/* * ESPRESSIF MIT License * * Copyright (c) 2018 * * Permission is hereby granted for use on ESPRESSIF SYSTEMS products only, in which case, * it is free of charge, to any person obtaining a copy of this software and associated * documentation files (the "Software"), to deal in the Software without restriction, including * without limitation the rights to use, copy, modify, merge, publish, distribute, sublicense, * and/or sell copies of the Software, and to permit persons to whom the Software is furnished * to do so, subject to the following conditions: * * The above copyright notice and this permission notice shall be included in all copies or * substantial portions of the Software. * * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, FITNESS * FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR * COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER * IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN * CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE. * */ /* HomeKit Smart Outlet Example */ //#define USE_HOMEKIT #ifdef USE_HOMEKIT #ifdef ESP32 #include #include #include #include #include #include #include #include #include #include #include #include //#include //#include static const char *TAG = "HAP outlet"; char *hk_desc; char hk_code[12]; uint8_t hk_services; extern void Ext_Replace_Cmd_Vars(char *srcbuf, uint32_t srcsize, char *dstbuf, uint32_t dstsize); extern uint32_t Ext_UpdVar(char *vname, float *fvar, uint32_t mode); #define MAX_HAP_DEFS 16 struct HAP_DESC { char hap_name[24]; char var_name[12]; char var2_name[12]; char var3_name[12]; char var4_name[12]; uint8_t hap_cid; uint8_t type; hap_acc_t *accessory; hap_serv_t *service; } hap_devs[MAX_HAP_DEFS]; #define HK_SRCBSIZE 256 #define SMART_OUTLET_TASK_PRIORITY 1 #define SMART_OUTLET_TASK_STACKSIZE 4 * 1024 #define SMART_OUTLET_TASK_NAME "hap_outlet" //#define OUTLET_IN_USE_GPIO GPIO_NUM_0 #define OUTLET_IN_USE_GPIO -1 #define ESP_INTR_FLAG_DEFAULT 0 static xQueueHandle s_esp_evt_queue = NULL; /** * @brief the recover outlet in use gpio interrupt function */ static void IRAM_ATTR outlet_in_use_isr(void* arg) { uint32_t gpio_num = (uint32_t) arg; xQueueSendFromISR(s_esp_evt_queue, &gpio_num, NULL); } /** * Enable a GPIO Pin for Outlet in Use Detection */ static void outlet_in_use_key_init(uint32_t key_gpio_pin) { gpio_config_t io_conf; /* Interrupt for both the edges */ io_conf.intr_type = GPIO_INTR_ANYEDGE; /* Bit mask of the pins */ io_conf.pin_bit_mask = 1 << key_gpio_pin; /* Set as input mode */ io_conf.mode = GPIO_MODE_INPUT; /* Enable internal pull-up */ io_conf.pull_up_en = 1; /* Disable internal pull-down */ io_conf.pull_down_en = 0; /* Set the GPIO configuration */ gpio_config(&io_conf); /* Install gpio isr service */ gpio_install_isr_service(ESP_INTR_FLAG_DEFAULT); /* Hook isr handler for specified gpio pin */ gpio_isr_handler_add(key_gpio_pin, outlet_in_use_isr, (void*)key_gpio_pin); } /** * Initialize the Smart Outlet Hardware.Here, we just