This is the Arduino platform specification, for use with Arduino development software starting from the Arduino IDE
1.5.x series.

Platforms add support for new boards to the Arduino development software. They are installable either via
[Boards Manager](package_index_json-specification.md) or manual installation to the _hardware_ folder of Arduino's
sketchbook folder (AKA "user directory").<br> A platform may consist of as little as a single configuration file.

## Platform installation directories

If the platforms are installed using the Board Manager the installation directory location will be as follow:

`{directories.data}/packages/{VENDOR_NAME}/hardware/{ARCHITECTURE}/{VERSION}/...`

- `{directories.data}` is the data directory as specified in the
  [configuration file](configuration.md#default-directories).
- `{VENDOR_NAME}` is the identifier of the vendor/maintainer of the platform.
- `{ARCHITECTURE}` is the architecture of the CPU used in the platform.
- `{VERSION}` is the platform version.

Alternatively, a platform may be manually installed by the user inside the Sketchbook/user directory as follows:

`{directories.user}/hardware/{VENDOR_NAME}/{ARCHITECTURE}/...`

- `{directories.user}` is the user directory as specified in the
  [configuration file](configuration.md#default-directories).
- `{VENDOR_NAME}` is the identifier of the vendor/maintainer of the platform.
  - The name of the vendor directory must not contain any characters other than the letters `A`-`Z` and `a`-`z`, numbers
    (`0`-`9`), underscores (`_`), dashes (`-`), and dots (`.`).
- `{ARCHITECTURE}` is the architecture of the CPU used in the platform.
  - The name of the architecture directory must not contain any characters other than the letters `A`-`Z` and `a`-`z`,
    numbers (`0`-`9`), underscores (`_`), dashes (`-`), and dots (`.`).

A vendor/maintainer may have multiple supported architectures.

Let's see an example, below we have a bunch of platforms downloaded from three hardware vendors `arduino`, `adafruit`
and `esp32`, and installed using the Board Manager:

```
{directories.data}/packages/arduino/hardware/avr/1.8.6/...
{directories.data}/packages/arduino/hardware/esp32/2.0.18-arduino.5/...
{directories.data}/packages/arduino/hardware/nrf52/1.4.5/...
{directories.data}/packages/adafruit/hardware/nrf52/1.6.1/...
{directories.data}/packages/esp32/hardware/esp32/3.0.7/...
```

In this example three architectures have been installed from the vendor `arduino` (`avr`, `esp32` and `nrf52`), and one
from `adafruit` and `esp32` (`nrf52` and `esp32` respectively). Note that the vendor `esp32` has the same name as the
architecture `esp32`.

If the user manually installed the same platforms, they should have unpacked them in the following directories:

```
{directories.user}/hardware/arduino/avr/...
{directories.user}/hardware/arduino/esp32/...
{directories.user}/hardware/arduino/nrf52/...
{directories.user}/hardware/adafruit/nrf52/...
{directories.user}/hardware/esp32/esp32/...
```

In this latter case the version must be omitted.

### Notes about choosing the architecture name

Architecture values are case sensitive (e.g. `AVR` != `avr`).

Platform developers should follow the existing architecture name conventions when creating hardware packages, if you
need to differentiate your package use the vendor/maintainer folder name to do so.

The architecture name is used to determine the libraries compatibility and to permit referencing resources from another
platform of the same architecture. Use of a non-standard architecture name can have a harmful effect.

## Architecture configurations

Each architecture must be configured through a set of configuration files:

- **platform.txt** contains definitions for the CPU architecture used (compiler, build process parameters, tools used
  for upload, etc.)
- **boards.txt** contains definitions for the boards (board name, parameters for building and uploading sketches, etc.)
- **programmers.txt** contains definitions for external programmers (typically used to burn bootloaders or sketches on a
  blank CPU/board)

### Configuration files format

A configuration file is a list of "key=value" properties. The **value** of a property can be expressed using the value
of another property by putting its name inside brackets "{" "}". For example:

```
compiler.path=/tools/g++_arm_none_eabi/bin/
compiler.c.cmd=arm-none-eabi-gcc
[....]
recipe.c.o.pattern={compiler.path}{compiler.c.cmd}
```

In this example the property **recipe.c.o.pattern** will be set to **/tools/g++\_arm_none_eabi/bin/arm-none-eabi-gcc**,
which is the composition of the properties **compiler.path** and **compiler.c.cmd**.

#### Comments

Lines starting with **#** are treated as comments and will be ignored.

```
# Like in this example
# --------------------
# I'm a comment!
```

#### Automatic property override for specific OS

We can specify an OS-specific value for a property. For example the following file:

```
tools.bossac.cmd=bossac
tools.bossac.cmd.windows=bossac.exe
```

will set the property **tools.bossac.cmd** to the value **bossac** on Linux and macOS and **bossac.exe** on Windows.
[Supported](https://github.com/arduino/Arduino/blob/1.8.12/arduino-core/src/processing/app/helpers/PreferencesMap.java#L110-L112)
suffixes are `.linux`, `.windows` and `.macosx`.

#### Global Predefined properties

The following automatically generated properties can be used globally in all configuration files:

- `{runtime.platform.path}`: is the absolute path of the [board platform](#platform-terminology) folder (i.e. the folder
  containing boards.txt) unless `{runtime.use_core_platform_path_for_runtime_platform_path}` is set to `true` in this
  case, the value is the absolute path of the referenced core platform.
- `{runtime.hardware.path}`: the absolute path of the hardware folder (i.e. the folder containing the
  [board platform](#platform-terminology) folder)
- `{runtime.ide.path}`: the absolute path of the Arduino IDE or Arduino CLI folder
- `{runtime.ide.version}`: the version number of the Arduino IDE as a number (this uses two digits per version number
  component, and removes the points and leading zeroes, so Arduino IDE 1.8.3 becomes `01.08.03` which becomes
  `runtime.ide.version=10803`). When using Arduino development software other than the Arduino IDE, this is set to a
  meaningless version number.
- `{ide_version}`: Compatibility alias for `{runtime.ide.version}`
- `{runtime.os}`: the running OS ("linux", "windows", "macosx")
- `{software}`: set to "ARDUINO"
- `{name}`: platform vendor name
- `{_id}`: [board ID](#boardstxt) of the board being compiled for
- `{build.fqbn}`: the FQBN (fully qualified board name) of the board being compiled for. The FQBN follows the format:
  `VENDOR:ARCHITECTURE:BOARD_ID[:MENU_ID=OPTION_ID[,MENU2_ID=OPTION_ID ...]]`
- `{build.source.path}`: Path to the sketch being compiled. If the sketch is in an unsaved state, it will be the path of
  its temporary folder.
- `{build.library_discovery_phase}`: set to 1 during library discovery and to 0 during normal build. A macro defined
  with this property can be used to disable the inclusion of heavyweight headers during discovery to reduce compilation
  time. This property was added in Arduino IDE 1.8.14/Arduino Builder 1.6.0/Arduino CLI 0.12.0. Note: with the same
  intent, `-DARDUINO_LIB_DISCOVERY_PHASE` was added to `recipe.preproc.macros` during library discovery in Arduino
  Builder 1.5.3/Arduino CLI 0.10.0. That flag was replaced by the more flexible `{build.library_discovery_phase}`
  property.
- `{compiler.optimization_flags}`: see ["Sketch debugging configuration"](#sketch-debugging-configuration) for details
- `{extra.time.utc}`: Unix time (seconds since 1970-01-01T00:00:00Z) according to the machine the build is running on
- `{extra.time.local}`: Unix time with local timezone and DST offset
- `{extra.time.zone}`: local timezone offset without the DST component
- `{extra.time.dst}`: local daylight savings time offset

Compatibility notes:

- Versions before Arduino IDE 1.6.0 only used one digit per version number component in `{runtime.ide.version}` (so
  1.5.9 was `159`, not `10509`).
- `{runtime.use_core_platform_path_for_runtime_platform_path}` support is available from Arduino CLI >=1.0.4.

## platform.txt

The platform.txt file contains information about a platform's specific aspects (compilers command line flags, paths,
system libraries, etc.).

The following meta-data must be defined:

```
name=Arduino AVR Boards
version=1.5.3
```

The **name** will be shown as the Arduino IDE's Board menu section title or the Name field of
[`arduino-cli core list`](commands/arduino-cli_core_list.md)'s output for the platform.<br> The **version** is currently
unused, it is reserved for future use (probably together with the Boards Manager to handle dependencies on cores).

### Build process

The platform.txt file is used to configure the [build process](sketch-build-process.md). This is done through a list of
**recipes**. Each recipe is a command line expression that explains how to call the compiler (or other tools) for every
build step and which parameter should be passed.

The Arduino development software, before starting the build, determines the list of files to compile. The list is
composed of:

- the user's Sketch
- source code in the selected board's Core
- source code in the Libraries used in the sketch

A temporary folder is created to store the build artifacts whose path is available through the global property
**{build.path}**. A property **{build.project_name}** with the name of the project and a property **{build.arch}** with
the name of the architecture is set as well.

- `{build.path}`: The path to the temporary folder to store build artifacts
- `{build.project_name}`: The project name
- `{build.arch}`: The MCU architecture (avr, sam, etc...)

There are some other **{build.xxx}** properties available, that are explained in the boards.txt section of this guide.

#### Security credential properties

Some of them allow specifying trusted security credentials (signing and encryption keys) that can be used by a
["secure boot" system](guides/secure-boot.md):

- `build.keys.keychain`: for the directory containing the keys
- `build.keys.sign_key`: for the signing key
- `build.keys.encrypt_key`: for the encryption key

If any of these properties are defined, the others are required.

