/** * Marlin 3D Printer Firmware * Copyright (c) 2019 MarlinFirmware [https://github.com/MarlinFirmware/Marlin] * * Based on Sprinter and grbl. * Copyright (c) 2011 Camiel Gubbels / Erik van der Zalm * * This program is free software: you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation, either version 3 of the License, or * (at your option) any later version. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program. If not, see . * */ #pragma once #include "../inc/MarlinConfig.h" #define BINARY_STREAM_COMPRESSION #if ENABLED(BINARY_STREAM_COMPRESSION) #include "../libs/heatshrink/heatshrink_decoder.h" #endif inline bool bs_serial_data_available(const uint8_t index) { switch (index) { case 0: return MYSERIAL0.available(); #if NUM_SERIAL > 1 case 1: return MYSERIAL1.available(); #endif } return false; } inline int bs_read_serial(const uint8_t index) { switch (index) { case 0: return MYSERIAL0.read(); #if NUM_SERIAL > 1 case 1: return MYSERIAL1.read(); #endif } return -1; } #if ENABLED(BINARY_STREAM_COMPRESSION) static heatshrink_decoder hsd; static uint8_t decode_buffer[512] = {}; #endif class SDFileTransferProtocol { private: struct Packet { struct [[gnu::packed]] Open { static bool validate(char* buffer, size_t length) { return (length > sizeof(Open) && buffer[length - 1] == '\0'); } static Open& decode(char* buffer) { data = &buffer[2]; return *reinterpret_cast(buffer); } bool compression_enabled() { return compression & 0x1; } bool dummy_transfer() { return dummy & 0x1; } static char* filename() { return data; } private: uint8_t dummy, compression; static char* data; // variable length strings complicate things }; }; static bool file_open(char* filename) { if (!dummy_transfer) { card.mount(); card.openFile(filename, false); if (!card.isFileOpen()) return false; } transfer_active = true; data_waiting = 0; #if ENABLED(BINARY_STREAM_COMPRESSION) heatshrink_decoder_reset(&hsd); #endif return true; } static bool file_write(char* buffer, const size_t length) { #if ENABLED(BINARY_STREAM_COMPRESSION) if (compression) { size_t total_processed = 0, processed_count = 0; HSD_poll_res presult; while (total_processed < length) { heatshrink_decoder_sink(&hsd, reinterpret_cast(&buffer[total_processed]), length - total_processed, &processed_count); total_processed += processed_count; do { presult = heatshrink_decoder_poll(&hsd, &decode_buffer[data_waiting], sizeof(decode_buffer) - data_waiting, &processed_count); data_waiting += processed_count; if (data_waiting == sizeof(decode_buffer)) { if (!dummy_transfer) if (card.write(decode_buffer, data_waiting) < 0) { return false; } data_waiting = 0; } } while (presult == HSDR_POLL_MORE); } return true; } #endif return (dummy_transfer || card.write(buffer, length) >= 0); } static bool file_close() { if (!dummy_transfer) { #if ENABLED(BINARY_STREAM_COMPRESSION) // flush any buffered data if (data_waiting) { if (card.write(decode_buffer, data_waiting) < 0) return false; data_waiting = 0; } #endif card.closefile(); card.release(); } #if ENABLED(BINARY_STREAM_COMPRESSION) heatshrink_decoder_finish(&hsd); #endif transfer_active = false; return true; } static void transfer_abort() { if (!dummy_transfer) { card.closefile(); card.removeFile(card.filename); card.release(); #if ENABLED(BINARY_STREAM_COMPRESSION) heatshrink_decoder_finish(&hsd); #endif } transfer_active = false; return; } enum class FileTransfer : uint8_t { QUERY, OPEN, CLOSE, WRITE, ABORT }; static size_t data_waiting, transfer_timeout, idle_timeout; static bool transfer_active, dummy_transfer, compression; public: static void idle() { // If a transfer is interrupted and a file is left open, abort it after TIMEOUT ms const millis_t ms = millis(); if (transfer_active && ELAPSED(ms, idle_timeout)) { idle_timeout = ms + IDLE_PERIOD; if (ELAPSED(ms, transfer_timeout)) transfer_abort(); } } static void process(uint8_t packet_type, char* buffer, const uint16_t length) { transfer_timeout = millis() + TIMEOUT; switch (static_cast(packet_type)) { case FileTransfer::QUERY: SERIAL_ECHOPAIR("PFT:version:", VERSION_MAJOR, ".", VERSION_MINOR, ".", VERSION_PATCH); #if ENABLED(BINARY_STREAM_COMPRESSION) SERIAL_ECHOLNPAIR(":compresion:heatshrink,", HEATSHRINK_STATIC_WINDOW_BITS, ",", HEATSHRINK_STATIC_LOOKAHEAD_BITS); #else