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rust:va108xx-hal-v0.11.1 rust:va108xx-embassy-v0.2.1 rust:vorago-reb1-v0.8.1 rust:va108xx-hal-v0.11.0 rust:va108xx-embassy-v0.2.0 rust:vorago-reb1-v0.8.0 rust:va108xx-hal-v0.10.0 rust:va108xx-v0.5.0 rust:va108xx-embassy-v0.1.2 rust:vorago-reb1-v0.7.0 rust:va108xx-hal-v0.9.0 rust:va108xx-v0.4.0 rust:vorago-reb1-v0.6.0 rust:va108xx-hal-v0.8.0 rust:vorago-reb1-v0.5.1 rust:va108xx-hal-v0.7.0 rust:vorago-reb1-v0.5.0 rust:va108xx-hal-v0.6.0 rust:va108xx-v0.3.0
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rust:va108xx-hal-v0.11.1 rust:va108xx-embassy-v0.2.1 rust:vorago-reb1-v0.8.1 rust:va108xx-hal-v0.11.0 rust:va108xx-embassy-v0.2.0 rust:vorago-reb1-v0.8.0 rust:va108xx-hal-v0.10.0 rust:va108xx-v0.5.0 rust:va108xx-embassy-v0.1.2 rust:vorago-reb1-v0.7.0 rust:va108xx-hal-v0.9.0 rust:va108xx-v0.4.0 rust:vorago-reb1-v0.6.0 rust:va108xx-hal-v0.8.0 rust:vorago-reb1-v0.5.1 rust:va108xx-hal-v0.7.0 rust:vorago-reb1-v0.5.0 rust:va108xx-hal-v0.6.0 rust:va108xx-v0.3.0

87 Commits
vorago-reb ... va108xx-ha

Author SHA1 Message Date
Robin Müller
bd286bdb2a Merge pull request 'small README tweak' (#44) from readme-tweak into main 
Reviewed-on: #44
 2025-02-13 14:56:48 +01:00
Robin Mueller
d3cc00a4a5 small README tweak 2025-02-13 14:56:24 +01:00
Robin Müller
1018a65447 Merge pull request 'add more defmt features' (#42) from add-more-defmt-features into main 
Reviewed-on: #42
 2025-02-13 14:52:03 +01:00
Robin Mueller
0a31b637e6 add more defmt features 2025-02-13 14:51:54 +01:00
Robin Müller
6e1ae70054 Merge pull request 'add various debug impls' (#43) from add-various-debug-impls into main 
Reviewed-on: #43
 2025-02-13 14:51:27 +01:00
Robin Mueller
8ae2d6189a add various debug impls 2025-02-13 14:50:00 +01:00
Robin Müller
549a98dbaf Merge pull request 'all doc fixes' (#41) from doc-fixes into main 
Reviewed-on: #41
 2025-02-13 12:23:56 +01:00
Robin Mueller
e24fc608a3 all doc fixes 2025-02-13 11:44:14 +01:00
Robin Müller
7b74312013 Merge pull request 'completed async RX support as well' (#39) from async-uart-rx into main 
Reviewed-on: #39
 2025-02-13 11:33:36 +01:00
Robin Mueller
417f5b7f67 completed async RX support as well 2025-02-13 11:31:17 +01:00
Robin Müller
3e796ef22b Merge pull request 'UART B hotfix' (#40) from uart-b-hotfix into main 
Reviewed-on: #40
 2025-02-13 11:30:37 +01:00
Robin Mueller
b145047b95 UART B hotfix 2025-02-13 11:14:39 +01:00
Robin Müller
82b4c16f8e Merge pull request 'bump PAC version' (#38) from bump-va108xx-version into main 
Reviewed-on: #38
 2025-02-12 14:57:53 +01:00
Robin Mueller
189ac2d256 bump PAC version 2025-02-12 14:47:18 +01:00
Robin Müller
c5543d8606 Merge pull request 'add back doc attribute' (#37) from prep-pac-release into main 
Reviewed-on: #37
 2025-02-12 14:25:28 +01:00
Robin Mueller
691911d087 add back doc attribute 2025-02-12 14:23:25 +01:00
Robin Müller
3953897c48 Merge pull request 'Async UART support' (#33) from async-uart into main 
Reviewed-on: #33
 2025-02-12 14:15:10 +01:00
Robin Mueller
6e0d417a5c Async UART TX support 2025-02-12 14:13:35 +01:00
Robin Müller
4edba63b02 Merge pull request 'docs fix' (#36) from docs-fix into main 
Reviewed-on: #36
 2025-02-12 14:11:21 +01:00
Robin Mueller
bcd79f0f20 docs fix 2025-02-12 14:07:18 +01:00
Robin Müller
77608da74e Merge pull request 'dynpin defmt bugfix' (#35) from dynpin-fix-2 into main 
Reviewed-on: #35
 2025-02-12 14:06:51 +01:00
Robin Mueller
066d91aee5 dynpin defmt bugfix 2025-02-12 14:06:41 +01:00
Robin Müller
e869355960 Merge pull request 'Regenerate PAC' (#29) from regenerate-pac into main 
Reviewed-on: #29
 2025-02-12 14:05:06 +01:00
Robin Mueller
99631dbd03 va108xx v0.4.0: Regnerate PAC 2025-02-12 14:04:56 +01:00
Robin Müller
698ed3a700 Merge pull request 'dynpin bugfix' (#34) from bugfix-dynpin into main 
Reviewed-on: #34
 2025-02-12 13:41:34 +01:00
Robin Mueller
f3d840ace7 dynpin bugfix 2025-02-12 13:41:06 +01:00
Robin Müller
f781505ec5 Merge pull request 'Asynchronous GPIO support' (#30) from async-gpio into main 
Reviewed-on: #30
 2025-02-11 18:56:28 +01:00
Robin Mueller
c6e840a991 Asynchronous GPIO support 2025-02-11 18:56:11 +01:00
Robin Müller
454635a473 Merge pull request 'update error handling' (#31) from update-error-types into main 
Reviewed-on: #31
 2025-02-11 16:19:47 +01:00
Robin Mueller
67ddba9c42 update error handling 2025-02-11 16:19:20 +01:00
Robin Müller
6efc902e02 Merge pull request 'disable the unittests' (#32) from disable-empty-unittests into main 
Reviewed-on: #32
 2025-02-11 16:18:31 +01:00
Robin Mueller
b6e9a7f68e disable the unittests 2025-02-10 17:13:03 +01:00
Robin Müller
6842e06bc6 Merge pull request 'Update for va108xx' (#28) from update-deps-add-embassy-lib into main 
Reviewed-on: #28
 2025-02-10 11:42:03 +01:00
Robin Mueller
5b614e1280 Update for va108xx 
- New `va108xx-embassy` crate.
- Embassy library uses new crate
- Updated all dependencies

va108xx-hal

- Refactored and simplified PWM driver
- Added new raw getter API for TIM peripheral blocks
 2025-02-10 11:40:37 +01:00
Robin Müller
16e5a5f197 Merge pull request 'GPIO refactoring and API improvements' (#27) from gpio-refactoring into main 
Reviewed-on: #27
 2025-02-10 11:36:45 +01:00
Robin Mueller
da1f2902b2 GPIO refactoring and API improvements 2025-02-10 11:35:20 +01:00
Robin Müller
b2d17e10ed Merge pull request 'bootloader tweak' (#26) from bootloader-tweak into main 
Reviewed-on: #26
 2025-01-14 10:30:08 +01:00
Robin Mueller
1412e1b7d1 bootloader tweak 2025-01-14 01:21:20 +01:00
Robin Müller
88ee85a4cd Merge pull request 'new update for ringbuf' (#25) from update-for-ringbuf into main 
Reviewed-on: #25
 2025-01-11 11:39:59 +01:00
Robin Mueller
4b318ecc76 new update for ringbuf 2025-01-11 11:38:04 +01:00
Robin Müller
badeea8071 Merge pull request 'fix memory x file' (#24) from fix-memory-x-file into main 
Reviewed-on: #24
 2025-01-10 17:49:45 +01:00
Robin Müller
c95558ff55 Merge branch 'main' into fix-memory-x-file 2025-01-10 17:49:38 +01:00
Robin Müller
cd222fd1e1 Merge pull request 'some clippy fixes' (#23) from some-clippy-fixes into main 
Reviewed-on: #23
 2025-01-10 17:49:20 +01:00
Robin Mueller
f438e7e40f some clippy fixes 2025-01-10 17:19:28 +01:00
Robin Mueller
9e547668c2 fix memory x file 2025-01-10 16:38:17 +01:00
Robin Müller
cf55fe1504 Merge pull request 'bootloader and flashloader update' (#22) from bootloader-flashloader-update into main 
Reviewed-on: #22
 2025-01-10 16:31:39 +01:00
Robin Mueller
74eebdcc03 bootloader and flashloader update 2025-01-10 16:31:15 +01:00
Robin Müller
35527f092a Merge pull request 'update probe-rs files' (#21) from probe-rs-update into main 
Reviewed-on: #21
 2024-11-26 10:23:37 +01:00
Robin Mueller
c6314f48d7 update probe-rs files 2024-11-26 10:23:27 +01:00
Robin Müller
7189cb246b Merge pull request 'delete some more re-exports' (#20) from delete-some-re-exports into main
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Reviewed-on: #20
 2024-10-07 09:48:13 +02:00
Robin Mueller
39b8633065 delete some more re-exports
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2024-10-07 09:47:24 +02:00
Robin Müller
df0760da98 Merge pull request 'prepare BSP release' (#19) from prep-bsp-release into main
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Reviewed-on: #19
 2024-09-30 12:12:20 +02:00
Robin Mueller
8ed26db6a7 prepare BSP release
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2024-09-30 12:10:03 +02:00
Robin Müller
307174b938 Merge pull request 'prepare HAL release' (#18) from prep-hal-release into main
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Reviewed-on: #18
 2024-09-30 12:02:23 +02:00
Robin Mueller
46df7f1007 prepare HAL release
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2024-09-30 11:58:04 +02:00
Robin Müller
48dd00661f Merge pull request 'added correction for link' (#17) from link-correction into main
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Reviewed-on: #17
 2024-09-30 11:47:57 +02:00
Robin Mueller
e98ef8501e added correction for link
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2024-09-30 11:46:16 +02:00
Robin Müller
b753a465bf Merge pull request 'Flashloader and Bootloader' (#16) from flashloader into main
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Reviewed-on: #16
 2024-09-30 11:43:58 +02:00
Robin Mueller
d6f69d4a54 Finished flashloader and bootloader implementation
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2024-09-30 11:41:52 +02:00
Robin Müller
e2a55e7309 Merge pull request 'bmstall is configurable now as well' (#15) from va108xx-update-package into main
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Reviewed-on: #15
 2024-09-20 12:13:12 +02:00
Robin Mueller
e971e8dc0d bmstall is configurable now as well
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2024-09-20 11:42:41 +02:00
Robin Müller
501d1c973e Merge pull request 'update package' (#14) from va108xx-update-package into main
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Reviewed-on: #14
 2024-09-20 11:29:58 +02:00
Robin Mueller
acb8b67ae7 update package
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- Add embassy example
- improve timer API
- restructure examples
- restructure and improve SPI
- Add REB1 M95M01 NVM module
 2024-09-20 10:53:42 +02:00
Robin Mueller
405cc089c3 update flasher script file
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2024-07-11 11:52:56 +02:00
Robin Mueller
f48ee8231a another link correction
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2024-07-04 18:55:30 +02:00
Robin Mueller
4fb19fe234 link fix
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2024-07-04 18:54:37 +02:00
Robin Mueller
652af5cb3c README correction
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2024-07-04 18:41:33 +02:00
Robin Mueller
6e231e2553 prepare next vorago-reb1 release
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2024-07-04 18:40:26 +02:00
Robin Müller
79b7d7b4c2 Merge pull request 'Improve UART CLK calculation' (#12) from improve-uart-clk-calc into main
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Reviewed-on: #12
 2024-07-04 18:33:08 +02:00
Robin Mueller
3196d74a34 doc correction
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2024-07-04 18:32:30 +02:00
Robin Mueller
d7c27446e0 Merge remote-tracking branch 'origin/main' into improve-uart-clk-calc
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2024-07-04 18:27:17 +02:00
Robin Mueller
3d4e8477c1 improve UART clock calculation 2024-07-04 18:26:56 +02:00
Robin Müller
e2e3cc7020 Merge pull request 'Improve HAL' (#11) from improve-hal into main
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Reviewed-on: #11
 2024-07-04 18:16:11 +02:00
Robin Mueller
4f15cd7a31 another small link fix
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2024-07-04 18:15:55 +02:00
Robin Mueller
3c8c455c6f Update and improve HAL library and docs
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2024-07-04 18:07:34 +02:00
Robin Müller
abb78c2682 Merge pull request 'update doc build settings' (#10) from update-doc-settings into main
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Reviewed-on: #10
 2024-06-26 23:05:30 +02:00
Robin Mueller
51f21fee43 update doc build settings
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2024-06-26 22:58:12 +02:00
Robin Müller
6fb3b0544f Merge pull request 'readme fix' (#9) from readme-fix into main
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Reviewed-on: #9
 2024-06-25 20:18:48 +02:00
Robin Müller
e3996d9166 Merge branch 'main' into readme-fix 2024-06-25 20:18:39 +02:00
Robin Mueller
deee5f6f46 readme fix
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Robin Müller
5d6c7ebf5e Merge pull request 'doc fixes and improvements' (#8) from update-docs into main
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Reviewed-on: #8
 2024-06-25 11:02:54 +02:00
Robin Müller
6b3cdf74cc Merge branch 'main' into update-docs
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Robin Mueller
f4f378ba4f doc fixes and improvements
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Robin Müller
4224b14545 Merge pull request 'update docs' (#7) from update-docs into main
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 2024-06-25 10:26:10 +02:00
Robin Müller
e3cdb19a35 Merge branch 'main' into update-docs 2024-06-25 10:26:02 +02:00
Robin Mueller
95e72cfea6 update docs
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6854703c5d link corrections
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236 changed files with 10126 additions and 4572 deletions
Expand all files Collapse all files