These properties can be overwritten respectively with `--keys-keychain`, `--sign-key`, `--encrypt-key`
[compile](commands/arduino-cli_compile.md) flags in the Arduino CLI.

#### Recipes to compile source code

We said that the Arduino development software determines a list of files to compile. Each file can be source code
written in C (.c files), C++ (.cpp/.cxx/.cc files) or Assembly (.S files). Every language is compiled using its
respective **recipe**:

- `recipe.c.o.pattern`: for C files (.c)
- `recipe.cpp.o.pattern`: for CPP files (.cpp/.cxx/.cc)
- `recipe.S.o.pattern`: for Assembly files (.S)

(an optional `recipe.cxx.o.pattern` and `recipe.cc.o.pattern` may be provided, if `.cxx` or `.cc` needs special
handling, but it's not required and we do not recommend it)

The recipes can be built concatenating the following automatically generated properties (for each file compiled):

- `{includes}`: the list of include paths in the format "-I/include/path -I/another/path...."
- `{source_file}`: the path to the source file
- `{object_file}`: the path to the output file

For example the following is used for AVR:

```
## Compiler global definitions
compiler.path={runtime.ide.path}/tools/avr/bin/
compiler.c.cmd=avr-gcc
compiler.c.flags=-c -g -Os -w -ffunction-sections -fdata-sections -MMD

[......]

## Compile c files
recipe.c.o.pattern="{compiler.path}{compiler.c.cmd}" {compiler.c.flags} -mmcu={build.mcu} -DF_CPU={build.f_cpu} -DARDUINO={runtime.ide.version} -DARDUINO_{build.board} -DARDUINO_ARCH_{build.arch} {build.extra_flags} {includes} "{source_file}" -o "{object_file}"
```

Note that some properties, like **{build.mcu}** for example, are taken from the **boards.txt** file which is documented
later in this specification.

#### Recipes to build the core.a archive file

The core of the selected board is compiled as described in the previous paragraph, but the object files obtained from
the compile are also archived into a static library named _core.a_ using the **recipe.ar.pattern**.

The recipe can be built concatenating the following automatically generated properties:

- `{object_file}`: the object file to include in the archive
- `{archive_file_path}`: fully qualified archive file (ex. "/path/to/core.a"). This property was added in Arduino IDE
  1.6.6/arduino builder 1.0.0-beta12 as a replacement for `{build.path}/{archive_file}`.
- `{archive_file}`: the name of the resulting archive (ex. "core.a")

For example, Arduino provides the following for AVR:

```
compiler.ar.cmd=avr-ar
compiler.ar.flags=rcs

[......]

## Create archives
recipe.ar.pattern="{compiler.path}{compiler.ar.cmd}" {compiler.ar.flags} "{archive_file_path}" "{object_file}"
```

#### Recipes for linking

All the artifacts produced by the previous steps (sketch object files, libraries object files and core.a archive) are
linked together using the **recipe.c.combine.pattern**.

The recipe can be built concatenating the following automatically generated properties:

- `{object_files}`: the list of object files to include in the archive ("file1.o file2.o ....")
- `{archive_file_path}`: fully qualified archive file (ex. "/path/to/core.a"). This property was added in Arduino IDE
  1.6.6/arduino builder 1.0.0-beta12 as a replacement for `{build.path}/{archive_file}`.
- `{archive_file}`: the name of the core archive file (ex. "core.a")
- `{compiler.libraries.ldflags}`: the linking flags for precompiled libraries, which consist of automatically generated
  `-L` flags for the library path and `-l` flags for library files, as well as any custom flags provided via the
  `ldflags` field of library.properties. In order to support precompiled libraries, platform.txt must contain a
  definition of `compiler.libraries.ldflags`, to which any automatically generated flags will be appended. Support for
  precompiled libraries was added in Arduino IDE 1.8.6/arduino-builder 1.4.0.

For example the following is used for AVR:

```
compiler.c.elf.flags=-Os -Wl,--gc-sections
compiler.c.elf.cmd=avr-gcc

compiler.libraries.ldflags=

[......]

## Combine gc-sections, archives, and objects
recipe.c.combine.pattern="{compiler.path}{compiler.c.elf.cmd}" {compiler.c.elf.flags} -mmcu={build.mcu} -o "{build.path}/{build.project_name}.elf" {object_files} {compiler.libraries.ldflags} "{archive_file_path}" "-L{build.path}" -lm
```

If the linking process requires multiple steps, the recipe can be written using the **recipe.c.combine.NUMBER.pattern**
syntax. In this case, each step will be executed in the order specified by the number. When multiple steps are defined,
the **recipe.c.combine.pattern** property is ignored.

#### Recipes for extraction of executable files and other binary data

An arbitrary number of extra steps can be performed at the end of objects linking. These steps can be used to extract
binary data used for upload and they are defined by a set of recipes with the following format:

```
recipe.objcopy.FILE_EXTENSION_1.pattern=[.....]
recipe.objcopy.FILE_EXTENSION_2.pattern=[.....]
[.....]
```

`FILE_EXTENSION_x` must be replaced with the extension of the extracted file, for example the AVR platform needs two
files a `.hex` and a `.eep`, so we made two recipes like:

```
recipe.objcopy.eep.pattern=[.....]
recipe.objcopy.hex.pattern=[.....]
```

There are no specific properties set by the Arduino development software here.

A full example for the AVR platform can be:

```
## Create eeprom
recipe.objcopy.eep.pattern="{compiler.path}{compiler.objcopy.cmd}" {compiler.objcopy.eep.flags} "{build.path}/{build.project_name}.elf" "{build.path}/{build.project_name}.eep"

## Create hex
recipe.objcopy.hex.pattern="{compiler.path}{compiler.elf2hex.cmd}" {compiler.elf2hex.flags} "{build.path}/{build.project_name}.elf" "{build.path}/{build.project_name}.hex"
```

#### Recipes to compute binary sketch size

At the end of the build the Arduino development software shows the final binary sketch size to the user. The size is
calculated using the recipe **recipe.size.pattern**. The output of the command executed using the recipe is parsed
through the regular expressions set in the properties:

- **recipe.size.regex**: Program storage space used.
- **recipe.size.regex.data**: Dynamic memory used by global variables.

For AVR we have:

```
compiler.size.cmd=avr-size
[....]
## Compute size
recipe.size.pattern="{compiler.path}{compiler.size.cmd}" -A "{build.path}/{build.project_name}.hex"
recipe.size.regex=^(?:\.text|\.data|\.bootloader)\s+([0-9]+).*
recipe.size.regex.data=^(?:\.data|\.bss|\.noinit)\s+([0-9]+).*
```

Two properties can be used to define the total available memory:

- `{upload.maximum_size}`: available program storage space
- `{upload.maximum_data_size}`: available dynamic memory for global variables

If the binary sketch size exceeds the value of these properties, the compilation process fails.

This information is displayed in the console output after compiling a sketch, along with the relative memory usage
value:

```
Sketch uses 924 bytes (2%) of program storage space. Maximum is 32256 bytes.
Global variables use 9 bytes (0%) of dynamic memory, leaving 2039 bytes for local variables. Maximum is 2048 bytes.
```

#### Recipes to compute binary sketch size for more complex systems (since Arduino CLI >=0.21.0)

A platform may provide a tool for the specific purpose to analyze the binaries and compute the sketch size and memory
usage statistics. This is especially useful for boards with non-trivial memory layouts where
[the classic reg-exp based approach](#recipes-to-compute-binary-sketch-size) is not sufficient.

The command line to run is specified with the recipe **recipe.advanced_size.pattern**.

The expected output from the tool is a JSON object with the following format:

```json
{
  "output": "Your sketch uses 2200 bytes of program memory out of 8192 (27%)\nThe static RAM used is 200 bytes (of 2048 max)",
  "severity": "info",
  "sections": [
    { "name": "text", "size": 2200, "max_size": 8192 },
    { "name": "data", "size": 200, "max_size": 2048 }
  ]
}
```

The meaning of the fields is the following:

- `output`: is a preformatted text that is displayed as-is in console.
- `severity`: indicates the warning level of the output messages, it must be `info`, `warning` or `error`. Warnings and
  errors are displayed in red (or in a different color than normal output). Errors will make the build/upload fail.
- `sections`: is an array containing the memory sections and their usage level. This array is used to report memory
  usage in a machine-readable format if requested by the user. Each item represents a memory section and may contain the
  following fields
  - `name`: an identifier for the section
  - `size`: the sketch size for the section
  - `max_size`: the maximum size for the section

When the `severity` is set to `error` the build/upload is interrupted and an exception is returned to the calling
process. In this case an extra exception message must be provided through the `error` field, for example:

```json
{
  "output": "Your sketch uses 12200 bytes of program memory out of 8192 (149%))\nThe static RAM used is 200 bytes (of 2048 max)",
  "severity": "error",
  "error": "Sketch is too big!",
  "sections": [
    { "name": "text", "size": 12200, "max_size": 8192 },
    { "name": "data", "size": 200, "max_size": 2048 }
  ]
}
```

This means that the `sections` part is **NOT** used to automatically check if the sketch size exceeds the available
memory: this check is now delegated to the tool that must report a `"severity":"error"` with a meaningful error message.

If both **recipe.size.pattern** and **recipe.advanced_size.pattern** are present then **recipe.advanced_size.pattern**
will be used. Since the **recipe.advanced_size.pattern** feature is available starting from Arduino CLI>=0.21.0, to
maximize backward compatibility, we recommend to provide both **recipe.size.pattern** and
**recipe.advanced_size.pattern** if possible, so the old versions of the IDE/CLI will continue to work (even with a less
detailed memory usage report).

