#include "../new_common.h" #include "http_fns.h" #include "../new_pins.h" #include "../new_cfg.h" #include "../ota/ota.h" // Commands register, execution API and cmd tokenizer #include "../cmnds/cmd_public.h" #include "../driver/drv_tuyaMCU.h" #include "../driver/drv_public.h" #include "../hal/hal_wifi.h" #include "../hal/hal_pins.h" #include "../hal/hal_flashConfig.h" #include "../logging/logging.h" #include "../devicegroups/deviceGroups_public.h" #include "../mqtt/new_mqtt.h" #include "hass.h" #include "../cJSON/cJSON.h" #include #include "../driver/drv_ntp.h" #include "../driver/drv_local.h" static char SUBMIT_AND_END_FORM[] = "
"; #ifdef WINDOWS // nothing #elif PLATFORM_BL602 #elif PLATFORM_W600 || PLATFORM_W800 #elif PLATFORM_XR809 #include #elif defined(PLATFORM_BK7231N) // tuya-iotos-embeded-sdk-wifi-ble-bk7231n/sdk/include/tuya_hal_storage.h #include "tuya_hal_storage.h" #include "BkDriverFlash.h" #else // REALLY? A typo in Tuya SDK? Storge? // tuya-iotos-embeded-sdk-wifi-ble-bk7231t/platforms/bk7231t/tuya_os_adapter/include/driver/tuya_hal_storge.h #include "tuya_hal_storge.h" #include "BkDriverFlash.h" #endif #if defined(PLATFORM_BK7231T) || defined(PLATFORM_BK7231N) int tuya_os_adapt_wifi_all_ap_scan(AP_IF_S** ap_ary, unsigned int* num); int tuya_os_adapt_wifi_release_ap(AP_IF_S* ap); #endif unsigned char hexdigit(char hex) { return (hex <= '9') ? hex - '0' : toupper((unsigned char)hex) - 'A' + 10; } unsigned char hexbyte(const char* hex) { return (hexdigit(*hex) << 4) | hexdigit(*(hex + 1)); } int http_fn_empty_url(http_request_t* request) { poststr(request, "HTTP/1.1 302 OK\nLocation: /index\nConnection: close\n\n"); poststr(request, NULL); return 0; } void postFormAction(http_request_t* request, char* action, char* value) { //"
" hprintf255(request, "
", action, value); } void poststr_h2(http_request_t* request, const char* content) { hprintf255(request, "

%s

", content); } void poststr_h4(http_request_t* request, const char* content) { hprintf255(request, "

%s

", content); } /// @brief Generate a pair of label and field elements for Name type entry. The field is limited to entry of a-zA-Z0-9_- characters. /// @param request /// @param label /// @param fieldId This also gets used as the field name /// @param value /// @param preContent void add_label_name_field(http_request_t* request, char* label, char* fieldId, const char* value, char* preContent) { if (strlen(preContent) > 0) { poststr(request, preContent); } hprintf255(request, "
", fieldId, label); hprintf255(request, ""); } /// @brief Generate a pair of label and field elements. /// @param request /// @param label /// @param fieldId This also gets used as the field name /// @param value /// @param preContent void add_label_input(http_request_t* request, char* inputType, char* label, char* fieldId, const char* value, char* preContent) { if (strlen(preContent) > 0) { poststr(request, preContent); } hprintf255(request, "
", fieldId, label); hprintf255(request, ""); } /// @brief Generates a pair of label and text field elements. /// @param request /// @param label Label for the field /// @param fieldId Field id, this also gets used as the name /// @param value String value /// @param preContent Content before the label void add_label_text_field(http_request_t* request, char* label, char* fieldId, const char* value, char* preContent) { add_label_input(request, "text", label, fieldId, value, preContent); } /// @brief Generates a pair of label and text field elements. /// @param request /// @param label Label for the field /// @param fieldId Field id, this also gets used as the name /// @param value String value /// @param preContent Content before the label void add_label_password_field(http_request_t* request, char* label, char* fieldId, const char* value, char* preContent) { add_label_input(request, "password", label, fieldId, value, preContent); } /// @brief Generate a pair of label and numeric field elements. /// @param request /// @param label Label for the field /// @param fieldId Field id, this also gets used as the name /// @param value Integer value /// @param preContent Content before the label void add_label_numeric_field(http_request_t* request, char* label, char* fieldId, int value, char* preContent) { char strValue[32]; sprintf(strValue, "%i", value); add_label_input(request, "number", label, fieldId, strValue, preContent); } int http_fn_testmsg(http_request_t* request) { poststr(request, "This is just a test msg\n\n"); poststr(request, NULL); return 0; } // bit mask telling which channels are hidden from HTTP // If given bit is set, then given channel is hidden extern int g_hiddenChannels; int http_fn_index(http_request_t* request) { int j, i, ch1, ch2; char tmpA[128]; int bRawPWMs; bool bForceShowRGBCW; float fValue; int iValue; bool bForceShowRGB; const char* inputName; int channelType; bRawPWMs = CFG_HasFlag(OBK_FLAG_LED_RAWCHANNELSMODE); bForceShowRGBCW = CFG_HasFlag(OBK_FLAG_LED_FORCESHOWRGBCWCONTROLLER); bForceShowRGB = CFG_HasFlag(OBK_FLAG_LED_FORCE_MODE_RGB); if (LED_IsLedDriverChipRunning()) { bForceShowRGBCW = true; } http_setup(request, httpMimeTypeHTML); //Add mimetype regardless of the request // use ?state URL parameter to only request current state if (!http_getArg(request->url, "state", tmpA, sizeof(tmpA))) { http_html_start(request, NULL); poststr(request, "
"); #if defined(PLATFORM_BEKEN) || defined(WINDOWS) if (DRV_IsRunning("PWMToggler")) { DRV_Toggler_ProcessChanges(request); } #endif #if defined(PLATFORM_BEKEN) || defined(WINDOWS) if (DRV_IsRunning("httpButtons")) { DRV_HTTPButtons_ProcessChanges(request); } #endif if (http_getArg(request->url, "tgl", tmpA, sizeof(tmpA))) { j = atoi(tmpA); if (j == SPECIAL_CHANNEL_LEDPOWER) { hprintf255(request, "

Toggled LED power!

", j); } else { hprintf255(request, "

Toggled %s!

", CHANNEL_GetLabel(j)); } CHANNEL_Toggle(j); } if (http_getArg(request->url, "on", tmpA, sizeof(tmpA))) { j = atoi(tmpA); hprintf255(request, "

Enabled %s!

", CHANNEL_GetLabel(j)); CHANNEL_Set(j, 255, 1); } if (http_getArg(request->url, "rgb", tmpA, sizeof(tmpA))) { hprintf255(request, "

Set RGB to %s!

", tmpA); LED_SetBaseColor(0, "led_basecolor", tmpA, 0); // auto enable - but only for changes made from WWW panel // This happens when users changes COLOR if (CFG_HasFlag(OBK_FLAG_LED_AUTOENABLE_ON_WWW_ACTION)) { LED_SetEnableAll(true); } } if (http_getArg(request->url, "off", tmpA, sizeof(tmpA))) { j = atoi(tmpA); hprintf255(request, "

Disabled %s!

", CHANNEL_GetLabel(j)); CHANNEL_Set(j, 0, 1); } if (http_getArg(request->url, "pwm", tmpA, sizeof(tmpA))) { int newPWMValue = atoi(tmpA); http_getArg(request->url, "pwmIndex", tmpA, sizeof(tmpA)); j = atoi(tmpA); if (j == SPECIAL_CHANNEL_TEMPERATURE) { hprintf255(request, "

Changed Temperature to %i!

", newPWMValue); } else { hprintf255(request, "

Changed pwm %i to %i!

", j, newPWMValue); } CHANNEL_Set(j, newPWMValue, 1); if (j == SPECIAL_CHANNEL_TEMPERATURE) { // auto enable - but only for changes made from WWW panel // This happens when users changes TEMPERATURE if (CFG_HasFlag(OBK_FLAG_LED_AUTOENABLE_ON_WWW_ACTION)) { LED_SetEnableAll(true); } } } if (http_getArg(request->url, "dim", tmpA, sizeof(tmpA))) { int newDimmerValue = atoi(tmpA); http_getArg(request->url, "dimIndex", tmpA, sizeof(tmpA)); j = atoi(tmpA); if (j == SPECIAL_CHANNEL_BRIGHTNESS) { hprintf255(request, "

Changed LED brightness to %i!

", newDimmerValue); } else { hprintf255(request, "

Changed dimmer %i to %i!

", j, newDimmerValue); } CHANNEL_Set(j, newDimmerValue, 1); if (j == SPECIAL_CHANNEL_BRIGHTNESS) { // auto enable - but only for changes made from WWW panel // This happens when users changes DIMMER if (CFG_HasFlag(OBK_FLAG_LED_AUTOENABLE_ON_WWW_ACTION)) { LED_SetEnableAll(true); } } } if (http_getArg(request->url, "set", tmpA, sizeof(tmpA))) { int newSetValue = atoi(tmpA); http_getArg(request->url, "setIndex", tmpA, sizeof(tmpA)); j = atoi(tmpA); hprintf255(request, "

Changed channel %s to %i!

