mh
/
mhsw-espurna

/*

RPN RULES MODULEUse RPNLib library (https://github.com/xoseperez/rpnlib)
Copyright (C) 2019 by Xose Pérez <xose dot perez at gmail dot com>
*/
#include "rpnrules.h"

#if RPN_RULES_SUPPORT

#include <rpnlib.h>

#include "light.h"
#include "mqtt.h"
#include "ntp.h"
#include "ntp_timelib.h"
#include "relay.h"
#include "rfbridge.h"
#include "rpc.h"
#include "rtcmem.h"
#include "sensor.h"
#include "terminal.h"
#include "wifi.h"
#include "ws.h"

#include <list>
#include <type_traits>
#include <vector>

// -----------------------------------------------------------------------------
// Custom commands
// -----------------------------------------------------------------------------

rpn_context _rpn_ctxt;bool _rpn_run = false;unsigned long _rpn_delay = RPN_DELAY;unsigned long _rpn_last = 0;
struct RpnRunner {    enum class Policy {        OneShot,        Periodic    };
    RpnRunner(Policy policy_, uint32_t period_) :        policy(policy_),        period(period_),        last(millis())    {}
    Policy policy { Policy::Periodic };
    uint32_t period { 0ul };    uint32_t last { 0ul };
    bool expired { false };};
std::vector<RpnRunner> _rpn_runners;
rpn_operator_error _rpnRunnerHandler(rpn_context & ctxt, RpnRunner::Policy policy, uint32_t time) {    for (auto& runner : _rpn_runners) {        if ((policy == runner.policy) && (time == runner.period)) {            return runner.expired                ? rpn_operator_error::Ok                : rpn_operator_error::CannotContinue;        }    }
    _rpn_runners.emplace_back(policy, time);
    return rpn_operator_error::CannotContinue;}
// -----------------------------------------------------------------------------

bool _rpnWebSocketOnKeyCheck(const char * key, JsonVariant& value) {    return (strncmp(key, "rpn", 3) == 0);}
void _rpnWebSocketOnConnected(JsonObject& root) {
    root["rpnSticky"] = getSetting("rpnSticky", 1 == RPN_STICKY);    root["rpnDelay"] = getSetting("rpnDelay", RPN_DELAY);    JsonArray& rules = root.createNestedArray("rpnRules");
    unsigned char i = 0;    String rule = getSetting({"rpnRule", i});    while (rule.length()) {        rules.add(rule);        rule = getSetting({"rpnRule", ++i});    }
    #if MQTT_SUPPORT
        i=0;        JsonArray& topics = root.createNestedArray("rpnTopics");        JsonArray& names = root.createNestedArray("rpnNames");        String rpn_topic = getSetting({"rpnTopic", i});        while (rpn_topic.length() > 0) {            String rpn_name = getSetting({"rpnName", i});            topics.add(rpn_topic);            names.add(rpn_name);            rpn_topic = getSetting({"rpnTopic", ++i});        }    #endif

}
#if MQTT_SUPPORT

void _rpnMQTTSubscribe() {    unsigned char i = 0;    String rpn_topic = getSetting({"rpnTopic", i});    while (rpn_topic.length()) {        mqttSubscribeRaw(rpn_topic.c_str());        rpn_topic = getSetting({"rpnTopic", ++i});    }}
void _rpnMQTTCallback(unsigned int type, const char * topic, const char * payload) {
    if (type == MQTT_CONNECT_EVENT) {        _rpnMQTTSubscribe();    }
    if (type == MQTT_MESSAGE_EVENT) {        unsigned char i = 0;        String rpn_topic = getSetting({"rpnTopic", i});        while (rpn_topic.length()) {            if (rpn_topic.equals(topic)) {                String rpn_name = getSetting({"rpnName", i});                if (rpn_name.length()) {                    rpn_value value { atof(payload) };                    rpn_variable_set(_rpn_ctxt, rpn_name, value);                    _rpn_run = true;                    break;                }            }            rpn_topic = getSetting({"rpnTopic", ++i});        }    }
}#endif // MQTT_SUPPORT