#### Recipes to export compiled binary

When you do a **Sketch > Export compiled Binary** in the Arduino IDE, the compiled binary is copied from the build
folder to the sketch folder. Two binaries are copied; the standard binary, and a binary that has been merged with the
bootloader file (identified by the `.with_bootloader` in the filename).

Two recipes affect how **Export compiled Binary** works:

- **recipe.output.tmp_file**: Defines the binary's filename in the build folder.
- **recipe.output.save_file**: Defines the filename to use when copying the binary file to the sketch folder.

As with other processes, there are pre and post build hooks for **Export compiled Binary**.

The **recipe.hooks.savehex.presavehex.NUMBER.pattern** and **recipe.hooks.savehex.postsavehex.NUMBER.pattern** hooks
(but not **recipe.output.tmp_file** and **recipe.output.save_file**) can be built concatenating the following
automatically generated properties:

- `{sketch_path}`: the absolute path of the sketch folder

#### Recipe to run the preprocessor

For detecting which libraries to include in the build, and for generating function prototypes, (just) the preprocessor
is run. For this, the **recipe.preproc.macros** recipe exists. This recipe must run the preprocessor on a given source
file, writing the preprocessed output to a given output file, and generate (only) preprocessor errors on standard
output. This preprocessor run should happen with the same defines and other preprocessor-influencing-options as for
normally compiling the source files.

The recipes can be built concatenating other automatically generated properties (for each file compiled):

- `{includes}`: the list of include paths in the format "-I/include/path -I/another/path...."
- `{source_file}`: the path to the source file
- `{preprocessed_file_path}`: the path to the output file

For example the following is used for AVR:

```
preproc.macros.flags=-w -x c++ -E -CC
recipe.preproc.macros="{compiler.path}{compiler.cpp.cmd}" {compiler.cpp.flags} {preproc.macros.flags} -mmcu={build.mcu} -DF_CPU={build.f_cpu} -DARDUINO={runtime.ide.version} -DARDUINO_{build.board} -DARDUINO_ARCH_{build.arch} {compiler.cpp.extra_flags} {build.extra_flags} {includes} "{source_file}" -o "{preprocessed_file_path}"
```

Note that the `{preprocessed_file_path}` might point to (your operating system's equivalent) of `/dev/null`. In this
case, also passing `-MMD` to gcc is problematic, as it will try to generate a dependency file called `/dev/null.d`,
which will usually result in a permission error. Since platforms typically include `{compiler.cpp.flags}` here, which
includes `-MMD`, the `-MMD` option is automatically filtered out of the `recipe.preproc.macros` recipe to prevent this
error.

If **recipe.preproc.macros** is not defined, it is automatically generated from **recipe.cpp.o.pattern**.

Note that older Arduino IDE versions used the **recipe.preproc.includes** recipe (which is not documented here) to
determine includes. Since Arduino IDE 1.6.7 (arduino-builder 1.2.0) this was changed and **recipe.preproc.includes** is
no longer used.

#### Pre and post build hooks (since Arduino IDE 1.6.5)

You can specify pre and post actions around each recipe. These are called "hooks". Here is the complete list of
available hooks:

- `recipe.hooks.prebuild.NUMBER.pattern` (called before sketch preprocessing and libraries discovery)
- `recipe.hooks.sketch.prebuild.NUMBER.pattern` (called before sketch compilation)
- `recipe.hooks.sketch.postbuild.NUMBER.pattern` (called after sketch compilation)
- `recipe.hooks.libraries.prebuild.NUMBER.pattern` (called before libraries compilation)
- `recipe.hooks.libraries.postbuild.NUMBER.pattern` (called after libraries compilation)
- `recipe.hooks.core.prebuild.NUMBER.pattern` (called before core compilation)
- `recipe.hooks.core.postbuild.NUMBER.pattern` (called after core compilation)
- `recipe.hooks.linking.prelink.NUMBER.pattern` (called before linking)
- `recipe.hooks.linking.postlink.NUMBER.pattern` (called after linking)
- `recipe.hooks.objcopy.preobjcopy.NUMBER.pattern` (called before objcopy recipes execution)
- `recipe.hooks.objcopy.postobjcopy.NUMBER.pattern` (called after objcopy recipes execution)
- `recipe.hooks.savehex.presavehex.NUMBER.pattern` (called before savehex recipe execution)
- `recipe.hooks.savehex.postsavehex.NUMBER.pattern` (called after savehex recipe execution)

Example: you want to execute two commands before sketch compilation and one after linking. You'll add to your
platform.txt:

```
recipe.hooks.sketch.prebuild.1.pattern=echo sketch compilation started at
recipe.hooks.sketch.prebuild.2.pattern=date

recipe.hooks.linking.postlink.1.pattern=echo linking is complete
```

Warning: hooks recipes are sorted before execution. If you need to write more than 10 recipes for a single hook, pad the
number with a zero, for example:

```
recipe.hooks.sketch.prebuild.01.pattern=echo 1
recipe.hooks.sketch.prebuild.02.pattern=echo 2
...
recipe.hooks.sketch.prebuild.11.pattern=echo 11
```

Note: all the `pre*` hooks are executed while producing the "compilation database" (a JSON file with the list of
commands to run to compile the sketch), but the `post*` hooks and all compile commands are skipped. See the
[`arduino-cli compile`](commands/arduino-cli_compile.md) command reference for more info.

## Global platform.txt

Properties defined in a platform.txt file located in the root of any of the packages folders will be used for all
platforms and will override local properties.

The packages folder locations are:

- `{directories.data}/packages`<br />(where `{directories.data}` is the path from the `directories.data`
  [configuration key](configuration.md))
- `{directories.user}/hardware`<br />(where `{directories.user}` is the path from the `directories.user`
  [configuration key](configuration.md), or Arduino IDE "Sketchbook location" preference)
- `{Arduino IDE installation}/hardware` (Arduino IDE 1.x only)<br />(where `{Arduino IDE installation}` is the path of
  the Arduino IDE installation folder)

## platform.local.txt

Introduced in Arduino IDE 1.5.7. This file can be used to override properties defined in `platform.txt` or define new
properties without modifying `platform.txt` (e.g. when `platform.txt` is tracked by a version control system). It must
be placed in the same folder as the `platform.txt` it supplements.

## boards.txt

This file contains definitions and metadata for the boards supported by the platform. Boards are referenced by their
short name, the board ID. The settings for a board are defined through a set of properties with keys having the board ID
as prefix.

The board ID must not contain any characters other than the letters `A`-`Z` and `a`-`z`, numbers (`0`-`9`), underscores
(`_`), and dashes (`-`).

For example, the board ID chosen for the Arduino Uno board is "uno". An extract of the Uno board configuration in
boards.txt looks like:

```
[......]
uno.name=Arduino Uno
uno.build.mcu=atmega328p
uno.build.f_cpu=16000000L
uno.build.board=AVR_UNO
uno.build.core=arduino
uno.build.variant=standard
[......]
```

Note that all the relevant keys start with the board ID **uno.xxxxx**.

The **uno.name** property contains the human-friendly name of the board. This is shown in the Board menu of the IDEs,
the "Board Name" field of Arduino CLI's text output, or the "name" key of Arduino CLI's JSON output.

The **uno.build.board** property is used to set a compile-time macro **ARDUINO\_{build.board}** to allow use of
conditional code between `#ifdef`s. If not defined, a **build.board** value is automatically generated and the Arduino
development software outputs a warning. In this case the macro defined at compile time will be `ARDUINO_AVR_UNO`.

The other properties will override the corresponding global properties when the user selects the board. These properties
will be globally available, in other configuration files too, without the board ID prefix:

```
uno.build.mcu           =>   build.mcu
uno.build.f_cpu         =>   build.f_cpu
uno.build.board         =>   build.board
uno.build.core          =>   build.core
uno.build.variant       =>   build.variant
```

This explains the presence of **{build.mcu}** or **{build.board}** in the platform.txt recipes: their value is
overwritten respectively by **{uno.build.mcu}** and **{uno.build.board}** when the Uno board is selected! Moreover the
following properties are automatically generated:

- `{build.board.platform.path}`: The path to the selected board's platform. (available since Arduino CLI >=1.0.4)
- `{build.core.platform.path}`: The path to the core's platform. It may differ from the board's platform path because
  the latter may reference a core from another platform. (available since Arduino CLI >=1.0.4)
- `{build.core.path}`: The path to the selected board's core folder (inside the [core platform](#platform-terminology),
  for example hardware/arduino/avr/core/arduino)
- `{build.system.path}`: The path to the [core platform](#platform-terminology)'s system folder if available (for
  example hardware/arduino/sam/system)
- `{build.variant.path}`: The path to the selected board variant folder (inside the
  [variant platform](#platform-terminology), for example hardware/arduino/avr/variants/micro)

If the platform supports pluggable discovery it may also declare a set of `upload_port.*` properties, these properties
will be used to identify a board by the discovery process when plugged in.

For example we could declare a series of `upload_port.vid` and `upload_port.pid` properties for the Uno like so:

```
uno.upload_port.0.vid=0x2341
uno.upload_port.0.pid=0x0043
uno.upload_port.1.vid=0x2341
uno.upload_port.1.pid=0x0001
uno.upload_port.2.vid=0x2A03
uno.upload_port.2.pid=0x0043
uno.upload_port.3.vid=0x2341
uno.upload_port.3.pid=0x0243
```

In this case we're using the board's USB VID/PID pair to identify it but `upload_port.*` properties can be anything that
can help identify a certain board. For more detailed information see the
[board identification](pluggable-discovery-specification.md#board-identification) section of the pluggable discovery
documentation.

