JacobBarthelmeh 015d47b9cd Merge pull request #8231 from LinuxJedi/STM32MP13 3 weeks ago
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README.md fbdb34a6e0 Add STM32MP13 to Cube IDE 1 month ago
STM32_Benchmarks.md cd0301fc66 Fixes for benchmark with small stack (RSA was being skipped). Added Thumb2 benchmarks for STM32H753. 10 months ago
default_conf.ftl fbdb34a6e0 Add STM32MP13 to Cube IDE 1 month ago
include.am ffb9a8b440 Improve the user_settings_template to incude Windows. Added STM32 configuration example. 3 years ago
main.c a3fb5029f8 clean up trailing whitespace and misplaced CRLFs, add missing final newlines, remove stray UTF8 nonprintables (BOMs) and ASCIIfy stray homoglyphs (spaces and apostrophes), guided by expanded coverage in wolfssl-multi-test check-source-text. 3 months ago
wolfssl_example.c cf450a3f37 Fix STM32 example broken in #8143. 1 month ago
wolfssl_example.h 31a6a2bf59 update copyright to 2024 5 months ago

README.md

wolfSSL STM32 Example for STM32 Cube IDE

This example includes:

  • wolfCrypt test
  • wolfCrypt benchmark
  • wolfSSL TLS client/server test using in-memory transfers

These examples use the Cube HAL for STM32.

Requirements

You need both the STM32 IDE and the STM32 initialization code generator (STM32CubeMX) tools. The STM32CubeMX tool is used to setup a project which is used by the IDE to make any required code level changes and program / debug the STM32.

STM32 Cube Pack

STM32 Cube Pack Installation

  1. Download wolfSSL Cube Pack
  2. Run the “STM32CubeMX” tool.
  3. Under “Manage software installations” pane on the right, click “INSTALL/REMOVE” button. This can be also found by clicking "Help" -> "Managed embedded software packages"
  4. From Local and choose “I-CUBE-wolfSSL.pack”.
  5. Accept the GPLv2 license. Contact wolfSSL at sales@wolfssl.com for a commercial license and support/maintenance.

STM32 Cube Pack Usage

  1. Create or open a Cube Project based on your hardware. See the sections below for creating a project and finding the example projects.
  2. Under “Software Packs” choose “Select Components”.
  3. Find and check all components for the wolfSSL.wolfSSL packs (wolfSSL / Core, wolfCrypt / Core and wolfCrypt / Test). Close
  4. Under the “Software Packs” section click on “wolfSSL.wolfSSL” and configure the parameters.
  5. For Cortex-M recommend “Math Configuration” -> “Single Precision Cortex-M Math” for the fastest option. If seeing error: r7 cannot be used in 'asm add -fomit-frame-pointer to the CFLAGS. This only happens in debug builds, because r7 is used for debug.
  6. Hit the "Generate Code" button
  7. Open the project in STM32CubeIDE
  8. The Benchmark example uses float. To enable go to "Project Properties" -> "C/C++ Build" -> "Settings" -> "Tool Settings" -> "MCU Settings" -> Check "Use float with printf".
  9. To enable printf make the main.c changes below in the STM32 Printf section.

Note: The STM32MP13 will likely require you to use DDR RAM, as well as enabling MMU and caches for optimum performance. Please see the STM32MP13.md file in wolfcrypt/src/port/st for more information on how to do this.

Creating your own STM32CubeMX configuration

If none of the examples fit your STM32 type then you can create your own in STM32CubeMX by doing the following:

  1. Create a project with the correct STM32 model.
  2. Click on the "Software Packs" drop down near the top and choose "Select Components".
  3. Expand the "wolfSSL" pack twice and check all the components. Then exit this menu.
  4. Under "System Core" select "SYS" and changed the "Timebase Source" to TIM1.
  5. Under "Timers" select "RTC" and make sure this is enabled.
  6. Under "Connectivity" enable whichever UART/USART you have a serial I/O connected to.
  7. Under "Middleware" select "FREERTOS" and change the interface to "CMSIS_V2".
    1. Increase the "TOTAL_HEAP_SIZE", preferably to 120000 but on smaller chips such as the F107 you may only be able to increase this to 40000.
    2. Enable "USE_MALLOC_FAILED_HOOK".
    3. Change "CHECK_FOR_STACK_OVERFLOW" to "Option2".
    4. Under "Tasks and Queues" select Add for a new task.
    5. Set the "Task Name" to "wolfCrypt".
    6. Set the "Stack Size" to 8960 or as high as you can close to that. The "Heap Usage" will show an error if this is too high.
    7. Set the "Entry Function" to "wolfCryptDemo".
    8. Set the "Code Generation Option" to "As external".
  8. In "Software Packs" select "wolfSSL" and change any options as required.
  9. Go to "Clock Configuration" and set the "HCLK" as high as the tool will let you.
  10. In "Project Manager" select the "STM32CubeIDE" toolchain.