void _rpnConfigure() {#if MQTT_SUPPORT
    if (mqttConnected()) {        _rpnMQTTSubscribe();    }#endif
    _rpn_delay = getSetting("rpnDelay", RPN_DELAY);}
void _rpnRelayStatus(size_t id, bool status) {    char name[32] = {0};    snprintf(name, sizeof(name), "relay%u", id);
    rpn_variable_set(_rpn_ctxt, name, rpn_value(std::forward<T>(value)));    _rpn_run = true;}
void _rpnLightStatus() {    auto channels = lightChannels();
    char name[32] = {0};    for (decltype(channels) channel = 0; channel < channels; ++channel) {        snprintf(name, sizeof(name), "channel%u", channel);        rpn_variable_set(_rpn_ctxt, name, rpn_value(lightChannel(channel)));    }
    _rpn_run = true;}
#if NTP_SUPPORT

namespace {
constexpr bool time_t_is_32bit { sizeof(time_t) == 4 };constexpr bool time_t_is_64bit { sizeof(time_t) == 8 };static_assert(time_t_is_32bit || time_t_is_64bit, "");
template <typename T>using split_t = std::integral_constant<bool, sizeof(T) == 8>;
using RpnNtpFunc = rpn_int(*)(time_t);
rpn_error _rpnNtpPopTimestampPair(rpn_context& ctxt, RpnNtpFunc func) {    rpn_value rhs = rpn_stack_pop(ctxt);    rpn_value lhs = rpn_stack_pop(ctxt);
    auto timestamp = (static_cast<long long>(lhs.toInt()) << 32ll)        | (static_cast<long long>(rhs.toInt()));
    rpn_value value(func(timestamp));    rpn_stack_push(ctxt, value);
    return 0;}
rpn_error _rpnNtpPopTimestampSingle(rpn_context& ctxt, RpnNtpFunc func) {    rpn_value input = rpn_stack_pop(ctxt);    rpn_value result(func(input.toInt()));    rpn_stack_push(ctxt, result);    return 0;}
void _rpnNtpPushTimestampPair(rpn_context& ctxt, time_t timestamp) {    rpn_value lhs(static_cast<rpn_int>((static_cast<long long>(timestamp) >> 32ll) & 0xffffffffll));    rpn_value rhs(static_cast<rpn_int>(static_cast<long long>(timestamp) & 0xffffffffll));
    rpn_stack_push(ctxt, lhs);    rpn_stack_push(ctxt, rhs);}
void _rpnNtpPushTimestampSingle(rpn_context& ctxt, time_t timestamp) {    rpn_value result(static_cast<rpn_int>(timestamp));    rpn_stack_push(ctxt, result);}
inline rpn_error _rpnNtpPopTimestamp(const std::true_type&, rpn_context& ctxt, RpnNtpFunc func) {    return _rpnNtpPopTimestampPair(ctxt, func);}
inline rpn_error _rpnNtpPopTimestamp(const std::false_type&, rpn_context& ctxt, RpnNtpFunc func) {    return _rpnNtpPopTimestampSingle(ctxt, func);}
rpn_error _rpnNtpPopTimestamp(rpn_context& ctxt, RpnNtpFunc func) {    return _rpnNtpPopTimestamp(split_t<time_t>{}, ctxt, func);}
inline void _rpnNtpPushTimestamp(const std::true_type&, rpn_context& ctxt, time_t timestamp) {    _rpnNtpPushTimestampPair(ctxt, timestamp);}
inline void _rpnNtpPushTimestamp(const std::false_type&, rpn_context& ctxt, time_t timestamp) {    _rpnNtpPushTimestampSingle(ctxt, timestamp);}
void _rpnNtpPushTimestamp(rpn_context& ctxt, time_t timestamp) {    _rpnNtpPushTimestamp(split_t<time_t>{}, ctxt, timestamp);}
rpn_error _rpnNtpNow(rpn_context & ctxt) {    if (ntpSynced()) {        _rpnNtpPushTimestamp(ctxt, now());        return 0;    }
    return rpn_operator_error::CannotContinue;}
rpn_error _rpnNtpFunc(rpn_context & ctxt, RpnNtpFunc func) {    return _rpnNtpPopTimestamp(ctxt, func);}
bool _rpn_ntp_tick_minute { false };bool _rpn_ntp_tick_hour { false };
rpn_error _rpnNtpTickMinute(rpn_context& ctxt) {    if (_rpn_ntp_tick_minute) {        _rpn_ntp_tick_minute = false;        return 0;    }
    return rpn_operator_error::CannotContinue;}
rpn_error _rpnNtpTickHour(rpn_context& ctxt) {    if (_rpn_ntp_tick_hour) {        _rpn_ntp_tick_hour = false;        return 0;    }
    return rpn_operator_error::CannotContinue;}
} // namespace