### Cores

Cores are placed inside the **cores** subfolder. Many different cores can be provided within a single platform. For
example the following could be a valid platform layout:

- `hardware/arduino/avr/cores/`: Cores folder for "avr" architecture, package "arduino"
- `hardware/arduino/avr/cores/arduino`: the Arduino Core
- `hardware/arduino/avr/cores/rtos`: a hypothetical RTOS Core

The board's property **build.core** is used to find the core that must be compiled and linked when the board is
selected. For example if a board needs the Arduino core the **build.core** variable should be set to:

```
uno.build.core=arduino
```

or if the RTOS core is needed, to:

```
uno.build.core=rtos
```

In any case the contents of the selected core folder are compiled and the core folder path is added to the include files
search path.

#### ArduinoCore-API

Although much of the implementation of a core is architecture-specific, the standardized core API and the hardware
independent components should be the same for every Arduino platform. In order to free platform authors from the burden
of individually maintaining duplicates of this common code, Arduino has published it in a dedicated repository from
which it may easily be shared by all platforms. In addition to significantly reducing the effort required to write and
maintain a core, ArduinoCore-API assists core authors in providing the unprecedented level of portability between
platforms that is a hallmark of the Arduino project.

See the [arduino/ArduinoCore-API repository](https://github.com/arduino/ArduinoCore-API) for more information.

### Core Variants

Sometimes a board needs some tweaking on the default core configuration (different pin mapping is a typical example). A
core variant folder is an additional folder that is compiled together with the core and allows platform developers to
easily add specific configurations.

Variants must be placed inside the **variants** folder in the current architecture. For example, Arduino AVR Boards
uses:

- `hardware/arduino/avr/cores`: Core folder for "avr" architecture, "arduino" package
- `hardware/arduino/avr/cores/arduino`: The Arduino core
- `hardware/arduino/avr/variants/`: Variant folder for "avr" architecture, "arduino" package
- `hardware/arduino/avr/variants/standard`: ATmega328 based variants
- `hardware/arduino/avr/variants/leonardo`: ATmega32U4 based variants

In this example, the Arduino Uno board needs the _standard_ variant so the **build.variant** property is set to
_standard_:

```
[.....]
uno.build.core=arduino
uno.build.variant=standard
[.....]
```

instead, the Arduino Leonardo board needs the _leonardo_ variant:

```
[.....]
leonardo.build.core=arduino
leonardo.build.variant=leonardo
[.....]
```

In the example above, both Uno and Leonardo share the same core but use different variants.<br> In any case, the
contents of the selected variant folder path is added to the include search path and its contents are compiled and
linked with the sketch.

The parameter **build.variant.path** is automatically generated.

### Board VID/PID

USB vendor IDs (VID) and product IDs (PID) identify USB devices to the computer. If the board uses a unique VID/PID
pair, it may be defined in boards.txt:

```
uno.vid.0=0x2341
uno.pid.0=0x0043
uno.vid.1=0x2341
uno.pid.1=0x0001
```

The **vid** and **pid** properties end with an arbitrary number, which allows multiple VID/PID pairs to be defined for a
board. The snippet above is defining the 2341:0043 and 2341:0001 pairs used by Uno boards.

The Arduino development software uses the **vid** and **pid** properties to automatically identify the boards connected
to the computer. This convenience feature isn't available for boards that don't present a unique VID/PID pair.

### Serial Monitor control signal configuration

Arduino boards that use a USB to TTL serial adapter chip for communication with the computer (e.g., Uno, Nano, Mega)
often utilize the DTR (data terminal ready) or RTS (request to send) serial control signals as a mechanism for the
Arduino development software to trigger a reset of the primary microcontroller. The adapter's DTR and RTS pins are set
`LOW` when the control signals are asserted by the computer and this `LOW` level is converted into a pulse on the
microcontroller's reset pin by an "auto-reset" circuit on the board. The auto-reset system is necessary to activate the
bootloader at the start of an upload.

This system is also used to reset the microcontroller when Serial Monitor is started. The reset is convenient because it
allows viewing all serial output from the time the program starts. In case the reset caused by opening Serial Monitor is
not desirable, the control signal assertion behavior of Serial Monitor is configurable via the **serial.disableDTR** and
**serial.disableRTS** properties. Setting these properties to `true` will prevent Serial Monitor from asserting the
control signals when that board is selected:

```
[.....]
uno.serial.disableDTR=true
uno.serial.disableRTS=true
[.....]
```

### Hiding boards

Adding a **hide** property to a board definition causes it to not be shown in the Arduino IDE's **Tools > Board** menu.

```
uno.hide=
```

The value of the property is ignored; it's the presence or absence of the property that controls the board's visibility.

## programmers.txt

This file contains definitions for external programmers. These programmers are used by:

- The [**Tools > Burn Bootloader**](#burn-bootloader) feature of the IDEs and
  [`arduino-cli burn-bootloader`](commands/arduino-cli_burn-bootloader.md)
- The [**Sketch > Upload Using Programmer**](#upload-using-an-external-programmer) feature of the IDEs and
  [`arduino-cli upload --programmer <programmer ID>`](commands/arduino-cli_upload.md#options)

programmers.txt works similarly to [boards.txt](#boardstxt). Programmers are referenced by their short name: the
programmer ID. The settings for a programmer are defined through a set of properties with keys that use the programmer
ID as prefix.

For example, the programmer ID chosen for the
["Arduino as ISP" programmer](https://www.arduino.cc/en/Tutorial/ArduinoISP) is "arduinoasisp". The definition of this
programmer in programmers.txt looks like:

```
[......]
arduinoasisp.name=Arduino as ISP
arduinoasisp.protocol=stk500v1
arduinoasisp.program.speed=19200
arduinoasisp.program.tool=avrdude
arduinoasisp.program.extra_params=-P{serial.port} -b{program.speed}
[......]
```

These properties can only be used in the recipes of the actions that use the programmer (`erase`, `bootloader`, and
`program`).

The **arduinoasisp.name** property defines the human-friendly name of the programmer. This is shown in the **Tools >
Programmer** menu of the IDEs and the output of [`arduino-cli upload --programmer list`](commands/arduino-cli_upload.md)
and [`arduino-cli burn-bootloader --programmer list`](commands/arduino-cli_burn-bootloader.md).

In Arduino IDE 1.8.12 and older, all programmers of all installed platforms were made available for use. Starting with
Arduino IDE 1.8.13 (and in all relevant versions of other Arduino development tools), only the programmers defined by
the [board and core platform](#platform-terminology) of the currently selected board are available. For this reason,
platforms may now need to define copies of the programmers that were previously assumed to be provided by another
platform.

### Set a default programmer for a board (since Arduino CLI >=0.35.0, Arduino IDE >=2.3.0)

A default programmer for each board may be specified through the `programmer.default` directive in the board definition:

```
BOARD_ID.programmer.default=PROGRAMMER_ID
```

The default programmer will be selected automatically if the user do not specifiy or select another programmer. This may
be useful for boards with an on-board programmer/debugger.

For example if we want to set Atmel ICE as the default programmer for the Arduino UNO we would add the following line to
the `boards.txt` file:

```
uno.programmer.default=atmel-ice
```

## Tools

The Arduino development software uses external command line tools to upload the compiled sketch to the board or to burn
bootloaders using external programmers. For example, _avrdude_ is used for AVR based boards and _bossac_ for SAM based
boards, but there is no limit, any command line executable can be used. The command line parameters are specified using
**recipes** in the same way used for platform build process.

Tools are configured inside the platform.txt file. Every Tool is identified by a short name, the Tool ID. A tool can be
used for different purposes:

- **upload** a sketch to the target board (using a bootloader preinstalled on the board)
- **program** a sketch to the target board using an external programmer
- **erase** the target board's flash memory using an external programmer
- burn a **bootloader** into the target board using an external programmer

Each action has its own recipe and its configuration is done through a set of properties having key starting with
**tools** prefix followed by the tool ID and the action:

```
[....]
tools.avrdude.upload.pattern=[......]
[....]
tools.avrdude.program.pattern=[......]
[....]
tools.avrdude.erase.pattern=[......]
[....]
tools.avrdude.bootloader.pattern=[......]
[.....]
```

A tool may have some actions not defined (it's not mandatory to define all four actions).<br> Let's look at how the
**upload** action is defined for avrdude:

```
tools.avrdude.path={runtime.tools.avrdude.path}
tools.avrdude.cmd.path={path}/bin/avrdude
tools.avrdude.config.path={path}/etc/avrdude.conf

tools.avrdude.upload.pattern="{cmd.path}" "-C{config.path}" -p{build.mcu} -c{upload.port.protocol} -P{upload.port.address} -b{upload.speed} -D "-Uflash:w:{build.path}/{build.project_name}.hex:i"
```

The tool configuration properties are available globally without the prefix. For example, the **tools.avrdude.cmd.path**
property can be used as **{cmd.path}** inside the recipe, and the same happens for all the other avrdude configuration
variables.

### How to retrieve tools path via `{runtime.tools.*}` properties

A **{runtime.tools.TOOLNAME.path}** and **{runtime.tools.TOOLNAME-TOOLVERSION.path}** property is generated for the
tools provided by the current platform and for any other platform installed via Boards Manager.

See [`{runtime.tools.*.path}` rules](package_index_json-specification.md#how-a-tools-path-is-determined-in-platformtxt)
for details on how the runtime properties are determined.