", CHANNEL_GetLabel(j), newSetValue); CHANNEL_Set(j, newSetValue, 1); } if (http_getArg(request->url, "restart", tmpA, sizeof(tmpA))) { poststr(request, "
Module will restart soon
"); RESET_ScheduleModuleReset(3); } if (http_getArg(request->url, "unsafe", tmpA, sizeof(tmpA))) { poststr(request, "
Will try to do unsafe init in few seconds
"); MAIN_ScheduleUnsafeInit(3); } poststr(request, "
"); // end div#change poststr(request, "
"); // replaceable content follows } poststr(request, ""); //Table default to 100% width in stylesheet for (i = 0; i < CHANNEL_MAX; i++) { channelType = CHANNEL_GetType(i); // check ability to hide given channel from gui if (BIT_CHECK(g_hiddenChannels, i)) { continue; // hidden } bool bToggleInv = channelType == ChType_Toggle_Inv; if (h_isChannelRelay(i) || channelType == ChType_Toggle) { if (i <= 1) { hprintf255(request, ""); } if (CHANNEL_Check(i) != bToggleInv) { poststr(request, ""); } else { poststr(request, ""); } if (i == CHANNEL_MAX - 1) { poststr(request, ""); } } } poststr(request, "
ONOFF
"); poststr(request, ""); //Table default to 100% width in stylesheet for (i = 0; i < CHANNEL_MAX; i++) { // check ability to hide given channel from gui if (BIT_CHECK(g_hiddenChannels, i)) { continue; // hidden } channelType = CHANNEL_GetType(i); bool bToggleInv = channelType == ChType_Toggle_Inv; if (h_isChannelRelay(i) || channelType == ChType_Toggle || bToggleInv) { const char* c; const char* prefix; if (i <= 1) { hprintf255(request, ""); } if (CHANNEL_Check(i) != bToggleInv) { c = "bgrn"; } else { c = "bred"; } poststr(request, "", c, prefix, CHANNEL_GetLabel(i)); if (i == CHANNEL_MAX - 1) { poststr(request, ""); } } } poststr(request, "
"); hprintf255(request, "", i); if (CHANNEL_ShouldAddTogglePrefixToUI(i)) { prefix = "Toggle "; } else { prefix = ""; } hprintf255(request, "
"); poststr(request, ""); //Table default to 100% width in stylesheet for (i = 0; i < PLATFORM_GPIO_MAX; i++) { int role; role = PIN_GetPinRoleForPinIndex(i); if (IS_PIN_DHT_ROLE(role)) { // DHT pin has two channels - temperature and humidity poststr(request, ""); } } for (i = 0; i < CHANNEL_MAX; i++) { // check ability to hide given channel from gui if (BIT_CHECK(g_hiddenChannels, i)) { continue; // hidden } channelType = CHANNEL_GetType(i); if (channelType == ChType_Temperature) { iValue = CHANNEL_Get(i); poststr(request, ""); } else if (channelType == ChType_TimerSeconds) { iValue = CHANNEL_Get(i); poststr(request, ""); } else if (channelType == ChType_Temperature_div2) { iValue = CHANNEL_Get(i); fValue = iValue * 0.5f; poststr(request, ""); } else if (channelType == ChType_Temperature_div10) { iValue = CHANNEL_Get(i); fValue = iValue * 0.1f; poststr(request, ""); } else if (channelType == ChType_Pressure_div100) { iValue = CHANNEL_Get(i); fValue = iValue * 0.01f; poststr(request, ""); } else if (channelType == ChType_Temperature_div100) { iValue = CHANNEL_Get(i); fValue = iValue * 0.01f; poststr(request, ""); } else if (channelType == ChType_Humidity) { iValue = CHANNEL_Get(i); poststr(request, ""); } else if (channelType == ChType_Humidity_div10) { iValue = CHANNEL_Get(i); fValue = iValue * 0.1f; poststr(request, ""); } else if (channelType == ChType_LowMidHigh) { const char* types[] = { "Low","Mid","High" }; iValue = CHANNEL_Get(i); poststr(request, ""); } else if (channelType == ChType_OffLowMidHigh || channelType == ChType_OffLowestLowMidHighHighest || channelType == ChType_LowestLowMidHighHighest || channelType == ChType_LowMidHighHighest || channelType == ChType_OffLowMidHighHighest || channelType == ChType_OffOnRemember) { const char** types; const char* types4[] = { "Off","Low","Mid","High" }; const char* typesLowMidHighHighest[] = { "Low","Mid","High","Highest" }; const char* typesOffLowMidHighHighest[] = { "Off", "Low","Mid","High","Highest" }; const char* types6[] = { "Off", "Lowest", "Low", "Mid", "High", "Highest" }; const char* types5NoOff[] = { "Lowest", "Low", "Mid", "High", "Highest" }; const char* typesOffOnRemember[] = { "Off", "On", "Remember" }; int numTypes; const char *what; if (channelType == ChType_OffOnRemember) { what = "memory"; } else { what = "speed"; } if (channelType == ChType_OffLowMidHigh) { types = types4; numTypes = 4; } else if (channelType == ChType_LowMidHighHighest) { types = typesLowMidHighHighest; numTypes = 4; } else if (channelType == ChType_OffLowMidHighHighest) { types = typesOffLowMidHighHighest; numTypes = 5; } else if (channelType == ChType_LowestLowMidHighHighest) { types = types5NoOff; numTypes = 5; } else if (channelType == ChType_OffOnRemember) { types = typesOffOnRemember; numTypes = 3; } else { types = types6; numTypes = 6; } iValue = CHANNEL_Get(i); poststr(request, ""); } else if (channelType == ChType_TextField) { iValue = CHANNEL_Get(i); poststr(request, ""); } else if (channelType == ChType_Illuminance) { iValue = CHANNEL_Get(i); poststr(request, ""); } else if (channelType == ChType_ReadOnly) { iValue = CHANNEL_Get(i); poststr(request, ""); } else if (channelType == ChType_Frequency_div100) { iValue = CHANNEL_Get(i); fValue = iValue * 0.01f; poststr(request, ""); } else if (channelType == ChType_Frequency_div10) { iValue = CHANNEL_Get(i); fValue = iValue * 0.1f; poststr(request, ""); } else if (channelType == ChType_EnergyToday_kWh_div1000) { iValue = CHANNEL_Get(i); fValue = iValue * 0.001f; poststr(request, ""); } else if (channelType == ChType_EnergyExport_kWh_div1000) { iValue = CHANNEL_Get(i); fValue = iValue * 0.001f; poststr(request, ""); } else if (channelType == ChType_EnergyTotal_kWh_div1000) { iValue = CHANNEL_Get(i); fValue = iValue * 0.001f; poststr(request, ""); } else if (channelType == ChType_EnergyTotal_kWh_div100) { iValue = CHANNEL_Get(i); fValue = iValue * 0.01f; poststr(request, ""); } else if (channelType == ChType_Voltage_div10) { iValue = CHANNEL_Get(i); fValue = iValue * 0.1f; poststr(request, ""); } else if (channelType == ChType_Voltage_div100) { iValue = CHANNEL_Get(i); fValue = iValue * 0.01f; poststr(request, ""); } else if (channelType == ChType_ReactivePower) { iValue = CHANNEL_Get(i); poststr(request, ""); } else if (channelType == ChType_Power_div10) { iValue = CHANNEL_Get(i); poststr(request, ""); } else if (channelType == ChType_Power) { iValue = CHANNEL_Get(i); poststr(request, ""); } else if (channelType == ChType_PowerFactor_div1000) { iValue = CHANNEL_Get(i); fValue = iValue * 0.001f; poststr(request, ""); } else if (channelType == ChType_PowerFactor_div100) { iValue = CHANNEL_Get(i); fValue = iValue * 0.01f; poststr(request, ""); } else if (channelType == ChType_Current_div100) { iValue = CHANNEL_Get(i); fValue = iValue * 0.01f; poststr(request, ""); } else if (channelType == ChType_Current_div1000) { iValue = CHANNEL_Get(i); fValue = iValue * 0.001f; poststr(request, ""); } else if (channelType == ChType_BatteryLevelPercent) { iValue = CHANNEL_Get(i); poststr(request, ""); } else if (channelType == ChType_OpenClosed) { iValue = CHANNEL_Get(i); poststr(request, ""); } else if (channelType == ChType_OpenClosed_Inv) { iValue = CHANNEL_Get(i); poststr(request, ""); } else if (h_isChannelRelay(i) || channelType == ChType_Toggle || channelType == ChType_Toggle_Inv) { // HANDLED ABOVE in previous loop } else if ((bRawPWMs && h_isChannelPWM(i)) || (channelType == ChType_Dimmer) || (channelType == ChType_Dimmer256) || (channelType == ChType_Dimmer1000)) { int maxValue; // PWM and dimmer both use a slider control inputName = h_isChannelPWM(i) ? "pwm" : "dim"; int pwmValue; if (channelType == ChType_Dimmer256) { maxValue = 255; } else if (channelType == ChType_Dimmer1000) { maxValue = 1000; } else { maxValue = 100; } pwmValue = CHANNEL_Get(i); poststr(request, ""); } else if (channelType == ChType_OffDimBright) { const char* types[] = { "Off","Dim","Bright" }; iValue = CHANNEL_Get(i); poststr(request, ""); } } if (bRawPWMs == 0 || bForceShowRGBCW || bForceShowRGB) { int c_pwms; int lm; lm = LED_GetMode(); //c_pwms = PIN_CountPinsWithRoleOrRole(IOR_PWM, IOR_PWM_n); // This will treat multiple PWMs on a single channel as one. // Thanks to this users can turn for example RGB LED controller // into high power 3-outputs single colors LED controller PIN_get_Relay_PWM_Count(0, &c_pwms, 0); if (bForceShowRGBCW) { c_pwms = 5; } else if (bForceShowRGB) { c_pwms = 3; } if (c_pwms > 0) { const char* c; if (CHANNEL_Check(SPECIAL_CHANNEL_LEDPOWER)) { c = "bgrn"; } else { c = "bred"; } poststr(request, ""); } if (c_pwms > 0) { int pwmValue; inputName = "dim"; pwmValue = LED_GetDimmer(); poststr(request, ""); } if (c_pwms >= 3) { char colorValue[16]; inputName = "rgb"; const char* activeStr = ""; if (lm == Light_RGB) { activeStr = "[ACTIVE]"; } LED_GetBaseColorString(colorValue); poststr(request, ""); } if (c_pwms == 2 || c_pwms >= 4) { // TODO: temperature slider int pwmValue; const char* activeStr = ""; if (lm == Light_Temperature) { activeStr = "[ACTIVE]"; } inputName = "pwm"; pwmValue = LED_GetTemperature(); long pwmKelvin = HASS_TO_KELVIN(pwmValue); long pwmKelvinMax = HASS_TO_KELVIN(led_temperature_min); long pwmKelvinMin = HASS_TO_KELVIN(led_temperature_max); poststr(request, ""); } } #if defined(PLATFORM_BEKEN) || defined(WINDOWS) if (DRV_IsRunning("PWMToggler")) { DRV_Toggler_AddToHtmlPage(request); } #endif #if defined(PLATFORM_BEKEN) || defined(WINDOWS) if (DRV_IsRunning("httpButtons")) { DRV_HTTPButtons_AddToHtmlPage(request); } #endif poststr(request, "
"); ch1 = PIN_GetPinChannelForPinIndex(i); ch2 = PIN_GetPinChannel2ForPinIndex(i); iValue = CHANNEL_Get(ch1); hprintf255(request, "Sensor %s on pin %i temperature %.2fC", PIN_RoleToString(role), i, (float)(iValue * 0.1f)); iValue = CHANNEL_Get(ch2); hprintf255(request, ", humidity %.1f%%
", (float)iValue); if (ch1 == ch2) { hprintf255(request, "WARNING: you have the same channel set twice for DHT, please fix in pins config, set two different channels"); } poststr(request, "
"); hprintf255(request, "Temperature Channel %s value %i C
", CHANNEL_GetLabel(i), iValue); poststr(request, "
"); hprintf255(request, "Timer Channel %s value ", CHANNEL_GetLabel(i)); if (iValue < 60) { hprintf255(request, "%i seconds
", iValue); } else if (iValue < 3600) { int minutes = iValue / 60; int seconds = iValue % 60; hprintf255(request, "%i minutes %i seconds
", minutes, seconds); } else { int hours = iValue / 3600; int remainingSeconds = iValue % 3600; int minutes = remainingSeconds / 60; int seconds = remainingSeconds % 60; hprintf255(request, "%i hours %i minutes %i seconds
", hours, minutes, seconds); } poststr(request, "
"); hprintf255(request, "Temperature Channel %s value %.2f C
", CHANNEL_GetLabel(i), fValue); poststr(request, "
"); hprintf255(request, "Temperature Channel %s value %.2f C
", CHANNEL_GetLabel(i), fValue); poststr(request, "
"); hprintf255(request, "Pressure Channel %s value %.2f hPa
", CHANNEL_GetLabel(i), fValue); poststr(request, "
"); hprintf255(request, "Temperature Channel %s value %.2f C
", CHANNEL_GetLabel(i), fValue); poststr(request, "
"); hprintf255(request, "Humidity Channel %s value %i Percent
", CHANNEL_GetLabel(i), iValue); poststr(request, "
"); hprintf255(request, "Humidity Channel %s value %.2f Percent
", CHANNEL_GetLabel(i), fValue); poststr(request, "
"); hprintf255(request, "

Select speed:

"); hprintf255(request, "", i); for (j = 0; j < 3; j++) { const char* check; if (j == iValue) check = "checked"; else check = ""; hprintf255(request, "%s", j, check, types[j]); } hprintf255(request, "
"); poststr(request, "
"); hprintf255(request, "

Select %s:

", what); hprintf255(request, "", i); for (j = 0; j < numTypes; j++) { const char* check; if (j == iValue) check = "checked"; else check = ""; hprintf255(request, "%s", j, check, types[j]); } hprintf255(request, "
"); poststr(request, "
"); hprintf255(request, "

Change channel %s value:

", CHANNEL_GetLabel(i)); hprintf255(request, "", i); hprintf255(request, "", iValue); hprintf255(request, "
"); hprintf255(request, ""); poststr(request, "
"); hprintf255(request, "Illuminance (%s) = %i Lux", CHANNEL_GetLabel(i), iValue); poststr(request, "
"); hprintf255(request, "Channel %s = %i", CHANNEL_GetLabel(i), iValue); poststr(request, "
"); hprintf255(request, "Frequency %.2fHz (ch %s)", fValue, CHANNEL_GetLabel(i)); poststr(request, "
"); hprintf255(request, "Frequency %.2fHz (ch %s)", fValue, CHANNEL_GetLabel(i)); poststr(request, "
"); hprintf255(request, "EnergyToday %.2fkWh (ch %s)", fValue, CHANNEL_GetLabel(i)); poststr(request, "
"); hprintf255(request, "EnergyExport(back to grid) %.2fkWh (ch %s)", fValue, CHANNEL_GetLabel(i)); poststr(request, "
"); hprintf255(request, "EnergyTotal %.2fkWh (ch %s)", fValue, CHANNEL_GetLabel(i)); poststr(request, "
"); hprintf255(request, "EnergyTotal %.2fkWh (ch %s)", fValue, CHANNEL_GetLabel(i)); poststr(request, "
"); hprintf255(request, "Voltage %.2fV (ch %s)", fValue, CHANNEL_GetLabel(i)); poststr(request, "
"); hprintf255(request, "Voltage %.3fV (ch %s)", fValue, CHANNEL_GetLabel(i)); poststr(request, "
"); hprintf255(request, "ReactivePower %iVAr (ch %s)", iValue, CHANNEL_GetLabel(i)); poststr(request, "
"); hprintf255(request, "Power %.2fW (ch %s)", (iValue * 0.1f), CHANNEL_GetLabel(i)); poststr(request, "
"); hprintf255(request, "Power %iW (ch %s)", iValue, CHANNEL_GetLabel(i)); poststr(request, "
"); hprintf255(request, "PowerFactor %.4f (ch %i)", fValue, i); poststr(request, "
"); hprintf255(request, "PowerFactor %.4f (ch %i)", fValue, i); poststr(request, "
"); hprintf255(request, "Current %.3fA (ch %s)", fValue, CHANNEL_GetLabel(i)); poststr(request, "
"); hprintf255(request, "Current %.4fA (ch %s)", fValue, CHANNEL_GetLabel(i)); poststr(request, "
"); hprintf255(request, "Battery level: %i", iValue); poststr(request, "%"); hprintf255(request, " (ch %i)", i); poststr(request, "
"); if (iValue) { hprintf255(request, "CLOSED (ch %i)", i); } else { hprintf255(request, "OPEN (ch %i)", i); } poststr(request, "
"); if (!iValue) { hprintf255(request, "CLOSED (ch %i)", i); } else { hprintf255(request, "OPEN (ch %i)", i); } poststr(request, "
"); hprintf255(request, "
", i); hprintf255(request, "", maxValue, inputName, i, pwmValue); hprintf255(request, "", inputName, i); hprintf255(request, "
", CHANNEL_GetLabel(i)); poststr(request, "
"); hprintf255(request, "

