localhorst/ESP32-Mesh-OTA
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base: localhorst:f1fb982e21013dab481abdefff9657450f128ee9
Branches Tags
localhorst:master localhorst:develop localhorst:feature/blockingOTA localhorst:feature/https_client localhorst:feature/mesh_network localhorst:feature/ota_https
...
compare: localhorst:feature/blockingOTA
Branches Tags
localhorst:master localhorst:develop localhorst:feature/blockingOTA localhorst:feature/https_client localhorst:feature/mesh_network localhorst:feature/ota_https

22 Commits
f1fb982e21 ... feature/bl

Author SHA1 Message Date
localhorst
7301305135 blocking OTA Tx and Rx 2021-01-20 10:23:41 +01:00
localhorst
57c71c401c OTA Tx and Rx over Mesh 2021-01-19 22:19:30 +01:00
localhorst
94aa8751cb Mesh OTA Master & Slave 2021-01-19 17:20:16 +01:00
localhorst
b274d939c4 OTA mesh worker 2021-01-19 12:36:21 +01:00
localhorst
6446049876 OTA message handle call and vAddAllNeighboursToQueue() 2021-01-18 22:56:42 +01:00
localhorst
88fd2c69a9 added OTA process mutex; progress log; reboot flag 2021-01-18 19:03:32 +01:00
localhorst
a0546aa3ef completet https ota 2021-01-18 17:38:08 +01:00
localhorst
c542dc05ab cleanup https ota 2021-01-18 12:49:52 +01:00
localhorst
cf99410893 added https ota code in task 2021-01-17 23:47:59 +01:00
localhorst
c6829f0483 added control for http_ota task 2021-01-17 23:27:01 +01:00
localhorst
62d16a437a completed demo app blinky_led 2021-01-16 18:23:10 +01:00
localhorst
62b9b1255f added app demo code 2021-01-16 00:23:02 +01:00
Hendrik Schutter
9b4b1d0443 Merge pull request 'feature/mesh_network' (#1) from feature/mesh_network into master 
Reviewed-on: #1
 2021-01-15 09:34:23 +01:00
Hendrik Schutter
0a32400a04 Merge branch 'master' into feature/mesh_network 2021-01-15 09:34:11 +01:00
localhorst
0289d3f1dd added mesh paket and ported to newer IDF 2021-01-14 23:08:45 +01:00
localhorst
c17756160f updated tests, changed file names, new mesh packet type 2021-01-11 22:56:39 +01:00
localhorst
d4182eddb2 format log output 2021-01-11 18:59:19 +01:00
localhorst
378f6e9ad0 cleanup 2021-01-11 18:31:37 +01:00
localhorst
1cdd9477c3 added new network module 2021-01-11 15:22:45 +01:00
localhorst
4ac270475b added image validation and signature 2021-01-10 14:03:50 +01:00
localhorst
0f38c893d9 cleanup 2021-01-09 17:41:40 +01:00
Hendrik Schutter
0244457d75 added WIP info 
added WIP info
 2020-12-02 18:04:03 +01:00
25 changed files with 2456 additions and 1892 deletions
Expand all files Collapse all files

3
.gitignore vendored
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@ -57,3 +57,6 @@ build/
test/build/ test/build/
*.old *.old
*.orig

17
README.md
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@ -1,2 +1,19 @@
# ESP32-Mesh-OTA # ESP32-Mesh-OTA
## Work in progress
<img src="https://patenschaft.bienenweide.org/img/loading.gif" alt="code_example_output" width="50"/>
## Todo for first release
### Refactoring
- architecture
- full error handling through all functions
- export as a component library
### Features
- root node: Download new Firmware from HTTPS server instead using newest ota partition
- add example main app

2
components/mesh_ota/CMakeLists.txt
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@ -1,4 +1,4 @@
idf_component_register(SRCS "https_client.c" "mesh_ota.c" idf_component_register(SRCS "HTTPS_client.c" "Mesh_network_handler.c" "Mesh_network.c" "Mesh_OTA.c"
INCLUDE_DIRS "include" INCLUDE_DIRS "include"
REQUIRES nvs_flash REQUIRES nvs_flash
esp_http_client esp_http_client

280
components/mesh_ota/HTTPS_client.c Normal file
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#include "HTTPS_client.h"
static const char *TAG = "https_client";
static const char *REQUEST = "GET " CONFIG_OTA_HTTPS_URL " HTTP/1.1\r\n"
"Host: "CONFIG_OTA_HTTPS_SERVER_COMMON_NAME"\r\n"
"User-Agent: esp-idf/1.0 esp32\r\n"
"Authorization: Basic " CONFIG_OTA_HTTPS_AUTH "\r\n"
"\r\n";
static HTTPS_Client_t sHTTPS_ClientConfig;
https_client_ret_t https_clientInitEmbedTLS();
https_client_ret_t errHTTPSClientConnectToServer();
https_client_ret_t errHTTPSClientValidateServer();
https_client_ret_t errHTTPSClientSendRequest();
https_client_ret_t errHTTPSClientInitialize()
{
https_client_ret_t i32RetHTTPClient = HTTPS_CLIENT_OK;
i32RetHTTPClient = https_clientInitEmbedTLS();
if (i32RetHTTPClient == HTTPS_CLIENT_ERROR_INIT_EMBEDTLS)
{
ESP_LOGE(TAG, "Unable to initialize EmbedTLS");
i32RetHTTPClient = HTTPS_CLIENT_ERROR;
}
return i32RetHTTPClient;
}
https_client_ret_t errHTTPSClientRetrieveData(char* pu8Data, uint32_t* pu32DataLenght, uint32_t* pu32BytesRead)
{
https_client_ret_t i32RetHTTPClient = HTTPS_CLIENT_OK;
int32_t i32RetRetrieveData = ESP_OK;
bool bRetriveData = true;
bzero(pu8Data, *pu32DataLenght);
*pu32BytesRead = 0U;
while (bRetriveData)
{
mbedtls_ssl_conf_read_timeout(&sHTTPS_ClientConfig.conf, HTTPS_READ_TIMEOUT); //set timeout
//Reading HTTP response
i32RetRetrieveData = mbedtls_ssl_read(&sHTTPS_ClientConfig.ssl, (unsigned char *)(pu8Data+(*pu32BytesRead)), ((*pu32DataLenght)-(*pu32BytesRead)));
if(i32RetRetrieveData > 0)
{
//Data received
*pu32BytesRead = *pu32BytesRead + i32RetRetrieveData;
if(*pu32DataLenght > 0)
{
//buffer not full yet --> read some more
bRetriveData = true;
}
else
{
//buffer full --> stop reading
bRetriveData = false;
}
}
if(i32RetRetrieveData == 0)
{
//all data read --> stop reading
bRetriveData = false;
pu32BytesRead = 0;
}
if(i32RetRetrieveData == MBEDTLS_ERR_SSL_TIMEOUT )
{
//timeout --> stop reading
bRetriveData = false;
}
if(i32RetRetrieveData == MBEDTLS_ERR_SSL_PEER_CLOSE_NOTIFY)
{
//connection is going to be closed
i32RetHTTPClient = HTTPS_CLIENT_ERROR;
bRetriveData = false;
}
}
return i32RetHTTPClient;
}
https_client_ret_t errHTTPSClientReset()
{
https_client_ret_t i32RetHTTPClient = HTTPS_CLIENT_OK;
i32RetHTTPClient = mbedtls_ssl_close_notify(&sHTTPS_ClientConfig.ssl); //close session
if(i32RetHTTPClient != ESP_OK)
{
ESP_LOGE(TAG, "mbedtls_ssl_close_notify returned 0x%x", i32RetHTTPClient);
}
mbedtls_ssl_session_reset(&sHTTPS_ClientConfig.ssl); //reset embedssl
mbedtls_net_free(&sHTTPS_ClientConfig.server_fd); //free ram
return i32RetHTTPClient;
}
https_client_ret_t https_clientInitEmbedTLS()
{
https_client_ret_t i32RetHTTPClient = HTTPS_CLIENT_OK;
int32_t i32RetEmbedTLS = ESP_OK;
static bool bAlreadySetup = false;
mbedtls_ssl_init(&sHTTPS_ClientConfig.ssl);
mbedtls_x509_crt_init(&sHTTPS_ClientConfig.cacert);
mbedtls_ctr_drbg_init(&sHTTPS_ClientConfig.ctr_drbg);
mbedtls_ssl_config_init(&sHTTPS_ClientConfig.conf);
mbedtls_entropy_init(&sHTTPS_ClientConfig.entropy);
i32RetEmbedTLS = mbedtls_ctr_drbg_seed(&sHTTPS_ClientConfig.ctr_drbg, mbedtls_entropy_func, &sHTTPS_ClientConfig.entropy, NULL, 0);
if(i32RetEmbedTLS!= ESP_OK)
{
ESP_LOGE(TAG, "mbedtls_ctr_drbg_seed returned %d", i32RetEmbedTLS);
}
if(i32RetEmbedTLS == ESP_OK)
{
//Attaching the certificate bundle
i32RetEmbedTLS = esp_crt_bundle_attach(&sHTTPS_ClientConfig.conf);
if(i32RetEmbedTLS != ESP_OK)
{
ESP_LOGE(TAG, "esp_crt_bundle_attach returned 0x%x\n\n", i32RetEmbedTLS);
}
}
if(i32RetEmbedTLS == ESP_OK)
{
//Setting hostname for TLS session.
i32RetEmbedTLS = mbedtls_ssl_set_hostname(&sHTTPS_ClientConfig.ssl, CONFIG_OTA_HTTPS_SERVER_COMMON_NAME);
// Hostname set here should match CN in server certificate
if(i32RetEmbedTLS != ESP_OK)
{
ESP_LOGE(TAG, "mbedtls_ssl_set_hostname returned 0x%x", i32RetEmbedTLS);
}
}
if(i32RetEmbedTLS == ESP_OK)
{
//Setting up the SSL/TLS structure
i32RetEmbedTLS = mbedtls_ssl_config_defaults(&sHTTPS_ClientConfig.conf,
MBEDTLS_SSL_IS_CLIENT,
MBEDTLS_SSL_TRANSPORT_STREAM,
MBEDTLS_SSL_PRESET_DEFAULT);
if(i32RetEmbedTLS != ESP_OK)
{
ESP_LOGE(TAG, "mbedtls_ssl_config_defaults returned %d", i32RetEmbedTLS);
}
}
if(i32RetEmbedTLS == ESP_OK)
{
mbedtls_ssl_conf_authmode(&sHTTPS_ClientConfig.conf, MBEDTLS_SSL_VERIFY_REQUIRED);
mbedtls_ssl_conf_ca_chain(&sHTTPS_ClientConfig.conf, &sHTTPS_ClientConfig.cacert, NULL);
mbedtls_ssl_conf_rng(&sHTTPS_ClientConfig.conf, mbedtls_ctr_drbg_random, &sHTTPS_ClientConfig.ctr_drbg);
if (bAlreadySetup == false) //check if mbedtls_ssl_setup was called before
{
i32RetEmbedTLS = mbedtls_ssl_setup(&sHTTPS_ClientConfig.ssl, &sHTTPS_ClientConfig.conf); //call this only once
if(i32RetEmbedTLS != ESP_OK)
{
ESP_LOGE(TAG, "mbedtls_ssl_setup returned 0x%x\n\n", i32RetEmbedTLS);
// uint8_t buffer[20];
//mbedtls_strerror(i32RetEmbedTLS, buffer, 20);
//ESP_LOGE(TAG, "%s", buffer);
}
else
{
bAlreadySetup = true;
}
}
}
if(i32RetEmbedTLS == ESP_OK)
{
mbedtls_net_init(&sHTTPS_ClientConfig.server_fd);
}
if (i32RetEmbedTLS != ESP_OK)
{
i32RetHTTPClient = HTTPS_CLIENT_ERROR_INIT_EMBEDTLS;
}
return i32RetHTTPClient;
}
https_client_ret_t errHTTPSClientConnectToServer()
{
https_client_ret_t i32RetHTTPClient = HTTPS_CLIENT_OK;
int32_t i32RetServerConnect = ESP_OK;
//Connecting to server
i32RetServerConnect = mbedtls_net_connect(&sHTTPS_ClientConfig.server_fd, CONFIG_OTA_HTTPS_SERVER_COMMON_NAME, CONFIG_OTA_HTTPS_SERVER_PORT, MBEDTLS_NET_PROTO_TCP);
if (i32RetServerConnect != ESP_OK)
{
ESP_LOGE(TAG, "mbedtls_net_connect returned %x", i32RetServerConnect);
}
if(i32RetServerConnect == ESP_OK)
{
mbedtls_ssl_set_bio(&sHTTPS_ClientConfig.ssl, &sHTTPS_ClientConfig.server_fd, mbedtls_net_send, mbedtls_net_recv, mbedtls_net_recv_timeout);
//Performing the SSL/TLS handshake
while ((i32RetServerConnect = mbedtls_ssl_handshake(&sHTTPS_ClientConfig.ssl)) != 0)
{
if ((i32RetServerConnect != MBEDTLS_ERR_SSL_WANT_READ) && (i32RetServerConnect != MBEDTLS_ERR_SSL_WANT_WRITE))
{
ESP_LOGE(TAG, "mbedtls_ssl_handshake returned 0x%x", i32RetServerConnect);
}
}
}
if(i32RetServerConnect != ESP_OK)
{
i32RetHTTPClient = HTTPS_CLIENT_ERROR_INIT_CONNECT_TWO_SERVER;
}
return i32RetHTTPClient;
}
https_client_ret_t errHTTPSClientValidateServer()
{
https_client_ret_t i32RetHTTPClient = HTTPS_CLIENT_OK;
int32_t i32RetValidateServer = ESP_OK;
//Verifying peer X.509 certificate
if ((i32RetValidateServer = mbedtls_ssl_get_verify_result(&sHTTPS_ClientConfig.ssl)) != 0)
{
ESP_LOGE(TAG, "Failed to verify peer certificate!");
}
if(i32RetValidateServer != ESP_OK)
{
i32RetHTTPClient = HTTPS_CLIENT_ERROR_INIT_VALIDATE_SERVER;
}
return i32RetHTTPClient;
}
https_client_ret_t errHTTPSClientSendRequest()
{
https_client_ret_t i32RetHTTPClient = HTTPS_CLIENT_OK;
int32_t i32RetSendRequest = ESP_OK;
uint32_t u32WrittenBytes = 0;
bool bWrite = true; //flag to stop loop
//Writing HTTP request
while((u32WrittenBytes < strlen(REQUEST)) && bWrite)
{
i32RetSendRequest = mbedtls_ssl_write(&sHTTPS_ClientConfig.ssl,
(const unsigned char *)REQUEST + u32WrittenBytes,
strlen(REQUEST) - u32WrittenBytes);
if (i32RetSendRequest >= 0)
{
//bytes written
u32WrittenBytes += i32RetSendRequest;
}
else if (i32RetSendRequest != MBEDTLS_ERR_SSL_WANT_WRITE && i32RetSendRequest != MBEDTLS_ERR_SSL_WANT_READ)
{
ESP_LOGE(TAG, "mbedtls_ssl_write returned 0x%x", i32RetSendRequest);
bWrite = false;
}
}
if(bWrite == false)
{
i32RetHTTPClient = HTTPS_CLIENT_ERROR_INIT_SEND_REQUEST;
}
return i32RetHTTPClient;
}