### Environment variables

All the tools launched to compile or upload a sketch will have the following environment variable set:

`ARDUINO_USER_AGENT`: contains the name and version of the client used by the user in
[HTTP user-agent format](https://en.wikipedia.org/wiki/User_agent), for example `"arduino-cli/0.21.0"`. It may also
contain multiple space-delimited entries like `"arduino-cli/0.21.0 ArduinoIDE/2.0.0-rc1"` if this information is
available.

### Pluggable discovery

Discovery tools are a special kind of tool used to find supported boards. A platform must declare one or more Pluggable
Discoveries in its [`platform.txt`](#platformtxt). Discoveries can be referenced from other packages, including the
`builtin` dummy package which contains the traditional discoveries.

There are two different syntaxes to declare discoveries. If the platform uses just one discovery:

```
pluggable_discovery.required=VENDOR_ID:DISCOVERY_NAME
```

instead if it needs multiple discoveries:

```
pluggable_discovery.required.0=VENDOR_ID:DISCOVERY_0_NAME
pluggable_discovery.required.1=VENDOR_ID:DISCOVERY_1_NAME
```

A platform that supports only boards connected via serial ports can easily use the `builtin` package's
`serial-discovery` without creating a custom pluggable discovery:

```
pluggable_discovery.required=builtin:serial-discovery
```

if it also supports boards connected via the network, it can use the `builtin` package's `mdns-discovery`:

```
pluggable_discovery.required.0=builtin:serial-discovery
pluggable_discovery.required.1=builtin:mdns-discovery
```

Since the above syntax requires specifying a discovery via the `discoveryDependencies` field of the platform's
[package index](package_index_json-specification.md), it might be cumbersome to use with manual installations. So we
provide another syntax to ease development and beta testing:

```
pluggable_discovery.DISCOVERY_ID.pattern=DISCOVERY_RECIPE
```

`DISCOVERY_ID` must be replaced by a unique identifier for the particular discovery and `DISCOVERY_RECIPE` must be
replaced by the command line to launch the discovery. An example could be:

```
## Teensy Ports Discovery
pluggable_discovery.teensy.pattern="{runtime.tools.teensy_ports.path}/hardware/tools/teensy_ports" -J2
```

We strongly recommend using this syntax only for development purposes and not on released platforms.

For backward compatibility, if a platform does not declare any discovery (using the `pluggable_discovery.*` properties
in `platform.txt`) it will automatically inherit `builtin:serial-discovery` and `builtin:mdns-discovery` (but not other
builtin discoveries that may be possibly added in the future).

For detailed information, see the [Pluggable Discovery specification](pluggable-discovery-specification.md).

### Pluggable monitor

Monitor tools are a special kind of tool used to let the user communicate with the supported boards.

A platform must declare one or more Pluggable Monitor in its [`platform.txt`](#platformtxt) and bind them to a specific
port protocol. Monitors can be referenced from other packages.

The following directive is used to bind a specific monitor tool to a specific port protocol:

```
pluggable_monitor.required.PROTOCOL=VENDOR_ID:MONITOR_NAME
```

where `PROTOCOL` must be replaced with the port protocol identifier and `VENDOR_ID:MONITOR_NAME` must be replaced with
the monitor tool identifier.

The platform can support as many protocols as needed:

```
pluggable_monitor.required.PROTOCOL1=VENDOR_ID:MONITOR_NAME1
pluggable_monitor.required.PROTOCOL2=VENDOR_ID:MONITOR_NAME2
...
```

The above syntax requires specifying a monitor tool via the `monitorDependencies` field of the platform's
[package index](package_index_json-specification.md). Since it might be cumbersome to use with manual installations, we
provide another syntax to ease development and beta testing:

```
pluggable_monitor.pattern.PROTOCOL=MONITOR_RECIPE
```

where `MONITOR_RECIPE` must be replaced by the command line to launch the monitor tool for the specific `PROTOCOL`. An
example could be:

```
pluggable_monitor.pattern.custom-ble="{runtime.tools.my-ble-monitor.path}/my-ble-monitor" -H
```

in this case the platform provides a new hypothetical `custom-ble` protocol monitor tool and the command line tool named
`my-ble-monitor` is launched with the `-H` parameter to start the monitor tool. In this case the command line pattern
may contain any extra parameter in the formula: this is different from the monitor tools installed through the
`monitorDependencies` field that must run without any command line parameter.

We strongly recommend using this syntax only for development purposes and not on released platforms.

#### Built-in monitors

If a platform supports only boards connected via serial ports it can easily use the `builtin:serial-monitor` tool
without creating a custom pluggable monitor:

```
pluggable_monitor.required.serial=builtin:serial-monitor
```

#### Backward compatibility

For backward compatibility, if a platform does not declare any discovery or monitor tool (using the
`pluggable_discovery.*` or `pluggable_monitor.*` properties in `platform.txt` respectively) it will automatically
inherit `builtin:serial-monitor` (but not other `builtin` monitor tools that may be possibly added in the future). This
will allow all legacy non-pluggable platforms to migrate to pluggable monitor without disruption.

For detailed information, see the [Pluggable Monitor specification](pluggable-monitor-specification.md).

#### Port configuration

Each pluggable monitor has its own default settings that can be overridden using the following board properties:

```
BOARD_ID.monitor_port.PROTOCOL.SETTING_NAME=SETTING_VALUE
```

where:

- `BOARD_ID` is the board identifier
- `PROTOCOL` is the port protocol
- `SETTING_NAME` and `SETTING_VALUE` are the port setting and the desired value

For example, let's suppose that a board needs the `baudrate` setting of the `serial` port to be `9600`, then the
corresponding properties in the `boards.txt` file will be:

```
myboard.monitor_port.serial.baudrate=9600
```

The settings available in a specific pluggable monitor can be
[queried directly from it](pluggable-monitor-specification.md#describe-command).

#### Legacy `serial.disableRTS` and `serial.disableDTR` properties

In the old Arduino IDE (<=1.8.x) we used the properties:

```
BOARD_ID.serial.disableRTS=true
BOARD_ID.serial.disableDTR=true
```

to disable RTS and DTR when opening the serial monitor. To keep backward compatibilty the properties above are
automatically converted to the corresponding pluggable monitor properties:

```
BOARD_ID.monitor_port.serial.rts=off
BOARD_ID.monitor_port.serial.dtr=off
```

### Verbose parameter

It is possible for the user to enable verbosity from the Preferences panel of the IDEs or Arduino CLI's `--verbose`
flag. This preference is transferred to the command line using the **ACTION.verbose** property (where ACTION is the
action we are considering).<br> When the verbose mode is enabled, the **tools.TOOL_ID.ACTION.params.verbose** property
is copied into **ACTION.verbose**. When the verbose mode is disabled, the **tools.TOOL_ID.ACTION.params.quiet** property
is copied into **ACTION.verbose**. Confused? Maybe an example will make things clear:

```
tools.avrdude.upload.params.verbose=-v -v -v -v
tools.avrdude.upload.params.quiet=-q -q
tools.avrdude.upload.pattern="{cmd.path}" "-C{config.path}" {upload.verbose} -p{build.mcu} -c{upload.protocol} -P{serial.port} -b{upload.speed} -D "-Uflash:w:{build.path}/{build.project_name}.hex:i"
```

In this example if the user enables verbose mode, then **{upload.params.verbose}** is used in **{upload.verbose}**:

```
tools.avrdude.upload.params.verbose    =>    upload.verbose
```

If the user didn't enable verbose mode, then **{upload.params.quiet}** is used in **{upload.verbose}**:

```
tools.avrdude.upload.params.quiet      =>    upload.verbose
```

### Sketch upload configuration

The Upload action is triggered when the user clicks on the "Upload" button on the IDE toolbar or uses
[`arduino-cli upload`](commands/arduino-cli_upload.md). Arduino uses the term "upload" for the process of transferring a
program to the Arduino board.

The **upload.tool.<protocol_name\>** property determines the tool to be used for upload. A specific
**upload.tool.<protocol_name\>** property should be defined for every board in boards.txt:

```
[......]
uno.upload.tool.serial=avrdude
[......]
leonardo.upload.tool.serial=avrdude
leonardo.upload.tool.network=arduino_ota
[......]
```

Multiple protocols can be defined for each board. When the user tries to upload using a protocol not supported by the
board, it will fallback to `default` if one was defined:

```
[......]
uno.upload.tool.default=avrdude
[......]
leonardo.upload.tool.default=avrdude
leonardo.upload.tool.network=arduino_ota
[......]
```

`default` is also used when no upload address is provided by the user. This can be used with tools that have built-in
port detection (e.g., `openocd`).

For backward compatibility with IDE 1.8.15 and older the previous syntax is still supported:

```
uno.upload.tool=avrdude
```

The previous syntax is equivalent to:

```
uno.upload.tool.default=avrdude
```

Other upload parameters can also be defined for the board. For example, in the Arduino AVR Boards boards.txt we have:

```
[.....]
uno.name=Arduino Uno
uno.upload.tool.serial=avrdude
uno.upload.protocol=arduino
uno.upload.maximum_size=32256
uno.upload.speed=115200
[.....]
leonardo.name=Arduino Leonardo
leonardo.upload.tool.serial=avrdude
leonardo.upload.protocol=avr109
leonardo.upload.maximum_size=28672
leonardo.upload.speed=57600
leonardo.upload.use_1200bps_touch=true
leonardo.upload.wait_for_upload_port=true
[.....]
```

Most **{upload.XXXX}** variables are used later in the avrdude upload recipe in platform.txt:

```
[.....]
tools.avrdude.upload.pattern="{cmd.path}" "-C{config.path}" {upload.verbose} -p{build.mcu} -c{upload.port.protocol} -P{upload.port.address} -b{upload.speed} -D "-Uflash:w:{build.path}/{build.project_name}.hex:i"
[.....]
```

If necessary the same property can be defined multiple times for different protocols:

```
leonardo.upload.serial.speed=57600
leonardo.upload.network.speed=19200
```

The two above properties will be available as **{upload.speed}**, the value will depend on the protocol used to upload.