Select level:

"); hprintf255(request, "", i); for (j = 0; j < 3; j++) { const char* check; if (j == iValue) check = "checked"; else check = ""; hprintf255(request, "%s", j, check, types[j]); } hprintf255(request, "
"); poststr(request, "
"); poststr(request, "
"); hprintf255(request, "", SPECIAL_CHANNEL_LEDPOWER); hprintf255(request, "
", c); poststr(request, "
"); hprintf255(request, "
LED Dimmer/Brightness
"); hprintf255(request, "
", SPECIAL_CHANNEL_BRIGHTNESS); hprintf255(request, "", inputName, SPECIAL_CHANNEL_BRIGHTNESS, pwmValue); hprintf255(request, "", inputName, SPECIAL_CHANNEL_BRIGHTNESS); hprintf255(request, "
", SPECIAL_CHANNEL_BRIGHTNESS); poststr(request, "
"); hprintf255(request, "
LED RGB Color %s
", activeStr); hprintf255(request, "
", SPECIAL_CHANNEL_BASECOLOR); // onchange would fire only if colour was changed // onblur will fire every time hprintf255(request, "", inputName, SPECIAL_CHANNEL_BASECOLOR, colorValue); hprintf255(request, "", inputName, SPECIAL_CHANNEL_BASECOLOR); hprintf255(request, "
"); poststr(request, "
"); hprintf255(request, "
LED Temperature Slider %s (%ld K) (Warm <--- ---> Cool)
", activeStr, pwmKelvin); hprintf255(request, "
", SPECIAL_CHANNEL_TEMPERATURE); //(KELVIN_TEMPERATURE_MAX - KELVIN_TEMPERATURE_MIN) / (HASS_TEMPERATURE_MAX - HASS_TEMPERATURE_MIN) = 13 hprintf255(request, "", pwmKelvin); hprintf255(request, "", inputName, SPECIAL_CHANNEL_TEMPERATURE); hprintf255(request, "", SPECIAL_CHANNEL_TEMPERATURE, inputName); poststr(request, "
"); #ifndef OBK_DISABLE_ALL_DRIVERS DRV_AppendInformationToHTTPIndexPage(request); #endif if (1) { int bFirst = true; hprintf255(request, "
"); for (i = 0; i < CHANNEL_MAX; i++) { if (CHANNEL_IsInUse(i)) { float value = CHANNEL_GetFloat(i); if (bFirst == false) { hprintf255(request, ", "); } hprintf255(request, "Channel %i = %.2f", i, value); bFirst = false; } } if (1) { i = RepeatingEvents_GetActiveCount(); if (i) { if (bFirst == false) { hprintf255(request, ", "); } hprintf255(request, "%i repeating events", i); bFirst = false; } i = EventHandlers_GetActiveCount(); if (i) { if (bFirst == false) { hprintf255(request, ", "); } hprintf255(request, "%i event handlers", i); bFirst = false; } #if defined(WINDOWS) || defined(PLATFORM_BEKEN) i = CMD_GetCountActiveScriptThreads(); if (i) { if (bFirst == false) { hprintf255(request, ", "); } hprintf255(request, "%i script threads", i); bFirst = false; } #endif } hprintf255(request, "
"); } hprintf255(request, "
Cfg size: %i, change counter: %i, ota counter: %i, boot incompletes %i (might change to 0 if you wait to 30 sec)!
", sizeof(g_cfg), g_cfg.changeCounter, g_cfg.otaCounter, g_bootFailures); inputName = CFG_GetPingHost(); if (inputName && *inputName && CFG_GetPingDisconnectedSecondsToRestart()) { hprintf255(request, "
Ping watchdog (%s) - ", inputName); if (g_startPingWatchDogAfter > 0) { hprintf255(request, "will start in %i!
", g_startPingWatchDogAfter); } else { hprintf255(request, "%i lost, %i ok, last reply was %is ago!", PingWatchDog_GetTotalLost(), PingWatchDog_GetTotalReceived(), g_timeSinceLastPingReply); } } if (Main_HasWiFiConnected()) { hprintf255(request, "
Wifi RSSI: %s (%idBm)
", str_rssi[wifi_rssi_scale(HAL_GetWifiStrength())], HAL_GetWifiStrength()); } #if PLATFORM_BEKEN /* typedef enum { RESET_SOURCE_POWERON = 0, RESET_SOURCE_REBOOT = 1, RESET_SOURCE_WATCHDOG = 2, RESET_SOURCE_DEEPPS_GPIO = 3, RESET_SOURCE_DEEPPS_RTC = 4, RESET_SOURCE_CRASH_XAT0 = 5, RESET_SOURCE_CRASH_UNDEFINED = 6, RESET_SOURCE_CRASH_PREFETCH_ABORT = 7, RESET_SOURCE_CRASH_DATA_ABORT = 8, RESET_SOURCE_CRASH_UNUSED = 9, } RESET_SOURCE_STATUS; */ int bk_misc_get_start_type(); { const char* s = "Unk"; i = bk_misc_get_start_type(); if (i == 0) s = "Pwr"; else if (i == 1) s = "Rbt"; else if (i == 2) s = "Wdt"; hprintf255(request, "
Reboot reason: %i - %s
", i, s); } #endif if (CFG_GetMQTTHost()[0] == 0) { hprintf255(request, "
MQTT State: not configured
"); } else { const char* stateStr; const char* colorStr; if (mqtt_reconnect > 0) { stateStr = "awaiting reconnect"; colorStr = "orange"; } else if (Main_HasMQTTConnected() == 1) { stateStr = "connected"; colorStr = "green"; } else { stateStr = "disconnected"; colorStr = "yellow"; } hprintf255(request, "
MQTT State: %s RES: %d(%s)
", colorStr, stateStr, MQTT_GetConnectResult(), get_error_name(MQTT_GetConnectResult())); hprintf255(request, "MQTT ErrMsg: %s
", (MQTT_GetStatusMessage() != NULL) ? MQTT_GetStatusMessage() : ""); hprintf255(request, "MQTT Stats:CONN: %d PUB: %d RECV: %d ERR: %d
", MQTT_GetConnectEvents(), MQTT_GetPublishEventCounter(), MQTT_GetReceivedEventCounter(), MQTT_GetPublishErrorCounter()); } /* Format current PINS input state for all unused pins */ if (CFG_HasFlag(OBK_FLAG_HTTP_PINMONITOR)) { for (i = 0; i < 29; i++) { if ((PIN_GetPinRoleForPinIndex(i) == IOR_None) && (i != 0) && (i != 1)) { HAL_PIN_Setup_Input(i); } } hprintf255(request, "
PIN States
"); for (i = 0; i < 29; i++) { if ((PIN_GetPinRoleForPinIndex(i) != IOR_None) || (i == 0) || (i == 1)) { hprintf255(request, "P%02i: NA ", i); } else { hprintf255(request, "P%02i: %i ", i, (int)HAL_PIN_ReadDigitalInput(i)); } if (i % 10 == 9) { hprintf255(request, "
"); } } hprintf255(request, "
"); } #if WINDOWS #elif PLATFORM_BL602 #elif PLATFORM_W600 || PLATFORM_W800 #elif PLATFORM_XR809 #elif PLATFORM_BK7231N || PLATFORM_BK7231T if (ota_progress() >= 0) { hprintf255(request, "
OTA In Progress. Downloaded: %i B Flashed: %06lXh
", OTA_GetTotalBytes(), ota_progress()); } #endif if (bSafeMode) { hprintf255(request, "
You are in safe mode (AP mode) because full reboot failed %i times. ", g_bootFailures); hprintf255(request, "Pins, relays, etc are disabled.
"); } // for normal page loads, show the rest of the HTML if (!http_getArg(request->url, "state", tmpA, sizeof(tmpA))) { poststr(request, "
"); // end div#state // Shared UI elements poststr(request, "
"); poststr(request, "
" "" "" "
"); if (bSafeMode) { poststr(request, "
" "" "" "
"); } poststr(request, "
"); poststr(request, "
"); poststr(request, htmlFooterRefreshLink); http_html_end(request); } poststr(request, NULL); return 0; } int http_fn_about(http_request_t* request) { http_setup(request, httpMimeTypeHTML); http_html_start(request, "About"); poststr_h2(request, "Open source firmware for BK7231N, BK7231T, XR809 and BL602 by OpenSHWProjects"); poststr(request, htmlFooterReturnToMenu); http_html_end(request); poststr(request, NULL); return 0; } int http_fn_cfg_mqtt(http_request_t* request) { http_setup(request, httpMimeTypeHTML); http_html_start(request, "MQTT"); poststr_h2(request, "Use this to connect to your MQTT"); poststr_h4(request, "To disable MQTT, clear the host field."); hprintf255(request, "

Command topic: cmnd/%s/[Command]

", CFG_GetMQTTClientId()); hprintf255(request, "

Publish data topic: %s/[Channel]/get

", CFG_GetMQTTClientId()); hprintf255(request, "

Receive data topic: %s/[Channel]/set

", CFG_GetMQTTClientId()); add_label_text_field(request, "Host", "host", CFG_GetMQTTHost(), "
"); add_label_numeric_field(request, "Port", "port", CFG_GetMQTTPort(), "
"); add_label_text_field(request, "Client Topic (Base Topic)", "client", CFG_GetMQTTClientId(), "

"); add_label_text_field(request, "Group Topic (Secondary Topic to only receive cmnds)", "group", CFG_GetMQTTGroupTopic(), "
"); add_label_text_field(request, "User", "user", CFG_GetMQTTUserName(), "
"); add_label_password_field(request, "Password", "password", CFG_GetMQTTPass(), "
"); poststr(request, "
"); poststr(request, htmlFooterReturnToCfgLink); http_html_end(request); poststr(request, NULL); return 0; } int http_fn_cfg_ip(http_request_t* request) { char tmp[64]; int g_changes = 0; http_setup(request, httpMimeTypeHTML); http_html_start(request, "IP"); poststr_h2(request, "Here you can set static IP or DHCP"); hprintf255(request, "

This setting applies only to WiFi client mode.

"); hprintf255(request, "

You must restart manually for changes to take place.

"); hprintf255(request, "

Currently, DHCP is enabled by default and works when you set IP to 0.0.0.0.

"); if (http_getArg(request->url, "IP", tmp, sizeof(tmp))) { str_to_ip(tmp, g_cfg.staticIP.localIPAddr); g_changes++; } if (http_getArg(request->url, "mask", tmp, sizeof(tmp))) { str_to_ip(tmp, g_cfg.staticIP.netMask); g_changes++; } if (http_getArg(request->url, "dns", tmp, sizeof(tmp))) { str_to_ip(tmp, g_cfg.staticIP.dnsServerIpAddr); g_changes++; } if (http_getArg(request->url, "gate", tmp, sizeof(tmp))) { str_to_ip(tmp, g_cfg.staticIP.gatewayIPAddr); g_changes++; } if (g_changes) { CFG_MarkAsDirty(); hprintf255(request, "

Saved.

