https://github.com/bazelembedded/bazel-embedded

Tools for embedded/bare-metal development using bazel
https://github.com/bazelembedded/bazel-embedded

arm bare-metal bazel bazel-toolchain cortex-m embedded

Last synced: 2 months ago
JSON representation

Tools for embedded/bare-metal development using bazel

• Host: GitHub
• URL: https://github.com/bazelembedded/bazel-embedded
• Owner: bazelembedded
• License: mit
• Created: 2019-11-17T08:59:27.000Z (over 4 years ago)
• Default Branch: master
• Last Pushed: 2023-09-26T23:14:43.000Z (9 months ago)
• Last Synced: 2024-03-17T14:01:11.723Z (3 months ago)
• Topics: arm, bare-metal, bazel, bazel-toolchain, cortex-m, embedded
• Language: Starlark
• Homepage: https://www.nb.rough.run/tags/bazel/
• Size: 232 KB
• Stars: 90
• Watchers: 5
• Forks: 30
• Open Issues: 14
• Metadata Files:
  • Readme: README.md
  • Funding: .github/FUNDING.yml
  • License: LICENSE

Lists

• awesome-bazel - bazelembedded/bazel-embedded - Set of bazel toolchains and tools, for compiling and uploading to embedded targets (Tooling / Toolchains)

README

        
# bazel-embedded

[![CI](https://github.com/bazelembedded/bazel-embedded/actions/workflows/main.yml/badge.svg)](https://github.com/bazelembedded/bazel-embedded/actions/workflows/main.yml)



At this point it is relatively easy to add support for new architectures, that have gcc based compilers. In future we will be adding clang support, so that we can make use of clangs static-analyzers. If you would like an architecture added to this repository let us know.

Currently supported hosts:

- Windows

- Mac/Unix

- Linux

Current support is limited to Arm Cortex-M Devices:

- Cortex M0

- Cortex M1

- Cortex M3

- Cortex M4 (with/out fpu)

- Cortex M7 (with/out fpu)

## What is included

List of support;

- [x] Toolchains

- [ ] Static analysers 

- [X] A collection of BUILD file templates for common embedded libraries

- [x] Utilities for programming targets

- [x] Utilities for debugging targets

- [ ] Parallel execution for a test "farm" of embedded test devices

## Our company needs feature X and would pay for its development

Reach out to [@silvergasp](https://github.com/silvergasp).

## Getting started

Add the following to your WORKSPACE file

```py

load("@bazel_tools//tools/build_defs/repo:git.bzl", "git_repository")

git_repository(

    name = "bazel_embedded",

    commit = "d3cbe4eff9a63d3dee63067d61096d681daca33b",

    remote = "https://github.com/bazelembedded/bazel-embedded.git",

    shallow_since = "1585022166 +0800",

)

load("@bazel_embedded//:bazel_embedded_deps.bzl", "bazel_embedded_deps")

bazel_embedded_deps()

load("@bazel_embedded//platforms:execution_platforms.bzl", "register_platforms")

register_platforms()

load(

    "@bazel_embedded//toolchains/compilers/gcc_arm_none_eabi:gcc_arm_none_repository.bzl",

    "gcc_arm_none_compiler",

)

gcc_arm_none_compiler()

load("@bazel_embedded//toolchains/gcc_arm_none_eabi:gcc_arm_none_toolchain.bzl", "register_gcc_arm_none_toolchain")

register_gcc_arm_none_toolchain()

load("@bazel_embedded//tools/openocd:openocd_repository.bzl", "openocd_deps")

openocd_deps()

```

Add the following to your .bazelrc file

```

# Enable toolchain resolution with cc

build --incompatible_enable_cc_toolchain_resolution

```

Cross Compile your target

```sh

bazel build //:your_target --platforms=@bazel_embedded//platforms:cortex_m0

bazel build //:your_target --platforms=@bazel_embedded//platforms:cortex_m1

bazel build //:your_target --platforms=@bazel_embedded//platforms:cortex_m3

bazel build //:your_target --platforms=@bazel_embedded//platforms:cortex_m4

bazel build //:your_target --platforms=@bazel_embedded//platforms:cortex_m7

bazel build //:your_target --platforms=@bazel_embedded//platforms:cortex_m4_fpu

bazel build //:your_target --platforms=@bazel_embedded//platforms:cortex_m7_fpu

```

Explore the examples for more in depth details...