When you get to the IDE make sure you edit wolfSSL.I-CUBE-wolfSSL_conf.h to set the HAL_CONSOLE_UART to the correct one for your configuration.

Configuration

The settings for the wolfSSL CubeMX pack are in the generated wolfSSL.I-CUBE-wolfSSL_conf.h file. An example of a generated file can be found at examples/configs/user_settings_stm32.h.

The template used for generation is IDE/STM32Cube/default_conf.ftl, which is stored in the pack here: STM32Cube/Repository/Packs/wolfSSL/wolfSSL/[Version]/CubeMX/templates/default_conf.ftl.

If the default settings for the Cube GUI are insufficient you can customize the build using one of these methods to prevent the changes from being overwritten when generating the code:

  • Copy the wolfSSL.I-CUBE-wolfSSL_conf.h to Core/Inc and rename to user_settings.h. Then add the preprocessor macro WOLFSSL_USER_SETTINGS to your project. This will use the user_settings.h instead of the generated configuration.

OR

  • Edit the source template file used for Cube pack generation here: STM32Cube/Repository/Packs/wolfSSL/wolfSSL/[Version]/CubeMX/templates/default_conf.ftl.

The section for "Hardware platform" may need to be adjusted depending on your processor and board:

  • To enable STM32F1 support define WOLFSSL_STM32F1.
  • To enable STM32F2 support define WOLFSSL_STM32F2.
  • To enable STM32F4 support define WOLFSSL_STM32F4.
  • To enable STM32F7 support define WOLFSSL_STM32F7.
  • To enable STM32L4 support define WOLFSSL_STM32L4.
  • To enable STM32L5 support define WOLFSSL_STM32L5.
  • To enable STM32H7 support define WOLFSSL_STM32H7.
  • To enable STM32WB support define WOLFSSL_STM32WB.
  • To enable STM32WL support define WOLFSSL_STM32WL.
  • To enable STM32U5 support define WOLFSSL_STM32U5.
  • To enable STM32H5 support define WOLFSSL_STM32H5.
  • To enable STM32MP13 support define WOLFSSL_STM32MP13.

To use the STM32 Cube HAL support make sure WOLFSSL_STM32_CUBEMX is defined.

The PKA acceleration for ECC is available on some U5, L5, WB55 and MP13 chips. This is enabled with WOLFSSL_STM32_PKA. You can see some of the benchmarks here.

To disable hardware crypto acceleration you can define:

  • NO_STM32_HASH
  • NO_STM32_CRYPTO
  • NO_STM32_RNG

To enable the latest Cube HAL support please define STM32_HAL_V2.

If you'd like to use the older Standard Peripheral library undefine WOLFSSL_STM32_CUBEMX.

With STM32 Cube HAL v2 some AES GCM hardware has a limitation for the AAD header, which must be a multiple of 4 bytes. If your HAL does not support CRYP_HEADERWIDTHUNIT_BYTE then consider adding STM32_AESGCM_PARTIAL if you are getting AES GCM authentication failures. This bug existed in v1.16.0 or later.

The STM32F7 v1.17.0 pack has a bug in the AES GCM code for handling of additional authentication data when not a multiple of 4 bytes. To patch see stm32f7xx_hal_cryp.c -> CRYP_GCMCCM_SetHeaderPhase:

diff --git a/stm32f7xx_hal_cryp.c b/stm32f7xx_hal_cryp.c
index 2ae42d0..9666f26 100644
--- a/stm32f7xx_hal_cryp.c
+++ b/stm32f7xx_hal_cryp.c
@@ -5600,7 +5600,6 @@ static HAL_StatusTypeDef CRYP_GCMCCM_SetHeaderPhase(CRYP_HandleTypeDef *hcryp, u
   uint32_t size_in_bytes;
   uint32_t tmp;
   uint32_t mask[12] = {0x0U, 0xFF000000U, 0xFFFF0000U, 0xFFFFFF00U,  /* 32-bit data type */
-                       0x0U, 0x0000FF00U, 0x0000FFFFU, 0xFF00FFFFU,  /* 16-bit data type */
                        0x0U, 0x000000FFU, 0x0000FFFFU, 0x00FFFFFFU}; /*  8-bit data type */

