モータードライバとWi-FiモジュールESP-WROOM-02をmbed LPC1114FN28に繋げて、RCWControllerからコントロールするプログラム
Dependencies: mbed
ESP8266InterfaceTiny/ESP8266/ESP8266.cpp
- Committer:
- jksoft
- Date:
- 2016-07-22
- Revision:
- 0:3c24a40c2343
File content as of revision 0:3c24a40c2343:
/* Copyright (C) 2012 mbed.org, MIT License * * 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. */ #include "mbed.h" #include "ESP8266.h" #include "Endpoint.h" //#include <string> //#include <algorithm> #include "SoftSerialSendOnry.h" extern SoftSerialSendOnry pc; //Debug is disabled by default #if 0 #define DBG(x, ...) pc.printf("[ESP8266 : DBG]"x" \t[%s,%d]\r\n", ##__VA_ARGS__,__FILE__,__LINE__); #define WARN(x, ...) pc.printf("[ESP8266 : WARN]"x" \t[%s,%d]\r\n", ##__VA_ARGS__,__FILE__,__LINE__); #define ERR(x, ...) pc.printf("[ESP8266 : ERR]"x" \t[%s,%d]\r\n", ##__VA_ARGS__,__FILE__,__LINE__); #else #define DBG(x, ...) //wait_us(10); #define WARN(x, ...) //wait_us(10); #define ERR(x, ...) #endif #if 0 #define INFO(x, ...) printf("[ESP8266 : INFO]"x" \t[%s,%d]\r\n", ##__VA_ARGS__,__FILE__,__LINE__); #else #define INFO(x, ...) #endif #define ESP_MAX_TRY_JOIN 3 #define ESP_MAXID 4 // the largest possible ID Value (max num of sockets possible) ESP8266 * ESP8266::inst; char* ip = NULL; ESP8266::ESP8266(PinName tx, PinName rx, PinName reset, const char *ssid, const char *phrase, uint32_t baud) : wifi(tx, rx), reset_pin(reset), buf_ESP8266(ESP_MBUFFE_MAX) { INFO("Initializing ESP8266 object"); memset(&state, 0, sizeof(state)); strcpy(this->ssid, ssid); strcpy(this->phrase, phrase); inst = this; attach_rx(false); wifi.baud(baud); // initial baud rate of the ESP8266 state.associated = false; state.cmdMode = false; } bool ESP8266::join() { char cmd[100]; sendCommand( "AT+CWMODE=1", "change", NULL, 1000); //string cmd="AT+CWJAP=\""+(string)this->ssid+"\",\""+(string)this->phrase+"\""; sprintf(cmd,"AT+CWJAP=\"%s\",\"%s\"",this->ssid,this->phrase); if( sendCommand( cmd, "OK", NULL, 10000) ) { // successfully joined the network state.associated = true; INFO("ssid: %s, phrase: %s", this->ssid, this->phrase); return true; } return false; } bool ESP8266::single_ap() { char cmd[100]; sendCommand( "AT+CWMODE=2", "change", NULL, 1000); //string cmd="AT+CWJAP=\""+(string)this->ssid+"\",\""+(string)this->phrase+"\""; sprintf(cmd,"AT+CWSAP=\"%s\",\"%s\",11,3",this->ssid,this->phrase); if( sendCommand( cmd, "OK", NULL, 10000) ) { // successfully joined the network state.associated = true; INFO("ssid: %s, phrase: %s", this->ssid, this->phrase); wait(1); // Enable DHCP sendCommand("AT+CWDHCP=0,1","OK",NULL,1000); wait(1); return true; } return false; } bool ESP8266::connect() { sendCommand("AT+CWDHCP=1,1","OK",NULL,1000); // DHCP Enabled in Station Mode return ESP8266::join(); } bool ESP8266::is_connected() { return true; } bool ESP8266::start(bool type,char* ip, int port, int id) { char cmd[256]; // Error Check if(id > ESP_MAXID) { ERR("startUDPMulti: max id is: %d, id given is %d",ESP_MAXID,id); return false; } // Single Connection Mode if(id < 0) { DBG("Start Single Connection Mode"); //char portstr[5]; bool check [3] = {0}; //sprintf(portstr, "%d", port); switch(type) { case ESP_UDP_TYPE : //UDP sprintf(cmd,"AT+CIPSTART=\"UDP\",\"%s\",%d,%d,0",ip,port,port+1); pc.printf("%s\r\n",cmd); check[0] = sendCommand(cmd, "OK", NULL, 10000); //check[0] = sendCommand(( "AT+CIPSTART=\"UDP\",\"" + (string) ip + "\"," + (string) portstr ).c_str(), "OK", NULL, 10000); break; case ESP_TCP_TYPE : //TCP sprintf(cmd,"AT+CIPSTART=\"TCP\",\"%s\",%d",ip,port); check[0] = sendCommand(cmd, "OK", NULL, 10000); //check[0] = sendCommand(( "AT+CIPSTART=\"TCP\",\"" + (string) ip + "\"," + (string) portstr ).c_str(), "OK", NULL, 10000); break; default: ERR("Default hit for starting connection, this shouldnt be possible!!"); break; } check[1] = sendCommand("AT+CIPMODE=1", "OK", NULL, 1000);// go into