#endif // NTP_SUPPORT

String _rpnValueToString(const rpn_value& value) {    String out;    if (value.isString()) {        out = value.toString();    } else if (value.isFloat()) {        out = String(value.toFloat(), 10);    } else if (value.isInt()) {        out = String(value.toInt(), 10);    } else if (value.isUint()) {        out = String(value.toUint(), 10);    } else if (value.isBoolean()) {        out = String(value.toBoolean() ? "true" : "false");    } else if (value.isNull()) {        out = F("(null)");    }    return out;}
char _rpnStackTypeTag(rpn_stack_value::Type type) {    switch (type) {    case rpn_stack_value::Type::None:        return 'N';    case rpn_stack_value::Type::Variable:        return '$';    case rpn_stack_value::Type::Array:        return 'A';    case rpn_stack_value::Type::Value:    default:        return ' ';    }}
#if RELAY_SUPPORT

rpn_error _rpnRelayStatus(rpn_context & ctxt, bool force) {    rpn_value id;    rpn_value status;
    rpn_stack_pop(ctxt, id);    rpn_stack_pop(ctxt, status);
    rpn_uint value = status.toUint();    if (value == 2) {        relayToggle(id.toUint());    } else if (relayStatusTarget(id.toUint()) != (value == 1)) {        relayStatus(id.toUint(), value == 1);    }
    return 0;}
#endif // RELAY_SUPPORT

