564bd47132
Extends the existing Clock with the metrics a host needs to gate
time-sensitive data against the equipment's sync state (E148 §6.3):
offset_seconds() current applied offset vs system clock
last_drift_seconds() signed drift observed at the most recent sync
sync_count() how many successful syncs have happened
sync_quality() Synchronized (|drift|<=1s) /
Drifting (<=60s) / Unsynchronized (>60s or
never synced)
The thresholds are tuneable per call; the defaults match typical fab
practice but the application can pass tighter bounds for tracelog-
sensitive flows. set_time_string() now snapshots the apparent delta
between the previously-applied offset and the new one as
last_drift_seconds_ at the moment of resync; no background timer.
Three new test cases cover the initial Unsynchronized state, a large
forward drift registering as Unsynchronized, and a same-value resync
landing as Synchronized.
Co-Authored-By: Claude Opus 4.7 <noreply@anthropic.com>
129 lines
4.4 KiB
C++
129 lines
4.4 KiB
C++
#pragma once
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#include <array>
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#include <chrono>
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#include <cstdint>
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#include <cstdio>
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#include <ctime>
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#include <string>
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namespace secsgem::gem {
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enum class TimeAck : uint8_t {
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Accept = 0,
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Error = 1,
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NotDoneNotEmpty = 2,
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};
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// Sync quality: |observed drift| over the last sync-to-sync interval.
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//
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// E148 defines a "sync quality" notion that hosts use to gate whether
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// time-sensitive data (e.g. trace timestamps) is trustworthy. We
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// expose three buckets keyed off seconds-of-drift, leaving the actual
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// thresholds tuneable by the application.
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enum class TimeSyncQuality : uint8_t {
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Synchronized = 0, // |drift| <= 1s
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Drifting = 1, // |drift| <= 60s
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Unsynchronized = 2, // never synced, or |drift| > 60s
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};
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inline const char* time_sync_quality_name(TimeSyncQuality q) {
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switch (q) {
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case TimeSyncQuality::Synchronized: return "Synchronized";
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case TimeSyncQuality::Drifting: return "Drifting";
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case TimeSyncQuality::Unsynchronized: return "Unsynchronized";
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}
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return "?";
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}
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// The equipment clock. current_time_string() returns the 16-char SECS-II
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// TIME format ("YYYYMMDDhhmmsscc"), with an offset applied if the host has
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// previously set the time via S2F31. Each set_time_string() call also
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// snapshots the observed drift versus the prior sync (E148 §6.3) so the
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// host can read it as an SVID.
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class Clock {
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public:
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std::string current_time_string() const {
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using namespace std::chrono;
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const auto now = system_clock::now() + seconds(offset_seconds_);
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const auto t = system_clock::to_time_t(now);
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const auto ms = duration_cast<milliseconds>(now.time_since_epoch()) % 1000;
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std::tm tm{};
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gmtime_r(&t, &tm);
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std::array<char, 64> buf{};
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std::snprintf(buf.data(), buf.size(), "%04d%02d%02d%02d%02d%02d%02d",
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tm.tm_year + 1900, tm.tm_mon + 1, tm.tm_mday,
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tm.tm_hour, tm.tm_min, tm.tm_sec,
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static_cast<int>(ms.count() / 10));
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return std::string(buf.data());
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}
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TimeAck set_time_string(const std::string& s) {
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if (s.size() != 14 && s.size() != 16) return TimeAck::Error;
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int y, mo, d, h, mi, se;
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if (!parse_digits(s.data() + 0, 4, y) ||
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!parse_digits(s.data() + 4, 2, mo) ||
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!parse_digits(s.data() + 6, 2, d) ||
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!parse_digits(s.data() + 8, 2, h) ||
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!parse_digits(s.data() + 10, 2, mi) ||
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!parse_digits(s.data() + 12, 2, se)) {
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return TimeAck::Error;
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}
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std::tm tm{};
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tm.tm_year = y - 1900;
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tm.tm_mon = mo - 1;
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tm.tm_mday = d;
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tm.tm_hour = h;
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tm.tm_min = mi;
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tm.tm_sec = se;
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const std::time_t target = timegm(&tm);
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if (target == static_cast<std::time_t>(-1)) return TimeAck::Error;
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// Drift = what we *would have* reported just before the new sync vs
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// what the host just told us. Magnitude of the previously-applied
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// offset added to the new offset gives the apparent delta.
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const std::time_t now_real = std::time(nullptr);
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const std::int64_t new_offset =
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static_cast<std::int64_t>(target - now_real);
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last_drift_seconds_ = new_offset - offset_seconds_;
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offset_seconds_ = new_offset;
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++sync_count_;
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return TimeAck::Accept;
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}
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// E148 metrics. drift is signed; quality buckets it. sync_count is
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// 0 until the first successful set_time_string().
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std::int64_t offset_seconds() const { return offset_seconds_; }
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std::int64_t last_drift_seconds() const { return last_drift_seconds_; }
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std::uint64_t sync_count() const { return sync_count_; }
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TimeSyncQuality sync_quality(std::int64_t synchronized_threshold = 1,
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std::int64_t drifting_threshold = 60) const {
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if (sync_count_ == 0) return TimeSyncQuality::Unsynchronized;
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const std::int64_t mag =
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last_drift_seconds_ < 0 ? -last_drift_seconds_ : last_drift_seconds_;
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if (mag <= synchronized_threshold) return TimeSyncQuality::Synchronized;
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if (mag <= drifting_threshold) return TimeSyncQuality::Drifting;
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return TimeSyncQuality::Unsynchronized;
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}
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private:
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static bool parse_digits(const char* p, std::size_t n, int& out) {
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int v = 0;
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for (std::size_t i = 0; i < n; ++i) {
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if (p[i] < '0' || p[i] > '9') return false;
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v = v * 10 + (p[i] - '0');
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}
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out = v;
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return true;
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}
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std::int64_t offset_seconds_ = 0;
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std::int64_t last_drift_seconds_ = 0;
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std::uint64_t sync_count_ = 0;
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};
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} // namespace secsgem::gem
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