enebale the Outlet-In-Use detection. */ void smart_outlet_hardware_init(int32_t gpio_num) { s_esp_evt_queue = xQueueCreate(2, sizeof(uint32_t)); if (gpio_num < 0) return; if (s_esp_evt_queue != NULL) { outlet_in_use_key_init(gpio_num); } } static int bridge_identify(hap_acc_t *ha) { ESP_LOGI(TAG, "Bridge identified"); return HAP_SUCCESS; } static int accessory_identify(hap_acc_t *ha) { hap_serv_t *hs = hap_acc_get_serv_by_uuid(ha, HAP_SERV_UUID_ACCESSORY_INFORMATION); hap_char_t *hc = hap_serv_get_char_by_uuid(hs, HAP_CHAR_UUID_NAME); const hap_val_t *val = hap_char_get_val(hc); char *name = val->s; ESP_LOGI(TAG, "Bridged Accessory %s identified", name); return HAP_SUCCESS; } const struct HAP_CHAR_TABLE { char stype[4]; char ntype; int8_t index; } hap_rtab[] = { {HAP_CHAR_UUID_CURRENT_TEMPERATURE,'f',0}, {HAP_CHAR_UUID_CURRENT_RELATIVE_HUMIDITY,'f',0}, {HAP_CHAR_UUID_CURRENT_AMBIENT_LIGHT_LEVEL,'f',0}, {HAP_CHAR_UUID_BATTERY_LEVEL,'u',0}, {HAP_CHAR_UUID_STATUS_LOW_BATTERY,'b',1}, {HAP_CHAR_UUID_CHARGING_STATE,'b',2}, {HAP_CHAR_UUID_ON,'b',0}, {HAP_CHAR_UUID_HUE,'f',1}, {HAP_CHAR_UUID_SATURATION,'f',2}, {HAP_CHAR_UUID_BRIGHTNESS,'u',3}, {HAP_CHAR_UUID_COLOR_TEMPERATURE,'u',0}, {HAP_CHAR_UUID_CONTACT_SENSOR_STATE,'u',0}, {HAP_CHAR_UUID_WATTAGE,'f',0} }; #define ARRAY_SIZE(x) (sizeof(x) / sizeof((x)[0])) /* A dummy callback for handling a write on the "On" characteristic of Outlet. * In an actual accessory, this should control the hardware */ static int sensor_write(hap_write_data_t write_data[], int count, void *serv_priv, void *write_priv, uint32_t index) { int i, ret = HAP_SUCCESS; float fvar; hap_write_data_t *write; for (i = 0; i < count; i++) { write = &write_data[i]; bool found = false; const char *hcp = hap_char_get_type_uuid(write->hc); for (uint32_t cnt = 0; cnt < ARRAY_SIZE(hap_rtab); cnt++ ) { if (!strcmp(hcp, hap_rtab[cnt].stype)) { hap_char_update_val(write->hc, &(write->val)); switch (hap_rtab[cnt].ntype) { case 'f': fvar = write->val.f; break; case 'u': fvar = write->val.u; break; case 'b': fvar = write->val.b; break; } switch (hap_rtab[cnt].index) { case 0: Ext_UpdVar(hap_devs[index].var_name, &fvar, 1);break; case 1: Ext_UpdVar(hap_devs[index].var2_name, &fvar, 1);break; case 2: Ext_UpdVar(hap_devs[index].var3_name, &fvar, 1);break; case 3: Ext_UpdVar(hap_devs[index].var4_name, &fvar, 1);break; } *(write->status) = HAP_STATUS_SUCCESS; found = true; break; } } if (!found) { *(write->status) = HAP_STATUS_RES_ABSENT; } } return ret; } // common read routine static int sensor_read(hap_char_t *hc, hap_status_t *status_code, void *serv_priv, void *read_priv, uint32_t index) { hap_val_t new_val; float fvar = 0; if (hap_req_get_ctrl_id(read_priv)) { ESP_LOGI(TAG, "Received read from %s", hap_req_get_ctrl_id(read_priv)); } const char *hcp = hap_char_get_type_uuid(hc); printf("read values %s\n", hcp ); for (uint32_t cnt = 0; cnt < ARRAY_SIZE(hap_rtab); cnt++ ) { if (!strcmp(hcp, hap_rtab[cnt].stype)) { switch (hap_rtab[cnt].index) { case 