You may choose to upload your code to a microcontroller using the [openocd](tools/openocd/README.md) package which allows you to program using SWD or JTAG. An example of this is shown below;

BUILD

```python

load("@rules_cc//cc:defs.bzl", "cc_binary")

load("@bazel_embedded//tools/openocd:defs.bzl", "openocd_debug_server", "openocd_flash")

# This target can be run to launch a gdb server on port 3333

openocd_debug_server(

    name = "main_debug_server",

    device_configs = [

        "target/stm32h7x_dual_bank.cfg",

    ],

    interface_configs = [

        "interface/stlink.cfg",

    ],

    transport = "hla_swd",

)

# The target to flash

cc_binary(

    name = "main",

    srcs = ["main.cc"],

    linkopts = [

        # app_code.ld is a linker script in the same directory

        "-T $(location :app_code.ld)",

        "-lc",

        "-lm",

        "-lnosys",

        "-u _printf_float",

    ],

    visibility = ["//visibility:public"],

    deps = [

        ":app_code.ld",

        "//libs/cpp/board_support:board_support_package",

    ],

)

# Run this target to upload to the microcontroller

openocd_flash(

    name = "main_flash",

    device_configs = [

        "target/stm32h7x_dual_bank.cfg",

    ],

    image = ":main.stripped",

    interface_configs = [

        "interface/stlink.cfg",

    ],

    transport = "hla_swd",

)

```

Alternatively, an execution wrapper can be used to execute a binary on an embedded target using openocd, and bazel's `--run_under` command line option.

BUILD

```python

load("@bazel_embedded//tools/openocd:defs.bzl", "openocd_execution_wrapper")

openocd_execution_wrapper(

    name = "test_wrapper",

    baud_rate = "115200",

    device_configs = [

        "target/stm32h7x_dual_bank.cfg",

    ],

    fail_string = "FAILED",

    interface_configs = [

        "interface/stlink.cfg",

    ],

    port = "/dev/ttyACM0",

    success_string = "PASSED",

    transport = "hla_swd",

)

```

```sh

bazel run //:your_target --platforms=@bazel_embedded//platforms:cortex_m7_fpu --run_under=//:test_wrapper

bazel test //:your_target --platforms=@bazel_embedded//platforms:cortex_m7_fpu --run_under=//:test_wrapper

```

This will pipe the serial output from the microcontroller over /dev/ttyACM0 to stdout. If a line contains 'PASSED', the wrapper will return 0, if a line contains 'FAILED' the wrapper will return 1. This is useful if you are wrapping a cc_test. If success_string or fail_string is not specified, the wrapper will not exit unless sent a sigterm (e.g. by CTRL-C). Leaving these empty can be useful when wrapping a standard cc_binary.

## How to have your embedded code coexist with host code

There are a number of cases where you may want to build and test everything but running.

```bash

bazel build //...

```

However by default this will capture and build all libraries for the host. This includes libraries that are only compatible with the host system. This can lead to scenarios where code will not compile on your host breaking a wildcards for building. As of bazel 4.0, incompatible target skipping is now supported which allows you to specify the constraint_values that your target is compatible. Bazel will then skip targets included in the wildcard that are not supported. If a target is built with the wrong target explicitly bazel will issue a warning saying that your target is not supported with the given platform.

e.g. 

```python

# Linux only

cc_library(

    name = "linux_only_lib",

    srcs = ["some_lib.cc"],

    target_compatible_with = [

        "@platforms//os:linux",

    ],

)

# Compatible with everything

cc_library(

    name = "generic",

    srcs = ["generic.cc"],

)

# Cortex m4 only

cc_library(

    name = "cortex_m4_only_lib",

    srcs = ["some_lib_m4.cc"],

    target_compatible_with = [

        "@platforms//cpu:armv7e-m",

    ],

)

# All cortex-m architectures

cc_library(

    name = "cortex_m_all_lib",

    srcs = ["some_lib_m_all.cc"],

    # Allow all cortex m architectures using a select statement. Reject anything else

    target_compatible_with = select({

        "@platforms//cpu:armv6-m": [],

        "@platforms//cpu:armv7-m": [],

        "@platforms//cpu:armv7e-m": [],

        "//conditions:default": ["@platforms//:incompatible"],

    ],

)

# Depends on platform specific target therefore can only be built with cortex m4

cc_library(

    name = "depends_on_m4",

    deps = [":cortex_m4_only_lib"],

)

```

For reference the following architectures constraint values map to cpu layouts.

"@platforms//cpu:armv6-m" -> Cortex-M0, Cortex-M0+, Cortex-M1

"@platforms//cpu:armv7-m" -> Cortex-M3

"@platforms//cpu:armv7e-m" -> Cortex-M4, Cortex-M7

## Feature configuration

Bazel can be configured using [features](https://docs.bazel.build/versions/master/cc-toolchain-config-reference.html#features). Each toolchain in this repository aims to implement a consistent behaviour for a given set of features. The list of available configuration features can be listed using the following command.

```bash

bazel run @bazel_embedded//toolchains/features:print_all_features

```

From here you may use each feature from the command line, the following example enables all warnings as errors and optimises for release;

```bash

bazel build //toolchains/compilation_tests/... --platforms=@bazel_embedded//platforms:cortex_m0 --features=all_warnings_as_errors,opt

```