hadif azli
/
TEST123
BLYNK TEST
ESP8266.cpp
- Committer:
- kenobi
- Date:
- 2021-01-26
- Revision:
- 5:8a3cf73d7ed3
- Parent:
- 3:4cd9171ba989
File content as of revision 5:8a3cf73d7ed3:
/** * @file ESP8266.cpp * @brief The implementation of class ESP8266. * @author Wu Pengfei<pengfei.wu@itead.cc> * @date 2015.02 * * @par Copyright: * Copyright (c) 2015 ITEAD Intelligent Systems Co., Ltd. \n\n * 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 2 of * the License, or (at your option) any later version. \n\n * 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. */ #include "ESP8266_HardSer.h" //#include <avr/pgmspace.h> #ifdef ESP8266_USE_SOFTWARE_SERIAL ESP8266::ESP8266(SoftwareSerial &uart): m_puart(&uart) { m_onData = NULL; m_onDataPtr = NULL; } #else ESP8266::ESP8266(HardwareSerial &uart): m_puart(&uart) { m_onData = NULL; m_onDataPtr = NULL; } #endif bool ESP8266::kick(void) { LOG_ENTER; return eAT(); } bool ESP8266::restart(void) { LOG_ENTER; unsigned long start; if (eATRST()) { //delay(2000); wait_ms(2000); //start = millis(); start = g_Timer.read_ms(); while (g_Timer.read_ms() - start < 3000) { if (eAT()) { //delay(1500); /* Waiting for stable */ wait_ms(1500); return true; } //delay(100); wait_ms(100); } } return false; } String ESP8266::getVersion(void) { LOG_ENTER; String version; eATGMR(version); return version; } bool ESP8266::setEcho(uint8_t mode) { LOG_ENTER; return eATE(mode); } bool ESP8266::restore(void) { LOG_ENTER; return eATRESTORE(); } bool ESP8266::setUart(uint32_t baudrate,uint8_t pattern) { LOG_ENTER; return eATSETUART(baudrate,pattern); } bool ESP8266::deepSleep(uint32_t time) { LOG_ENTER; return eATGSLP(time); } bool ESP8266::setOprToStation(uint8_t pattern1,uint8_t pattern2) { LOG_ENTER; uint8_t mode; if (!qATCWMODE(&mode,pattern1)) { return false; } if (mode == 1) { return true; } else { if (sATCWMODE(1,pattern2)) { return true; } else { return false; } } } String ESP8266::getWifiModeList(void) { LOG_ENTER; String list; eATCWMODE(list); return list; } bool ESP8266::setOprToSoftAP(uint8_t pattern1,uint8_t pattern2) { LOG_ENTER; uint8_t mode; if (!qATCWMODE(&mode,pattern1)) { return false; } if (mode == 2) { return true; } else { if (sATCWMODE(2,pattern2) ) { return true; } else { return false; } } } bool ESP8266::setOprToStationSoftAP(uint8_t pattern1,uint8_t pattern2) { LOG_ENTER; uint8_t mode; if (!qATCWMODE(&mode,pattern1)) { return false; } if (mode == 3) { return true; } else { if (sATCWMODE(3,pattern2) ) { return true; } else { return false; } } } uint8_t ESP8266::getOprMode(uint8_t pattern1) { LOG_ENTER; uint8_t mode; if (!qATCWMODE(&mode,pattern1)) { return 0; } else { return mode; } } String ESP8266::getNowConecAp(uint8_t pattern) { LOG_ENTER; String ssid; qATCWJAP(ssid,pattern); return ssid; } String ESP8266::getAPList(void) { LOG_ENTER; String list; eATCWLAP(list); return list; } bool ESP8266::joinAP(String ssid, String pwd,uint8_t pattern) { LOG_ENTER; return sATCWJAP(ssid, pwd,pattern); } bool ESP8266::leaveAP(void) { LOG_ENTER; return eATCWQAP(); } String ESP8266::getSoftAPParam(uint8_t pattern) { LOG_ENTER; String list; qATCWSAP(list,pattern); return list; } bool ESP8266::setSoftAPParam(String ssid, String pwd, uint8_t chl, uint8_t ecn,uint8_t pattern) { LOG_ENTER; return sATCWSAP(ssid, pwd, chl, ecn,pattern); } String ESP8266::getJoinedDeviceIP(void) { LOG_ENTER; String list; eATCWLIF(list); return list; } String ESP8266::getDHCP(uint8_t pattern) { LOG_ENTER; String dhcp; qATCWDHCP(dhcp,pattern); return dhcp; } bool