HTTPS server

This code example demonstrates the implementation of an HTTPS server with PSoC™ 6 MCU and AIROC™ CYW43xxx Wi-Fi & Bluetooth® combo chips.

It employs the HTTPS server middleware library, which takes care of all the underlying socket connections with the HTTPS client. In this example, the HTTPS server establishes a secure connection with an HTTPS client through an SSL handshake. After the SSL handshake completes successfully, the HTTPS client can make GET, POST, and PUT requests with the server.

View this README on GitHub.

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Requirements

• ModusToolbox™ software v3.0 or later (tested with v3.0)
• Board support package (BSP) minimum required version: 4.0.0
• Programming language: C
• Associated parts: All PSoC™ 6 MCU parts, AIROC™ CYW20735 Bluetooth® & Bluetooth® LE system on chip, AIROC™ CYW20819 Bluetooth® & Bluetooth® LE system on chip, AIROC™ CYW43012 Wi-Fi & Bluetooth® combo chip, AIROC™ CYW4343W Wi-Fi & Bluetooth® combo chip

Supported toolchains (make variable 'TOOLCHAIN')

• GNU Arm® embedded compiler v10.3.1 (GCC_ARM) - Default value of TOOLCHAIN
• Arm® compiler v6.16 (ARM)
• IAR C/C++ compiler v9.30.1 (IAR)

Supported kits (make variable 'TARGET')

• PSoC™ 6 Wi-Fi Bluetooth® prototyping kit (CY8CPROTO-062-4343W) - Default value of TARGET
• PSoC™ 6 Wi-Fi Bluetooth® pioneer kit (CY8CKIT-062-WIFI-BT)
• PSoC™ 62S2 Wi-Fi Bluetooth® pioneer kit (CY8CKIT-062S2-43012)
• PSoC™ 62S1 Wi-Fi Bluetooth® pioneer kit (CYW9P62S1-43438EVB-01)
• PSoC™ 62S1 Wi-Fi Bluetooth® pioneer kit (CYW9P62S1-43012EVB-01)
• PSoC™ 62S3 Wi-Fi Bluetooth® prototyping kit (CY8CPROTO-062S3-4343W)
• PSoC™ 64 "Secure Boot" Wi-Fi Bluetooth® pioneer kit (CY8CKIT-064B0S2-4343W)
• PSoC™ 62S2 evaluation kit (CY8CEVAL-062S2-LAI-4373M2, CY8CEVAL-062S2-LAI-43439M2, CY8CEVAL-062S2-MUR-43439M2)

Hardware setup

This example uses the board's default configuration. See the kit user guide to ensure that the board is configured correctly.

Note: The PSoC™ 6 Bluetooth® LE pioneer kit (CY8CKIT-062-BLE) and the PSoC™ 6 Wi-Fi Bluetooth® pioneer kit (CY8CKIT-062-WIFI-BT) ship with KitProg2 installed. The ModusToolbox™ software requires KitProg3. Before using this code example, make sure that the board is upgraded to KitProg3. The tool and instructions are available in the Firmware Loader GitHub repository. If you do not upgrade, you will see an error like "unable to find CMSIS-DAP device" or "KitProg firmware is out of date".

Software setup

Install a terminal emulator if you don't have one. Instructions in this document use Tera Term.

Note: This code example also uses the cURL utility to test the HTTPS server. This utility helps to send HTTPS GET, POST, and PUT requests to the server. The cURL utility (version 7.59.0) is already shipped with the ModusToolbox™ software v2.2 or later; it is available under {ModusToolbox™ install directory}/tools_<version>/modus-shell/bin).

Using the code example

Create the project and open it using one of the following:

project-creator-cli --board-id CY8CKIT-062-WIFI-BT --app-id mtb-example-wifi-https-server --user-app-name HttpsServer --target-dir "C:/mtb_projects"

~/ModusToolbox/tools_3.0/library-manager/library-manager-cli --project "C:/mtb_projects/HttpsServer" --add-bsp-name CY8CPROTO-062-4343W --add-bsp-version "latest-v4.X" --add-bsp-location "local"

~/ModusToolbox/tools_3.0/library-manager/library-manager-cli --project "C:/mtb_projects/HttpsServer" --set-active-bsp APP_CY8CPROTO-062-4343W

Operation

1. Connect the board to your PC using the provided USB cable through the KitProg3 USB connector.

2. Open secure_http_server.h and modify the WIFI_SSID, WIFI_PASSWORD, and WIFI_SECURITY_TYPE macros to match the credentials of the Wi-Fi network that you want to connect to.

   All possible security types are defined in the cy_wcm_security_t structure in the cy_wcm.h file.

3. Because this code example uses a self-signed SSL certificate, you need to generate the certificates required by the HTTPS server and client so that they can successfully establish a secure HTTPS connection. Follow the steps provided in a separate section that explains how to generate the certificates.