3
.cargo/def-config.toml
View File

@ -24,8 +24,7 @@ rustflags = [
# "-C", "link-arg=-Tdefmt.x",
# Can be useful for debugging.
"-Clink-args=-Map=app.map"
# "-Clink-args=-Map=app.map"
]
[build]

10
.github/workflows/ci.yml vendored
View File

@ -10,8 +10,8 @@ jobs:
- uses: dtolnay/rust-toolchain@stable
with:
targets: "thumbv6m-none-eabi"
- run: cargo check --target thumbv6m-none-eabi --release
- run: cargo check --target thumbv6m-none-eabi --examples --release
- run: cargo check --target thumbv6m-none-eabi
- run: cargo check --target thumbv6m-none-eabi --examples
test:
name: Run Tests
@ -21,7 +21,7 @@ jobs:
- uses: dtolnay/rust-toolchain@stable
- name: Install nextest
uses: taiki-e/install-action@nextest
- run: cargo nextest run --all-features -p va108xx-hal
- run: cargo nextest run --all-features -p va108xx-hal --no-tests=pass
# I think we can skip those on an embedded crate..
# - run: cargo test --doc -p va108xx-hal
@ -39,7 +39,9 @@ jobs:
steps:
- uses: actions/checkout@v4
- uses: dtolnay/rust-toolchain@nightly
- run: cargo +nightly doc --all-features --config 'build.rustdocflags=["--cfg", "docs_rs"]'
- run: RUSTDOCFLAGS="--cfg docsrs --generate-link-to-definition -Z unstable-options" cargo +nightly doc -p va108xx
- run: RUSTDOCFLAGS="--cfg docsrs --generate-link-to-definition -Z unstable-options" cargo +nightly doc -p va108xx-hal
- run: RUSTDOCFLAGS="--cfg docsrs --generate-link-to-definition -Z unstable-options" cargo +nightly doc -p vorago-reb1
clippy:
name: Clippy

2
.gitignore vendored
View File

@ -16,3 +16,5 @@ Cargo.lock
# JetBrains IDEs
/.idea
*.iml
/Embed.toml

26
Cargo.toml
View File

@ -1,15 +1,21 @@
[workspace]
resolver = "2"
members = [
"vorago-reb1",
"va108xx",
"va108xx-hal",
"vorago-reb1",
"va108xx",
"va108xx-hal",
"va108xx-embassy",
"examples/simple",
"examples/rtic",
"examples/embassy",
"board-tests",
"bootloader",
"flashloader",
]
exclude = [
"defmt-testapp",
"flashloader/slot-a-blinky",
"flashloader/slot-b-blinky",
]
[profile.dev]
@ -17,7 +23,8 @@ codegen-units = 1
debug = 2
debug-assertions = true # <-
incremental = false
opt-level = 'z' # <-
# 1 instead of 0, the flashloader is too larger otherwise..
# opt-level = 1 # <-
overflow-checks = true # <-
# cargo build/run --release
@ -29,3 +36,12 @@ incremental = false
lto = 'fat'
opt-level = 3 # <-
overflow-checks = false # <-
[profile.small]
inherits = "release"
codegen-units = 1
debug-assertions = false # <-
lto = true
opt-level = 'z' # <-
overflow-checks = false # <-
strip = true # Automatically strip symbols from the binary.

12
Embed.toml.sample Normal file
View File

@ -0,0 +1,12 @@
[default.probe]
protocol = "Jtag"
[default.general]
chip = "VA108xx_RAM"
[default.rtt]
enabled = true
[default.gdb]
# Whether or not a GDB server should be opened after flashing.
enabled = false

21
README.md
View File

@ -19,9 +19,18 @@ This workspace contains the following released crates:
It also contains the following helper crates:
- The `board-tests` contains an application which can be used to test the libraries on the
board.
- The `examples` crates contains various example applications for the HAL and the PAC.
- The [`bootloader`](https://egit.irs.uni-stuttgart.de/rust/va108xx-rs/src/branch/main/bootloader)
crate contains a sample bootloader strongly based on the one provided by Vorago.
- The [`flashloader`](https://egit.irs.uni-stuttgart.de/rust/va108xx-rs/src/branch/main/flashloader)
crate contains a sample flashloader which is able to update the redundant images in the NVM which
is compatible to the provided bootloader as well.
- The [`board-tests`](https://egit.irs.uni-stuttgart.de/rust/va108xx-rs/src/branch/main/board-tests)
contains an application which can be used to test the libraries on the board.
- The [`examples`](https://egit.irs.uni-stuttgart.de/rust/va108xx-rs/src/branch/main/examples)
folder contains various example applications crates using the HAL and the PAC.
This folder also contains dedicated example applications using the
[`RTIC`](https://rtic.rs/2/book/en/) and [`embassy`](https://github.com/embassy-rs/embassy)
native Rust RTOSes.
## Using the `.cargo/config.toml` file
@ -94,6 +103,8 @@ example.
Assuming a working debug connection to your VA108xx board, you can debug using VS Code with
the [`Cortex-Debug` plugin](https://marketplace.visualstudio.com/items?itemName=marus25.cortex-debug).
Please make sure that [`objdump-multiarch` and `nm-multiarch`](https://forums.raspberrypi.com/viewtopic.php?t=333146)
are installed as well.
Some sample configuration files for VS code were provided and can be used by running
`cp -rT vscode .vscode` like specified above. After that, you can use `Run and Debug`
@ -106,3 +117,7 @@ configuration variables in your `settings.json`:
- `"cortex-debug.gdbPath.linux"`
- `"cortex-debug.gdbPath.windows"`
- `"cortex-debug.gdbPath.osx"`
The provided VS Code configurations also provide an integrated RTT logger, which you can access
via the terminal at `RTT Ch:0 console`. In order for the RTT block address detection to
work properly, `objdump-multiarch` and `nm-multiarch` need to be installed.

4
automation/Jenkinsfile vendored
View File

@ -25,7 +25,9 @@ pipeline {
stage('Docs') {
steps {
sh """
cargo +nightly doc --all-features --config 'build.rustdocflags=["--cfg", "docs_rs"]'
RUSTDOCFLAGS="--cfg docsrs --generate-link-to-definition -Z unstable-options" cargo +nightly doc -p va108xx
RUSTDOCFLAGS="--cfg docsrs --generate-link-to-definition -Z unstable-options" cargo +nightly doc -p va108xx-hal
RUSTDOCFLAGS="--cfg docsrs --generate-link-to-definition -Z unstable-options" cargo +nightly doc -p vorago-reb1
"""
}
}

8
board-tests/Cargo.toml
View File

@ -4,18 +4,16 @@ version = "0.1.0"
edition = "2021"
[dependencies]
cortex-m-rtic = "1"
panic-halt = "0.2"
cortex-m = { version = "0.7.6", features = ["critical-section-single-core"] }
cortex-m-rt = "0.7"
rtt-target = "0.5"
panic-rtt-target = "0.1.3"
panic-halt = "1"
rtt-target = "0.6"
panic-rtt-target = "0.2"
embedded-hal = "1"
embedded-hal-nb = "1"
embedded-io = "0.6"
[dependencies.va108xx-hal]
version = "0.6"
path = "../va108xx-hal"
features = ["rt"]

24
board-tests/src/main.rs
View File

@ -17,7 +17,7 @@ use va108xx_hal::{
pac::{self, interrupt},
prelude::*,
time::Hertz,
timer::{default_ms_irq_handler, set_up_ms_tick, CountDownTimer, IrqCfg},
timer::{default_ms_irq_handler, set_up_ms_tick, CountdownTimer, InterruptConfig},
};
#[allow(dead_code)]
@ -44,8 +44,8 @@ fn main() -> ! {
rprintln!("-- VA108xx Test Application --");
let mut dp = pac::Peripherals::take().unwrap();
let cp = cortex_m::Peripherals::take().unwrap();
let pinsa = PinsA::new(&mut dp.sysconfig, None, dp.porta);
let pinsb = PinsB::new(&mut dp.sysconfig, Some(dp.ioconfig), dp.portb);
let pinsa = PinsA::new(&mut dp.sysconfig, dp.porta);
let pinsb = PinsB::new(&mut dp.sysconfig, dp.portb);
let mut led1 = pinsa.pa10.into_readable_push_pull_output();
let test_case = TestCase::DelayMs;
@ -99,9 +99,11 @@ fn main() -> ! {
}
TestCase::TestMask => {
// Tie PORTA[0] to PORTA[1] for these tests!
let input = pinsa.pa1.into_pull_down_input().clear_datamask();
let mut input = pinsa.pa1.into_pull_down_input();
input.clear_datamask();
assert!(!input.datamask());
let mut out = pinsa.pa0.into_push_pull_output().clear_datamask();
let mut out = pinsa.pa0.into_push_pull_output();
out.clear_datamask();
assert!(input.is_low_masked().is_err());
assert!(out.set_high_masked().is_err());
}
@ -119,17 +121,15 @@ fn main() -> ! {
assert_eq!(PinsB::get_perid(), 0x004007e1);
}
TestCase::Pulse => {
let mut output_pulsed = pinsa
.pa0
.into_push_pull_output()
.pulse_mode(true, PinState::Low);
let mut output_pulsed = pinsa.pa0.into_push_pull_output();
output_pulsed.pulse_mode(true, PinState::Low);
rprintln!("Pulsing high 10 times..");
output_pulsed.set_low().unwrap();
for _ in 0..10 {
output_pulsed.set_high().unwrap();
cortex_m::asm::delay(25_000_000);
}
let mut output_pulsed = output_pulsed.pulse_mode(true, PinState::High);
output_pulsed.pulse_mode(true, PinState::High);
rprintln!("Pulsing low 10 times..");
for _ in 0..10 {
output_pulsed.set_low().unwrap();
@ -155,7 +155,7 @@ fn main() -> ! {
}
TestCase::DelayMs => {
let mut ms_timer = set_up_ms_tick(
IrqCfg::new(pac::Interrupt::OC0, true, true),
InterruptConfig::new(pac::Interrupt::OC0, true, true),
&mut dp.sysconfig,
Some(&mut dp.irqsel),
50.MHz(),
@ -168,7 +168,7 @@ fn main() -> ! {
ms_timer.delay_ms(500);
}
let mut delay_timer = CountDownTimer::new(&mut dp.sysconfig, 50.MHz(), dp.tim1);
let mut delay_timer = CountdownTimer::new(&mut dp.sysconfig, 50.MHz(), dp.tim1);
let mut pa0 = pinsa.pa0.into_readable_push_pull_output();
for _ in 0..5 {
led1.toggle().ok();

25
bootloader/Cargo.toml Normal file
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@ -0,0 +1,25 @@
[package]
name = "bootloader"
version = "0.1.0"
edition = "2021"
[dependencies]
cortex-m = "0.7"
cortex-m-rt = "0.7"
embedded-hal = "1"
panic-rtt-target = "0.2"
panic-halt = "1"
rtt-target = "0.6"
crc = "3"
num_enum = { version = "0.7", default-features = false }
static_assertions = "1"
[dependencies.va108xx-hal]
path = "../va108xx-hal"
[dependencies.vorago-reb1]
path = "../vorago-reb1"
[features]
default = []
rtt-panic = []

51
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@ -0,0 +1,51 @@
VA108xx Bootloader Application
=======
This is the Rust version of the bootloader supplied by Vorago.
## Memory Map
The bootloader uses the following memory map:
| Address | Notes | Size |
| ------ | ---- | ---- |
| 0x0 | Bootloader start | code up to 0x2FFE bytes |
| 0x2FFE | Bootloader CRC | half-word |
| 0x3000 | App image A start | code up to 0xE7F4 (~59K) bytes |
| 0x117F8 | App image A CRC check length | word |
| 0x117FC | App image A CRC check value | word |
| 0x117FC | App image B start | code up to 0xE7F4 (~59K) bytes |
| 0x1FFF0 | App image B CRC check length | word |
| 0x1FFF4 | App image B CRC check value | word |
| 0x1FFF8 | Reserved section, contains boot select parameter | 8 bytes |
| 0x20000 | End of NVM | end |
## Additional Information
This bootloader was specifically written for the REB1 board, so it assumes a M95M01 ST EEPROM
is used to load the application code. The bootloader will also delay for a configurable amount
of time before booting. This allows to catch the RTT printout, but should probably be disabled
for production firmware.
This bootloader does not provide tools to flash the NVM memory by itself. Instead, you can use
the [flashloader](https://egit.irs.uni-stuttgart.de/rust/va108xx-rs/src/branch/main/flashloader)
application to perform this task using a CCSDS interface via a UART.
The bootloader performs the following steps:
1. The application will calculate the checksum of itself if the bootloader CRC is blank (all zeroes
or all ones). If the CRC is not blank and the checksum check fails, it will immediately boot
application image A. Otherwise, it proceeds to the next step.
2. Read the boot slot from a reserved section at the end of the EEPROM. If no valid value is read,
select boot slot A.
3. Check the checksum of the boot slot. If that checksum is valid, it will boot that slot. If not,
it will proceed to the next step.
4. Check the checksum of the other slot . If that checksum is valid, it will boot that slot. If
not, it will boot App A as the fallback image.
In your actual production application, a command to update the preferred boot slot could be exposed
to allow performing software updates in a safe way.
Please note that you *MUST* compile the application at slot A and slot B with an appropriate
`memory.x` file where the base address of the `FLASH` was adapted according to the base address
shown in the memory map above. The memory files to do this were provided in the `scripts` folder.

