Rick McConney
/
AvnetATT_shape_hackathon
This program simply connects to a HTS221 I2C device to proximity sensor
main.cpp
- Committer:
- elmkom
- Date:
- 2016-09-26
- Revision:
- 38:532a0d929756
- Parent:
- 37:ee01f752524a
- Child:
- 39:3bbb3dbb531b
File content as of revision 38:532a0d929756:
#include "mbed.h" #include <cctype> #include <string> #include "SerialBuffered.h" #include "HTS221.h" #include "config_me.h" #include "wnc_control.h" #include "sensors.h" #include "Proximity.h" #include "hardware.h" I2C i2c(PTC11, PTC10); //SDA, SCL -- define the I2C pins being used Proximity proximityStrip; // comment out the following line if color is not supported on the terminal #define USE_COLOR #ifdef USE_COLOR #define BLK "\033[30m" #define RED "\033[31m" #define GRN "\033[32m" #define YEL "\033[33m" #define BLU "\033[34m" #define MAG "\033[35m" #define CYN "\033[36m" #define WHT "\033[37m" #define DEF "\033[39m" #else #define BLK #define RED #define GRN #define YEL #define BLU #define MAG #define CYN #define WHT #define DEF #endif #define MDM_DBG_OFF 0 #define MDM_DBG_AT_CMDS (1 << 0) #define MUXADDRESS 0x70 #define PROXIMITYADDRESS 0x39 int mdm_dbgmask = MDM_DBG_OFF; Serial pc(USBTX, USBRX); SerialBuffered mdm(PTD3, PTD2, 128); DigitalOut led_green(LED_GREEN); DigitalOut led_red(LED_RED); DigitalOut led_blue(LED_BLUE); DigitalOut mdm_uart2_rx_boot_mode_sel(PTC17); // on powerup, 0 = boot mode, 1 = normal boot DigitalOut mdm_power_on(PTB9); // 0 = turn modem on, 1 = turn modem off (should be held high for >5 seconds to cycle modem) DigitalOut mdm_wakeup_in(PTC2); // 0 = let modem sleep, 1 = keep modem awake -- Note: pulled high on shield DigitalOut mdm_reset(PTC12); // active high DigitalOut shield_3v3_1v8_sig_trans_ena(PTC4); // 0 = disabled (all signals high impedence, 1 = translation active DigitalOut mdm_uart1_cts(PTD0); #define TOUPPER(a) (a) //toupper(a) const char ok_str[] = "OK"; const char error_str[] = "ERROR"; #define MDM_OK 0 #define MDM_ERR_TIMEOUT -1 #define MAX_AT_RSP_LEN 255 bool proximityChange = false; bool powerSave = false; //******************************************************************************************************************************************** //* Set the RGB LED's Color //* LED Color 0=Off to 7=White. 3 bits represent BGR (bit0=Red, bit1=Green, bit2=Blue) //******************************************************************************************************************************************** void SetLedColor(unsigned char ucColor) { if(powerSave) { led_red = !0; led_green = !0; led_blue = !0; } else { //Note that when an LED is on, you write a 0 to it: led_red = !(ucColor & 0x1); //bit 0 led_green = !(ucColor & 0x2); //bit 1 led_blue = !(ucColor & 0x4); //bit 2 } } //SetLedColor() ssize_t mdm_getline(char *buff, size_t size, int timeout_ms) { int cin = -1; int cin_last; if (NULL == buff || size == 0) { return -1; } size_t len = 0; Timer timer; timer.start(); while ((len < (size-1)) && (timer.read_ms() < timeout_ms)) { if (mdm.readable()) { cin_last = cin; cin = mdm.getc(); if (isprint(cin)) { buff[len++] = (char)cin; continue; } else if (('\r' == cin_last) && ('\n' == cin)) { break; } } wait_ms(1); } buff[len] = (char)NULL; return len; } int mdm_sendAtCmd(const char *cmd, const char **rsp_list, int timeout_ms) { if (cmd && strlen(cmd) > 0) { if (mdm_dbgmask & MDM_DBG_AT_CMDS) { printf(MAG "ATCMD: " DEF "--> " GRN "%s" DEF "\n", cmd); } mdm.printf("%s\r\n", cmd); } if (rsp_list) { Timer