This adds SBOM information for submodules, which are not managed
by Espressif. Meaning there is no fork for them in the espressif
namespace. Other submodules should add sbom.yml manifest file to
the root of their git repository.
The SBOM information for submodules is stored in the .gitmodules file.
Each SBOM related variable has the "sbom-" prefix and the following
variables may be used:
sbom-version:
submodule version
sbom-cpe:
CPE record if available in NVD. This will be used by the SBOM
tool to check for possible submodule vulnerabilities. The
version in the CPE can be replaced with the "{}" placeholder,
which will be replaced by the "sbom-version" value from above.
sbom-supplier:
Person or organization who is providing the submodule.
It has to start with "Person:" or "Organization:" prefix
as required by the SPDX-2.2 standard.
sbom-url:
URL to the project if exists, e.g. github.
sbom-description:
Project description.
sbom-hash:
Submodule SHA as recorded in the git-tree. This field is used by
CI to check that the submodule checkout hash and info in .gitmodules
are in sync. IOW if submodule is updated and it has SBOM info in
.gitmodules, the .gitmodules has to be updated too. The test is
part of this commit. The checkout has of the submodule can be found
by using "git submodule status".
Example for micro-ecc submodule
---8<---
[submodule "components/bootloader/subproject/components/micro-ecc/micro-ecc"]
path = components/bootloader/subproject/components/micro-ecc/micro-ecc
url = ../../kmackay/micro-ecc.git
sbom-version = 1.0
sbom-cpe = cpe:2.3🅰️micro-ecc_project:micro-ecc:{}:*:*:*:*:*:*:*
sbom-supplier = Person: Ken MacKay
sbom-url = https://github.com/kmackay/micro-ecc
sbom-description = A small and fast ECDH and ECDSA implementation for 8-bit, 32-bit, and 64-bit processors
sbom-hash = d037ec89546fad14b5c4d5456c2e23a71e554966
---8<---
Signed-off-by: Frantisek Hrbata <frantisek.hrbata@espressif.com>
The changes only related to C6 and H2 chips where CONFIG_SOC_IEEE802154_SUPPORTED=y.
For this case these APIs return 8 bytes
esp_efuse_mac_get_default() -> 8 bytes
esp_efuse_mac_get_custom() -> 8 bytes
esp_read_mac(..., ESP_MAC_IEEE802154) -> 8 bytes
The rest cases len is 6 bytes
The race condition is very unlikely on real hardware but can be observed with
qemu under heavy load.
Also add missing `memw` instructions which are generated by the C compiler but
absent in the assembly code.
Signed-off-by: Paul Guyot <pguyot@kallisys.net>
Signed-off-by: KonstantinKondrashov <konstantin@espressif.com>
Merges https://github.com/espressif/esp-idf/pull/11447
Closes https://github.com/espressif/esp-idf/issues/11433
- Technical details covered in section "15.3.2 Anti-DPA Attack Security
Control" chapter of the ESP32-C6 TRM
- Default configuration sets the security level low for the DPA
protection
- This change applies to all the crypto peripherals where the clock
frequency is dynamically adjusted to create randomness in the power
consumption trajectory
- This configuration helps to make the SCA attacks difficult on the
crypto peripherals
This extends information provided in the project_description.json file.
Newly added information can be used in the SBOM generating tool and
also to improve hints regarding the the component dependency issues.
Added fields
version:
This adds versioning to the project_description.json file,
so it's easy to identify if it contains the required information.
project_version:
Can be used as a version for the resulting binary e.g. `hello_world.bin`.
idf_path:
This one is probably not necessary, but it allows tools to run even without
esp-idf environment exported(e.g. export.sh).
c_compiler:
The `CMAKE_C_COMPILER` value with full path to the compiler binary. This can
be used to get information about toolchain, which was used to build the project.
common_component_reqs:
List of common components as presented in cmake's __COMPONENT_REQUIRES_COMMON
and set in tools/cmake/build.cmake:__build_init().
build_component_info:
Detailed information about components used during build. It's a
dictionary with the component name as a key and each component has
a dictionary with detailed information. Following is an example for
the efuse component.
"efuse": {
"alias": "idf::efuse",
"target": "___idf_efuse",
"prefix": "idf",
"dir": "/home/fhrbata/work/esp-idf/components/efuse",
"type": "LIBRARY",
"lib": "__idf_efuse",
"reqs": [],
"priv_reqs": [ "bootloader_support", "soc", "spi_flash" ],
"managed_reqs": [],
"managed_priv_reqs": [],
"file": "/home/fhrbata/work/blink/build/esp-idf/efuse/libefuse.a",
"sources": [ "/home/fhrbata/work/esp-idf/components/efuse/esp32s3/esp_efuse_table.c", ... ],
"include_dirs": [ "include", "esp32s3/include" ]
}
Signed-off-by: Frantisek Hrbata <frantisek.hrbata@espressif.com>
Currently make_json_list() returns '[ "" ]' for empty cmake list. Fix this
so empty json list is returned instead.
Signed-off-by: Frantisek Hrbata <frantisek.hrbata@espressif.com>
The number of the DMA descriptors allocated for certain length (e.g.,
8176) were not sufficient (off by 1 error). This used to result in the
dynamic memory corruption as the region was modified beyond the
allocated range.
This change fixes the DMA descriptor calculation part and allocates
sufficient DMA descriptors based on the data length alignment considerations.
Test has also been added to cover the specific scenario in the CI.
Closes https://github.com/espressif/esp-idf/issues/11310
* The RNG reading frequency of 200 KHz has been too high for
C6 and H2 since on these chips the RNG output is combined
with the RTC slow clock which is only 150KHz. Reduced the max
reading frequency via esp_random() from 200KHz to 62.5KHz,
which show best results in tests.
Also updated the bootloader_fill_random() max frequency to the
same value to be in line, even though it was just 83KHz.