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components/mesh_ota/Mesh_OTA.c Normal file
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#include "Mesh_OTA.h"
static const char *LOG_TAG = "mesh_ota";
xQueueHandle queueNodes; //nodes that should be checked for ota update (contains children and parent)
xQueueHandle queueMessageOTA; //mesh ota controll messages like "OTA_Version_Response" "OTA_ACK"
SemaphoreHandle_t bsStartStopServerWorker; //binary semaphore
SemaphoreHandle_t bsOTAProcess; //binary semaphore
const esp_partition_t* pOTAPartition; //pointer to ota partition
bool bWantReboot; //flag to signal pending reboot
bool bOtaAbortTx = false;
esp_partition_t* pBootPartitionTx; //pointer to boot partition (that will booted after reset)
uint32_t u32OTABytesWrittenTx = 0U;
uint32_t u32SegmentCounterTx = 0U;
bool bNodeIsRespondingTx = false; //remote node is still active
esp_err_t errMeshOTAInitialize()
{
esp_err_t err = ESP_OK;
BaseType_t xReturned;
bWantReboot = false;
//create queue to store nodes for ota worker task
queueNodes = xQueueCreate(QUEUE_NODES_SIZE, sizeof(mesh_addr_t));
if (queueNodes == 0) // Queue not created
{
ESP_LOGE(LOG_TAG, "Unable to create Queue for Nodes");
err = ESP_FAIL;
}
if(err == ESP_OK)
{
//create queue to store ota messages
queueMessageOTA = xQueueCreate(QUEUE_MESSAGE_OTA_SIZE, sizeof(MESH_PACKET_t));
if (queueMessageOTA == 0) // Queue not created
{
ESP_LOGE(LOG_TAG, "Unable to create Queue for OTA Messages");
err = ESP_FAIL;
}
}
if(err == ESP_OK)
{
bsStartStopServerWorker = xSemaphoreCreateBinary();
if( bsStartStopServerWorker == NULL )
{
ESP_LOGE(LOG_TAG, "Unable to create Mutex to represent state of Server worker");
err = ESP_FAIL;
}
}
if(err == ESP_OK)
{
bsOTAProcess = xSemaphoreCreateBinary();
if( bsOTAProcess == NULL )
{
ESP_LOGE(LOG_TAG, "Unable to create Mutex to grant access to OTA Process");
err = ESP_FAIL;
}
}
if(err == ESP_OK)
{
xSemaphoreGive(bsOTAProcess); //unlock binary semaphore
if( bsOTAProcess == NULL )
{
ESP_LOGE(LOG_TAG, "Unable to unlock Mutex to grant access to OTA Process");
err = ESP_FAIL;
}
}
ERROR_CHECK(errMeshNetworkSetChildConnectedHandle(vAddNodeToPossibleUpdatableQueue));
ERROR_CHECK(errMeshNetworkSetOTAMessageHandle(vAddOTAControllMessageToQueue));
ERROR_CHECK(errMeshNetworkSetChangeStateOfServerWorkerHandle(vChangeStateOfServerWorker));
ERROR_CHECK(errMeshNetworkSetOtaDataHandle(vRecOtaDataHandler));
ERROR_CHECK(errMeshNetworkSetOtaAckHandle(vRecOtaAckHandler));
//ERROR_CHECK(errMeshNetworkSetOtaCompleteHandle(vRecOtaCompleteHandler));
// ERROR_CHECK(errMeshNetworkSetOtaAbortHandle(vRecOtaAbortHandler));
if(err == ESP_OK)
{
pOTAPartition = esp_ota_get_next_update_partition(NULL); //get ota partition
if(pOTAPartition == NULL)
{
err = ESP_FAIL;
ESP_LOGE(LOG_TAG, "unable to get next ota partition");
}
}
if(err == ESP_OK)
{
xReturned = xTaskCreate(vTaskServerWorker, "vTaskServerWorker", 8192, NULL, 5, NULL);
if(xReturned != pdPASS)
{
ESP_LOGE(LOG_TAG, "Unable to create the server worker task");
err = ESP_FAIL;
}
}
if(err == ESP_OK)
{
xReturned = xTaskCreate(vTaskOTAWorker, "vTaskOTAWorker", 8192, NULL, 5, NULL);
if(xReturned != pdPASS)
{
ESP_LOGE(LOG_TAG, "Unable to create the OTA worker task");
err = ESP_FAIL;
}
}
return err;
}
void vAddNodeToPossibleUpdatableQueue(uint8_t* pu8MAC)
{
//send payload to node queues
mesh_addr_t addrNode;
memcpy(&addrNode.addr, (uint8_t *)pu8MAC, 6); //copy MAC
if (xQueueSend(queueNodes, &addrNode, portMAX_DELAY) != pdPASS)
{
ESP_LOGE(LOG_TAG, "Unable to push node into node queue");
}
else
{
ESP_LOGI(LOG_TAG, "added node \"%x:%x:%x:%x:%x:%x\" to possible updatable queue", addrNode.addr[0], addrNode.addr[1], addrNode.addr[2], addrNode.addr[3], addrNode.addr[4], addrNode.addr[5]);
}
}
void vAddOTAControllMessageToQueue(MESH_PACKET_t* puMeshPacket)
{
//send ota packet to packet queue
if (xQueueSend(queueMessageOTA, puMeshPacket, portMAX_DELAY) != pdPASS)
{
ESP_LOGE(LOG_TAG, "Unable to push ota packet into packet queue");
}
else
{
ESP_LOGI(LOG_TAG, "added ota message to queue: %i (type)", puMeshPacket->type);
}
}
void vChangeStateOfServerWorker(bool bState) //allow access via function ptn to networl_handler
{
static bool bLastState = false;
if(bState != bLastState) //change only if necessary
{
ESP_LOGI(LOG_TAG, "server worker change handler");
if(bState == true)
{
if (xSemaphoreGive(bsStartStopServerWorker) != pdTRUE)
{
ESP_LOGE(LOG_TAG, "Unable to give mutex to activate the server worker");
}
}
else
{
if (xSemaphoreTake(bsStartStopServerWorker,( TickType_t ) 10 ) != pdTRUE)
{
ESP_LOGE(LOG_TAG, "Unable to obtain mutex to deactivate the server worker");
}
}
bLastState = bState;
}
}
void vTaskServerWorker(void *arg)
{
esp_err_t err;
bool bNewOTAImage; //true if a new ota image was downloaded and validated
bool bFirstRun = true;
while(true)
{
err = ESP_OK;
bNewOTAImage = false;
xSemaphoreTake(bsStartStopServerWorker, portMAX_DELAY); //wait for binary semaphore that allows to start the worker
xSemaphoreGive(bsStartStopServerWorker); //free binary semaphore, this allows the handler to change is to taken
if (esp_mesh_is_root()) //check again that this node is the root node
{
ESP_LOGI(LOG_TAG, "Checking firmware image on server");
if(bFirstRun == true)
{
ERROR_CHECK(errHTTPSClientInitialize());
bFirstRun = false;
}
ERROR_CHECK(errHTTPSClientConnectToServer());
ERROR_CHECK(errHTTPSClientValidateServer());
ERROR_CHECK(errHTTPSClientSendRequest());
ERROR_CHECK(errOTAHTTPS(&bNewOTAImage));
errHTTPSClientReset();
if(bNewOTAImage == true)
{
//set want reboot
ESP_LOGI(LOG_TAG, "Updated successfully via HTTPS, set pending reboot");
bWantReboot = true;
vAddAllNeighboursToQueue(); //add all existing neighbours to queue (aparent will not be added because this node is the root)
}
vTaskDelay( (SERVER_CHECK_INTERVAL*1000) / portTICK_PERIOD_MS); //sleep till next server checks
}
}
}
void vTaskOTAWorker(void *arg)
{
esp_err_t err = ESP_OK;
bool bNewOTAImage; //true if a new ota image was downloaded and validated
mesh_addr_t meshNodeAddr; //node that should be checked for ota update
while(true)
{
err = ESP_OK;
bNewOTAImage = false;
if((uxQueueSpacesAvailable(queueNodes) - QUEUE_NODES_SIZE) == 0)
{
//nodes queue is empty
ESP_LOGI(LOG_TAG, "nodes queue is empty");
if(bWantReboot == true)
{
ESP_LOGI(LOG_TAG, "ESP32 Reboot ...");
//vTaskDelay( (1000) / portTICK_PERIOD_MS);
//esp_restart();
}
ERROR_CHECK(errOTAMeshSlave(&bNewOTAImage));
}
else
{
//queue not empty
ESP_LOGI(LOG_TAG, "nodes queue not empty: %i", (QUEUE_NODES_SIZE - uxQueueSpacesAvailable(queueNodes)));
if (xQueueReceive(queueNodes, &meshNodeAddr, ((100) / portTICK_PERIOD_MS)) != pdTRUE)
{
ESP_LOGE(LOG_TAG, "Unable to receive OTA Messages from Queue");
err = ESP_FAIL;
}
ERROR_CHECK(errOTAMeshMaster(&bNewOTAImage, &meshNodeAddr));
if (err != ESP_OK)
{
//OTA process faild --> add back to queue
vAddNodeToPossibleUpdatableQueue(meshNodeAddr.addr);
}
}
if(bNewOTAImage == true)
{
//set want reboot
ESP_LOGI(LOG_TAG, "Updated successfully via Mesh, set pending reboot");
bWantReboot = true;
vAddAllNeighboursToQueue(); //add all existing neighbours to queue
}
vTaskDelay( (1000) / portTICK_PERIOD_MS); //TODO this is debug
}
}
esp_err_t errOTAHTTPS(bool* pbNewOTAImage)
{
esp_err_t err = ESP_OK;
char u8OTABuffer[OTA_HTTPS_SEGMENT_SIZE]; //store image segment from server before ota write
uint32_t u32BufferLenght = OTA_HTTPS_SEGMENT_SIZE; //size of buffer
uint32_t u32BytesRead = 0; //number of bytes that are read from server, <= u32BufferLenght
char pcRemoteVersionNumber[12]; //string for version number in server image
const esp_partition_t* pBootPartition; //pointer to boot partition (that will booted after reset)
static esp_ota_handle_t otaHandle; //OTA process handle
uint32_t u32StartOffset = 0U; //start offset for image (exclude the http response data)
esp_app_desc_t bootPartitionDesc; //Metadate from boot partition
uint32_t u32OTABytesWritten = 0U; //counter unsed for progress log
ERROR_CHECK(errHTTPSClientRetrieveData(u8OTABuffer, &u32BufferLenght, &u32BytesRead)); //read first bytes if image, including the version
ERROR_CHECK(errExtractVersionNumber(u8OTABuffer, &u32BytesRead, pcRemoteVersionNumber)); //extract version numbers
if(err == ESP_OK) //check if version number is found
{
xSemaphoreTake(bsOTAProcess, portMAX_DELAY); //wait for binary semaphore that allows to start the OTA process
pBootPartition = esp_ota_get_boot_partition(); //get boot partition (that will booted after reset), not the running partition
ERROR_CHECK(esp_ota_get_partition_description(pBootPartition, &bootPartitionDesc)); //get metadata of partition
if(bNewerVersion((bootPartitionDesc).version, pcRemoteVersionNumber)) //compare local and remote version
{
// server image is newer --> OTA update required
ESP_LOGI(LOG_TAG, "Server: image is newer --> OTA update required");
ERROR_CHECK(errFindImageStart(u8OTABuffer, &u32BufferLenght, &u32StartOffset)); //get image start offset
ERROR_CHECK(esp_ota_begin(pOTAPartition, OTA_SIZE_UNKNOWN, &otaHandle)); //start ota update process
if(err == ESP_OK)
{
//image download and ota partition write
ESP_LOGI(LOG_TAG, "start OTA download via HTTPS");
do
{
vPrintOTAProgress(&(pOTAPartition->size), &u32OTABytesWritten, Receiver);
ERROR_CHECK(esp_ota_write(otaHandle, (const void*) u8OTABuffer+u32StartOffset, (u32BytesRead-u32StartOffset)));
if(err == ESP_OK)
{
//write was succsesfull
u32StartOffset = 0U; //reset the offset for next download
ERROR_CHECK(errHTTPSClientRetrieveData(u8OTABuffer, &u32BufferLenght, &u32BytesRead)); //download next data segment
u32OTABytesWritten = u32OTABytesWritten + u32BytesRead; //update counter
}
}
while ((u32BytesRead > 0) && (err == ESP_OK) && (u32OTABytesWritten <= pOTAPartition->size)); //loop until error or complete image downloaded
}
if(err == ESP_OK)
{
//no error occurred --> finish ota update process
ERROR_CHECK(esp_ota_end(otaHandle)); //finish process
ERROR_CHECK(esp_ota_set_boot_partition(pOTAPartition)); //set new image as boot
if(err == ESP_OK)
{
*pbNewOTAImage = true; //image validated
}
}
else
{
//error occurred --> abort ota update process
ESP_LOGE(LOG_TAG, "abort ota process due to error 0x%x -> %s", err, esp_err_to_name(err));
ERROR_CHECK(esp_ota_abort(otaHandle));
*pbNewOTAImage = false; //ota update failed
}
}
else
{
ESP_LOGI(LOG_TAG, "server image is NOT newer --> OTA update NOT required");
}
xSemaphoreGive(bsOTAProcess); //free binary semaphore, this allows other tasks to start the OTA process
} //end version number extracted
return err;
}
esp_err_t errOTAMeshSlave(bool* pbNewOTAImage)
{
esp_err_t err = ESP_OK;
MESH_PACKET_t sOTAMessage;
const esp_partition_t* pBootPartition; //pointer to boot partition (that will booted after reset)
esp_app_desc_t bootPartitionDesc; //Metadate from boot partition
*pbNewOTAImage = false; //set default false
//read OTAMessages queue
if(uxQueueSpacesAvailable(queueMessageOTA) < QUEUE_MESSAGE_OTA_SIZE)
{
//queue not empty
if (xQueueReceive(queueMessageOTA, &sOTAMessage, ((100) / portTICK_PERIOD_MS)) != pdTRUE)
{
ESP_LOGE(LOG_TAG, "Unable to receive OTA Messages from Queue");
err = ESP_FAIL;
}
if((err == ESP_OK) && (sOTAMessage.type == OTA_Version_Request)) //if OTA_Version_Request
{
xSemaphoreTake(bsOTAProcess, portMAX_DELAY); //wait for binary semaphore that allows to start the OTA process
pBootPartition = esp_ota_get_boot_partition(); //get boot partition (that will booted after reset), not the running partition
ERROR_CHECK(esp_ota_get_partition_description(pBootPartition, &bootPartitionDesc)); //get metadata of partition
ESP_LOGI(LOG_TAG, "//send OTA_Version_Response to sender of OTA_Version_Request packet with version in payload");
ERROR_CHECK(errSendOTAVersionResponse(&sOTAMessage.meshSenderAddr));
if((bNewerVersion((bootPartitionDesc).version, (char*) sOTAMessage.au8Payload)) && (err == ESP_OK)) //compare local and remote version
{
//remote newer as local
ESP_LOGI(LOG_TAG, "remote image on node is newer --> OTA update required");
// --> this version older --> start OTA_Rx --> set pbNewOTAImage true
ERROR_CHECK(errOTAMeshReceive(pbNewOTAImage, &sOTAMessage.meshSenderAddr));
}
if((bNewerVersion((char*) sOTAMessage.au8Payload, (bootPartitionDesc).version)) && (err == ESP_OK)) //compare remote and local version
{
//local newer as remote
ESP_LOGI(LOG_TAG, "remote image on node is older --> OTA send required");
// --> this version newer --> start OTA_Tx
ERROR_CHECK(errOTAMeshTransmit(&sOTAMessage.meshSenderAddr));
}
xSemaphoreGive(bsOTAProcess); //free binary semaphore, this allows other tasks to start the OTA process
}
}
return err;
}
esp_err_t errOTAMeshMaster(bool* pbNewOTAImage, mesh_addr_t* pMeshNodeAddr)
{
esp_err_t err = ESP_OK;
MESH_PACKET_t sOTAMessage;
const esp_partition_t* pBootPartition; //pointer to boot partition (that will booted after reset)
esp_app_desc_t bootPartitionDesc; //Metadata from boot partition
bool bNodeIsConnected = false;
bool bNodeIsResponding = false;
*pbNewOTAImage = false; //set default false
if(bIsNodeNeighbour(pMeshNodeAddr) == true) //check if node is still connected
{
bNodeIsConnected = true; //node is one of the neighbours
xSemaphoreTake(bsOTAProcess, portMAX_DELAY); //wait for binary semaphore that allows to start the OTA process
ERROR_CHECK(errSendOTAVersionRequest(pMeshNodeAddr)); //send OTA_VERSION_REQUEST with local version in payload
for (uint32_t u32Index = 0; u32Index < QUEUE_MESSAGE_OTA_SIZE; u32Index++) //loop through all OTA messages
{
//if(uxQueueSpacesAvailable(queueMessageOTA) < QUEUE_MESSAGE_OTA_SIZE)
// {
//queue not empty
if (xQueueReceive(queueMessageOTA, &sOTAMessage, ((OTA_MESH_TIMEOUT) / portTICK_PERIOD_MS)) != pdTRUE)
{
ESP_LOGE(LOG_TAG, "Unable to receive OTA Messages from queue");
err = ESP_FAIL;
}
if((err == ESP_OK) && (sOTAMessage.type == OTA_Version_Response) && (bCheckMACEquality(sOTAMessage.meshSenderAddr.addr, pMeshNodeAddr->addr))) //if OTA_Version_Request
{
bNodeIsResponding = true;
u32Index = QUEUE_MESSAGE_OTA_SIZE; //this will exit the loop through all OTA messages
pBootPartition = esp_ota_get_boot_partition(); //get boot partition (that will booted after reset), not the running partition
ERROR_CHECK(esp_ota_get_partition_description(pBootPartition, &bootPartitionDesc)); //get metadata of partition
if((bNewerVersion((bootPartitionDesc).version, (char*) sOTAMessage.au8Payload)) && (err == ESP_OK)) //compare local and remote version
{
//remote newer as local
ESP_LOGI(LOG_TAG, "Mesh: remote image on node is newer --> OTA update required");
// --> this version older --> start OTA_Rx --> set pbNewOTAImage true
ERROR_CHECK(errOTAMeshReceive(pbNewOTAImage, &sOTAMessage.meshSenderAddr));
}
if((bNewerVersion((char*) sOTAMessage.au8Payload, (bootPartitionDesc).version)) && (err == ESP_OK)) //compare remote and local version
{
//local newer as remote
ESP_LOGI(LOG_TAG, "Mesh: remote image on node is older --> OTA send required");
// --> this version newer --> start OTA_Tx
ERROR_CHECK(errOTAMeshTransmit(&sOTAMessage.meshSenderAddr));
}
}
else if (err == ESP_OK)
{
ESP_LOGI(LOG_TAG, "//received from wrong node or type --> back to queue");
vAddOTAControllMessageToQueue(&sOTAMessage);
}
/* }
else
{
ESP_LOGI(LOG_TAG, "// OTA Message queue is empty --> wait some time");
vTaskDelay(OTA_MESH_TIMEOUT*u32Index / portTICK_PERIOD_MS);
}
*/
}//end loop
xSemaphoreGive(bsOTAProcess); //free binary semaphore, this allows other tasks to start the OTA process
}
if((bNodeIsResponding == false) && (bNodeIsConnected == true))
{
ESP_LOGI(LOG_TAG, "//add node back to queue if connected and NOT responding");
vAddNodeToPossibleUpdatableQueue(pMeshNodeAddr->addr);
}
return err;
}
bool bNewerVersion(const char* pu8Local, const char* pu8Remote)
{
/*
* Return true if remote version is newer (higher) than local version
*/
char u8LocalTmp[12]; //local version
char u8RemoteTmp[12]; //remote version
char* pu8saveptrLocal; //context for strok_r
char* pu8saveptrRemote; //context for strok_r
bool bReturn = false; //flag to stop loop
uint8_t u8Index = 0; //numbers counter in version string
strncpy(u8LocalTmp, pu8Local, 12); //copy in tmp
strncpy(u8RemoteTmp, pu8Remote, 12); //copy in tmp
char* pu8TokenLocal = strtok_r(u8LocalTmp, ".", &pu8saveptrLocal); //split tokens
char* pu8TokenRemote = strtok_r(u8RemoteTmp, ".", &pu8saveptrRemote); //split tokens
while( (u8Index <= 2) && (bReturn == false)) //loop through tokens
{
u8Index++;
if(atoi(pu8TokenLocal) < atoi(pu8TokenRemote))
{
bReturn = true; //version number difference --> stop loop
}
pu8TokenLocal = strtok_r(NULL, ".", &pu8saveptrLocal); //split tokens
pu8TokenRemote = strtok_r(NULL, ".", &pu8saveptrRemote); //split tokens
}
return bReturn;
}
esp_err_t errFindImageStart(const char* pu8Data, uint32_t* pu32DataLenght, uint32_t* pu32StartOffset)
{
/*
Offset value
0 = 0xE9 (first byte in image --> magic byte)
48 = first digit of version number
*/
esp_err_t errReturn = ESP_OK;
bool bImageStartOffsetFound = false;
uint32_t u32DataIndex = 0;
uint32_t u32FirstDotOffset = 0;
uint32_t u32SecondDotOffset = 0;
uint8_t u8FirstDotIndex = 0;
uint8_t u8SecondDotIndex = 0;
*pu32StartOffset = 0U; //reset offset to zero
while((u32DataIndex < *pu32DataLenght) && (bImageStartOffsetFound == false))
{
//search for magic byte
if(pu8Data[u32DataIndex] == 0xe9)
{
//magic byte found
while ((u8FirstDotIndex < 3) && (u32FirstDotOffset == 0))
{
//search first dot in version number
if((u32DataIndex+49+u8FirstDotIndex) < *pu32DataLenght)
{
if((pu8Data[(u32DataIndex+49+u8FirstDotIndex)] == 0x2e))
{
//first dot found
u32FirstDotOffset = (u32DataIndex+49+u8FirstDotIndex);
}
}
u8FirstDotIndex++;
}
while ((u8SecondDotIndex < 3) && (u32SecondDotOffset == 0) && (u32FirstDotOffset != 0))
{
//search first dot in version number
if((u32FirstDotOffset+(u8SecondDotIndex+2)) < *pu32DataLenght)
{
if((pu8Data[(u32FirstDotOffset+(u8SecondDotIndex+2))] == 0x2e))
{
//second dot found
u32SecondDotOffset = (u32FirstDotOffset+(u8SecondDotIndex+2));
}
}
u8SecondDotIndex++;
}
if((u32FirstDotOffset != 0) && (u32SecondDotOffset != 0))
{
//image start found based on magic byte and version number systax
*pu32StartOffset = u32DataIndex; //store image start offset
bImageStartOffsetFound = true;
}
else
{
// this is propably not the magic byte --> reset
u32FirstDotOffset = 0;
u32SecondDotOffset = 0;
u8FirstDotIndex = 0;
u8SecondDotIndex = 0;
}
}
u32DataIndex++;
}
if(bImageStartOffsetFound == false)
{
errReturn = ESP_ERR_NOT_FOUND;
}
return errReturn;
}
esp_err_t errExtractVersionNumber(const char* pu8Data, uint32_t* pu32DataLenght, char* pc8RemoteVersionNumber)
{
uint32_t u32StartOffset;
esp_err_t err = ESP_OK;
strcpy(pc8RemoteVersionNumber, "999.999.999"); //init value
err = errFindImageStart(pu8Data, pu32DataLenght, &u32StartOffset); //get image start offset
if(err == ESP_OK)
{
//image found
strncpy(pc8RemoteVersionNumber, pu8Data+(u32StartOffset+48), 11); //copy version number
pc8RemoteVersionNumber[12] = '\0';
}
return err;
}
void vPrintOTAProgress(const uint32_t* const pu32TotalImageSize, const uint32_t* const pu32BytesWritten, OTA_MESH_ROLE_t eRole)
{
uint32_t u32Percentage = 0U;
static uint32_t u32LastPercentage = 0U;
if((*pu32BytesWritten) >= (*pu32TotalImageSize))
{
u32Percentage = 100;
}
else
{
u32Percentage = (uint32_t) (((float) (*pu32BytesWritten)/(float) (*pu32TotalImageSize)) * 100.0);
}
if((u32Percentage-u32LastPercentage) >= OTA_PROGRESS_LOG_INTERVAL)
{
if(eRole == Transmitter)
{
ESP_LOGE(LOG_TAG, "Transmitting OTA update: %i %%", u32Percentage);
}
if(eRole == Receiver)
{
ESP_LOGE(LOG_TAG, "Receiving OTA update: %i %%", u32Percentage);
}
u32LastPercentage = u32Percentage;
}
}
void vAddAllNeighboursToQueue(void)
{
esp_err_t err = ESP_OK;
mesh_addr_t addrParent; //addr of parent node
mesh_addr_t childrenAddr[CONFIG_MESH_ROUTE_TABLE_SIZE]; //array of children attached to this node
uint16_t u16ChildrenSize = 0U; //number of children attached to this node
err = errGetParentNode(&addrParent);
if(err == ESP_OK)
{
vAddNodeToPossibleUpdatableQueue(addrParent.addr);
ESP_LOGI(LOG_TAG, "added parent");
}
err = ESP_OK; //reset error code
ERROR_CHECK(errGetChildren(childrenAddr, &u16ChildrenSize)); //get all children
for (uint16_t u16Index = 0; ((u16Index < u16ChildrenSize) && (err == ESP_OK)); u16Index++)
{
vAddNodeToPossibleUpdatableQueue(childrenAddr[u16Index].addr);
ESP_LOGI(LOG_TAG, "added child");
}
}
esp_err_t errSendOTAVersionResponse(mesh_addr_t* pMeshReceiverAddr)
{
esp_err_t err = ESP_OK;
MESH_PACKET_t packet;
packet.type = OTA_Version_Response;
const esp_partition_t* pBootPartition; //pointer to boot partition (that will booted after reset)
esp_app_desc_t bootPartitionDesc; //Metadata from boot partition
pBootPartition = esp_ota_get_boot_partition(); //get boot partition (that will booted after reset), not the running partition
ERROR_CHECK(esp_ota_get_partition_description(pBootPartition, &bootPartitionDesc)); //get metadate of partition
memcpy(&packet.au8Payload, &bootPartitionDesc.version, 12); //copy local version to OTA_Version_Response packet
err = errSendMeshPacket(pMeshReceiverAddr, &packet);
return err;
}
esp_err_t errSendOTAVersionRequest(mesh_addr_t* pMeshReceiverAddr)
{
esp_err_t err = ESP_OK;
MESH_PACKET_t packet;
packet.type = OTA_Version_Request;
const esp_partition_t* pBootPartition; //pointer to boot partition (that will booted after reset)
esp_app_desc_t bootPartitionDesc; //Metadata from boot partition
pBootPartition = esp_ota_get_boot_partition(); //get boot partition (that will booted after reset), not the running partition
ERROR_CHECK(esp_ota_get_partition_description(pBootPartition, &bootPartitionDesc)); //get metadate of partition
memcpy(&packet.au8Payload, &bootPartitionDesc.version, 12); //copy local version to OTA_Version_Request packet
err = errSendMeshPacket(pMeshReceiverAddr, &packet);
return err;
}
esp_err_t errOTAMeshTransmit(mesh_addr_t* pMeshNodeAddr)
{
esp_err_t err = ESP_OK;
//const esp_partition_t* pBootPartition; //pointer to boot partition (that will booted after reset)
MESH_PACKET_t sMeshPacket; //packet for sending and receiving
//uint32_t u32Index = 0U; //index for partition read offset
//bool bAbort = false; //abort the OTA process
//bool bNodeIsResponding = false; //remote node is still active
//uint32_t u32OTABytesWritten = 0U;
//uint32_t u32SegmentCounter = 0U;
pBootPartitionTx = esp_ota_get_boot_partition(); //get boot partition (that will booted after reset), not the running partition
u32OTABytesWrittenTx = 0U;
u32SegmentCounterTx = 0U;
bNodeIsRespondingTx = false; //remote node is still active
//loop through partition to read in segmensts until end or error or abort called
// while( ((OTA_MESH_SEGMENT_SIZE * u32SegmentCounter) < pBootPartition->size) && (err == ESP_OK) && (bAbort == false))
{
//bNodeIsResponding = false; //reset to default
/*
ESP_LOGI(LOG_TAG, "// read partition with offset based in index");
ERROR_CHECK(esp_partition_read(pBootPartition, (OTA_MESH_SEGMENT_SIZE * u32Index), sMeshPacket.au8Payload, OTA_MESH_SEGMENT_SIZE));
u32OTABytesWritten = ((u32SegmentCounter+1) * OTA_MESH_SEGMENT_SIZE);
vPrintOTAProgress(&(pBootPartition->size), &u32OTABytesWritten, Transmitter);
if(err == ESP_OK)
{
//ESP_LOGI(LOG_TAG, "//no error while read --> send OTA_DATA packet");
sMeshPacket.type = OTA_Data;
if((OTA_MESH_SEGMENT_SIZE * (u32SegmentCounter+1)) >= pBootPartition->size) //check if last segment
{
ESP_LOGI(LOG_TAG, "//last partition image segment --> send OTA_Complete");
sMeshPacket.type = OTA_Complete;
ESP_LOGE(LOG_TAG, "u32SegmentCounter: %i", u32SegmentCounter);
}
err = errSendMeshPacket(pMeshNodeAddr, &sMeshPacket);
}
else
{
ESP_LOGI(LOG_TAG, "// error while read --> send OTA_ABORT and abort this OTA process");
sMeshPacket.type = OTA_Abort;
bAbort = true;
errSendMeshPacket(pMeshNodeAddr, &sMeshPacket);
}
*/
// loop through all OTA messages or until abort is called or error
for (uint32_t u32Index = 0; ((u32Index < QUEUE_MESSAGE_OTA_SIZE) && (bOtaAbortTx == false)); u32Index++) //loop through all OTA messages
{
// if(uxQueueSpacesAvailable(queueMessageOTA) < QUEUE_MESSAGE_OTA_SIZE)
// {
//queue not empty
if (xQueueReceive(queueMessageOTA, &sMeshPacket, ((OTA_MESH_TIMEOUT) / portTICK_PERIOD_MS)) != pdTRUE)
{
ESP_LOGE(LOG_TAG, "Unable to receive OTA Messages from queue");
err = ESP_FAIL;
}
if((err == ESP_OK) && (bCheckMACEquality(sMeshPacket.meshSenderAddr.addr, pMeshNodeAddr->addr))) //if OTA_Version_Request
{
ESP_LOGI(LOG_TAG, "//packet from node received");
switch (sMeshPacket.type)
{
case OTA_Abort: //abort this OTA process
bOtaAbortTx = true;
bNodeIsRespondingTx = true;
break;
default:
ESP_LOGI(LOG_TAG, "//receives wrong OTA message type from node --> back to queue");
vAddOTAControllMessageToQueue(&sMeshPacket);
break;
}
}
else if (err == ESP_OK)
{
ESP_LOGI(LOG_TAG, "//received from wrong node --> back to queue");
vAddOTAControllMessageToQueue(&sMeshPacket);
if(bNodeIsRespondingTx == false)
{
ESP_LOGI(LOG_TAG, "//no abort was called but node didnt responded");
bOtaAbortTx = true;
err = ESP_FAIL; //this OTA process failed with error
}
else
{
bNodeIsRespondingTx = false;
}
}
// }
// else
//{
// ESP_LOGI(LOG_TAG, "// OTA Message queue is empty --> wait some time");
//vTaskDelay(OTA_MESH_TIMEOUT*u32Index/ portTICK_PERIOD_MS);
// }
}//end OTA message loop
}
// u32SegmentCounter++;
//}//end of partition segment loop
return err;
}
esp_err_t errOTAMeshReceive(bool* pbNewOTAImage, mesh_addr_t* pMeshNodeAddr)
{
esp_err_t err = ESP_OK;
MESH_PACKET_t sMeshPacket; //packet for sending and receiving
bool bComplete = false; //complete the OTA process
bool bAbort = false; //abort the OTA process
bool bNodeIsResponding = false; //remote node is still active
uint32_t u32OTABytesWritten = 0U; //counter unsed for progress log
static esp_ota_handle_t otaHandle; //OTA process handle
*pbNewOTAImage = false;
uint32_t u32SegmentCounter = 0U;
ERROR_CHECK(esp_ota_begin(pOTAPartition, OTA_SIZE_UNKNOWN, &otaHandle)); //start ota update process
//partition segement loop through partition to read in segmensts until end or error or abort called
while((bComplete == false) && (err == ESP_OK) && (bAbort == false) && (u32OTABytesWritten <= pOTAPartition->size))
{
bNodeIsResponding = false; //reset to default
// loop through all OTA messages or until abort is called
for (uint32_t u32Index = 0; ((u32Index < QUEUE_MESSAGE_OTA_SIZE) && (bAbort == false)); u32Index++) //loop through all OTA messages
{
//if(uxQueueSpacesAvailable(queueMessageOTA) < QUEUE_MESSAGE_OTA_SIZE)
// {
//queue not empty
if (xQueueReceive(queueMessageOTA, &sMeshPacket, ((OTA_MESH_TIMEOUT) / portTICK_PERIOD_MS)) != pdTRUE)
{
ESP_LOGE(LOG_TAG, "Unable to receive OTA Messages from queue");
err = ESP_FAIL;
}
if((err == ESP_OK) && (bCheckMACEquality(sMeshPacket.meshSenderAddr.addr, pMeshNodeAddr->addr))) //if OTA_Version_Request
{
ESP_LOGI(LOG_TAG, "//packet from node received");
switch (sMeshPacket.type)
{
case OTA_Complete:
ESP_LOGI(LOG_TAG, "//signal end of this OTA process, fall through because same behavior as OTA_Data");
bComplete = true;
ESP_LOGE(LOG_TAG, "after rec:Complete u32SegmentCounter: %i", u32SegmentCounter);
//fall through
case OTA_Data:
ESP_LOGI(LOG_TAG, "//data segement received");
bNodeIsResponding = true;
u32Index = QUEUE_MESSAGE_OTA_SIZE; //this will exit the loop through all OTA messages
ERROR_CHECK(esp_ota_write(otaHandle, sMeshPacket.au8Payload, OTA_MESH_SEGMENT_SIZE));
if(err != ESP_OK)
{
ESP_LOGE(LOG_TAG, "write error - Segement: %i", u32SegmentCounter);
}
u32OTABytesWritten = ((u32SegmentCounter+1) * OTA_MESH_SEGMENT_SIZE);
vPrintOTAProgress(&(pOTAPartition->size), &u32OTABytesWritten, Receiver);
break;
case OTA_Abort: //abort this OTA process
bAbort = true;
bNodeIsResponding = true;
break;
default:
ESP_LOGI(LOG_TAG, "//receives wrong OTA message type from node --> back to queue");
vAddOTAControllMessageToQueue(&sMeshPacket);
break;
}
}
else if (err == ESP_OK)
{
ESP_LOGI(LOG_TAG, "//received from wrong node --> back to queue");
vAddOTAControllMessageToQueue(&sMeshPacket);
}
// }
// else
// {
// ESP_LOGI(LOG_TAG, "// OTA Message queue is empty --> wait some time");
// vTaskDelay((OTA_MESH_TIMEOUT*u32Index) / portTICK_PERIOD_MS);
// }
}//end of OTA message loop
if(bNodeIsResponding == false)
{
ESP_LOGI(LOG_TAG, "//no abort was called but node didnt responded --> error");
bAbort = true; //this will stop the partition segement loop
err = ESP_FAIL; //this OTA process failed with error
}
else
{
ESP_LOGI(LOG_TAG, "//node has responded with OTA_DATA or OTA_Complete or OTA_ABORT");
if(err == ESP_OK)
{
if((bAbort == false) && (bComplete == false))
{
ESP_LOGI(LOG_TAG, "//no error while ota write --> send OTA_ACK packet");
sMeshPacket.type = OTA_ACK;
err = errSendMeshPacket(pMeshNodeAddr, &sMeshPacket);
}
}
else if (bComplete == false)
{
ESP_LOGI(LOG_TAG, "// error while read --> send OTA_ABORT and abort this OTA process");
sMeshPacket.type = OTA_Abort;
bAbort = true;
errSendMeshPacket(pMeshNodeAddr, &sMeshPacket);
}
}
u32SegmentCounter++;
}//end of partition segement loop
if(bComplete == true)
{
ESP_LOGI(LOG_TAG, "//all OTA segments received --> validate");
ERROR_CHECK(esp_ota_end(otaHandle));
ERROR_CHECK(esp_ota_set_boot_partition(pOTAPartition));
if(err == ESP_OK)
{
ESP_LOGI(LOG_TAG, "//successfully updated OTA partition");
*pbNewOTAImage = true;
}
}
else
{
ESP_LOGI(LOG_TAG, "//not all OTA segments received --> abort this OTA process");
ERROR_CHECK(esp_ota_abort(otaHandle));
}
return err;
}
void vRecOtaDataHandler(MESH_PACKET_t* puMeshPacket)
{
if(bOtaAbortTx == false)
{
}
}
void vRecOtaAckHandler(MESH_PACKET_t* puMeshPacket)
{
esp_err_t err = ESP_OK;
MESH_PACKET_t sMeshPacket; //packet for sending and receiving
if(bOtaAbortTx == false)
{
//sender node == ota node ?
bNodeIsRespondingTx = true;
ESP_LOGI(LOG_TAG, "// read partition with offset based in index");
ERROR_CHECK(esp_partition_read(pBootPartitionTx, (OTA_MESH_SEGMENT_SIZE * u32SegmentCounterTx), sMeshPacket.au8Payload, OTA_MESH_SEGMENT_SIZE));
u32OTABytesWrittenTx = ((u32SegmentCounterTx+1) * OTA_MESH_SEGMENT_SIZE);
vPrintOTAProgress(&(pBootPartitionTx->size), &u32OTABytesWrittenTx, Transmitter);
sMeshPacket.type = OTA_Data;
if(err != ESP_OK)
{
bOtaAbortTx = true;
sMeshPacket.type = OTA_Abort;
}
if((OTA_MESH_SEGMENT_SIZE * (u32SegmentCounterTx+1)) >= pBootPartitionTx->size) //check if last segment
{
ESP_LOGI(LOG_TAG, "//last partition image segment --> send OTA_Complete");
sMeshPacket.type = OTA_Complete;
ESP_LOGE(LOG_TAG, "u32SegmentCounterTx: %i", u32SegmentCounterTx);
}
err = errSendMeshPacket(&puMeshPacket->meshSenderAddr, &sMeshPacket);
u32SegmentCounterTx++;
}
}
/*
void vRecOtaCompleteHandler(MESH_PACKET_t* puMeshPacket)
{
return;
}
void vRecOtaAbortHandler(MESH_PACKET_t* puMeshPacket)
{
return;
}
*/