"); } convert_IP_to_string(tmp, g_cfg.staticIP.localIPAddr); add_label_text_field(request, "IP", "IP", tmp, "
"); convert_IP_to_string(tmp, g_cfg.staticIP.netMask); add_label_text_field(request, "Mask", "mask", tmp, "

"); convert_IP_to_string(tmp, g_cfg.staticIP.dnsServerIpAddr); add_label_text_field(request, "DNS", "dns", tmp, "
"); convert_IP_to_string(tmp, g_cfg.staticIP.gatewayIPAddr); add_label_text_field(request, "Gate", "gate", tmp, "
"); poststr(request, "
"); poststr(request, htmlFooterReturnToCfgLink); http_html_end(request); poststr(request, NULL); return 0; } int http_fn_cfg_mqtt_set(http_request_t* request) { char tmpA[128]; http_setup(request, httpMimeTypeHTML); http_html_start(request, "Saving MQTT"); if (http_getArg(request->url, "host", tmpA, sizeof(tmpA))) { } // FIX: always set, so people can clear field CFG_SetMQTTHost(tmpA); if (http_getArg(request->url, "port", tmpA, sizeof(tmpA))) { CFG_SetMQTTPort(atoi(tmpA)); } if (http_getArg(request->url, "user", tmpA, sizeof(tmpA))) { CFG_SetMQTTUserName(tmpA); } if (http_getArg(request->url, "password", tmpA, sizeof(tmpA))) { CFG_SetMQTTPass(tmpA); } if (http_getArg(request->url, "client", tmpA, sizeof(tmpA))) { CFG_SetMQTTClientId(tmpA); } if (http_getArg(request->url, "group", tmpA, sizeof(tmpA))) { CFG_SetMQTTGroupTopic(tmpA); } CFG_Save_SetupTimer(); poststr(request, "Please wait for module to connect... if there is problem, restart it from Index html page..."); g_mqtt_bBaseTopicDirty = 1; poststr(request, "
Return to MQTT settings
"); poststr(request, htmlFooterReturnToCfgLink); http_html_end(request); poststr(request, NULL); return 0; } int http_fn_cfg_webapp(http_request_t* request) { http_setup(request, httpMimeTypeHTML); http_html_start(request, "Set Webapp"); add_label_text_field(request, "URL of the Webapp", "url", CFG_GetWebappRoot(), "
"); poststr(request, SUBMIT_AND_END_FORM); poststr(request, htmlFooterReturnToCfgLink); http_html_end(request); poststr(request, NULL); return 0; } int http_fn_cfg_webapp_set(http_request_t* request) { char tmpA[128]; http_setup(request, httpMimeTypeHTML); http_html_start(request, "Saving Webapp"); if (http_getArg(request->url, "url", tmpA, sizeof(tmpA))) { CFG_SetWebappRoot(tmpA); CFG_Save_IfThereArePendingChanges(); hprintf255(request, "Webapp url set to %s", tmpA); } else { poststr(request, "Webapp url not set because you didn't specify the argument."); } poststr(request, "
"); poststr(request, htmlFooterReturnToCfgLink); http_html_end(request); poststr(request, NULL); return 0; } int http_fn_cfg_ping(http_request_t* request) { char tmpA[128]; int bChanged; http_setup(request, httpMimeTypeHTML); http_html_start(request, "Set Watchdog"); bChanged = 0; poststr(request, "

Ping watchdog (backup reconnect mechanism)

"); poststr(request, "

By default, all OpenBeken devices automatically tries to reconnect to WiFi when a connection is lost."); poststr(request, " I have tested the reconnect mechanism many times by restarting my router and it always worked reliably."); poststr(request, " However, according to some reports, there are still some edge cases when a device fails to reconnect to WIFi."); poststr(request, " This is why this mechanism has been added.

"); poststr(request, "

This mechanism keeps pinging certain host and reconnects to WiFi if it doesn't respond at all for a certain amount of seconds.

"); poststr(request, "

USAGE: For a host, choose the main address of your router and make sure it responds to a pings. Interval is 1 second or so, timeout can be set by user, to eg. 60 sec

"); if (http_getArg(request->url, "host", tmpA, sizeof(tmpA))) { CFG_SetPingHost(tmpA); poststr_h4(request, "New ping host set!"); bChanged = 1; } /* if(http_getArg(request->url,"interval",tmpA,sizeof(tmpA))) { CFG_SetPingIntervalSeconds(atoi(tmpA)); poststr(request,"

New ping interval set!

"); bChanged = 1; }*/ if (http_getArg(request->url, "disconnectTime", tmpA, sizeof(tmpA))) { CFG_SetPingDisconnectedSecondsToRestart(atoi(tmpA)); poststr_h4(request, "New ping disconnectTime set!"); bChanged = 1; } if (http_getArg(request->url, "clear", tmpA, sizeof(tmpA))) { CFG_SetPingDisconnectedSecondsToRestart(0); CFG_SetPingIntervalSeconds(0); CFG_SetPingHost(""); poststr_h4(request, "Ping watchdog disabled!"); bChanged = 1; } if (bChanged) { CFG_Save_IfThereArePendingChanges(); poststr_h4(request, "Changes will be applied after restarting"); } poststr(request, "\ \ \
"); poststr_h2(request, "Use this to enable pinger"); add_label_text_field(request, "Host", "host", CFG_GetPingHost(), "
"); add_label_numeric_field(request, "Take action after this number of seconds with no reply", "disconnectTime", CFG_GetPingDisconnectedSecondsToRestart(), "
"); poststr(request, "

\ \
"); poststr(request, htmlFooterReturnToCfgLink); http_html_end(request); poststr(request, NULL); return 0; } int http_fn_cfg_wifi(http_request_t* request) { // for a test, show password as well... char tmpA[128]; http_setup(request, httpMimeTypeHTML); http_html_start(request, "Set Wifi"); /*bChanged = 0; if(http_getArg(recvbuf,"ssid",tmpA,sizeof(tmpA))) { CFG_SetWiFiSSID(tmpA); poststr(request,"

WiFi SSID set!

"); bChanged = 1; } if(http_getArg(recvbuf,"pass",tmpA,sizeof(tmpA))) { CFG_SetWiFiPass(tmpA); poststr(request,"

WiFi Password set!

"); bChanged = 1; } if(bChanged) { poststr(request,"

Device will reconnect after restarting

"); }*/ poststr(request, "

Check networks reachable by module

This will lag few seconds.
"); if (http_getArg(request->url, "scan", tmpA, sizeof(tmpA))) { #ifdef WINDOWS poststr(request, "Not available on Windows
"); #elif PLATFORM_XR809 poststr(request, "TODO XR809
"); #elif PLATFORM_W600 || PLATFORM_W800 poststr(request, "TODO W800
"); #elif PLATFORM_BL602 poststr(request, "TODO BL602
"); #elif PLATFORM_BK7231T int i; AP_IF_S* ar; uint32_t num; bk_printf("Scan begin...\r\n"); tuya_hal_wifi_all_ap_scan(&ar, &num); bk_printf("Scan returned %i networks\r\n", num); for (i = 0; i < num; i++) { hprintf255(request, "[%i/%i] SSID: %s, Channel: %i, Signal %i
", i, (int)num, ar[i].ssid, ar[i].channel, ar[i].rssi); } tuya_hal_wifi_release_ap(ar); #elif PLATFORM_BK7231N int i; AP_IF_S* ar; uint32_t num; bk_printf("Scan begin...\r\n"); tuya_os_adapt_wifi_all_ap_scan(&ar, (unsigned int*)&num); bk_printf("Scan returned %i networks\r\n", num); for (i = 0; i < num; i++) { hprintf255(request, "[%i/%i] SSID: %s, Channel: %i, Signal %i
", i + 1, (int)num, ar[i].ssid, ar[i].channel, ar[i].rssi); } tuya_os_adapt_wifi_release_ap(ar); #else #error "Unknown platform" poststr(request, "Unknown platform
"); #endif } poststr(request, "
\ \ \
"); poststr_h4(request, "Use this to disconnect from your WiFi"); poststr(request, "
\ \ \
"); poststr_h2(request, "Use this to connect to your WiFi"); add_label_text_field(request, "SSID", "ssid", CFG_GetWiFiSSID(), "
"); add_label_password_field(request, "Password", "pass", CFG_GetWiFiPass(), "
"); poststr_h2(request, "Alternate WiFi (used when first one is not responding)"); add_label_text_field(request, "SSID2", "ssid2", CFG_GetWiFiSSID2(), ""); add_label_password_field(request, "Password2", "pass2", CFG_GetWiFiPass2(), "
"); #if ALLOW_WEB_PASSWORD int web_password_enabled = strcmp(CFG_GetWebPassword(), "") == 0 ? 0 : 1; poststr_h2(request, "Web Authentication"); poststr(request, "

Enabling web authentication will protect this web interface and API using basic HTTP authentication. Username is always admin.

"); hprintf255(request, "
", (web_password_enabled > 0 ? " checked" : "")); poststr(request, "
"); add_label_password_field(request, "Admin Password", "web_admin_password", CFG_GetWebPassword(), ""); #endif poststr(request, "

\ \
"); poststr(request, htmlFooterReturnToCfgLink); http_html_end(request); poststr(request, NULL); return 0; } int http_fn_cfg_name(http_request_t* request) { // for a test, show password as well... char tmpA[128]; http_setup(request, httpMimeTypeHTML); http_html_start(request, "Set name"); poststr_h2(request, "Change device names for display"); if (http_getArg(request->url, "shortName", tmpA, sizeof(tmpA))) { if (STR_ReplaceWhiteSpacesWithUnderscore(tmpA)) { poststr_h2(request, "You cannot have whitespaces in short name!"); } CFG_SetShortDeviceName(tmpA); } if (http_getArg(request->url, "name", tmpA, sizeof(tmpA))) { CFG_SetDeviceName(tmpA); } CFG_Save_IfThereArePendingChanges(); poststr_h2(request, "Use this to change device names"); add_label_name_field(request, "ShortName", "shortName", CFG_GetShortDeviceName(), "
"); add_label_name_field(request, "Full Name", "name", CFG_GetDeviceName(), "
"); poststr(request, "

"); poststr(request, ""); poststr(request, "
"); //poststr(request,htmlReturnToCfg); //HTTP_AddBuildFooter(request); //poststr(request,htmlEnd); poststr(request, htmlFooterReturnToCfgLink); http_html_end(request); poststr(request, NULL); return 0; } int http_fn_cfg_wifi_set(http_request_t* request) { char tmpA[128]; int bChanged; addLogAdv(LOG_INFO, LOG_FEATURE_HTTP, "HTTP_ProcessPacket: generating cfg_wifi_set \r\n"); bChanged = 0; http_setup(request, httpMimeTypeHTML); http_html_start(request, "Saving Wifi"); if (http_getArg(request->url, "open", tmpA, sizeof(tmpA))) { bChanged |= CFG_SetWiFiSSID(""); bChanged |= CFG_SetWiFiPass(""); poststr(request, "WiFi mode set: open access point."); } else { if (http_getArg(request->url, "ssid", tmpA, sizeof(tmpA))) { bChanged |= CFG_SetWiFiSSID(tmpA); } if (http_getArg(request->url, "pass", tmpA, sizeof(tmpA))) { bChanged |= CFG_SetWiFiPass(tmpA); } poststr(request, "WiFi mode set: connect to WLAN."); } if (http_getArg(request->url, "ssid2", tmpA, sizeof(tmpA))) { bChanged |= CFG_SetWiFiSSID2(tmpA); } if (http_getArg(request->url, "pass2", tmpA, sizeof(tmpA))) { bChanged |= CFG_SetWiFiPass2(tmpA); } #if ALLOW_WEB_PASSWORD if (http_getArg(request->url, "web_admin_password_enabled", tmpA, sizeof(tmpA))) { int web_password_enabled = atoi(tmpA); if (web_password_enabled > 0 && http_getArg(request->url, "web_admin_password", tmpA, sizeof(tmpA))) { if (strlen(tmpA) < 5) { poststr_h4(request, "Web password needs to be at least 5 characters long!"); } else { poststr(request, "

Web password has been changed.

"); CFG_SetWebPassword(tmpA); } } } else { CFG_SetWebPassword(""); } #endif CFG_Save_SetupTimer(); if (bChanged == 0) { poststr(request, "

WiFi: No changes detected.

"); } else { poststr(request, "

WiFi: Please wait for module to reset...

