/*! * \file com/sequencer.h * \brief * A script based automation tool for send/receive communications * * \copyright Copyright (C) 2021 Christos Choutouridis * *
License
* The MIT License (MIT) * * Permission is hereby granted, free of charge, to any person obtaining a copy * of this software and associated documentation files (the "Software"), to deal * in the Software without restriction, including without limitation the rights * to use, copy, modify, merge, publish, distribute, sublicense, and/or sell * copies of the Software, and to permit persons to whom the Software is * furnished to do so, subject to the following conditions: * * The above copyright notice and this permission notice shall be included in all * copies or substantial portions of the Software. * * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE * AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER * LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, * OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE * SOFTWARE. *
*/ #ifndef TBX_COM_SEQUENCER_H_ #define TBX_COM_SEQUENCER_H_ #include #include #include #include #include #include #include #include #include namespace tbx { /*! * \class sequencer * \brief * A CRTP base class to provide the sequencer functionality. * * Sequencer is a script engine with receive/transmit functionalities based on predicates. It has: * - A program counter like variable named \c step. * - \c step actions like NEXT, GOTO exit with status etc... * - Input data match predicates to trigger those actions. * - Input data handlers to trigger external functionality on predicate match * - Output data handlers to "edit" data before transmiting them * - A small predicate set provided to the user. (starts_with, ends_with, contains). * * Sequencer can automate communication with a terminal-like device such as AT-command modems, can * be used to implement communication protocols, or even small http servers. * * It can operate based on a script array and handle the outgoing commands and incoming responses. * The user can create matching rules on received data and hook handlers and actions on them. * * The derived class (implementation) has to provide: * 1) size_t get(Data_t* data); * This function return 0 or a number of Data_t items. The data points to buffer for the input data. * * 3) size_t contents_ (Data_t* data); * This function return 0 or a number of Data_t items without removing them from the implementer's container * The data points to buffer for the input data. * * 2) size_t put(const Data_t* data, size_t n); * This function sends to implementation the data pointed by \c data witch have size \c n. * * 4) clock_t clock(); * This function return a number to be used as time. The units of this function may be arbitrary but they * match the units in \c record_t::timeout field. * * \tparam Impl_t The type of derived class * \tparam Data_t The char-like stream item type. Usually \c char * \tparam N The size of the sequence buffer to temporary store each line from get(). * * \note * We need access to derived class container to sneaky get a range of the data beside * the normal data flow, in order to implement the \see control_t::DETECT operation. */ template class sequencer { _CRTP_IMPL(Impl_t); //! \name Public types //! @{ public: using value_type = Data_t; using pointer_type = Data_t*; using size_type = size_t; using string_view = std::basic_string_view; /*! * The sequencer engine status. A variable of this type is returned by * \see action_(). */ enum class seq_status_t { CONTINUE, //!< Means we keep looping EXIT //!< Means, we exit with status the one indicated by \c action_t of the \c record_t }; //! \enum control_t //! \brief The control type of the script entry. enum class control_t { NOP, //!< No command, dont send or expect anything, used for delays SEND, //!< Send data to implementation through put() EXPECT, //!< Expects data from implementation via get() OR_EXPECT, //!< Expects data from implementation via get() in conjunction with previous EXPECT DETECT, //!< Detects data into rx buffer without receiving them via contents() OR_DETECT, //!< Detects data into rx buffer without receiving them via contents() in conjunction with //!< previous DETECT OTHERWISE //!