376
components/mesh_ota/Mesh_network.c Normal file
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#include "Mesh_OTA.h"
static const char *LOG_TAG = "mesh_network";
static uint8_t tx_buf[CONFIG_MESH_MESSAGE_SIZE] = { 0, };
static uint8_t rx_buf[CONFIG_MESH_MESSAGE_SIZE] = { 0, };
uint8_t u8ownMAC[6];
esp_netif_t* netif_sta;
bool bIsMeshConnected;
int32_t i32MeshLayer;
mesh_addr_t meshParentAddr;
void (*pAppRxHandle)(uint8_t*, uint8_t* );
void (*pOTAChildConnectHandle)(uint8_t* );
void (*pOTAMessageHandle)(MESH_PACKET_t* );
void (*pChangeStateOfServerWorkerHandle)(bool );
void (*pOtaDataHandle)(MESH_PACKET_t* );
void (*pOtaAckHandle)(MESH_PACKET_t* );
void (*pOtaCompleteHandle)(MESH_PACKET_t* );
void (*pOtaAbortHandle)(MESH_PACKET_t* );
esp_err_t errMeshNetworkInitialize()
{
//init module variables
esp_err_t err;
bIsMeshConnected = false;
i32MeshLayer = -1;
netif_sta = NULL;
err = nvs_flash_init(); //init non-volatile storage
#ifdef ERASE_NVS
if(err == ESP_ERR_NVS_NO_FREE_PAGES) //check if storage is full
{
ERROR_CHECK(nvs_flash_erase());
}
#endif
// tcpip initialization
ERROR_CHECK(esp_netif_init());
//event initialization
ERROR_CHECK(esp_event_loop_create_default());
//create network interfaces for mesh (only station instance saved for further manipulation, soft AP instance ignored
ERROR_CHECK(esp_netif_create_default_wifi_mesh_netifs(&netif_sta, NULL));
//wifi initialization
ERROR_CHECK(errMeshNetworkInitializeWiFi());
//mesh initialization
ERROR_CHECK(esp_mesh_init());
//mesh initialization
ERROR_CHECK(esp_event_handler_register(MESH_EVENT, ESP_EVENT_ANY_ID, &vMeshEventHandler, NULL));
//set mesh topology
ERROR_CHECK(esp_mesh_set_topology(CONFIG_MESH_TOPOLOGY));
//set mesh max layer according to the topology
ERROR_CHECK(esp_mesh_set_max_layer(CONFIG_MESH_MAX_LAYER));
ERROR_CHECK(esp_mesh_set_vote_percentage(1));
ERROR_CHECK(esp_mesh_set_xon_qsize(128));
//Disable mesh PS function
ERROR_CHECK(esp_mesh_disable_ps());
ERROR_CHECK(esp_mesh_set_ap_assoc_expire(10));
mesh_cfg_t cfg = MESH_INIT_CONFIG_DEFAULT();
/* mesh ID */
memcpy((uint8_t *) &cfg.mesh_id, CONFIG_MESH_ID, 6);
ERROR_CHECK(errMeshNetworkInitializeRouter(&cfg));
/* mesh softAP */
ERROR_CHECK(esp_mesh_set_ap_authmode(CONFIG_MESH_AP_AUTHMODE));
cfg.mesh_ap.max_connection = CONFIG_MESH_AP_CONNECTIONS;
memcpy((uint8_t *) &cfg.mesh_ap.password, CONFIG_MESH_AP_PASSWD,
strlen(CONFIG_MESH_AP_PASSWD));
ERROR_CHECK(esp_mesh_set_config(&cfg));
/* mesh start */
ERROR_CHECK(esp_mesh_start());
ERROR_CHECK(esp_base_mac_addr_get(u8ownMAC))
//debug info
ESP_LOGD(LOG_TAG, "mesh starts successfully, heap:%d, %s<%d>%s, ps:%d\n", esp_get_minimum_free_heap_size(),
esp_mesh_is_root_fixed() ? "root fixed" : "root not fixed",
esp_mesh_get_topology(), esp_mesh_get_topology() ? "(chain)":"(tree)", esp_mesh_is_ps_enabled());
ESP_LOGI(LOG_TAG, "Node MAC: \"%x:%x:%x:%x:%x:%x\" ", u8ownMAC[0], u8ownMAC[1], u8ownMAC[2], u8ownMAC[3], u8ownMAC[4], u8ownMAC[5]);
return ESP_OK;
}
esp_err_t errMeshNetworkInitializeWiFi()
{
//wifi initialization
esp_err_t err = ESP_OK;
wifi_init_config_t config = WIFI_INIT_CONFIG_DEFAULT();
ERROR_CHECK(esp_wifi_init(&config));
ERROR_CHECK(esp_event_handler_register(IP_EVENT, IP_EVENT_STA_GOT_IP, &vIPEventHandler, NULL));
ERROR_CHECK(esp_wifi_set_storage(WIFI_STORAGE_FLASH));
ERROR_CHECK(esp_wifi_start());
return err;
}
esp_err_t errMeshNetworkInitializeRouter(mesh_cfg_t* cfg)
{
//router initialization
esp_err_t err = ESP_OK;
(*cfg).channel = CONFIG_MESH_CHANNEL;
(*cfg).router.ssid_len = strlen(CONFIG_MESH_ROUTER_SSID);
memcpy((uint8_t *) &(*cfg).router.ssid, CONFIG_MESH_ROUTER_SSID, (*cfg).router.ssid_len);
memcpy((uint8_t *) &(*cfg).router.password, CONFIG_MESH_ROUTER_PASSWD,
strlen(CONFIG_MESH_ROUTER_PASSWD));
return err;
}
//returns true if MAC address is equal
bool bCheckMACEquality(uint8_t* pu8aMAC, uint8_t* pu8bMAC)
{
bool bRet = true;
uint8_t index = 0;
while ((index < 6) && (bRet == true))
{
if(pu8aMAC[index] != pu8bMAC[index])
{
bRet = false;
}
index++;
}
return bRet;
}
esp_err_t errGetChildren(mesh_addr_t* pChildren, uint16_t* pu16ChildrenSize)
{
esp_err_t err = ESP_OK;
int route_table_size = 0;
*pu16ChildrenSize = 0;
mesh_addr_t route_table[CONFIG_MESH_ROUTE_TABLE_SIZE];
ERROR_CHECK(esp_mesh_get_routing_table((mesh_addr_t *) &route_table, (CONFIG_MESH_ROUTE_TABLE_SIZE * 6), &route_table_size));
if (err == ESP_OK)
{
for(uint16_t index = 0; index < esp_mesh_get_routing_table_size(); index++)
{
if(! (bCheckMACEquality(u8ownMAC, route_table[index].addr)) )
{
//child node
//ESP_LOGI(LOG_TAG, "adding Node: \"0x%x, 0x%x, 0x%x, 0x%x, 0x%x, 0x%x\" ", route_table[index].addr[0], route_table[index].addr[1], route_table[index].addr[2], route_table[index].addr[3], route_table[index].addr[4], route_table[index].addr[5]);
pChildren[*pu16ChildrenSize] = route_table[index];
*pu16ChildrenSize = (*pu16ChildrenSize)+1;
}
}
}
return err;
}
esp_err_t errGetParentNode(mesh_addr_t* pMeshParentAddr)
{
esp_err_t err = ESP_OK;
if((bIsMeshConnected == false) || (esp_mesh_is_root()))
{
//this node is not connected or is the root --> this node has no parent
err = ESP_FAIL;
}
else
{
//node has parent
memcpy(pMeshParentAddr, &meshParentAddr, sizeof(mesh_addr_t));
}
return err;
}
void vGetOwnAddr(mesh_addr_t* pMeshOwnAddr)
{
memcpy(pMeshOwnAddr->addr, u8ownMAC, 6);
}
bool bIsRootNode()
{
return esp_mesh_is_root();
}
bool bIsNodeNeighbour(mesh_addr_t* pNode)
{
esp_err_t err = ESP_OK;
bool bReturn = false;
mesh_addr_t addrParent; //addr of parent node
mesh_addr_t childrenAddr[CONFIG_MESH_ROUTE_TABLE_SIZE]; //array of children attached to this node
uint16_t u16ChildrenSize = 0U; //number of children attached to this node
err = errGetParentNode(&addrParent);
if(err == ESP_OK)
{
if(bCheckMACEquality(pNode->addr, addrParent.addr) == true)
{
bReturn = true; //node was found
}
}
if(bReturn == false)
{
err = ESP_OK; //reset error code
ERROR_CHECK(errGetChildren(childrenAddr, &u16ChildrenSize)); //get all children
for (uint16_t u16Index = 0; ((u16Index < u16ChildrenSize) && (err == ESP_OK) && (bReturn == false)); u16Index++)
{
if(bCheckMACEquality(pNode->addr, childrenAddr[u16Index].addr) == true)
{
bReturn = true; //node was found
}
}
}
return bReturn;
}
esp_err_t errMeshNetworkSetAppReceiveHandle(void (*pAppRxHandleTmp)(uint8_t * pu8Data, uint8_t* pu8Sender))
{
pAppRxHandle = pAppRxHandleTmp; //set handle from app as receive handle if an app packet is received
return ESP_OK;
}
esp_err_t errMeshNetworkSetChildConnectedHandle(void (*pChildConnectHandleTmp)(uint8_t * pu8Data))
{
pOTAChildConnectHandle = pChildConnectHandleTmp;
return ESP_OK;
}
esp_err_t errMeshNetworkSetOTAMessageHandle(void (*pOTAMessageHandleTmp)(MESH_PACKET_t* puMeshPacket))
{
pOTAMessageHandle = pOTAMessageHandleTmp;
return ESP_OK;
}
esp_err_t errMeshNetworkSetOtaDataHandle(void (*pOtaDataHandleTmp)(MESH_PACKET_t* puMeshPacket))
{
pOtaDataHandle = pOtaDataHandleTmp;
return ESP_OK;
}
esp_err_t errMeshNetworkSetOtaAckHandle(void (*pOtaAckHandleTmp)(MESH_PACKET_t* puMeshPacket))
{
pOtaAckHandle = pOtaAckHandleTmp;
return ESP_OK;
}
esp_err_t errMeshNetworkSetOtaCompleteHandle(void (*pOtaCompleteHandleTmp)(MESH_PACKET_t* puMeshPacket))
{
pOtaCompleteHandle = pOtaCompleteHandleTmp;
return ESP_OK;
}
esp_err_t errMeshNetworkSetOtaAbortHandle(void (*pOtaAbortHandleTmp)(MESH_PACKET_t* puMeshPacket))
{
pOtaAbortHandle = pOtaAbortHandleTmp;
return ESP_OK;
}
esp_err_t errMeshNetworkSetChangeStateOfServerWorkerHandle(void (*pChangeStateOfServerWorkerHandleTmp)(bool bState))
{
pChangeStateOfServerWorkerHandle = pChangeStateOfServerWorkerHandleTmp;
return ESP_OK;
}
esp_err_t errSendMeshPacket(mesh_addr_t* pAddrDest, MESH_PACKET_t* pPacket)
{
esp_err_t err;
mesh_data_t data;
data.data = tx_buf;
data.size = sizeof(tx_buf);
data.proto = MESH_PROTO_BIN;
data.tos = MESH_TOS_P2P;
memcpy(tx_buf, (uint8_t *)pPacket, sizeof(MESH_PACKET_t));
err = esp_mesh_send(pAddrDest, &data, MESH_DATA_P2P, NULL, 0);
return err;
}
esp_err_t errStartReceiveTask()
{
esp_err_t err = ESP_OK;
BaseType_t xReturned;
xReturned = xTaskCreate(vTaskReceiveMeshData, "ReceiveMeshData", 7000, NULL, 5, NULL);
if(xReturned != pdPASS)
{
err = ESP_FAIL;
}
return err;
}
void vTaskReceiveMeshData(void *arg)
{
esp_err_t err;
mesh_addr_t from;
mesh_data_t data;
int flag = 0;
data.data = rx_buf;
data.size = CONFIG_MESH_MESSAGE_SIZE;
while (true)
{
data.size = CONFIG_MESH_MESSAGE_SIZE;
err = esp_mesh_recv(&from, &data, portMAX_DELAY, &flag, NULL, 0);
if (err != ESP_OK || !data.size)
{
ESP_LOGE(LOG_TAG, "err:0x%x, size:%d", err, data.size);
continue;
}
MESH_PACKET_t packet;
memcpy(&packet, (uint8_t *)rx_buf, sizeof(MESH_PACKET_t)); //parse MESH_PACKET_t
memcpy(&packet.meshSenderAddr, &from, sizeof(mesh_addr_t)); //copy sender into packet
switch (packet.type)
{
case APP_Data:
ESP_LOGD(LOG_TAG, "recv: APP_Data");
//call the rx handle from app
pAppRxHandle(packet.au8Payload, from.addr); //hand over payload and sender of this mesh packet
break;
case OTA_Version_Request:
case OTA_Version_Response:
case OTA_Complete:
case OTA_Abort:
//call the rx handle from OTA
if(pOTAMessageHandle)
{
pOTAMessageHandle(&packet);
}
break;
case OTA_Data:
if(pOtaDataHandle)
{
pOtaDataHandle(&packet);
}
break;
case OTA_ACK:
if(pOtaAckHandle)
{
pOtaAckHandle(&packet);
}
break;
/* case OTA_Complete:
if(pOtaCompleteHandle)
{
pOtaCompleteHandle(&packet);
}
break;
case OTA_Abort:
if(pOtaAbortHandle)
{
pOtaAbortHandle(&packet);
}
break;
*/
default:
ESP_LOGE(LOG_TAG, "recv: something");
break;
}//end switch
} //end while
}