#if RFB_SUPPORT

struct rpn_rfbridge_code {    unsigned char protocol;    String raw;    size_t count;    decltype(millis()) last;};
// TODO: in theory, we could do with forward_list. however, this would require a more complicated removal process,
//       as we would no longer know the previous element and would need to track 2 elements at a time
static std::list<rpn_rfbridge_code> _rfb_codes;
static uint32_t _rfb_code_repeat_window;static uint32_t _rfb_code_stale_delay;
static uint32_t _rfb_code_match_window;
struct rpn_rfbridge_match {    unsigned char protocol;    String raw;};
rpn_error _rpnRfbSequence(rpn_context& ctxt) {    auto raw_second = rpn_stack_pop(ctxt);    auto proto_second = rpn_stack_pop(ctxt);
    auto raw_first = rpn_stack_pop(ctxt);    auto proto_first = rpn_stack_pop(ctxt);
    // find 2 codes in the same order and save pointers
    rpn_rfbridge_match match[2] {        {static_cast<unsigned char>(proto_first.toUint()), raw_first.toString()},        {static_cast<unsigned char>(proto_second.toUint()), raw_second.toString()}    };    rpn_rfbridge_code* refs[2] {nullptr, nullptr};
    for (auto& recent : _rfb_codes) {        if ((refs[0] != nullptr) && (refs[1] != nullptr)) {            break;        }        for (int index = 0; index < 2; ++index) {            if ((refs[index] == nullptr)             && (match[index].protocol == recent.protocol)             && (match[index].raw == recent.raw)) {                refs[index] = &recent;            }        }    }
    if ((refs[0] == nullptr) || (refs[1] == nullptr)) {        return rpn_operator_error::CannotContinue;    }
    // purge codes to avoid matching again on the next rules run
    if ((millis() - refs[0]->last) > (millis() - refs[1]->last)) {        _rfb_codes.remove_if([&refs](rpn_rfbridge_code& code) {            return (refs[0] == &code) || (refs[1] == &code);        });        return rpn_operator_error::Ok;    }
    return rpn_operator_error::CannotContinue;}
decltype(_rfb_codes)::iterator _rpnRfbFindCode(unsigned char protocol, const String& match) {    return std::find_if(_rfb_codes.begin(), _rfb_codes.end(), [protocol, &match](const rpn_rfbridge_code& code) {        return (code.protocol == protocol) && (code.raw == match);    });}
rpn_error _rpnRfbSend(rpn_context& ctxt) {    auto code = rpn_stack_pop(ctxt);    if (!code.isString()) {        return rpn_operator_error::InvalidArgument;    }
    rfbSend(code.toString());    return rpn_operator_error::Ok;}
rpn_error _rpnRfbPop(rpn_context& ctxt) {    auto code = rpn_stack_pop(ctxt);    auto proto = rpn_stack_pop(ctxt);
    auto result = _rpnRfbFindCode(proto.toUint(), code.toString());    if (result == _rfb_codes.end()) {        return rpn_operator_error::CannotContinue;    }
    _rfb_codes.erase(result);    return rpn_operator_error::Ok;}
rpn_error _rpnRfbInfo(rpn_context& ctxt) {    auto code = rpn_stack_pop(ctxt);    auto proto = rpn_stack_pop(ctxt);
    auto result = _rpnRfbFindCode(proto.toUint(), code.toString());    if (result == _rfb_codes.end()) {        return rpn_operator_error::CannotContinue;    }
    rpn_stack_push(ctxt, rpn_value(        static_cast<rpn_uint>((*result).count)));    rpn_stack_push(ctxt, rpn_value(        static_cast<rpn_uint>((*result).last)));
    return rpn_operator_error::Ok;}
rpn_error _rpnRfbWaitMatch(rpn_context& ctxt) {    auto code = rpn_stack_pop(ctxt);    auto proto = rpn_stack_pop(ctxt);    auto count = rpn_stack_pop(ctxt);    auto time = rpn_stack_pop(ctxt);
    auto result = _rpnRfbFindCode(proto.toUint(), code.toString());    if (result == _rfb_codes.end()) {        return rpn_operator_error::CannotContinue;    }
    if ((*result).count < count.toUint()) {        return rpn_operator_error::CannotContinue;    }
    // purge code to avoid matching again on the next rules run
    if (rpn_operator_error::Ok == _rpnRunnerHandler(ctxt, RpnRunner::Policy::OneShot, time.toUint())) {        _rfb_codes.erase(result);        return rpn_operator_error::Ok;    }
    return rpn_operator_error::CannotContinue;}
rpn_error _rpnRfbMatcher(rpn_context& ctxt) {    auto code = rpn_stack_pop(ctxt);    auto proto = rpn_stack_pop(ctxt);    auto count = rpn_stack_pop(ctxt);
    auto result = _rpnRfbFindCode(proto.toUint(), code.toString());    if (result == _rfb_codes.end()) {        return rpn_operator_error::CannotContinue;    }
    // only process recent codes, ignore when rule is processing outside of this small window
    if (millis() - (*result).last >= _rfb_code_match_window) {        return rpn_operator_error::CannotContinue;    }
    // purge code to avoid matching again on the next rules run
    if ((*result).count == count.toUint()) {        _rfb_codes.erase(result);        return rpn_operator_error::Ok;    }
    return rpn_operator_error::CannotContinue;}
void _rpnBrokerRfbridgeCallback(unsigned char protocol, const char* raw_code) {
    // remove really old codes that we have not seen in a while to avoid memory exhaustion
    auto ts = millis();    auto old = std::remove_if(_rfb_codes.begin(), _rfb_codes.end(), [ts](rpn_rfbridge_code& code) {        return (ts - code.last) >= _rfb_code_stale_delay;    });
    if (old != _rfb_codes.end()) {        _rfb_codes.erase(old, _rfb_codes.end());    }
    auto result = _rpnRfbFindCode(protocol, raw_code);    if (result != _rfb_codes.end()) {        // we also need to reset the counter at a certain point to allow next batch of repeats to go through
        if (millis() - (*result).last >= _rfb_code_repeat_window) {            (*result).count = 0;        }        (*result).last = millis();        (*result).count += 1u;    } else {        _rfb_codes.push_back({protocol, raw_code, 1u, millis()});    }
    _rpn_run = true;}
void _rpnRfbSetup() {    // - Repeat window is an arbitrary time, just about 3-4 more times it takes for
    //   a code to be sent again when holding a generic remote button
    //   Code counter is reset to 0 when outside of the window.
    // - Stale delay allows broker callback to remove really old codes.
    //   (TODO: can this happen in loop() cb instead?)
    _rfb_code_repeat_window = getSetting("rfbRepeatWindow", 2000ul);    _rfb_code_match_window = getSetting("rfbMatchWindow", 2000ul);    _rfb_code_stale_delay = getSetting("rfbStaleDelay", 10000ul);
#if TERMINAL_SUPPORT
    terminalRegisterCommand(F("RFB.CODES"), [](const terminal::CommandContext& ctx) {        for (auto& code : _rfb_codes) {            char buffer[128] = {0};            snprintf_P(buffer, sizeof(buffer),                PSTR("proto=%u raw=\"%s\" count=%u last=%u"),                code.protocol,                code.raw.c_str(),                code.count,                code.last            );            ctx.output.println(buffer);        }    });#endif

