esp-idf/components/hal/test_apps/crypto
Aditya Patwardhan e5fcc2d315
fix(hal): Fixed crypto test app
Previously the crypto test app was not verifying
    that the no of failures is 0.
    Added the check to verify that
2024-06-28 18:41:01 +05:30
..
components/mbedtls/include feat(hal/testapps): Added AES and SHA testcases with DMA support 2024-02-09 14:23:06 +05:30
main fix(hal): correct the power up sequence for MPI/ECC peripherals in ESP32-C5 2024-06-21 09:42:57 +08:00
CMakeLists.txt hal: add digital signature peripheral verification tests 2023-05-22 15:19:34 +05:30
pytest_crypto.py fix(hal): Fixed crypto test app 2024-06-28 18:41:01 +05:30
README.md ci(esp32c5mp): disable the unsupported tests 2024-04-07 12:13:29 +08:00
sdkconfig.ci.long_aes_operations feat(hal/testapps): Added AES and SHA testcases with DMA support 2024-02-09 14:23:06 +05:30
sdkconfig.defaults hal: add digital signature peripheral verification tests 2023-05-22 15:19:34 +05:30

Supported Targets ESP32 ESP32-C2 ESP32-C3 ESP32-C5 ESP32-C6 ESP32-H2 ESP32-P4 ESP32-S2 ESP32-S3

Crypto peripherals test

This is a combined crypto peripherals verification application using mostly HAL APIs. This application is intentionally kept simple and does not use any higher layer constructs. This application can help in the early verification of the new SoC.

This contains tests for the following features of the crypto peripherals:

  • MPI peripheral

    • MPI Modular Multiplication
    • MPI Multiplication
    • MPI Modular Exponentiation
  • ECC peripheral

    • ECC Point multiplication for P192 and P256 curve
    • ECC Point verification for P192 and P256 curve
    • ECC Point verify and multiply for P192 and P256 curve
    • ECC Inverse multiplication for P192 and P256

    If the hardware supports extended work modes then it also tests:

    • ECC Jacobian multiplication for P192 and P256 curve
    • ECC Jacobian verification for P192 and P256 curve
    • ECC Point verification and Jacobian multiplication for P192 and P256 curve
    • ECC Point addition for P192 and P256 curve
    • Mod addition
    • Mod subtraction
    • Mod multiplication
  • HMAC periperhal

    • HMAC 'downstream' JTAG Enable mode
    • HMAC 'downstream' JTAG Disable
    • HMAC 'upstream' MAC generation with zeroes
    • HMAC 'upstream' MAC generation from data
  • DS peripheral

    • Digital Signature Parameter Encryption
    • Digital Signature wrong HMAC key purpose
    • Digital Signature Blocking wrong HMAC key purpose
    • Digital Signature Operation
    • Digital Signature Blocking Operation
    • Digital Signature Invalid Data
  • ECDSA peripheral

    • ECDSA P192 signature generation
    • ECDSA P256 signature generation
    • ECDSA P192 signature verification
    • ECDSA P256 signature verification
    • ECDSA P192 export public key
    • ECDSA P256 export public key
    • ECDSA P192 deterministic signature generation
    • ECDSA P256 deterministic signature generation
  • AES peripheral

    • Block Mode
      • CBC AES-256
      • CTR AES-256
  • SHA peripheral

    • Block Mode
      • SHA-1
      • SHA-224
      • SHA-256
      • SHA-384
      • SHA-512
      • SHA-512/224
      • SHA-512/256
      • SHA-512/t

NOTE: The verification tests for the HMAC and Digital Signature peripherals would get exercised in only in an FPGA environment.

Burning the HMAC key

The HMAC tests need an HMAC key to be burned in the BLOCK_KEY3 and BLOCK_KEY4 of the efuses. As this verification application is independent of the efuse component, the user needs to manually burn the keys and their key purposes using espefuse.py.

espefuse.py -p $ESPPORT burn_key BLOCK_KEY3 main/hmac/hmac_key.bin HMAC_DOWN_JTAG

espefuse.py -p $ESPPORT burn_key BLOCK_KEY4 main/hmac/hmac_key.bin HMAC_UP

Burning the HMAC keys for Digital Signature tests

The tests needs some HMAC keys to be burned in the BLOCK_KEY0, BLOCK_KEY1 and BLOCK_KEY2 of the efuses. As this verification application is independent of the efuse component, the user needs to manually burn the keys and their key purposes using espefuse.py.

If SOC_DS_SIGNATURE_MAX_BIT_LEN == 3072:

espefuse.py -p $ESPPORT burn_key BLOCK_KEY0 main/ds/keys/3072/ds_key1.bin HMAC_DOWN_DIGITAL_SIGNATURE

espefuse.py -p $ESPPORT burn_key BLOCK_KEY1 main/ds/keys/3072/ds_key2.bin HMAC_DOWN_DIGITAL_SIGNATURE

espefuse.py -p $ESPPORT burn_key BLOCK_KEY2 main/ds/keys/3072/ds_key3.bin HMAC_DOWN_DIGITAL_SIGNATURE

If SOC_DS_SIGNATURE_MAX_BIT_LEN == 4096:

espefuse.py -p $ESPPORT burn_key BLOCK_KEY0 main/ds/keys/4096/ds_key1.bin HMAC_DOWN_DIGITAL_SIGNATURE

espefuse.py -p $ESPPORT burn_key BLOCK_KEY1 main/ds/keys/4096/ds_key2.bin HMAC_DOWN_DIGITAL_SIGNATURE

espefuse.py -p $ESPPORT burn_key BLOCK_KEY2 main/ds/keys/4096/ds_key3.bin HMAC_DOWN_DIGITAL_SIGNATURE

Burning the ECDSA keys

By default, ECDSA tests are disabled. You can enable it after disabling HMAC tests using idf.py menuconfig -> Test App Configuration -> Enable ECDSA Peripheral test cases

The ECDSA tests need some ECDSA keys to be burned in the BLOCK_KEY4 and BLOCK_KEY5 of the efuses. As this verification application is independent of the efuse component, the user needs to manually burn the keys and their key purposes using espefuse.py.

espefuse.py -p $ESPPORT burn_key BLOCK_KEY4 main/ecdsa/ecdsa192_priv_key.pem ECDSA_KEY

espefuse.py -p $ESPPORT burn_key BLOCK_KEY5 main/ecdsa/ecdsa256_priv_key.pem ECDSA_KEY

Building

idf.py set-target <TARGET>
idf.py build

Running the app manually

idf.py flash monitor

Enter the test that you want to run locally

Running tests

pytest --target <TARGET>