0: Ext_UpdVar(hap_devs[index].var_name, &fvar, 0);break; case 1: Ext_UpdVar(hap_devs[index].var2_name, &fvar, 0);break; case 2: Ext_UpdVar(hap_devs[index].var3_name, &fvar, 0);break; case 3: Ext_UpdVar(hap_devs[index].var4_name, &fvar, 0);break; } switch (hap_rtab[cnt].ntype) { case 'f': new_val.f = fvar; break; case 'u': new_val.u = fvar; break; case 'b': new_val.b = fvar; break; } hap_char_update_val(hc, &new_val); *status_code = HAP_STATUS_SUCCESS; } } return HAP_SUCCESS; } // update values every 500 ms void hap_update_from_vars(void) { float fvar; hap_char_t *hc; hap_val_t new_val; for (uint32_t cnt = 0; cnt < hk_services; cnt++) { switch (hap_devs[cnt].hap_cid) { case HAP_CID_SENSOR: switch (hap_devs[cnt].type) { case 0: hc = hap_serv_get_char_by_uuid(hap_devs[cnt].service, HAP_CHAR_UUID_CURRENT_TEMPERATURE); if (Ext_UpdVar(hap_devs[cnt].var_name, &fvar, 0)) { new_val.f = fvar; hap_char_update_val(hc, &new_val); } break; case 1: hc = hap_serv_get_char_by_uuid(hap_devs[cnt].service, HAP_CHAR_UUID_CURRENT_RELATIVE_HUMIDITY); if (Ext_UpdVar(hap_devs[cnt].var_name, &fvar, 0)) { new_val.f = fvar; hap_char_update_val(hc, &new_val); } break; case 2: hc = hap_serv_get_char_by_uuid(hap_devs[cnt].service, HAP_CHAR_UUID_CURRENT_AMBIENT_LIGHT_LEVEL); if (Ext_UpdVar(hap_devs[cnt].var_name, &fvar, 0)) { new_val.f = fvar; hap_char_update_val(hc, &new_val); } break; case 3: hc = hap_serv_get_char_by_uuid(hap_devs[cnt].service, HAP_CHAR_UUID_BATTERY_LEVEL); if (Ext_UpdVar(hap_devs[cnt].var_name, &fvar, 0)) { new_val.u = fvar; hap_char_update_val(hc, &new_val); } hc = hap_serv_get_char_by_uuid(hap_devs[cnt].service, HAP_CHAR_UUID_STATUS_LOW_BATTERY); if (Ext_UpdVar(hap_devs[cnt].var2_name, &fvar, 0)) { new_val.u = fvar; hap_char_update_val(hc, &new_val); } hc = hap_serv_get_char_by_uuid(hap_devs[cnt].service, HAP_CHAR_UUID_STATUS_LOW_BATTERY); if (Ext_UpdVar(hap_devs[cnt].var3_name, &fvar, 0)) { new_val.u = fvar; hap_char_update_val(hc, &new_val); } break; case 4: hc = hap_serv_get_char_by_uuid(hap_devs[cnt].service, HAP_CHAR_UUID_CURRENT_AMBIENT_LIGHT_LEVEL); if (Ext_UpdVar(hap_devs[cnt].var_name, &fvar, 0)) { new_val.f = fvar; hap_char_update_val(hc, &new_val); } break; case 5: hc = hap_serv_get_char_by_uuid(hap_devs[cnt].service, HAP_CHAR_UUID_CONTACT_SENSOR_STATE); if (Ext_UpdVar(hap_devs[cnt].var_name, &fvar, 0)) { new_val.u = fvar; hap_char_update_val(hc, &new_val); } break; } break; case HAP_CID_OUTLET: hc = hap_serv_get_char_by_uuid(hap_devs[cnt].service, HAP_CHAR_UUID_ON); if (Ext_UpdVar(hap_devs[cnt].var_name, &fvar, 0)) { new_val.b = fvar; hap_char_update_val(hc, &new_val); } break; case HAP_CID_LIGHTING: hc = hap_serv_get_char_by_uuid(hap_devs[cnt].service, HAP_CHAR_UUID_ON); if (Ext_UpdVar(hap_devs[cnt].var_name, &fvar, 0)) { new_val.b = fvar; hap_char_update_val(hc, &new_val); } hc = hap_serv_get_char_by_uuid(hap_devs[cnt].service, HAP_CHAR_UUID_HUE); if (Ext_UpdVar(hap_devs[cnt].var2_name, &fvar, 0)) { new_val.f = fvar; hap_char_update_val(hc, &new_val); } hc = hap_serv_get_char_by_uuid(hap_devs[cnt].service, HAP_CHAR_UUID_SATURATION); if (Ext_UpdVar(hap_devs[cnt].var3_name, &fvar, 0)) { new_val.f = fvar; hap_char_update_val(hc, &new_val); } hc = hap_serv_get_char_by_uuid(hap_devs[cnt].service, HAP_CHAR_UUID_BRIGHTNESS); if (Ext_UpdVar(hap_devs[cnt].var4_name, &fvar, 0)) { new_val.u = fvar; hap_char_update_val(hc, &new_val); } break; } } } #define HAP_READ hap_char_t *hc, hap_status_t *status_code, void *serv_priv, void *read_priv) { return sensor_read(hc, status_code, serv_priv, read_priv static int sensor_read1(HAP_READ, 0);} static int sensor_read2(HAP_READ, 1);} static int sensor_read3(HAP_READ, 2);} static int sensor_read4(HAP_READ, 3);} static int sensor_read5(HAP_READ, 4);} static int sensor_read6(HAP_READ, 5);} static int sensor_read7(HAP_READ, 6);} static int sensor_read8(HAP_READ, 7);} static int sensor_read9(HAP_READ, 8);} static int sensor_read10(HAP_READ, 9);} static int sensor_read11(HAP_READ, 10);} static int sensor_read12(HAP_READ, 11);} static int sensor_read13(HAP_READ, 12);} static int sensor_read14(HAP_READ, 13);} static int sensor_read15(HAP_READ, 14);} static int sensor_read16(HAP_READ, 15);} void hap_set_read(hap_serv_t *service, uint32_t index) { switch (index) { case 0: hap_serv_set_read_cb(service, sensor_read1);break; case 1: hap_serv_set_read_cb(service, sensor_read2);break; case 2: hap_serv_set_read_cb(service, sensor_read3);break; case 3: hap_serv_set_read_cb(service, sensor_read4);break; case 4: hap_serv_set_read_cb(service, sensor_read5);break; case 5: hap_serv_set_read_cb(service, sensor_read6);break; case 6: hap_serv_set_read_cb(service, sensor_read7);break; case 7: hap_serv_set_read_cb(service, sensor_read8);break; case 8: hap_serv_set_read_cb(service, sensor_read9);break; case 9: hap_serv_set_read_cb(service, sensor_read10);break; case 10: hap_serv_set_read_cb(service, sensor_read11);break; case 11: hap_serv_set_read_cb(service, sensor_read12);break; case 12: hap_serv_set_read_cb(service, sensor_read13);break; case 13: hap_serv_set_read_cb(service, sensor_read14);break; case 14: hap_serv_set_read_cb(service, sensor_read15);break; case 15: hap_serv_set_read_cb(service, sensor_read16);break; } } #define HAP_WRITE hap_write_data_t write_data[], int count, void *serv_priv, void *write_priv) { return sensor_write(write_data, count, serv_priv, write_priv static int sensor_write1(HAP_WRITE, 0);} static int sensor_write2(HAP_WRITE, 1);} static int sensor_write3(HAP_WRITE, 2);} static int sensor_write4(HAP_WRITE, 3);} static int sensor_write5(HAP_WRITE, 4);} static int sensor_write6(HAP_WRITE, 5);} static int sensor_write7(HAP_WRITE, 6);} static int sensor_write8(HAP_WRITE, 7);} static int sensor_write9(HAP_WRITE, 8);} static int sensor_write10(HAP_WRITE, 9);} static int sensor_write11(HAP_WRITE, 10);} static int sensor_write12(HAP_WRITE, 11);} static int sensor_write13(HAP_WRITE, 12);} static int sensor_write14(HAP_WRITE, 13);} static int