    // Main bulk of the processing goes on in here
    RfbridgeBroker::Register(_rpnBrokerRfbridgeCallback);}
#endif // RFB_SUPPORT

void _rpnShowStack(Print& print) {    print.println(F("Stack:"));
    auto index = rpn_stack_size(_rpn_ctxt);    if (!index) {        print.println(F("      (empty)"));        return;    }
    rpn_stack_foreach(_rpn_ctxt, [&index, &print](rpn_stack_value::Type type, const rpn_value& value) {        print.printf("%c      %02u: %s\n",            _rpnStackTypeTag(type), index--,            _rpnValueToString(value).c_str()        );    });}
void _rpnInit() {
    // Init context
    rpn_init(_rpn_ctxt);
    // Time functions need NTP support
    // TODO: since 1.15.0, timelib+ntpclientlib are no longer used with latest Cores
    //       `now` is always in UTC, `utc_...` functions to be used instead to convert time
    #if NTP_SUPPORT && !NTP_LEGACY_SUPPORT
    {        constexpr size_t time_t_argc { split_t<time_t>{} ? 2 : 1 };
        rpn_operator_set(_rpn_ctxt, "tick_1h", 0, _rpnNtpTickHour);        rpn_operator_set(_rpn_ctxt, "tick_1m", 0, _rpnNtpTickMinute);
        rpn_operator_set(_rpn_ctxt, "utc", 0, _rpnNtpNow);        rpn_operator_set(_rpn_ctxt, "now", 0, _rpnNtpNow);
        rpn_operator_set(_rpn_ctxt, "utc_month", time_t_argc, [](rpn_context & ctxt) {            return _rpnNtpFunc(ctxt, utc_month);        });        rpn_operator_set(_rpn_ctxt, "month", time_t_argc, [](rpn_context & ctxt) {            return _rpnNtpFunc(ctxt, month);        });
        rpn_operator_set(_rpn_ctxt, "utc_day", time_t_argc, [](rpn_context & ctxt) {            return _rpnNtpFunc(ctxt, utc_day);        });        rpn_operator_set(_rpn_ctxt, "day", time_t_argc, [](rpn_context & ctxt) {            return _rpnNtpFunc(ctxt, day);        });
        rpn_operator_set(_rpn_ctxt, "utc_dow", time_t_argc, [](rpn_context & ctxt) {            return _rpnNtpFunc(ctxt, utc_weekday);        });        rpn_operator_set(_rpn_ctxt, "dow", time_t_argc, [](rpn_context & ctxt) {            return _rpnNtpFunc(ctxt, weekday);        });
        rpn_operator_set(_rpn_ctxt, "utc_hour", time_t_argc, [](rpn_context & ctxt) {            return _rpnNtpFunc(ctxt, utc_hour);        });        rpn_operator_set(_rpn_ctxt, "hour", time_t_argc, [](rpn_context & ctxt) {            return _rpnNtpFunc(ctxt, hour);        });
        rpn_operator_set(_rpn_ctxt, "utc_minute", time_t_argc, [](rpn_context & ctxt) {            return _rpnNtpFunc(ctxt, utc_minute);        });        rpn_operator_set(_rpn_ctxt, "minute", time_t_argc, [](rpn_context & ctxt) {            return _rpnNtpFunc(ctxt, minute);        });    }    #endif

    // TODO: 1.14.0 weekday(...) conversion seemed to have 0..6 range with Monday as 0
    //       using classic Sunday as first, but instead of 0 it is 1
    //       Implementation above also uses 1 for Sunday, staying compatible with TimeLib
    #if NTP_SUPPORT && NTP_LEGACY_SUPPORT
        rpn_operator_set(_rpn_ctxt, "utc", 0, [](rpn_context & ctxt) -> rpn_error {            if (!ntpSynced()) return rpn_operator_error::CannotContinue;            rpn_value ts { static_cast<rpn_int>(ntpLocal2UTC(now())) };            rpn_stack_push(ctxt, ts);            return 0;        });        rpn_operator_set(_rpn_ctxt, "now", 0, _rpnNtpNow);
        rpn_operator_set(_rpn_ctxt, "month", 1, [](rpn_context & ctxt) {            return _rpnNtpFunc(ctxt, month);        });        rpn_operator_set(_rpn_ctxt, "day", 1, [](rpn_context & ctxt) {            return _rpnNtpFunc(ctxt, day);        });        rpn_operator_set(_rpn_ctxt, "dow", 1, [](rpn_context & ctxt) {            return _rpnNtpFunc(ctxt, weekday);        });        rpn_operator_set(_rpn_ctxt, "hour", 1, [](rpn_context & ctxt) {            return _rpnNtpFunc(ctxt, hour);        });        rpn_operator_set(_rpn_ctxt, "minute", 1, [](rpn_context & ctxt) {            return _rpnNtpFunc(ctxt, minute);        });    #endif