10
bootloader/src/lib.rs Normal file
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@ -0,0 +1,10 @@
#![no_std]
use core::convert::Infallible;
/// Simple trait which makes swapping the NVM easier. NVMs only need to implement this interface.
pub trait NvmInterface {
fn write(&mut self, address: usize, data: &[u8]) -> Result<(), Infallible>;
fn read(&mut self, address: usize, buf: &mut [u8]) -> Result<(), Infallible>;
fn verify(&mut self, address: usize, data: &[u8]) -> Result<bool, Infallible>;
}

340
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@ -0,0 +1,340 @@
//! Vorago bootloader which can boot from two images.
#![no_main]
#![no_std]
use bootloader::NvmInterface;
use cortex_m_rt::entry;
use crc::{Crc, CRC_16_IBM_3740};
use embedded_hal::delay::DelayNs;
use num_enum::TryFromPrimitive;
#[cfg(not(feature = "rtt-panic"))]
use panic_halt as _;
#[cfg(feature = "rtt-panic")]
use panic_rtt_target as _;
use rtt_target::{rprintln, rtt_init_print};
use va108xx_hal::{pac, time::Hertz, timer::CountdownTimer};
use vorago_reb1::m95m01::M95M01;
// Useful for debugging and see what the bootloader is doing. Enabled currently, because
// the binary stays small enough.
const RTT_PRINTOUT: bool = true;
const DEBUG_PRINTOUTS: bool = true;
// Small delay, allows RTT printout to catch up.
const BOOT_DELAY_MS: u32 = 2000;
// Dangerous option! An image with this option set to true will flash itself from RAM directly
// into the NVM. This can be used as a recovery option from a direct RAM flash to fix the NVM
// boot process. Please note that this will flash an image which will also always perform the
// self-flash itself. It is recommended that you use a tool like probe-rs, Keil IDE, or a flash
// loader to boot a bootloader without this feature.
const FLASH_SELF: bool = false;
// Register definitions for Cortex-M0 SCB register.
pub const SCB_AIRCR_VECTKEY_POS: u32 = 16;
pub const SCB_AIRCR_VECTKEY_MSK: u32 = 0xFFFF << SCB_AIRCR_VECTKEY_POS;
pub const SCB_AIRCR_SYSRESETREQ_POS: u32 = 2;
pub const SCB_AIRCR_SYSRESETREQ_MSK: u32 = 1 << SCB_AIRCR_SYSRESETREQ_POS;
const CLOCK_FREQ: Hertz = Hertz::from_raw(50_000_000);
// Important bootloader addresses and offsets, vector table information.
const NVM_SIZE: u32 = 0x20000;
const BOOTLOADER_START_ADDR: u32 = 0x0;
const BOOTLOADER_CRC_ADDR: u32 = BOOTLOADER_END_ADDR - 2;
// This is also the maximum size of the bootloader.
const BOOTLOADER_END_ADDR: u32 = 0x3000;
const APP_A_START_ADDR: u32 = BOOTLOADER_END_ADDR;
// 0x117F8
const APP_A_SIZE_ADDR: u32 = APP_A_END_ADDR - 8;
// Four bytes reserved, even when only 2 byte CRC is used. Leaves flexibility to switch to CRC32.
// 0x117FC
const APP_A_CRC_ADDR: u32 = APP_A_END_ADDR - 4;
// 0x11800
pub const APP_A_END_ADDR: u32 = APP_A_START_ADDR + APP_IMG_SZ;
// The actual size of the image which is relevant for CRC calculation.
const APP_B_START_ADDR: u32 = APP_A_END_ADDR;
// The actual size of the image which is relevant for CRC calculation.
// 0x1FFF8
const APP_B_SIZE_ADDR: u32 = APP_B_END_ADDR - 8;
// Four bytes reserved, even when only 2 byte CRC is used. Leaves flexibility to switch to CRC32.
// 0x1FFFC
const APP_B_CRC_ADDR: u32 = APP_B_END_ADDR - 4;
// 0x20000. 8 bytes at end of EEPROM reserved for preferred image parameter. This reserved
// size should be a multiple of 8 due to alignment requirements.
pub const APP_B_END_ADDR: u32 = NVM_SIZE - 8;
pub const APP_IMG_SZ: u32 = (APP_B_END_ADDR - APP_A_START_ADDR) / 2;
static_assertions::const_assert!((APP_B_END_ADDR - BOOTLOADER_END_ADDR) % 2 == 0);
pub const VECTOR_TABLE_OFFSET: u32 = 0x0;
pub const VECTOR_TABLE_LEN: u32 = 0xC0;
pub const RESET_VECTOR_OFFSET: u32 = 0x4;
pub const PREFERRED_SLOT_OFFSET: u32 = 0x20000 - 1;
const CRC_ALGO: Crc<u16> = Crc::<u16>::new(&CRC_16_IBM_3740);
#[derive(Debug, Copy, Clone, PartialEq, Eq, TryFromPrimitive)]
#[repr(u8)]
enum AppSel {
A = 0,
B = 1,
}
pub struct NvmWrapper(pub M95M01);
// Newtype pattern. We could now more easily swap the used NVM type.
impl NvmInterface for NvmWrapper {
fn write(&mut self, address: usize, data: &[u8]) -> Result<(), core::convert::Infallible> {
self.0.write(address, data)
}
fn read(&mut self, address: usize, buf: &mut [u8]) -> Result<(), core::convert::Infallible> {
self.0.read(address, buf)
}
fn verify(&mut self, address: usize, data: &[u8]) -> Result<bool, core::convert::Infallible> {
self.0.verify(address, data)
}
}
#[entry]
fn main() -> ! {
if RTT_PRINTOUT {
rtt_init_print!();
rprintln!("-- VA108xx bootloader --");
}
let mut dp = pac::Peripherals::take().unwrap();
let cp = cortex_m::Peripherals::take().unwrap();
let mut timer = CountdownTimer::new(&mut dp.sysconfig, CLOCK_FREQ, dp.tim0);
let mut nvm = M95M01::new(&mut dp.sysconfig, CLOCK_FREQ, dp.spic);
if FLASH_SELF {
let mut first_four_bytes: [u8; 4] = [0; 4];
read_four_bytes_at_addr_zero(&mut first_four_bytes);
let bootloader_data = {
unsafe {
&*core::ptr::slice_from_raw_parts(
(BOOTLOADER_START_ADDR + 4) as *const u8,
(BOOTLOADER_END_ADDR - BOOTLOADER_START_ADDR - 6) as usize,
)
}
};
let mut digest = CRC_ALGO.digest();
digest.update(&first_four_bytes);
digest.update(bootloader_data);
let bootloader_crc = digest.finalize();
nvm.write(0x0, &first_four_bytes)
.expect("writing to NVM failed");
nvm.write(0x4, bootloader_data)
.expect("writing to NVM failed");
if let Err(e) = nvm.verify(0x0, &first_four_bytes) {
if RTT_PRINTOUT {
rprintln!("verification of self-flash to NVM failed: {:?}", e);
}
}
if let Err(e) = nvm.verify(0x4, bootloader_data) {
if RTT_PRINTOUT {
rprintln!("verification of self-flash to NVM failed: {:?}", e);
}
}
nvm.write(BOOTLOADER_CRC_ADDR as usize, &bootloader_crc.to_be_bytes())
.expect("writing CRC failed");
if let Err(e) = nvm.verify(BOOTLOADER_CRC_ADDR as usize, &bootloader_crc.to_be_bytes()) {
if RTT_PRINTOUT {
rprintln!(
"error: CRC verification for bootloader self-flash failed: {:?}",
e
);
}
}
}
let mut nvm = NvmWrapper(nvm);
// Check bootloader's CRC (and write it if blank)
check_own_crc(&dp.sysconfig, &cp, &mut nvm, &mut timer);
let mut preferred_app_raw = [0; 1];
nvm.read(PREFERRED_SLOT_OFFSET as usize, &mut preferred_app_raw)
.expect("reading preferred slot failed");
let preferred_app = AppSel::try_from(preferred_app_raw[0]).unwrap_or(AppSel::A);
let other_app = if preferred_app == AppSel::A {
AppSel::B
} else {
AppSel::A
};
if check_app_crc(preferred_app) {
boot_app(&dp.sysconfig, &cp, preferred_app, &mut timer)
} else if check_app_crc(other_app) {
boot_app(&dp.sysconfig, &cp, other_app, &mut timer)
} else {
if DEBUG_PRINTOUTS && RTT_PRINTOUT {
rprintln!("both images corrupt! booting image A");
}
// TODO: Shift a CCSDS packet out to inform host/OBC about image corruption.
// Both images seem to be corrupt. Boot default image A.
boot_app(&dp.sysconfig, &cp, AppSel::A, &mut timer)
}
}
fn check_own_crc(
sysconfig: &pac::Sysconfig,
cp: &cortex_m::Peripherals,
nvm: &mut NvmWrapper,
timer: &mut CountdownTimer<pac::Tim0>,
) {
let crc_exp = unsafe { (BOOTLOADER_CRC_ADDR as *const u16).read_unaligned().to_be() };
// I'd prefer to use [core::slice::from_raw_parts], but that is problematic
// because the address of the bootloader is 0x0, so the NULL check fails and the functions
// panics.
let mut first_four_bytes: [u8; 4] = [0; 4];
read_four_bytes_at_addr_zero(&mut first_four_bytes);
let mut digest = CRC_ALGO.digest();
digest.update(&first_four_bytes);
digest.update(unsafe {
&*core::ptr::slice_from_raw_parts(
(BOOTLOADER_START_ADDR + 4) as *const u8,
(BOOTLOADER_END_ADDR - BOOTLOADER_START_ADDR - 6) as usize,
)
});
let crc_calc = digest.finalize();
if crc_exp == 0x0000 || crc_exp == 0xffff {
if DEBUG_PRINTOUTS && RTT_PRINTOUT {
rprintln!("BL CRC blank - prog new CRC");
}
// Blank CRC, write it to NVM.
nvm.write(BOOTLOADER_CRC_ADDR as usize, &crc_calc.to_be_bytes())
.expect("writing CRC failed");
// The Vorago bootloader resets here. I am not sure why this is done but I think it is
// necessary because somehow the boot will not work if we just continue as usual.
// cortex_m::peripheral::SCB::sys_reset();
} else if crc_exp != crc_calc {
// Bootloader is corrupted. Try to run App A.
if DEBUG_PRINTOUTS && RTT_PRINTOUT {
rprintln!(
"bootloader CRC corrupt, read {} and expected {}. booting image A immediately",
crc_calc,
crc_exp
);
}
// TODO: Shift out minimal CCSDS frame to notify about bootloader corruption.
boot_app(sysconfig, cp, AppSel::A, timer);
}
}
// Reading from address 0x0 is problematic in Rust.
// See https://users.rust-lang.org/t/reading-from-physical-address-0x0/117408/5.
// This solution falls back to assembler to deal with this.
fn read_four_bytes_at_addr_zero(buf: &mut [u8; 4]) {
unsafe {
core::arch::asm!(
"ldr r0, [{0}]", // Load 4 bytes from src into r0 register
"str r0, [{1}]", // Store r0 register into first_four_bytes
in(reg) BOOTLOADER_START_ADDR as *const u8, // Input: src pointer (0x0)
in(reg) buf as *mut [u8; 4], // Input: destination pointer
);
}
}
fn check_app_crc(app_sel: AppSel) -> bool {
if DEBUG_PRINTOUTS && RTT_PRINTOUT {
rprintln!("Checking image {:?}", app_sel);
}
if app_sel == AppSel::A {
check_app_given_addr(APP_A_CRC_ADDR, APP_A_START_ADDR, APP_A_SIZE_ADDR)
} else {
check_app_given_addr(APP_B_CRC_ADDR, APP_B_START_ADDR, APP_B_SIZE_ADDR)
}
}
fn check_app_given_addr(crc_addr: u32, start_addr: u32, image_size_addr: u32) -> bool {
let crc_exp = unsafe { (crc_addr as *const u16).read_unaligned().to_be() };
let image_size = unsafe { (image_size_addr as *const u32).read_unaligned().to_be() };
// Sanity check.
if image_size > APP_A_END_ADDR - APP_A_START_ADDR - 8 {
if RTT_PRINTOUT {
rprintln!("detected invalid app size {}", image_size);
}
return false;
}
let crc_calc = CRC_ALGO.checksum(unsafe {
core::slice::from_raw_parts(start_addr as *const u8, image_size as usize)
});
if crc_calc == crc_exp {
return true;
}
false
}
// The boot works by copying the interrupt vector table (IVT) of the respective app to the
// base address in code RAM (0x0) and then performing a soft reset.
fn boot_app(
syscfg: &pac::Sysconfig,
cp: &cortex_m::Peripherals,
app_sel: AppSel,
timer: &mut CountdownTimer<pac::Tim0>,
) -> ! {
if DEBUG_PRINTOUTS && RTT_PRINTOUT {
rprintln!("booting app {:?}", app_sel);
}
timer.delay_ms(BOOT_DELAY_MS);
// Clear all interrupts set.
unsafe {
cp.NVIC.icer[0].write(0xFFFFFFFF);
cp.NVIC.icpr[0].write(0xFFFFFFFF);
}
// Disable ROM protection.
syscfg.rom_prot().write(|w| w.wren().set_bit());
let base_addr = if app_sel == AppSel::A {
APP_A_START_ADDR
} else {
APP_B_START_ADDR
};
unsafe {
// First 4 bytes done with inline assembly, writing to the physical address 0x0 can not
// be done without it. See https://users.rust-lang.org/t/reading-from-physical-address-0x0/117408/2.
let first_four_bytes = core::ptr::read(base_addr as *const u32);
core::arch::asm!(
"str {0}, [{1}]",
in(reg) first_four_bytes, // Input: App vector table.
in(reg) BOOTLOADER_START_ADDR as *mut u32, // Input: destination pointer
);
core::slice::from_raw_parts_mut(
(BOOTLOADER_START_ADDR + 4) as *mut u8,
(VECTOR_TABLE_LEN - 4) as usize,
)
.copy_from_slice(core::slice::from_raw_parts(
(base_addr + 4) as *const u8,
(VECTOR_TABLE_LEN - 4) as usize,
));
}
// Disable re-loading from FRAM/code ROM on soft reset
syscfg
.rst_cntl_rom()
.modify(|_, w| w.sysrstreq().clear_bit());
soft_reset(cp);
}
// Soft reset based on https://github.com/ARM-software/CMSIS_6/blob/5782d6f8057906d360f4b95ec08a2354afe5c9b9/CMSIS/Core/Include/core_cm0.h#L874.
fn soft_reset(cp: &cortex_m::Peripherals) -> ! {
// Ensure all outstanding memory accesses included buffered write are completed before reset.
cortex_m::asm::dsb();
unsafe {
cp.SCB
.aircr
.write((0x5FA << SCB_AIRCR_VECTKEY_POS) | SCB_AIRCR_SYSRESETREQ_MSK);
}
// Ensure completion of memory access.
cortex_m::asm::dsb();
// Loop until the reset occurs.
loop {
cortex_m::asm::nop();
}
}

