETIME = undefined;
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os.windows.kernel32.GetSystemTimeAsFileTime(&ft);
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const ft64 = (@as(u64, ft.dwHighDateTime) << 32) | ft.dwLowDateTime;
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return @as(i128, @as(i64, @bitCast(ft64)) + epoch_adj) * 100;
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}
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if (builtin.os.tag == .wasi and !builtin.link_libc) {
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var ns: os.wasi.timestamp_t = undefined;
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const err = os.wasi.clock_time_get(os.wasi.CLOCK.REALTIME, 1, &ns);
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assert(err == .SUCCESS);
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return ns;
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}
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var ts: os.timespec = undefined;
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os.clock_gettime(os.CLOCK.REALTIME, &ts) catch |err| switch (err) {
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error.UnsupportedClock, error.Unexpected => return 0, // "Precision of timing depends on hardware and OS".
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};
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return (@as(i128, ts.tv_sec) * ns_per_s) + ts.tv_nsec;
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}
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test "timestamp" {
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const margin = ns_per_ms * 50;
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const time_0 = milliTimestamp();
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sleep(ns_per_ms);
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const time_1 = milliTimestamp();
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const interval = time_1 - time_0;
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try testing.expect(interval > 0);
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// Tests should not depend on timings: skip test if outside margin.
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if (!(interval < margin)) return error.SkipZigTest;
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}
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// Divisions of a nanosecond.
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pub const ns_per_us = 1000;
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pub const ns_per_ms = 1000 * ns_per_us;
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pub const ns_per_s = 1000 * ns_per_ms;
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pub const ns_per_min = 60 * ns_per_s;
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pub const ns_per_hour = 60 * ns_per_min;
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pub const ns_per_day = 24 * ns_per_hour;
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pub const ns_per_week = 7 * ns_per_day;
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// Divisions of a microsecond.
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pub const us_per_ms = 1000;
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pub const us_per_s = 1000 * us_per_ms;
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pub const us_per_min = 60 * us_per_s;
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pub const us_per_hour = 60 * us_per_min;
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pub const us_per_day = 24 * us_per_hour;
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pub const us_per_week = 7 * us_per_day;
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// Divisions of a millisecond.
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pub const ms_per_s = 1000;
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pub const ms_per_min = 60 * ms_per_s;
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pub const ms_per_hour = 60 * ms_per_min;
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pub const ms_per_day = 24 * ms_per_hour;
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pub const ms_per_week = 7 * ms_per_day;
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// Divisions of a second.
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pub const s_per_min = 60;
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pub const s_per_hour = s_per_min * 60;
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pub const s_per_day = s_per_hour * 24;
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pub const s_per_week = s_per_day * 7;
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/// An Instant represents a timestamp with respect to the currently
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/// executing program that ticks during suspend and can be used to
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/// record elapsed time unlike `nanoTimestamp`.
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///
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/// It tries to sample the system's fastest and most precise timer available.
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/// It also tries to be monotonic, but this is not a guarantee due to OS/hardware bugs.
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/// If you need monotonic readings for elapsed time, consider `Timer` instead.
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pub const Instant = struct {
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timestamp: if (is_posix) os.timespec else u64,
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// true if we should use clock_gettime()
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const is_posix = switch (builtin.os.tag) {
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.wasi => builtin.link_libc,
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.windows => false,
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else => true,
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};
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/// Queries the system for the current moment of time as an Instant.
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/// This is not guaranteed to be monotonic or steadily increasing, but for most implementations it is.
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/// Returns `error.Unsupported` when a suitable clock is not detected.
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pub fn now() error{Unsupported}!Instant {
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// QPC on windows doesn't fail on >= XP/2000 and includes time suspended.
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if (builtin.os.tag == .windows) {
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return Instant{ .timestamp = os.windows.QueryPerformanceCounter() };
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}
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// On WASI without libc, use clock_time_get directly.
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if (builtin.os.tag == .wasi and !builtin.link_libc) {
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var ns: os.wasi.timestamp_t = undefined;
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const rc = os.wasi.clock_time_get(os.wasi.CLOCK.MONOTONIC, 1, &ns);
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if (rc != .SUCCESS) return error.Unsupported;
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return Instant{ .timestamp = ns };
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}
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// On darwin, use UPTIME_RAW instead of MONOTONIC as it ticks while suspended.
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// On linux, use BOOTTIME instead of MONOTONIC as it ticks while suspended.
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// On freebsd derivatives, use MONOTONIC_FAST as currently there's no precision tradeoff.
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// On other posix systems, MONOTONIC is generally the fastest and ticks while suspended.
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const clock_id = switch (builtin.os.tag) {
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.macos, .ios, .tvos, .watchos => os.CLOCK.UPTIME_RAW,
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.freebsd, .dragonfly => os.CLOCK.MONOTONIC_FAST,
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.linux => os.CLOCK.BOOTTIME,
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else => os.CLOCK.MONOTONIC,
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};
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var ts: os.timespec = undefined;
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os.clock_gettime(clock_id, &ts) catch return error.Unsupported;
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return Instant{ .timestamp = ts };
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}
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/// Quickly compares two instances between each other.