230
components/mesh_ota/Mesh_network_handler.c Normal file
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#include "Mesh_OTA.h"
static const char *LOG_TAG = "mesh_network_handler";
void vIPEventHandler(void *arg, esp_event_base_t event_base, int32_t i32EventID, void *vpEventData)
{
ip_event_got_ip_t *event = (ip_event_got_ip_t *) vpEventData;
ESP_LOGI(LOG_TAG, "<IP_EVENT_STA_GOT_IP>IP:" IPSTR, IP2STR(&event->ip_info.ip));
if(pChangeStateOfServerWorkerHandle)
{
pChangeStateOfServerWorkerHandle(true); //signal that this node (root node) has access to internet
}
}
void vMeshEventHandler(void *arg, esp_event_base_t event_base, int32_t i32EventID, void* vpEventData)
{
mesh_addr_t id = {0,};
static uint16_t last_layer = 0;
switch (i32EventID)
{
case MESH_EVENT_STARTED:
{
esp_mesh_get_id(&id);
ESP_LOGI(LOG_TAG, "<MESH_EVENT_MESH_STARTED>ID:"MACSTR"", MAC2STR(id.addr));
bIsMeshConnected = false;
i32MeshLayer = esp_mesh_get_layer();
}
break;
case MESH_EVENT_STOPPED:
{
ESP_LOGI(LOG_TAG, "<MESH_EVENT_STOPPED>");
bIsMeshConnected = false;
i32MeshLayer = esp_mesh_get_layer();
}
break;
case MESH_EVENT_CHILD_CONNECTED:
{
mesh_event_child_connected_t *child_connected = (mesh_event_child_connected_t *)vpEventData;
ESP_LOGI(LOG_TAG, "<MESH_EVENT_CHILD_CONNECTED>aid:%d, "MACSTR"", child_connected->aid, MAC2STR(child_connected->mac));
if(pOTAChildConnectHandle){pOTAChildConnectHandle(child_connected->mac);}//add this child to queue using handle
}
break;
case MESH_EVENT_CHILD_DISCONNECTED:
{
mesh_event_child_disconnected_t *child_disconnected = (mesh_event_child_disconnected_t *)vpEventData;
ESP_LOGI(LOG_TAG, "<MESH_EVENT_CHILD_DISCONNECTED>aid:%d, "MACSTR"",
child_disconnected->aid,
MAC2STR(child_disconnected->mac));
}
break;
case MESH_EVENT_ROUTING_TABLE_ADD:
{
mesh_event_routing_table_change_t *routing_table = (mesh_event_routing_table_change_t *)vpEventData;
ESP_LOGW(LOG_TAG, "<MESH_EVENT_ROUTING_TABLE_ADD>add %d, new:%d, layer:%d",
routing_table->rt_size_change,
routing_table->rt_size_new, i32MeshLayer);
}
break;
case MESH_EVENT_ROUTING_TABLE_REMOVE:
{
mesh_event_routing_table_change_t *routing_table = (mesh_event_routing_table_change_t *)vpEventData;
ESP_LOGW(LOG_TAG, "<MESH_EVENT_ROUTING_TABLE_REMOVE>remove %d, new:%d, layer:%d",
routing_table->rt_size_change,
routing_table->rt_size_new, i32MeshLayer);
}
break;
case MESH_EVENT_NO_PARENT_FOUND:
{
mesh_event_no_parent_found_t *no_parent = (mesh_event_no_parent_found_t *)vpEventData;
ESP_LOGI(LOG_TAG, "<MESH_EVENT_NO_PARENT_FOUND>scan times:%d",
no_parent->scan_times);
/* TODO handler for the failure, maybe nominate themselves */
}
break;
case MESH_EVENT_PARENT_CONNECTED:
{
mesh_event_connected_t *connected = (mesh_event_connected_t *)vpEventData;
esp_mesh_get_id(&id);
i32MeshLayer = connected->self_layer;
memcpy(&meshParentAddr.addr, connected->connected.bssid, 6);
ESP_LOGI(LOG_TAG, "<MESH_EVENT_PARENT_CONNECTED>layer:%d-->%d, parent:"MACSTR"%s, ID:"MACSTR", duty:%d",
last_layer, i32MeshLayer, MAC2STR(meshParentAddr.addr),
esp_mesh_is_root() ? "<ROOT>" : (i32MeshLayer == 2) ? "<layer2>" : "", //print own node title
MAC2STR(id.addr), connected->duty);
last_layer = i32MeshLayer;
bIsMeshConnected = true;
if (esp_mesh_is_root())
{
if(esp_netif_dhcpc_start(netif_sta) == ESP_ERR_ESP_NETIF_DHCP_ALREADY_STARTED) //get a IP from router
{
if(pChangeStateOfServerWorkerHandle){pChangeStateOfServerWorkerHandle(true);}// signal reconnect
}
}
errStartReceiveTask();//start receiving
}
break;
case MESH_EVENT_PARENT_DISCONNECTED:
{
mesh_event_disconnected_t *disconnected = (mesh_event_disconnected_t *)vpEventData;
ESP_LOGI(LOG_TAG, "<MESH_EVENT_PARENT_DISCONNECTED>reason:%d", disconnected->reason);
bIsMeshConnected = false;
if(pChangeStateOfServerWorkerHandle){pChangeStateOfServerWorkerHandle(false);}
i32MeshLayer = esp_mesh_get_layer();
}
break;
case MESH_EVENT_LAYER_CHANGE:
{
mesh_event_layer_change_t *layer_change = (mesh_event_layer_change_t *)vpEventData;
i32MeshLayer = layer_change->new_layer;
ESP_LOGI(LOG_TAG, "<MESH_EVENT_LAYER_CHANGE>layer:%d-->%d%s",
last_layer, i32MeshLayer,
esp_mesh_is_root() ? "<ROOT>" : (i32MeshLayer == 2) ? "<layer2>" : "");
last_layer = i32MeshLayer;
}
break;
case MESH_EVENT_ROOT_ADDRESS:
{
mesh_event_root_address_t *root_addr = (mesh_event_root_address_t *)vpEventData;
ESP_LOGI(LOG_TAG, "<MESH_EVENT_ROOT_ADDRESS>root address:"MACSTR"",
MAC2STR(root_addr->addr));
}
break;
case MESH_EVENT_VOTE_STARTED:
{
mesh_event_vote_started_t *vote_started = (mesh_event_vote_started_t *)vpEventData;
ESP_LOGI(LOG_TAG, "<MESH_EVENT_VOTE_STARTED>attempts:%d, reason:%d, rc_addr:"MACSTR"",
vote_started->attempts,
vote_started->reason,
MAC2STR(vote_started->rc_addr.addr));
}
break;
case MESH_EVENT_VOTE_STOPPED:
{
ESP_LOGI(LOG_TAG, "<MESH_EVENT_VOTE_STOPPED>");
}
break;
case MESH_EVENT_ROOT_SWITCH_REQ:
{
mesh_event_root_switch_req_t *switch_req = (mesh_event_root_switch_req_t *)vpEventData;
ESP_LOGI(LOG_TAG, "<MESH_EVENT_ROOT_SWITCH_REQ>reason:%d, rc_addr:"MACSTR"", switch_req->reason,
MAC2STR( switch_req->rc_addr.addr));
}
break;
case MESH_EVENT_ROOT_SWITCH_ACK:
{
//new root
i32MeshLayer = esp_mesh_get_layer();
esp_mesh_get_parent_bssid(&meshParentAddr);
ESP_LOGI(LOG_TAG, "<MESH_EVENT_ROOT_SWITCH_ACK>layer:%d, parent:"MACSTR"", i32MeshLayer, MAC2STR(meshParentAddr.addr));
}
break;
case MESH_EVENT_TODS_STATE:
{
mesh_event_toDS_state_t *toDs_state = (mesh_event_toDS_state_t *)vpEventData;
ESP_LOGI(LOG_TAG, "<MESH_EVENT_TODS_REACHABLE>state:%d", *toDs_state);
}
break;
case MESH_EVENT_ROOT_FIXED:
{
mesh_event_root_fixed_t *root_fixed = (mesh_event_root_fixed_t *)vpEventData;
ESP_LOGI(LOG_TAG, "<MESH_EVENT_ROOT_FIXED>%s",
root_fixed->is_fixed ? "fixed" : "not fixed");
}
break;
case MESH_EVENT_ROOT_ASKED_YIELD:
{
mesh_event_root_conflict_t *root_conflict = (mesh_event_root_conflict_t *)vpEventData;
ESP_LOGI(LOG_TAG, "<MESH_EVENT_ROOT_ASKED_YIELD>"MACSTR", rssi:%d, capacity:%d",
MAC2STR(root_conflict->addr), root_conflict->rssi, root_conflict->capacity);
}
break;
case MESH_EVENT_CHANNEL_SWITCH:
{
mesh_event_channel_switch_t *channel_switch = (mesh_event_channel_switch_t *)vpEventData;
ESP_LOGI(LOG_TAG, "<MESH_EVENT_CHANNEL_SWITCH>new channel:%d", channel_switch->channel);
}
break;
case MESH_EVENT_SCAN_DONE:
{
mesh_event_scan_done_t *scan_done = (mesh_event_scan_done_t *)vpEventData;
ESP_LOGI(LOG_TAG, "<MESH_EVENT_SCAN_DONE>number:%d", scan_done->number);
}
break;
case MESH_EVENT_NETWORK_STATE:
{
mesh_event_network_state_t *network_state = (mesh_event_network_state_t *)vpEventData;
ESP_LOGI(LOG_TAG, "<MESH_EVENT_NETWORK_STATE>is_rootless:%d", network_state->is_rootless);
}
break;
case MESH_EVENT_STOP_RECONNECTION:
{
ESP_LOGI(LOG_TAG, "<MESH_EVENT_STOP_RECONNECTION>");
}
break;
case MESH_EVENT_FIND_NETWORK:
{
mesh_event_find_network_t *find_network = (mesh_event_find_network_t *)vpEventData;
ESP_LOGI(LOG_TAG, "<MESH_EVENT_FIND_NETWORK>new channel:%d, router BSSID:"MACSTR"",
find_network->channel, MAC2STR(find_network->router_bssid));
}
break;
case MESH_EVENT_ROUTER_SWITCH:
{
mesh_event_router_switch_t *router_switch = (mesh_event_router_switch_t *)vpEventData;
ESP_LOGI(LOG_TAG, "<MESH_EVENT_ROUTER_SWITCH>new router:%s, channel:%d, "MACSTR"",
router_switch->ssid, router_switch->channel, MAC2STR(router_switch->bssid));
}
break;
case MESH_EVENT_PS_PARENT_DUTY:
{
mesh_event_ps_duty_t *ps_duty = (mesh_event_ps_duty_t *)vpEventData;
ESP_LOGI(LOG_TAG, "<MESH_EVENT_PS_PARENT_DUTY>duty:%d", ps_duty->duty);
}
break;
case MESH_EVENT_PS_CHILD_DUTY:
{
mesh_event_ps_duty_t *ps_duty = (mesh_event_ps_duty_t *)vpEventData;
ESP_LOGI(LOG_TAG, "<MESH_EVENT_PS_CHILD_DUTY>cidx:%d, "MACSTR", duty:%d", ps_duty->child_connected.aid-1,
MAC2STR(ps_duty->child_connected.mac), ps_duty->duty);
}
break;
default:
ESP_LOGI(LOG_TAG, "unknown id:%d", i32EventID);
break;
}
}

293
components/mesh_ota/https_client.c
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@ -1,293 +0,0 @@
#include "https_client.h"
static const char *TAG = "https_client";
static const char *REQUEST = "GET " CONFIG_OTA_HTTPS_URL " HTTP/1.1\r\n"
"Host: "CONFIG_OTA_HTTPS_SERVER_COMMON_NAME"\r\n"
"User-Agent: esp-idf/1.0 esp32\r\n"
"Authorization: Basic " CONFIG_OTA_HTTPS_AUTH "\r\n"
"\r\n";
static HTTPS_Client_t sHTTPS_ClientConfig;
https_client_ret_t https_clientInitEmbedTLS();
https_client_ret_t https_clientConnectToServer();
https_client_ret_t https_clientValidateServer();
https_client_ret_t https_clientSendRequest();
https_client_ret_t https_clientInitialize()
{
https_client_ret_t i32RetHTTPClient = HTTPS_CLIENT_OK;
i32RetHTTPClient = https_clientInitEmbedTLS();
if(i32RetHTTPClient == HTTPS_CLIENT_OK)
{
i32RetHTTPClient = https_clientConnectToServer();
}
if(i32RetHTTPClient == HTTPS_CLIENT_OK)
{
i32RetHTTPClient = https_clientValidateServer();
}
if(i32RetHTTPClient == HTTPS_CLIENT_OK)
{
i32RetHTTPClient = https_clientSendRequest();
}
switch (i32RetHTTPClient)
{
case HTTPS_CLIENT_ERROR_INIT_EMBEDTLS:
ESP_LOGE(TAG, "Unable to initialize EmbedTLS");
i32RetHTTPClient = HTTPS_CLIENT_ERROR;
break;
case HTTPS_CLIENT_ERROR_INIT_CONNECT_TWO_SERVER:
ESP_LOGE(TAG, "Unable to connect to server");
i32RetHTTPClient = HTTPS_CLIENT_ERROR;
break;
case HTTPS_CLIENT_ERROR_INIT_VALIDATE_SERVER:
ESP_LOGE(TAG, "Unable to validate the server");
i32RetHTTPClient = HTTPS_CLIENT_ERROR;
break;
case HTTPS_CLIENT_ERROR_INIT_SEND_REQUEST:
ESP_LOGE(TAG, "Unable to send request to server");
i32RetHTTPClient = HTTPS_CLIENT_ERROR;
break;
case HTTPS_CLIENT_OK:
ESP_LOGI(TAG, "HTTPS Client successfully initialized");
i32RetHTTPClient = HTTPS_CLIENT_OK;
break;
default:
i32RetHTTPClient = HTTPS_CLIENT_ERROR;
ESP_LOGE(TAG, "Unknown error while init");
break;
}
return i32RetHTTPClient;
}
https_client_ret_t https_clientRetrieveData(char* pu8Data, uint32_t* pu32DataLenght, uint32_t* pu32BytesRead)
{
https_client_ret_t i32RetHTTPClient = HTTPS_CLIENT_OK;
int32_t i32RetRetrieveData = ESP_OK;
bzero(pu8Data, *pu32DataLenght);
bool bRetriveData = true;
*pu32BytesRead = 0U;
while (bRetriveData)
{
//Reading HTTP response
i32RetRetrieveData = mbedtls_ssl_read(&sHTTPS_ClientConfig.ssl, (unsigned char *)(pu8Data+(*pu32BytesRead)), ((*pu32DataLenght)-(*pu32BytesRead)));
if(i32RetRetrieveData > 0)
{
//Data received
*pu32BytesRead = *pu32BytesRead + i32RetRetrieveData;
if(*pu32DataLenght > 0)
{
//buffer not full yet --> read some more
bRetriveData = true;
}
else
{
//buffer full --> stop reading
bRetriveData = false;
}
}
if(i32RetRetrieveData == 0)
{
//all data read --> stop reading
bRetriveData = false;
pu32BytesRead = 0;
}
if(i32RetRetrieveData == MBEDTLS_ERR_SSL_PEER_CLOSE_NOTIFY)
{
//connection is going to be closed
i32RetHTTPClient = HTTPS_CLIENT_ERROR;
bRetriveData = false;
}
}
return i32RetHTTPClient;
}
https_client_ret_t https_clientDeinitialize()
{
https_client_ret_t i32RetHTTPClient = HTTPS_CLIENT_OK;
i32RetHTTPClient = mbedtls_ssl_close_notify(&sHTTPS_ClientConfig.ssl);
if(i32RetHTTPClient != ESP_OK)
{
ESP_LOGE(TAG, "mbedtls_ssl_close_notify returned 0x%x", i32RetHTTPClient);
}
mbedtls_ssl_session_reset(&sHTTPS_ClientConfig.ssl);
mbedtls_net_free(&sHTTPS_ClientConfig.server_fd);
return i32RetHTTPClient;
}
https_client_ret_t https_clientInitEmbedTLS() {
https_client_ret_t i32RetHTTPClient = HTTPS_CLIENT_OK;
int32_t i32RetEmbedTLS = ESP_OK;
mbedtls_ssl_init(&sHTTPS_ClientConfig.ssl);
mbedtls_x509_crt_init(&sHTTPS_ClientConfig.cacert);
mbedtls_ctr_drbg_init(&sHTTPS_ClientConfig.ctr_drbg);
mbedtls_ssl_config_init(&sHTTPS_ClientConfig.conf);
mbedtls_entropy_init(&sHTTPS_ClientConfig.entropy);
i32RetEmbedTLS = mbedtls_ctr_drbg_seed(&sHTTPS_ClientConfig.ctr_drbg, mbedtls_entropy_func, &sHTTPS_ClientConfig.entropy, NULL, 0);
if(i32RetEmbedTLS!= ESP_OK)
{
ESP_LOGE(TAG, "mbedtls_ctr_drbg_seed returned %d", i32RetEmbedTLS);
}
if(i32RetEmbedTLS == ESP_OK)
{
//Attaching the certificate bundle
i32RetEmbedTLS = esp_crt_bundle_attach(&sHTTPS_ClientConfig.conf);
if(i32RetEmbedTLS != ESP_OK)
{
ESP_LOGE(TAG, "esp_crt_bundle_attach returned 0x%x\n\n", i32RetEmbedTLS);
}
}
if(i32RetEmbedTLS == ESP_OK)
{
//Setting hostname for TLS session.
i32RetEmbedTLS = mbedtls_ssl_set_hostname(&sHTTPS_ClientConfig.ssl, CONFIG_OTA_HTTPS_SERVER_COMMON_NAME);
// Hostname set here should match CN in server certificate
if(i32RetEmbedTLS != ESP_OK)
{
ESP_LOGE(TAG, "mbedtls_ssl_set_hostname returned 0x%x", i32RetEmbedTLS);
}
}
if(i32RetEmbedTLS == ESP_OK)
{
//Setting up the SSL/TLS structure
i32RetEmbedTLS = mbedtls_ssl_config_defaults(&sHTTPS_ClientConfig.conf,
MBEDTLS_SSL_IS_CLIENT,
MBEDTLS_SSL_TRANSPORT_STREAM,
MBEDTLS_SSL_PRESET_DEFAULT);
if(i32RetEmbedTLS != ESP_OK)
{
ESP_LOGE(TAG, "mbedtls_ssl_config_defaults returned %d", i32RetEmbedTLS);
}
}
if(i32RetEmbedTLS == ESP_OK)
{
mbedtls_ssl_conf_authmode(&sHTTPS_ClientConfig.conf, MBEDTLS_SSL_VERIFY_REQUIRED);
mbedtls_ssl_conf_ca_chain(&sHTTPS_ClientConfig.conf, &sHTTPS_ClientConfig.cacert, NULL);
mbedtls_ssl_conf_rng(&sHTTPS_ClientConfig.conf, mbedtls_ctr_drbg_random, &sHTTPS_ClientConfig.ctr_drbg);
i32RetEmbedTLS = mbedtls_ssl_setup(&sHTTPS_ClientConfig.ssl, &sHTTPS_ClientConfig.conf);
if(i32RetEmbedTLS != ESP_OK)
{
ESP_LOGE(TAG, "mbedtls_ssl_setup returned -0x%x\n\n", i32RetEmbedTLS);
}
}
if(i32RetEmbedTLS == ESP_OK)
{
mbedtls_net_init(&sHTTPS_ClientConfig.server_fd);
}
if (i32RetEmbedTLS != ESP_OK)
{
i32RetHTTPClient = HTTPS_CLIENT_ERROR_INIT_EMBEDTLS;
}
return i32RetHTTPClient;
}
https_client_ret_t https_clientConnectToServer()
{
https_client_ret_t i32RetHTTPClient = HTTPS_CLIENT_OK;
int32_t i32RetServerConnect = ESP_OK;
//Connecting to server
i32RetServerConnect = mbedtls_net_connect(&sHTTPS_ClientConfig.server_fd, CONFIG_OTA_HTTPS_SERVER_COMMON_NAME, CONFIG_OTA_HTTPS_SERVER_PORT, MBEDTLS_NET_PROTO_TCP);
if (i32RetServerConnect != ESP_OK)
{
ESP_LOGE(TAG, "mbedtls_net_connect returned %x", i32RetServerConnect);
}
if(i32RetServerConnect == ESP_OK)
{
mbedtls_ssl_set_bio(&sHTTPS_ClientConfig.ssl, &sHTTPS_ClientConfig.server_fd, mbedtls_net_send, mbedtls_net_recv, NULL);
//Performing the SSL/TLS handshake
while ((i32RetServerConnect = mbedtls_ssl_handshake(&sHTTPS_ClientConfig.ssl)) != 0)
{
if ((i32RetServerConnect != MBEDTLS_ERR_SSL_WANT_READ) && (i32RetServerConnect != MBEDTLS_ERR_SSL_WANT_WRITE))
{
ESP_LOGE(TAG, "mbedtls_ssl_handshake returned 0x%x", i32RetServerConnect);
}
}
}
if(i32RetServerConnect != ESP_OK)
{
i32RetHTTPClient = HTTPS_CLIENT_ERROR_INIT_CONNECT_TWO_SERVER;
}
return i32RetHTTPClient;
}
https_client_ret_t https_clientValidateServer()
{
https_client_ret_t i32RetHTTPClient = HTTPS_CLIENT_OK;
int32_t i32RetValidateServer = ESP_OK;
//Verifying peer X.509 certificate
if ((i32RetValidateServer = mbedtls_ssl_get_verify_result(&sHTTPS_ClientConfig.ssl)) != 0)
{
ESP_LOGE(TAG, "Failed to verify peer certificate!");
}
if(i32RetValidateServer != ESP_OK)
{
i32RetHTTPClient = HTTPS_CLIENT_ERROR_INIT_VALIDATE_SERVER;
}
return i32RetHTTPClient;
}
https_client_ret_t https_clientSendRequest()
{
https_client_ret_t i32RetHTTPClient = HTTPS_CLIENT_OK;
int32_t i32RetSendRequest = ESP_OK;
uint32_t u32WrittenBytes = 0;
bool bWrite = true;
//Writing HTTP request
while((u32WrittenBytes < strlen(REQUEST)) && bWrite)
{
i32RetSendRequest = mbedtls_ssl_write(&sHTTPS_ClientConfig.ssl,
(const unsigned char *)REQUEST + u32WrittenBytes,
strlen(REQUEST) - u32WrittenBytes);
if (i32RetSendRequest >= 0)
{
//bytes written
u32WrittenBytes += i32RetSendRequest;
} else if (i32RetSendRequest != MBEDTLS_ERR_SSL_WANT_WRITE && i32RetSendRequest != MBEDTLS_ERR_SSL_WANT_READ) {
ESP_LOGE(TAG, "mbedtls_ssl_write returned 0x%x", i32RetSendRequest);
bWrite = false;
}
}
if(bWrite == false)
{
i32RetHTTPClient = HTTPS_CLIENT_ERROR_INIT_SEND_REQUEST;
}
return i32RetHTTPClient;
}

12
components/mesh_ota/include/https_client.h → components/mesh_ota/include/HTTPS_client.h
View File

@ -44,7 +44,6 @@
#define CONFIG_OTA_HTTPS_SERVER_COMMON_NAME "exmaple.com" #define CONFIG_OTA_HTTPS_SERVER_COMMON_NAME "exmaple.com"
#endif #endif
#define HTTPS_CLIENT_OK 0 #define HTTPS_CLIENT_OK 0
#define HTTPS_CLIENT_ERROR -1 #define HTTPS_CLIENT_ERROR -1
#define HTTPS_CLIENT_ERROR_INIT_EMBEDTLS -2 #define HTTPS_CLIENT_ERROR_INIT_EMBEDTLS -2
@ -52,6 +51,8 @@
#define HTTPS_CLIENT_ERROR_INIT_VALIDATE_SERVER -4 #define HTTPS_CLIENT_ERROR_INIT_VALIDATE_SERVER -4
#define HTTPS_CLIENT_ERROR_INIT_SEND_REQUEST -5 #define HTTPS_CLIENT_ERROR_INIT_SEND_REQUEST -5
#define HTTPS_READ_TIMEOUT 1000 //ms
struct HTTPS_Client struct HTTPS_Client
{ {
mbedtls_entropy_context entropy; mbedtls_entropy_context entropy;
@ -65,9 +66,12 @@ struct HTTPS_Client
typedef int32_t https_client_ret_t; typedef int32_t https_client_ret_t;
typedef struct HTTPS_Client HTTPS_Client_t; typedef struct HTTPS_Client HTTPS_Client_t;
https_client_ret_t https_clientInitialize(); https_client_ret_t errHTTPSClientInitialize();
https_client_ret_t https_clientRetrieveData(char* pu8Data, uint32_t* pu32DataLenght, uint32_t* pu32BytesRead); https_client_ret_t errHTTPSClientConnectToServer();
https_client_ret_t https_clientDeinitialize(); https_client_ret_t errHTTPSClientValidateServer();
https_client_ret_t errHTTPSClientSendRequest();
https_client_ret_t errHTTPSClientRetrieveData(char* pu8Data, uint32_t* pu32DataLenght, uint32_t* pu32BytesRead);
https_client_ret_t errHTTPSClientReset();
#endif /* H_HTTPS_CLIENT */ #endif /* H_HTTPS_CLIENT */

79
components/mesh_ota/include/Mesh_OTA.h Normal file
View File

@ -0,0 +1,79 @@
#ifndef H_MESH_OTA
#define H_MESH_OTA
#include <string.h>
#include "esp_wifi.h"
#include "esp_system.h"
#include "esp_event.h"
#include "esp_log.h"
#include "esp_mesh.h"
#include "esp_mesh_internal.h"
#include "nvs_flash.h"
#include "driver/gpio.h"
#include "esp_ota_ops.h"
#include "esp_partition.h"
#include "Mesh_network.h"
#include "HTTPS_client.h"
#define ERASE_NVS //erase non volatile storage if full
#define QUEUE_NODES_SIZE 10
#define QUEUE_MESSAGE_OTA_SIZE 10
#define SERVER_CHECK_INTERVAL 30 //in seconds
#define OTA_HTTPS_SEGMENT_SIZE 2048U
#define OTA_PROGRESS_LOG_INTERVAL 7U
#define OTA_MESH_SEGMENT_SIZE MESH_NETWORK_PAYLOAD_SIZE
#define OTA_MESH_TIMEOUT 100U //in ms
#define ERROR_CHECK(x) if (err == ESP_OK) \
{ \
err = (x); \
if (err != ESP_OK) \
{ \
ESP_LOGE(LOG_TAG, "%s failed with error: 0x%x -> %s", #x, err, esp_err_to_name(err)); \
} \
} \
enum otaMeshRole
{
Transmitter,
Receiver
};
typedef enum otaMeshRole OTA_MESH_ROLE_t;
esp_err_t errMeshOTAInitialize();
esp_err_t errOTAHTTPS(bool* pbNewOTAImage);
esp_err_t errOTAMeshSlave(bool* pbNewOTAImage);
esp_err_t errOTAMeshMaster(bool* pbNewOTAImage, mesh_addr_t* pMeshNodeAddr);
esp_err_t errOTAMeshTransmit(mesh_addr_t* pMeshNodeAddr);
esp_err_t errOTAMeshReceive(bool* pbNewOTAImage, mesh_addr_t* pMeshNodeAddr);
//helper functions
bool bNewerVersion(const char* pu8Local, const char* pu8Remote);
esp_err_t errExtractVersionNumber(const char* pu8Data, uint32_t* pu32DataLenght, char* pc8RemoteVersionNumber);
esp_err_t errFindImageStart(const char* pu8Data, uint32_t* pu32DataLenght, uint32_t* pu32StartOffset);
void vPrintOTAProgress(const uint32_t* const pu32TotalImageSize, const uint32_t* const pu32BytesWritten, OTA_MESH_ROLE_t eRole);
void vAddAllNeighboursToQueue(void);
esp_err_t errSendOTAVersionResponse(mesh_addr_t* meshReceiverAddr);
esp_err_t errSendOTAVersionRequest(mesh_addr_t* meshReceiverAddr);
//Handler
void vAddNodeToPossibleUpdatableQueue(uint8_t* pu8MAC);
void vAddOTAControllMessageToQueue(MESH_PACKET_t* puMeshPacket);
void vChangeStateOfServerWorker(bool state);
void vRecOtaDataHandler(MESH_PACKET_t* puMeshPacket);
void vRecOtaAckHandler(MESH_PACKET_t* puMeshPacket);
//void vRecOtaCompleteHandler(MESH_PACKET_t* puMeshPacket);
//void vRecOtaAbortHandler(MESH_PACKET_t* puMeshPacket);
//Tasks
void vTaskServerWorker(void *arg);
void vTaskOTAWorker(void *arg);
#endif /* H_MESH_OTA */