ESP8266::setDHCP(uint8_t mode, uint8_t en, uint8_t pattern) { LOG_ENTER; return sATCWDHCP(mode, en, pattern); } bool ESP8266::setAutoConnect(uint8_t en) { LOG_ENTER; return eATCWAUTOCONN(en); } String ESP8266::getStationMac(uint8_t pattern) { LOG_ENTER; String mac; qATCIPSTAMAC(mac,pattern); return mac; } bool ESP8266::setStationMac(String mac,uint8_t pattern) { LOG_ENTER; return eATCIPSTAMAC(mac,pattern); } String ESP8266::getStationIp(uint8_t pattern) { LOG_ENTER; String ip; qATCIPSTAIP(ip,pattern); return ip; } bool ESP8266::setStationIp(String ip,String gateway,String netmask,uint8_t pattern) { LOG_ENTER; return eATCIPSTAIP(ip,gateway,netmask,pattern); } String ESP8266::getAPIp(uint8_t pattern) { LOG_ENTER; String ip; qATCIPAP(ip,pattern); return ip; } bool ESP8266::setAPIp(String ip,uint8_t pattern) { LOG_ENTER; return eATCIPAP(ip,pattern); } bool ESP8266::startSmartConfig(uint8_t type) { LOG_ENTER; return eCWSTARTSMART(type); } bool ESP8266::stopSmartConfig(void) { LOG_ENTER; return eCWSTOPSMART(); } String ESP8266::getIPStatus(void) { LOG_ENTER; String list; eATCIPSTATUS(list); return list; } String ESP8266::getLocalIP(void) { LOG_ENTER; String list; eATCIFSR(list); return list; } bool ESP8266::enableMUX(void) { LOG_ENTER; return sATCIPMUX(1); } bool ESP8266::disableMUX(void) { LOG_ENTER; return sATCIPMUX(0); } bool ESP8266::createTCP(String addr, uint32_t port) { LOG_ENTER; return sATCIPSTARTSingle("TCP", addr, port); } bool ESP8266::releaseTCP(void) { LOG_ENTER; return eATCIPCLOSESingle(); } bool ESP8266::registerUDP(String addr, uint32_t port) { LOG_ENTER; return sATCIPSTARTSingle("UDP", addr, port); } bool ESP8266::unregisterUDP(void) { LOG_ENTER; return eATCIPCLOSESingle(); } bool ESP8266::createTCP(uint8_t mux_id, String addr, uint32_t port) { LOG_ENTER; return sATCIPSTARTMultiple(mux_id, "TCP", addr, port); } bool ESP8266::releaseTCP(uint8_t mux_id) { LOG_ENTER; return sATCIPCLOSEMulitple(mux_id); } bool ESP8266::registerUDP(uint8_t mux_id, String addr, uint32_t port) { LOG_ENTER; return sATCIPSTARTMultiple(mux_id, "UDP", addr, port); } bool ESP8266::unregisterUDP(uint8_t mux_id) { LOG_ENTER; return sATCIPCLOSEMulitple(mux_id); } bool ESP8266::setTCPServerTimeout(uint32_t timeout) { LOG_ENTER; return sATCIPSTO(timeout); } bool ESP8266::startTCPServer(uint32_t port) { LOG_ENTER; if (sATCIPSERVER(1, port)) { return true; } return false; } bool ESP8266::stopTCPServer(void) { LOG_ENTER; sATCIPSERVER(0); restart(); return false; } bool ESP8266::setCIPMODE(uint8_t mode) { LOG_ENTER; return sATCIPMODE(mode); } bool ESP8266::saveTransLink (uint8_t mode,String ip,uint32_t port) { LOG_ENTER; return eATSAVETRANSLINK(mode,ip,port); } bool ESP8266::setPing(String ip) { LOG_ENTER; return eATPING(ip); } bool ESP8266::startServer(uint32_t port) { LOG_ENTER; return startTCPServer(port); } bool ESP8266::stopServer(void) { LOG_ENTER; return stopTCPServer(); } bool ESP8266::send(const uint8_t *buffer, uint32_t len) { LOG_ENTER; return sATCIPSENDSingle(buffer, len); } bool ESP8266::sendFromFlash(uint8_t mux_id, const uint8_t *buffer, uint32_t len) { LOG_ENTER; return sATCIPSENDMultipleFromFlash(mux_id, buffer, len); } bool ESP8266::sendFromFlash(const uint8_t *buffer, uint32_t len) { LOG_ENTER; return sATCIPSENDSingleFromFlash(buffer, len); } bool ESP8266::send(uint8_t mux_id, const uint8_t *buffer, uint32_t len) { LOG_ENTER; return sATCIPSENDMultiple(mux_id, buffer, len); } void ESP8266::run() { LOG_ENTER; rx_empty(); } /*----------------------------------------------------------------------------*/ /* +IPD,<id>,<len>:<data> */ /* +IPD,<len>:<data> */ uint32_t ESP8266::checkIPD(String& data) { //Serial.print("### check: "); //Serial.println(data); LOG_ENTER; int32_t index_PIPDcomma = -1; int32_t index_colon = -1; /* : */ int32_t index_comma = -1; /* , */ int32_t len = -1; int8_t id = -1; { // Just for easier diffing index_PIPDcomma = data.indexOf("+IPD,"); if (index_PIPDcomma != -1) { index_colon = data.indexOf(':', index_PIPDcomma + 5); if (index_colon != -1) { index_comma = data.indexOf(',', index_PIPDcomma + 5); /* +IPD,id,len:data */ if (index_comma != -1 && index_comma < index_colon) { id = data.substring(index_PIPDcomma + 5, index_comma).toInt(); if (id < 0 || id > 4) { return 0; } len = data.substring(index_comma + 1, index_colon).toInt(); if (len <= 0) { return 0; } } else { /* +IPD,len:data */ len = data.substring(index_PIPDcomma + 5, index_colon).toInt(); if (len <= 0) { return 0; } } if (m_onData) { m_onData(id, len, m_onDataPtr); } return len; } } } return 0; } void ESP8266::rx_empty(void) { LOG_ENTER; String data; char a; unsigned long start = g_Timer.read_ms(); while (g_Timer.read_ms() - start < 10) { if (m_puart->readable()) { a = m_puart->getc(); if(a == '\0') continue; data += a; if (checkIPD(data)) { data = ""; } start = g_Timer.read_ms(); } } } String ESP8266::recvString(String target, uint32_t timeout) { LOG_ENTER; String data; char a; unsigned long start = g_Timer.read_ms(); while (g_Timer.read_ms() - start < timeout) { while(m_puart->readable() > 0) { a = m_puart->getc(); ESP8266_LOG("a=0x%02X ", a); if(a == '\0') continue; data += a; if (data.indexOf(target) != -1) { ESP8266_LOG("\r\ndata = %s\r\n", data.c_str()); return data; } else if (checkIPD(data)) { data = ""; } } } ESP8266_LOG("\r\n"); ESP8266_LOG("data1 = %s\r\n", data.c_str()); return data; } String ESP8266::recvString(String target1, String target2, uint32_t timeout) { LOG_ENTER; String data; char a; unsigned long start = g_Timer.read_ms(); while (g_Timer.read_ms() - start < timeout) { while(m_puart->readable() > 0) { a = m_puart->getc(); ESP8266_LOG("a=0x%02x ", a); if(a == '\0') continue; data += a; if (data.indexOf(target1) != -1) { ESP8266_LOG("\r\ndata2 = %s\r\n", data.c_str()); return data; } else if (data.indexOf(target2) != -1) { ESP8266_LOG("\r\ndata3 = %s\r\n", data.c_str()); return data; } else if (checkIPD(data)) { data = ""; } } } ESP8266_LOG("\r\ndata4 = %s\r\n", data.c_str()); return data; } String ESP8266::recvString(String target1, String target2, String target3, uint32_t timeout) { LOG_ENTER; String data; char a; unsigned long start = g_Timer.read_ms(); while (g_Timer.read_ms() - start < timeout) { while(m_puart->readable() > 0) { a = m_puart->getc(); ESP8266_LOG("a=0x%02x ", a); if(a == '\0') continue; data += a; if (data.indexOf(target1) != -1) { ESP8266_LOG("\r\ndata5 = %s\r\n", data.c_str()); return data; } else if (data.indexOf(target2) != -1) { ESP8266_LOG("\r\ndata6 = %s\r\n", data.c_str()); return data; } else if (data.indexOf(target3) != -1) { ESP8266_LOG("\r\ndata7 = %s\r\n", data.c_str()); return data; } else if (checkIPD(data)) { data = ""; } } } ESP8266_LOG("\r\ndata8 = %s\r\n", data.c_str()); return data; } bool ESP8266::recvFind(String target, uint32_t timeout) { LOG_ENTER; String data_tmp; data_tmp = recvString(target, timeout); if (data_tmp.indexOf(target) != -1) { return true; } return false; } bool ESP8266::recvFindAndFilter(String target, String begin, String end, String &data, uint32_t