transparent mode check[2] = sendCommand("AT+CIPSEND", ">", NULL, 1000);// go into transparent mode // check that all commands were sucessful if(check[0] and check[1] and check[2]) { state.cmdMode = false; return true; } else { ERR("startUDPTransparent Failed for ip:%s, port:%d",ip,port); return false; } } // Multi Connection Mode else { //TODO: impliment Multi Connection Mode ERR("Not currently Supported!"); return false; } } bool ESP8266::startUDP(char* ip, int port, int id, int length) { char cmd[256]; char portstr[5]; char idstr[1]; char lenstr[2]; sprintf(portstr, "%d", port); sprintf(idstr, "%d", id); sprintf(lenstr, "%d", length); sendCommand("AT+CIPMUX=1", "OK", NULL, 1000); sprintf(cmd,"AT+CIPSTART=%d,\"UDP\",\"%s\",%d,1112,0",id,ip,port); sendCommand(cmd, "OK", NULL, 10000); //sendCommand(( "AT+CIPSTART=" + string(idstr) + ",\"UDP\",\"" + (string) ip + "\"," + (string) portstr + ",1112,0").c_str(), "OK", NULL, 10000); sprintf(cmd,"AT+CIPSEND=%d,%d",id,length); sendCommand(cmd, ">", NULL, 1000);// go into transparent mode //sendCommand(("AT+CIPSEND=" + (string)idstr + "," + (string)lenstr).c_str(), ">", NULL, 1000);// go into transparent mode DBG("Data Mode\r\n"); state.cmdMode = false; return true; } bool ESP8266::startTCPServer(int port) { char cmd[100]; bool command_results[3]; command_results[0]=sendCommand("AT+CWMODE=3", "OK", NULL, 1000); command_results[1]=sendCommand("AT+CIPMUX=1", "OK", NULL, 1000); if(port == 333){ command_results[2]=sendCommand("AT+CIPSERVER=1", "OK", NULL, 1000); } else{ sprintf(cmd,"AT+CIPSERVER=1,%d",port); command_results[2]=sendCommand(cmd, "OK", NULL, 1000); } //sendCommand("AT+CIFSR", "OK", NULL, 1000); DBG("Data Mode\r\n"); state.cmdMode = false; if (command_results[0] and command_results[1] and command_results[2]){ return true; } else{ return false; } } bool ESP8266::close() { wait(0.1f); send("+++",3); wait(1.0f); state.cmdMode = true; sendCommand("AT+CIPCLOSE","OK", NULL, 10000); return true; } bool ESP8266::disconnect() { // if already disconnected, return if (!state.associated) return true; // send command to quit AP sendCommand("AT+CWQAP", "OK", NULL, 10000); state.associated = false; return true; } int ESP8266::strfind(const char *str,const char *chkstr,int pos) { if( (strlen(str)-pos) < strlen(chkstr) ) return(-1); for(int i=pos;i<strlen(str);i++) { if(memcmp(chkstr,&str[i],strlen(chkstr))==0) { return(i); } } return(-1); } char* ESP8266::substr(const char *str , char *outstr , int pos1 , int pos2 ) { int size = pos2 - pos1; memcpy(outstr , &str[pos1] , size ); outstr[size] = '\0'; return(outstr); } int ESP8266::strcount(const char *str , char countstr ) { int ret = 0; for(int i = 0 ; i < strlen(str) ; i++) { if( str[i] == countstr ) { ret++; } } return(ret); } /* Assuming Returned data looks like this: +CIFSR:STAIP,"192.168.11.2" +CIFSR:STAMAC,"18:fe:34:9f:3a:f5" grabbing IP from first set of quotation marks */ char* ESP8266::getIPAddress() { char result[80] = {0}; char tmp[30] = {0}; int check = 0; check = sendCommand("AT+CIFSR", NULL, result, 1000); pc.printf("\r\nReceivedInfo for IP Command is: %s\r\n",result); ip = ipString; if(check) { // Success uint8_t pos1 = 0, pos2 = 0; //uint8_t pos3 = 0, pos4 = 0; //pos1 = strfind(result,"+CIFSR:STAIP",0); pos1 = strfind(result,"+CIFSR:APIP",0); //pos1 = resultString.find("+CIFSR:STAIP"); pos1 = strfind(result,"\"",pos1); //pos1 = resultString.find('"',pos1); pos2 = strfind(result,"\"",pos1+1); //pos2 = resultString.find('"',pos1+1); //pos3 = resultString.find('"',pos2+1); //would find mac address //pos4 = resultString.find('"',pos3+1); strncpy(ipString,substr(result,tmp,pos1+1,pos2),sizeof(ipString)); ipString[pos2 - pos1 +1] = 0; // null terminate string correctly. INFO("IP: %s",ipString); ip = ipString; } else { // Failure ERR("getIPAddress() failed"); ip = NULL; } return ip; } bool ESP8266::gethostbyname(const char * host, char * ip) { int nb_digits = 0; char tmp[100]; strcpy(ip,host); return true; #if 0 // no dns needed int pos = strfind(host,".",0); if (pos != -1) { nb_digits = atoi(substr(host,tmp,0,pos)); } //printf("substrL %s\r\n", sub.c_str()); if (strcount(host,'.') == 3 && nb_digits > 0) { strcpy(ip, host); return true; } else { // dns needed, not currently available ERR("gethostbyname(): DNS Not currently available, only use IP Addresses!"); return false; } #endif } void ESP8266::reset() { reset_pin = 0; wait_us(20); reset_pin = 1; //wait(1); //reset_pin = !reset_pin //send("+++",3); wait(1); state.cmdMode = true; sendCommand("AT", "OK", NULL, 1000); sendCommand("AT+RST", "ready", NULL, 10000); state.associated = false; } bool ESP8266::reboot() { reset(); return true; } void ESP8266::handler_rx(void) { //read characters char c; while (wifi.readable()) { c=wifi.getc(); buf_ESP8266.queue(c); //if (state.cmdMode) pc.printf("%c",c); //debug echo, needs fast serial console to prevent UART overruns } } void ESP8266::attach_rx(bool callback) { if (!callback) { wifi.attach(NULL); } else { wifi.attach(this, &ESP8266::handler_rx); } } int ESP8266::readable() { return buf_ESP8266.available(); } int ESP8266::writeable() { return wifi.writeable(); } char ESP8266::getc() { char c=0; while (!buf_ESP8266.available()); buf_ESP8266.dequeue(&c); return c; } int ESP8266::putc(char c) { while (!wifi.writeable() || wifi.readable()); //wait for echoed command characters to be read first return wifi.putc(c); } void ESP8266::flush() { buf_ESP8266.flush(); } int ESP8266::send(const char * buf, int len) { //TODO: need to add handler for data > 2048B, this is the max packet size of the ESP8266. if(len >= 2048){ WARN("send buffer >= 2048B, need to chunk this up to be less."); } const char* bufptr=buf; for(int i=0; i<len; i++) { putc((int)*bufptr++); } return len; } bool ESP8266::sendCommand(const char * cmd, const char * ACK, char * res, int timeout) { char read; char checking[512] = ""; int checking_size = 0; int fond = -1; Timer tmr; int result = 0; DBG("sendCmd:\t %s",cmd); attach_rx(true); //We flush the buffer while (readable()) getc(); if (!ACK || !strcmp(ACK, "NO")) { for (int i = 0; i < strlen(cmd); i++) { result = (putc(cmd[i]) == cmd[i]) ? result + 1 : result; wait(0.005f); // prevents stuck recieve ready (?) need to let echoed character get read first } putc(13); //CR wait(0.005f); // wait for echo putc(10); //LF } else { //We flush the buffer while (readable()) getc(); tmr.start(); for (int i = 0; i < strlen(cmd); i++) { result = (putc(cmd[i]) == cmd[i]) ? result + 1 : result; wait(.005); // wait for echo } putc(13); //CR wait(0.005f); // wait for echo putc(10); //LF while (1) { if (tmr.read_ms() > timeout) { //We flush the buffer while (readable()) getc(); DBG("check:\t %s", checking); attach_rx(true); return -1; } else if (readable()) { read = getc(); //pc.printf("%c",read); //debug echo if ( read != '\r' && read != '\n') { checking[checking_size] = read; checking_size++; checking[checking_size] = '\0'; fond = strfind(checking,ACK,0); if (fond != -1) { wait(0.01f); //We flush the buffer while (readable()) read = getc(); //printf("%c",read); //debug echo break; } } } } DBG("check: %s", checking); attach_rx(true); return result; } //the user wants the result from the command (ACK == NULL, res != NULL) if (res != NULL) { int i = 0; Timer timeout; timeout.start(); tmr.reset(); while (1) { if (timeout.read() > 2) { if (i == 0) { res = NULL; break; } res[i] = '\0'; DBG("user str 1: %s", res); break; } else { if (tmr.read_ms() > 300) { res[i] = '\0'; DBG("user str: %s", res); break; } if (readable()) { tmr.start(); read = getc(); // we drop \r and \n if ( read != '\r' && read != '\n') { res[i++] = read; } } } } DBG("user str: %s", res); } //We flush the buffer while (readable()) getc(); attach_rx(true); DBG("result: %d", result) return result; }