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@ -0,0 +1,33 @@
VA108xx Example Applications
========
This folder contains various examples
Consult the main README first for setup of the repository.
## Simple examples
```rs
cargo run --example blinky
```
You can have a look at the `simple/examples` folder to see all available simple examples
## RTIC example
```rs
cargo run --bin rtic-example
```
## Embassy example
Blinky with time driver IRQs in library
```rs
cargo run --bin embassy-example
```
Blinky with custom time driver IRQs
```rs
cargo run --bin embassy-example --no-default-features --features custom-irqs
```

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@ -0,0 +1,37 @@
[package]
name = "embassy-example"
version = "0.1.0"
edition = "2021"
[dependencies]
cfg-if = "1"
cortex-m = { version = "0.7", features = ["critical-section-single-core"] }
cortex-m-rt = "0.7"
embedded-hal = "1"
embedded-hal-async = "1"
embedded-io = "0.6"
embedded-io-async = "0.6"
heapless = "0.8"
static_cell = "2"
rtt-target = "0.6"
panic-rtt-target = "0.2"
critical-section = "1"
portable-atomic = { version = "1", features = ["unsafe-assume-single-core"]}
embassy-sync = "0.6"
embassy-time = "0.4"
embassy-executor = { version = "0.7", features = [
"arch-cortex-m",
"executor-thread",
"executor-interrupt"
]}
va108xx-hal = { path = "../../va108xx-hal" }
va108xx-embassy = { path = "../../va108xx-embassy", default-features = false }
[features]
default = ["ticks-hz-1_000", "va108xx-embassy/irq-oc30-oc31"]
custom-irqs = []
ticks-hz-1_000 = ["embassy-time/tick-hz-1_000"]
ticks-hz-32_768 = ["embassy-time/tick-hz-32_768"]

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//! This example demonstrates the usage of async GPIO operations on VA108xx.
//!
//! You need to tie the PA0 to the PA1 pin for this example to work. You can optionally tie the PB22 to PB23 pins well
//! and then set the `CHECK_PB22_TO_PB23` to true to also test async operations on Port B.
#![no_std]
#![no_main]
use embassy_executor::Spawner;
use embassy_sync::channel::{Receiver, Sender};
use embassy_sync::{blocking_mutex::raw::ThreadModeRawMutex, channel::Channel};
use embassy_time::{Duration, Instant, Timer};
use embedded_hal::digital::{InputPin, OutputPin, StatefulOutputPin};
use embedded_hal_async::digital::Wait;
use panic_rtt_target as _;
use rtt_target::{rprintln, rtt_init_print};
use va108xx_embassy::embassy;
use va108xx_hal::gpio::{on_interrupt_for_asynch_gpio, InputDynPinAsync, InputPinAsync, PinsB};
use va108xx_hal::{
gpio::{DynPin, PinsA},
pac::{self, interrupt},
prelude::*,
};
const SYSCLK_FREQ: Hertz = Hertz::from_raw(50_000_000);
const CHECK_PA0_TO_PA1: bool = true;
const CHECK_PB22_TO_PB23: bool = false;
// Can also be set to OC10 and works as well.
const PB22_TO_PB23_IRQ: pac::Interrupt = pac::Interrupt::OC11;
#[derive(Clone, Copy)]
pub struct GpioCmd {
cmd_type: GpioCmdType,
after_delay: u32,
}
impl GpioCmd {
pub fn new(cmd_type: GpioCmdType, after_delay: u32) -> Self {
Self {
cmd_type,
after_delay,
}
}
}
#[derive(Clone, Copy)]
pub enum GpioCmdType {
SetHigh,
SetLow,
RisingEdge,
FallingEdge,
}
// Declare a bounded channel of 3 u32s.
static CHANNEL_PA0_PA1: Channel<ThreadModeRawMutex, GpioCmd, 3> = Channel::new();
static CHANNEL_PB22_TO_PB23: Channel<ThreadModeRawMutex, GpioCmd, 3> = Channel::new();
#[embassy_executor::main]
async fn main(spawner: Spawner) {
rtt_init_print!();
rprintln!("-- VA108xx Async GPIO Demo --");
let mut dp = pac::Peripherals::take().unwrap();
// Safety: Only called once here.
unsafe {
embassy::init(
&mut dp.sysconfig,
&dp.irqsel,
SYSCLK_FREQ,
dp.tim23,
dp.tim22,
)
};
let porta = PinsA::new(&mut dp.sysconfig, dp.porta);
let portb = PinsB::new(&mut dp.sysconfig, dp.portb);
let mut led0 = porta.pa10.into_readable_push_pull_output();
let out_pa0 = porta.pa0.into_readable_push_pull_output();
let in_pa1 = porta.pa1.into_floating_input();
let out_pb22 = portb.pb22.into_readable_push_pull_output();
let in_pb23 = portb.pb23.into_floating_input();
let in_pa1_async = InputPinAsync::new(in_pa1, pac::Interrupt::OC10);
let out_pa0_dyn = out_pa0.downgrade();
let in_pb23_async = InputDynPinAsync::new(in_pb23.downgrade(), PB22_TO_PB23_IRQ).unwrap();
let out_pb22_dyn = out_pb22.downgrade();
spawner
.spawn(output_task(
"PA0 to PA1",
out_pa0_dyn,
CHANNEL_PA0_PA1.receiver(),
))
.unwrap();
spawner
.spawn(output_task(
"PB22 to PB23",
out_pb22_dyn,
CHANNEL_PB22_TO_PB23.receiver(),
))
.unwrap();
if CHECK_PA0_TO_PA1 {
check_pin_to_pin_async_ops("PA0 to PA1", CHANNEL_PA0_PA1.sender(), in_pa1_async).await;
rprintln!("Example PA0 to PA1 done");
}
if CHECK_PB22_TO_PB23 {
check_pin_to_pin_async_ops("PB22 to PB23", CHANNEL_PB22_TO_PB23.sender(), in_pb23_async)
.await;
rprintln!("Example PB22 to PB23 done");
}
rprintln!("Example done, toggling LED0");
loop {
led0.toggle().unwrap();
Timer::after(Duration::from_millis(500)).await;
}
}
async fn check_pin_to_pin_async_ops(
ctx: &'static str,
sender: Sender<'static, ThreadModeRawMutex, GpioCmd, 3>,
mut async_input: impl Wait,
) {
rprintln!(
"{}: sending SetHigh command ({} ms)",
ctx,
Instant::now().as_millis()
);
sender.send(GpioCmd::new(GpioCmdType::SetHigh, 20)).await;
async_input.wait_for_high().await.unwrap();
rprintln!(
"{}: Input pin is high now ({} ms)",
ctx,
Instant::now().as_millis()
);
rprintln!(
"{}: sending SetLow command ({} ms)",
ctx,
Instant::now().as_millis()
);
sender.send(GpioCmd::new(GpioCmdType::SetLow, 20)).await;
async_input.wait_for_low().await.unwrap();
rprintln!(
"{}: Input pin is low now ({} ms)",
ctx,
Instant::now().as_millis()
);
rprintln!(
"{}: sending RisingEdge command ({} ms)",
ctx,
Instant::now().as_millis()
);
sender.send(GpioCmd::new(GpioCmdType::RisingEdge, 20)).await;
async_input.wait_for_rising_edge().await.unwrap();
rprintln!(
"{}: input pin had rising edge ({} ms)",
ctx,
Instant::now().as_millis()
);
rprintln!(
"{}: sending Falling command ({} ms)",
ctx,
Instant::now().as_millis()
);
sender
.send(GpioCmd::new(GpioCmdType::FallingEdge, 20))
.await;
async_input.wait_for_falling_edge().await.unwrap();
rprintln!(
"{}: input pin had a falling edge ({} ms)",
ctx,
Instant::now().as_millis()
);
rprintln!(
"{}: sending Falling command ({} ms)",
ctx,
Instant::now().as_millis()
);
sender
.send(GpioCmd::new(GpioCmdType::FallingEdge, 20))
.await;
async_input.wait_for_any_edge().await.unwrap();
rprintln!(
"{}: input pin had a falling (any) edge ({} ms)",
ctx,
Instant::now().as_millis()
);
rprintln!(
"{}: sending Falling command ({} ms)",
ctx,
Instant::now().as_millis()
);
sender.send(GpioCmd::new(GpioCmdType::RisingEdge, 20)).await;
async_input.wait_for_any_edge().await.unwrap();
rprintln!(
"{}: input pin had a rising (any) edge ({} ms)",
ctx,
Instant::now().as_millis()
);
}
#[embassy_executor::task(pool_size = 2)]
async fn output_task(
ctx: &'static str,
mut out: DynPin,
receiver: Receiver<'static, ThreadModeRawMutex, GpioCmd, 3>,
) {
loop {
let next_cmd = receiver.receive().await;
Timer::after(Duration::from_millis(next_cmd.after_delay.into())).await;
match next_cmd.cmd_type {
GpioCmdType::SetHigh => {
rprintln!("{}: Set output high", ctx);
out.set_high().unwrap();
}
GpioCmdType::SetLow => {
rprintln!("{}: Set output low", ctx);
out.set_low().unwrap();
}
GpioCmdType::RisingEdge => {
rprintln!("{}: Rising edge", ctx);
if !out.is_low().unwrap() {
out.set_low().unwrap();
}
out.set_high().unwrap();
}
GpioCmdType::FallingEdge => {
rprintln!("{}: Falling edge", ctx);
if !out.is_high().unwrap() {
out.set_high().unwrap();
}
out.set_low().unwrap();
}
}
}
}
// PB22 to PB23 can be handled by both OC10 and OC11 depending on configuration.
#[interrupt]
#[allow(non_snake_case)]
fn OC10() {
on_interrupt_for_asynch_gpio();
}
#[interrupt]
#[allow(non_snake_case)]
fn OC11() {
on_interrupt_for_asynch_gpio();
}