timer; char rsp[MAX_AT_RSP_LEN+1]; int len; timer.start(); while (timer.read_ms() < timeout_ms) { len = mdm_getline(rsp, sizeof(rsp), timeout_ms - timer.read_ms()); if (len < 0) return MDM_ERR_TIMEOUT; if (len == 0) continue; if (mdm_dbgmask & MDM_DBG_AT_CMDS) { printf(MAG "ATRSP: " DEF "<-- " CYN "%s" DEF "\n", rsp); } if (rsp_list) { int rsp_idx = 0; while (rsp_list[rsp_idx]) { if (strcasecmp(rsp, rsp_list[rsp_idx]) == 0) { return rsp_idx; } rsp_idx++; } } } return MDM_ERR_TIMEOUT; } return MDM_OK; } int mdm_init(void) { // disable signal level translator (necessary // for the modem to boot properly) shield_3v3_1v8_sig_trans_ena = 0; // Hard reset the modem (doesn't go through // the signal level translator) mdm_reset = 1; // wait a moment for the modem to react wait_ms(10); // Let modem boot mdm_reset = 0; // wait a moment for the modem to react wait(1.0); // power modem on //off mdm_power_on = 0; //1; // insure modem boots into normal operating mode // and does not go to sleep when powered on mdm_uart2_rx_boot_mode_sel = 1; mdm_wakeup_in = 1; // initialze comm with the modem mdm.baud(115200); // clear out potential garbage while (mdm.readable()) mdm.getc(); mdm_uart1_cts = 0; // wait a moment for the modem to react to signal // conditions while the level translator is disabled // (sorry, don't have enough information to know // what exactly the modem is doing with the current // pin settings) wait(1.0); // enable the signal level translator to start // modem reset process (modem will be powered down) shield_3v3_1v8_sig_trans_ena = 1; // Give the modem 60 secons to start responding by // sending simple 'AT' commands to modem once per second. Timer timer; timer.start(); while (timer.read() < 60) { SetLedColor(0x1); //red const char * rsp_lst[] = { ok_str, error_str, NULL }; int rc = mdm_sendAtCmd("AT", rsp_lst, 500); if (rc == 0) return true; //timer.read(); SetLedColor(0); //off wait_ms(1000 - (timer.read_ms() % 1000)); pc.printf("\r%d",timer.read_ms()/1000); } return false; } bool oldwakeModem() { Timer timer; timer.start(); while (timer.read() < 60) { const char * rsp_lst[] = { ok_str, error_str, NULL }; int rc = mdm_sendAtCmd("AT", rsp_lst, 500); if (rc == 0) return true; wait_ms(1000 - (timer.read_ms() % 1000)); pc.printf("\r%d",timer.read_ms()/1000); } return false; } /* bool wakeModem() { const char * rsp_lst[] = { ok_str, error_str, NULL }; int tries = 60; pc.printf("wake "); while (tries > 0) { tries--; pc.printf("."); int rc = mdm_sendAtCmd("AT", rsp_lst, 500); if (rc == 0) { pc.printf("\r\n"); return true; } wait(1.0); } return false; } bool rebootModem() { mdm.printf("ATZ\r\n"); return wakeModem(); } */ int oldmdm_init(void) { // Hard reset the modem (doesn't go through // the signal level translator) mdm_reset = 0; // disable signal level translator (necessary // for the modem to boot properly). All signals // except mdm_reset go through the level translator // and have internal pull-up/down in the module. While // the level translator is disabled, these pins will // be in the correct state. shield_3v3_1v8_sig_trans_ena = 0; // While the level translator is disabled and ouptut pins // are tristated, make sure the inputs are in the same state // as the WNC Module pins so that when the level translator is // enabled, there are no differences. mdm_uart2_rx_boot_mode_sel = 1; // UART2_RX should be high mdm_power_on = 0; // powr_on should be low mdm_wakeup_in = 1; // wake-up should be high mdm_uart1_cts = 