SERIAL_ECHOLNPGM(":compresion:none"); #endif break; case FileTransfer::OPEN: if (transfer_active) SERIAL_ECHOLNPGM("PFT:busy"); else { if (Packet::Open::validate(buffer, length)) { auto packet = Packet::Open::decode(buffer); compression = packet.compression_enabled(); dummy_transfer = packet.dummy_transfer(); if (file_open(packet.filename())) { SERIAL_ECHOLNPGM("PFT:success"); break; } } SERIAL_ECHOLNPGM("PFT:fail"); } break; case FileTransfer::CLOSE: if (transfer_active) { if (file_close()) SERIAL_ECHOLNPGM("PFT:success"); else SERIAL_ECHOLNPGM("PFT:ioerror"); } else SERIAL_ECHOLNPGM("PFT:invalid"); break; case FileTransfer::WRITE: if (!transfer_active) SERIAL_ECHOLNPGM("PFT:invalid"); else if (!file_write(buffer, length)) SERIAL_ECHOLNPGM("PFT:ioerror"); break; case FileTransfer::ABORT: transfer_abort(); SERIAL_ECHOLNPGM("PFT:success"); break; default: SERIAL_ECHOLNPGM("PTF:invalid"); break; } } static const uint16_t VERSION_MAJOR = 0, VERSION_MINOR = 1, VERSION_PATCH = 0, TIMEOUT = 10000, IDLE_PERIOD = 1000; }; class BinaryStream { public: enum class Protocol : uint8_t { CONTROL, FILE_TRANSFER }; enum class ProtocolControl : uint8_t { SYNC = 1, CLOSE }; enum class StreamState : uint8_t { PACKET_RESET, PACKET_WAIT, PACKET_HEADER, PACKET_DATA, PACKET_FOOTER, PACKET_PROCESS, PACKET_RESEND, PACKET_TIMEOUT, PACKET_ERROR }; struct Packet { // 10 byte protocol overhead, ascii with checksum and line number has a minimum of 7 increasing with line union Header { static constexpr uint16_t HEADER_TOKEN = 0xB5AD; struct [[gnu::packed]] { uint16_t token; // packet start token uint8_t sync; // stream sync, resend id and packet loss detection uint8_t meta; // 4 bit protocol, // 4 bit packet type uint16_t size; // data length uint16_t checksum; // header checksum }; uint8_t protocol() { return (meta >> 4) & 0xF; } uint8_t type() { return meta & 0xF; } void reset() { token = 0; sync = 0; meta = 0; size = 0; checksum = 0; } uint8_t data[1]; }; union Footer { struct [[gnu::packed]] { uint16_t checksum; // full packet checksum }; void reset() { checksum = 0; } uint8_t data[1]; }; Header header; Footer footer; uint32_t bytes_received; uint16_t checksum, header_checksum; millis_t timeout; char* buffer; void reset() { header.reset(); footer.reset(); bytes_received = 0; checksum = 0; header_checksum = 0; timeout = millis() + PACKET_MAX_WAIT; buffer = nullptr; } } packet{}; void reset() { sync = 0; packet_retries = 0; buffer_next_index = 0; } // fletchers 16 checksum uint32_t checksum(uint32_t cs, uint8_t value) { uint16_t cs_low = (((cs & 0xFF) + value) % 255); return ((((cs >> 8) + cs_low) % 255) << 8) | cs_low; } // read the next byte from the data stream keeping track of // whether the stream times out from data starvation // takes the data variable by reference in order to return status bool stream_read(uint8_t& data) { if (stream_state != StreamState::PACKET_WAIT && ELAPSED(millis(), packet.timeout)) { stream_state = StreamState::PACKET_TIMEOUT; return false; } if (!bs_serial_data_available(card.transfer_port_index)) return false; data = bs_read_serial(card.transfer_port_index); packet.timeout = millis() + PACKET_MAX_WAIT; return true; } template void receive(char (&buffer)[buffer_size]) { uint8_t data = 0; millis_t transfer_window = millis() + RX_TIMESLICE; #if ENABLED(SDSUPPORT) PORT_REDIRECT(card.transfer_port_index); #endif #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Warray-bounds" while (PENDING(millis(), transfer_window)) { switch (stream_state) { /** * Data stream packet handling */ case StreamState::PACKET_RESET: packet.reset(); stream_state = StreamState::PACKET_WAIT; case StreamState::PACKET_WAIT: if (!stream_read(data)) { idle(); return; } // no active packet so don't wait packet.header.data[1] = data; if (packet.header.token == packet.header.HEADER_TOKEN) { packet.bytes_received = 2; stream_state = StreamState::PACKET_HEADER; } else { // stream corruption drop data packet.header.data[0] = data; } break; case StreamState::PACKET_HEADER: if (!stream_read(data)) break; packet.header.data[packet.bytes_received++] = data; packet.checksum = checksum(packet.checksum, data); // header checksum calculation can't contain the checksum if (packet.bytes_received == sizeof(Packet::header) - 