#### Properties from pluggable discovery

If a platform supports pluggable discovery it can also use the port's properties returned by a discovery. For example,
the following port metadata coming from a pluggable discovery:

```
   {
      "eventType": "add",
      "port": {
        "address": "/dev/ttyACM0",
        "label": "ttyACM0",
        "protocol": "serial",
        "protocolLabel": "Serial Port (USB)",
        "properties": {
          "pid": "0x804e",
          "vid": "0x2341",
          "serialNumber": "EBEABFD6514D32364E202020FF10181E",
          "name": "ttyACM0"
        }
      }
    }
```

will be available on the recipe as the variables:

```
{upload.port.address} = /dev/ttyACM0
{upload.port.label} = ttyACM0
{upload.port.protocol} = serial
{upload.port.protocolLabel} = Serial Port (USB)
{upload.port.properties.pid} = 0x8043
{upload.port.properties.vid} = 0x2341
{upload.port.properties.serialNumber} = EBEABFD6514D32364E202020FF10181E
{upload.port.properties.name} = ttyACM0
{serial.port} = /dev/ttyACM0                # for backward compatibility
{serial.port.file} = ttyACM0                # only because protocol=serial
```

Here another example:

```
    {
      "eventType": "add",
      "port": {
        "address": "192.168.1.232",
        "label": "SSH on my-board (192.168.1.232)",
        "protocol": "ssh",
        "protocolLabel": "SSH Network port",
        "properties": {
          "macprefix": "AA:BB:CC",
          "macaddress": "AA:BB:CC:DD:EE:FF"
        }
      }
    }
```

that is translated to:

```
{upload.port.address} = 192.168.1.232
{upload.port.label} = SSH on my-board (192.168.1.232)
{upload.port.protocol} = ssh
{upload.port.protocolLabel} = SSH Network port
{upload.port.properties.macprefix} = AA:BB:CC
{upload.port.properties.macaddress} = AA:BB:CC:DD:EE:FF
{serial.port} = 192.168.1.232                  # for backward compatibility
```

This configuration, together with protocol selection, allows to remove the hardcoded `network_pattern`. Now we can
replace the legacy recipe (split into multiple lines for clarity):

```
tools.bossac.upload.network_pattern="{runtime.tools.arduinoOTA.path}/bin/arduinoOTA"
                                -address {serial.port} -port 65280
                                -sketch "{build.path}/{build.project_name}.bin"
```

with:

```
tools.arduino_ota.upload.pattern="{runtime.tools.arduinoOTA.path}/bin/arduinoOTA"
                            -address {upload.port.address} -port 65280
                            -sketch "{build.path}/{build.project_name}.bin"
```

#### User provided fields

Some upload recipes might require custom fields that must be provided by the user, like username and password to upload
over the network. In this case the recipe must use the special placeholder **{upload.field.FIELD_NAME}**, where
**FIELD_NAME** must be declared separately in the recipe using the following format:

```
tools.UPLOAD_RECIPE_ID.upload.field.FIELD_NAME=FIELD_LABEL
tools.UPLOAD_RECIPE_ID.upload.field.FIELD_NAME.secret=true
```

**FIELD_LABEL** is the label shown in the graphical prompt where the user is asked to enter the value for the field.

The optional **secret** property should be set to `true` if the field is a secret (like a password or token).

Let's see a complete example:

```
tools.arduino_ota.upload.field.username=Username
tools.arduino_ota.upload.field.password=Password
tools.arduino_ota.upload.field.password.secret=true
tools.arduino_ota.upload.pattern="{runtime.tools.arduinoOTA.path}/bin/arduinoOTA" -address {upload.port.address} -port 65280 -username "{upload.field.username} -password "{upload.field.password}" -sketch "{build.path}/{build.project_name}.bin"
```

If a **FIELD_LABEL** is longer than 50 characters it will be truncated to 49 characters and an ellipsis (`…`) appended
to it. For example this field:

```
tools.arduino_ota.upload.field.some_field=This is a really long label that ideally must never be set by any platform
```

will be shown to the user as:

```
This is a really long label that ideally must nev…
```

#### Upload verification

Upload verification can be enabled via the Arduino IDE's **File > Preferences > Verify code after upload** or
`arduino-cli upload --verify`. This uses a system similar to the [verbose parameter](#verbose-parameter).

**tools.TOOL_ID.ACTION.params.verify** defines the value of the **ACTION.verify** property when verification is enabled
and **tools.TOOL_ID.ACTION.params.noverify** the value when verification is disabled.

The **{ACTION.verify}** property is only defined for the `upload` and `program` actions of `upload.tool`.

Prior to Arduino IDE 1.6.9, **tools.TOOL_ID.ACTION.params.verify/noverify** were not supported and `{upload.verify}` was
set to `true`/`false` according to the verification preference setting, while `{program.verify}` was left undefined. For
this reason, backwards compatibility with older IDE versions requires the addition of definitions for the
**upload.verify** and **program.verify** properties to platform.txt:

```
[.....]
tools.avrdude.upload.verify=
[.....]
tools.avrdude.program.verify=
[.....]
```

These definitions are overridden with the value defined by **tools.TOOL_ID.ACTION.params.verify/noverify** when a modern
version of Arduino development software is in use.

#### 1200 bps bootloader reset

Some Arduino boards use a dedicated USB-to-serial chip, that takes care of restarting the main MCU (starting the
bootloader) when the serial port is opened. However, boards that have a native USB connection (such as the Leonardo or
Zero) will have to disconnect from USB when rebooting into the bootloader (after which the bootloader reconnects to USB
and offers a new serial port for uploading). After the upload is complete, the bootloader disconnects from USB again,
starts the sketch, which then reconnects to USB. Because of these reconnections, the standard restart-on-serial open
will not work, since that would cause the serial port to disappear and be closed again. Instead, the sketch running on
these boards interprets a bitrate of 1200 bps as a signal the bootloader should be started.

To let the Arduino development software perform these steps, two board properties can be set to `true`:

- `use_1200bps_touch` causes the selected serial port to be briefly opened at 1200 bps (8N1) before starting the upload.
- `wait_for_upload_port` causes the upload procedure to wait for the serial port to (re)appear before and after the
  upload. This is only used when `use_1200bps_touch` is also set. When set, after doing the 1200 bps touch, the
  development software will wait for a new serial port to appear and use that as the port for uploads. Alternatively, if
  the original port does not disappear within a few seconds, the upload continues with the original port (which can be
  the case if the board was already put into bootloader manually, or the the disconnect and reconnect was missed).
  Additionally, after the upload is complete, the IDE again waits for a new port to appear (or the originally selected
  port to be present).

Note that the IDE implementation of this 1200 bps touch has some peculiarities, and the newer `arduino-cli`
implementation also seems different (does not wait for the port after the reset, which is probably only needed in the
IDE to prevent opening the wrong port on the serial monitor, and does not have a shorter timeout when the port never
disappears).

#### Upload Using Programmer by default

If the **upload.protocol** property is not defined for a board, the Arduino IDE's "Upload" process will use the same
behavior as ["Upload Using Programmer"](#upload-using-an-external-programmer). This is convenient for boards which only
support uploading via programmer.

### Serial port

The full path (e.g., `/dev/ttyACM0`) of the port selected via the IDE or
[`arduino-cli upload`](commands/arduino-cli_upload.md)'s `--port` option is available as a configuration property
**{upload.port.address}**.

The file component of the port's path (e.g., `ttyACM0`) is available as the configuration property
**{upload.port.label}**.

For backward compatibility with IDE 1.8.15 and older the old property **serial.port** is still available and is
identical to **{upload.port.address}**. Instead **serial.port.file** is identical to **{upload.port.label}** and
available only if protocol in use is **serial**.

### Upload using an external programmer

The `program` action is triggered via the **Sketch > Upload Using Programmer** feature of the IDEs or
[`arduino-cli upload --programmer <programmer ID>`](commands/arduino-cli_upload.md). This action is used to transfer a
compiled sketch to a board using an external programmer.

The **program.tool** property determines the tool to be used for this action. This property is typically defined for
each programmer in [programmers.txt](#programmerstxt) and uses the same syntax as
[the `upload` action](#sketch-upload-configuration):

```
[......]
usbasp.program.tool.serial=avrdude
[......]
arduinoasisp.program.tool.serial=avrdude
[......]
arduinoisp.program.tool.default=avrdude
[......]
```

For backward compatibility with IDE 1.8.15 and older the previous syntax is still supported:

```
[......]
usbasp.program.tool=avrdude
[......]
arduinoasisp.program.tool=avrdude
[......]
```

This action can use the same [upload verification preference system](#upload-verification) as the `upload` action, via
the **program.verify** property.

When using the Arduino IDE, if the selected programmer is from a different platform than the board, the `program` recipe
defined in the programmer's platform is used without overrides from the properties defined in the
[platform.txt](#platformtxt) of the [board platform](#platform-terminology). When using Arduino development software
other than the Arduino IDE, the handling of properties is the same as when doing a
[standard Upload](#sketch-upload-configuration).