110
components/mesh_ota/include/Mesh_network.h Normal file
View File

@ -0,0 +1,110 @@
#ifndef H_MESH_NETWORK
#define H_MESH_NETWORK
#include <string.h>
#include "esp_wifi.h"
#include "esp_system.h"
#include "esp_event.h"
#include "esp_log.h"
#include "esp_mesh.h"
#include "esp_mesh_internal.h"
#ifndef CONFIG_MESH_MESSAGE_SIZE
#define CONFIG_MESH_MESSAGE_SIZE 1500
#endif
#ifndef CONFIG_MESH_TOPOLOGY
#define CONFIG_MESH_TOPOLOGY MESH_TOPO_TREE
#endif
#ifndef CONFIG_MESH_MAX_LAYER
#define CONFIG_MESH_MAX_LAYER 6
#endif
#ifndef CONFIG_MESH_ID
#define CONFIG_MESH_ID "00, 00, 00, 00, 00, 00"
#endif
#ifndef CONFIG_MESH_AP_AUTHMODE
#define CONFIG_MESH_AP_AUTHMODE WIFI_AUTH_WPA2_PSK
#endif
#ifndef CONFIG_MESH_AP_CONNECTIONS
#define CONFIG_MESH_AP_CONNECTIONS 6
#endif
#ifndef CONFIG_MESH_AP_PASSWD
#define CONFIG_MESH_AP_PASSWD "MAP_PASSWD"
#endif
#ifndef CONFIG_MESH_CHANNEL
#define CONFIG_MESH_CHANNEL 0
#endif
#ifndef CONFIG_MESH_ROUTER_SSID
#define CONFIG_MESH_ROUTER_SSID "ROUTER_SSID"
#endif
#ifndef CONFIG_MESH_ROUTER_PASSWD
#define CONFIG_MESH_ROUTER_PASSWD "ROUTER_PASSWD"
#endif
#ifndef CONFIG_MESH_ROUTE_TABLE_SIZE
#define CONFIG_MESH_ROUTE_TABLE_SIZE 50
#endif
#define MESH_NETWORK_PAYLOAD_SIZE 1024U
struct meshPacket
{
enum otaMeshPacketType
{
APP_Data, //data for application
OTA_Version_Request, //send own version in payload
OTA_Version_Response, //send own version in payload
OTA_Data, //send image segment
OTA_ACK, //ack image segment
OTA_Complete, //signal end of image
OTA_Abort //abort OTA process
} type;
uint8_t au8Payload[MESH_NETWORK_PAYLOAD_SIZE];
mesh_addr_t meshSenderAddr;
};
typedef struct meshPacket MESH_PACKET_t;
extern bool bIsMeshConnected;
extern int32_t i32MeshLayer;
extern mesh_addr_t meshParentAddr;
extern esp_netif_t* netif_sta;
extern uint8_t u8ownMAC[6];
extern void (*pOTAChildConnectHandle)(uint8_t* );
extern void (*pChangeStateOfServerWorkerHandle)(bool );
esp_err_t errMeshNetworkInitialize();
esp_err_t errMeshNetworkInitializeWiFi();
esp_err_t errMeshNetworkInitializeRouter(mesh_cfg_t* cfg);
esp_err_t errMeshNetworkSetAppReceiveHandle(void (*pAppRxHandleTmp)(uint8_t * pu8Data, uint8_t* pu8Sender));
esp_err_t errMeshNetworkSetChildConnectedHandle(void (*pChildConnectHandleTmp)(uint8_t * pu8Data));
esp_err_t errMeshNetworkSetOTAMessageHandle(void (*pOTAMessageHandleTmp)(MESH_PACKET_t* puMeshPacket));
esp_err_t errMeshNetworkSetOtaDataHandle(void (*pOtaDataHandleTmp)(MESH_PACKET_t* puMeshPacket));
esp_err_t errMeshNetworkSetOtaAckHandle(void (*pOtaAckHandleTmp)(MESH_PACKET_t* puMeshPacket));
esp_err_t errMeshNetworkSetOtaCompleteHandle(void (*pOtaCompleteHandleTmp)(MESH_PACKET_t* puMeshPacket));
esp_err_t errMeshNetworkSetOtaAbortHandle(void (*pOtaAbortHandleTmp)(MESH_PACKET_t* puMeshPacket));
esp_err_t errMeshNetworkSetChangeStateOfServerWorkerHandle(void (*pChangeStateOfServerWorkerHandleTmp)(bool bState));
bool bCheckMACEquality(uint8_t* pu8aMAC, uint8_t* pu8bMAC);
void vGetOwnAddr(mesh_addr_t* pMeshOwnAddr);
esp_err_t errGetParentNode(mesh_addr_t* pMeshParentAddr);
esp_err_t errGetChildren(mesh_addr_t* pChildren, uint16_t* pu16ChildrenSize);
bool bIsRootNode();
bool bIsNodeNeighbour(mesh_addr_t* pNode);
esp_err_t errStartReceiveTask();
void vTaskReceiveMeshData(void *arg);
void vMeshEventHandler(void *arg, esp_event_base_t event_base, int32_t i32EventID, void* vpEventData);
void vIPEventHandler(void *arg, esp_event_base_t event_base, int32_t i32EventID, void *event_data);
esp_err_t errSendMeshPacket(mesh_addr_t* pAddrDest, MESH_PACKET_t* pPacket);
#endif /* H_MESH_NETWORK */

23
components/mesh_ota/include/mesh_ota.h
View File

@ -1,23 +0,0 @@
#ifndef H_MESH_OTA
#define H_MESH_OTA
#include <string.h>
#include "esp_wifi.h"
#include "esp_system.h"
#include "esp_event.h"
#include "esp_log.h"
#include "esp_mesh.h"
#include "esp_mesh_internal.h"
#include "nvs_flash.h"
#include "driver/gpio.h"
#include "esp_ota_ops.h"
#include "esp_partition.h"
#include "https_client.h"
bool bNewerVersion(const char* pu8Local, const char* pu8Remote);
esp_err_t errExtractVersionNumber(const char* pu8Data, uint32_t* pu32DataLenght, char* pc8RemoteVersionNumber);
esp_err_t errFindImageStart(const char* pu8Data, uint32_t* pu32DataLenght, uint32_t* pu32StartOffset);
#endif /* H_MESH_OTA */

155
components/mesh_ota/mesh_ota.c
View File

@ -1,155 +0,0 @@
#include "mesh_ota.h"
/*
* 999.999.999
* Return true if remote version is newer (higher) than local version
*/
bool bNewerVersion(const char* pu8Local, const char* pu8Remote) {
char u8LocalTmp[12];
char u8RemoteTmp[12];
char* pu8saveptrLocal;
char* pu8saveptrRemote;
strcpy(u8LocalTmp, pu8Local);
strcpy(u8RemoteTmp, pu8Remote);
char* pu8TokenLocal = strtok_r(u8LocalTmp, ".", &pu8saveptrLocal);
char* pu8TokenRemote = strtok_r(u8RemoteTmp, ".", &pu8saveptrRemote) ;
bool bReturn = false;
uint8_t u8Index = 0;
while( (u8Index <= 2) && (bReturn == false)) {
u8Index++;
if(atoi(pu8TokenLocal) < atoi(pu8TokenRemote))
{
bReturn = true;
}
pu8TokenLocal = strtok_r(NULL, ".", &pu8saveptrLocal);
pu8TokenRemote = strtok_r(NULL, ".", &pu8saveptrRemote) ;
}
return bReturn;
}
esp_err_t errFindImageStart(const char* pu8Data, uint32_t* pu32DataLenght, uint32_t* pu32StartOffset)
{
/*
Offset value
0 = E9
48 = first digit of version number
*/
esp_err_t errReturn = ESP_OK;
bool bImageStartOffsetFound = false;
*pu32StartOffset = 0U;
uint32_t u32DataIndex = 0;
uint32_t u32FirstDotOffset = 0;
uint32_t u32SecondDotOffset = 0;
uint8_t u8FirstDotIndex = 0;
uint8_t u8SecondDotIndex = 0;
while((u32DataIndex < *pu32DataLenght) && (bImageStartOffsetFound == false))
{
//search for magic byte
if(pu8Data[u32DataIndex] == 0xe9)
{
//magic byte found
printf("\n magic byte found: %i\n", u32DataIndex);
while ((u8FirstDotIndex < 3) && (u32FirstDotOffset == 0))
{
//search first dot in version number
if((u32DataIndex+49+u8FirstDotIndex) < *pu32DataLenght)
{
if((pu8Data[(u32DataIndex+49+u8FirstDotIndex)] == 0x2e))
{
//first do found
u32FirstDotOffset = (u32DataIndex+49+u8FirstDotIndex);
//printf("First dot offset: %i\n", u32FirstDotOffset);
}
}
u8FirstDotIndex++;
}
while ((u8SecondDotIndex < 3) && (u32SecondDotOffset == 0) && (u32FirstDotOffset != 0))
{
//search first dot in version number
if((u32FirstDotOffset+(u8SecondDotIndex+2)) < *pu32DataLenght)
{
if((pu8Data[(u32FirstDotOffset+(u8SecondDotIndex+2))] == 0x2e))
{
//second do found
u32SecondDotOffset = (u32FirstDotOffset+(u8SecondDotIndex+2));
//printf("Second dot offset: %i\n", u32SecondDotOffset);
}
}
u8SecondDotIndex++;
}
if((u32FirstDotOffset != 0) && (u32SecondDotOffset != 0))
{
//image start found based on magic byte and version number systax
*pu32StartOffset = u32DataIndex; //store image start offset
bImageStartOffsetFound = true;
}
else
{
// this is propably not the magic byte --> reset
u32FirstDotOffset = 0;
u32SecondDotOffset = 0;
u8FirstDotIndex = 0;
u8SecondDotIndex = 0;
}
}
u32DataIndex++;
//putchar(pu8Data[i]);
//printf("%x ", pu8Data[u32DataIndex]);
}
if(bImageStartOffsetFound == false)
{
errReturn = ESP_ERR_NOT_FOUND;
}
return errReturn;
}
esp_err_t errExtractVersionNumber(const char* pu8Data, uint32_t* pu32DataLenght, char* pc8RemoteVersionNumber)
{
strcpy(pc8RemoteVersionNumber, "999.999.999"); //init value
uint32_t u32StartOffset;
esp_err_t err = errFindImageStart(pu8Data, pu32DataLenght, &u32StartOffset);
if(err == ESP_OK)
{
printf("\nImage start found: %i\n", u32StartOffset);
strncpy(pc8RemoteVersionNumber, pu8Data+(u32StartOffset+48), 11);
pc8RemoteVersionNumber[12] = '\0';
printf("remote version number %s\n\n", pc8RemoteVersionNumber);
}
return err;
}

4
components/mesh_ota/test/test_image_hex.h
View File

@ -1,7 +1,6 @@
#ifndef H_TEST_IMAGE_HEX #ifndef H_TEST_IMAGE_HEX
#define H_TEST_IMAGE_HEX #define H_TEST_IMAGE_HEX
//with http response + 0.0.1 //with http response + 0.0.1
char dataWithHttpRespone0_0_1[] = char dataWithHttpRespone0_0_1[] =
{ {
@ -32,7 +31,6 @@ char dataWithHttpRespone0_0_1[] =
0x65, 0x2f, 0x68, 0x65, 0x6e, 0x64, 0x72, 0x69, 0x6b, 0x2f, 0x65, 0x73, 0x70, 0x2f, 0x65, 0x73, 0x70, 0x2d, 0x69, 0x64, 0x66, 0x2f, 0x63, 0x6f, 0x6d, 0x70, 0x6f, 0x6e, 0x65, 0x6e, 0x74 0x65, 0x2f, 0x68, 0x65, 0x6e, 0x64, 0x72, 0x69, 0x6b, 0x2f, 0x65, 0x73, 0x70, 0x2f, 0x65, 0x73, 0x70, 0x2d, 0x69, 0x64, 0x66, 0x2f, 0x63, 0x6f, 0x6d, 0x70, 0x6f, 0x6e, 0x65, 0x6e, 0x74
}; };
//without http response + 0.0.1 //without http response + 0.0.1
char dataWithoutHttpRespone0_0_1[] = char dataWithoutHttpRespone0_0_1[] =
{ {
@ -80,7 +78,6 @@ char dataWithoutHttpRespone999_999_999[] =
}; };
//with http response + 999.999.999 //with http response + 999.999.999
char dataWithHttpRespone999_999_999[] = char dataWithHttpRespone999_999_999[] =
{ {
@ -171,5 +168,4 @@ char dataWithHttpRespone999_99_999[] =
0x68, 0x6f, 0x6d, 0x65, 0x2f, 0x68, 0x65, 0x6e, 0x64, 0x72, 0x69, 0x6b, 0x2f, 0x65, 0x73, 0x70, 0x2f, 0x65, 0x73, 0x70, 0x2d, 0x69, 0x64, 0x66, 0x2f, 0x63, 0x6f, 0x6d, 0x70, 0x6f, 0x6e, 0x65, 0x6e, 0x74, 0x68, 0x6f, 0x6d, 0x65, 0x2f, 0x68, 0x65, 0x6e, 0x64, 0x72, 0x69, 0x6b, 0x2f, 0x65, 0x73, 0x70, 0x2f, 0x65, 0x73, 0x70, 0x2d, 0x69, 0x64, 0x66, 0x2f, 0x63, 0x6f, 0x6d, 0x70, 0x6f, 0x6e, 0x65, 0x6e, 0x74,
}; };
#endif /* H_TEST_IMAGE_HEX */ #endif /* H_TEST_IMAGE_HEX */

3
components/mesh_ota/test/test_mesh_ota.c
View File

@ -1,8 +1,7 @@
#include <limits.h> #include <limits.h>
#include "unity.h" #include "unity.h"
#include "mesh_ota.h" #include "Mesh_OTA.h"
#include "test_image_hex.h" #include "test_image_hex.h"
// ### ### ### distinguish newer image version ### ### ### // ### ### ### distinguish newer image version ### ### ###

186
main/Blinky_LED.c Normal file
View File

@ -0,0 +1,186 @@
#include "Blinky_LED.h"
static const char *LOG_TAG = "blinky_led";
static bool bLEDisOn = false; //set led default off
static mesh_addr_t addrParent; //addr of parent node
static mesh_addr_t childrenAddr[CONFIG_MESH_ROUTE_TABLE_SIZE]; //array of children attached to this node
static uint16_t u16ChildrenSize; //number of children attached to this node
xQueueHandle queueBlinkyLEDPackets; //handle for led action queue
esp_err_t errBlinkyLEDInitialize()
{
esp_err_t err = ESP_OK;
BaseType_t xReturned;
vGPIOInitialize();
//create queue to store led action created from BTN and mesh network events
queueBlinkyLEDPackets = xQueueCreate(5, sizeof(BLINKY_PACKET_t));
if (queueBlinkyLEDPackets == 0) // Queue not created
{
ESP_LOGE(LOG_TAG, "Unable to create Queue for Application Packets");
err = ESP_FAIL;
}
//register the receiver handle in mesh network
ERROR_CHECK(errMeshNetworkSetAppReceiveHandle(rxHandle));
if(err == ESP_OK)
{
xReturned = xTaskCreate(vTaskReadUserInput, "vTaskReadUserInput", 4096, NULL, 5, NULL);
if(xReturned != pdPASS)
{
err = ESP_FAIL;
}
}
if(err == ESP_OK)
{
xReturned = xTaskCreate(vTaskReceiveData, "vTaskReceiveData", 4096, NULL, 5, NULL);
if(xReturned != pdPASS)
{
err = ESP_FAIL;
}
}
return err;
}
void vGPIOInitialize()
{
gpio_config_t gpioConf;
//LED as Output
gpio_reset_pin(GPIO_LED);
gpio_set_direction(GPIO_LED, GPIO_MODE_OUTPUT);
//BTN as Input
gpioConf.intr_type = GPIO_INTR_DISABLE;
gpioConf.mode = GPIO_MODE_INPUT;
gpioConf.pin_bit_mask = GPIO_INPUT_PIN_SEL;
gpioConf.pull_down_en = 0;
gpioConf.pull_up_en = 1;
gpio_config(&gpioConf);
}
void rxHandle(uint8_t* pu8Data, uint8_t* pu8Sender)
{
//send payload to app queue
BLINKY_PACKET_t bTmpPacket;
memcpy(&bTmpPacket, (uint8_t *)pu8Data, sizeof(BLINKY_PACKET_t));
memcpy(&bTmpPacket.meshSenderAddr, (uint8_t *)pu8Sender, 6); //copy MAC from sender into app packet
if (xQueueSend(queueBlinkyLEDPackets, &bTmpPacket, portMAX_DELAY) != pdPASS)
{
ESP_LOGE(LOG_TAG, "Unable to push packet from mesh into Queue");
}
}
void vTaskReadUserInput(void *arg)
{
esp_err_t err = ESP_OK;
BLINKY_PACKET_t bTmpPacket;
MESH_PACKET_t meshPacket;
bTmpPacket.type = LED_OFF; //default off
meshPacket.type = APP_Data; //this is a app packet
while(true)
{
//check for BTN press
if(gpio_get_level(GPIO_BOOT_BTN) == 0)
{
err = ESP_OK;
if(bLEDisOn == false)
{
bTmpPacket.type = LED_ON;
}
else
{
bTmpPacket.type = LED_OFF;
}
//push led action into queue
if (xQueueSend(queueBlinkyLEDPackets, &bTmpPacket, portMAX_DELAY) != pdPASS)
{
ESP_LOGE(LOG_TAG, "Unable to push packet into queue");
}
memcpy(meshPacket.au8Payload, &bTmpPacket, sizeof(BLINKY_PACKET_t));
if(bIsRootNode() == false)
{
//this node is not root --> send led action to parent
ERROR_CHECK(errGetParentNode(&addrParent));
ERROR_CHECK(errSendMeshPacket(&addrParent, &meshPacket));
}
else
{
//this node is root --> send led action to children
ERROR_CHECK(errGetChildren(childrenAddr, &u16ChildrenSize));
for (uint16_t u16Index = 0; u16Index < u16ChildrenSize; u16Index++)
{
ERROR_CHECK (errSendMeshPacket(&childrenAddr[u16Index], &meshPacket));
}
}
vTaskDelay(200 / portTICK_PERIOD_MS);
}
vTaskDelay(50 / portTICK_PERIOD_MS);
}
}
void vTaskReceiveData(void *arg)
{
esp_err_t err = ESP_OK;
MESH_PACKET_t meshPacket;
BLINKY_PACKET_t bTmpPacket;
bTmpPacket.type = LED_OFF; //default off
meshPacket.type = APP_Data; //this is a app packet
while (1)
{
if (xQueueReceive(queueBlinkyLEDPackets, &bTmpPacket, portMAX_DELAY) != pdTRUE)
{
ESP_LOGE(LOG_TAG, "Unable to receive packet from Queue");
}
else
{
err = ESP_OK;
//Successfully RECEIVED the packet
switch (bTmpPacket.type)
{
case LED_ON:
bLEDisOn = true;
gpio_set_level(GPIO_LED, 1); //switch on
ESP_LOGI(LOG_TAG,"switch LED ON");
break;
case LED_OFF:
bLEDisOn = false;
gpio_set_level(GPIO_LED, 0); //switch off
ESP_LOGI(LOG_TAG,"switch LED OFF");
break;
default:
bLEDisOn = false;
gpio_set_level(GPIO_LED, 0); //switch off
ESP_LOGI(LOG_TAG,"switch LED OFF");
break;
}
}
ERROR_CHECK(errGetChildren(childrenAddr, &u16ChildrenSize)); //get all children attached to this node
memcpy(meshPacket.au8Payload, &bTmpPacket, sizeof(BLINKY_PACKET_t)); //copy led action in mesh packet payload
for (uint16_t u16Index = 0; u16Index < u16ChildrenSize; u16Index++)
{
//loop through children
if(bCheckMACEquality(bTmpPacket.meshSenderAddr.addr, childrenAddr[u16Index].addr) == false) //exclude the sender node
{
ERROR_CHECK (errSendMeshPacket(&childrenAddr[u16Index], &meshPacket)); //send to child
}
}
vTaskDelay(200 / portTICK_PERIOD_MS);
}
}

39
main/Blinky_LED.h Normal file
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@ -0,0 +1,39 @@
#ifndef H_BLINKY_LED
#define H_BLINKY_LED
#include <string.h>
#include "esp_wifi.h"
#include "esp_system.h"
#include "esp_log.h"
#include "freertos/FreeRTOS.h"
#include "freertos/task.h"
#include "driver/gpio.h"
#include "Mesh_OTA.h"
#define GPIO_BOOT_BTN 0 //GPIO0 (Boot BTN)
#define GPIO_LED 2 //GPIO2 (internal blue LED in DevKit V1.0)
#define GPIO_INPUT_PIN_SEL (1ULL<<GPIO_BOOT_BTN)
struct blinky_packet
{
enum blinky_packet_type
{
LED_OFF,
LED_ON,
} type;
mesh_addr_t meshSenderAddr; //stores addr of sender of this packet
};
typedef struct blinky_packet BLINKY_PACKET_t;
esp_err_t errBlinkyLEDInitialize();
void vGPIOInitialize();
void rxHandle(uint8_t* pu8Data, uint8_t* pu8Sender);
void vTaskReadUserInput(void *arg);
void vTaskReceiveData(void *arg);
#endif /* H_BLINKY_LED */

2
main/CMakeLists.txt
View File

@ -1,2 +1,2 @@
idf_component_register(SRCS "main.c" idf_component_register(SRCS "Blinky_LED.c" "Main.c"
INCLUDE_DIRS ".") INCLUDE_DIRS ".")

13
main/Kconfig.projbuild
View File

@ -106,6 +106,12 @@ menu "Mesh OTA Configuration"
help help
mesh network channel. mesh network channel.
config MESH_ID
string "ID for mesh network"
default "00, 00, 00, 00, 00, 00"
help
Mesh network id like MAC addr.
config MESH_ROUTER_SSID config MESH_ROUTER_SSID
string "Router SSID" string "Router SSID"
default "ROUTER_SSID" default "ROUTER_SSID"
@ -158,6 +164,13 @@ menu "Mesh OTA Configuration"
help help
The number of devices over the network(max: 300). The number of devices over the network(max: 300).
config MESH_MESSAGE_SIZE
int "Mesh network messages size"
range 1 65536
default 1500
help
Length of messages deliveres by the mesh network.
config OTA_HTTPS_SERVER_COMMON_NAME config OTA_HTTPS_SERVER_COMMON_NAME
string "Common name OTA server" string "Common name OTA server"
default "exmaple.com" default "exmaple.com"

37
main/Main.c Normal file
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@ -0,0 +1,37 @@
#include <string.h>
#include "esp_wifi.h"
#include "esp_system.h"
#include "esp_event.h"
#include "esp_log.h"
#include "esp_mesh.h"
#include "esp_mesh_internal.h"
#include "nvs_flash.h"
#include "driver/gpio.h"
#include "esp_ota_ops.h"
#include "esp_partition.h"
#include "Mesh_OTA.h"
#include "Blinky_LED.h"
static const char *LOG_TAG = "esp_main";
void app_main(void)
{
esp_err_t err = ESP_OK;
ESP_LOGI(LOG_TAG, "hardcoded: 0.0.1");
ESP_LOGI(LOG_TAG, "start mesh network");
err = errMeshNetworkInitialize();
ESP_ERROR_CHECK(err);
ESP_LOGI(LOG_TAG, "start ota");
err = errMeshOTAInitialize();
ESP_ERROR_CHECK(err);
ESP_LOGI(LOG_TAG, "start app");
err = errBlinkyLEDInitialize();
ESP_ERROR_CHECK(err);
}