4. Open the source/secure_keys.h file and do the following:

   1. Modify keySERVER_CERTIFICATE_PEM with the contents from the mysecurehttpserver.local.crt file generated in Step 3.
   2. Modify keySERVER_PRIVATE_KEY_PEM with the contents from the mysecurehttpserver.local.key file generated in Step 3.
   3. Modify keyCLIENT_ROOTCA_PEM with the contents from the rootCA.crt file generated in Step 3.

5. Open a terminal program and select the KitProg3 COM port. Set the serial port parameters to 8N1 and 115200 baud.

6. Program the board using one of the following:

   Using Eclipse IDE for ModusToolbox™ software

   1. Select the application project in the Project Explorer.

   2. In the Quick Panel, scroll down, and click <Application Name> Program (KitProg3_MiniProg4).

   Using CLI

   From the terminal, execute the make program command to build and program the application using the default toolchain to the default target. The default toolchain is specified in the application's Makefile but you can override this value manually:

   make program TOOLCHAIN=<toolchain>
   

   Example:

   make program TOOLCHAIN=GCC_ARM
   

7. After programming, the application starts automatically. Verify that the following logs appear on the serial terminal:

   Info: ===================================
   Info: HTTPS Server
   Info: ===================================
   
   WLAN MAC Address : A0:C9:A0:3D:D3:6A
   WLAN Firmware    : wl0: Jan 30 2020 21:41:53 version 7.45.98.95 (r724303 CY) FWID 01-5afc8c1e
   WLAN CLM         : API: 12.2 Data: 9.10.39 Compiler: 1.29.4 ClmImport: 1.36.3 Creation: 2020-01-30 21:30:05
   WHD VERSION      : v1.90.2 : v1.90.2 : GCC 7.2 : 2020-04-13 02:49:57 -0500
   Info: Wi-Fi initialization is successful
   Info: Join to AP: WIFI_SSID
   Info: Successfully joined Wi-Fi network WIFI_SSID
   Info: Assigned IP address: 192.168.0.12
   Info: HTTPS server has successfully started. The server is running at URL https://mysecurehttpserver.local:50007
   

8. The client needs to install rootCA.crt to trust the HTTPS website and its own certificate mysecurehttpclient.pfx. The .pfx file bundles the client certificate and key in PKCS format.

   Do the following to install the certificates on the client machine. In this code example, the HTTPS server has two types of clients: one uses the cURL utility while the other uses a web browser.

   • cURL utility:

     • Ensure that the cURL utility has access to the rootCA.crt, mysecurehttpclient.crt, and mysecurehttpclient.key files generated in Step 3 of the operation section. cURL commands can be invoked from anywhere in the modus-shell. The command takes the argument such as --cacert, --cert, and --key, which indicates the file path to rootCA.crt, mysecurehttpclient.crt, and mysecurehttpclient.key respectively.

   • Web browser:

     • Mozilla Firefox:

       1. Select Options > Privacy & Security (Windows) or Preferences > Privacy & Security (macOS and Ubuntu).

       2. Find the Certificates section and then click View Certificates.

          The browser displays the Certificate Manager dialog.

       3. Click Import and select the rootCA.crt file generated in Step 3 of the operation section and click Open.

       4. Trust this certificate authority to identify websites and email users and click OK.

          The rootCA.crt is now installed.

       5. Similarly, import the client certificate mysecurehttpclient.pfx file, generated in Step 3 of the operation section, under Your Certificates on the Certificate Manager window. The certificate was generated with an empty password; therefore, leave it empty if it asks for a password during import.

     • Google Chrome and Internet Explorer on Windows:

       1. In the Run dialog (click Win key + R), type certmgr.msc and click OK.

          The Windows Certificate Manager application opens.

       2. Navigate to the Trusted Root Certification Authorities/Certificates folder.

       3. Go to Action > All Tasks > Import and click Next.

       4. Select the rootCA.crt file generated in Step 3 of the operation section. Make sure to change the file type to All Files to find the rootCA.crt file. Click Open.

       5. Select the certification store as Trusted Root Certification Authorities and click Finish.

       6. Click Yes to the security warning window to acknowledge that you trust rootCA.crt to allow its websites and email users.

          The rootCA.crt is now installed.

       7. Similarly, import the client certificate mysecurehttpclient.pfx file, generated in Step 3 of the operation section, under the Personal category.

     • Google Chrome (Ubuntu):

       1. Select Settings > Show Advanced Settings > HTTPS/SSL. Click Manage Certificates under the Security tab.

       2. In the Certificate Manager window, click Import under the Authorities tab.

       3. Select the rootCA.crt file generated in Step 3 of the operation section. Make sure to change the file type to All Files to find the rootCA.crt file. Click Open.