    // Accept relay number and numeric API status value (0, 1 and 2)
    #if RELAY_SUPPORT

        // apply status and reset timers when called
        rpn_operator_set(_rpn_ctxt, "relay_reset", 2, [](rpn_context & ctxt) {            return _rpnRelayStatus(ctxt, true);        });
        // only update status when target status differs, keep running timers
        rpn_operator_set(_rpn_ctxt, "relay", 2, [](rpn_context & ctxt) {            return _rpnRelayStatus(ctxt, false);        });
    #endif // RELAY_SUPPORT == 1

    // Channel operators
    #if LIGHT_PROVIDER != LIGHT_PROVIDER_NONE

        rpn_operator_set(_rpn_ctxt, "update", 0, [](rpn_context & ctxt) -> rpn_error {            lightUpdate();            return 0;        });
        rpn_operator_set(_rpn_ctxt, "black", 0, [](rpn_context & ctxt) -> rpn_error {            lightColor(0ul);            return 0;        });
        rpn_operator_set(_rpn_ctxt, "channel", 2, [](rpn_context & ctxt) -> rpn_error {            rpn_value value;            rpn_value id;            rpn_stack_pop(ctxt, id);            rpn_stack_pop(ctxt, value);            lightChannel(id.toUint(), id.toInt());            return 0;        });
    #endif

    #if RFB_SUPPORT
        rpn_operator_set(_rpn_ctxt, "rfb_send", 1, _rpnRfbSend);        rpn_operator_set(_rpn_ctxt, "rfb_pop", 2, _rpnRfbPop);        rpn_operator_set(_rpn_ctxt, "rfb_info", 2, _rpnRfbInfo);        rpn_operator_set(_rpn_ctxt, "rfb_sequence", 4, _rpnRfbSequence);        rpn_operator_set(_rpn_ctxt, "rfb_match", 3, _rpnRfbMatcher);        rpn_operator_set(_rpn_ctxt, "rfb_match_wait", 4, _rpnRfbWaitMatch);    #endif

    #if MQTT_SUPPORT
        rpn_operator_set(_rpn_ctxt, "mqtt_send", 2, [](rpn_context & ctxt) -> rpn_error {            rpn_value message;            rpn_stack_pop(ctxt, message);
            rpn_value topic;            rpn_stack_pop(ctxt, topic);
            return mqttSendRaw(topic.toString().c_str(), message.toString().c_str())                ? rpn_operator_error::Ok                : rpn_operator_error::CannotContinue;        });    #endif

    // Some debugging. Dump stack contents
    #if TERMINAL_SUPPORT
        rpn_operator_set(_rpn_ctxt, "showstack", 0, [](rpn_context & ctxt) -> rpn_error {            _rpnShowStack(terminalDefaultStream());            return 0;        });    #endif

    // And, simple string logging
    #if DEBUG_SUPPORT
        rpn_operator_set(_rpn_ctxt, "dbgmsg", 1, [](rpn_context & ctxt) -> rpn_error {            rpn_value message;            rpn_stack_pop(ctxt, message);
            DEBUG_MSG_P(PSTR("[RPN] %s\n"), message.toString().c_str());
            return 0;        });    #endif