< An "else" path if the EXPECT[, OR_EXPECT[, OR_EXPECT ... ]] block timesout. //! \note //! The \c DETECT extra incoming channel serve the purpose of sneak into receive //! buffer and check for data without getting them. This is useful when the receive driver //! is buffered with a delimiter and we seek for data that don't follow the delimiter pattern. //! //! For example: //! A modem sends responses with '\n' termination but for some "special" command it opens a cursor //! lets say ">$ " without '\n' at the end. }; //! \enum action_t //! \brief //! Possible response actions for the sequencer. This is the //! equivalent of changing the program counter of the sequencer //! and is composed by a type and a value. //! struct action_t { enum { NO =0, //!< Do not change sequencer's step NEXT, //!< Go to next sequencer step. In case of EXPECT/DETECT block of records //!< skip the entire block of EXPECT[, OR_EXPECT[, OR_EXPECT ...]] and go //!< to the next (non OR_*) control record. GOTO, //!< Manually sets the step counter to the number of the \c step member. EXIT, //!< Instruct for an exit returning the action.value as status } type; size_t value; //!< Used by \c GOTO to indicate the next sequencer's step. }; //! A no_action action_t static constexpr action_t no_action = {action_t::NO, 0}; //! A next action_t static constexpr action_t next = {action_t::NEXT, 0}; //! A goto action_t template template static constexpr action_t go_to = {action_t::GOTO, static_cast(GOTO)}; //! An exit ok action_t static constexpr action_t exit_ok = {action_t::EXIT, 0}; //! An exit error action_t static constexpr action_t exit_error = {action_t::EXIT, static_cast(-1)}; //! A generic exit action_t template template static constexpr action_t exit = {action_t::EXIT, static_cast(Status)}; /*! * Match binary predicate function pointer type. * Expects two string views and return a boolean. * It is used by EXPECT/DETECT blocks to trigger their {handler, action} pair. */ using match_ft = bool (*) (const string_view haystack, const string_view needle); /*! * Send/Receive handler function pointer type. * Expects a pointer to buffer and a size and returns status. * It is used on predicate match on EXPECT/DETECT blocks, or as data wrapper on SEND blocks. */ using handler_ft = void (*) (const Data_t*, size_t); /*! * \struct record_t * \brief * Describes the sequencer's script record entry (line). */ struct record_t { control_t control; //!< The control type of the entry string_view token; //!< String view to token data. [MUST BE null terminated]. //!< This is passed as 2nd argument to match predicate on EXPECT/DETECT, or as //! {data, size} pair to SEND handler and put_(). //!< If unused set it to "" match_ft match; //!< Match predicate to used in EXPECT/DETECT blocks //!< If unused set it to nullptr handler_ft handler; //!< The handler to called if the match is successful, or before put_() //!< If unused set it to nullptr action_t action; //!< Indicates the step manipulation if the match is successful or after NOP and put_() clock_t timeout; //!< Timeout in CPU time }; /*! * \struct script_t * \brief * Describes the sequencer's script. * * The user can create arrays as the example bellow to act as a script. * \code * Seq s; * const Seq::script_t<4> script = {{ * {Seq::control_t::NOP, "", Seq::nil, Seq::nil, {Seq::action_t::GOTO, 1}, 1000}, * * {Seq::control_t::SEND, "ATE0\r\n", Seq::nil, Seq::nil, {Seq::action_t::NEXT, 0}, 0}, * {Seq::control_t::EXPECT, "OK\r\n", Seq::ends_with, Seq::nil, {Seq::action_t::EXIT_OK, 0}, 1000}, * {Seq::control_t::OR_EXPECT, "ERROR", Seq::contains, Seq::nil, {Seq::action_t::EXIT_ERROR, 0}, 0} * }}; * s.run(script); * \endcode */ template using script_t = std::array; /*! * \brief * Check if the \c stream1 is equal to \c stream2 * \param stream1 The stream in witch we search [The input buffer] * \param stream2 What we search [The record's token] * \return True on success, false otherwise */ static constexpr auto equals = [](const string_view stream1, const string_view stream2) noexcept -> bool { return (stream1 == stream2); }; /*! * \brief * Check if the \c stream starts with the \c prefix * \param stream The stream in witch we search [The input buffer] * \param prefix What we search [The record's token] * \return True on success, false otherwise */ static constexpr auto starts_with = [](const string_view stream, const string_view prefix) noexcept -> bool { return (stream.rfind(prefix, 0) != string_view::npos); }; /*! * \brief * Check if the \c stream ends with the \c postfix * \param stream The stream in witch we search [The input buffer] * \param postfix What we search [The record's token] * \return True on success, false otherwise */ static constexpr auto ends_with = [](const string_view stream, const string_view postfix) -> bool { if (stream.size() < postfix.size()) return false; return ( stream.compare( stream.size() - postfix.size(), postfix.size(), postfix) == 0 ); }; /*! * \brief * Check if the \c haystack contains the \c needle * \param haystack The stream in witch we search [The input buffer] * \param needle What we search [The record's token] * \return True on success, false otherwise */ static constexpr auto contains = [](const string_view haystack, const string_view needle) noexcept -> bool { return (haystack.find(needle) != string_view::npos); }; //! Always false predicate static constexpr auto always_true = [](const string_view s1, const string_view s2) noexcept -> bool { (void)s1; (void)s2; return true; }; //! Always false predicate static constexpr auto always_false = [](const string_view s1, const string_view s2) noexcept -> bool { (void)s1; (void)s2; return false; }; //! Empty predicate or handler static constexpr auto nil = nullptr; //! @} //! \name Object lifetime //!@{ protected: ~sequencer () = default; //!< \brief Allow destructor from derived only constexpr sequencer () noexcept = default; //!< \brief A default constructor from derived only sequencer(const sequencer&) = delete; //!< No copies sequencer& operator= (const sequencer&) = delete; //!< No copy assignments //!@} //! \name Sequencer interface requirements for implementer //! @{ private: size_t get_ (Data_t* data) { return impl().get (data); } size_t contents_ (Data_t* data) { return impl().contents(data); } size_t put_ (const Data_t* data, size_t n) { return impl().put (data, n); } clock_t clock_ () noexcept { return impl().clock(); } //! @} //! \name Private functionality //! @{ private: /*! * Check if there is a handler and call it * \param handler The handler to check * \param buffer String view to buffer to pass to handler * \return True if handler is called */ constexpr bool handle_ (handler_ft handler, const string_view buffer = string_view{}) { if (handler != nullptr) { handler (buffer.begin(), buffer.size()); return true; } return false; } /*! * \brief * Return the new sequencer's step value and the sequencer's loop status as pair. * * \param script Reference to entire script. * \param step The current step * \return new step - status pair */ template constexpr std::pair action_ (const script_t& script, size_t step) { control_t skip_while{}; size_t s; switch (script[step].action.type) { default: case action_t::NO: return std::make_pair(step, seq_status_t::CONTINUE); case action_t::NEXT: switch (script[step].control) { case control_t::NOP: return std::make_pair(++step, seq_status_t::CONTINUE); case control_t::SEND: return std::make_pair(++step, seq_status_t::CONTINUE); case control_t::EXPECT: case control_t::OR_EXPECT: skip_while = control_t::OR_EXPECT; break; case control_t::DETECT: case control_t::OR_DETECT: skip_while = control_t::OR_DETECT; break; case control_t::OTHERWISE: skip_while = control_t::OTHERWISE; break; } s = step; while (script[++s].control == skip_while) ; return std::make_pair(s, seq_status_t::CONTINUE); case action_t::GOTO: return std::make_pair(script[step].action.value, seq_status_t::CONTINUE); case action_t::EXIT: return std::make_pair(script[step].action.value, seq_status_t::EXIT); } } template size_t expect_end (const script_t& script, size_t step) { while ((++step < Steps) && (script[step].control == control_t::OR_EXPECT)) ; return step; } template size_t detect_end (const script_t& script, size_t step) { while ((++step < Steps) && (script[step].control == control_t::OR_DETECT)) ; return step; } //! @} public: //! \return The buffer size of the sequencer constexpr size_t size() const noexcept { return N; } /*! * \brief * A static functionality to provide access to sequencer's inner matching mechanism. * Checks the \c buffer against \c handle and calls its action if needed. * * \param buffer The buffer to check (1st parameter to match) * \param token String view to check