0; // indicate that it is ok to send // Now, wait for the WNC Module to perform its initial boot correctly wait(1.0); // The WNC module initializes comms at 115200 8N1 so set it up mdm.baud(115200); //Now, enable the level translator, the input pins should now be the //same as how the M14A module is driving them with internal pull ups/downs. //When enabled, there will be no changes in these 4 pins... shield_3v3_1v8_sig_trans_ena = 1; // Now, give the modem 60 secons to start responding by // sending simple 'AT' commands to modem once per second. Timer timer; timer.start(); while (timer.read() < 60) { const char * rsp_lst[] = { ok_str, error_str, NULL }; int rc = mdm_sendAtCmd("AT", rsp_lst, 500); if (rc == 0) return true; //timer.read(); wait_ms(1000 - (timer.read_ms() % 1000)); pc.printf("\r%d",timer.read_ms()/1000); } return false; } int mdm_sendAtCmdRsp(const char *cmd, const char **rsp_list, int timeout_ms, string * rsp, int * len) { static char cmd_buf[3200]; // Need enough room for the WNC sockreads (over 3000 chars) size_t n = strlen(cmd); if (cmd && n > 0) { if (mdm_dbgmask & MDM_DBG_AT_CMDS) { printf(MAG "ATCMD: " DEF "--> " GRN "%s" DEF "\n", cmd); } while (n--) { mdm.putc(*cmd++); wait_ms(1); }; mdm.putc('\r'); wait_ms(1); mdm.putc('\n'); wait_ms(1); } if (rsp_list) { rsp->erase(); // Clean up from prior cmd response *len = 0; Timer timer; timer.start(); while (timer.read_ms() < timeout_ms) { int lenCmd = mdm_getline(cmd_buf, sizeof(cmd_buf), timeout_ms - timer.read_ms()); if (lenCmd == 0) continue; if (lenCmd < 0) return MDM_ERR_TIMEOUT; else { *len += lenCmd; *rsp += cmd_buf; } if (mdm_dbgmask & MDM_DBG_AT_CMDS) { printf(MAG "ATRSP: " DEF "<-- " CYN "%s" DEF "\n", cmd_buf); } int rsp_idx = 0; while (rsp_list[rsp_idx]) { if (strcasecmp(cmd_buf, rsp_list[rsp_idx]) == 0) { return rsp_idx; } rsp_idx++; } } return MDM_ERR_TIMEOUT; } pc.printf("D %s",rsp); return MDM_OK; } void system_reset() { printf(RED "\n\rSystem resetting..." DEF "\n"); NVIC_SystemReset(); } void reinitialize_mdm(void) { system_reset(); /* // Initialize the modem printf(GRN "Modem RE-initializing..." DEF "\r\n"); if (!mdm_init()) { system_reset(); } printf("\r\n"); */ } // These are built on the fly string MyServerIpAddress; string MySocketData; // These are to be built on the fly string my_temp; string my_humidity; #define CTOF(x) ((x)*1.8+32) //******************************************************************************************************************************************** //* Create string with sensor readings that can be sent to flow as an HTTP get //******************************************************************************************************************************************** K64F_Sensors_t SENSOR_DATA = { .Temperature = "0", .Humidity = "0", .AccelX = "0", .AccelY = "0", .AccelZ = "0", .MagnetometerX = "0", .MagnetometerY = "0", .MagnetometerZ = "0", .AmbientLightVis = "0", .AmbientLightIr = "0", .UVindex = "0", .Proximity = "0", .Temperature_Si7020 = "0", .Humidity_Si7020 = "0" }; void GenerateModemString(char * modem_string) { switch(iSensorsToReport) { case PROXIMITY_ONLY: { char* data = proximityStrip.getDataStr(); sprintf(modem_string, "GET %s%s?serial=%s&data=[%s] %s%s\r\n\r\n", FLOW_BASE_URL, FLOW_INPUT_NAME, FLOW_DEVICE_NAME, data, FLOW_URL_TYPE, MY_SERVER_URL); break; } case TEMP_HUMIDITY_ONLY: { sprintf(modem_string, "GET %s%s?serial=%s&temp=%s&humidity=%s %s%s\r\n\r\n", FLOW_BASE_URL, FLOW_INPUT_NAME, FLOW_DEVICE_NAME, SENSOR_DATA.Temperature, SENSOR_DATA.Humidity, FLOW_URL_TYPE, MY_SERVER_URL); break; } case TEMP_HUMIDITY_ACCELEROMETER: { sprintf(modem_string, "GET %s%s?serial=%s&temp=%s&humidity=%s&accelX=%s&accelY=%s&accelZ=%s %s%s\r\n\r\n", FLOW_BASE_URL, FLOW_INPUT_NAME, FLOW_DEVICE_NAME, SENSOR_DATA.Temperature, SENSOR_DATA.Humidity, SENSOR_DATA.AccelX,SENSOR_DATA.AccelY,SENSOR_DATA.AccelZ, FLOW_URL_TYPE, MY_SERVER_URL); break; } case TEMP_HUMIDITY_ACCELEROMETER_PMODSENSORS: { sprintf(modem_string, "GET %s%s?serial=%s&temp=%s&humidity=%s&accelX=%s&accelY=%s&accelZ=%s&proximity=%s&light_uv=%s&light_vis=%s&light_ir=%s %s%s\r\n\r\n", FLOW_BASE_URL, FLOW_INPUT_NAME, FLOW_DEVICE_NAME, SENSOR_DATA.Temperature, SENSOR_DATA.Humidity, SENSOR_DATA.AccelX,SENSOR_DATA.AccelY,SENSOR_DATA.AccelZ, SENSOR_DATA.Proximity, SENSOR_DATA.UVindex, SENSOR_DATA.AmbientLightVis, SENSOR_DATA.AmbientLightIr, FLOW_URL_TYPE, MY_SERVER_URL); break; } default: { sprintf(modem_string, "Invalid sensor selected\r\n\r\n"); break; } } //switch(iSensorsToReport) } //GenerateModemString //******************************************************************************************************************************************** //* Process JSON response messages //******************************************************************************************************************************************** bool extract_JSON(char* search_field, char* found_string) { char* beginquote; char* endquote; beginquote = strchr(search_field, '{'); //start of JSON endquote = strchr(search_field, '}'); //end of JSON if (beginquote != 0) { uint16_t ifoundlen; if (endquote != 0) { ifoundlen = (uint16_t) (endquote - beginquote) + 1; strncpy(found_string, beginquote, ifoundlen ); found_string[ifoundlen] = 0; //null terminate return true; } else { endquote = strchr(search_field, '\0'); //end of string... sometimes the end bracket is missing ifoundlen = (uint16_t) (endquote - beginquote) + 1; strncpy(found_string, beginquote, ifoundlen ); found_string[ifoundlen] = 0; //null terminate return false; } } else { return false; } } //extract_JSON void setPowerSave(bool on) { string * pRespStr; if(on) { powerSave = true; send_wnc_cmd("AT+CPSMS=1", &pRespStr, WNC_TIMEOUT_MS); } else { powerSave = false; send_wnc_cmd("AT+CPSMS=0", &pRespStr, WNC_TIMEOUT_MS); } } void parse_JSON_PSM(char* json_string) { char* beginquote; char token[] = "\"PSM\":\""; beginquote = strstr(json_string, token ); if ((beginquote != 0)) { char mode = beginquote[strlen(token)]; printf(GRN "PSM Found : %c" DEF "\r\n", mode); switch(mode) { case 'T': { setPowerSave(true); break; } case 'F': { setPowerSave(false); break; } } } } int secToTau(int time) { /* 0 - value is incremented in multiples of 10 minutes 1 - value is incremented in multiples of 1 hour 2 - value is incremented in multiples of 10 hours 3 - value is incremented in multiples of 2 seconds 4 - value is incremented in multiples of 30 seconds 5 - value is incremented in multiples of 1 minute */ if(time/2 < 32) { return (0x3<<5)+time/2; } else if(time/30 < 32) { return (0x4<<5)+time/30; } else if(time/60 < 32) { return (0x5<<5)+time/60; } else if(time/3600 < 32) { return (0x1<<5)+time/3600; } else if(time/36000 < 32) { return (0x2<<5)+time/36000; } else return (0x7<<5); } int secToActivity(int time) { /* 0 - value is incremented in multiples of 2 seconds 1 - value is incremented in multiples of 1 minute 2 - value is incremented in multiples of decihours 7 - value