171
examples/embassy/src/bin/async-uart-rx.rs Normal file
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@ -0,0 +1,171 @@
//! Asynchronous UART reception example application.
//!
//! This application receives data on two UARTs permanently using a ring buffer.
//! The ring buffer are read them asynchronously. UART A is received on ports PA8 and PA9.
//! UART B is received on ports PA2 and PA3.
//!
//! Instructions:
//!
//! 1. Tie a USB to UART converter with RX to PA9 and TX to PA8 for UART A.
//! Tie a USB to UART converter with RX to PA3 and TX to PA2 for UART B.
//! 2. Connect to the serial interface by using an application like Putty or picocom. You can
//! type something in the terminal and check if the data is echoed back. You can also check the
//! RTT logs to see received data.
#![no_std]
#![no_main]
use core::cell::RefCell;
use critical_section::Mutex;
use embassy_executor::Spawner;
use embassy_time::Instant;
use embedded_hal::digital::StatefulOutputPin;
use embedded_io::Write;
use embedded_io_async::Read;
use heapless::spsc::{Consumer, Producer, Queue};
use panic_rtt_target as _;
use rtt_target::{rprintln, rtt_init_print};
use va108xx_embassy::embassy;
use va108xx_hal::{
gpio::PinsA,
pac::{self, interrupt},
prelude::*,
uart::{
self, on_interrupt_uart_b_overwriting,
rx_asynch::{on_interrupt_uart_a, RxAsync},
RxAsyncSharedConsumer, Tx,
},
InterruptConfig,
};
const SYSCLK_FREQ: Hertz = Hertz::from_raw(50_000_000);
static QUEUE_UART_A: static_cell::ConstStaticCell<Queue<u8, 256>> =
static_cell::ConstStaticCell::new(Queue::new());
static PRODUCER_UART_A: Mutex<RefCell<Option<Producer<u8, 256>>>> = Mutex::new(RefCell::new(None));
static QUEUE_UART_B: static_cell::ConstStaticCell<Queue<u8, 256>> =
static_cell::ConstStaticCell::new(Queue::new());
static PRODUCER_UART_B: Mutex<RefCell<Option<Producer<u8, 256>>>> = Mutex::new(RefCell::new(None));
static CONSUMER_UART_B: Mutex<RefCell<Option<Consumer<u8, 256>>>> = Mutex::new(RefCell::new(None));
// main is itself an async function.
#[embassy_executor::main]
async fn main(spawner: Spawner) {
rtt_init_print!();
rprintln!("-- VA108xx Async UART RX Demo --");
let mut dp = pac::Peripherals::take().unwrap();
// Safety: Only called once here.
unsafe {
embassy::init(
&mut dp.sysconfig,
&dp.irqsel,
SYSCLK_FREQ,
dp.tim23,
dp.tim22,
);
}
let porta = PinsA::new(&mut dp.sysconfig, dp.porta);
let mut led0 = porta.pa10.into_readable_push_pull_output();
let mut led1 = porta.pa7.into_readable_push_pull_output();
let mut led2 = porta.pa6.into_readable_push_pull_output();
let tx_uart_a = porta.pa9.into_funsel_2();
let rx_uart_a = porta.pa8.into_funsel_2();
let uarta = uart::Uart::new_with_interrupt(
&mut dp.sysconfig,
50.MHz(),
dp.uarta,
(tx_uart_a, rx_uart_a),
115200.Hz(),
InterruptConfig::new(pac::Interrupt::OC2, true, true),
);
let tx_uart_b = porta.pa3.into_funsel_2();
let rx_uart_b = porta.pa2.into_funsel_2();
let uartb = uart::Uart::new_with_interrupt(
&mut dp.sysconfig,
50.MHz(),
dp.uartb,
(tx_uart_b, rx_uart_b),
115200.Hz(),
InterruptConfig::new(pac::Interrupt::OC3, true, true),
);
let (mut tx_uart_a, rx_uart_a) = uarta.split();
let (tx_uart_b, rx_uart_b) = uartb.split();
let (prod_uart_a, cons_uart_a) = QUEUE_UART_A.take().split();
// Pass the producer to the interrupt handler.
let (prod_uart_b, cons_uart_b) = QUEUE_UART_B.take().split();
critical_section::with(|cs| {
*PRODUCER_UART_A.borrow(cs).borrow_mut() = Some(prod_uart_a);
*PRODUCER_UART_B.borrow(cs).borrow_mut() = Some(prod_uart_b);
*CONSUMER_UART_B.borrow(cs).borrow_mut() = Some(cons_uart_b);
});
let mut async_rx_uart_a = RxAsync::new(rx_uart_a, cons_uart_a);
let async_rx_uart_b = RxAsyncSharedConsumer::new(rx_uart_b, &CONSUMER_UART_B);
spawner
.spawn(uart_b_task(async_rx_uart_b, tx_uart_b))
.unwrap();
let mut buf = [0u8; 256];
loop {
rprintln!("Current time UART A: {}", Instant::now().as_secs());
led0.toggle().ok();
led1.toggle().ok();
led2.toggle().ok();
let read_bytes = async_rx_uart_a.read(&mut buf).await.unwrap();
let read_str = core::str::from_utf8(&buf[..read_bytes]).unwrap();
rprintln!(
"Read {} bytes asynchronously on UART A: {:?}",
read_bytes,
read_str
);
tx_uart_a.write_all(read_str.as_bytes()).unwrap();
}
}
#[embassy_executor::task]
async fn uart_b_task(mut async_rx: RxAsyncSharedConsumer<pac::Uartb, 256>, mut tx: Tx<pac::Uartb>) {
let mut buf = [0u8; 256];
loop {
rprintln!("Current time UART B: {}", Instant::now().as_secs());
// Infallible asynchronous operation.
let read_bytes = async_rx.read(&mut buf).await.unwrap();
let read_str = core::str::from_utf8(&buf[..read_bytes]).unwrap();
rprintln!(
"Read {} bytes asynchronously on UART B: {:?}",
read_bytes,
read_str
);
tx.write_all(read_str.as_bytes()).unwrap();
}
}
#[interrupt]
#[allow(non_snake_case)]
fn OC2() {
let mut prod =
critical_section::with(|cs| PRODUCER_UART_A.borrow(cs).borrow_mut().take().unwrap());
let errors = on_interrupt_uart_a(&mut prod);
critical_section::with(|cs| *PRODUCER_UART_A.borrow(cs).borrow_mut() = Some(prod));
// In a production app, we could use a channel to send the errors to the main task.
if let Err(errors) = errors {
rprintln!("UART A errors: {:?}", errors);
}
}
#[interrupt]
#[allow(non_snake_case)]
fn OC3() {
let mut prod =
critical_section::with(|cs| PRODUCER_UART_B.borrow(cs).borrow_mut().take().unwrap());
let errors = on_interrupt_uart_b_overwriting(&mut prod, &CONSUMER_UART_B);
critical_section::with(|cs| *PRODUCER_UART_B.borrow(cs).borrow_mut() = Some(prod));
// In a production app, we could use a channel to send the errors to the main task.
if let Err(errors) = errors {
rprintln!("UART B errors: {:?}", errors);
}
}

97
examples/embassy/src/bin/async-uart-tx.rs Normal file
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@ -0,0 +1,97 @@
//! Asynchronous UART transmission example application.
//!
//! This application receives sends 4 strings with different sizes permanently using UART A.
//! Ports PA8 and PA9 are used for this.
//!
//! Instructions:
//!
//! 1. Tie a USB to UART converter with RX to PA9 and TX to PA8 for UART A.
//! 2. Connect to the serial interface by using an application like Putty or picocom. You can
//! can verify the correctness of the sent strings.
#![no_std]
#![no_main]
use embassy_executor::Spawner;
use embassy_time::{Duration, Instant, Ticker};
use embedded_hal::digital::StatefulOutputPin;
use embedded_io_async::Write;
use panic_rtt_target as _;
use rtt_target::{rprintln, rtt_init_print};
use va108xx_embassy::embassy;
use va108xx_hal::{
gpio::PinsA,
pac::{self, interrupt},
prelude::*,
uart::{self, on_interrupt_uart_a_tx, TxAsync},
InterruptConfig,
};
const SYSCLK_FREQ: Hertz = Hertz::from_raw(50_000_000);
const STR_LIST: &[&str] = &[
"Hello World\r\n",
"Smoll\r\n",
"A string which is larger than the FIFO size\r\n",
"A really large string which is significantly larger than the FIFO size\r\n",
];
// main is itself an async function.
#[embassy_executor::main]
async fn main(_spawner: Spawner) {
rtt_init_print!();
rprintln!("-- VA108xx Async UART TX Demo --");
let mut dp = pac::Peripherals::take().unwrap();
// Safety: Only called once here.
unsafe {
embassy::init(
&mut dp.sysconfig,
&dp.irqsel,
SYSCLK_FREQ,
dp.tim23,
dp.tim22,
);
}
let porta = PinsA::new(&mut dp.sysconfig, dp.porta);
let mut led0 = porta.pa10.into_readable_push_pull_output();
let mut led1 = porta.pa7.into_readable_push_pull_output();
let mut led2 = porta.pa6.into_readable_push_pull_output();
let tx = porta.pa9.into_funsel_2();
let rx = porta.pa8.into_funsel_2();
let uarta = uart::Uart::new_with_interrupt(
&mut dp.sysconfig,
50.MHz(),
dp.uarta,
(tx, rx),
115200.Hz(),
InterruptConfig::new(pac::Interrupt::OC2, true, true),
);
let (tx, _rx) = uarta.split();
let mut async_tx = TxAsync::new(tx);
let mut ticker = Ticker::every(Duration::from_secs(1));
let mut idx = 0;
loop {
rprintln!("Current time: {}", Instant::now().as_secs());
led0.toggle().ok();
led1.toggle().ok();
led2.toggle().ok();
let _written = async_tx
.write(STR_LIST[idx].as_bytes())
.await
.expect("writing failed");
idx += 1;
if idx == STR_LIST.len() {
idx = 0;
}
ticker.next().await;
}
}
#[interrupt]
#[allow(non_snake_case)]
fn OC2() {
on_interrupt_uart_a_tx();
}

67
examples/embassy/src/main.rs Normal file
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@ -0,0 +1,67 @@
#![no_std]
#![no_main]
use embassy_executor::Spawner;
use embassy_time::{Duration, Instant, Ticker};
use embedded_hal::digital::StatefulOutputPin;
use panic_rtt_target as _;
use rtt_target::{rprintln, rtt_init_print};
use va108xx_embassy::embassy;
cfg_if::cfg_if! {
if #[cfg(feature = "custom-irqs")] {
use va108xx_embassy::embassy_time_driver_irqs;
use va108xx_hal::pac::interrupt;
embassy_time_driver_irqs!(timekeeper_irq = OC23, alarm_irq = OC24);
}
}
use va108xx_hal::{gpio::PinsA, pac, prelude::*};
const SYSCLK_FREQ: Hertz = Hertz::from_raw(50_000_000);
// main is itself an async function.
#[embassy_executor::main]
async fn main(_spawner: Spawner) {
rtt_init_print!();
rprintln!("-- VA108xx Embassy Demo --");
let mut dp = pac::Peripherals::take().unwrap();
// Safety: Only called once here.
unsafe {
cfg_if::cfg_if! {
if #[cfg(not(feature = "custom-irqs"))] {
embassy::init(
&mut dp.sysconfig,
&dp.irqsel,
SYSCLK_FREQ,
dp.tim23,
dp.tim22,
);
} else {
embassy::init_with_custom_irqs(
&mut dp.sysconfig,
&dp.irqsel,
SYSCLK_FREQ,
dp.tim23,
dp.tim22,
pac::Interrupt::OC23,
pac::Interrupt::OC24,
);
}
}
}
let porta = PinsA::new(&mut dp.sysconfig, dp.porta);
let mut led0 = porta.pa10.into_readable_push_pull_output();
let mut led1 = porta.pa7.into_readable_push_pull_output();
let mut led2 = porta.pa6.into_readable_push_pull_output();
let mut ticker = Ticker::every(Duration::from_secs(1));
loop {
ticker.next().await;
rprintln!("Current time: {}", Instant::now().as_secs());
led0.toggle().ok();
led1.toggle().ok();
led2.toggle().ok();
}
}

26
examples/rtic/Cargo.toml Normal file
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@ -0,0 +1,26 @@
[package]
name = "rtic-example"
version = "0.1.0"
edition = "2021"
[dependencies]
cortex-m = { version = "0.7", features = ["critical-section-single-core"] }
cortex-m-rt = "0.7"
embedded-hal = "1"
embedded-io = "0.6"
rtt-target = "0.6"
panic-rtt-target = "0.2"
# Even though we do not use this directly, we need to activate this feature explicitely
# so that RTIC compiles because thumv6 does not have CAS operations natively.
portable-atomic = { version = "1", features = ["unsafe-assume-single-core"]}
rtic = { version = "2", features = ["thumbv6-backend"] }
rtic-monotonics = { version = "2", features = ["cortex-m-systick"] }
rtic-sync = { version = "1.3", features = ["defmt-03"] }
once_cell = {version = "1", default-features = false, features = ["critical-section"]}
ringbuf = { version = "0.4.7", default-features = false, features = ["portable-atomic"] }
va108xx-hal = { version = "0.9", path = "../../va108xx-hal" }
vorago-reb1 = { path = "../../vorago-reb1" }

45
vorago-reb1/examples/blinky-button-rtic.rs → examples/rtic/src/bin/blinky-button-rtic.rs
View File

@ -5,17 +5,20 @@
#[rtic::app(device = pac)]
mod app {
use panic_rtt_target as _;
use rtic_example::SYSCLK_FREQ;
use rtt_target::{rprintln, rtt_init_default, set_print_channel};
use va108xx_hal::{
clock::{set_clk_div_register, FilterClkSel},
gpio::{FilterType, InterruptEdge, PinsA},
pac,
prelude::*,
timer::{default_ms_irq_handler, set_up_ms_tick, IrqCfg},
timer::{default_ms_irq_handler, set_up_ms_tick, InterruptConfig},
};
use vorago_reb1::button::Button;
use vorago_reb1::leds::Leds;
rtic_monotonics::systick_monotonic!(Mono, 1_000);
#[derive(Debug, PartialEq)]
pub enum PressMode {
Toggle,
@ -43,10 +46,12 @@ mod app {
struct Shared {}
#[init]
fn init(ctx: init::Context) -> (Shared, Local, init::Monotonics) {
fn init(cx: init::Context) -> (Shared, Local) {
let channels = rtt_init_default!();
set_print_channel(channels.up.0);
rprintln!("-- Vorago Button IRQ Example --");
Mono::start(cx.core.SYST, SYSCLK_FREQ.raw());
let mode = match CFG_MODE {
// Ask mode from user via RTT
CfgMode::Prompt => prompt_mode(channels.down.0),
@ -55,24 +60,25 @@ mod app {
};
rprintln!("Using {:?} mode", mode);
let mut dp = ctx.device;
let pinsa = PinsA::new(&mut dp.sysconfig, Some(dp.ioconfig), dp.porta);
let mut dp = cx.device;
let pinsa = PinsA::new(&mut dp.sysconfig, dp.porta);
let edge_irq = match mode {
PressMode::Toggle => InterruptEdge::HighToLow,
PressMode::Keep => InterruptEdge::BothEdges,
};
// Configure an edge interrupt on the button and route it to interrupt vector 15
let mut button = Button::new(pinsa.pa11.into_floating_input()).edge_irq(
let mut button = Button::new(pinsa.pa11.into_floating_input());
button.configure_edge_interrupt(
edge_irq,
IrqCfg::new(pac::interrupt::OC15, true, true),
InterruptConfig::new(pac::interrupt::OC15, true, true),
Some(&mut dp.sysconfig),
Some(&mut dp.irqsel),
);
if mode == PressMode::Toggle {
// This filter debounces the switch for edge based interrupts
button = button.filter_type(FilterType::FilterFourClockCycles, FilterClkSel::Clk1);
button.configure_filter_type(FilterType::FilterFourClockCycles, FilterClkSel::Clk1);
set_clk_div_register(&mut dp.sysconfig, FilterClkSel::Clk1, 50_000);
}
let mut leds = Leds::new(
@ -84,13 +90,13 @@ mod app {
led.off();
}
set_up_ms_tick(
IrqCfg::new(pac::Interrupt::OC0, true, true),
InterruptConfig::new(pac::Interrupt::OC0, true, true),
&mut dp.sysconfig,
Some(&mut dp.irqsel),
50.MHz(),
dp.tim0,
);
(Shared {}, Local { leds, button, mode }, init::Monotonics())
(Shared {}, Local { leds, button, mode })
}
// `shared` cannot be accessed from this context
@ -108,12 +114,10 @@ mod app {
let mode = cx.local.mode;
if *mode == PressMode::Toggle {
leds[0].toggle();
} else if button.released() {
leds[0].off();
} else {
if button.released() {
leds[0].off();
} else {
leds[0].on();
}
leds[0].on();
}
}
@ -129,14 +133,11 @@ mod app {
let mut read;
loop {
read = down_channel.read(&mut read_buf);
for i in 0..read {
let val = read_buf[i] as char;
if val == '0' || val == '1' {
return if val == '0' {
PressMode::Toggle
} else {
PressMode::Keep
};
for &byte in &read_buf[..read] {
match byte as char {
'0' => return PressMode::Toggle,
'1' => return PressMode::Keep,
_ => continue, // Ignore other characters
}
}
}