"); RESET_ScheduleModuleReset(3); } poststr(request, "
Return to WiFi settings
"); poststr(request, htmlFooterReturnToCfgLink); http_html_end(request); poststr(request, NULL); return 0; } int http_fn_cfg_loglevel_set(http_request_t* request) { char tmpA[128]; addLogAdv(LOG_INFO, LOG_FEATURE_HTTP, "HTTP_ProcessPacket: generating cfg_loglevel_set \r\n"); http_setup(request, httpMimeTypeHTML); http_html_start(request, "Set log level"); if (http_getArg(request->url, "loglevel", tmpA, sizeof(tmpA))) { #if WINDOWS #else g_loglevel = atoi(tmpA); #endif poststr(request, "LOG level changed."); } tmpA[0] = 0; #if WINDOWS add_label_text_field(request, "Loglevel", "loglevel", "", "
"); #else add_label_numeric_field(request, "Loglevel", "loglevel", g_loglevel, ""); #endif poststr(request, "

\ \
"); poststr(request, "
Return to config settings
"); poststr(request, htmlFooterReturnToCfgLink); http_html_end(request); poststr(request, NULL); return 0; } int http_fn_cfg_mac(http_request_t* request) { // must be unsigned, else print below prints negatives as e.g. FFFFFFFe unsigned char mac[6]; char tmpA[128]; int i; char macStr[16]; http_setup(request, httpMimeTypeHTML); http_html_start(request, "Set MAC address"); if (http_getArg(request->url, "mac", tmpA, sizeof(tmpA))) { for (i = 0; i < 6; i++) { mac[i] = hexbyte(&tmpA[i * 2]); } //sscanf(tmpA,"%02X%02X%02X%02X%02X%02X",&mac[0],&mac[1],&mac[2],&mac[3],&mac[4],&mac[5]); if (WiFI_SetMacAddress((char*)mac)) { poststr_h4(request, "New MAC set!"); } else { poststr_h4(request, "MAC change error?"); } CFG_Save_IfThereArePendingChanges(); } WiFI_GetMacAddress((char*)mac); poststr_h2(request, "Here you can change MAC address."); sprintf(macStr, "%02X%02X%02X%02X%02X%02X", mac[0], mac[1], mac[2], mac[3], mac[4], mac[5]); add_label_text_field(request, "MAC", "mac", macStr, "
"); poststr(request, "

\ \
"); poststr(request, htmlFooterReturnToCfgLink); http_html_end(request); poststr(request, NULL); return 0; } // //int http_fn_flash_read_tool(http_request_t* request) { // int len = 16; // int ofs = 1970176; // int res; // int rem; // int now; // int nowOfs; // int hex; // int i; // char tmpA[128]; // char tmpB[64]; // // http_setup(request, httpMimeTypeHTML); // http_html_start(request, "Flash read"); // poststr_h4(request, "Flash Read Tool"); // if (http_getArg(request->url, "hex", tmpA, sizeof(tmpA))) { // hex = atoi(tmpA); // } // else { // hex = 0; // } // // if (http_getArg(request->url, "offset", tmpA, sizeof(tmpA)) && // http_getArg(request->url, "len", tmpB, sizeof(tmpB))) { // unsigned char buffer[128]; // len = atoi(tmpB); // ofs = atoi(tmpA); // hprintf255(request, "Memory at %i with len %i reads: ", ofs, len); // poststr(request, "
"); // // ///res = bekken_hal_flash_read (ofs, buffer,len); // //sprintf(tmpA,"Result %i",res); // // strcat(outbuf,tmpA); // /// strcat(outbuf,"
"); // // nowOfs = ofs; // rem = len; // while (1) { // if (rem > sizeof(buffer)) { // now = sizeof(buffer); // } // else { // now = rem; // } //#if PLATFORM_XR809 // //uint32_t flash_read(uint32_t flash, uint32_t addr,void *buf, uint32_t size) //#define FLASH_INDEX_XR809 0 // res = flash_read(FLASH_INDEX_XR809, nowOfs, buffer, now); //#elif PLATFORM_BL602 // //#elif PLATFORM_W600 || PLATFORM_W800 // //#else // res = bekken_hal_flash_read(nowOfs, buffer, now); //#endif // for (i = 0; i < now; i++) { // unsigned char val = buffer[i]; // if (!hex && isprint(val)) { // hprintf255(request, "'%c' ", val); // } // else { // hprintf255(request, "%02X ", val); // } // } // rem -= now; // nowOfs += now; // if (rem <= 0) { // break; // } // } // // poststr(request, "
"); // } // poststr(request, "
"); // // poststr(request, "
"); // // add_label_numeric_field(request, "Offset", "offset", ofs, ""); // add_label_numeric_field(request, "Length", "len", len, "
"); // poststr(request, SUBMIT_AND_END_FORM); // // poststr(request, htmlFooterReturnToCfgLink); // http_html_end(request); // poststr(request, NULL); // return 0; //} const char* CMD_GetResultString(commandResult_t r) { if (r == CMD_RES_OK) return "OK"; if (r == CMD_RES_EMPTY_STRING) return "No command entered"; if (r == CMD_RES_ERROR) return "Command found but returned error"; if (r == CMD_RES_NOT_ENOUGH_ARGUMENTS) return "Not enough arguments for this command"; if (r == CMD_RES_UNKNOWN_COMMAND) return "Unknown command"; if (r == CMD_RES_BAD_ARGUMENT) return "Bad argument"; return "Unknown error"; } // all log printfs made by command will be sent also to request void LOG_SetCommandHTTPRedirectReply(http_request_t* request); int http_fn_cmd_tool(http_request_t* request) { commandResult_t res; const char* resStr; char tmpA[128]; char* long_str_alloced = 0; int commandLen; http_setup(request, httpMimeTypeHTML); http_html_start(request, "Command tool"); poststr_h4(request, "Command Tool"); poststr(request, "This is a basic command line.
"); poststr(request, "Please consider using 'Web Application' console with more options and real time log view.
"); poststr(request, "Remember that some commands are added after a restart when a driver is activated...
"); commandLen = http_getArg(request->url, "cmd", tmpA, sizeof(tmpA)); if (commandLen) { poststr(request, "
"); // all log printfs made by command will be sent also to request LOG_SetCommandHTTPRedirectReply(request); if (commandLen > (sizeof(tmpA) - 5)) { commandLen += 8; long_str_alloced = (char*)malloc(commandLen); if (long_str_alloced) { http_getArg(request->url, "cmd", long_str_alloced, commandLen); res = CMD_ExecuteCommand(long_str_alloced, COMMAND_FLAG_SOURCE_CONSOLE); free(long_str_alloced); } else { res = CMD_RES_ERROR; } } else { res = CMD_ExecuteCommand(tmpA, COMMAND_FLAG_SOURCE_CONSOLE); } LOG_SetCommandHTTPRedirectReply(0); resStr = CMD_GetResultString(res); hprintf255(request, "

%s

", resStr); poststr(request, "
"); } add_label_text_field(request, "Command", "cmd", tmpA, ""); poststr(request, SUBMIT_AND_END_FORM); poststr(request, htmlFooterReturnToCfgLink); http_html_end(request); poststr(request, NULL); return 0; } int http_fn_startup_command(http_request_t* request) { char tmpA[512]; http_setup(request, httpMimeTypeHTML); http_html_start(request, "Set startup command"); poststr_h4(request, "Set/Change/Clear startup command line"); poststr(request, "

Startup command is a shorter, smaller alternative to LittleFS autoexec.bat. " "The startup commands are ran at device startup. " "You can use them to init peripherals and drivers, like BL0942 energy sensor. " "Use backlog cmd1; cmd2; cmd3; etc to enter multiple commands

"); if (http_getArg(request->url, "startup_cmd", tmpA, sizeof(tmpA))) { http_getArg(request->url, "data", tmpA, sizeof(tmpA)); // hprintf255(request,"

Set command to %s!

",tmpA); // tmpA can be longer than 128 bytes and this would crash hprintf255(request, "

Command changed!