697
main/main.c
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@ -1,697 +0,0 @@
#include <string.h>
#include "esp_wifi.h"
#include "esp_system.h"
#include "esp_event.h"
#include "esp_log.h"
#include "esp_mesh.h"
#include "esp_mesh_internal.h"
#include "nvs_flash.h"
#include "driver/gpio.h"
#include "esp_ota_ops.h"
#include "esp_partition.h"
#include "mesh_ota.h"
#define RX_SIZE (1234)
#define TX_SIZE (1234)
static const char *MESH_TAG = "mesh_main";
static const uint8_t MESH_ID[6] = { 0x77, 0x77, 0x77, 0x77, 0x77, 0x77};
static uint8_t tx_buf[TX_SIZE] = { 0, };
static uint8_t rx_buf[RX_SIZE] = { 0, };
static bool is_mesh_connected = false;
static mesh_addr_t mesh_parent_addr;
static uint8_t ownMAC[6];
static int mesh_layer = -1;
static esp_netif_t *netif_sta = NULL;
struct ota_mesh_packet
{
enum ota_mesh_packet_type
{
APP_Version_Request,
APP_Version_Response,
OTA_Data,
OTA_ACK,
OTA_Complete
} type;
uint8_t au8Payload[1024];
};
/*******************************************************
* Function Declarations
*******************************************************/
esp_err_t esp_mesh_send_packet(mesh_addr_t* dest, struct ota_mesh_packet* packet);
/*******************************************************
* Function Definitions
*******************************************************/
esp_err_t esp_mesh_ota_send(mesh_addr_t* dest)
{
esp_err_t err = ESP_OK;
static uint32_t u32index;
const esp_partition_t * currentPartition = esp_ota_get_boot_partition();
if((*currentPartition).subtype == 0)
{
int data_read = 0;
struct ota_mesh_packet packet;
packet.type=OTA_Data;
if(u32index == 1024)
{
//all data read
data_read = 0;
u32index = 0;
}
else
{
ESP_LOGI(MESH_TAG, "OTA-Data read: %i", u32index);
err = esp_partition_read(currentPartition, (1024*u32index), packet.au8Payload, 1024 );
ESP_ERROR_CHECK(err);
data_read = 1024;
u32index++;
}
if (data_read > 0)
{
//send ota fragemnt to node
esp_mesh_send_packet(dest, &packet);
}
ESP_ERROR_CHECK(err);
}
else
{
ESP_LOGI(MESH_TAG, "Subtype: %d", (*currentPartition).subtype);
}
return err;
}
esp_err_t esp_mesh_ota_receive(mesh_addr_t* dest, struct ota_mesh_packet* packet)
{
esp_err_t err = ESP_OK;
static esp_ota_handle_t otaHandle;
static uint32_t u32index;
const esp_partition_t * currentPartition = esp_ota_get_boot_partition();
const esp_partition_t * otaPartition = esp_ota_get_next_update_partition(currentPartition);
if(u32index == 0)
{
//first run
err = esp_ota_begin(otaPartition, OTA_SIZE_UNKNOWN, &otaHandle);
ESP_ERROR_CHECK(err);
}
ESP_LOGI(MESH_TAG, "OTA-Data write: %i", u32index);
err = esp_ota_write(otaHandle, packet->au8Payload, 1024);
if(err != ESP_OK)
{
ESP_LOGE(MESH_TAG, "OTA-Data write error: %i at %i", err, u32index);
}
ESP_ERROR_CHECK(err);
if(u32index >= 1023)
{
//ota update complete
ESP_LOGI(MESH_TAG, "OTA-Data complete arrived: %i", u32index);
err = esp_ota_end(otaHandle);
ESP_ERROR_CHECK(err);
esp_app_desc_t otaPartitionDesc;
err = esp_ota_get_partition_description(otaPartition, &otaPartitionDesc);
ESP_ERROR_CHECK(err);
ESP_LOGI(MESH_TAG, "otaPartition project_name: %s", (otaPartitionDesc).project_name);
err = esp_ota_set_boot_partition(otaPartition);
ESP_ERROR_CHECK(err);
struct ota_mesh_packet retPacket;
retPacket.type=OTA_Complete;
ESP_ERROR_CHECK (esp_mesh_send_packet(dest, &retPacket)); //send back to parent
//check if this node has children --> Update them
esp_restart();
}
u32index++;
return err;
}
//returns true if MAC address is equal
bool esp_mesh_check_MAC_Equality(uint8_t* aMAC, uint8_t* bMAC)
{
for (uint8_t index = 0; index < 6; index++)
{
if(aMAC[index] != bMAC[index])
{
return false;
}
}
return true;
}
esp_err_t esp_mesh_get_Children(mesh_addr_t children[], uint16_t* pu16ChildrenSize)
{
*pu16ChildrenSize = 0;
mesh_addr_t route_table[CONFIG_MESH_ROUTE_TABLE_SIZE];
int route_table_size = 0;
esp_mesh_get_routing_table((mesh_addr_t *) &route_table, CONFIG_MESH_ROUTE_TABLE_SIZE * 6, &route_table_size);
for(uint16_t index = 0; index < esp_mesh_get_routing_table_size(); index++)
{
if(! (esp_mesh_check_MAC_Equality(ownMAC, route_table[index].addr)) )
{
//child node
// ESP_LOGI(MESH_TAG, "adding Node: \"0x%x, 0x%x, 0x%x, 0x%x, 0x%x, 0x%x\" ", route_table[index].addr[0], route_table[index].addr[1], route_table[index].addr[2], route_table[index].addr[3], route_table[index].addr[4], route_table[index].addr[5]);
children[*pu16ChildrenSize] = route_table[index];
*pu16ChildrenSize = (*pu16ChildrenSize)+1;
}
}
return ESP_OK;
}
esp_err_t esp_mesh_send_packet(mesh_addr_t* dest, struct ota_mesh_packet* packet)
{
esp_err_t err;
mesh_data_t data;
data.data = tx_buf;
data.size = sizeof(tx_buf);
data.proto = MESH_PROTO_BIN;
data.tos = MESH_TOS_P2P;
memcpy(tx_buf, (uint8_t *)packet, sizeof(struct ota_mesh_packet));
err = esp_mesh_send(dest, &data, MESH_DATA_P2P, NULL, 0);
return err;
}
void esp_mesh_p2p_rx_main(void *arg)
{
esp_err_t err;
mesh_addr_t from;
mesh_data_t data;
int flag = 0;
data.data = rx_buf;
data.size = RX_SIZE;
while (true)
{
data.size = RX_SIZE;
err = esp_mesh_recv(&from, &data, portMAX_DELAY, &flag, NULL, 0);
if (err != ESP_OK || !data.size)
{
ESP_LOGE(MESH_TAG, "err:0x%x, size:%d", err, data.size);
continue;
}
struct ota_mesh_packet packet;
memcpy(&packet, (uint8_t *)rx_buf, sizeof(struct ota_mesh_packet));
switch (packet.type)
{
case APP_Version_Request:
ESP_LOGI(MESH_TAG, "recv: APP_Version_Request");
packet.type=APP_Version_Response;
packet.au8Payload[0] = 42; //TODO get current running version
ESP_ERROR_CHECK (esp_mesh_send_packet(&from, &packet)); //send back to parent
break;
case APP_Version_Response:
ESP_LOGI(MESH_TAG, "recv: APP_Version_Response - App Version %i: ", packet.au8Payload[0]);
//check if node is out-dated
esp_mesh_ota_send(&from);
break;
case OTA_Data:
ESP_LOGI(MESH_TAG, "recv: OTA_Data");
esp_mesh_ota_receive(&from, &packet);
packet.type=OTA_ACK;
ESP_ERROR_CHECK (esp_mesh_send_packet(&from, &packet)); //send back to parent
break;
case OTA_ACK:
ESP_LOGI(MESH_TAG, "recv: OTA_ACK");
esp_mesh_ota_send(&from);
break;
case OTA_Complete:
ESP_LOGI(MESH_TAG, "recv: OTA_Complete");
break;
default:
ESP_LOGE(MESH_TAG, "recv: something");
break;
}
} //end while
vTaskDelete(NULL);
}
esp_err_t esp_mesh_comm_p2p_start(void)
{
static bool is_comm_p2p_started = false;
if (!is_comm_p2p_started)
{
is_comm_p2p_started = true;
xTaskCreate(esp_mesh_p2p_rx_main, "MPRX", 7000, NULL, 5, NULL);
}
return ESP_OK;
}
void mesh_event_handler(void *arg, esp_event_base_t event_base,
int32_t event_id, void *event_data)
{
mesh_addr_t id = {0,};
static uint16_t last_layer = 0;
switch (event_id)
{
case MESH_EVENT_STARTED:
{
esp_mesh_get_id(&id);
ESP_LOGI(MESH_TAG, "<MESH_EVENT_MESH_STARTED>ID:"MACSTR"", MAC2STR(id.addr));
is_mesh_connected = false;
mesh_layer = esp_mesh_get_layer();
}
break;
case MESH_EVENT_STOPPED: {
ESP_LOGI(MESH_TAG, "<MESH_EVENT_STOPPED>");
is_mesh_connected = false;
mesh_layer = esp_mesh_get_layer();
}
break;
case MESH_EVENT_CHILD_CONNECTED: {
mesh_event_child_connected_t *child_connected = (mesh_event_child_connected_t *)event_data;
ESP_LOGI(MESH_TAG, "<MESH_EVENT_CHILD_CONNECTED>aid:%d, "MACSTR"",
child_connected->aid,
MAC2STR(child_connected->mac));
}
break;
case MESH_EVENT_CHILD_DISCONNECTED: {
mesh_event_child_disconnected_t *child_disconnected = (mesh_event_child_disconnected_t *)event_data;
ESP_LOGI(MESH_TAG, "<MESH_EVENT_CHILD_DISCONNECTED>aid:%d, "MACSTR"",
child_disconnected->aid,
MAC2STR(child_disconnected->mac));
}
break;
case MESH_EVENT_ROUTING_TABLE_ADD: {
mesh_event_routing_table_change_t *routing_table = (mesh_event_routing_table_change_t *)event_data;
ESP_LOGW(MESH_TAG, "<MESH_EVENT_ROUTING_TABLE_ADD>add %d, new:%d, layer:%d",
routing_table->rt_size_change,
routing_table->rt_size_new, mesh_layer);
}
break;
case MESH_EVENT_ROUTING_TABLE_REMOVE: {
mesh_event_routing_table_change_t *routing_table = (mesh_event_routing_table_change_t *)event_data;
ESP_LOGW(MESH_TAG, "<MESH_EVENT_ROUTING_TABLE_REMOVE>remove %d, new:%d, layer:%d",
routing_table->rt_size_change,
routing_table->rt_size_new, mesh_layer);
}
break;
case MESH_EVENT_NO_PARENT_FOUND: {
mesh_event_no_parent_found_t *no_parent = (mesh_event_no_parent_found_t *)event_data;
ESP_LOGI(MESH_TAG, "<MESH_EVENT_NO_PARENT_FOUND>scan times:%d",
no_parent->scan_times);
}
/* TODO handler for the failure */
break;
case MESH_EVENT_PARENT_CONNECTED: {
mesh_event_connected_t *connected = (mesh_event_connected_t *)event_data;
esp_mesh_get_id(&id);
mesh_layer = connected->self_layer;
memcpy(&mesh_parent_addr.addr, connected->connected.bssid, 6);
ESP_LOGI(MESH_TAG,
"<MESH_EVENT_PARENT_CONNECTED>layer:%d-->%d, parent:"MACSTR"%s, ID:"MACSTR", duty:%d",
last_layer, mesh_layer, MAC2STR(mesh_parent_addr.addr),
esp_mesh_is_root() ? "<ROOT>" :
(mesh_layer == 2) ? "<layer2>" : "", MAC2STR(id.addr), connected->duty);
last_layer = mesh_layer;
// mesh_connected_indicator(mesh_layer);
is_mesh_connected = true;
if (esp_mesh_is_root()) {
esp_netif_dhcpc_start(netif_sta);
}
esp_mesh_comm_p2p_start();//start receiving
}
break;
case MESH_EVENT_PARENT_DISCONNECTED: {
mesh_event_disconnected_t *disconnected = (mesh_event_disconnected_t *)event_data;
ESP_LOGI(MESH_TAG,
"<MESH_EVENT_PARENT_DISCONNECTED>reason:%d",
disconnected->reason);
is_mesh_connected = false;
// mesh_disconnected_indicator();
mesh_layer = esp_mesh_get_layer();
}
break;
case MESH_EVENT_LAYER_CHANGE: {
mesh_event_layer_change_t *layer_change = (mesh_event_layer_change_t *)event_data;
mesh_layer = layer_change->new_layer;
ESP_LOGI(MESH_TAG, "<MESH_EVENT_LAYER_CHANGE>layer:%d-->%d%s",
last_layer, mesh_layer,
esp_mesh_is_root() ? "<ROOT>" :
(mesh_layer == 2) ? "<layer2>" : "");
last_layer = mesh_layer;
// mesh_connected_indicator(mesh_layer);
}
break;
case MESH_EVENT_ROOT_ADDRESS: {
mesh_event_root_address_t *root_addr = (mesh_event_root_address_t *)event_data;
ESP_LOGI(MESH_TAG, "<MESH_EVENT_ROOT_ADDRESS>root address:"MACSTR"",
MAC2STR(root_addr->addr));
}
break;
case MESH_EVENT_VOTE_STARTED: {
mesh_event_vote_started_t *vote_started = (mesh_event_vote_started_t *)event_data;
ESP_LOGI(MESH_TAG,
"<MESH_EVENT_VOTE_STARTED>attempts:%d, reason:%d, rc_addr:"MACSTR"",
vote_started->attempts,
vote_started->reason,
MAC2STR(vote_started->rc_addr.addr));
}
break;
case MESH_EVENT_VOTE_STOPPED: {
ESP_LOGI(MESH_TAG, "<MESH_EVENT_VOTE_STOPPED>");
break;
}
case MESH_EVENT_ROOT_SWITCH_REQ: {
mesh_event_root_switch_req_t *switch_req = (mesh_event_root_switch_req_t *)event_data;
ESP_LOGI(MESH_TAG,
"<MESH_EVENT_ROOT_SWITCH_REQ>reason:%d, rc_addr:"MACSTR"",
switch_req->reason,
MAC2STR( switch_req->rc_addr.addr));
}
break;
case MESH_EVENT_ROOT_SWITCH_ACK: {
/* new root */
mesh_layer = esp_mesh_get_layer();
esp_mesh_get_parent_bssid(&mesh_parent_addr);
ESP_LOGI(MESH_TAG, "<MESH_EVENT_ROOT_SWITCH_ACK>layer:%d, parent:"MACSTR"", mesh_layer, MAC2STR(mesh_parent_addr.addr));
}
break;
case MESH_EVENT_TODS_STATE: {
mesh_event_toDS_state_t *toDs_state = (mesh_event_toDS_state_t *)event_data;
ESP_LOGI(MESH_TAG, "<MESH_EVENT_TODS_REACHABLE>state:%d", *toDs_state);
}
break;
case MESH_EVENT_ROOT_FIXED: {
mesh_event_root_fixed_t *root_fixed = (mesh_event_root_fixed_t *)event_data;
ESP_LOGI(MESH_TAG, "<MESH_EVENT_ROOT_FIXED>%s",
root_fixed->is_fixed ? "fixed" : "not fixed");
}
break;
case MESH_EVENT_ROOT_ASKED_YIELD: {
mesh_event_root_conflict_t *root_conflict = (mesh_event_root_conflict_t *)event_data;
ESP_LOGI(MESH_TAG,
"<MESH_EVENT_ROOT_ASKED_YIELD>"MACSTR", rssi:%d, capacity:%d",
MAC2STR(root_conflict->addr),
root_conflict->rssi,
root_conflict->capacity);
}
break;
case MESH_EVENT_CHANNEL_SWITCH: {
mesh_event_channel_switch_t *channel_switch = (mesh_event_channel_switch_t *)event_data;
ESP_LOGI(MESH_TAG, "<MESH_EVENT_CHANNEL_SWITCH>new channel:%d", channel_switch->channel);
}
break;
case MESH_EVENT_SCAN_DONE: {
mesh_event_scan_done_t *scan_done = (mesh_event_scan_done_t *)event_data;
ESP_LOGI(MESH_TAG, "<MESH_EVENT_SCAN_DONE>number:%d",
scan_done->number);
}
break;
case MESH_EVENT_NETWORK_STATE: {
mesh_event_network_state_t *network_state = (mesh_event_network_state_t *)event_data;
ESP_LOGI(MESH_TAG, "<MESH_EVENT_NETWORK_STATE>is_rootless:%d",
network_state->is_rootless);
}
break;
case MESH_EVENT_STOP_RECONNECTION: {
ESP_LOGI(MESH_TAG, "<MESH_EVENT_STOP_RECONNECTION>");
}
break;
case MESH_EVENT_FIND_NETWORK: {
mesh_event_find_network_t *find_network = (mesh_event_find_network_t *)event_data;
ESP_LOGI(MESH_TAG, "<MESH_EVENT_FIND_NETWORK>new channel:%d, router BSSID:"MACSTR"",
find_network->channel, MAC2STR(find_network->router_bssid));
}
break;
case MESH_EVENT_ROUTER_SWITCH: {
mesh_event_router_switch_t *router_switch = (mesh_event_router_switch_t *)event_data;
ESP_LOGI(MESH_TAG, "<MESH_EVENT_ROUTER_SWITCH>new router:%s, channel:%d, "MACSTR"",
router_switch->ssid, router_switch->channel, MAC2STR(router_switch->bssid));
}
break;
case MESH_EVENT_PS_PARENT_DUTY: {
mesh_event_ps_duty_t *ps_duty = (mesh_event_ps_duty_t *)event_data;
ESP_LOGI(MESH_TAG, "<MESH_EVENT_PS_PARENT_DUTY>duty:%d", ps_duty->duty);
}
break;
case MESH_EVENT_PS_CHILD_DUTY: {
mesh_event_ps_duty_t *ps_duty = (mesh_event_ps_duty_t *)event_data;
ESP_LOGI(MESH_TAG, "<MESH_EVENT_PS_CHILD_DUTY>cidx:%d, "MACSTR", duty:%d", ps_duty->child_connected.aid-1,
MAC2STR(ps_duty->child_connected.mac), ps_duty->duty);
}
break;
default:
ESP_LOGI(MESH_TAG, "unknown id:%d", event_id);
break;
}
}
void ip_event_handler(void *arg, esp_event_base_t event_base,
int32_t event_id, void *event_data)
{
ip_event_got_ip_t *event = (ip_event_got_ip_t *) event_data;
ESP_LOGI(MESH_TAG, "<IP_EVENT_STA_GOT_IP>IP:" IPSTR, IP2STR(&event->ip_info.ip));
}
static void test(void *pvParameters)
{
esp_err_t err;
uint32_t u32BufferLenght = 1024U;
char buffer[1024U];
uint32_t u32BytesRead = 0;
char pcRemoteVersionNumber[12];
ESP_LOGI(MESH_TAG, "Hello World");
const esp_partition_t * currentPartition = esp_ota_get_boot_partition();
ESP_LOGI(MESH_TAG, "Type: %d", (*currentPartition).subtype);
ESP_LOGI(MESH_TAG, "Start address: %d", (*currentPartition).address);
ESP_LOGI(MESH_TAG, "Size: %d", (*currentPartition).size);
ESP_LOGI(MESH_TAG, "Encrypted: %d", (*currentPartition).encrypted);
esp_app_desc_t curPartitionDesc;
err = esp_ota_get_partition_description(currentPartition, &curPartitionDesc);
ESP_ERROR_CHECK(err);
ESP_LOGI(MESH_TAG, "currentPartition project_name: %s", (curPartitionDesc).project_name);
ESP_LOGI(MESH_TAG, "currentPartition version: %s", (curPartitionDesc).version);
ESP_LOGI(MESH_TAG, "currentPartition Timestamp: %s %s", (curPartitionDesc).date, (curPartitionDesc).time);
https_clientInitialize();
https_clientRetrieveData(buffer, &u32BufferLenght, &u32BytesRead);
ESP_LOGI(MESH_TAG, "Data received: %i", u32BytesRead);
err = errExtractVersionNumber(buffer, &u32BytesRead, pcRemoteVersionNumber);
if(err == ESP_OK)
{
if(bNewerVersion((curPartitionDesc).version, pcRemoteVersionNumber))
{
ESP_LOGI(MESH_TAG, "Newer Version available");
//write ota
const esp_partition_t * currentPartition = esp_ota_get_boot_partition();
const esp_partition_t * otaPartition = esp_ota_get_next_update_partition(currentPartition);
static esp_ota_handle_t otaHandle;
uint32_t u32StartOffset = 305; //TODO fix this
/*
//esp_err_t err = errFindImageStart(pu8Data, pu32DataLenght, &u32StartOffset);
esp_err_t err = errFindImageStart(buffer, &u32BufferLenght, &u32StartOffset);
if(err != ESP_OK)
{
ESP_LOGI(MESH_TAG, "errFindImageStart failed: %i", err);
}
*/
ESP_LOGI(MESH_TAG, "first byte offset: %i", u32StartOffset);
ESP_LOGI(MESH_TAG, "first byte: %x", buffer[u32StartOffset]);
err = esp_ota_begin(otaPartition, OTA_SIZE_UNKNOWN, &otaHandle);
ESP_ERROR_CHECK(err);
/*
bool stop = false;
while(stop == false)
{
https_clientRetrieveData(buffer, &u32BufferLenght, &u32BytesRead);
ESP_LOGI(MESH_TAG, "OTA-Data written: %i", u32BytesRead);
if(u32BytesRead == 0)
{
stop = true;
}
}
ESP_LOGI(MESH_TAG, "END");
*/
do {
ESP_LOGI(MESH_TAG, "OTA-Data written: %i", u32BytesRead);
err = esp_ota_write(otaHandle, (const void*) buffer+u32StartOffset, (u32BytesRead-u32StartOffset));
u32StartOffset = 0U;
https_clientRetrieveData(buffer, &u32BufferLenght, &u32BytesRead);
} while (u32BytesRead > 0);
err = esp_ota_end(otaHandle);
ESP_ERROR_CHECK(err);
esp_app_desc_t otaPartitionDesc;
err = esp_ota_get_partition_description(otaPartition, &otaPartitionDesc);
ESP_ERROR_CHECK(err);
ESP_LOGI(MESH_TAG, "otaPartition project_name: %s", (otaPartitionDesc).project_name);
err = esp_ota_set_boot_partition(otaPartition);
ESP_ERROR_CHECK(err);
//esp_restart();
}
else
{
ESP_LOGI(MESH_TAG, "NO newer Version available");
}
}
else
{
ESP_LOGI(MESH_TAG, "errExtractVersionNumber failed: %i", err);
}
https_clientDeinitialize();
while(1)
{
vTaskDelay(1000 / portTICK_PERIOD_MS);
}
}
void app_main(void)
{
/*
err = nvs_flash_erase();
if(err != ESP_OK){
ESP_LOGI(MESH_TAG, "Error: %x", err);
while(1){
}
}
*/
ESP_ERROR_CHECK(nvs_flash_init());
/* tcpip initialization */
ESP_ERROR_CHECK(esp_netif_init());
/* event initialization */
ESP_ERROR_CHECK(esp_event_loop_create_default());
/* create network interfaces for mesh (only station instance saved for further manipulation, soft AP instance ignored */
ESP_ERROR_CHECK(esp_netif_create_default_wifi_mesh_netifs(&netif_sta, NULL));
/* wifi initialization */
wifi_init_config_t config = WIFI_INIT_CONFIG_DEFAULT();
ESP_ERROR_CHECK(esp_wifi_init(&config));
ESP_ERROR_CHECK(esp_event_handler_register(IP_EVENT, IP_EVENT_STA_GOT_IP, &ip_event_handler, NULL));
ESP_ERROR_CHECK(esp_wifi_set_storage(WIFI_STORAGE_FLASH));
ESP_ERROR_CHECK(esp_wifi_start());
/* mesh initialization */
ESP_ERROR_CHECK(esp_mesh_init());
ESP_ERROR_CHECK(esp_event_handler_register(MESH_EVENT, ESP_EVENT_ANY_ID, &mesh_event_handler, NULL));
/* set mesh topology */
ESP_ERROR_CHECK(esp_mesh_set_topology(CONFIG_MESH_TOPOLOGY));
/* set mesh max layer according to the topology */
ESP_ERROR_CHECK(esp_mesh_set_max_layer(CONFIG_MESH_MAX_LAYER));
ESP_ERROR_CHECK(esp_mesh_set_vote_percentage(1));
ESP_ERROR_CHECK(esp_mesh_set_xon_qsize(128));
/* Disable mesh PS function */
ESP_ERROR_CHECK(esp_mesh_disable_ps());
ESP_ERROR_CHECK(esp_mesh_set_ap_assoc_expire(10));
mesh_cfg_t cfg = MESH_INIT_CONFIG_DEFAULT();
/* mesh ID */
memcpy((uint8_t *) &cfg.mesh_id, MESH_ID, 6);
/* router */
cfg.channel = CONFIG_MESH_CHANNEL;
cfg.router.ssid_len = strlen(CONFIG_MESH_ROUTER_SSID);
memcpy((uint8_t *) &cfg.router.ssid, CONFIG_MESH_ROUTER_SSID, cfg.router.ssid_len);
memcpy((uint8_t *) &cfg.router.password, CONFIG_MESH_ROUTER_PASSWD,
strlen(CONFIG_MESH_ROUTER_PASSWD));
/* mesh softAP */
ESP_ERROR_CHECK(esp_mesh_set_ap_authmode(CONFIG_MESH_AP_AUTHMODE));
cfg.mesh_ap.max_connection = CONFIG_MESH_AP_CONNECTIONS;
memcpy((uint8_t *) &cfg.mesh_ap.password, CONFIG_MESH_AP_PASSWD,
strlen(CONFIG_MESH_AP_PASSWD));
ESP_ERROR_CHECK(esp_mesh_set_config(&cfg));
ESP_ERROR_CHECK(esp_base_mac_addr_get(ownMAC));
ESP_LOGI(MESH_TAG, "Own MAC: \"0x%x, 0x%x, 0x%x, 0x%x, 0x%x, 0x%x\" ", ownMAC[0], ownMAC[1], ownMAC[2], ownMAC[3], ownMAC[4], ownMAC[5]);
/* mesh start */
ESP_ERROR_CHECK(esp_mesh_start());
ESP_LOGI(MESH_TAG, "mesh starts successfully, heap:%d, %s<%d>%s, ps:%d\n", esp_get_minimum_free_heap_size(),
esp_mesh_is_root_fixed() ? "root fixed" : "root not fixed",
esp_mesh_get_topology(), esp_mesh_get_topology() ? "(chain)":"(tree)", esp_mesh_is_ps_enabled());
for(;;) {
if(gpio_get_level(0) == 0){
break;
}
vTaskDelay(1000 / portTICK_PERIOD_MS);
}
xTaskCreate(&test, "test_task", 8192, NULL, 5, NULL);
}