timeout) { LOG_ENTER; String data_tmp; data_tmp = recvString(target, timeout); if (data_tmp.indexOf(target) != -1) { int32_t index1 = data_tmp.indexOf(begin); int32_t index2 = data_tmp.indexOf(end); if (index1 != -1 && index2 != -1) { index1 += begin.length(); data = data_tmp.substring(index1, index2); return true; } } data = data_tmp; return false; } bool ESP8266::eAT(void) { LOG_ENTER; rx_empty(); //m_puart->println(F("AT")); m_puart->printf("AT\r\n"); return recvFind("OK"); } bool ESP8266::eATRST(void) { LOG_ENTER; rx_empty(); //m_puart->println(F("AT+RST")); m_puart->printf("AT+RST\r\n"); return recvFind("OK"); } bool ESP8266::eATGMR(String &version) { LOG_ENTER; rx_empty(); wait_ms(3000); //m_puart->println(F("AT+GMR")); m_puart->printf("AT+GMR\r\n"); return recvFindAndFilter("OK", "\r\r\n", "\r\n\r\nOK", version, 10000); } bool ESP8266::eATGSLP(uint32_t time) { LOG_ENTER; rx_empty(); //m_puart->print(F("AT+GSLP=")); //m_puart->println(time); m_puart->printf("AT+GSLP=%u\r\n", time); return recvFind("OK"); } bool ESP8266::eATE(uint8_t mode) { LOG_ENTER; rx_empty(); //m_puart->print(F("ATE")); //m_puart->println(mode); m_puart->printf("ATE%d\r\n", mode); return recvFind("OK"); } bool ESP8266::eATRESTORE(void) { LOG_ENTER; rx_empty(); //m_puart->println(F("AT+RESTORE")); m_puart->printf("AT+RESTORE\r\n"); return recvFind("OK"); } bool ESP8266::eATSETUART(uint32_t baudrate,uint8_t pattern) { LOG_ENTER; rx_empty(); if(pattern>3||pattern<1) { return false; } switch(pattern) { case 1: //m_puart->print(F("AT+UART=")); m_puart->printf("AT+UART="); break; case 2: //m_puart->print(F("AT+UART_CUR=")); m_puart->printf("AT+UART_CUR="); break; case 3: //m_puart->print(F("AT+UART_DEF=")); m_puart->printf("AT+UART_DEF="); break; } #if 0 m_puart->print(baudrate); m_puart->print(F(",")); m_puart->print(8); m_puart->print(F(",")); m_puart->print(1); m_puart->print(F(",")); m_puart->print(0); m_puart->print(F(",")); m_puart->println(0); #else m_puart->printf("%u,%d,%d,%d,%d\r\n", baudrate, 8, 1, 0, 0); #endif if(recvFind("OK",5000)) { //m_puart->begin(baudrate); m_puart->baud(baudrate); return true; } else { return false; } } bool ESP8266::qATCWMODE(uint8_t *mode,uint8_t pattern) { LOG_ENTER; String str_mode; bool ret; if (!mode||!pattern) { return false; } rx_empty(); switch(pattern) { case 1 : //m_puart->println(F("AT+CWMODE_DEF?")); m_puart->printf("AT+CWMODE_DEF?\r\n"); break; case 2: //m_puart->println(F("AT+CWMODE_CUR?")); m_puart->printf("AT+CWMODE_CUR?\r\n"); break; default: //m_puart->println(F("AT+CWMODE?")); m_puart->printf("AT+CWMODE?\r\n"); } ret = recvFindAndFilter("OK", ":", "\r\n\r\nOK", str_mode); if (ret) { *mode = (uint8_t)str_mode.toInt(); return true; } else { return false; } } bool ESP8266::eATCWMODE(String &list) { LOG_ENTER; rx_empty(); //m_puart->println(F("AT+CWMODE=?")); m_puart->printf("AT+CWMODE=?\r\n"); return recvFindAndFilter("OK", "+CWMODE:(", ")\r\n\r\nOK", list); } bool ESP8266::sATCWMODE(uint8_t mode,uint8_t pattern) { LOG_ENTER; if(!pattern) { return false; } String data; rx_empty(); switch(pattern) { case 1 : //m_puart->print(F("AT+CWMODE_DEF=")); m_puart->printf("AT+CWMODE_DEF="); break; case 2: //m_puart->print(F("AT+CWMODE_CUR=")); m_puart->printf("AT+CWMODE_CUR="); break; default: //m_puart->print(F("AT+CWMODE=")); m_puart->printf("AT+CWMODE="); } //m_puart->println(mode); m_puart->printf("%d\r\n", mode); data = recvString("OK", "no change"); if (data.indexOf("OK") != -1 || data.indexOf("no change") != -1) { return true; } return false; } bool ESP8266::qATCWJAP(String &ssid,uint8_t pattern) { LOG_ENTER; bool ret; if (!pattern) { return false; } rx_empty(); switch(pattern) { case 1 : //m_puart->println(F("AT+CWJAP_DEF?")); m_puart->printf("AT+CWJAP_DEF?