    rpn_operator_set(_rpn_ctxt, "mem?", 0, [](rpn_context & ctxt) -> rpn_error {        rpn_stack_push(ctxt, rpn_value(rtcmemStatus()));        return 0;    });
    rpn_operator_set(_rpn_ctxt, "mem_write", 2, [](rpn_context & ctxt) -> rpn_error {        auto addr = rpn_stack_pop(ctxt).toUint();        auto value = rpn_stack_pop(ctxt).toUint();
        if (addr < RTCMEM_BLOCKS) {            auto* rtcmem = reinterpret_cast<volatile uint32_t*>(RTCMEM_ADDR);            *(rtcmem + addr) = value;            return 0;        }
        return rpn_operator_error::InvalidArgument;    });
    rpn_operator_set(_rpn_ctxt, "mem_read", 1, [](rpn_context & ctxt) -> rpn_error {        auto addr = rpn_stack_pop(ctxt).toUint();
        if (addr < RTCMEM_BLOCKS) {            auto* rtcmem = reinterpret_cast<volatile uint32_t*>(RTCMEM_ADDR);            rpn_uint result = *(rtcmem + addr);            rpn_stack_push(ctxt, rpn_value(result));            return 0;        }
        return rpn_operator_error::InvalidArgument;    });
    rpn_operator_set(_rpn_ctxt, "sleep", 2, [](rpn_context & ctxt) -> rpn_error {        static bool once { false };        if (once) return rpn_operator_error::CannotContinue;
        auto value = rpn_stack_pop(ctxt).checkedToUint();        if (!value.ok()) {            return value.error();        }
        uint64_t duration = value.value();        if (!duration) {            return rpn_operator_error::CannotContinue;        }
        auto mode = rpn_stack_pop(ctxt).toUint();
        once = true;        schedule_function([duration, mode]() {            wifiTurnOff();            ESP.deepSleep(duration * 1000000ull, static_cast<RFMode>(mode));        });
        return 0;    });
    rpn_operator_set(_rpn_ctxt, "stations", 0, [](rpn_context & ctxt) -> rpn_error {        if (!(WiFi.getMode() & WIFI_AP)) return rpn_operator_error::CannotContinue;        rpn_stack_push(ctxt, rpn_value(static_cast<rpn_uint>(WiFi.softAPgetStationNum())));        return 0;    });
    rpn_operator_set(_rpn_ctxt, "disconnect", 0, [](rpn_context & ctxt) -> rpn_error {        wifiDisconnect();        yield();        return 0;    });
    rpn_operator_set(_rpn_ctxt, "rssi", 0, [](rpn_context & ctxt) -> rpn_error {        if (!wifiConnected()) return rpn_operator_error::CannotContinue;        rpn_stack_push(ctxt, rpn_value(static_cast<rpn_int>(WiFi.RSSI())));        return 0;    });
    rpn_operator_set(_rpn_ctxt, "delay", 1, [](rpn_context & ctxt) -> rpn_error {        auto ms = rpn_stack_pop(ctxt);        delay(ms.toUint());        return 0;    });
    rpn_operator_set(_rpn_ctxt, "yield", 0, [](rpn_context & ctxt) -> rpn_error {        yield();        return 0;    });
    rpn_operator_set(_rpn_ctxt, "reset", 0, [](rpn_context & ctxt) -> rpn_error {        static bool once = ([]() {            deferredReset(100, CustomResetReason::Rule);            return true;        })();        return once            ? rpn_operator_error::CannotContinue            : rpn_operator_error::Ok;    });
    rpn_operator_set(_rpn_ctxt, "millis", 0, [](rpn_context & ctxt) -> rpn_error {        rpn_stack_push(ctxt, rpn_value(static_cast<uint32_t>(millis())));        return 0;    });
    rpn_operator_set(_rpn_ctxt, "oneshot_ms", 1, [](rpn_context & ctxt) -> rpn_error {        auto every = rpn_stack_pop(ctxt);        return _rpnRunnerHandler(ctxt, RpnRunner::Policy::OneShot, every.toUint());    });
    rpn_operator_set(_rpn_ctxt, "every_ms", 1, [](rpn_context & ctxt) -> rpn_error {        auto every = rpn_stack_pop(ctxt);        return _rpnRunnerHandler(ctxt, RpnRunner::Policy::Periodic, every.toUint());    });
    // XXX: workaround for the vector 2x growth on push. will need to fix this in the rpnlib
    _rpn_ctxt.operators.shrink_to_fit();
    DEBUG_MSG_P(PSTR("[RPN] Registered %u operators\n"), _rpn_ctxt.operators.size());
}
#if TERMINAL_SUPPORT