       4. Trust this certificate authority to identify websites and email users and click OK.

          The rootCA.crt is now installed.

       5. Similarly, import the client certificate mysecurehttpclient.pfx file, generated in Step 3 of the operation, under the Personal category.

     • Google Chrome (macOS):

       1. Open Finder > Applications > Utilities > Keychain Access.

       2. Select the System keychain.

       3. Open File > Import Items, and import the certificate file rootCA.crt, generated in Step 3 of the operation section, into the System keychain.

       4. Right-click the certificate and select Get Info.

          A certificate information window appears.

       5. Expand the Trust category and select Always Trust to trust this certificate authority.

       6. Similarly, import the client certificate mysecurehttpclient.pfx file, generated in Step 3 of the operation section, under MyCertificates category. The certificate was generated with an empty password; therefore, leave it empty if it asks for a password.

     Notes:

     • Browsers might need a restart after importing the certificate.

     • When importing the mysecurehttpclient.pfx file, the Chrome browser asks the user to set the CryptoAPI Private Key to protect the client certificate key from accessing it by the browser. The browser is given access to the client's private key only after entering the correct key and allowing access by the user.

9. Ensure that your PC is connected to the same Wi-Fi access point that you have configured in Step 2.

10. Enter https://mysecurehttpserver.local:50007 in the web browser to access the HTTPS server webpage.

Test the HTTPS server

Using a web browser:

1. Enter the URL https://mysecurehttpserver.local:50007. This opens the HTML page; it will look as follows:

   Figure 1. HTTPS web page

   

2. Click Get LED status to send an HTTPS GET command to the server running on the kit.

   The server returns the current LED status on the kit as a response. Note that entering the URL itself will send a GET command to the server to get the HTML page.

3. Click Toggle LED to send an HTTPS POST command to the server running on the kit.

   The server acts on the command request and toggles the LED on the kit.

Using the cURL utility:

1. Open modus-shell application ({ModusToolbox™ install directory}/tools_<version>/modus-shell/Cygwin.bat).

2. Set the path to rootCA.crt, mysecurehttpclient.crt, and mysecurehttpclient.key in a variable:

   PATH_TO_ROOTCA="<Path to rootCA.crt file>"
   

   PATH_TO_CLIENT_CRT="<Path to mysecurehttpclient.crt file>"
   

   PATH_TO_CLIENT_KEY="<Path to mysecurehttpclient.key file>"
   

3. Set the path to the HTTPS web page URL in a variable:

   HTTPS_SERVER_URL="https://mysecurehttpserver.local:50007"
   

   where mysecurehttpserver.local is the HTTPS server domain name; 50007 is the HTTPS port number defined in the secure_http_server.h file in the HTTPS_PORT macro.

4. Use the following cURL commands to test HTTPS commands with the HTTPS server:

   1. HTTPS GET: Get the kit's LED status (ON or OFF).

      curl --cacert $PATH_TO_ROOTCA --cert $PATH_TO_CLIENT_CRT --key $PATH_TO_CLIENT_KEY -X GET $HTTPS_SERVER_URL --output -
      

   2. Verify that the HTTPS server responds with the following HTML output. This contains the LED status (ON or OFF) of the kit:

      <!DOCTYPE html><html><head><title>HTTPS Server Demo</title></head><body><h1>HTTPS Server Demo</h1><form method="get"><fieldset><legend>HTTPS GET</legend><input type="submit" value="Get LED status"/><input type="text" name="led_status" value="OFF" size="3" readonly/></br></br></fieldset></br></form><form method="post"><fieldset><legend>HTTPS POST</legend><input type="submit" name="toggle_led" value="Toggle LED"/></br></br></fieldset></br></form></body></html>
      

   3. HTTPS POST: Toggle the LED (ON or OFF) on the :

      curl --cacert $PATH_TO_ROOTCA --cert $PATH_TO_CLIENT_CRT --key $PATH_TO_CLIENT_KEY -X POST $HTTPS_SERVER_URL --output -
      

   4. Verify that the HTTPS server responds with the following HTML output. The response contains the LED status (ON or OFF) of the last GET request:

      <!DOCTYPE html><html><head><title>HTTPS Server Demo</title></head><body><h1>HTTPS Server Demo</h1><form method="get"><fieldset><legend>HTTPS GET</legend><input type="submit" value="Get LED status"/><input type="text" name="led_status" value="OFF" size="3" readonly/></br></br></fieldset></br></form><form method="post"><fieldset><legend>HTTPS POST</legend><input type="submit" name="toggle_led" value="Toggle LED"/></br></br></fieldset></br></form></body></html>
      

   5. HTTPS PUT: Register a new HTTP resource. The HTTPS server creates a new resource called myhellomessage:

      curl --cacert $PATH_TO_ROOTCA --cert $PATH_TO_CLIENT_CRT --key $PATH_TO_CLIENT_KEY -X PUT -d "/myhellomessage=Hello!" $HTTPS_SERVER_URL --output -
      

   6. Verify the newly created resource by sending an HTTPS GET request:

      curl --cacert $PATH_TO_ROOTCA --cert $PATH_TO_CLIENT_CRT --key $PATH_TO_CLIENT_KEY -X GET $HTTPS_SERVER_URL/myhellomessage --output -
      

   7. Verify that the HTTPS server responds with a 'Hello' text message:

      Hello!
      