\r\n"); break; case 2: //m_puart->println(F("AT+CWJAP_CUR?")); m_puart->printf("AT+CWJAP_CUR?\r\n"); break; default: //m_puart->println(F("AT+CWJAP?")); m_puart->printf("AT+CWJAP?\r\n"); } ssid = recvString("OK", "No AP"); if (ssid.indexOf("OK") != -1 || ssid.indexOf("No AP") != -1) { return true; } return false; } bool ESP8266::sATCWJAP(String ssid, String pwd, uint8_t pattern) { LOG_ENTER; String data; if (!pattern) { return false; } rx_empty(); switch(pattern) { case 1 : //m_puart->print(F("AT+CWJAP_DEF=\"")); m_puart->printf("AT+CWJAP_DEF=\""); break; case 2: //m_puart->print(F("AT+CWJAP_CUR=\"")); m_puart->printf("AT+CWJAP_CUR=\""); break; default: //m_puart->print(F("AT+CWJAP=\"")); m_puart->printf("AT+CWJAP=\""); } #if 0 m_puart->print(ssid); m_puart->print(F("\",\"")); m_puart->print(pwd); m_puart->println(F("\"")); #else //TODO: m_puart->printf("%s\",\"%s\"\r\n", ssid.c_str(), pwd.c_str()); #endif data = recvString("OK", "FAIL", 20000); if (data.indexOf("OK") != -1) { return true; } return false; } bool ESP8266::eATCWLAP(String &list) { LOG_ENTER; String data; rx_empty(); //m_puart->println(F("AT+CWLAP")); m_puart->printf("AT+CWLAP\r\n"); return recvFindAndFilter("OK", "\r\r\n", "\r\n\r\nOK", list, 15000); } bool ESP8266::eATCWQAP(void) { LOG_ENTER; String data; rx_empty(); //m_puart->println(F("AT+CWQAP")); m_puart->printf("AT+CWQAP\r\n"); return recvFind("OK"); } bool ESP8266::qATCWSAP(String &List,uint8_t pattern) { LOG_ENTER; if (!pattern) { return false; } rx_empty(); switch(pattern) { case 1 : //m_puart->println(F("AT+CWSAP_DEF?")); m_puart->printf("AT+CWSAP_DEF?\r\n"); break; case 2: //m_puart->println(F("AT+CWSAP_CUR?")); m_puart->printf("AT+CWSAP_CUR?\r\n"); break; default: //m_puart->println(F("AT+CWSAP?")); m_puart->printf("AT+CWSAP?\r\n"); } return recvFindAndFilter("OK", "\r\r\n", "\r\n\r\nOK", List,10000); } bool ESP8266::sATCWSAP(String ssid, String pwd, uint8_t chl, uint8_t ecn,uint8_t pattern) { LOG_ENTER; String data; if (!pattern) { return false; } rx_empty(); switch(pattern) { case 1 : //m_puart->print(F("AT+CWSAP_DEF=\"")); m_puart->printf("AT+CWSAP_DEF=\""); break; case 2: //m_puart->print(F("AT+CWSAP_CUR=\"")); m_puart->printf("AT+CWSAP_CUR=\""); break; default: //m_puart->print(F("AT+CWSAP=\"")); m_puart->printf("AT+CWSAP=\""); } #if 0 m_puart->print(ssid); m_puart->print(F("\",\"")); m_puart->print(pwd); m_puart->print(F("\",")); m_puart->print(chl); m_puart->print(F(",")); m_puart->println(ecn); #else m_puart->printf("%s\",\"%s\",%d,%d\r\n", ssid.c_str(), pwd.c_str(), chl, ecn); #endif data = recvString("OK", "ERROR", 5000); if (data.indexOf("OK") != -1) { return true; } return false; } bool ESP8266::eATCWLIF(String &list) { LOG_ENTER; String data; rx_empty(); //m_puart->println(F("AT+CWLIF")); m_puart->printf("AT+CWLIF\r\n"); return recvFindAndFilter("OK", "\r\r\n", "\r\n\r\nOK", list); } bool ESP8266::qATCWDHCP(String &List,uint8_t pattern) { LOG_ENTER; if (!pattern) { return false; } rx_empty(); switch(pattern) { case 1 : //m_puart->println(F("AT+CWDHCP_DEF?")); m_puart->printf("AT+CWDHCP_DEF?\r\n"); break; case 2: //m_puart->println(F("AT+CWDHCP_CUR?")); m_puart->printf("AT+CWDHCP_CUR?\r\n"); break; default: //m_puart->println(F("AT+CWDHCP?")); m_puart->printf("AT+CWDHCP?