When testing with custom entropy sources, if MBEDTLS_ENTROPY_NV_SEED
is enabled at compile time but the NV seed source is not used at
runtime, mbedtls_entropy_func makes a second pass anyway. Cope with
this in the test code by telling the entropy module not to make this
second pass.
Add a function to configure entropy sources. For testing only.
Use it to test that the library initialization fails properly if there is no
entropy source.
Allow mbedtls_psa_crypto_free to be called twice, or without a prior
call to psa_crypto_init. Keep track of the initialization state more
precisely in psa_crypto_init so that mbedtls_psa_crypto_free knows
what to do.
When running `make install`, it can be desirable for the PSA Crypto header
files to get installed as well, so that the PSA portions of the library are
usable.
Note that one can also use CMake and doesn't strictly require GNU Make. For
instance, telling CMake to output Visual Studio project files and using
those would preclude the need for GNU Make.
For Makefiles, enable overriding where includes can come from in order to
enable the parent module to set the include path. This allows the parent
module to specify that its config.h should be used, even when the submodule
when built standalone would use a different config.h.
For CMake, always look in the parent's include folder and our own. List the
parent's include folder first, so that preference is given to parent
include files.
Move our Mbed Crypto README out from the crypto folder and up to the top
level for better visibility when using Mbed Crypto as a submodule of Mbed
TLS.
When building Mbed Crypto as a subproject, don't add targets for
libmbedx509 or libmbedtls, as the parent project should build these. The
parent project will define USE_CRYPTO_SUBMODULE variable when using Mbed
Crypto as a submodule, so we can depend on that variable to control whether
or not we build non-crypto libraries.
The new file is conditionally compiled with the new mbedtls
configuration option that Mbed OS would set by default -
`MBEDTLS_PSA_CRYPTO_STORAGE_ITS_C`.
-
When generating keys that have persistent lifetime, we will need
the keys to be in the exported format to save to persistent storage.
This refactoring to separate checking the slots usage from the
exporting of the key data will be necessary for using
psa_internal_export_key in psa_generate_key.
Allow use of persistent keys, including configuring them, importing and
exporting them, and destroying them.
When getting a slot using psa_get_key_slot, there are 3 scenarios that
can occur if the keys lifetime is persistent:
1. Key type is PSA_KEY_TYPE_NONE, no persistent storage entry:
- The key slot is treated as a standard empty key slot
2. Key type is PSA_KEY_TYPE_NONE, persistent storage entry exists:
- Attempt to load the key from persistent storage
3. Key type is not PSA_KEY_TYPE_NONE:
- As checking persistent storage on every use of the key could
be expensive, the persistent key is assumed to be saved in
persistent storage, the in-memory key is continued to be used.
Create a new function psa_remove_key_from_memory() from psa_destroy_key().
This is needed as psa_destroy_key() will remove all key data, including
persistent storage. mbedtls_psa_crypto_free() will now only free in-memory
data and not persistent data.
Create a new function psa_import_key_into_slot() from psa_import_key().
This is common functionality that will be used both when importing a
key and loading a key from persistent storage.
Add a magic header to the storage format used with files. The
header is used as an initial check that the data is what we expect,
rather than garbage data.
Add new functions, psa_load_persistent_key(),
psa_free_persistent_key_data(), and psa_save_persistent_key(), for
managing persistent keys. These functions load to or save from our
internal representation of key slots. Serialization is a concern of the
storage backend implementation and doesn't abstraction-leak into the
lifetime management code.
An initial implementation for files is provided. Additional storage
backends can implement this interface for other storage types.
The persistent key implementation will be split across multiple
files as it will eventually be implementing multiple storage
backends. As these internal functions will need to be callable by
other files, we will add the headers in the library folder. This
commit adds this include location to the necessary scripts.
For tests, the library is added as an include location as testing
on-target with Mbed OS is not possible with paths including ".."
This commit adds the default upstream configuration to the set of
tests we run on CI, which was long overdue.
config-default is a copy of the Mbed TLS upstream config.h. It's
useful for two things: to compare our local changes to
include/mbedtls/config.h, and to test that we aren't breaking the
default upstream configuration.
Run a subset of the TLS tests that focus on exercising cryptographic
algorithms as used from TLS. Don't run the full set of TLS tests
because they're unlikely to be affected by changes in the PSA branch.
Upstream mbedtls maintains the default configuration in
include/mbedtls/config.h. We maintain the default configuration in
configs/config-default.h, and our PSA-specific configuration in
include/mbedtls/config.h. This means, each time we update Mbed TLS, we need
to update the default configuration file (configs/config-default.h)
manually using the copy from mbedtls.
Mbed TLS version 2.14.0
Resolved conflicts in include/mbedtls/config.h,
tests/scripts/check-files.py, and yotta/create-module.sh by removing yotta.
Resolved conflicts in tests/.jenkins/Jenkinsfile by continuing to run
mbedtls-psa job.