   /***************************** Header phase for GCM/GMAC or CCM *********************************/
@@ -5842,7 +5841,7 @@ static HAL_StatusTypeDef CRYP_GCMCCM_SetHeaderPhase(CRYP_HandleTypeDef *hcryp, u
       {
         /* Enter last bytes, padded with zeroes */
         tmp =  *(uint32_t *)(hcryp->Init.Header + hcryp->CrypHeaderCount);
-        tmp &= mask[(hcryp->Init.DataType * 2U) + (size_in_bytes % 4U)];
+        tmp &= mask[(hcryp->Init.HeaderWidthUnit * 4U) + (size_in_bytes % 4U)];
         hcryp->Instance->DINR = tmp;
         loopcounter++;
         /* Pad the data with zeros to have a complete block */

If you are using FreeRTOS make sure your FreeRTOSConfig.h has its configTOTAL_HEAP_SIZE increased.

The TLS client/server benchmark example requires about 76 KB for allocated tasks (with stack) and peak heap. This uses both a TLS client and server to test a TLS connection locally for each enabled TLS cipher suite.

Example IDE/STM32Cube/wolfssl_example.c Output

....MENU

.t. WolfCrypt Test
.b. WolfCrypt Benchmark
.l. WolfSSL TLS Bench
.e. Show Cipher List
.s. Run TLS 1.3 Server over UART
.c. Run TLS 1.3 Client over UART

Please select one of the above options:

Example for TLS v1.3 over UART

A tutorial for setting this up can be found here: https://www.youtube.com/watch?v=OK6MKXYiVBY

The TLS v1.3 client/server examples over UART are paired with these host-side applications:

To use this example you will need to use the STM32Cube interface to enable an additional USART and enable DMA for the RX with defaults. Enabling DMA for the USART requires adding the USART RX DMA in the STM32Cube tool. Under Connectivity click on your TLS USART# and goto DMA Settings and "Add" one for USART#_RX with default options.

On some boards, such as U5, there is GPDMA support. In this case when you click on "DMA Settings" you will be given a button to take you to GPDMA1 configuration. Click it. You can then enable a channel (any of the ones from 0 to 11 should be fine.) as "Standard Request Mode" and set the "Request Configuration" section's "Request" to USART#_RX. In the "System Core" tab, find NVIC and click on it. Make sure that the GPDMA1 global interrupt for your channel is enabled as well as USARTx global interrupt.

Then set the TLS_UART macro to the correct huart# instance. This USART will be used as a TLS transport.

#define TLS_UART huart2

To disable the TLS UART example you can define NO_TLS_UART_TEST.

Benchmarks

See STM32_Benchmarks.md.

Note: The Benchmark example uses float. To enable go to "Project Properties" -> "C/C++ Build" -> "Settings" -> "Tool Settings" -> "MCU Settings" -> Check "Use float with printf".

STM32 Printf

In main.c make the following changes:

This section needs to go below the UART_HandleTypeDef line, otherwise wolfssl/wolfcrypt/settings.h will error.

/* Retargets the C library printf function to the USART. */
#include <stdio.h>
#include <wolfssl/wolfcrypt/settings.h>
#ifdef __GNUC__
int __io_putchar(int ch)
#else
int fputc(int ch, FILE *f)
#endif
{
    HAL_UART_Transmit(&HAL_CONSOLE_UART, (uint8_t *)&ch, 1, 0xFFFF);

    return ch;
}
#ifdef __GNUC__
int _write(int file,char *ptr, int len)
{
    int DataIdx;
    for (DataIdx= 0; DataIdx< len; DataIdx++) {
        __io_putchar(*ptr++);
    }
    return len;
}
#endif

In the main() function make the follow setvbuf() additions after HAL_Init().

int main(void)
{
    /* Reset of all peripherals, Initializes the Flash interface and the Systick. */
    HAL_Init();

    /* Turn off buffers, so I/O occurs immediately */
    setvbuf(stdin, NULL, _IONBF, 0);
    setvbuf(stdout, NULL, _IONBF, 0);
    setvbuf(stderr, NULL, _IONBF, 0);

Support

For questions please email support@wolfssl.com