"); CFG_SetShortStartupCommand(tmpA); CFG_Save_IfThereArePendingChanges(); } add_label_text_field(request, "Startup command", "data", CFG_GetShortStartupCommand(), ""); poststr(request, ""); poststr(request, SUBMIT_AND_END_FORM); poststr(request, htmlFooterReturnToCfgLink); http_html_end(request); poststr(request, NULL); return 0; } void doHomeAssistantDiscovery(const char* topic, http_request_t* request) { int i; int relayCount; int pwmCount; int dInputCount; bool ledDriverChipRunning; HassDeviceInfo* dev_info = NULL; bool measuringPower = false; bool measuringBattery = false; struct cJSON_Hooks hooks; bool discoveryQueued = false; int type; // warning - this is 32 bit int flagsChannelPublished; int ch; int dimmer, toggle, brightness_scale; // no channels published yet flagsChannelPublished = 0; if (topic == 0 || *topic == 0) { topic = "homeassistant"; } #ifndef OBK_DISABLE_ALL_DRIVERS measuringPower = DRV_IsMeasuringPower(); measuringBattery = DRV_IsMeasuringBattery(); #endif PIN_get_Relay_PWM_Count(&relayCount, &pwmCount, &dInputCount); addLogAdv(LOG_INFO, LOG_FEATURE_HTTP, "HASS counts: %i rels, %i pwms, %i inps", relayCount, pwmCount, dInputCount); ledDriverChipRunning = LED_IsLedDriverChipRunning(); hooks.malloc_fn = os_malloc; hooks.free_fn = os_free; cJSON_InitHooks(&hooks); #if ENABLE_ADVANCED_CHANNELTYPES_DISCOVERY // try to pair toggles with dimmers. This is needed only for TuyaMCU, // where custom channel types are used. This is NOT used for simple // CW/RGB/RGBCW/etc lights. while (true) { // find first dimmer dimmer = -1; for (i = 0; i < CHANNEL_MAX; i++) { type = g_cfg.pins.channelTypes[i]; if (BIT_CHECK(flagsChannelPublished, i)) { continue; } if (type == ChType_Dimmer) { brightness_scale = 100; dimmer = i; break; } if (type == ChType_Dimmer1000) { brightness_scale = 1000; dimmer = i; break; } if (type == ChType_Dimmer256) { brightness_scale = 256; dimmer = i; break; } } // find first togle toggle = -1; for (i = 0; i < CHANNEL_MAX; i++) { type = g_cfg.pins.channelTypes[i]; if (BIT_CHECK(flagsChannelPublished, i)) { continue; } if (type == ChType_Toggle) { toggle = i; break; } } // if nothing found, stop if (toggle == -1 || dimmer == -1) { break; } BIT_SET(flagsChannelPublished, toggle); BIT_SET(flagsChannelPublished, dimmer); dev_info = hass_init_light_singleColor_onChannels(toggle, dimmer, brightness_scale); MQTT_QueuePublish(topic, dev_info->channel, hass_build_discovery_json(dev_info), OBK_PUBLISH_FLAG_RETAIN); hass_free_device_info(dev_info); } #endif //if (relayCount > 0) { for (i = 0; i < CHANNEL_MAX; i++) { // if already included by light, skip if (BIT_CHECK(flagsChannelPublished, i)) { continue; } bool bToggleInv = g_cfg.pins.channelTypes[i] == ChType_Toggle_Inv; if (h_isChannelRelay(i) || g_cfg.pins.channelTypes[i] == ChType_Toggle || bToggleInv) { // TODO: flags are 32 bit and there are 64 max channels BIT_SET(flagsChannelPublished, i); if (CFG_HasFlag(OBK_FLAG_MQTT_HASS_ADD_RELAYS_AS_LIGHTS)) { dev_info = hass_init_relay_device_info(i, LIGHT_ON_OFF, bToggleInv); } else { dev_info = hass_init_relay_device_info(i, RELAY, bToggleInv); } MQTT_QueuePublish(topic, dev_info->channel, hass_build_discovery_json(dev_info), OBK_PUBLISH_FLAG_RETAIN); hass_free_device_info(dev_info); dev_info = NULL; discoveryQueued = true; } } //} if (dInputCount > 0) { for (i = 0; i < CHANNEL_MAX; i++) { if (h_isChannelDigitalInput(i)) { // TODO: flags are 32 bit and there are 64 max channels BIT_SET(flagsChannelPublished, i); dev_info = hass_init_binary_sensor_device_info(i, false); MQTT_QueuePublish(topic, dev_info->channel, hass_build_discovery_json(dev_info), OBK_PUBLISH_FLAG_RETAIN); hass_free_device_info(dev_info); dev_info = NULL; discoveryQueued = true; } } } if (pwmCount == 5 || ledDriverChipRunning || (pwmCount == 4 && CFG_HasFlag(OBK_FLAG_LED_EMULATE_COOL_WITH_RGB))) { if (dev_info == NULL) { dev_info = hass_init_light_device_info(LIGHT_RGBCW); } // Enable + RGB control + CW control MQTT_QueuePublish(topic, dev_info->channel, hass_build_discovery_json(dev_info), OBK_PUBLISH_FLAG_RETAIN); hass_free_device_info(dev_info); dev_info = NULL; discoveryQueued = true; } else if (pwmCount > 0) { if (pwmCount == 4) { addLogAdv(LOG_ERROR, LOG_FEATURE_HTTP, "4 PWM device not yet handled\r\n"); } else if (pwmCount == 3) { // Enable + RGB control dev_info = hass_init_light_device_info(LIGHT_RGB); } else if (pwmCount == 2) { // PWM + Temperature (https://github.com/openshwprojects/OpenBK7231T_App/issues/279) dev_info = hass_init_light_device_info(LIGHT_PWMCW); } else { dev_info = hass_init_light_device_info(LIGHT_PWM); } if (dev_info != NULL) { MQTT_QueuePublish(topic, dev_info->channel, hass_build_discovery_json(dev_info), OBK_PUBLISH_FLAG_RETAIN); hass_free_device_info(dev_info); dev_info = NULL; discoveryQueued = true; } } #ifndef OBK_DISABLE_ALL_DRIVERS if (measuringPower == true) { for (i = 0; i < OBK_NUM_SENSOR_COUNT; i++) { dev_info = hass_init_power_sensor_device_info(i); if (dev_info) { MQTT_QueuePublish(topic, dev_info->channel, hass_build_discovery_json(dev_info), OBK_PUBLISH_FLAG_RETAIN); hass_free_device_info(dev_info); discoveryQueued = true; } } } #endif if (measuringBattery == true) { dev_info = hass_init_sensor_device_info(BATTERY_SENSOR, 0, -1, -1, 1); MQTT_QueuePublish(topic, dev_info->channel, hass_build_discovery_json(dev_info), OBK_PUBLISH_FLAG_RETAIN); hass_free_device_info(dev_info); dev_info = hass_init_sensor_device_info(BATTERY_VOLTAGE_SENSOR, 0, -1, -1, 1); MQTT_QueuePublish(topic, dev_info->channel, hass_build_discovery_json(dev_info), OBK_PUBLISH_FLAG_RETAIN); hass_free_device_info(dev_info); discoveryQueued = true; } for (i = 0; i < PLATFORM_GPIO_MAX; i++) { if (IS_PIN_DHT_ROLE(g_cfg.pins.roles[i]) || IS_PIN_TEMP_HUM_SENSOR_ROLE(g_cfg.pins.roles[i])) { ch = PIN_GetPinChannelForPinIndex(i); // TODO: flags are 32 bit and there are 64 max channels BIT_SET(flagsChannelPublished, ch); dev_info = hass_init_sensor_device_info(TEMPERATURE_SENSOR, ch, 2, 1, 1); MQTT_QueuePublish(topic, dev_info->channel, hass_build_discovery_json(dev_info), OBK_PUBLISH_FLAG_RETAIN); hass_free_device_info(dev_info); ch = PIN_GetPinChannel2ForPinIndex(i); // TODO: flags are 32 bit and there are 64 max channels BIT_SET(flagsChannelPublished, ch); dev_info = hass_init_sensor_device_info(HUMIDITY_SENSOR, ch, -1, -1, 1); MQTT_QueuePublish(topic, dev_info->channel, hass_build_discovery_json(dev_info), OBK_PUBLISH_FLAG_RETAIN); hass_free_device_info(dev_info); discoveryQueued = true; } else if (IS_PIN_AIR_SENSOR_ROLE(g_cfg.pins.roles[i])) { ch = PIN_GetPinChannelForPinIndex(i); // TODO: flags are 32 bit and there are 64 max channels BIT_SET(flagsChannelPublished, ch); dev_info = hass_init_sensor_device_info(CO2_SENSOR, ch, -1, -1, 1); MQTT_QueuePublish(topic, dev_info->channel, hass_build_discovery_json(dev_info), OBK_PUBLISH_FLAG_RETAIN); hass_free_device_info(dev_info); ch = PIN_GetPinChannel2ForPinIndex(i); // TODO: flags are 32 bit and there are 64 max channels BIT_SET(flagsChannelPublished, ch); dev_info = hass_init_sensor_device_info(TVOC_SENSOR, ch, -1, -1, 1); MQTT_QueuePublish(topic, dev_info->channel, hass_build_discovery_json(dev_info), OBK_PUBLISH_FLAG_RETAIN); hass_free_device_info(dev_info); discoveryQueued = true; } } #if ENABLE_ADVANCED_CHANNELTYPES_DISCOVERY for (i = 0; i < CHANNEL_MAX; i++) { type = g_cfg.pins.channelTypes[i]; // TODO: flags are 32 bit and there are 64 max channels if (BIT_CHECK(flagsChannelPublished, i)) { continue; } switch (type) { case ChType_OpenClosed: { dev_info = hass_init_binary_sensor_device_info(i, false); MQTT_QueuePublish(topic, dev_info->channel, hass_build_discovery_json(dev_info), OBK_PUBLISH_FLAG_RETAIN); hass_free_device_info(dev_info); discoveryQueued = true; } break; case ChType_OpenClosed_Inv: { dev_info = hass_init_binary_sensor_device_info(i, true); MQTT_QueuePublish(topic, dev_info->channel, hass_build_discovery_json(dev_info), OBK_PUBLISH_FLAG_RETAIN); hass_free_device_info(dev_info); discoveryQueued = true; } break; case ChType_Voltage_div10: { dev_info = hass_init_sensor_device_info(VOLTAGE_SENSOR, i, 2, 1, 1); MQTT_QueuePublish(topic, dev_info->channel, hass_build_discovery_json(dev_info), OBK_PUBLISH_FLAG_RETAIN); hass_free_device_info(dev_info); discoveryQueued = true; } break; case ChType_Voltage_div100: { dev_info = hass_init_sensor_device_info(VOLTAGE_SENSOR, i, 2, 2, 1); MQTT_QueuePublish(topic, dev_info->channel, hass_build_discovery_json(dev_info), OBK_PUBLISH_FLAG_RETAIN); hass_free_device_info(dev_info); discoveryQueued = true; } break; case ChType_ReadOnlyLowMidHigh: { dev_info = hass_init_sensor_device_info(READONLYLOWMIDHIGH_SENSOR, i, -1, -1, 1); MQTT_QueuePublish(topic, dev_info->channel, hass_build_discovery_json(dev_info), OBK_PUBLISH_FLAG_RETAIN); hass_free_device_info(dev_info); discoveryQueued = true; } break; case ChType_SmokePercent: { dev_info = hass_init_sensor_device_info(SMOKE_SENSOR, i, -1, -1, 1); MQTT_QueuePublish(topic, dev_info->channel, hass_build_discovery_json(dev_info), OBK_PUBLISH_FLAG_RETAIN); hass_free_device_info(dev_info); discoveryQueued = true; } break; case ChType_Illuminance: { dev_info = hass_init_sensor_device_info(ILLUMINANCE_SENSOR, i, -1, -1, 1); MQTT_QueuePublish(topic, dev_info->channel, hass_build_discovery_json(dev_info), OBK_PUBLISH_FLAG_RETAIN); hass_free_device_info(dev_info); discoveryQueued = true; } break; case ChType_ReadOnly: { dev_info = hass_init_sensor_device_info(CUSTOM_SENSOR, i, -1, -1, 1); MQTT_QueuePublish(topic, dev_info->channel, hass_build_discovery_json(dev_info), OBK_PUBLISH_FLAG_RETAIN); hass_free_device_info(dev_info); discoveryQueued = true; } break; case ChType_Temperature: { dev_info = hass_init_sensor_device_info(TEMPERATURE_SENSOR, i, -1, -1, 1); MQTT_QueuePublish(topic, dev_info->channel, hass_build_discovery_json(dev_info), OBK_PUBLISH_FLAG_RETAIN); hass_free_device_info(dev_info); discoveryQueued = true; } break; case ChType_Temperature_div2: { dev_info = hass_init_sensor_device_info(TEMPERATURE_SENSOR, i, 2, 1, 5); MQTT_QueuePublish(topic, dev_info->channel, hass_build_discovery_json(dev_info), OBK_PUBLISH_FLAG_RETAIN); hass_free_device_info(dev_info); discoveryQueued = true; } break; case ChType_Temperature_div10: { dev_info = hass_init_sensor_device_info(TEMPERATURE_SENSOR, i, 2, 1, 1); MQTT_QueuePublish(topic, dev_info->channel, hass_build_discovery_json(dev_info), OBK_PUBLISH_FLAG_RETAIN); hass_free_device_info(dev_info); discoveryQueued = true; } break; case ChType_Temperature_div100: { dev_info = hass_init_sensor_device_info(TEMPERATURE_SENSOR, i, 2, 2, 1); MQTT_QueuePublish(topic, dev_info->channel, hass_build_discovery_json(dev_info), OBK_PUBLISH_FLAG_RETAIN); hass_free_device_info(dev_info); discoveryQueued = true; } break; case ChType_Humidity: { dev_info = hass_init_sensor_device_info(HUMIDITY_SENSOR, i, -1, -1, 1); MQTT_QueuePublish(topic, dev_info->channel, hass_build_discovery_json(dev_info), OBK_PUBLISH_FLAG_RETAIN); hass_free_device_info(dev_info); discoveryQueued = true; } break; case ChType_Humidity_div10: { dev_info = hass_init_sensor_device_info(HUMIDITY_SENSOR, i, 2, 1, 1); MQTT_QueuePublish(topic, dev_info->channel, hass_build_discovery_json(dev_info), OBK_PUBLISH_FLAG_RETAIN); hass_free_device_info(dev_info); discoveryQueued = true; } break; case ChType_Current_div100: { dev_info = hass_init_sensor_device_info(CURRENT_SENSOR, i, 3, 2, 1); MQTT_QueuePublish(topic, dev_info->channel, hass_build_discovery_json(dev_info), OBK_PUBLISH_FLAG_RETAIN); hass_free_device_info(dev_info); discoveryQueued = true; } break; case ChType_Current_div1000: { dev_info = hass_init_sensor_device_info(CURRENT_SENSOR, i, 3, 3, 1); MQTT_QueuePublish(topic, dev_info->channel, hass_build_discovery_json(dev_info), OBK_PUBLISH_FLAG_RETAIN); hass_free_device_info(dev_info); discoveryQueued = true; } break; case ChType_Power: { dev_info = hass_init_sensor_device_info(POWER_SENSOR, i, -1, -1, 1); MQTT_QueuePublish(topic, dev_info->channel, hass_build_discovery_json(dev_info), OBK_PUBLISH_FLAG_RETAIN); hass_free_device_info(dev_info); discoveryQueued = true; } break; case ChType_Power_div10: { dev_info = hass_init_sensor_device_info(POWER_SENSOR, i, 2, 1, 1); MQTT_QueuePublish(topic, dev_info->channel, hass_build_discovery_json(dev_info), OBK_PUBLISH_FLAG_RETAIN); hass_free_device_info(dev_info); discoveryQueued = true; } break; case ChType_PowerFactor_div100: { dev_info = hass_init_sensor_device_info(POWERFACTOR_SENSOR, i, 3, 2, 1); MQTT_QueuePublish(topic, dev_info->channel, hass_build_discovery_json(dev_info), OBK_PUBLISH_FLAG_RETAIN); hass_free_device_info(dev_info); discoveryQueued = true; } break; case ChType_Pressure_div100: { dev_info = hass_init_sensor_device_info(PRESSURE_SENSOR, i, 3, 2, 1); MQTT_QueuePublish(topic, dev_info->channel, hass_build_discovery_json(dev_info), OBK_PUBLISH_FLAG_RETAIN); hass_free_device_info(dev_info); discoveryQueued = true; } break; case ChType_PowerFactor_div1000: { dev_info = hass_init_sensor_device_info(POWERFACTOR_SENSOR, i, 4, 3, 1); MQTT_QueuePublish(topic, dev_info->channel, hass_build_discovery_json(dev_info), OBK_PUBLISH_FLAG_RETAIN); hass_free_device_info(dev_info); discoveryQueued = true; } break; case ChType_Frequency_div100: { dev_info = hass_init_sensor_device_info(FREQUENCY_SENSOR, i, 3, 2, 1); MQTT_QueuePublish(topic, dev_info->channel, hass_build_discovery_json(dev_info), OBK_PUBLISH_FLAG_RETAIN); hass_free_device_info(dev_info); discoveryQueued = true; } break; case ChType_Frequency_div10: { dev_info = hass_init_sensor_device_info(FREQUENCY_SENSOR, i, 3, 1, 1); MQTT_QueuePublish(topic, dev_info->channel, hass_build_discovery_json(dev_info), OBK_PUBLISH_FLAG_RETAIN); hass_free_device_info(dev_info); discoveryQueued = true; } break; case ChType_EnergyTotal_kWh_div100: { dev_info = hass_init_sensor_device_info(ENERGY_SENSOR, i, 3, 2, 1); MQTT_QueuePublish(topic, dev_info->channel, hass_build_discovery_json(dev_info), OBK_PUBLISH_FLAG_RETAIN); hass_free_device_info(dev_info); discoveryQueued = true; } break; case ChType_EnergyTotal_kWh_div1000: { dev_info = hass_init_sensor_device_info(ENERGY_SENSOR, i, 3, 3, 1); MQTT_QueuePublish(topic, dev_info->channel, hass_build_discovery_json(dev_info), OBK_PUBLISH_FLAG_RETAIN); hass_free_device_info(dev_info); discoveryQueued = true; } break; } } #endif if (1) { dev_info = hass_init_sensor_device_info(HASS_RSSI, 0, -1, -1, 1); MQTT_QueuePublish(topic, dev_info->channel, hass_build_discovery_json(dev_info), OBK_PUBLISH_FLAG_RETAIN); hass_free_device_info(dev_info); discoveryQueued = true; } if (discoveryQueued) { MQTT_InvokeCommandAtEnd(PublishChannels); } else { const char* msg = "No relay, PWM, sensor or power driver running."; if (request) { poststr(request, msg); poststr(request, NULL); } else { addLogAdv(LOG_ERROR, LOG_FEATURE_HTTP, "HA discovery: %s\r\n", msg); } } } /// @brief Sends HomeAssistant discovery MQTT messages. /// @param request /// @return int http_fn_ha_discovery(http_request_t* request) { char topic[32]; http_setup(request, httpMimeTypeText); if (MQTT_IsReady() == false) { poststr(request, "MQTT not running."); poststr(request, NULL); return 0; } // even if it returns the empty HA topic, // the function call below will set default http_getArg(request->url, "prefix", topic, sizeof(topic)); doHomeAssistantDiscovery(topic, request); poststr(request, "MQTT discovery queued."); poststr(request, NULL); return 0; } void http_generate_singleColor_cfg(http_request_t* request, const char* clientId) { hprintf255(request, " command_topic: \"cmnd/%s/led_enableAll\"\n", clientId); hprintf255(request, " state_topic: \"%s/led_enableAll/get\"\n", clientId); hprintf255(request, " availability_topic: \"%s/connected\"\n", clientId); hprintf255(request, " payload_on: 1\n"); hprintf255(request, " payload_off: 0\n"); hprintf255(request, " brightness_command_topic: \"cmnd/%s/led_dimmer\"\n", clientId); hprintf255(request, " brightness_state_topic: \"%s/led_dimmer/get\"\n", clientId); hprintf255(request, " brightness_scale: 100\n"); } void http_generate_rgb_cfg(http_request_t* request, const char* clientId) { hprintf255(request, " rgb_command_template: \"{{ '#%%02x%%02x%%02x0000' | format(red, green, blue)}}\"\n"); hprintf255(request, " rgb_value_template: \"{{ value[0:2]|int(base=16) }},{{ value[2:4]|int(base=16) }},{{ value[4:6]|int(base=16) }}\"\n"); hprintf255(request, " rgb_state_topic: \"%s/led_basecolor_rgb/get\"\n", clientId); hprintf255(request, " rgb_command_topic: \"cmnd/%s/led_basecolor_rgb\"\n", clientId); http_generate_singleColor_cfg(request, clientId); } void http_generate_cw_cfg(http_request_t* request, const char* clientId) { hprintf255(request, " color_temp_command_topic: \"cmnd/%s/led_temperature\"\n", clientId); hprintf255(request, " color_temp_state_topic: \"%s/led_temperature/get\"\n", clientId); http_generate_singleColor_cfg(request, clientId); } void hprintf_qos_payload(http_request_t* request, const char* clientId) { poststr(request, " qos: 1\n"); poststr(request, " payload_on: 1\n"); poststr(request, " payload_off: 0\n"); poststr(request, " retain: true\n"); hprintf255(request, " availability:\n"); hprintf255(request, " - topic: \"%s/connected\"\n", clientId); } int http_fn_ha_cfg(http_request_t* request) { int relayCount; int pwmCount; int dInputCount; const char* shortDeviceName; const char* clientId; int i; char mqttAdded = 0; char switchAdded = 0; char lightAdded = 0; i = 0; shortDeviceName = CFG_GetShortDeviceName(); clientId = CFG_GetMQTTClientId(); http_setup(request, httpMimeTypeHTML); http_html_start(request, "Home Assistant Setup"); poststr_h4(request, "Home Assistant Cfg"); hprintf255(request, "