0
examples/simple/examples/rtic-empty.rs → examples/rtic/src/bin/rtic-empty.rs
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131
examples/rtic/src/bin/uart-echo-rtic.rs Normal file
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@ -0,0 +1,131 @@
//! More complex UART application
//!
//! Uses the IRQ capabilities of the VA10820 peripheral and the RTIC framework to poll the UART in
//! a non-blocking way. All received data will be sent back to the sender.
#![no_main]
#![no_std]
use ringbuf::StaticRb;
// Larger buffer for TC to be able to hold the possibly large memory write packets.
const RX_RING_BUF_SIZE: usize = 1024;
#[rtic::app(device = pac, dispatchers = [OC4])]
mod app {
use super::*;
use embedded_io::Write;
use panic_rtt_target as _;
use ringbuf::traits::{Consumer, Observer, Producer};
use rtic_example::SYSCLK_FREQ;
use rtic_monotonics::Monotonic;
use rtt_target::{rprintln, rtt_init_print};
use va108xx_hal::{
gpio::PinsA,
pac,
prelude::*,
uart::{self, RxWithInterrupt, Tx},
InterruptConfig,
};
#[local]
struct Local {
rx: RxWithInterrupt<pac::Uarta>,
tx: Tx<pac::Uarta>,
}
#[shared]
struct Shared {
rb: StaticRb<u8, RX_RING_BUF_SIZE>,
}
rtic_monotonics::systick_monotonic!(Mono, 1_000);
#[init]
fn init(cx: init::Context) -> (Shared, Local) {
rtt_init_print!();
rprintln!("-- VA108xx UART Echo with IRQ example application--");
Mono::start(cx.core.SYST, SYSCLK_FREQ.raw());
let mut dp = cx.device;
let gpioa = PinsA::new(&mut dp.sysconfig, dp.porta);
let tx = gpioa.pa9.into_funsel_2();
let rx = gpioa.pa8.into_funsel_2();
let irq_uart = uart::Uart::new_with_interrupt(
&mut dp.sysconfig,
SYSCLK_FREQ,
dp.uarta,
(tx, rx),
115200.Hz(),
InterruptConfig::new(pac::Interrupt::OC3, true, true),
);
let (tx, rx) = irq_uart.split();
let mut rx = rx.into_rx_with_irq();
rx.start();
echo_handler::spawn().unwrap();
(
Shared {
rb: StaticRb::default(),
},
Local { rx, tx },
)
}
// `shared` cannot be accessed from this context
#[idle]
fn idle(_cx: idle::Context) -> ! {
loop {
cortex_m::asm::nop();
}
}
#[task(
binds = OC3,
shared = [rb],
local = [
rx,
],
)]
fn reception_task(mut cx: reception_task::Context) {
let mut buf: [u8; 16] = [0; 16];
let mut ringbuf_full = false;
let result = cx.local.rx.on_interrupt(&mut buf);
if result.bytes_read > 0 && result.errors.is_none() {
cx.shared.rb.lock(|rb| {
if rb.vacant_len() < result.bytes_read {
ringbuf_full = true;
} else {
rb.push_slice(&buf[0..result.bytes_read]);
}
});
}
if ringbuf_full {
// Could also drop oldest data, but that would require the consumer to be shared.
rprintln!("buffer full, data was dropped");
}
}
#[task(shared = [rb], local = [
buf: [u8; RX_RING_BUF_SIZE] = [0; RX_RING_BUF_SIZE],
tx
], priority=1)]
async fn echo_handler(mut cx: echo_handler::Context) {
loop {
cx.shared.rb.lock(|rb| {
let bytes_to_read = rb.occupied_len();
if bytes_to_read > 0 {
let actual_read_bytes = rb.pop_slice(&mut cx.local.buf[0..bytes_to_read]);
cx.local
.tx
.write_all(&cx.local.buf[0..actual_read_bytes])
.expect("Failed to write to TX");
}
});
Mono::delay(50.millis()).await;
}
}
}

4
examples/rtic/src/lib.rs Normal file
View File

@ -0,0 +1,4 @@
#![no_std]
use va108xx_hal::time::Hertz;
pub const SYSCLK_FREQ: Hertz = Hertz::from_raw(50_000_000);

67
examples/rtic/src/main.rs Normal file
View File

@ -0,0 +1,67 @@
//! RTIC minimal blinky
#![no_main]
#![no_std]
#[rtic::app(device = pac, dispatchers = [OC31, OC30, OC29])]
mod app {
use cortex_m::asm;
use embedded_hal::digital::StatefulOutputPin;
use panic_rtt_target as _;
use rtic_example::SYSCLK_FREQ;
use rtic_monotonics::systick::prelude::*;
use rtic_monotonics::Monotonic;
use rtt_target::{rprintln, rtt_init_print};
use va108xx_hal::{
gpio::{OutputReadablePushPull, Pin, PinsA, PA10, PA6, PA7},
pac,
};
#[local]
struct Local {
led0: Pin<PA10, OutputReadablePushPull>,
led1: Pin<PA7, OutputReadablePushPull>,
led2: Pin<PA6, OutputReadablePushPull>,
}
#[shared]
struct Shared {}
rtic_monotonics::systick_monotonic!(Mono, 1_000);
#[init]
fn init(mut cx: init::Context) -> (Shared, Local) {
rtt_init_print!();
rprintln!("-- Vorago VA108xx RTIC template --");
Mono::start(cx.core.SYST, SYSCLK_FREQ.raw());
let porta = PinsA::new(&mut cx.device.sysconfig, cx.device.porta);
let led0 = porta.pa10.into_readable_push_pull_output();
let led1 = porta.pa7.into_readable_push_pull_output();
let led2 = porta.pa6.into_readable_push_pull_output();
blinky::spawn().ok();
(Shared {}, Local { led0, led1, led2 })
}
// `shared` cannot be accessed from this context
#[idle]
fn idle(_cx: idle::Context) -> ! {
loop {
asm::nop();
}
}
#[task(
priority = 3,
local=[led0, led1, led2],
)]
async fn blinky(cx: blinky::Context) {
loop {
rprintln!("toggling LEDs");
cx.local.led0.toggle().ok();
cx.local.led1.toggle().ok();
cx.local.led2.toggle().ok();
Mono::delay(1000.millis()).await;
}
}
}

25
examples/simple/Cargo.toml
View File

@ -4,30 +4,21 @@ version = "0.1.0"
edition = "2021"
[dependencies]
panic-halt = "0.2"
cortex-m = {version = "0.7", features = ["critical-section-single-core"]}
panic-rtt-target = "0.1"
cortex-m-rt = "0.7"
rtt-target = "0.5"
rtic-sync = { version = "1.3", features = ["defmt-03"] }
panic-halt = "1"
panic-rtt-target = "0.2"
critical-section = "1"
rtt-target = "0.6"
embedded-hal = "1"
embedded-hal-nb = "1"
embedded-io = "0.6"
cortex-m-semihosting = "0.5.0"
# I'd really like to use those, but it is tricky without probe-rs..
# defmt = "0.3"
# defmt-brtt = { version = "0.1", default-features = false, features = ["rtt"] }
# panic-probe = { version = "0.3", features = ["print-defmt"] }
[dependencies.rtic]
version = "2"
features = ["thumbv6-backend"]
[dependencies.rtic-monotonics]
version = "1"
features = ["cortex-m-systick"]
[dependencies.va108xx-hal]
version = "0.6"
path = "../../va108xx-hal"
version = "0.9"
features = ["rt", "defmt"]
[dependencies.vorago-reb1]
path = "../../vorago-reb1"

10
examples/simple/examples/blinky.rs
View File

@ -16,24 +16,24 @@ use va108xx_hal::{
gpio::PinsA,
pac::{self, interrupt},
prelude::*,
pwm::{default_ms_irq_handler, set_up_ms_tick, CountDownTimer},
timer::DelayMs,
IrqCfg,
timer::{default_ms_irq_handler, set_up_ms_tick, CountdownTimer},
InterruptConfig,
};
#[entry]
fn main() -> ! {
let mut dp = pac::Peripherals::take().unwrap();
let mut delay_ms = DelayMs::new(set_up_ms_tick(
IrqCfg::new(interrupt::OC0, true, true),
InterruptConfig::new(interrupt::OC0, true, true),
&mut dp.sysconfig,
Some(&mut dp.irqsel),
50.MHz(),
dp.tim0,
))
.unwrap();
let mut delay_tim1 = CountDownTimer::new(&mut dp.sysconfig, 50.MHz(), dp.tim1);
let porta = PinsA::new(&mut dp.sysconfig, Some(dp.ioconfig), dp.porta);
let mut delay_tim1 = CountdownTimer::new(&mut dp.sysconfig, 50.MHz(), dp.tim1);
let porta = PinsA::new(&mut dp.sysconfig, dp.porta);
let mut led1 = porta.pa10.into_readable_push_pull_output();
let mut led2 = porta.pa7.into_readable_push_pull_output();
let mut led3 = porta.pa6.into_readable_push_pull_output();

22
examples/simple/examples/cascade.rs
View File

@ -17,13 +17,13 @@ use va108xx_hal::{
prelude::*,
timer::{
default_ms_irq_handler, set_up_ms_delay_provider, CascadeCtrl, CascadeSource,
CountDownTimer, Event, IrqCfg,
CountdownTimer, Event, InterruptConfig,
},
};
static CSD_TGT_1: Mutex<RefCell<Option<CountDownTimer<pac::Tim4>>>> =
static CSD_TGT_1: Mutex<RefCell<Option<CountdownTimer<pac::Tim4>>>> =
Mutex::new(RefCell::new(None));
static CSD_TGT_2: Mutex<RefCell<Option<CountDownTimer<pac::Tim5>>>> =
static CSD_TGT_2: Mutex<RefCell<Option<CountdownTimer<pac::Tim5>>>> =
Mutex::new(RefCell::new(None));
#[entry]
@ -36,19 +36,19 @@ fn main() -> ! {
// Will be started periodically to trigger a cascade
let mut cascade_triggerer =
CountDownTimer::new(&mut dp.sysconfig, 50.MHz(), dp.tim3).auto_disable(true);
CountdownTimer::new(&mut dp.sysconfig, 50.MHz(), dp.tim3).auto_disable(true);
cascade_triggerer.listen(
Event::TimeOut,
IrqCfg::new(pac::Interrupt::OC1, true, false),
InterruptConfig::new(pac::Interrupt::OC1, true, false),
Some(&mut dp.irqsel),
Some(&mut dp.sysconfig),
);
// First target for cascade
let mut cascade_target_1 =
CountDownTimer::new(&mut dp.sysconfig, 50.MHz(), dp.tim4).auto_deactivate(true);
CountdownTimer::new(&mut dp.sysconfig, 50.MHz(), dp.tim4).auto_deactivate(true);
cascade_target_1
.cascade_0_source(CascadeSource::TimBase, Some(3))
.cascade_0_source(CascadeSource::Tim(3))
.expect("Configuring cascade source for TIM4 failed");
let mut csd_cfg = CascadeCtrl {
enb_start_src_csd0: true,
@ -62,7 +62,7 @@ fn main() -> ! {
// the timer expires
cascade_target_1.listen(
Event::TimeOut,
IrqCfg::new(pac::Interrupt::OC2, true, false),
InterruptConfig::new(pac::Interrupt::OC2, true, false),
Some(&mut dp.irqsel),
Some(&mut dp.sysconfig),
);
@ -72,10 +72,10 @@ fn main() -> ! {
// Activated by first cascade target
let mut cascade_target_2 =
CountDownTimer::new(&mut dp.sysconfig, 50.MHz(), dp.tim5).auto_deactivate(true);
CountdownTimer::new(&mut dp.sysconfig, 50.MHz(), dp.tim5).auto_deactivate(true);
// Set TIM4 as cascade source
cascade_target_2
.cascade_1_source(CascadeSource::TimBase, Some(4))
.cascade_1_source(CascadeSource::Tim(4))
.expect("Configuring cascade source for TIM5 failed");
csd_cfg = CascadeCtrl::default();
@ -88,7 +88,7 @@ fn main() -> ! {
// the timer expires
cascade_target_2.listen(
Event::TimeOut,
IrqCfg::new(pac::Interrupt::OC3, true, false),
InterruptConfig::new(pac::Interrupt::OC3, true, false),
Some(&mut dp.irqsel),
Some(&mut dp.sysconfig),
);