against buffer (2nd parameter to match) * \param handler Function pointer to match predicate to use * \param handle Reference to handle to call on match * * \return True on match, false otherwise */ constexpr bool check_handle (const string_view buffer, const string_view token, match_ft match, handler_ft handle) { if (match != nullptr && match(buffer, token)) return handle_ (handle, buffer); return false; } /*! * \brief * Run the script array * * The main sequencer functionality. It starts with the first entry of the array. * * - If the record is \c NOP it executes the action after the timeout. * \c NOP uses {\c action_t, \c timeout}. * - If the record is \c SEND passes the token to handler (if any), then to put_() and executes the action after that. * \c SEND uses {\c token, \c handler, \c action_t} * - If the record is \c EXCEPT it continuously try to receive data using \see get_() * * If no data until timeout, exit with failure * * On data reception for this record AND for each OR_EXPECT that follows, calls the match predicate * by passing the received data and token. * On predicate match * - Calls the handler if there is one * - Executes the action. No farther EXPECT, OR_EXPECT, ... checks are made. * - If the record is \c DETECT it continuously try to receive data using \see contents_() * * If no data until timeout, exit with failure * * On data reception for this record AND for each OR_DETECT that follows, calls the match predicate * by passing the received data and token. * On predicate match * - Calls the handler if there is one * - Executes the action. No farther DETECT, OR_DETECT, ... checks are made. * * \tparam Steps The number of records of the script * * \param script Reference to script to run * \return The status of entire operation as described above * \arg 0 Success * \arg (size_t)-1 Failure * \arg other Arbitrary return status */ template size_t run (const script_t& script) { Data_t buffer[N]; size_t resp_size; size_t step =0, p_step =0; clock_t mark = clock_(); seq_status_t status{seq_status_t::CONTINUE}; do { if (step >= Steps) return exit_error.value; const record_t& record = script[step]; // get reference ot current line if (step != p_step) { // renew time marker in each step p_step = step; mark = clock_(); } switch (record.control) { default: case control_t::NOP: if ((clock_() - mark) >= record.timeout) std::tie(step, status) = action_ (script, step); break; case control_t::SEND: if (record.handler != nullptr) record.handler(record.token.data(), record.token.size()); if (put_(record.token.data(), record.token.size()) != record.token.size()) return exit_error.value; std::tie(step, status) = action_ (script, step); break; case control_t::EXPECT: case control_t::OR_EXPECT: resp_size = get_(buffer); if (resp_size) { for (size_t s = step ; s < expect_end(script, step) ; ++s) { if (script[s].match != nullptr && script[s].match({buffer, resp_size}, script[s].token)) { handle_ (script[s].handler, {buffer, resp_size}); std::tie(step, status) = action_ (script, s); break; } } } if (record.timeout && (clock_() - mark) >= record.timeout) { size_t s = expect_end(script, step); if ((s < Steps) && (script[s].control == control_t::OTHERWISE)) { handle_ (script[s].handler, {buffer, resp_size}); std::tie(step, status) = action_ (script, s); } else { return exit_error.value; } } break; case control_t::DETECT: case control_t::OR_DETECT: resp_size = contents_(buffer); if (resp_size) { for (size_t s = step ; s < detect_end(script, step) ; ++s) { if (script[s].match != nullptr && script[s].match({buffer, resp_size}, script[s].token)) { handle_ (script[s].handler, {buffer, resp_size}); std::tie(step, status) = action_ (script, s); break; } } } if (record.timeout && (clock_() - mark) >= record.timeout) { size_t s = detect_end(script, step); if ((s < Steps) && (script[s].control == control_t::OTHERWISE)) { handle_ (script[s].handler, {buffer, resp_size}); std::tie(step, status) = action_ (script, s); } else { return exit_error.value; } } break; case control_t::OTHERWISE: handle_ (script[step].handler, {buffer, resp_size}); std::tie(step, status) = action_ (script, step); break; } // switch (record.control) } while ( status == seq_status_t::CONTINUE); return step; // step here is set by action_ as the return status } }; } #endif /* TBX_COM_SEQUENCER_H_ */