\r\n"); } return recvFindAndFilter("OK", "\r\r\n", "\r\nOK", List,10000); } bool ESP8266::sATCWDHCP(uint8_t mode, uint8_t en, uint8_t pattern) { LOG_ENTER; String data; if (!pattern) { return false; } rx_empty(); switch(pattern) { case 1 : //m_puart->print(F("AT+CWDHCP_DEF=")); m_puart->printf("AT+CWDHCP_DEF="); break; case 2: //m_puart->print(F("AT+CWDHCP_CUR=")); m_puart->printf("AT+CWDHCP_CUR="); break; default: //m_puart->print(F("AT+CWDHCP=")); m_puart->printf("AT+CWDHCP="); } #if 0 m_puart->print(mode); m_puart->print(F(",")); m_puart->println(en); #else m_puart->printf("%d,%d\r\n", mode, en); #endif data = recvString("OK", "ERROR", 2000); if (data.indexOf("OK") != -1) { return true; } return false; } bool ESP8266::eATCWAUTOCONN(uint8_t en) { LOG_ENTER; rx_empty(); if(en>1||en<0) { return false; } #if 0 m_puart->print(F("AT+CWAUTOCONN=")); m_puart->println(en); #else m_puart->printf("AT+CWAUTOCONN=%d\r\n", en); #endif return recvFind("OK"); } bool ESP8266::qATCIPSTAMAC(String &mac,uint8_t pattern) { LOG_ENTER; rx_empty(); if (!pattern) { return false; } switch(pattern) { case 1 : //m_puart->println(F("AT+CIPSTAMAC_DEF?")); m_puart->printf("AT+CIPSTAMAC_DEF?\r\n"); break; case 2: //m_puart->println(F("AT+CIPSTAMAC_CUR?")); m_puart->printf("AT+CIPSTAMAC_CUR?\r\n"); break; default: //m_puart->println(F("AT+CIPSTAMAC?")); m_puart->printf("AT+CIPSTAMAC?\r\n"); } return recvFindAndFilter("OK", "\r\r\n", "\r\n\r\nOK", mac,2000); } bool ESP8266::eATCIPSTAMAC(String mac,uint8_t pattern) { LOG_ENTER; rx_empty(); if (!pattern) { return false; } switch(pattern) { case 1 : //m_puart->print(F("AT+CIPSTAMAC_DEF=")); m_puart->printf("AT+CIPSTAMAC_DEF="); break; case 2: //m_puart->print(F("AT+CIPSTAMAC_CUR=")); m_puart->printf("AT+CIPSTAMAC_CUR="); break; default: //m_puart->print(F("AT+CIPSTAMAC=")); m_puart->printf("AT+CIPSTAMAC="); } #if 0 m_puart->print(F("\"")); m_puart->print(mac); m_puart->println(F("\"")); #else m_puart->printf("\"%s\"\r\n", mac.c_str()); #endif return recvFind("OK"); } bool ESP8266::qATCIPSTAIP(String &ip,uint8_t pattern) { LOG_ENTER; rx_empty(); if (!pattern) { return false; } switch(pattern) { case 1 : //m_puart->println(F("AT+CIPSTA_DEF?")); m_puart->printf("AT+CIPSTA_DEF?\r\n"); break; case 2: //m_puart->println(F("AT+CIPSTA_CUR?")); m_puart->printf("AT+CIPSTA_CUR?\r\n"); break; default: //m_puart->println(F("AT+CIPSTA?")); m_puart->printf("AT+CIPSTA?\r\n"); } return recvFindAndFilter("OK", "\r\r\n", "\r\n\r\nOK", ip,2000); } bool ESP8266::eATCIPSTAIP(String ip,String gateway,String netmask,uint8_t pattern) { LOG_ENTER; rx_empty(); if (!pattern) { return false; } switch(pattern) { case 1 : //m_puart->print(F("AT+CIPSTA_DEF=")); m_puart->printf("AT+CIPSTA_DEF="); break; case 2: //m_puart->print(F("AT+CIPSTA_CUR=")); m_puart->printf("AT+CIPSTA_CUR="); break; default: //m_puart->print(F("AT+CIPSTA=")); m_puart->printf("AT+CIPSTA="); } #if 0 m_puart->print(F("\"")); m_puart->print(ip); m_puart->print(F("\",\"")); m_puart->print(gateway); m_puart->print(F("\",\"")); m_puart->print(netmask); m_puart->println(F("\"")); #else m_puart->printf("\"%s\",\"%s\",\"%s\"\r\n", ip.c_str(), gateway.c_str(), netmask.c_str()); #endif return recvFind("OK"); } bool ESP8266::qATCIPAP(String &ip,uint8_t pattern) { LOG_ENTER; rx_empty(); if (!pattern) { return false; } switch(pattern) { case 1 : //m_puart->println(F("AT+CIPAP_DEF?")); m_puart->printf("AT+CIPAP_DEF?\r\n"); break; case 2: //m_puart->println(F("AT+CIPAP_CUR?")); m_puart->printf("AT+CIPAP_CUR?\r\n"); break; default: //m_puart->println(F("AT+CIPAP?")); m_puart->printf("AT+CIPAP?