Note that your short device name is: %s

", shortDeviceName); poststr_h4(request, "Paste this to configuration yaml"); poststr(request, "
Make sure that you have \"switch:\" keyword only once! Home Assistant doesn't like dup keywords.
"); poststr(request, "
You can also use \"switch MyDeviceName:\" to avoid keyword duplication!
"); poststr(request, ""); poststr(request, "
 

"); poststr(request, htmlFooterReturnToCfgLink); http_html_end(request); poststr(request, ha_discovery_script); poststr(request, NULL); return 0; } int http_fn_cm(http_request_t* request) { char tmpA[128]; char* long_str_alloced = 0; int commandLen = 0; http_setup(request, httpMimeTypeJson); // exec command if (request->method == HTTP_GET) { commandLen = http_getArg(request->url, "cmnd", tmpA, sizeof(tmpA)); //ADDLOG_INFO(LOG_FEATURE_HTTP, "Got here (GET) %s;%s;%d\n", request->url, tmpA, commandLen); } else if (request->method == HTTP_POST || request->method == HTTP_PUT) { commandLen = http_getRawArg(request->bodystart, "cmnd", tmpA, sizeof(tmpA)); //ADDLOG_INFO(LOG_FEATURE_HTTP, "Got here (POST) %s;%s;%d\n", request->bodystart, tmpA, commandLen); } if (commandLen) { if (commandLen > (sizeof(tmpA) - 5)) { commandLen += 8; long_str_alloced = (char*)malloc(commandLen); if (long_str_alloced) { if (request->method == HTTP_GET) { http_getArg(request->url, "cmnd", long_str_alloced, commandLen); } else if (request->method == HTTP_POST || request->method == HTTP_PUT) { http_getRawArg(request->bodystart, "cmnd", long_str_alloced, commandLen); } CMD_ExecuteCommand(long_str_alloced, COMMAND_FLAG_SOURCE_HTTP); JSON_ProcessCommandReply(long_str_alloced, skipToNextWord(long_str_alloced), request, (jsonCb_t)hprintf255, COMMAND_FLAG_SOURCE_HTTP); free(long_str_alloced); } } else { CMD_ExecuteCommand(tmpA, COMMAND_FLAG_SOURCE_HTTP); JSON_ProcessCommandReply(tmpA, skipToNextWord(tmpA), request, (jsonCb_t)hprintf255, COMMAND_FLAG_SOURCE_HTTP); } } poststr(request, NULL); return 0; } int http_fn_cfg(http_request_t* request) { http_setup(request, httpMimeTypeHTML); http_html_start(request, "Config"); postFormAction(request, "cfg_pins", "Configure Module"); postFormAction(request, "cfg_generic", "Configure General/Flags"); postFormAction(request, "cfg_startup", "Configure Startup"); postFormAction(request, "cfg_dgr", "Configure Device Groups"); postFormAction(request, "cfg_wifi", "Configure WiFi & Web"); postFormAction(request, "cfg_ip", "Configure IP"); postFormAction(request, "cfg_mqtt", "Configure MQTT"); postFormAction(request, "cfg_name", "Configure Names"); postFormAction(request, "cfg_mac", "Change MAC"); postFormAction(request, "cfg_ping", "Ping Watchdog (Network lost restarter)"); postFormAction(request, "cfg_webapp", "Configure Webapp"); postFormAction(request, "ha_cfg", "Home Assistant Configuration"); postFormAction(request, "ota", "OTA (update software by WiFi)"); postFormAction(request, "cmd_tool", "Execute custom command"); //postFormAction(request, "flash_read_tool", "Flash Read Tool"); postFormAction(request, "startup_command", "Change startup command text"); #if 0 #if PLATFORM_BK7231T | PLATFORM_BK7231N { int i, j, k; k = config_get_tableOffsets(BK_PARTITION_NET_PARAM, &i, &j); hprintf255(request, "BK_PARTITION_NET_PARAM: bOk %i, at %i, len %i
", k, i, j); k = config_get_tableOffsets(BK_PARTITION_RF_FIRMWARE, &i, &j); hprintf255(request, "BK_PARTITION_RF_FIRMWARE: bOk %i, at %i, len %i
", k, i, j); k = config_get_tableOffsets(BK_PARTITION_OTA, &i, &j); hprintf255(request, "BK_PARTITION_OTA: bOk %i, at %i, len %i
", k, i, j); } #endif #endif poststr(request, htmlFooterReturnToMenu); http_html_end(request); poststr(request, NULL); return 0; } int http_fn_cfg_pins(http_request_t* request) { int iChanged = 0; int iChangedRequested = 0; int i; char tmpA[128]; char tmpB[64]; http_setup(request, httpMimeTypeHTML); http_html_start(request, "Pin config"); poststr(request, "

The first field assigns a role to the given pin. The next field is used to enter channel index (relay index), used to support multiple relays and buttons. "); poststr(request, "So, first button and first relay should have channel 1, second button and second relay have channel 2, etc.

"); poststr(request, "

Only for button roles another field will be provided to enter channel to toggle when doing double click. "); poststr(request, "It shows up when you change role to button and save.

"); #if PLATFORM_BK7231N || PLATFORM_BK7231T poststr(request, "

BK7231N/BK7231T supports PWM only on pins 6, 7, 8, 9, 24 and 26!

"); #endif for (i = 0; i < PLATFORM_GPIO_MAX; i++) { sprintf(tmpA, "%i", i); if (http_getArg(request->url, tmpA, tmpB, sizeof(tmpB))) { int role; int pr; iChangedRequested++; role = atoi(tmpB); pr = PIN_GetPinRoleForPinIndex(i); if (pr != role) { PIN_SetPinRoleForPinIndex(i, role); iChanged++; } } sprintf(tmpA, "r%i", i); if (http_getArg(request->url, tmpA, tmpB, sizeof(tmpB))) { int rel; int prevRel; iChangedRequested++; rel = atoi(tmpB); prevRel = PIN_GetPinChannelForPinIndex(i); if (prevRel != rel) { PIN_SetPinChannelForPinIndex(i, rel); iChanged++; } } sprintf(tmpA, "e%i", i); if (http_getArg(request->url, tmpA, tmpB, sizeof(tmpB))) { int rel; int prevRel; iChangedRequested++; rel = atoi(tmpB); prevRel = PIN_GetPinChannel2ForPinIndex(i); if (prevRel != rel) { PIN_SetPinChannel2ForPinIndex(i, rel); iChanged++; } } } if (iChangedRequested > 0) { // Anecdotally, if pins are configured badly, the // second-timer breaks. To reconfigure, force // saving the configuration instead of waiting. //CFG_Save_SetupTimer(); CFG_Save_IfThereArePendingChanges(); // Invoke Hass discovery if configuration has changed and not in safe mode. if (!bSafeMode && CFG_HasFlag(OBK_FLAG_AUTOMAIC_HASS_DISCOVERY)) { Main_ScheduleHomeAssistantDiscovery(1); } hprintf255(request, "Pins update - %i reqs, %i changed!