699
main/main.c.orig
View File

@ -1,699 +0,0 @@
#include <string.h>
#include "esp_wifi.h"
#include "esp_system.h"
#include "esp_event.h"
#include "esp_log.h"
#include "esp_mesh.h"
#include "esp_mesh_internal.h"
#include "nvs_flash.h"
#include "driver/gpio.h"
#include "esp_ota_ops.h"
#include "esp_partition.h"
#include "mesh_ota.h"
#define RX_SIZE (1234)
#define TX_SIZE (1234)
static const char *MESH_TAG = "mesh_main";
static const uint8_t MESH_ID[6] = { 0x77, 0x77, 0x77, 0x77, 0x77, 0x77};
static uint8_t tx_buf[TX_SIZE] = { 0, };
static uint8_t rx_buf[RX_SIZE] = { 0, };
static bool is_mesh_connected = false;
static mesh_addr_t mesh_parent_addr;
static uint8_t ownMAC[6];
static int mesh_layer = -1;
static esp_netif_t *netif_sta = NULL;
struct ota_mesh_packet
{
enum ota_mesh_packet_type
{
APP_Version_Request,
APP_Version_Response,
OTA_Data,
OTA_ACK,
OTA_Complete
} type;
uint8_t au8Payload[1024];
};
/*******************************************************
* Function Declarations
*******************************************************/
esp_err_t esp_mesh_send_packet(mesh_addr_t* dest, struct ota_mesh_packet* packet);
/*******************************************************
* Function Definitions
*******************************************************/
esp_err_t esp_mesh_ota_send(mesh_addr_t* dest)
{
esp_err_t err = ESP_OK;
static uint32_t u32index;
const esp_partition_t * currentPartition = esp_ota_get_boot_partition();
if((*currentPartition).subtype == 0)
{
int data_read = 0;
struct ota_mesh_packet packet;
packet.type=OTA_Data;
if(u32index == 1024)
{
//all data read
data_read = 0;
u32index = 0;
}
else
{
ESP_LOGI(MESH_TAG, "OTA-Data read: %i", u32index);
err = esp_partition_read(currentPartition, (1024*u32index), packet.au8Payload, 1024 );
ESP_ERROR_CHECK(err);
data_read = 1024;
u32index++;
}
if (data_read > 0)
{
//send ota fragemnt to node
esp_mesh_send_packet(dest, &packet);
}
ESP_ERROR_CHECK(err);
}
else
{
ESP_LOGI(MESH_TAG, "Subtype: %d", (*currentPartition).subtype);
}
return err;
}
esp_err_t esp_mesh_ota_receive(mesh_addr_t* dest, struct ota_mesh_packet* packet)
{
esp_err_t err = ESP_OK;
static esp_ota_handle_t otaHandle;
static uint32_t u32index;
const esp_partition_t * currentPartition = esp_ota_get_boot_partition();
const esp_partition_t * otaPartition = esp_ota_get_next_update_partition(currentPartition);
if(u32index == 0)
{
//first run
err = esp_ota_begin(otaPartition, OTA_SIZE_UNKNOWN, &otaHandle);
ESP_ERROR_CHECK(err);
}
ESP_LOGI(MESH_TAG, "OTA-Data write: %i", u32index);
err = esp_ota_write(otaHandle, packet->au8Payload, 1024);
if(err != ESP_OK)
{
ESP_LOGE(MESH_TAG, "OTA-Data write error: %i at %i", err, u32index);
}
ESP_ERROR_CHECK(err);
if(u32index >= 1023)
{
//ota update complete
ESP_LOGI(MESH_TAG, "OTA-Data complete arrived: %i", u32index);
err = esp_ota_end(otaHandle);
ESP_ERROR_CHECK(err);
esp_app_desc_t otaPartitionDesc;
err = esp_ota_get_partition_description(otaPartition, &otaPartitionDesc);
ESP_ERROR_CHECK(err);
ESP_LOGI(MESH_TAG, "otaPartition project_name: %s", (otaPartitionDesc).project_name);
err = esp_ota_set_boot_partition(otaPartition);
ESP_ERROR_CHECK(err);
struct ota_mesh_packet retPacket;
retPacket.type=OTA_Complete;
ESP_ERROR_CHECK (esp_mesh_send_packet(dest, &retPacket)); //send back to parent
//check if this node has children --> Update them
esp_restart();
}
u32index++;
return err;
}
//returns true if MAC address is equal
bool esp_mesh_check_MAC_Equality(uint8_t* aMAC, uint8_t* bMAC)
{
for (uint8_t index = 0; index < 6; index++)
{
if(aMAC[index] != bMAC[index])
{
return false;
}
}
return true;
}
esp_err_t esp_mesh_get_Children(mesh_addr_t children[], uint16_t* pu16ChildrenSize)
{
*pu16ChildrenSize = 0;
mesh_addr_t route_table[CONFIG_MESH_ROUTE_TABLE_SIZE];
int route_table_size = 0;
esp_mesh_get_routing_table((mesh_addr_t *) &route_table, CONFIG_MESH_ROUTE_TABLE_SIZE * 6, &route_table_size);
for(uint16_t index = 0; index < esp_mesh_get_routing_table_size(); index++)
{
if(! (esp_mesh_check_MAC_Equality(ownMAC, route_table[index].addr)) )
{
//child node
// ESP_LOGI(MESH_TAG, "adding Node: \"0x%x, 0x%x, 0x%x, 0x%x, 0x%x, 0x%x\" ", route_table[index].addr[0], route_table[index].addr[1], route_table[index].addr[2], route_table[index].addr[3], route_table[index].addr[4], route_table[index].addr[5]);
children[*pu16ChildrenSize] = route_table[index];
*pu16ChildrenSize = (*pu16ChildrenSize)+1;
}
}
return ESP_OK;
}
esp_err_t esp_mesh_send_packet(mesh_addr_t* dest, struct ota_mesh_packet* packet)
{
esp_err_t err;
mesh_data_t data;
data.data = tx_buf;
data.size = sizeof(tx_buf);
data.proto = MESH_PROTO_BIN;
data.tos = MESH_TOS_P2P;
memcpy(tx_buf, (uint8_t *)packet, sizeof(struct ota_mesh_packet));
err = esp_mesh_send(dest, &data, MESH_DATA_P2P, NULL, 0);
return err;
}
void esp_mesh_p2p_rx_main(void *arg)
{
esp_err_t err;
mesh_addr_t from;
mesh_data_t data;
int flag = 0;
data.data = rx_buf;
data.size = RX_SIZE;
while (true)
{
data.size = RX_SIZE;
err = esp_mesh_recv(&from, &data, portMAX_DELAY, &flag, NULL, 0);
if (err != ESP_OK || !data.size)
{
ESP_LOGE(MESH_TAG, "err:0x%x, size:%d", err, data.size);
continue;
}
struct ota_mesh_packet packet;
memcpy(&packet, (uint8_t *)rx_buf, sizeof(struct ota_mesh_packet));
switch (packet.type)
{
case APP_Version_Request:
ESP_LOGI(MESH_TAG, "recv: APP_Version_Request");
packet.type=APP_Version_Response;
packet.au8Payload[0] = 42; //TODO get current running version
ESP_ERROR_CHECK (esp_mesh_send_packet(&from, &packet)); //send back to parent
break;
case APP_Version_Response:
ESP_LOGI(MESH_TAG, "recv: APP_Version_Response - App Version %i: ", packet.au8Payload[0]);
//check if node is out-dated
esp_mesh_ota_send(&from);
break;
case OTA_Data:
ESP_LOGI(MESH_TAG, "recv: OTA_Data");
esp_mesh_ota_receive(&from, &packet);
packet.type=OTA_ACK;
ESP_ERROR_CHECK (esp_mesh_send_packet(&from, &packet)); //send back to parent
break;
case OTA_ACK:
ESP_LOGI(MESH_TAG, "recv: OTA_ACK");
esp_mesh_ota_send(&from);
break;
case OTA_Complete:
ESP_LOGI(MESH_TAG, "recv: OTA_Complete");
break;
default:
ESP_LOGE(MESH_TAG, "recv: something");
break;
}
} //end while
vTaskDelete(NULL);
}
esp_err_t esp_mesh_comm_p2p_start(void)
{
static bool is_comm_p2p_started = false;
if (!is_comm_p2p_started)
{
is_comm_p2p_started = true;
xTaskCreate(esp_mesh_p2p_rx_main, "MPRX", 7000, NULL, 5, NULL);
}
return ESP_OK;
}
void mesh_event_handler(void *arg, esp_event_base_t event_base,
int32_t event_id, void *event_data)
{
mesh_addr_t id = {0,};
static uint16_t last_layer = 0;
switch (event_id)
{
case MESH_EVENT_STARTED:
{
esp_mesh_get_id(&id);
ESP_LOGI(MESH_TAG, "<MESH_EVENT_MESH_STARTED>ID:"MACSTR"", MAC2STR(id.addr));
is_mesh_connected = false;
mesh_layer = esp_mesh_get_layer();
}
break;
case MESH_EVENT_STOPPED: {
ESP_LOGI(MESH_TAG, "<MESH_EVENT_STOPPED>");
is_mesh_connected = false;
mesh_layer = esp_mesh_get_layer();
}
break;
case MESH_EVENT_CHILD_CONNECTED: {
mesh_event_child_connected_t *child_connected = (mesh_event_child_connected_t *)event_data;
ESP_LOGI(MESH_TAG, "<MESH_EVENT_CHILD_CONNECTED>aid:%d, "MACSTR"",
child_connected->aid,
MAC2STR(child_connected->mac));
}
break;
case MESH_EVENT_CHILD_DISCONNECTED: {
mesh_event_child_disconnected_t *child_disconnected = (mesh_event_child_disconnected_t *)event_data;
ESP_LOGI(MESH_TAG, "<MESH_EVENT_CHILD_DISCONNECTED>aid:%d, "MACSTR"",
child_disconnected->aid,
MAC2STR(child_disconnected->mac));
}
break;
case MESH_EVENT_ROUTING_TABLE_ADD: {
mesh_event_routing_table_change_t *routing_table = (mesh_event_routing_table_change_t *)event_data;
ESP_LOGW(MESH_TAG, "<MESH_EVENT_ROUTING_TABLE_ADD>add %d, new:%d, layer:%d",
routing_table->rt_size_change,
routing_table->rt_size_new, mesh_layer);
}
break;
case MESH_EVENT_ROUTING_TABLE_REMOVE: {
mesh_event_routing_table_change_t *routing_table = (mesh_event_routing_table_change_t *)event_data;
ESP_LOGW(MESH_TAG, "<MESH_EVENT_ROUTING_TABLE_REMOVE>remove %d, new:%d, layer:%d",
routing_table->rt_size_change,
routing_table->rt_size_new, mesh_layer);
}
break;
case MESH_EVENT_NO_PARENT_FOUND: {
mesh_event_no_parent_found_t *no_parent = (mesh_event_no_parent_found_t *)event_data;
ESP_LOGI(MESH_TAG, "<MESH_EVENT_NO_PARENT_FOUND>scan times:%d",
no_parent->scan_times);
}
/* TODO handler for the failure */
break;
case MESH_EVENT_PARENT_CONNECTED: {
mesh_event_connected_t *connected = (mesh_event_connected_t *)event_data;
esp_mesh_get_id(&id);
mesh_layer = connected->self_layer;
memcpy(&mesh_parent_addr.addr, connected->connected.bssid, 6);
ESP_LOGI(MESH_TAG,
"<MESH_EVENT_PARENT_CONNECTED>layer:%d-->%d, parent:"MACSTR"%s, ID:"MACSTR", duty:%d",
last_layer, mesh_layer, MAC2STR(mesh_parent_addr.addr),
esp_mesh_is_root() ? "<ROOT>" :
(mesh_layer == 2) ? "<layer2>" : "", MAC2STR(id.addr), connected->duty);
last_layer = mesh_layer;
// mesh_connected_indicator(mesh_layer);
is_mesh_connected = true;
if (esp_mesh_is_root()) {
esp_netif_dhcpc_start(netif_sta);
}
esp_mesh_comm_p2p_start();//start receiving
}
break;
case MESH_EVENT_PARENT_DISCONNECTED: {
mesh_event_disconnected_t *disconnected = (mesh_event_disconnected_t *)event_data;
ESP_LOGI(MESH_TAG,
"<MESH_EVENT_PARENT_DISCONNECTED>reason:%d",
disconnected->reason);
is_mesh_connected = false;
// mesh_disconnected_indicator();
mesh_layer = esp_mesh_get_layer();
}
break;
case MESH_EVENT_LAYER_CHANGE: {
mesh_event_layer_change_t *layer_change = (mesh_event_layer_change_t *)event_data;
mesh_layer = layer_change->new_layer;
ESP_LOGI(MESH_TAG, "<MESH_EVENT_LAYER_CHANGE>layer:%d-->%d%s",
last_layer, mesh_layer,
esp_mesh_is_root() ? "<ROOT>" :
(mesh_layer == 2) ? "<layer2>" : "");
last_layer = mesh_layer;
// mesh_connected_indicator(mesh_layer);
}
break;
case MESH_EVENT_ROOT_ADDRESS: {
mesh_event_root_address_t *root_addr = (mesh_event_root_address_t *)event_data;
ESP_LOGI(MESH_TAG, "<MESH_EVENT_ROOT_ADDRESS>root address:"MACSTR"",
MAC2STR(root_addr->addr));
}
break;
case MESH_EVENT_VOTE_STARTED: {
mesh_event_vote_started_t *vote_started = (mesh_event_vote_started_t *)event_data;
ESP_LOGI(MESH_TAG,
"<MESH_EVENT_VOTE_STARTED>attempts:%d, reason:%d, rc_addr:"MACSTR"",
vote_started->attempts,
vote_started->reason,
MAC2STR(vote_started->rc_addr.addr));
}
break;
case MESH_EVENT_VOTE_STOPPED: {
ESP_LOGI(MESH_TAG, "<MESH_EVENT_VOTE_STOPPED>");
break;
}
case MESH_EVENT_ROOT_SWITCH_REQ: {
mesh_event_root_switch_req_t *switch_req = (mesh_event_root_switch_req_t *)event_data;
ESP_LOGI(MESH_TAG,
"<MESH_EVENT_ROOT_SWITCH_REQ>reason:%d, rc_addr:"MACSTR"",
switch_req->reason,
MAC2STR( switch_req->rc_addr.addr));
}
break;
case MESH_EVENT_ROOT_SWITCH_ACK: {
/* new root */
mesh_layer = esp_mesh_get_layer();
esp_mesh_get_parent_bssid(&mesh_parent_addr);
ESP_LOGI(MESH_TAG, "<MESH_EVENT_ROOT_SWITCH_ACK>layer:%d, parent:"MACSTR"", mesh_layer, MAC2STR(mesh_parent_addr.addr));
}
break;
case MESH_EVENT_TODS_STATE: {
mesh_event_toDS_state_t *toDs_state = (mesh_event_toDS_state_t *)event_data;
ESP_LOGI(MESH_TAG, "<MESH_EVENT_TODS_REACHABLE>state:%d", *toDs_state);
}
break;
case MESH_EVENT_ROOT_FIXED: {
mesh_event_root_fixed_t *root_fixed = (mesh_event_root_fixed_t *)event_data;
ESP_LOGI(MESH_TAG, "<MESH_EVENT_ROOT_FIXED>%s",
root_fixed->is_fixed ? "fixed" : "not fixed");
}
break;
case MESH_EVENT_ROOT_ASKED_YIELD: {
mesh_event_root_conflict_t *root_conflict = (mesh_event_root_conflict_t *)event_data;
ESP_LOGI(MESH_TAG,
"<MESH_EVENT_ROOT_ASKED_YIELD>"MACSTR", rssi:%d, capacity:%d",
MAC2STR(root_conflict->addr),
root_conflict->rssi,
root_conflict->capacity);
}
break;
case MESH_EVENT_CHANNEL_SWITCH: {
mesh_event_channel_switch_t *channel_switch = (mesh_event_channel_switch_t *)event_data;
ESP_LOGI(MESH_TAG, "<MESH_EVENT_CHANNEL_SWITCH>new channel:%d", channel_switch->channel);
}
break;
case MESH_EVENT_SCAN_DONE: {
mesh_event_scan_done_t *scan_done = (mesh_event_scan_done_t *)event_data;
ESP_LOGI(MESH_TAG, "<MESH_EVENT_SCAN_DONE>number:%d",
scan_done->number);
}
break;
case MESH_EVENT_NETWORK_STATE: {
mesh_event_network_state_t *network_state = (mesh_event_network_state_t *)event_data;
ESP_LOGI(MESH_TAG, "<MESH_EVENT_NETWORK_STATE>is_rootless:%d",
network_state->is_rootless);
}
break;
case MESH_EVENT_STOP_RECONNECTION: {
ESP_LOGI(MESH_TAG, "<MESH_EVENT_STOP_RECONNECTION>");
}
break;
case MESH_EVENT_FIND_NETWORK: {
mesh_event_find_network_t *find_network = (mesh_event_find_network_t *)event_data;
ESP_LOGI(MESH_TAG, "<MESH_EVENT_FIND_NETWORK>new channel:%d, router BSSID:"MACSTR"",
find_network->channel, MAC2STR(find_network->router_bssid));
}
break;
case MESH_EVENT_ROUTER_SWITCH: {
mesh_event_router_switch_t *router_switch = (mesh_event_router_switch_t *)event_data;
ESP_LOGI(MESH_TAG, "<MESH_EVENT_ROUTER_SWITCH>new router:%s, channel:%d, "MACSTR"",
router_switch->ssid, router_switch->channel, MAC2STR(router_switch->bssid));
}
break;
case MESH_EVENT_PS_PARENT_DUTY: {
mesh_event_ps_duty_t *ps_duty = (mesh_event_ps_duty_t *)event_data;
ESP_LOGI(MESH_TAG, "<MESH_EVENT_PS_PARENT_DUTY>duty:%d", ps_duty->duty);
}
break;
case MESH_EVENT_PS_CHILD_DUTY: {
mesh_event_ps_duty_t *ps_duty = (mesh_event_ps_duty_t *)event_data;
ESP_LOGI(MESH_TAG, "<MESH_EVENT_PS_CHILD_DUTY>cidx:%d, "MACSTR", duty:%d", ps_duty->child_connected.aid-1,
MAC2STR(ps_duty->child_connected.mac), ps_duty->duty);
}
break;
default:
ESP_LOGI(MESH_TAG, "unknown id:%d", event_id);
break;
}
}
void ip_event_handler(void *arg, esp_event_base_t event_base,
int32_t event_id, void *event_data)
{
ip_event_got_ip_t *event = (ip_event_got_ip_t *) event_data;
ESP_LOGI(MESH_TAG, "<IP_EVENT_STA_GOT_IP>IP:" IPSTR, IP2STR(&event->ip_info.ip));
}
static void test(void *pvParameters)
{
esp_err_t err;
uint32_t u32BufferLenght = 1024U;
char buffer[1024U];
uint32_t u32BytesRead = 0;
char pcRemoteVersionNumber[12];
ESP_LOGI(MESH_TAG, "Hello World");
const esp_partition_t * currentPartition = esp_ota_get_boot_partition();
ESP_LOGI(MESH_TAG, "Type: %d", (*currentPartition).subtype);
ESP_LOGI(MESH_TAG, "Start address: %d", (*currentPartition).address);
ESP_LOGI(MESH_TAG, "Size: %d", (*currentPartition).size);
ESP_LOGI(MESH_TAG, "Encrypted: %d", (*currentPartition).encrypted);
esp_app_desc_t curPartitionDesc;
err = esp_ota_get_partition_description(currentPartition, &curPartitionDesc);
ESP_ERROR_CHECK(err);
ESP_LOGI(MESH_TAG, "currentPartition project_name: %s", (curPartitionDesc).project_name);
ESP_LOGI(MESH_TAG, "currentPartition version: %s", (curPartitionDesc).version);
ESP_LOGI(MESH_TAG, "currentPartition Timestamp: %s %s", (curPartitionDesc).date, (curPartitionDesc).time);
https_clientInitialize();
https_clientRetrieveData(buffer, &u32BufferLenght, &u32BytesRead);
ESP_LOGI(MESH_TAG, "Data received: %i", u32BytesRead);
err = errExtractVersionNumber(buffer, &u32BytesRead, pcRemoteVersionNumber);
if(err == ESP_OK)
{
if(bNewerVersion((curPartitionDesc).version, pcRemoteVersionNumber))
{
ESP_LOGI(MESH_TAG, "Newer Version available");
//write ota
const esp_partition_t * currentPartition = esp_ota_get_boot_partition();
const esp_partition_t * otaPartition = esp_ota_get_next_update_partition(currentPartition);
static esp_ota_handle_t otaHandle;
uint32_t u32StartOffset = 305; //TODO fix this
/*
//esp_err_t err = errFindImageStart(pu8Data, pu32DataLenght, &u32StartOffset);
esp_err_t err = errFindImageStart(buffer, &u32BufferLenght, &u32StartOffset);
if(err != ESP_OK)
{
ESP_LOGI(MESH_TAG, "errFindImageStart failed: %i", err);
}
*/
ESP_LOGI(MESH_TAG, "first byte offset: %i", u32StartOffset);
ESP_LOGI(MESH_TAG, "first byte: %x", buffer[u32StartOffset]);
err = esp_ota_begin(otaPartition, OTA_SIZE_UNKNOWN, &otaHandle);
ESP_ERROR_CHECK(err);
bool stop = false;
while(stop == false )
{
https_clientRetrieveData(buffer, &u32BufferLenght, &u32BytesRead);
ESP_LOGI(MESH_TAG, "OTA-Data written: %i", u32BytesRead);
if(u32BytesRead == 0)
{
stop = true;
}
}
ESP_LOGI(MESH_TAG, "END");
/*
do {
ESP_LOGI(MESH_TAG, "OTA-Data written: %i", u32BytesRead);
err = esp_ota_write(otaHandle, (const void*) buffer+u32StartOffset, (u32BytesRead-u32StartOffset));
u32StartOffset = 0U;
https_clientRetrieveData(buffer, &u32BufferLenght, &u32BytesRead);
} while (u32BytesRead > 0);
err = esp_ota_end(otaHandle);
ESP_ERROR_CHECK(err);
esp_app_desc_t otaPartitionDesc;
err = esp_ota_get_partition_description(otaPartition, &otaPartitionDesc);
ESP_ERROR_CHECK(err);
ESP_LOGI(MESH_TAG, "otaPartition project_name: %s", (otaPartitionDesc).project_name);
err = esp_ota_set_boot_partition(otaPartition);
ESP_ERROR_CHECK(err);
//esp_restart();
*/
}
else
{
ESP_LOGI(MESH_TAG, "NO newer Version available");
}
}
else
{
ESP_LOGI(MESH_TAG, "errExtractVersionNumber failed: %i", err);
}
https_clientDeinitialize();
while(1)
{
vTaskDelay(1000 / portTICK_PERIOD_MS);
}
}
void app_main(void)
{
/*
err = nvs_flash_erase();
if(err != ESP_OK){
ESP_LOGI(MESH_TAG, "Error: %x", err);
while(1){
}
}
*/
ESP_ERROR_CHECK(nvs_flash_init());
/* tcpip initialization */
ESP_ERROR_CHECK(esp_netif_init());
/* event initialization */
ESP_ERROR_CHECK(esp_event_loop_create_default());
/* create network interfaces for mesh (only station instance saved for further manipulation, soft AP instance ignored */
ESP_ERROR_CHECK(esp_netif_create_default_wifi_mesh_netifs(&netif_sta, NULL));
/* wifi initialization */
wifi_init_config_t config = WIFI_INIT_CONFIG_DEFAULT();
ESP_ERROR_CHECK(esp_wifi_init(&config));
ESP_ERROR_CHECK(esp_event_handler_register(IP_EVENT, IP_EVENT_STA_GOT_IP, &ip_event_handler, NULL));
ESP_ERROR_CHECK(esp_wifi_set_storage(WIFI_STORAGE_FLASH));
ESP_ERROR_CHECK(esp_wifi_start());
/* mesh initialization */
ESP_ERROR_CHECK(esp_mesh_init());
ESP_ERROR_CHECK(esp_event_handler_register(MESH_EVENT, ESP_EVENT_ANY_ID, &mesh_event_handler, NULL));
/* set mesh topology */
ESP_ERROR_CHECK(esp_mesh_set_topology(CONFIG_MESH_TOPOLOGY));
/* set mesh max layer according to the topology */
ESP_ERROR_CHECK(esp_mesh_set_max_layer(CONFIG_MESH_MAX_LAYER));
ESP_ERROR_CHECK(esp_mesh_set_vote_percentage(1));
ESP_ERROR_CHECK(esp_mesh_set_xon_qsize(128));
/* Disable mesh PS function */
ESP_ERROR_CHECK(esp_mesh_disable_ps());
ESP_ERROR_CHECK(esp_mesh_set_ap_assoc_expire(10));
mesh_cfg_t cfg = MESH_INIT_CONFIG_DEFAULT();
/* mesh ID */
memcpy((uint8_t *) &cfg.mesh_id, MESH_ID, 6);
/* router */
cfg.channel = CONFIG_MESH_CHANNEL;
cfg.router.ssid_len = strlen(CONFIG_MESH_ROUTER_SSID);
memcpy((uint8_t *) &cfg.router.ssid, CONFIG_MESH_ROUTER_SSID, cfg.router.ssid_len);
memcpy((uint8_t *) &cfg.router.password, CONFIG_MESH_ROUTER_PASSWD,
strlen(CONFIG_MESH_ROUTER_PASSWD));
/* mesh softAP */
ESP_ERROR_CHECK(esp_mesh_set_ap_authmode(CONFIG_MESH_AP_AUTHMODE));
cfg.mesh_ap.max_connection = CONFIG_MESH_AP_CONNECTIONS;
memcpy((uint8_t *) &cfg.mesh_ap.password, CONFIG_MESH_AP_PASSWD,
strlen(CONFIG_MESH_AP_PASSWD));
ESP_ERROR_CHECK(esp_mesh_set_config(&cfg));
ESP_ERROR_CHECK(esp_base_mac_addr_get(ownMAC));
ESP_LOGI(MESH_TAG, "Own MAC: \"0x%x, 0x%x, 0x%x, 0x%x, 0x%x, 0x%x\" ", ownMAC[0], ownMAC[1], ownMAC[2], ownMAC[3], ownMAC[4], ownMAC[5]);
/* mesh start */
ESP_ERROR_CHECK(esp_mesh_start());
ESP_LOGI(MESH_TAG, "mesh starts successfully, heap:%d, %s<%d>%s, ps:%d\n", esp_get_minimum_free_heap_size(),
esp_mesh_is_root_fixed() ? "root fixed" : "root not fixed",
esp_mesh_get_topology(), esp_mesh_get_topology() ? "(chain)":"(tree)", esp_mesh_is_ps_enabled());
for(;;) {
if(gpio_get_level(0) == 0){
break;
}
vTaskDelay(1000 / portTICK_PERIOD_MS);
}
xTaskCreate(&test, "test_task", 8192, NULL, 5, NULL);
}