void _rpnInitCommands() {
    terminalRegisterCommand(F("RPN.RUNNERS"), [](const terminal::CommandContext& ctx) {        if (!_rpn_runners.size()) {            terminalError(ctx, F("No active runners"));            return;        }
        for (auto& runner : _rpn_runners) {            char buffer[128] = {0};            snprintf_P(buffer, sizeof(buffer), PSTR("%p %s %u ms, last %u ms"),                &runner, (RpnRunner::Policy::Periodic == runner.policy) ? "every" : "one-shot",                runner.period, runner.last            );            ctx.output.println(buffer);        }
        terminalOK(ctx);    });
    terminalRegisterCommand(F("RPN.VARS"), [](const terminal::CommandContext& ctx) {        rpn_variables_foreach(_rpn_ctxt, [&ctx](const String& name, const rpn_value& value) {            char buffer[256] = {0};            snprintf_P(buffer, sizeof(buffer), PSTR("      %s: %s"), name.c_str(), _rpnValueToString(value).c_str());            ctx.output.println(buffer);        });        terminalOK(ctx);    });
    terminalRegisterCommand(F("RPN.OPS"), [](const terminal::CommandContext& ctx) {        rpn_operators_foreach(_rpn_ctxt, [&ctx](const String& name, size_t argc, rpn_operator::callback_type) {            char buffer[128] = {0};            snprintf_P(buffer, sizeof(buffer), PSTR("      %s (%d)"), name.c_str(), argc);            ctx.output.println(buffer);        });        terminalOK(ctx);    });
    terminalRegisterCommand(F("RPN.TEST"), [](const terminal::CommandContext& ctx) {        if (ctx.argc != 2) {            terminalError(F("Wrong arguments"));            return;        }
        ctx.output.print(F("Running RPN expression: "));        ctx.output.println(ctx.argv[1].c_str());
        if (!rpn_process(_rpn_ctxt, ctx.argv[1].c_str())) {            rpn_stack_clear(_rpn_ctxt);            char buffer[64] = {0};            snprintf_P(buffer, sizeof(buffer), PSTR("position=%u category=%d code=%d"),                _rpn_ctxt.error.position, static_cast<int>(_rpn_ctxt.error.category), _rpn_ctxt.error.code);            terminalError(ctx, buffer);            return;        }
        _rpnShowStack(ctx.output);        rpn_stack_clear(_rpn_ctxt);
        terminalOK(ctx);    });
}#endif

// enables us to use rules without any events firing
// notice: requires rpnRun to trigger at least once so that we can install runners
void _rpnRunnersCheck() {    auto ts = millis();    for (auto& runner : _rpn_runners) {        if (ts - runner.last >= runner.period) {            runner.expired = true;            runner.last = ts;            _rpn_run = true;        }    }}
void _rpnRunnersReset() {    auto old = std::remove_if(_rpn_runners.begin(), _rpn_runners.end(), [](RpnRunner& runner) {        return (RpnRunner::Policy::OneShot == runner.policy) && runner.expired;    });
    if (old != _rpn_runners.end()) {        _rpn_runners.erase(old, _rpn_runners.end());    }
    for (auto& runner : _rpn_runners) {        runner.expired = false;    }}
void _rpnRun() {
    if (!_rpn_run) {        return;    }
    if (millis() - _rpn_last <= _rpn_delay) {        return;    }
    _rpn_last = millis();    _rpn_run = false;
    String rule;    unsigned char i = 0;    while ((rule = getSetting({"rpnRule", i++})).length()) {        rpn_process(_rpn_ctxt, rule.c_str());        rpn_stack_clear(_rpn_ctxt);    }
    if (!getSetting("rpnSticky", 1 == RPN_STICKY)) {        rpn_variables_clear(_rpn_ctxt);    }
}
void _rpnLoop() {
    _rpnRunnersCheck();    _rpnRun();    _rpnRunnersReset();
}
void rpnSetup() {
    // Init context
    _rpnInit();
    // Load & cache settings
    _rpnConfigure();
    // Terminal commands
    #if TERMINAL_SUPPORT
        _rpnInitCommands();    #endif

    // Websockets
    #if WEB_SUPPORT
        wsRegister()            .onVisible([](JsonObject& root) { root["rpnVisible"] = 1; })            .onConnected(_rpnWebSocketOnConnected)            .onKeyCheck(_rpnWebSocketOnKeyCheck);    #endif

    // MQTT
    #if MQTT_SUPPORT
        mqttRegister(_rpnMQTTCallback);    #endif

#if NTP_SUPPORT
    NtpBroker::Register([](NtpTick tick, time_t, const String&) {        switch (tick) {        case NtpTick::EveryMinute:            _rpn_ntp_tick_minute = true;            break;        case NtpTick::EveryHour:            _rpn_ntp_tick_hour = true;            break;        }        _rpn_run = true;    });#endif

#if RELAY_SUPPORT
    relaySetStatusChange(_rpnRelayStatus);#endif

#if LIGHT_PROVIDER != LIGHT_PROVIDER_NONE
    lightSetReportListener(_rpnLightStatus);#endif

    #if RFB_SUPPORT
        _rpnRfbSetup();    #endif

    #if SENSOR_SUPPORT
        SensorReadBroker::Register(_rpnBrokerCallback);    #endif

    espurnaRegisterReload(_rpnConfigure);    espurnaRegisterLoop(_rpnLoop);
    _rpn_last = millis();    _rpn_run = true;
}
#endif // RPN_RULES_SUPPORT