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pub fn order(self: Instant, other: Instant) std.math.Order {
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// windows and wasi timestamps are in u64 which is easily comparible
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if (!is_posix) {
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return std.math.order(self.timestamp, other.timestamp);
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}
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var ord = std.math.order(self.timestamp.tv_sec, other.timestamp.tv_sec);
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if (ord == .eq) {
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ord = std.math.order(self.timestamp.tv_nsec, other.timestamp.tv_nsec);
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}
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return ord;
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}
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/// Returns elapsed time in nanoseconds since the `earlier` Instant.
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/// This assumes that the `earlier` Instant represents a moment in time before or equal to `self`.
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/// This also assumes that the time that has passed between both Instants fits inside a u64 (~585 yrs).
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pub fn since(self: Instant, earlier: Instant) u64 {
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if (builtin.os.tag == .windows) {
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// We don't need to cache QPF as it's internally just a memory read to KUSER_SHARED_DATA
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// (a read-only page of info updated and mapped by the kernel to all processes):
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// https://docs.microsoft.com/en-us/windows-hardware/drivers/ddi/ntddk/ns-ntddk-kuser_shared_data
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// https://www.geoffchappell.com/studies/windows/km/ntoskrnl/inc/api/ntexapi_x/kuser_shared_data/index.htm
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const qpc = self.timestamp - earlier.timestamp;
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const qpf = os.windows.QueryPerformanceFrequency();
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// 10Mhz (1 qpc tick every 100ns) is a common enough QPF value that we can optimize on it.
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// https://github.com/microsoft/STL/blob/785143a0c73f030238ef618890fd4d6ae2b3a3a0/stl/inc/chrono#L694-L701
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const common_qpf = 10_000_000;
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if (qpf == common_qpf) {
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return qpc * (ns_per_s / common_qpf);
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}
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// Convert to ns using fixed point.
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const scale = @as(u64, std.time.ns_per_s << 32) / @as(u32, @intCast(qpf));
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const result = (@as(u96, qpc) * scale) >> 32;
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return @as(u64, @truncate(result));
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}
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// WASI timestamps are directly in nanoseconds
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if (builtin.os.tag == .wasi and !builtin.link_libc) {
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return self.timestamp - earlier.timestamp;
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}
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// Convert timespec diff to ns
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const seconds = @as(u64, @intCast(self.timestamp.tv_sec - earlier.timestamp.tv_sec));
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const elapsed = (seconds * ns_per_s) + @as(u32, @intCast(self.timestamp.tv_nsec));
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return elapsed - @as(u32, @intCast(earlier.timestamp.tv_nsec));
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}
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};
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/// A monotonic, high performance timer.
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///
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/// Timer.start() is used to initialize the timer
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/// and gives the caller an opportunity to check for the existence of a supported clock.
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/// Once a supported clock is discovered,
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/// it is assumed that it will be available for the duration of the Timer's use.
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///
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/// Monotonicity is ensured by saturating on the most previous sample.
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/// This means that while timings reported are monotonic,
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/// they're not guaranteed to tick at a steady rate as this is up to the underlying system.
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pub const Timer = struct {
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started: Instant,
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previous: Instant,
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pub const Error = error{TimerUnsupported};
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/// Initialize the timer by querying for a supported clock.
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/// Returns `error.TimerUnsupported` when such a clock is unavailable.
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/// This should only fail in hostile environments such as linux seccomp misuse.
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pub fn start() Error!Timer {
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const current = Instant.now() catch return error.TimerUnsupported;
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return Timer{ .started = current, .previous = current };
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}
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/// Reads the timer value since start or the last reset in nanoseconds.
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pub fn read(self: *Timer) u64 {
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const current = self.sample();
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return current.since(self.started);
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}
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/// Resets the timer value to 0/now.
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pub fn reset(self: *Timer) void {
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const current = self.sample();
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self.started = current;
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}
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/// Returns the current value of the timer in nanoseconds, then resets it.
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pub fn lap(self: *Timer) u64 {
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const current = self.sample();
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defer self.started = current;
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return current.since(self.started);
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}
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/// Returns an Instant sampled at the callsite that is
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/// guaranteed to be monotonic with respect to the timer's starting point.
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fn sample(self: *Timer) Instant {
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const current = Instant.now() catch unreachable;
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if (current.order(self.previous) == .gt) {
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self.previous = current;
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}
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return self.previous;
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}
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};
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test "Timer + Instant" {
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const margin = ns_per_ms * 150;
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var timer = try Timer.start();
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sleep(10 * ns_per_ms);
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const time_0 = timer.read();
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try testing.expect(time_0 > 0);
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// Tests should not depend on timings: skip test if outside margin.
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if (!(time_0 < margin)) return error.SkipZigTest;
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const time_1 = timer.lap();
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try testing.expect(time_1 >= time_0);
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timer.reset();
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try testing.expect(timer.read() < time_1);
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}
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test {
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_ = epoch;
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}
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