### Burn Bootloader

The `erase` and `bootloader` actions are triggered via the **Tools > Burn Bootloader** feature of the Arduino IDE or
[`arduino-cli burn-bootloader`](commands/arduino-cli_burn-bootloader.md). This action is used to flash a bootloader to
the board.

"Burn Bootloader" is unique in that it uses two actions, which are executed in sequence:

1. `erase` is typically used to erase the microcontroller's flash memory and set the configuration fuses according to
   the properties defined in the [board definition](#boardstxt)
1. `bootloader` is used to flash the bootloader to the board

The **bootloader.tool** property determines the tool to be used for the `erase` and `bootloader` actions both. This
property is typically defined for each board in boards.txt and uses the same syntax as
[the `upload` action](#sketch-upload-configuration):

```
[......]
uno.bootloader.tool.serial=avrdude
[......]
leonardo.bootloader.tool.serial=avrdude
leonardo.bootloader.tool.network=arduino_ota
[......]
duemilanove.bootloader.tool.default=avrdude
[......]
```

For backward compatibility with IDE 1.8.15 and older the previous syntax is still supported:

```
[......]
uno.bootloader.tool=avrdude
[......]
leonardo.bootloader.tool=avrdude
[......]
```

When using the Arduino IDE, if the board uses a
[core reference](https://arduino.github.io/arduino-cli/dev/platform-specification/#core-reference), the platform.txt of
the [core platform](#platform-terminology) is not used at all in defining the recipes for `erase` and `bootloader`
actions. When using Arduino development software other than the Arduino IDE, the handling of properties from the core
platform's platform.txt is done as usual.

## Sketch debugging configuration

Starting from Arduino CLI 0.9.0 / Arduino IDE 2.x, sketch debugging support is available for platforms.

The debug action is triggered when the user clicks the Debug button in the Arduino IDE or runs the
[`arduino-cli debug`](commands/arduino-cli_debug.md) command.

Since opening a debug session requires the orchestration of numerous tools, the CLI/IDE will take care of that duty:
differently from the upload actions, there is no need for the platform to provide debug recipes, the only requirement is
to provide some debug configuration directives.

### Debugger configuration directives

All the debug directives are grouped under the `debug.*` directives. Here is the complete list of the supported
directives:

- `debug.executable`: is the absolute path to the compiled binary of the sketch
- `debug.toolchain`: is a unique identifier of the required toolchain, currently we support `gcc` (and compatible) only
- `debug.toolchain.path`: is the absolute path to the toolchain directory
- `debug.toolchain.prefix`: is the prefix of the toolchain (for example `arm-none-eabi-`)
- `debug.server`: is a unique identifier of the required debug server, currently we support only `openocd`
- `debug.svd_file`: is the absolute path to the SVD descriptor.

If the `debug.executable` property is not present or is empty debugging will not be allowed.

OpenOCD server specific configurations:

- `debug.server.openocd.path`: is the absolute path to the OpenOCD directory
- `debug.server.openocd.scripts_dir`: is the absolute path to the OpenOCD scripts directory
- `debug.server.openocd.scripts.N`: is a list of OpenOCD script files to run, where N is a number (a sequence of
  non-consecutive numbers is allowed)
- `debug.server.openocd.script`: if there is only one OpenOCD script to run, this directive con be used instead of the
  `debug.server.openocd.scripts.N` (this directive is ignored if `debug.server.openocd.scripts.N` is present)

### Custom config for Cortext-debug plugin for Arduino IDE

The Arduino IDE uses cortex-debug plugin to start a debugging session. The IDE creates a `launch.json` file that is
needed to start the debugging via the cortex-debug plugin. To give the platform developers more flexibility, it is
allowed to pass any extra arbitrary setup to `launch.json` generated by the IDE. To allow this the directives under the
group `debug.cortex-debug.custom.*` are converted into JSON and added to the generated `launch.json` as-is. Moreover, if
a directive has a key with a numeric suffix, it is converted into a JSON array.

For example the following directives:

```
debug.cortex-debug.custom.postAttachCommands.0=set remote hardware-watchpoint-limit 2
debug.cortex-debug.custom.postAttachCommands.1=monitor reset halt
debug.cortex-debug.custom.postAttachCommands.2=monitor gdb_sync
debug.cortex-debug.custom.postAttachCommands.3=thb setup
debug.cortex-debug.custom.postAttachCommands.4=c
debug.cortex-debug.custom.overrideRestartCommands.0=monitor reset halt
debug.cortex-debug.custom.overrideRestartCommands.1=monitor gdb_sync
debug.cortex-debug.custom.overrideRestartCommands.2=thb setup
debug.cortex-debug.custom.overrideRestartCommands.3=c
```

will result in the following JSON to be merged in the Arduino IDE generated `launch.json`:

```json
{
  "overrideRestartCommands": ["monitor reset halt", "monitor gdb_sync", "thb setup", "c"],
  "postAttachCommands": [
    "set remote hardware-watchpoint-limit 2",
    "monitor reset halt",
    "monitor gdb_sync",
    "thb setup",
    "c"
  ]
}
```

All the values are converted by default to a string in the resulting JSON. If another type is needed the value can be
prefixed with the tags `[boolean]`, `[number]`, `[string]` or `[object]` to force a specific type in the JSON. Moreover
the hierarchy of the properties may be used to build JSON objects. For example:

```
debug.cortex-debug.custom.aBoolean=[boolean]true
debug.cortex-debug.custom.aNumber=[number]10
debug.cortex-debug.custom.anotherNumber=[number]10.20
debug.cortex-debug.custom.anObject=[object]{"key":"value", "boolean":true}
debug.cortex-debug.custom.anotherObject.key=value
debug.cortex-debug.custom.anotherObject.boolean=[boolean]true
```

will result in the following JSON:

```json
{
  "aBoolean": true,
  "aNumber": 10,
  "anotherNumber": 10.2,
  "anObject": {
    "boolean": true,
    "key": "value"
  },
  "anotherObject": {
    "boolean": true,
    "key": "value"
  }
}
```

### Additional debugger config selection via `debug.additional_config` directive.

It is possible to use any sub-tree of the platform configuration to override the debugger configuration using the
directive `debug.additional_config=CONFIG_PREFIX`. This rule will use the configuration under `CONFIG_PREFIX.*` to
override the current `debug.*` config.

This change allows a more convenient rationalization and selection of the configs to apply to the debugger. For example,
we could factor common parts of a configuration in the platform.txt file:

```
# CONFIG 1
debug-overrides.esp32.cortex-debug.custom.name=Arduino on ESP32
debug-overrides.esp32.cortex-debug.custom.request=attach
debug-overrides.esp32.cortex-debug.custom.postAttachCommands.0=set remote hardware-watchpoint-limit 2
debug-overrides.esp32.cortex-debug.custom.postAttachCommands.1=monitor reset halt
debug-overrides.esp32.cortex-debug.custom.postAttachCommands.2=monitor gdb_sync
debug-overrides.esp32.cortex-debug.custom.postAttachCommands.3=thb setup
debug-overrides.esp32.cortex-debug.custom.postAttachCommands.4=c
debug-overrides.esp32.cortex-debug.custom.overrideRestartCommands.0=monitor reset halt
debug-overrides.esp32.cortex-debug.custom.overrideRestartCommands.1=monitor gdb_sync
debug-overrides.esp32.cortex-debug.custom.overrideRestartCommands.2=thb setup
debug-overrides.esp32.cortex-debug.custom.overrideRestartCommands.3=c

# CONFIG 2
debug-overrides.esp32s2.cortex-debug.custom.name=Arduino on ESP32-S2
debug-overrides.esp32s2.cortex-debug.custom.request=attach
debug-overrides.esp32s2.cortex-debug.custom.postAttachCommands.0=set remote hardware-watchpoint-limit 2
debug-overrides.esp32s2.cortex-debug.custom.postAttachCommands.1=monitor reset halt
debug-overrides.esp32s2.cortex-debug.custom.postAttachCommands.2=monitor gdb_sync
debug-overrides.esp32s2.cortex-debug.custom.postAttachCommands.3=thb setup
debug-overrides.esp32s2.cortex-debug.custom.postAttachCommands.4=c
debug-overrides.esp32s2.cortex-debug.custom.overrideRestartCommands.0=monitor reset halt
debug-overrides.esp32s2.cortex-debug.custom.overrideRestartCommands.1=monitor gdb_sync
debug-overrides.esp32s2.cortex-debug.custom.overrideRestartCommands.2=thb setup
debug-overrides.esp32s2.cortex-debug.custom.overrideRestartCommands.3=c
```

and choose which one to use depending on the board in the boards.txt file:

```
myboard.name=My Board with esp32
myboard.debug.additional_config=debug-overrides.esp32

anotherboard.name=My Board with esp32s2
anotherboard.debug.additional_config=debug-overrides.esp32s2
...
```

Another possibility is to compose the configuration using another variable present in the board configuration, for
example if in the `platform.txt` we add:

```
debug.additional_config=debug-overrides.{build.mcu}
```

we may use the `build.mcu` value as a "selector" for the board-specific debug configuration that is overlapped to the
global debug configuration:

```
myboard.name=My Board with esp32
myboard.build.mcu=esp32
...

anotherboard.name=My Board with esp32s2
anotherboard.build.mcu=esp32s2
...
```

### Optimization level for debugging

The compiler optimization level that is appropriate for normal usage will often not provide a good experience while
debugging. For this reason, it may be helpful to use different compiler flags when compiling a sketch for use with the
debugger. The flags for use when compiling for debugging can be defined via the **compiler.optimization_flags.debug**
property, and those for normal use via the **compiler.optimization_flags.release** property. The
**compiler.optimization_flags** property will be defined according to one or the other depending on the Arduino Pro
IDE's **Sketch > Optimize for Debugging** setting or [`arduino-cli compile`](commands/arduino-cli_compile.md)'s
`--optimize-for-debug` option.