6
examples/simple/examples/pwm.rs
View File

@ -19,11 +19,11 @@ fn main() -> ! {
rtt_init_print!();
rprintln!("-- VA108xx PWM example application--");
let mut dp = pac::Peripherals::take().unwrap();
let pinsa = PinsA::new(&mut dp.sysconfig, None, dp.porta);
let pinsa = PinsA::new(&mut dp.sysconfig, dp.porta);
let mut pwm = pwm::PwmPin::new(
(pinsa.pa3.into_funsel_1(), dp.tim3),
50.MHz(),
&mut dp.sysconfig,
50.MHz(),
(pinsa.pa3.into_funsel_1(), dp.tim3),
10.Hz(),
);
let mut delay = set_up_ms_delay_provider(&mut dp.sysconfig, 50.MHz(), dp.tim0);

4
examples/simple/examples/rtt-log.rs
View File

@ -3,12 +3,14 @@
#![no_std]
use cortex_m_rt::entry;
use panic_halt as _;
use panic_rtt_target as _;
use rtt_target::{rprintln, rtt_init_print};
use va108xx_hal as _;
#[entry]
fn main() -> ! {
rtt_init_print!();
rprintln!("-- VA108XX RTT example --");
let mut counter = 0;
loop {
rprintln!("{}: Hello, world!", counter);

178
examples/simple/examples/spi.rs
View File

@ -15,17 +15,16 @@ use va108xx_hal::{
gpio::{PinsA, PinsB},
pac::{self, interrupt},
prelude::*,
pwm::{default_ms_irq_handler, set_up_ms_tick},
spi::{self, Spi, SpiBase, TransferConfig},
IrqCfg,
spi::{self, Spi, SpiBase, SpiClkConfig, TransferConfigWithHwcs},
timer::{default_ms_irq_handler, set_up_ms_tick},
InterruptConfig,
};
#[derive(PartialEq, Debug)]
pub enum ExampleSelect {
// Enter loopback mode. It is not necessary to tie MOSI/MISO together for this
Loopback,
// Send a test buffer and print everything received
TestBuffer,
MosiMisoTiedTogetherManually,
}
#[derive(PartialEq, Debug)]
@ -48,17 +47,19 @@ fn main() -> ! {
rprintln!("-- VA108xx SPI example application--");
let mut dp = pac::Peripherals::take().unwrap();
let mut delay = set_up_ms_tick(
IrqCfg::new(interrupt::OC0, true, true),
InterruptConfig::new(interrupt::OC0, true, true),
&mut dp.sysconfig,
Some(&mut dp.irqsel),
50.MHz(),
dp.tim0,
);
let spi_clk_cfg = SpiClkConfig::from_clk(50.MHz(), SPI_SPEED_KHZ.kHz())
.expect("creating SPI clock config failed");
let spia_ref: RefCell<Option<SpiBase<pac::Spia, u8>>> = RefCell::new(None);
let spib_ref: RefCell<Option<SpiBase<pac::Spib, u8>>> = RefCell::new(None);
let pinsa = PinsA::new(&mut dp.sysconfig, None, dp.porta);
let pinsb = PinsB::new(&mut dp.sysconfig, Some(dp.ioconfig), dp.portb);
let pinsa = PinsA::new(&mut dp.sysconfig, dp.porta);
let pinsb = PinsB::new(&mut dp.sysconfig, dp.portb);
let mut spi_cfg = spi::SpiConfig::default();
if EXAMPLE_SEL == ExampleSelect::Loopback {
@ -73,13 +74,12 @@ fn main() -> ! {
pinsa.pa30.into_funsel_1(),
pinsa.pa29.into_funsel_1(),
);
let mut spia = Spi::spia(
let mut spia = Spi::new(
&mut dp.sysconfig,
50.MHz(),
dp.spia,
(sck, miso, mosi),
50.MHz(),
spi_cfg,
Some(&mut dp.sysconfig),
None,
);
spia.set_fill_word(FILL_WORD);
spia_ref.borrow_mut().replace(spia.downgrade());
@ -90,13 +90,12 @@ fn main() -> ! {
pinsb.pb8.into_funsel_2(),
pinsb.pb7.into_funsel_2(),
);
let mut spia = Spi::spia(
let mut spia = Spi::new(
&mut dp.sysconfig,
50.MHz(),
dp.spia,
(sck, miso, mosi),
50.MHz(),
spi_cfg,
Some(&mut dp.sysconfig),
None,
);
spia.set_fill_word(FILL_WORD);
spia_ref.borrow_mut().replace(spia.downgrade());
@ -107,13 +106,12 @@ fn main() -> ! {
pinsb.pb4.into_funsel_1(),
pinsb.pb3.into_funsel_1(),
);
let mut spib = Spi::spib(
let mut spib = Spi::new(
&mut dp.sysconfig,
50.MHz(),
dp.spib,
(sck, miso, mosi),
50.MHz(),
spi_cfg,
Some(&mut dp.sysconfig),
None,
);
spib.set_fill_word(FILL_WORD);
spib_ref.borrow_mut().replace(spib.downgrade());
@ -123,19 +121,25 @@ fn main() -> ! {
match SPI_BUS_SEL {
SpiBusSelect::SpiAPortA | SpiBusSelect::SpiAPortB => {
if let Some(ref mut spi) = *spia_ref.borrow_mut() {
let transfer_cfg =
TransferConfig::new_no_hw_cs(SPI_SPEED_KHZ.kHz(), SPI_MODE, BLOCKMODE, false);
let transfer_cfg = TransferConfigWithHwcs::new_no_hw_cs(
Some(spi_clk_cfg),
Some(SPI_MODE),
BLOCKMODE,
true,
false,
);
spi.cfg_transfer(&transfer_cfg);
}
}
SpiBusSelect::SpiBPortB => {
if let Some(ref mut spi) = *spib_ref.borrow_mut() {
let hw_cs_pin = pinsb.pb2.into_funsel_1();
let transfer_cfg = TransferConfig::new(
SPI_SPEED_KHZ.kHz(),
SPI_MODE,
let transfer_cfg = TransferConfigWithHwcs::new(
Some(spi_clk_cfg),
Some(SPI_MODE),
Some(hw_cs_pin),
BLOCKMODE,
true,
false,
);
spi.cfg_transfer(&transfer_cfg);
@ -149,88 +153,64 @@ fn main() -> ! {
match SPI_BUS_SEL {
SpiBusSelect::SpiAPortA | SpiBusSelect::SpiAPortB => {
if let Some(ref mut spi) = *spia_ref.borrow_mut() {
if EXAMPLE_SEL == ExampleSelect::Loopback {
// Can't really verify correct reply here.
spi.write(&[0x42]).expect("write failed");
// Because of the loopback mode, we should get back the fill word here.
spi.read(&mut reply_buf[0..1]).unwrap();
assert_eq!(reply_buf[0], FILL_WORD);
delay.delay_ms(500_u32);
// Can't really verify correct reply here.
spi.write(&[0x42]).expect("write failed");
// Because of the loopback mode, we should get back the fill word here.
spi.read(&mut reply_buf[0..1]).unwrap();
assert_eq!(reply_buf[0], FILL_WORD);
delay.delay_ms(500_u32);
let tx_buf: [u8; 3] = [0x01, 0x02, 0x03];
spi.transfer(&mut reply_buf[0..3], &tx_buf).unwrap();
assert_eq!(tx_buf, reply_buf[0..3]);
rprintln!(
"Received reply: {}, {}, {}",
reply_buf[0],
reply_buf[1],
reply_buf[2]
);
delay.delay_ms(500_u32);
let tx_buf: [u8; 3] = [0x01, 0x02, 0x03];
spi.transfer(&mut reply_buf[0..3], &tx_buf).unwrap();
assert_eq!(tx_buf, reply_buf[0..3]);
rprintln!(
"Received reply: {}, {}, {}",
reply_buf[0],
reply_buf[1],
reply_buf[2]
);
delay.delay_ms(500_u32);
let mut tx_rx_buf: [u8; 3] = [0x03, 0x02, 0x01];
spi.transfer_in_place(&mut tx_rx_buf).unwrap();
rprintln!(
"Received reply: {}, {}, {}",
tx_rx_buf[0],
tx_rx_buf[1],
tx_rx_buf[2]
);
assert_eq!(&tx_rx_buf[0..3], &[0x03, 0x02, 0x01]);
} else {
let send_buf: [u8; 3] = [0x01, 0x02, 0x03];
spi.transfer(&mut reply_buf[0..3], &send_buf).unwrap();
rprintln!(
"Received reply: {}, {}, {}",
reply_buf[0],
reply_buf[1],
reply_buf[2]
);
delay.delay_ms(1000_u32);
}
let mut tx_rx_buf: [u8; 3] = [0x03, 0x02, 0x01];
spi.transfer_in_place(&mut tx_rx_buf).unwrap();
rprintln!(
"Received reply: {}, {}, {}",
tx_rx_buf[0],
tx_rx_buf[1],
tx_rx_buf[2]
);
assert_eq!(&tx_rx_buf[0..3], &[0x03, 0x02, 0x01]);
}
}
SpiBusSelect::SpiBPortB => {
if let Some(ref mut spi) = *spib_ref.borrow_mut() {
if EXAMPLE_SEL == ExampleSelect::Loopback {
// Can't really verify correct reply here.
spi.write(&[0x42]).expect("write failed");
// Because of the loopback mode, we should get back the fill word here.
spi.read(&mut reply_buf[0..1]).unwrap();
assert_eq!(reply_buf[0], FILL_WORD);
delay.delay_ms(500_u32);
// Can't really verify correct reply here.
spi.write(&[0x42]).expect("write failed");
// Because of the loopback mode, we should get back the fill word here.
spi.read(&mut reply_buf[0..1]).unwrap();
assert_eq!(reply_buf[0], FILL_WORD);
delay.delay_ms(500_u32);
let tx_buf: [u8; 3] = [0x01, 0x02, 0x03];
spi.transfer(&mut reply_buf[0..3], &tx_buf).unwrap();
assert_eq!(tx_buf, reply_buf[0..3]);
rprintln!(
"Received reply: {}, {}, {}",
reply_buf[0],
reply_buf[1],
reply_buf[2]
);
delay.delay_ms(500_u32);
let tx_buf: [u8; 3] = [0x01, 0x02, 0x03];
spi.transfer(&mut reply_buf[0..3], &tx_buf).unwrap();
assert_eq!(tx_buf, reply_buf[0..3]);
rprintln!(
"Received reply: {}, {}, {}",
reply_buf[0],
reply_buf[1],
reply_buf[2]
);
delay.delay_ms(500_u32);
let mut tx_rx_buf: [u8; 3] = [0x03, 0x02, 0x01];
spi.transfer_in_place(&mut tx_rx_buf).unwrap();
rprintln!(
"Received reply: {}, {}, {}",
tx_rx_buf[0],
tx_rx_buf[1],
tx_rx_buf[2]
);
assert_eq!(&tx_rx_buf[0..3], &[0x03, 0x02, 0x01]);
} else {
let send_buf: [u8; 3] = [0x01, 0x02, 0x03];
spi.transfer(&mut reply_buf[0..3], &send_buf).unwrap();
rprintln!(
"Received reply: {}, {}, {}",
reply_buf[0],
reply_buf[1],
reply_buf[2]
);
delay.delay_ms(1000_u32);
}
let mut tx_rx_buf: [u8; 3] = [0x03, 0x02, 0x01];
spi.transfer_in_place(&mut tx_rx_buf).unwrap();
rprintln!(
"Received reply: {}, {}, {}",
tx_rx_buf[0],
tx_rx_buf[1],
tx_rx_buf[2]
);
assert_eq!(&tx_rx_buf[0..3], &[0x03, 0x02, 0x01]);
}
}
}

21
examples/simple/examples/timer-ticks.rs
View File

@ -3,8 +3,8 @@
#![no_std]
use core::cell::Cell;
use cortex_m::interrupt::Mutex;
use cortex_m_rt::entry;
use critical_section::Mutex;
use panic_rtt_target as _;
use rtt_target::{rprintln, rtt_init_print};
use va108xx_hal::{
@ -12,7 +12,9 @@ use va108xx_hal::{
pac::{self, interrupt},
prelude::*,
time::Hertz,
timer::{default_ms_irq_handler, set_up_ms_tick, CountDownTimer, Event, IrqCfg, MS_COUNTER},
timer::{
default_ms_irq_handler, set_up_ms_tick, CountdownTimer, Event, InterruptConfig, MS_COUNTER,
},
};
#[allow(dead_code)]
@ -65,17 +67,17 @@ fn main() -> ! {
}
LibType::Hal => {
set_up_ms_tick(
IrqCfg::new(interrupt::OC0, true, true),
InterruptConfig::new(interrupt::OC0, true, true),
&mut dp.sysconfig,
Some(&mut dp.irqsel),
50.MHz(),
dp.tim0,
);
let mut second_timer =
CountDownTimer::new(&mut dp.sysconfig, get_sys_clock().unwrap(), dp.tim1);
CountdownTimer::new(&mut dp.sysconfig, get_sys_clock().unwrap(), dp.tim1);
second_timer.listen(
Event::TimeOut,
IrqCfg::new(interrupt::OC1, true, true),
InterruptConfig::new(interrupt::OC1, true, true),
Some(&mut dp.irqsel),
Some(&mut dp.sysconfig),
);
@ -83,11 +85,12 @@ fn main() -> ! {
}
}
loop {
let current_ms = cortex_m::interrupt::free(|cs| MS_COUNTER.borrow(cs).get());
let current_ms = critical_section::with(|cs| MS_COUNTER.borrow(cs).get());
if current_ms - last_ms >= 1000 {
last_ms = current_ms;
// To prevent drift.
last_ms += 1000;
rprintln!("MS counter: {}", current_ms);
let second = cortex_m::interrupt::free(|cs| SEC_COUNTER.borrow(cs).get());
let second = critical_section::with(|cs| SEC_COUNTER.borrow(cs).get());
rprintln!("Second counter: {}", second);
}
cortex_m::asm::delay(10000);
@ -110,7 +113,7 @@ fn OC0() {
#[interrupt]
#[allow(non_snake_case)]
fn OC1() {
cortex_m::interrupt::free(|cs| {
critical_section::with(|cs| {
let mut sec = SEC_COUNTER.borrow(cs).get();
sec += 1;
SEC_COUNTER.borrow(cs).set(sec);