\r\n"); } return recvFindAndFilter("OK", "\r\r\n", "\r\n\r\nOK", ip,2000); } bool ESP8266::eATCIPAP(String ip,uint8_t pattern) { LOG_ENTER; rx_empty(); if (!pattern) { return false; } switch(pattern) { case 1 : //m_puart->print(F("AT+CIPAP_DEF=")); m_puart->printf("AT+CIPAP_DEF="); break; case 2: //m_puart->print(F("AT+CIPAP_CUR=")); m_puart->printf("AT+CIPAP_CUR="); break; default: //m_puart->print(F("AT+CIPAP=")); m_puart->printf("AT+CIPAP="); } #if 0 m_puart->print(F("\"")); m_puart->print(ip); m_puart->println(F("\"")); #else m_puart->printf("\"%s\"\r\n", ip.c_str()); #endif return recvFind("OK"); } bool ESP8266::eCWSTARTSMART(uint8_t type) { LOG_ENTER; rx_empty(); #if 0 m_puart->print(F("AT+CWSTARTSMART=")); m_puart->println(type); #else m_puart->printf("AT+CWSTARTSMART=%d\r\n", type); #endif return recvFind("OK"); } bool ESP8266::eCWSTOPSMART(void) { LOG_ENTER; rx_empty(); //m_puart->println(F("AT+CWSTOPSMART")); m_puart->printf("AT+CWSTOPSMART\r\n"); return recvFind("OK"); } bool ESP8266::eATCIPSTATUS(String &list) { LOG_ENTER; String data; //delay(100); wait_ms(100); rx_empty(); //m_puart->println(F("AT+CIPSTATUS")); m_puart->printf("AT+CIPSTATUS\r\n"); return recvFindAndFilter("OK", "\r\r\n", "\r\n\r\nOK", list); } bool ESP8266::sATCIPSTARTSingle(String type, String addr, uint32_t port) { LOG_ENTER; String data; rx_empty(); #if 0 m_puart->print(F("AT+CIPSTART=\"")); m_puart->print(type); m_puart->print(F("\",\"")); m_puart->print(addr); m_puart->print(F("\",")); m_puart->println(port); #else m_puart->printf("AT+CIPSTART=\"%s\",\"%s\",%u\r\n", type.c_str(), addr.c_str(), port); #endif data = recvString("OK", "ERROR", "ALREADY CONNECT", 10000); if (data.indexOf("OK") != -1 || data.indexOf("ALREADY CONNECT") != -1) { return true; } return false; } bool ESP8266::sATCIPSTARTMultiple(uint8_t mux_id, String type, String addr, uint32_t port) { LOG_ENTER; String data; rx_empty(); #if 0 m_puart->print(F("AT+CIPSTART=")); m_puart->print(mux_id); m_puart->print(F(",\"")); m_puart->print(type); m_puart->print(F("\",\"")); m_puart->print(addr); m_puart->print(F("\",")); m_puart->println(port); #else m_puart->printf("AT+CIPSTART=%d,\"%s\",\"%s\",%u\r\n", mux_id, type.c_str(), addr.c_str(), port); #endif data = recvString("OK", "ERROR", "ALREADY CONNECT", 10000); if (data.indexOf("OK") != -1 || data.indexOf("ALREADY CONNECT") != -1) { return true; } return false; } bool ESP8266::sATCIPSENDSingle(const uint8_t *buffer, uint32_t len) { LOG_ENTER; rx_empty(); #if 0 m_puart->print(F("AT+CIPSEND=")); m_puart->println(len); #else m_puart->printf("AT+CIPSEND=%u\r\n", len); #endif if (recvFind(">", 5000)) { rx_empty(); for (uint32_t i = 0; i < len; i++) { //m_puart->write(buffer[i]); m_puart->putc(buffer[i]); } return recvFind("SEND OK", 10000); } return false; } bool ESP8266::sATCIPSENDMultiple(uint8_t mux_id, const uint8_t *buffer, uint32_t len) { LOG_ENTER; rx_empty(); #if 0 m_puart->print(F("AT+CIPSEND=")); m_puart->print(mux_id); m_puart->print(F(",")); m_puart->println(len); #else m_puart->printf("AT+CIPSEND=%d,%u\r\n", mux_id, len); #endif if (recvFind(">", 5000)) { rx_empty(); for (uint32_t i = 0; i < len; i++) { //m_puart->write(buffer[i]); m_puart->putc(buffer[i]); } return recvFind("SEND OK", 10000); } return false; } bool ESP8266::sATCIPSENDSingleFromFlash(const uint8_t *buffer, uint32_t len) { LOG_ENTER; rx_empty(); #if 0 m_puart->print(F("AT+CIPSEND=")); m_puart->println(len); #else m_puart->printf("AT+CIPSEND=%u\r\n", len); #endif if (recvFind(">", 5000)) { rx_empty(); for (uint32_t i = 0; i < len; i++) { //m_puart->write((char) pgm_read_byte(&buffer[i])); m_puart->putc(buffer[i]); } return recvFind("SEND OK", 10000); } return false; } bool ESP8266::sATCIPSENDMultipleFromFlash(uint8_t mux_id, const uint8_t *buffer, uint32_t len) { LOG_ENTER; rx_empty(); #if 0 m_puart->print(F("AT+CIPSEND=")); m_puart->print(mux_id); m_puart->print(F(",")); m_puart->println(len); #else m_puart->printf("AT+CIPSEND=%d,%u\r\n", mux_id, len); #endif if (recvFind(">", 5000)) { rx_empty(); for (uint32_t i = 0; i < len; i++) { //m_puart->write((char) pgm_read_byte(&buffer[i])); m_puart->putc(buffer[i]); } return recvFind("SEND OK", 10000); } return false; } bool ESP8266::sATCIPCLOSEMulitple(uint8_t mux_id) { LOG_ENTER; String data; rx_empty(); #if 0 m_puart->print(F("AT+CIPCLOSE=")); m_puart->println(mux_id); #else m_puart->printf("AT+CIPCLOSE=%d\r\n", mux_id); #endif data = recvString("OK", "link is not", 5000); if (data.indexOf("OK") != -1 || data.indexOf("link is not") != -1) { return true; } return false; } bool ESP8266::eATCIPCLOSESingle(void) { LOG_ENTER; rx_empty(); //m_puart->println(F("AT+CIPCLOSE")); m_puart->printf("AT+CIPCLOSE\r\n"); return recvFind("OK", 5000); } bool ESP8266::eATCIFSR(String &list) { LOG_ENTER; rx_empty(); //m_puart->println(F("AT+CIFSR")); m_puart->printf("AT+CIFSR\r\n"); return recvFindAndFilter("OK", "\r\r\n", "\r\n\r\nOK", list); } bool ESP8266::sATCIPMUX(uint8_t mode) { LOG_ENTER; String data; rx_empty(); #if 0 m_puart->print(F("AT+CIPMUX=")); m_puart->println(mode); #else m_puart->printf("AT+CIPMUX=%d\r\n", mode); #endif data = recvString("OK", "Link is builded"); if (data.indexOf("OK") != -1) { return true; } return false; } bool ESP8266::sATCIPSERVER(uint8_t mode, uint32_t port) { LOG_ENTER; String data; if (mode) { rx_empty(); #if 0 m_puart->print(F("AT+CIPSERVER=1,")); m_puart->println(port); #else m_puart->printf("AT+CIPSERVER=1,%u\r\n", port); #endif data = recvString("OK", "no change"); if (data.indexOf("OK") != -1 || data.indexOf("no change") != -1) { return true; } return false; } else { rx_empty(); //m_puart->println(F("AT+CIPSERVER=0")); m_puart->printf("AT+CIPSERVER=0\r\n"); return recvFind("\r\r\n"); } } bool ESP8266::sATCIPMODE(uint8_t mode) { LOG_ENTER; String data; if(mode>1||mode<0) { return false; } rx_empty(); #if 0 m_puart->print(F("AT+CIPMODE=")); m_puart->println(mode); #else m_puart->printf("AT+CIPMODE=%d\r\n", mode); #endif data = recvString("OK", "Link is builded",2000); if (data.indexOf("OK") != -1 ) { return true; } return false; } bool ESP8266::eATSAVETRANSLINK(uint8_t mode,String ip,uint32_t port) { LOG_ENTER; String data; rx_empty(); #if 0 m_puart->print(F("AT+SAVETRANSLINK=")); m_puart->print(mode); m_puart->print(F(",\"")); m_puart->print(ip); m_puart->print(F("\",")); m_puart->println(port); #else m_puart->printf("AT+SAVETRANSLINK=%d,\"%s\",%u\r\n", mode, ip.c_str(), port); #endif data = recvString("OK", "ERROR",2000); if (data.indexOf("OK") != -1 ) { return true; } return false; } bool ESP8266::eATPING(String ip) { LOG_ENTER; rx_empty(); #if 0 m_puart->print(F("AT+PING=")); m_puart->print(F("\"")); m_puart->print(ip); m_puart->println(F("\"")); #else m_puart->printf("AT+PING=\"%s\"\r\n", ip.c_str()); #endif return recvFind("OK",2000); } bool ESP8266::sATCIPSTO(uint32_t timeout) { LOG_ENTER; rx_empty(); #if 0 m_puart->print(F("AT+CIPSTO=")); m_puart->println(timeout); #else m_puart->printf("AT+CIPSTO=%u\r\n", timeout); #endif return recvFind("OK"); }