43
sdkconfig
View File

@ -32,7 +32,7 @@ CONFIG_APP_COMPILE_TIME_DATE=y
# CONFIG_APP_EXCLUDE_PROJECT_VER_VAR is not set # CONFIG_APP_EXCLUDE_PROJECT_VER_VAR is not set
# CONFIG_APP_EXCLUDE_PROJECT_NAME_VAR is not set # CONFIG_APP_EXCLUDE_PROJECT_NAME_VAR is not set
CONFIG_APP_PROJECT_VER_FROM_CONFIG=y CONFIG_APP_PROJECT_VER_FROM_CONFIG=y
CONFIG_APP_PROJECT_VER="0.0.0" CONFIG_APP_PROJECT_VER="0.0.1"
CONFIG_APP_RETRIEVE_LEN_ELF_SHA=16 CONFIG_APP_RETRIEVE_LEN_ELF_SHA=16
# end of Application manager # end of Application manager
@ -67,11 +67,12 @@ CONFIG_BOOTLOADER_RESERVE_RTC_SIZE=0
# #
# Security features # Security features
# #
CONFIG_SECURE_SIGNED_ON_BOOT=y
CONFIG_SECURE_SIGNED_ON_UPDATE=y CONFIG_SECURE_SIGNED_ON_UPDATE=y
CONFIG_SECURE_SIGNED_APPS=y CONFIG_SECURE_SIGNED_APPS=y
CONFIG_SECURE_SIGNED_APPS_NO_SECURE_BOOT=y CONFIG_SECURE_SIGNED_APPS_NO_SECURE_BOOT=y
CONFIG_SECURE_SIGNED_APPS_ECDSA_SCHEME=y CONFIG_SECURE_SIGNED_APPS_ECDSA_SCHEME=y
# CONFIG_SECURE_SIGNED_ON_BOOT_NO_SECURE_BOOT is not set CONFIG_SECURE_SIGNED_ON_BOOT_NO_SECURE_BOOT=y
CONFIG_SECURE_SIGNED_ON_UPDATE_NO_SECURE_BOOT=y CONFIG_SECURE_SIGNED_ON_UPDATE_NO_SECURE_BOOT=y
# CONFIG_SECURE_BOOT is not set # CONFIG_SECURE_BOOT is not set
CONFIG_SECURE_BOOT_BUILD_SIGNED_BINARIES=y CONFIG_SECURE_BOOT_BUILD_SIGNED_BINARIES=y
@ -127,7 +128,7 @@ CONFIG_ESPTOOLPY_MONITOR_BAUD=115200
CONFIG_PARTITION_TABLE_CUSTOM=y CONFIG_PARTITION_TABLE_CUSTOM=y
CONFIG_PARTITION_TABLE_CUSTOM_FILENAME="partitions.csv" CONFIG_PARTITION_TABLE_CUSTOM_FILENAME="partitions.csv"
CONFIG_PARTITION_TABLE_FILENAME="partitions.csv" CONFIG_PARTITION_TABLE_FILENAME="partitions.csv"
CONFIG_PARTITION_TABLE_OFFSET=0x8000 CONFIG_PARTITION_TABLE_OFFSET=0x10000
CONFIG_PARTITION_TABLE_MD5=y CONFIG_PARTITION_TABLE_MD5=y
# end of Partition Table # end of Partition Table
@ -149,6 +150,7 @@ CONFIG_MESH_PS_NETWORK_DUTY_APPLIED_ENTIRE=y
CONFIG_MESH_PS_NWK_DUTY_RULE=0 CONFIG_MESH_PS_NWK_DUTY_RULE=0
CONFIG_MESH_MAX_LAYER=6 CONFIG_MESH_MAX_LAYER=6
CONFIG_MESH_CHANNEL=13 CONFIG_MESH_CHANNEL=13
CONFIG_MESH_ID="00, 00, 00, 00, 00, 00"
CONFIG_MESH_ROUTER_SSID="labNet" CONFIG_MESH_ROUTER_SSID="labNet"
CONFIG_MESH_ROUTER_PASSWD="12345678" CONFIG_MESH_ROUTER_PASSWD="12345678"
CONFIG_WIFI_AUTH_WPA2_PSK=y CONFIG_WIFI_AUTH_WPA2_PSK=y
@ -157,9 +159,10 @@ CONFIG_MESH_AP_AUTHMODE=3
CONFIG_MESH_AP_PASSWD="qaws1234" CONFIG_MESH_AP_PASSWD="qaws1234"
CONFIG_MESH_AP_CONNECTIONS=6 CONFIG_MESH_AP_CONNECTIONS=6
CONFIG_MESH_ROUTE_TABLE_SIZE=50 CONFIG_MESH_ROUTE_TABLE_SIZE=50
CONFIG_MESH_MESSAGE_SIZE=1234
CONFIG_OTA_HTTPS_SERVER_COMMON_NAME="ota.hendrikschutter.com" CONFIG_OTA_HTTPS_SERVER_COMMON_NAME="ota.hendrikschutter.com"
CONFIG_OTA_HTTPS_SERVER_PORT="443" CONFIG_OTA_HTTPS_SERVER_PORT="443"
CONFIG_OTA_HTTPS_URL="https://ota.hendrikschutter.com/hello-world.bin" CONFIG_OTA_HTTPS_URL="https://ota.hendrikschutter.com/mesh_ota.bin"
CONFIG_OTA_HTTPS_AUTH="b3RhOnB3" CONFIG_OTA_HTTPS_AUTH="b3RhOnB3"
# end of Mesh OTA Configuration # end of Mesh OTA Configuration
@ -361,6 +364,7 @@ CONFIG_ESP_CONSOLE_UART_DEFAULT=y
# CONFIG_ESP_CONSOLE_UART_CUSTOM is not set # CONFIG_ESP_CONSOLE_UART_CUSTOM is not set
# CONFIG_ESP_CONSOLE_NONE is not set # CONFIG_ESP_CONSOLE_NONE is not set
CONFIG_ESP_CONSOLE_UART=y CONFIG_ESP_CONSOLE_UART=y
CONFIG_ESP_CONSOLE_MULTIPLE_UART=y
CONFIG_ESP_CONSOLE_UART_NUM=0 CONFIG_ESP_CONSOLE_UART_NUM=0
CONFIG_ESP_CONSOLE_UART_BAUDRATE=115200 CONFIG_ESP_CONSOLE_UART_BAUDRATE=115200
CONFIG_ESP_INT_WDT=y CONFIG_ESP_INT_WDT=y
@ -604,7 +608,8 @@ CONFIG_FREERTOS_IDLE_TASK_STACKSIZE=2304
CONFIG_FREERTOS_ISR_STACKSIZE=1536 CONFIG_FREERTOS_ISR_STACKSIZE=1536
# CONFIG_FREERTOS_LEGACY_HOOKS is not set # CONFIG_FREERTOS_LEGACY_HOOKS is not set
CONFIG_FREERTOS_MAX_TASK_NAME_LEN=16 CONFIG_FREERTOS_MAX_TASK_NAME_LEN=16
# CONFIG_FREERTOS_SUPPORT_STATIC_ALLOCATION is not set CONFIG_FREERTOS_SUPPORT_STATIC_ALLOCATION=y
# CONFIG_FREERTOS_ENABLE_STATIC_TASK_CLEAN_UP is not set
CONFIG_FREERTOS_TIMER_TASK_PRIORITY=1 CONFIG_FREERTOS_TIMER_TASK_PRIORITY=1
CONFIG_FREERTOS_TIMER_TASK_STACK_DEPTH=2048 CONFIG_FREERTOS_TIMER_TASK_STACK_DEPTH=2048
CONFIG_FREERTOS_TIMER_QUEUE_LENGTH=10 CONFIG_FREERTOS_TIMER_QUEUE_LENGTH=10
@ -701,7 +706,6 @@ CONFIG_LWIP_LOOPBACK_MAX_PBUFS=8
# #
# TCP # TCP
# #
CONFIG_LWIP_TCP_ISN_HOOK=y
CONFIG_LWIP_MAX_ACTIVE_TCP=16 CONFIG_LWIP_MAX_ACTIVE_TCP=16
CONFIG_LWIP_MAX_LISTENING_TCP=16 CONFIG_LWIP_MAX_LISTENING_TCP=16
CONFIG_LWIP_TCP_HIGH_SPEED_RETRANSMISSION=y CONFIG_LWIP_TCP_HIGH_SPEED_RETRANSMISSION=y
@ -729,6 +733,14 @@ CONFIG_LWIP_MAX_UDP_PCBS=16
CONFIG_LWIP_UDP_RECVMBOX_SIZE=6 CONFIG_LWIP_UDP_RECVMBOX_SIZE=6
# end of UDP # end of UDP
#
# Checksums
#
# CONFIG_LWIP_CHECKSUM_CHECK_IP is not set
# CONFIG_LWIP_CHECKSUM_CHECK_UDP is not set
CONFIG_LWIP_CHECKSUM_CHECK_ICMP=y
# end of Checksums
CONFIG_LWIP_TCPIP_TASK_STACK_SIZE=3072 CONFIG_LWIP_TCPIP_TASK_STACK_SIZE=3072
CONFIG_LWIP_TCPIP_TASK_AFFINITY_NO_AFFINITY=y CONFIG_LWIP_TCPIP_TASK_AFFINITY_NO_AFFINITY=y
# CONFIG_LWIP_TCPIP_TASK_AFFINITY_CPU0 is not set # CONFIG_LWIP_TCPIP_TASK_AFFINITY_CPU0 is not set
@ -761,6 +773,20 @@ CONFIG_LWIP_SNTP_UPDATE_DELAY=3600000
CONFIG_LWIP_ESP_LWIP_ASSERT=y CONFIG_LWIP_ESP_LWIP_ASSERT=y
#
# Hooks
#
# CONFIG_LWIP_HOOK_TCP_ISN_NONE is not set
CONFIG_LWIP_HOOK_TCP_ISN_DEFAULT=y
# CONFIG_LWIP_HOOK_TCP_ISN_CUSTOM is not set
CONFIG_LWIP_HOOK_IP6_ROUTE_NONE=y
# CONFIG_LWIP_HOOK_IP6_ROUTE_DEFAULT is not set
# CONFIG_LWIP_HOOK_IP6_ROUTE_CUSTOM is not set
CONFIG_LWIP_HOOK_NETCONN_EXT_RESOLVE_NONE=y
# CONFIG_LWIP_HOOK_NETCONN_EXT_RESOLVE_DEFAULT is not set
# CONFIG_LWIP_HOOK_NETCONN_EXT_RESOLVE_CUSTOM is not set
# end of Hooks
# #
# Debug # Debug
# #
@ -771,8 +797,10 @@ CONFIG_LWIP_ESP_LWIP_ASSERT=y
# CONFIG_LWIP_SOCKETS_DEBUG is not set # CONFIG_LWIP_SOCKETS_DEBUG is not set
# CONFIG_LWIP_IP_DEBUG is not set # CONFIG_LWIP_IP_DEBUG is not set
# CONFIG_LWIP_ICMP_DEBUG is not set # CONFIG_LWIP_ICMP_DEBUG is not set
# CONFIG_LWIP_DHCP_DEBUG is not set
# CONFIG_LWIP_IP6_DEBUG is not set # CONFIG_LWIP_IP6_DEBUG is not set
# CONFIG_LWIP_ICMP6_DEBUG is not set # CONFIG_LWIP_ICMP6_DEBUG is not set
# CONFIG_LWIP_TCP_DEBUG is not set
# end of Debug # end of Debug
# end of LWIP # end of LWIP
@ -1081,6 +1109,7 @@ CONFIG_WPA_MBEDTLS_CRYPTO=y
# CONFIG_WPA_DEBUG_PRINT is not set # CONFIG_WPA_DEBUG_PRINT is not set
# CONFIG_WPA_TESTING_OPTIONS is not set # CONFIG_WPA_TESTING_OPTIONS is not set
# CONFIG_WPA_WPS_WARS is not set # CONFIG_WPA_WPS_WARS is not set
# CONFIG_WPA_11KV_SUPPORT is not set
# end of Supplicant # end of Supplicant
# end of Component config # end of Component config
@ -1203,7 +1232,7 @@ CONFIG_MB_EVENT_QUEUE_TIMEOUT=20
CONFIG_MB_TIMER_PORT_ENABLED=y CONFIG_MB_TIMER_PORT_ENABLED=y
CONFIG_MB_TIMER_GROUP=0 CONFIG_MB_TIMER_GROUP=0
CONFIG_MB_TIMER_INDEX=0 CONFIG_MB_TIMER_INDEX=0
# CONFIG_SUPPORT_STATIC_ALLOCATION is not set # CONFIG_ENABLE_STATIC_TASK_CLEAN_UP_HOOK is not set
CONFIG_TIMER_TASK_PRIORITY=1 CONFIG_TIMER_TASK_PRIORITY=1
CONFIG_TIMER_TASK_STACK_DEPTH=2048 CONFIG_TIMER_TASK_STACK_DEPTH=2048
CONFIG_TIMER_QUEUE_LENGTH=10 CONFIG_TIMER_QUEUE_LENGTH=10

15
style_code.sh Normal file
View File

@ -0,0 +1,15 @@
#! /bin/bash
cd main
astyle --style=gnu *.c
astyle --style=gnu *.h
cd ..
cd components/mesh_ota
astyle --style=gnu *.c
cd include
astyle --style=gnu *.h

32
test/sdkconfig
View File

@ -321,6 +321,7 @@ CONFIG_ESP_CONSOLE_UART_DEFAULT=y
# CONFIG_ESP_CONSOLE_UART_CUSTOM is not set # CONFIG_ESP_CONSOLE_UART_CUSTOM is not set
# CONFIG_ESP_CONSOLE_NONE is not set # CONFIG_ESP_CONSOLE_NONE is not set
CONFIG_ESP_CONSOLE_UART=y CONFIG_ESP_CONSOLE_UART=y
CONFIG_ESP_CONSOLE_MULTIPLE_UART=y
CONFIG_ESP_CONSOLE_UART_NUM=0 CONFIG_ESP_CONSOLE_UART_NUM=0
CONFIG_ESP_CONSOLE_UART_BAUDRATE=115200 CONFIG_ESP_CONSOLE_UART_BAUDRATE=115200
CONFIG_ESP_INT_WDT=y CONFIG_ESP_INT_WDT=y
@ -560,7 +561,8 @@ CONFIG_FREERTOS_IDLE_TASK_STACKSIZE=2304
CONFIG_FREERTOS_ISR_STACKSIZE=1536 CONFIG_FREERTOS_ISR_STACKSIZE=1536
# CONFIG_FREERTOS_LEGACY_HOOKS is not set # CONFIG_FREERTOS_LEGACY_HOOKS is not set
CONFIG_FREERTOS_MAX_TASK_NAME_LEN=16 CONFIG_FREERTOS_MAX_TASK_NAME_LEN=16
# CONFIG_FREERTOS_SUPPORT_STATIC_ALLOCATION is not set CONFIG_FREERTOS_SUPPORT_STATIC_ALLOCATION=y
# CONFIG_FREERTOS_ENABLE_STATIC_TASK_CLEAN_UP is not set
CONFIG_FREERTOS_TIMER_TASK_PRIORITY=1 CONFIG_FREERTOS_TIMER_TASK_PRIORITY=1
CONFIG_FREERTOS_TIMER_TASK_STACK_DEPTH=2048 CONFIG_FREERTOS_TIMER_TASK_STACK_DEPTH=2048
CONFIG_FREERTOS_TIMER_QUEUE_LENGTH=10 CONFIG_FREERTOS_TIMER_QUEUE_LENGTH=10
@ -657,7 +659,6 @@ CONFIG_LWIP_LOOPBACK_MAX_PBUFS=8
# #
# TCP # TCP
# #
CONFIG_LWIP_TCP_ISN_HOOK=y
CONFIG_LWIP_MAX_ACTIVE_TCP=16 CONFIG_LWIP_MAX_ACTIVE_TCP=16
CONFIG_LWIP_MAX_LISTENING_TCP=16 CONFIG_LWIP_MAX_LISTENING_TCP=16
CONFIG_LWIP_TCP_HIGH_SPEED_RETRANSMISSION=y CONFIG_LWIP_TCP_HIGH_SPEED_RETRANSMISSION=y
@ -685,6 +686,14 @@ CONFIG_LWIP_MAX_UDP_PCBS=16
CONFIG_LWIP_UDP_RECVMBOX_SIZE=6 CONFIG_LWIP_UDP_RECVMBOX_SIZE=6
# end of UDP # end of UDP
#
# Checksums
#
# CONFIG_LWIP_CHECKSUM_CHECK_IP is not set
# CONFIG_LWIP_CHECKSUM_CHECK_UDP is not set
CONFIG_LWIP_CHECKSUM_CHECK_ICMP=y
# end of Checksums
CONFIG_LWIP_TCPIP_TASK_STACK_SIZE=3072 CONFIG_LWIP_TCPIP_TASK_STACK_SIZE=3072
CONFIG_LWIP_TCPIP_TASK_AFFINITY_NO_AFFINITY=y CONFIG_LWIP_TCPIP_TASK_AFFINITY_NO_AFFINITY=y
# CONFIG_LWIP_TCPIP_TASK_AFFINITY_CPU0 is not set # CONFIG_LWIP_TCPIP_TASK_AFFINITY_CPU0 is not set
@ -717,6 +726,20 @@ CONFIG_LWIP_SNTP_UPDATE_DELAY=3600000
CONFIG_LWIP_ESP_LWIP_ASSERT=y CONFIG_LWIP_ESP_LWIP_ASSERT=y
#
# Hooks
#
# CONFIG_LWIP_HOOK_TCP_ISN_NONE is not set
CONFIG_LWIP_HOOK_TCP_ISN_DEFAULT=y
# CONFIG_LWIP_HOOK_TCP_ISN_CUSTOM is not set
CONFIG_LWIP_HOOK_IP6_ROUTE_NONE=y
# CONFIG_LWIP_HOOK_IP6_ROUTE_DEFAULT is not set
# CONFIG_LWIP_HOOK_IP6_ROUTE_CUSTOM is not set
CONFIG_LWIP_HOOK_NETCONN_EXT_RESOLVE_NONE=y
# CONFIG_LWIP_HOOK_NETCONN_EXT_RESOLVE_DEFAULT is not set
# CONFIG_LWIP_HOOK_NETCONN_EXT_RESOLVE_CUSTOM is not set
# end of Hooks
# #
# Debug # Debug
# #
@ -727,8 +750,10 @@ CONFIG_LWIP_ESP_LWIP_ASSERT=y
# CONFIG_LWIP_SOCKETS_DEBUG is not set # CONFIG_LWIP_SOCKETS_DEBUG is not set
# CONFIG_LWIP_IP_DEBUG is not set # CONFIG_LWIP_IP_DEBUG is not set
# CONFIG_LWIP_ICMP_DEBUG is not set # CONFIG_LWIP_ICMP_DEBUG is not set
# CONFIG_LWIP_DHCP_DEBUG is not set
# CONFIG_LWIP_IP6_DEBUG is not set # CONFIG_LWIP_IP6_DEBUG is not set
# CONFIG_LWIP_ICMP6_DEBUG is not set # CONFIG_LWIP_ICMP6_DEBUG is not set
# CONFIG_LWIP_TCP_DEBUG is not set
# end of Debug # end of Debug
# end of LWIP # end of LWIP
@ -1037,6 +1062,7 @@ CONFIG_WPA_MBEDTLS_CRYPTO=y
# CONFIG_WPA_DEBUG_PRINT is not set # CONFIG_WPA_DEBUG_PRINT is not set
# CONFIG_WPA_TESTING_OPTIONS is not set # CONFIG_WPA_TESTING_OPTIONS is not set
# CONFIG_WPA_WPS_WARS is not set # CONFIG_WPA_WPS_WARS is not set
# CONFIG_WPA_11KV_SUPPORT is not set
# end of Supplicant # end of Supplicant
# end of Component config # end of Component config
@ -1155,7 +1181,7 @@ CONFIG_MB_EVENT_QUEUE_TIMEOUT=20
CONFIG_MB_TIMER_PORT_ENABLED=y CONFIG_MB_TIMER_PORT_ENABLED=y
CONFIG_MB_TIMER_GROUP=0 CONFIG_MB_TIMER_GROUP=0
CONFIG_MB_TIMER_INDEX=0 CONFIG_MB_TIMER_INDEX=0
# CONFIG_SUPPORT_STATIC_ALLOCATION is not set # CONFIG_ENABLE_STATIC_TASK_CLEAN_UP_HOOK is not set
CONFIG_TIMER_TASK_PRIORITY=1 CONFIG_TIMER_TASK_PRIORITY=1
CONFIG_TIMER_TASK_STACK_DEPTH=2048 CONFIG_TIMER_TASK_STACK_DEPTH=2048
CONFIG_TIMER_QUEUE_LENGTH=10 CONFIG_TIMER_QUEUE_LENGTH=10