Current version of the test is using "git-submodule foreach", which
requires submodules to be initialized. Non-initialized submodules are
ignored. Our CI is not performing submodule initialization, but instead
it only downloads the submodule content in tools/ci/ci_fetch_submodule.py
from cache and copies it into the submodule path.
Since we already know the submodule path from .gitconfig, we can use it
as argument to git-ls-tree and avoid calling git-submodule at all. This
allows to perform the test even if the submodules are not initialization
and also it makes the code simpler.
Signed-off-by: Frantisek Hrbata <frantisek.hrbata@espressif.com>
Conflicts:
- protobuf-c submodule version and hash changed to v1.4.0
- removed pytest dependency
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>
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>
This commit fixes an issue where paths on Windows are case insensitive, for instance when setting the build folder its name would be converted to lowercase.
The culprit is our realpath() function, that was calling os.path.normcase() internally, since we are removing that call it makes sense to just remove the function entirely and call os.path.realpath() wherever necessary.
Closes https://github.com/espressif/esp-idf/issues/10282
This fixes an attempted fix for diram size calculation where it was counted twice, however the fix did not account for cases where iram was not fully filled with cache and therefore was of non 0 size.
Now the calculation should be correct regardless of the cache size.
Closes https://github.com/espressif/esp-idf/issues/9960
Fix expected output
On xtensa architecture, the call to __assert_func uses a reference to __func__ that can
sometimes be placed in flash. Since the __asert_func can be called from functions in IRAM
the check_callgraph script can report an error when checking for invalid calls from IRAM
to flash sections. However, the __asert_func prevents this scenario at runtime so the
check_callgraph script reports a 'flas positive' situation. For this reasson, all references
to __func__$x found prior to a call to __assert_func are droped in the parsing of the rtl files.
this commits:
- adds build-time test to check that no call to flash regions are done from IRAM functions
- resolves problems related to IRAM function using content in flash memory
- update heap_caps_alloc_failed to use a default function name in DRAM
when necessary instead of creating a function name variable in DRAM for
each call of heap_caps_alloc_failed. This allows to save some extra bytes
in RAM.