/* Copyright (c) 2013 Arduino LLC. All right reserved. This library is free software; you can redistribute it and/or modify it under the terms of the GNU Lesser General Public License as published by the Free Software Foundation; either version 2.1 of the License, or (at your option) any later version. This library 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 Lesser General Public License for more details. You should have received a copy of the GNU Lesser General Public License along with this library; if not, write to the Free Software Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA */ #include "Bridge.h" BridgeClass::BridgeClass(Stream &_stream) : index(0), stream(_stream), started(false) { // Empty } void BridgeClass::begin() { if (started) return; started = true; // TODO: A more robust restart // Wait for Atheros bootloader to finish startup do { dropAll(); delay(1100); } while (available()>0); // Bridge startup: // - If the bridge is not running starts it safely print(CTRL_C); print(F("\n")); delay(500); // Wait for OpenWRT message // "Press enter to activate console" print(F("run-bridge\n")); delay(1000); dropAll(); // - If the bridge was already running previous commands // are ignored as "invalid packets". // Reset the brigde uint8_t cmd[] = {'X','X'}; transfer(cmd, 2); } uint8_t BridgeClass::runCommand(String &command) { uint8_t cmd[] = {'R'}; uint8_t res[1]; transfer(cmd, 1, (uint8_t*)command.c_str(), command.length(), res, 1); return res[0]; } bool BridgeClass::commandIsRunning(uint8_t handle) { uint8_t cmd[] = {'r', handle}; uint8_t res[1]; transfer(cmd, 2, res, 1); return (res[0] == 1); } unsigned int BridgeClass::commandExitValue(uint8_t handle) { uint8_t cmd[] = {'W', handle}; uint8_t res[2]; transfer(cmd, 2, res, 2); return (res[0] << 8) + res[1]; } void BridgeClass::cleanCommand(uint8_t handle) { uint8_t cmd[] = {'w', handle}; transfer(cmd, 2); } unsigned int BridgeClass::commandOutputAvailable(uint8_t handle) { uint8_t cmd[] = {'o', handle}; uint8_t res[1]; transfer(cmd, 2, res, 1); return res[0]; } unsigned int BridgeClass::readCommandOutput(uint8_t handle, uint8_t *buffer, unsigned int size) { if (size > 255) size = 255; uint8_t cmd[] = {'O', handle, size}; return transfer(cmd, 3, buffer, size); } void BridgeClass::writeCommandInput(uint8_t handle, const uint8_t *buff, unsigned int size) { uint8_t cmd[] = {'I', handle}; transfer(cmd, 2, buff, size, NULL, 0); } uint8_t BridgeClass::fileOpen(String &file, uint8_t mode, uint8_t &err) { uint8_t cmd[] = {'F', mode}; uint8_t res[2]; transfer(cmd, 2, (uint8_t*)file.c_str(), file.length(), res, 2); err = res[0]; return res[1]; } void BridgeClass::fileClose(uint8_t handle) { uint8_t cmd[] = {'f', handle}; transfer(cmd, 2); } unsigned int BridgeClass::fileRead(uint8_t handle, uint8_t *buff, unsigned int size, uint8_t &err) { uint8_t s = size > 255 ? 255 : size-1; uint8_t cmd[] = {'G', handle, s}; uint8_t l = transfer(cmd, 3, buff, size) - 1; err = buff[0]; // First byte is error code if (l>0) { // Shift the reminder of buffer for (uint8_t i=0; i> 24) & 0xFF, (position >> 16) & 0xFF, (position >> 8) & 0xFF, position & 0xFF }; uint8_t res[1]; transfer(cmd, 6, res, 1); err = res[0]; } unsigned int BridgeClass::readMessage(uint8_t *buff, unsigned int size) { uint8_t tmp[] = { 'm' }; return transfer(tmp, 1, buff, size); } void BridgeClass::writeMessage(const uint8_t *buff, unsigned int size) { uint8_t cmd[] = {'M'}; transfer(cmd, 1, buff, size, NULL, 0); } unsigned int BridgeClass::messageAvailable() { uint8_t tmp[] = {'n'}; uint8_t res[2]; transfer(tmp, 1, res, 2); return (res[0] << 8) + res[1]; } void BridgeClass::put(const char *key, const char *value) { // TODO: do it in a more efficient way String cmd = "D"; cmd += key; cmd += "\xFE"; cmd += value; transfer((uint8_t*)cmd.c_str(), cmd.length()); } unsigned int BridgeClass::get(const char *key, uint8_t *value, unsigned int maxlen) { uint8_t cmd[] = {'d'}; unsigned int l = transfer(cmd, 1, (uint8_t *)key, strlen(key), value, maxlen); if (l < maxlen) value[l] = 0; // Zero-terminate string return l; } void BridgeClass::crcUpdate(uint8_t c) { CRC = CRC ^ c; CRC = (CRC >> 8) + (CRC << 8); } void BridgeClass::crcReset() { CRC = 0xAAAA; } void BridgeClass::crcWrite() { write((char)(CRC >> 8)); write((char)(CRC & 0xFF)); } bool BridgeClass::crcCheck(uint16_t _CRC) { return CRC == _CRC; } uint8_t BridgeClass::transfer(const uint8_t *buff1, uint16_t len1, const uint8_t *buff2, uint16_t len2, const uint8_t *buff3, uint16_t len3, uint8_t *rxbuff, uint16_t rxlen) { uint16_t len = len1 + len2 + len3; for ( ; ; delay(100), dropAll() /* Delay for retransmission */) { // Send packet crcReset(); write((char)0xFF); // Start of packet (0xFF) crcUpdate(0xFF); write((char)index); // Message index crcUpdate(index); write((char)((len >> 8) & 0xFF)); // Message length (hi) crcUpdate((len >> 8) & 0xFF); write((char)(len & 0xFF)); // Message length (lo) crcUpdate(len & 0xFF); for (uint16_t i=0; i rxlen) return rxlen; return l; } } int BridgeClass::timedRead(unsigned int timeout) { int c; unsigned long _startMillis = millis(); do { c = read(); if (c >= 0) return c; } while(millis() - _startMillis < timeout); return -1; // -1 indicates timeout } void BridgeClass::dropAll() { while (available() > 0) { read(); } } // Bridge instance #ifdef __AVR_ATmega32U4__ // Leonardo variants (where HardwareSerial is Serial1) SerialBridgeClass Bridge(Serial1); #else SerialBridgeClass Bridge(Serial); #endif