2) packet.header_checksum = packet.checksum; if (packet.bytes_received == sizeof(Packet::header)) { if (packet.header.checksum == packet.header_checksum) { // The SYNC control packet is a special case in that it doesn't require the stream sync to be correct if (static_cast(packet.header.protocol()) == Protocol::CONTROL && static_cast(packet.header.type()) == ProtocolControl::SYNC) { SERIAL_ECHOLNPAIR("ss", sync, ",", buffer_size, ",", VERSION_MAJOR, ".", VERSION_MINOR, ".", VERSION_PATCH); stream_state = StreamState::PACKET_RESET; break; } if (packet.header.sync == sync) { buffer_next_index = 0; packet.bytes_received = 0; if (packet.header.size) { stream_state = StreamState::PACKET_DATA; packet.buffer = static_cast(&buffer[0]); // multipacket buffering not implemented, always allocate whole buffer to packet } else stream_state = StreamState::PACKET_PROCESS; } else if (packet.header.sync == sync - 1) { // ok response must have been lost SERIAL_ECHOLNPAIR("ok", packet.header.sync); // transmit valid packet received and drop the payload stream_state = StreamState::PACKET_RESET; } else if (packet_retries) { stream_state = StreamState::PACKET_RESET; // could be packets already buffered on flow controlled connections, drop them without ack } else { SERIAL_ECHO_MSG("Datastream packet out of order"); stream_state = StreamState::PACKET_RESEND; } } else { SERIAL_ECHO_START(); SERIAL_ECHOLNPAIR("Packet header(", packet.header.sync, "?) corrupt"); stream_state = StreamState::PACKET_RESEND; } } break; case StreamState::PACKET_DATA: if (!stream_read(data)) break; if (buffer_next_index < buffer_size) packet.buffer[buffer_next_index] = data; else { SERIAL_ECHO_MSG("Datastream packet data buffer overrun"); stream_state = StreamState::PACKET_ERROR; break; } packet.checksum = checksum(packet.checksum, data); packet.bytes_received++; buffer_next_index++; if (packet.bytes_received == packet.header.size) { stream_state = StreamState::PACKET_FOOTER; packet.bytes_received = 0; } break; case StreamState::PACKET_FOOTER: if (!stream_read(data)) break; packet.footer.data[packet.bytes_received++] = data; if (packet.bytes_received == sizeof(Packet::footer)) { if (packet.footer.checksum == packet.checksum) { stream_state = StreamState::PACKET_PROCESS; } else { SERIAL_ECHO_START(); SERIAL_ECHOLNPAIR("Packet(", packet.header.sync, ") payload corrupt"); stream_state = StreamState::PACKET_RESEND; } } break; case StreamState::PACKET_PROCESS: sync++; packet_retries = 0; bytes_received += packet.header.size; SERIAL_ECHOLNPAIR("ok", packet.header.sync); // transmit valid packet received dispatch(); stream_state = StreamState::PACKET_RESET; break; case StreamState::PACKET_RESEND: if (packet_retries < MAX_RETRIES || MAX_RETRIES == 0) { packet_retries++; stream_state = StreamState::PACKET_RESET; SERIAL_ECHO_START(); SERIAL_ECHOLNPAIR("Resend request ", int(packet_retries)); SERIAL_ECHOLNPAIR("rs", sync); } else stream_state = StreamState::PACKET_ERROR; break; case StreamState::PACKET_TIMEOUT: SERIAL_ECHO_MSG("Datastream timeout"); stream_state = StreamState::PACKET_RESEND; break; case StreamState::PACKET_ERROR: SERIAL_ECHOLNPAIR("fe", packet.header.sync); reset(); // reset everything, resync required stream_state = StreamState::PACKET_RESET; break; } } #pragma GCC diagnostic pop } void dispatch() { switch(static_cast(packet.header.protocol())) { case Protocol::CONTROL: switch(static_cast(packet.header.type())) { case ProtocolControl::CLOSE: // revert back to ASCII mode card.flag.binary_mode = false; break; default: SERIAL_ECHO_MSG("Unknown BinaryProtocolControl Packet"); } break; case Protocol::FILE_TRANSFER: SDFileTransferProtocol::process(packet.header.type(), packet.buffer, packet.header.size); // send user data to be processed break; default: SERIAL_ECHO_MSG("Unsupported Binary Protocol"); } } void idle() { // Some Protocols may need periodic updates without new data SDFileTransferProtocol::idle(); } static const uint16_t PACKET_MAX_WAIT = 500, RX_TIMESLICE = 20, MAX_RETRIES = 0, VERSION_MAJOR = 0, VERSION_MINOR = 1, VERSION_PATCH = 0; uint8_t packet_retries, sync; uint16_t buffer_next_index; uint32_t bytes_received; StreamState stream_state = StreamState::PACKET_RESET; }; extern BinaryStream binaryStream[NUM_SERIAL];