## Custom board options

It can sometimes be useful to provide user selectable configuration options for a specific board. For example, a board
could be provided in two or more variants with different microcontrollers, or may have different crystal speed based on
the board model, and so on...

When using Arduino CLI, the option can be selected via the FQBN, or using the `--board-options` flag

In the Arduino IDE the options add extra menu items under the "Tools" menu.

In Arduino Web Editor, the options are displayed in the "Flavours" menu.

Let's see an example of how a custom option is implemented. The board used in the example is the Arduino Duemilanove.
This board was produced in two models, one with an ATmega168 microcontroller and another with an ATmega328P.<br> We are
going then to define a custom option, using the "cpu" MENU_ID, that allows the user to choose between the two different
microcontrollers.

We must first define a set of **menu.MENU_ID=Text** properties.

The menu ID must not contain any characters other than the letters `A`-`Z` and `a`-`z`, numbers (`0`-`9`), underscores
(`_`), and dashes (`-`).

**Text** is what is displayed on the GUI for every custom menu we are going to create and must be declared at the
beginning of the boards.txt file:

```
menu.cpu=Processor
[.....]
```

in this case, the menu name is "Processor".<br> Now let's add, always in the boards.txt file, the default configuration
(common to all processors) for the duemilanove board:

```
menu.cpu=Processor
[.....]
duemilanove.name=Arduino Duemilanove
duemilanove.upload.tool=avrdude
duemilanove.upload.protocol=arduino
duemilanove.build.f_cpu=16000000L
duemilanove.build.board=AVR_DUEMILANOVE
duemilanove.build.core=arduino
duemilanove.build.variant=standard
[.....]
```

Now let's define the possible values of the "cpu" option:

```
[.....]
duemilanove.menu.cpu.atmega328=ATmega328P
[.....]
duemilanove.menu.cpu.atmega168=ATmega168
[.....]
```

We have defined two values: "atmega328" and "atmega168".<br> Note that the property keys must follow the format
**BOARD_ID.menu.MENU_ID.OPTION_ID=Text**, where **Text** is what is displayed under the "Processor" menu in the IDE's
GUI.

The option ID must not contain any characters other than the letters `A`-`Z` and `a`-`z`, numbers (`0`-`9`), underscores
(`_`), dashes (`-`), and equal signs (`=`).

Finally, the specific configuration for each option value:

```
[.....]
## Arduino Duemilanove w/ ATmega328P
duemilanove.menu.cpu.atmega328=ATmega328P
duemilanove.menu.cpu.atmega328.upload.maximum_size=30720
duemilanove.menu.cpu.atmega328.upload.speed=57600
duemilanove.menu.cpu.atmega328.build.mcu=atmega328p

## Arduino Duemilanove w/ ATmega168
duemilanove.menu.cpu.atmega168=ATmega168
duemilanove.menu.cpu.atmega168.upload.maximum_size=14336
duemilanove.menu.cpu.atmega168.upload.speed=19200
duemilanove.menu.cpu.atmega168.build.mcu=atmega168
[.....]
```

Note that when the user selects an option value, all the "sub properties" of that value are copied in the global
configuration. For example, when the user selects "ATmega168" from the "Processor" menu, or uses the FQBN
`arduino:avr:duemilanove:cpu=atmega168` with Arduino CLI, the configuration under atmega168 is made available globally:

```
duemilanove.menu.cpu.atmega168.upload.maximum_size     =>   upload.maximum_size
duemilanove.menu.cpu.atmega168.upload.speed            =>   upload.speed
duemilanove.menu.cpu.atmega168.build.mcu               =>   build.mcu
```

There is no limit to the number of custom menus that can be defined.

## Referencing another core, variant or tool

The Arduino platform referencing system allows using components of other platforms in cases where it would otherwise be
necessary to duplicate those components. This feature allows us to reduce the minimum set of files needed to define a
new "hardware" to just the boards.txt file.

### Core reference

Inside the boards.txt we can define a board that uses a core provided by another vendor/maintainer using the syntax
**VENDOR_ID:CORE_ID**. For example, if we want to define a board that uses the "arduino" core from the "arduino" vendor
we should write:

```
[....]
myboard.name=My Wonderful Arduino Compatible board
myboard.build.core=arduino:arduino
[....]
```

Note that we don't need to specify any architecture since the same architecture of "myboard" is used, so we just say
"arduino:arduino" instead of "arduino:avr:arduino".

The platform.txt settings are inherited from the referenced core platform, thus there is no need to provide a
platform.txt unless there are some specific properties that need to be overridden.

The [bundled libraries](#platform-bundled-libraries) from the referenced platform are used, thus there is no need for
the referencing platform to bundle those libraries. If libraries are provided, the list of available libraries is the
sum of the two libraries, where the referencing platform has priority over the referenced platform.

The [programmers](#programmerstxt) from the referenced platform are made available, thus there is no need for the
referencing platform to define those programmers. If the referencing platform does provide its own programmer
definitions, the list of available programmer is the sum of the programmers of the two platforms. In Arduino IDE 1.8.12
and older, all programmers of all installed platforms were made available.

### Variant reference

In the same way we can use a variant defined on another platform using the syntax **VENDOR_ID:VARIANT_ID**:

```
[....]
myboard.build.variant=arduino:standard
[....]
```

Note that, unlike core references, other resources (platform.txt, bundled libraries, programmers) are _not_ inherited
from the referenced platform.

### Tool references

Tool recipes defined in the platform.txt of other platforms can also be referenced using the syntax
**VENDOR_ID:TOOL_ID**:

```
[....]
myboard.upload.tool=arduino:avrdude
myboard.bootloader.tool=arduino:avrdude
[....]
```

When using Arduino CLI or Arduino IDE 2.x (but not Arduino IDE 1.x), properties used in the referenced tool recipe may
be overridden in the referencing platform's platform.txt.

Note that, unlike core references, referencing a tool recipe does _not_ result in any other resources being inherited
from the referenced platform.

### Platform Terminology

Because boards can reference cores, variants and tools in different platforms, this means that a single build or upload
can use data from up to four different platforms. To keep this clear, the following terminology is used:

- The "board platform" is the platform that defines the currently selected board (e.g. the platform that contains the
  board.txt the board is defined in.
- The "core platform" is the the platform that contains the core to be used.
- The "variant platform" is the platform that contains the variant to be used.
- The "tool platform" is the platform that contains the tool used for the current operation.

In the most common case: a board platform without any references, all of these will refer to the same platform.

Note that the above terminology is not in widespread use, but was invented for clarity within this document. In the
actual Arduino CLI code, the "board platform" is called `targetPlatform`, the "core platform" is called
`actualPlatform`, the others are pretty much nameless.

## boards.local.txt

Introduced in Arduino IDE 1.6.6. This file can be used to override properties defined in `boards.txt` or define new
properties without modifying `boards.txt`. It must be placed in the same folder as the `boards.txt` it supplements.

## Platform bundled libraries

Arduino libraries placed in the platform's `libraries` subfolder are accessible when a board of the platform, or of a
platform that [references](#referencing-another-core-variant-or-tool) the platform's core, is selected. When any other
board is selected, the platform bundled libraries are inaccessible.

These are often architecture-specific libraries (e.g., SPI, Wire) which must be implemented differently for each
architecture.

Platform bundled libraries may be used to provide specialized versions of libraries which use the
[dependency resolution system](sketch-build-process.md#dependency-resolution) to override built-in libraries.

For more information, see the [Arduino library specification](library-specification.md).

## keywords.txt

As of Arduino IDE 1.6.6, per-platform keywords can be defined by adding a keywords.txt file to the platform's
architecture folder. These keywords are only highlighted in the Arduino IDE when one of the boards of that platform are
selected. This file follows the [same format](library-specification.md#keywords) as the keywords.txt used in libraries.

## Post-install script

After Boards Manager finishes installation of a platform, it checks for the presence of a script named:

- `post_install.bat` - when running on Windows
- `post_install.sh` - when running on any non-Windows operating system

If present, the script is executed.

This script may be used to configure the user's system for the platform, such as installing drivers.

The circumstances under which the post-install script will run are different depending on which Arduino development
software is in use:

- **Arduino IDE 1.x**: runs the script when the installed platform is signed with Arduino's private key.
- **Arduino IDE 2.x**: runs the script for any installed platform.
- **Arduino CLI**: (since 0.12.0) runs the script for any installed platform when Arduino CLI is in "interactive" mode.
  This behavior
  [can be configured](https://arduino.github.io/arduino-cli/latest/commands/arduino-cli_core_install/#options)

## Pre-uninstall script

Before Boards Manager starts uninstalling a platform, it checks for the presence of a script named:

- `pre_uninstall.bat` - when running on Windows
- `pre_uninstall.sh` - when running on any non-Windows operating system

If present, the script is executed.

This script may be used to configure the user's system for the removal of drivers, stopping background programs and
execute any action that should be performed before the platform files are removed.

The circumstances under which the pre-uninstall script will run are different depending on which Arduino development
software is in use:

- **Arduino CLI**: runs the script for any installed platform when Arduino CLI is in "interactive" mode. This behavior
  [can be configured](https://arduino.github.io/arduino-cli/latest/commands/arduino-cli_core_install/#options)