smartcontrol remote
Dependencies: EthernetInterface HTTPServer RemoteIR SDFileSystem mbed-rpc mbed-rtos mbed
Fork of SmartRemote by
main.cpp
- Committer:
- sammacjunkie
- Date:
- 2013-12-03
- Revision:
- 14:2b63c0f795cb
- Parent:
- 13:12749822ba56
- Child:
- 15:c8074f5f241a
File content as of revision 14:2b63c0f795cb:
#include "mbed.h" #include "EthernetInterface.h" #include "HTTPServer.h" #include "FsHandler.h" #include "RpcHandler.h" #include "rtos.h" DigitalOut led1(LED1); DigitalOut led2(LED2); //Start IR #include "ReceiverIR.h" #include "TransmitterIR.h" #include "IR.h" //END IR // Start DB #include <stdio.h> #include <stdlib.h> #include "SDFileSystem.h" #include "db.h" // End DB // Start RPC #include "RPCVariable.h" int Request = 0; int Learn = 0; char Learn_name0; char Learn_name1; char Learn_name2; char Learn_name3; char Learn_name4; char Learn_name5; char Learn_name6; char Learn_name7; char Learn_name8; char Learn_name9; //Make these variables accessible over RPC by attaching them to an RPCVariable RPCVariable<int> RPCRequest(&Request, "Request"); RPCVariable<int> RPCLearn(&Learn, "Learn"); RPCVariable<char> RPCLearner0(&Learn_name0, "Learn_name0"); RPCVariable<char> RPCLearner1(&Learn_name1, "Learn_name1"); RPCVariable<char> RPCLearner2(&Learn_name2, "Learn_name2"); RPCVariable<char> RPCLearner3(&Learn_name3, "Learn_name3"); RPCVariable<char> RPCLearner4(&Learn_name4, "Learn_name4"); RPCVariable<char> RPCLearner5(&Learn_name5, "Learn_name5"); RPCVariable<char> RPCLearner6(&Learn_name6, "Learn_name6"); RPCVariable<char> RPCLearner7(&Learn_name7, "Learn_name7"); RPCVariable<char> RPCLearner8(&Learn_name8, "Learn_name8"); RPCVariable<char> RPCLearner9(&Learn_name9, "Learn_name9"); // End RPC Serial pc(USBTX, USBRX, "pc"); // Instantiate a HTTPServer to handle incoming requests HTTPServer svr; // Instantiate a local file system handler named 'local' which will be used later to access files on the mbed. LocalFileSystem local("local"); SDFileSystem sd(p5, p6, p7, p8, "sd"); // the pinout on the mbed int main() { printf("Setting up Apache...\n \r"); HTTPFsRequestHandler::mount("/local/", "/"); HTTPFsRequestHandler::mount("/sd/", "/sd/"); svr.addHandler<HTTPFsRequestHandler>("/"); svr.addHandler<HTTPRpcRequestHandler>("/rpc"); EthernetInterface eth; eth.init(); //Use DHCP eth.connect(); // Now start the server on port 80. if (!svr.start(80, ð)) { error("Server not starting !"); exit(0); } printf("IP: %s\n \r", eth.getIPAddress()); printf("Setup OK\n \r"); // DB Init mkdir("/sd/SmartRemote", 0777); char tuple_code[128]; char tuple_name[128]; char tuple_bitlength[128]; char tuple_format[128]; char temp[20]; //End DB init //IR Init uint8_t buf1[32]; uint8_t buf2[32]; int bitlength1; int bitlength2; RemoteIR::Format format; memset(buf1, 0x00, sizeof(buf1)); memset(buf2, 0x00, sizeof(buf2)); //END IR Init printf("Listening...\n \r"); Timer tm; tm.start(); //Listen indefinitely while(true) { svr.poll(); if(tm.read()>.5) { tm.start(); } if (Learn) { // Debug LED led1 = 1; // Receive the code { bitlength1 = receive(&format, buf1, sizeof(buf1)); if (bitlength1 < 0) { continue; } display_status("RECV", bitlength1); display_data(buf1, bitlength1); //display_format(format); } // Reset led1 = 0; Learn = 0; // Set up the variables sprintf(tuple_name, "%c%c%c%c%c%c%c%c%c%c", Learn_name0,Learn_name1,Learn_name2,Learn_name3,Learn_name4,Learn_name5,Learn_name6,Learn_name7,Learn_name8,Learn_name9); //sprintf(tuple_code, "%X", buf1); sprintf(tuple_bitlength, "%d", bitlength1); sprintf(tuple_format, "%d", format); for (int i = 0; i < 10; i++) { if (tuple_name[i] == '~') tuple_name[i] = ' '; } const int n = bitlength1 / 8 + (((bitlength1 % 8) != 0) ? 1 : 0); strcpy(tuple_code, ""); for (int i = 0; i < n; i++) { sprintf(temp, "%02X", buf1[i]); strcat(tuple_code, temp); } // Insert into DB db_insert_tuple(tuple_name, tuple_code, tuple_bitlength, tuple_format); } if ( Request != 0) { led2 = 1; db_find_tuple(Request, tuple_name, tuple_code, tuple_bitlength, tuple_format); { RemoteIR::Format f = static_cast<RemoteIR::Format>(atoi(tuple_format)); bitlength1 = transmit(f, (uint8_t *)atoi(tuple_code), atoi(tuple_bitlength)); if (bitlength1 < 0) { continue; } printf("%d", (uint8_t *)atoi(tuple_code)); display_status("TRAN", bitlength1); //display_data(buf1, bitlength1); //display_format(format); } led2 = 0; Request = 0; } } return 0; }