sensor_write15(HAP_WRITE, 14);} static int sensor_write16(HAP_WRITE, 15);} void hap_set_write(hap_serv_t *service, uint32_t index) { switch (index) { case 0: hap_serv_set_write_cb(service, sensor_write1);break; case 1: hap_serv_set_write_cb(service, sensor_write2);break; case 2: hap_serv_set_write_cb(service, sensor_write3);break; case 3: hap_serv_set_write_cb(service, sensor_write4);break; case 4: hap_serv_set_write_cb(service, sensor_write5);break; case 5: hap_serv_set_write_cb(service, sensor_write6);break; case 6: hap_serv_set_write_cb(service, sensor_write7);break; case 7: hap_serv_set_write_cb(service, sensor_write8);break; case 8: hap_serv_set_write_cb(service, sensor_write9);break; case 9: hap_serv_set_write_cb(service, sensor_write10);break; case 10: hap_serv_set_write_cb(service, sensor_write11);break; case 11: hap_serv_set_write_cb(service, sensor_write12);break; case 12: hap_serv_set_write_cb(service, sensor_write13);break; case 13: hap_serv_set_write_cb(service, sensor_write14);break; case 14: hap_serv_set_write_cb(service, sensor_write15);break; case 15: hap_serv_set_write_cb(service, sensor_write16);break; } } uint32_t HK_getlinelen(char *lp) { uint32_t cnt; for (cnt=0; cnt= 0) { hap_val_t appliance_value = { .b = true, }; /* Listen for Outlet-In-Use state change events. Other read/write functionality will be handled * by the HAP Core. * When the Outlet in Use GPIO goes low, it means Outlet is not in use. * When the Outlet in Use GPIO goes high, it means Outlet is in use. * Applications can define own logic as per their hardware. */ while (1) { if (xQueueReceive(s_esp_evt_queue, &io_num, portMAX_DELAY) == pdFALSE) { ESP_LOGI(TAG, "Outlet-In-Use trigger FAIL"); } else { appliance_value.b = gpio_get_level(io_num); /* If any state change is detected, update the Outlet In Use characteristic value */ hap_char_update_val(outlet_in_use, &appliance_value); ESP_LOGI(TAG, "Outlet-In-Use triggered [%d]", appliance_value.b); } } } else { // vTaskDelete(NULL); while (1) { delay(500); // hap_update_from_vars(); } } } #define HK_PASSCODE "111-11-111" int hap_loop_stop(void); extern void Ext_toLog(char *str); void homekit_main(char *desc, uint32_t flag ) { if (desc) { char *cp = desc; cp += 2; while (*cp == ' ') cp++; // "111-11-111" if (*cp == '*') { strlcpy(hk_code, HK_PASSCODE, 10); cp++; } else { uint32_t cnt; for (cnt = 0; cnt < 10; cnt++) { hk_code[cnt] = *cp++; } hk_code[cnt] = 0; } if (*cp != '\n') { printf("init error\n"); return; } cp++; hk_desc = cp; } else { if (flag == 99) { hap_loop_stop(); hap_reset_to_factory(); } else if (flag == 98) { hap_loop_stop(); // is just the folder in wrapper hap_platfrom_keystore_erase_partition(hap_platform_keystore_get_nvs_partition_name()); } else { hap_loop_stop(); } return; } if (!hk_desc) return; /* Create the application thread */ xTaskCreate(smart_outlet_thread_entry, SMART_OUTLET_TASK_NAME, SMART_OUTLET_TASK_STACKSIZE, NULL, SMART_OUTLET_TASK_PRIORITY, NULL); } #endif // ESP32 #endif // USE_HOMEKIT