indicates that the timer is deactivated. */ if(time/2 < 32) { return (0x0<<5)+time/2; } else if(time/60 < 32) { return (0x1<<5)+time/60; } else if(time/36000 < 32) { return (0x2<<5)+time/36000; } else return (0x7<<5); } void setTauTimer(int time) { string * pRespStr; string cmd_str("AT%SETACFG=\"ecm.Mtc.PsmPTAU_T3412\",\""); char str[15]; sprintf(str, "%d", secToTau(time)); pc.printf("TAU %d = %d",time,secToTau(time)); cmd_str += str; cmd_str += "\""; send_wnc_cmd("AT%SETCFG=\"EXT_TAU_CAP_EN\",\"1\"", &pRespStr, WNC_TIMEOUT_MS); send_wnc_cmd("AT%SETACFG=\"ecm.Mtc.PsmCpsmsEn\",\"true\"", &pRespStr, WNC_TIMEOUT_MS); send_wnc_cmd(cmd_str.c_str(), &pRespStr, WNC_TIMEOUT_MS); } void setActivityTimer(int time) { string * pRespStr; string cmd_str("AT%SETACFG=\"ecm.Mtc.PsmActTime_T3324\",\""); char str[15]; sprintf(str, "%d", secToActivity(time)); pc.printf("Activity %d = %d",time,secToActivity(time)); cmd_str += str; cmd_str += "\""; send_wnc_cmd("AT%SETCFG=\"PSM_CAP_EN\",\"1\"", &pRespStr, WNC_TIMEOUT_MS); send_wnc_cmd("AT%SETACFG=\"ecm.Mtc.PsmCpsmsEn\",\"true\"", &pRespStr, WNC_TIMEOUT_MS); send_wnc_cmd(cmd_str.c_str(), &pRespStr, WNC_TIMEOUT_MS); } int main() { int i; int sendAttemps = 0; HTS221 hts221; pc.baud(115200); void hts221_init(void); // Set LED to RED until init finishes SetLedColor(0x1); pc.printf(BLU "Hello World from AT&T Shape!\r\n\n\r"); pc.printf(GRN "Initialize the HTS221\n\r"); i = hts221.begin(); if( i ) pc.printf(BLU "HTS221 Detected! (0x%02X)\n\r",i); else pc.printf(RED "HTS221 NOT DETECTED!!\n\r"); printf("Temp is: %0.2f F \n\r",CTOF(hts221.readTemperature())); printf("Humid is: %02d %%\n\r",hts221.readHumidity()); // Initialize the modem printf(GRN "Modem initializing... will take up to 60 seconds" DEF "\r\n"); do { i=mdm_init(); if (!i) { pc.printf(RED "Modem initialization failed!" DEF "\n"); } } while (!i); //Software init software_init_mdm(); // Resolve URL to IP address to connect to resolve_mdm(); sockopen_mdm(); // Set LED BLUE for partial init SetLedColor(0x4); setTauTimer(12*60*60); setActivityTimer(20); proximityStrip.init(); proximityStrip.on(); int count = 0; // Send and receive data perpetually while(1) { //sprintf(SENSOR_DATA.Temperature, "%0.2f", CTOF(hts221.readTemperature())); //sprintf(SENSOR_DATA.Humidity, "%02d", hts221.readHumidity()); // read_sensors(); //read available external sensors from a PMOD and the on-board motion sensor SetLedColor(0x2); //green proximityStrip.scan(); SetLedColor(0); //off if(count >= 5*60 ||proximityStrip.changed(50)) { count = 0; SetLedColor(0x04); //blue char modem_string[512]; GenerateModemString(&modem_string[0]); printf(BLU "Sending to modem : %s" DEF "\r\n", modem_string); wakeModem(); sockwrite_mdm(modem_string); sockread_mdm(&MySocketData, 1024, 20); // If any non-zero response from server, make it GREEN one-time // then the actual FLOW responses will set the color. if (MySocketData.length() > 0) { SetLedColor(0x2); // green //only copy on sucessful send printf(BLU "Read back : %s" DEF "\r\n", &MySocketData[0]); char myJsonResponse[512]; if (extract_JSON(&MySocketData[0], &myJsonResponse[0])) { printf(GRN "JSON : %s" DEF "\r\n", &myJsonResponse[0]); parse_JSON_PSM(&myJsonResponse[0]); } SetLedColor(0); // off } else { SetLedColor(0x1); //red // reset socket if read fails if(sendAttemps < 2) { sendAttemps++; sockclose_mdm(); sockopen_mdm(); } else // give up and do full reset { if(!rebootModem()) system_reset(); } } } count++; wait(0.2); } //forever loop }