Debugging

You can debug the example to step through the code. In the IDE, use the <Application Name> Debug (KitProg3_MiniProg4) configuration in the Quick Panel. For details, see the "Program and debug" section in the Eclipse IDE for ModusToolbox™ software user guide.

Note: (Only while debugging) On the CM4 CPU, some code in main() may execute before the debugger halts at the beginning of main(). This means that some code executes twice – once before the debugger stops execution, and again after the debugger resets the program counter to the beginning of main(). See KBA231071 to learn about this and for the workaround.

Known issues

An issue has been observed with the multicast domain name system (mDNS) when the device joins the home AP (D-Link DIR-816 and TP-Link Archer C20 APs). To work around this issue, connect the kit to a mobile hotspot if the device reports the following error when joining the AP.

Info: Wi-Fi initialization is successful
Info: Join to AP: WIFI_SSID
Function whd_wifi_unregister_multicast_address failed at line 2834 checkres = 101580800
Received buffer request ID: 42 (expectation: 42)
whd_cdc_send_ioctl is already timed out, drop the buffer

This issue will be addressed in a future update of this code example.

Design and implementation

Resources and settings

Table 1. Application resources

This example uses the Arm® Cortex®-M4 (CM4) CPU of PSoC™ 6 MCU to start the HTTPS server task. At device reset, the default Cortex®-M0+ (CM0+) application enables the CM4 CPU and configures the CM0+ CPU to go to sleep.

In this example, the HTTPS server establishes a secure connection with a web browser or cURL client through an SSL handshake. During the SSL handshake, the server presents its SSL certificate for verification and verifies the incoming client identity. This example uses mDNS provided by the lwIP open-source TCP/IP network stack. mDNS helps in resolving the domain name of the HTTPS server to an IP address in the local network. This code example supports only IPv4 with mDNS.

You can define the maximum number of HTTPS page resources for the HTTPS server in the application Makefile, as shown below. The HTTPS server library maintains the database of pages based on this value.

DEFINES+=MAX_NUMBER_OF_HTTP_SERVER_RESOURCES=10

Note that if the MAX_NUMBER_OF_HTTP_SERVER_RESOURCES value is not defined in the application Makefile, the HTTPS server will set it to 10 by default. This code example does not define this parameter in the application Makefile; therefore, the application uses the default value of 10. This depends on the availability of memory on the MCU device.

Creating a self-signed SSL certificate

The HTTPS server demonstrated in this example uses a self-signed SSL certificate. This requires OpenSSL which is already preloaded in the ModusToolbox™ software installation. A Self-signed SSL certificate means that there is no third-party certificate issuing authority, commonly referred to as CA, involved in the authentication of the server. Clients connecting to the server must have a root CA certificate to verify and trust the websites defined by the certificate. Only when the client trusts the website, it can establish a secure connection with the HTTPS server.

Do the following to generate a self-signed SSL certificate:

Generate an SSL certificate and private key

Run the following script to generate the self-signed SSL certificate and private key.

Before invoking the following command, modify the OPENSSL_SUBJECT_INFO macro in the generate_ssl_certs.sh file to match your local domain configuration such as Country, State, Locality, Organization, Organization Unit name, and Common Name. This macro is used by the openssl commands when generating the certificate.

./generate_ssl_certs.sh

This will produce the following files:

The HTTPS server should be configured to take mysecurehttpserver.local.crt as the certificate, mysecurehttpserver.local.key as the private key, and rootCA.crt as the rootCA certificate.

You can either convert the values to strings manually following the format shown in source/secure_keys.h or use the HTML utility available here to convert the certificates and keys from PEM format to C string format. You need to clone the repository from GitHub to use the utility.

The rootCA.crt and mysecurehttpclient.pfx should be installed on the web browser clients which are trying to communicate with the HTTPS server. With cURL, the rootCA.crt, mysecurehttpclient.crt, and mysecurehttpclient.key can be passed as command-line arguments.

Related resources

Other resources

Infineon provides a wealth of data at www.infineon.com to help you select the right device, and quickly and effectively integrate it into your design.

For PSoC™ 6 MCU devices, see How to design with PSoC™ 6 MCU - KBA223067 in the Infineon Developer community.

Document history

Document title: CE230422 - HTTPS server

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