", iChangedRequested, iChanged); } // strcat(outbuf,""); poststr(request, "
"); for (i = 0; i < PLATFORM_GPIO_MAX; i++) { int si, ch, ch2; int j; const char* alias; // On BL602, any GPIO can be mapped to one of 5 PWM channels // But on Beken chips, only certain pins can be PWM int bCanThisPINbePWM; si = PIN_GetPinRoleForPinIndex(i); ch = PIN_GetPinChannelForPinIndex(i); ch2 = PIN_GetPinChannel2ForPinIndex(i); bCanThisPINbePWM = HAL_PIN_CanThisPinBePWM(i); // if available.. alias = HAL_PIN_GetPinNameAlias(i); poststr(request, "
"); if (alias) { #if defined(PLATFORM_BEKEN) || defined(WINDOWS) hprintf255(request, "P%i (%s) ", i, alias); #else poststr(request, alias); poststr(request, " "); #endif } else { hprintf255(request, "P%i ", i); } hprintf255(request, ""); // Primary linked channel // Some roles do not need any channels if ((si != IOR_SGP_CLK && si != IOR_SHT3X_CLK && si != IOR_CHT8305_CLK && si != IOR_Button_ToggleAll && si != IOR_Button_ToggleAll_n && si != IOR_BL0937_CF && si != IOR_BL0937_CF1 && si != IOR_BL0937_SEL && si != IOR_LED_WIFI && si != IOR_LED_WIFI_n && si != IOR_LED_WIFI_n && !(si >= IOR_IRRecv && si <= IOR_DHT11) && !(si >= IOR_SM2135_DAT && si <= IOR_BP1658CJ_CLK)) || IS_PIN_DHT_ROLE(si)) { hprintf255(request, "", i, ch); } // Secondary linked channel // For button, is relay index to toggle on double click if (si == IOR_Button || si == IOR_Button_n || IS_PIN_DHT_ROLE(si) || IS_PIN_TEMP_HUM_SENSOR_ROLE(si) || IS_PIN_AIR_SENSOR_ROLE(si)) { hprintf255(request, "", i, ch2); } poststr(request, "
"); } poststr(request, "
"); poststr(request, htmlFooterReturnToCfgLink); http_html_end(request); poststr(request, NULL); return 0; } const char* g_obk_flagNames[] = { "[MQTT] Broadcast led params together (send dimmer and color when dimmer or color changes, topic name: YourDevName/led_basecolor_rgb/get, YourDevName/led_dimmer/get)", "[MQTT] Broadcast led final color (topic name: YourDevName/led_finalcolor_rgb/get)", "[MQTT] Broadcast self state every N (def: 60) seconds (delay configurable by 'mqtt_broadcastInterval' and 'mqtt_broadcastItemsPerSec' commands)", "[LED][Debug] Show raw PWM controller on WWW index instead of new LED RGB/CW/etc picker", "[LED] Force show RGBCW controller (for example, for SM2135 LEDs, or for DGR sender)", "[CMD] Enable TCP console command server (for Putty, etc)", "[BTN] Instant touch reaction instead of waiting for release (aka SetOption 13)", "[MQTT] [Debug] Always set Retain flag to all published values", "[LED] Alternate CW light mode (first PWM for warm/cold slider, second for brightness)", "[SM2135] Use separate RGB/CW modes instead of writing all 5 values as RGB", "[MQTT] Broadcast self state on MQTT connect", "[PWM] BK7231 use 600hz instead of 1khz default", "[LED] Remember LED driver state (RGBCW, enable, brightness, temperature) after reboot", "[HTTP] Show actual PIN logic level for unconfigured pins", "[IR] Do MQTT publish (RAW STRING) for incoming IR data", "[IR] Allow 'unknown' protocol", "[MQTT] Broadcast led final color RGBCW (topic name: YourDevName/led_finalcolor_rgbcw/get)", "[LED] Automatically enable Light when changing brightness, color or temperature on WWW panel", "[LED] Smooth transitions for LED (EXPERIMENTAL)", "[MQTT] Always publish channels used by TuyaMCU", "[LED] Force RGB mode (3 PWMs for LEDs) and ignore futher PWMs if they are set", "[MQTT] Retain power channels (Relay channels, etc)", "[IR] Do MQTT publish (Tasmota JSON format) for incoming IR data", "[LED] Automatically enable Light on any change of brightness, color or temperature", "[LED] Emulate Cool White with RGB in device with four PWMS - Red is 0, Green 1, Blue 2, and Warm is 4", "[POWER] Allow negative current/power for power measurement (all chips, BL0937, BL0942, etc)", // On BL602, if marked, uses /dev/ttyS1, otherwise S0 // On Beken, if marked, uses UART2, otherwise UART1 "[UART] Use alternate UART for BL0942, CSE, TuyaMCU, etc", "[HASS] Invoke HomeAssistant discovery on change to ip address, configuration", "[LED] Setting RGB white (FFFFFF) enables temperature mode", "[NETIF] Use short device name as a hostname instead of a long name", "[MQTT] Enable Tasmota TELE etc publishes (for ioBroker etc)", "[UART] Enable UART command line", "[LED] Use old linear brightness mode, ignore gamma ramp", "[MQTT] Apply channel type multiplier on (if any) on channel value before publishing it", "[MQTT] In HA discovery, add relays as lights", "[HASS] Deactivate avty_t flag for sensor when publishing to HASS (permit to keep value). You must restart HASS discovery for change to take effect.", "[DRV] Deactivate Autostart of all drivers", "[WiFi] Quick connect to WiFi on reboot (TODO: check if it works for you and report on github)", "[Power] Set power and current to zero if all relays are open", "[MQTT] [Debug] Publish all channels (don't enable it, it will be publish all 64 possible channels on connect)", "[MQTT] Use kWh unit for energy consumption (total, last hour, today) instead of Wh", "[BTN] Ignore all button events (aka child lock)", "[DoorSensor] Invert state", "[TuyaMCU] Use queue", "[HTTP] Disable authentication in safe mode (not recommended)", "error", "error", }; int http_fn_cfg_generic(http_request_t* request) { int i; char tmpA[64]; char tmpB[64]; http_setup(request, httpMimeTypeHTML); http_html_start(request, "Generic config"); if (http_getArg(request->url, "boot_ok_delay", tmpA, sizeof(tmpA))) { i = atoi(tmpA); if (i <= 0) { poststr(request, "
Boot ok delay must be at least 1 second
"); i = 1; } hprintf255(request, "
Setting boot OK delay to %i
", i); CFG_SetBootOkSeconds(i); } if (http_getArg(request->url, "setFlags", tmpA, sizeof(tmpA))) { for (i = 0; i < OBK_TOTAL_FLAGS; i++) { int ni; sprintf(tmpB, "flag%i", i); if (http_getArg(request->url, tmpB, tmpA, sizeof(tmpA))) { ni = atoi(tmpA); } else { ni = 0; } //hprintf255(request, "
Setting flag %i to %i
", i, ni); CFG_SetFlag(i, ni); } } CFG_Save_IfThereArePendingChanges(); hprintf255(request, "

Flags (Current value=%i)

", CFG_GetFlags()); poststr(request, "
"); for (i = 0; i < OBK_TOTAL_FLAGS; i++) { const char* flagName = g_obk_flagNames[i]; /*
*/ hprintf255(request, "
", i, i, (CFG_HasFlag(i) ? " checked" : "")); //this is less that 128 char hprintf255(request, "
"); } poststr(request, ""); poststr(request, SUBMIT_AND_END_FORM); add_label_numeric_field(request, "Uptime seconds required to mark boot as ok", "boot_ok_delay", CFG_GetBootOkSeconds(), ""); poststr(request, "
"); poststr(request, htmlFooterReturnToCfgLink); http_html_end(request); poststr(request, NULL); return 0; } int http_fn_cfg_startup(http_request_t* request) { int channelIndex; int newValue; int i; char tmpA[128]; http_setup(request, httpMimeTypeHTML); http_html_start(request, "Config startup"); poststr_h4(request, "Here you can set pin start values"); poststr(request, ""); if (http_getArg(request->url, "idx", tmpA, sizeof(tmpA))) { channelIndex = atoi(tmpA); if (http_getArg(request->url, "value", tmpA, sizeof(tmpA))) { newValue = atoi(tmpA); CFG_SetChannelStartupValue(channelIndex, newValue); // also save current value if marked as saved Channel_SaveInFlashIfNeeded(channelIndex); hprintf255(request, "
Setting channel %i start value to %i
", channelIndex, newValue); CFG_Save_IfThereArePendingChanges(); } } poststr_h4(request, "New start values"); for (i = 0; i < CHANNEL_MAX; i++) { if (CHANNEL_IsInUse(i)) { int startValue = CFG_GetChannelStartupValue(i); poststr(request, "
"); hprintf255(request, "", i); sprintf(tmpA, "Channel %i", i); add_label_numeric_field(request, tmpA, "value", startValue, ""); poststr(request, "

"); } } poststr(request, htmlFooterReturnToCfgLink); http_html_end(request); poststr(request, NULL); return 0; } int http_fn_cfg_dgr(http_request_t* request) { char tmpA[128]; bool bForceSet; http_setup(request, httpMimeTypeHTML); http_html_start(request, "Device groups"); hprintf255(request, "
Here you can configure Tasmota Device Groups
"); if (http_getArg(request->url, "bSet", tmpA, sizeof(tmpA))) { bForceSet = true; } else { bForceSet = false; } if (http_getArg(request->url, "name", tmpA, sizeof(tmpA)) || bForceSet) { int newSendFlags; int newRecvFlags; newSendFlags = 0; newRecvFlags = 0; if (http_getArgInteger(request->url, "s_pwr")) newSendFlags |= DGR_SHARE_POWER; if (http_getArgInteger(request->url, "r_pwr")) newRecvFlags |= DGR_SHARE_POWER; if (http_getArgInteger(request->url, "s_lbr")) newSendFlags |= DGR_SHARE_LIGHT_BRI; if (http_getArgInteger(request->url, "r_lbr")) newRecvFlags |= DGR_SHARE_LIGHT_BRI; if (http_getArgInteger(request->url, "s_lcl")) newSendFlags |= DGR_SHARE_LIGHT_COLOR; if (http_getArgInteger(request->url, "r_lcl")) newRecvFlags |= DGR_SHARE_LIGHT_COLOR; CFG_DeviceGroups_SetName(tmpA); CFG_DeviceGroups_SetSendFlags(newSendFlags); CFG_DeviceGroups_SetRecvFlags(newRecvFlags); if (tmpA[0] != 0) { #ifndef OBK_DISABLE_ALL_DRIVERS DRV_StartDriver("DGR"); #endif } CFG_Save_IfThereArePendingChanges(); } { int newSendFlags; int newRecvFlags; const char* groupName = CFG_DeviceGroups_GetName(); newSendFlags = CFG_DeviceGroups_GetSendFlags(); newRecvFlags = CFG_DeviceGroups_GetRecvFlags(); add_label_text_field(request, "Group name", "name", groupName, "
"); poststr(request, "
"); poststr(request, " "); poststr(request, ""); poststr(request, " "); poststr(request, ""); poststr(request, " "); poststr(request, ""); poststr(request, "
NameTasmota CodeReceiveSend
Power1
Light Brightness2
Light Color16
"); poststr(request, SUBMIT_AND_END_FORM); } poststr(request, htmlFooterReturnToCfgLink); http_html_end(request); poststr(request, NULL); return 0; } void XR809_RequestOTAHTTP(const char* s); void OTA_RequestDownloadFromHTTP(const char* s) { #if WINDOWS #elif PLATFORM_BL602 #elif PLATFORM_W600 || PLATFORM_W800 t_http_fwup(s); #elif PLATFORM_XR809 XR809_RequestOTAHTTP(s); #else otarequest(s); #endif } int http_fn_ota_exec(http_request_t* request) { char tmpA[128]; //char tmpB[64]; http_setup(request, httpMimeTypeHTML); http_html_start(request, "OTA request"); if (http_getArg(request->url, "host", tmpA, sizeof(tmpA))) { hprintf255(request, "

OTA requested for %s!

", tmpA); addLogAdv(LOG_INFO, LOG_FEATURE_HTTP, "http_fn_ota_exec: will try to do OTA for %s \r\n", tmpA); OTA_RequestDownloadFromHTTP(tmpA); } poststr(request, htmlFooterReturnToMenu); http_html_end(request); poststr(request, NULL); return 0; } int http_fn_ota(http_request_t* request) { http_setup(request, httpMimeTypeHTML); http_html_start(request, "OTA system"); poststr(request, "

Simple OTA system (you should rather use the OTA from App panel where you can drag and drop file easily without setting up server). Use RBL file for OTA. In the OTA below, you should paste link to RBL file (you need HTTP server).

"); add_label_text_field(request, "URL for new bin file", "host", "", ""); poststr(request, "
\ \
"); poststr(request, htmlFooterReturnToMenu); http_html_end(request); poststr(request, NULL); return 0; } int http_fn_other(http_request_t* request) { http_setup(request, httpMimeTypeHTML); http_html_start(request, "Not found"); poststr(request, "Not found.
"); poststr(request, htmlFooterReturnToMenu); http_html_end(request); poststr(request, NULL); return 0; }