172
examples/simple/examples/uart-irq-rtic.rs
View File

@ -1,172 +0,0 @@
//! More complex UART application
//!
//! Uses the IRQ capabilities of the VA10820 peripheral and the RTIC framework to poll the UART in
//! a non-blocking way. You can send variably sized strings to the VA10820 which will be echoed
//! back to the sender.
//!
//! This script was tested with an Arduino Due. You can find the test script in the
//! [`/test/DueSerialTest`](https://egit.irs.uni-stuttgart.de/rust/va108xx-hal/src/branch/main/test/DueSerialTest)
//! folder.
#![no_main]
#![no_std]
#[rtic::app(device = pac, dispatchers = [OC4])]
mod app {
use embedded_io::Write;
use panic_rtt_target as _;
use rtic_monotonics::systick::Systick;
use rtic_sync::make_channel;
use rtt_target::{rprintln, rtt_init_print};
use va108xx_hal::{
gpio::PinsB,
pac,
prelude::*,
time::Hertz,
uart::{self, IrqCfg, IrqResult, UartWithIrqBase},
};
#[local]
struct Local {
rx_info_tx: rtic_sync::channel::Sender<'static, RxInfo, 3>,
rx_info_rx: rtic_sync::channel::Receiver<'static, RxInfo, 3>,
}
#[shared]
struct Shared {
irq_uart: UartWithIrqBase<pac::Uartb>,
rx_buf: [u8; 64],
}
#[derive(Debug, Copy, Clone)]
struct RxInfo {
pub bytes_read: usize,
pub end_idx: usize,
pub timeout: bool,
}
#[init]
fn init(cx: init::Context) -> (Shared, Local) {
rtt_init_print!();
//set_print_channel(channels.up.0);
rprintln!("-- VA108xx UART IRQ example application--");
// Initialize the systick interrupt & obtain the token to prove that we did
let systick_mono_token = rtic_monotonics::create_systick_token!();
Systick::start(
cx.core.SYST,
Hertz::from(50.MHz()).raw(),
systick_mono_token,
);
let mut dp = cx.device;
let gpiob = PinsB::new(&mut dp.sysconfig, Some(dp.ioconfig), dp.portb);
let tx = gpiob.pb21.into_funsel_1();
let rx = gpiob.pb20.into_funsel_1();
let irq_cfg = IrqCfg::new(pac::interrupt::OC3, true, true);
let (mut irq_uart, _) =
uart::Uart::uartb(dp.uartb, (tx, rx), 115200.Hz(), &mut dp.sysconfig, 50.MHz())
.into_uart_with_irq(irq_cfg, Some(&mut dp.sysconfig), Some(&mut dp.irqsel))
.downgrade();
irq_uart
.read_fixed_len_using_irq(64, true)
.expect("Read initialization failed");
let (rx_info_tx, rx_info_rx) = make_channel!(RxInfo, 3);
let rx_buf: [u8; 64] = [0; 64];
//reply_handler::spawn().expect("spawning reply handler failed");
(
Shared { irq_uart, rx_buf },
Local {
rx_info_tx,
rx_info_rx,
},
)
}
// `shared` cannot be accessed from this context
#[idle]
fn idle(_cx: idle::Context) -> ! {
loop {
cortex_m::asm::nop();
}
}
#[task(
binds = OC3,
shared = [irq_uart, rx_buf],
local = [cnt: u32 = 0, result: IrqResult = IrqResult::new(), rx_info_tx],
)]
fn reception_task(cx: reception_task::Context) {
let result = cx.local.result;
let cnt: &mut u32 = cx.local.cnt;
let irq_uart = cx.shared.irq_uart;
let rx_buf = cx.shared.rx_buf;
let (completed, end_idx) = (irq_uart, rx_buf).lock(|irq_uart, rx_buf| {
match irq_uart.irq_handler(result, rx_buf) {
Ok(_) => {
if result.complete() {
// Initiate next transfer immediately
irq_uart
.read_fixed_len_using_irq(64, true)
.expect("Read operation init failed");
let mut end_idx = 0;
for idx in 0..rx_buf.len() {
if (rx_buf[idx] as char) == '\n' {
end_idx = idx;
break;
}
}
(true, end_idx)
} else {
(false, 0)
}
}
Err(e) => {
rprintln!("reception error {:?}", e);
(false, 0)
}
}
});
if completed {
rprintln!("counter: {}", cnt);
cx.local
.rx_info_tx
.try_send(RxInfo {
bytes_read: result.bytes_read,
end_idx,
timeout: result.timeout(),
})
.expect("RX queue full");
}
*cnt += 1;
}
#[task(shared = [irq_uart, rx_buf], local = [rx_info_rx], priority=1)]
async fn reply_handler(cx: reply_handler::Context) {
let mut irq_uart = cx.shared.irq_uart;
let mut rx_buf = cx.shared.rx_buf;
loop {
match cx.local.rx_info_rx.recv().await {
Ok(rx_info) => {
rprintln!("reception success, {} bytes read", rx_info.bytes_read);
if rx_info.timeout {
rprintln!("timeout occurred");
}
rx_buf.lock(|rx_buf| {
let string = core::str::from_utf8(&rx_buf[0..rx_info.end_idx])
.expect("Invalid string format");
rprintln!("read string: {}", string);
irq_uart.lock(|uart| {
writeln!(uart.uart, "{}", string).expect("Sending reply failed");
});
});
}
Err(e) => {
rprintln!("error receiving RX info: {:?}", e);
}
}
}
}
}

12
examples/simple/examples/uart.rs
View File

@ -24,12 +24,18 @@ fn main() -> ! {
let mut dp = pac::Peripherals::take().unwrap();
let gpioa = PinsA::new(&mut dp.sysconfig, Some(dp.ioconfig), dp.porta);
let gpioa = PinsA::new(&mut dp.sysconfig, dp.porta);
let tx = gpioa.pa9.into_funsel_2();
let rx = gpioa.pa8.into_funsel_2();
let uart = uart::Uart::new_without_interrupt(
&mut dp.sysconfig,
50.MHz(),
dp.uarta,
(tx, rx),
115200.Hz(),
);
let uarta = uart::Uart::uarta(dp.uarta, (tx, rx), 115200.Hz(), &mut dp.sysconfig, 50.MHz());
let (mut tx, mut rx) = uarta.split();
let (mut tx, mut rx) = uart.split();
writeln!(tx, "Hello World\r").unwrap();
loop {
// Echo what is received on the serial link.

1
flashloader/.gitignore vendored Normal file
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@ -0,0 +1 @@
/venv

35
flashloader/Cargo.toml Normal file
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@ -0,0 +1,35 @@
[package]
name = "flashloader"
version = "0.1.0"
edition = "2021"
[dependencies]
cortex-m = "0.7"
cortex-m-rt = "0.7"
embedded-hal = "1"
embedded-hal-nb = "1"
embedded-io = "0.6"
panic-rtt-target = "0.2"
rtt-target = "0.6"
num_enum = { version = "0.7", default-features = false }
log = "0.4"
crc = "3"
cobs = { version = "0.3", default-features = false }
satrs = { version = "0.2", default-features = false }
rtt-log = "0.5"
ringbuf = { version = "0.4.7", default-features = false, features = ["portable-atomic"] }
once_cell = { version = "1", default-features = false, features = ["critical-section"] }
spacepackets = { version = "0.11", default-features = false }
# Even though we do not use this directly, we need to activate this feature explicitely
# so that RTIC compiles because thumv6 does not have CAS operations natively.
portable-atomic = {version = "1", features = ["unsafe-assume-single-core"]}
rtic = { version = "2", features = ["thumbv6-backend"] }
rtic-monotonics = { version = "2", features = ["cortex-m-systick"] }
rtic-sync = {version = "1", features = ["defmt-03"]}
[dependencies.va108xx-hal]
path = "../va108xx-hal"
[dependencies.vorago-reb1]
path = "../vorago-reb1"

75
flashloader/README.md Normal file
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@ -0,0 +1,75 @@
VA108xx Flashloader Application
========
This flashloader shows a minimal example for a self-updatable Rust software which exposes
a simple PUS (CCSDS) interface to update the software. It also provides a Python application
called the `image-loader.py` which can be used to upload compiled images to the flashloader
application to write them to the NVM.
Please note that the both the application and the image loader are tailored towards usage
with the [bootloader provided by this repository](https://egit.irs.uni-stuttgart.de/rust/va108xx-rs/src/branch/main/bootloader).
The software can quickly be adapted to interface with a real primary on-board software instead of
the Python script provided here to upload images because it uses a low-level CCSDS based packet
interface.
## Using the Python image loader
The Python image loader communicates with the Rust flashload application using a dedicated serial
port with a baudrate of 115200.
It is recommended to run the script in a dedicated virtual environment. For example, on UNIX
systems you can use `python3 -m venv venv` and then `source venv/bin/activate` to create
and activate a virtual environment.
After that, you can use
```sh
pip install -r requirements.txt
```
to install all required dependencies.
After that, it is recommended to use `./image-load.py -h` to get an overview of some options.
The flash loader uses the UART0 with the Pins PA8 (RX) and PA9 (TX) interface of the VA108xx to perform CCSDS based
communication. The Python image loader application will search for a file named `loader.toml` and
use the `serial_port` key to determine the serial port to use for serial communication.
### Examples
You can use
```sh
./image-loader.py -p
```
to send a ping an verify the connection.
You can use
```sh
cd flashloader/slot-a-blinky
cargo build --release
cd ../..
./image-loader.py -t a ./slot-a-blinky/target/thumbv6m-none-eabi/release/slot-a-blinky
```
to build the slot A sample application and upload it to a running flash loader application
to write it to slot A.
You can use
```sh
./image-loader.py -s a
```
to select the Slot A as a boot slot. The boot slot is stored in a reserved section in EEPROM
and will be read and used by the bootloader to determine which slot to boot.
You can use
```sh
./image-loader.py -c -t a
```
to corrupt the image A and test that it switches to image B after a failed CRC check instead.

475
flashloader/image-loader.py Executable file
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@ -0,0 +1,475 @@
#!/usr/bin/env python3
from typing import List, Tuple
from spacepackets.ecss.defs import PusService
from spacepackets.ecss.tm import PusTm
from tmtccmd.com import ComInterface
import toml
import struct
import logging
import argparse
import time
import enum
from tmtccmd.com.serial_base import SerialCfg
from tmtccmd.com.serial_cobs import SerialCobsComIF
from tmtccmd.com.ser_utils import prompt_com_port
from crcmod.predefined import PredefinedCrc
from spacepackets.ecss.tc import PusTc
from spacepackets.ecss.pus_verificator import PusVerificator, StatusField
from spacepackets.ecss.pus_1_verification import Service1Tm, UnpackParams
from spacepackets.seqcount import SeqCountProvider
from pathlib import Path
import dataclasses
from elftools.elf.elffile import ELFFile
BAUD_RATE = 115200
BOOTLOADER_START_ADDR = 0x0
BOOTLOADER_END_ADDR = 0x3000
BOOTLOADER_CRC_ADDR = BOOTLOADER_END_ADDR - 2
BOOTLOADER_MAX_SIZE = BOOTLOADER_END_ADDR - BOOTLOADER_START_ADDR - 2
APP_A_START_ADDR = 0x3000
APP_B_END_ADDR = 0x20000 - 8
IMG_SLOT_SIZE = (APP_B_END_ADDR - APP_A_START_ADDR) // 2
APP_A_END_ADDR = APP_A_START_ADDR + IMG_SLOT_SIZE
# The actual size of the image which is relevant for CRC calculation.
APP_A_SIZE_ADDR = APP_A_END_ADDR - 8
APP_A_CRC_ADDR = APP_A_END_ADDR - 4
APP_A_MAX_SIZE = APP_A_END_ADDR - APP_A_START_ADDR - 8
APP_B_START_ADDR = APP_A_END_ADDR
# The actual size of the image which is relevant for CRC calculation.
APP_B_SIZE_ADDR = APP_B_END_ADDR - 8
APP_B_CRC_ADDR = APP_B_END_ADDR - 4
APP_B_MAX_SIZE = APP_A_END_ADDR - APP_A_START_ADDR - 8
CHUNK_SIZE = 400
MEMORY_SERVICE = 6
ACTION_SERVICE = 8
RAW_MEMORY_WRITE_SUBSERVICE = 2
BOOT_NVM_MEMORY_ID = 1
PING_PAYLOAD_SIZE = 0
class ActionId(enum.IntEnum):
CORRUPT_APP_A = 128
CORRUPT_APP_B = 129
SET_BOOT_SLOT = 130
_LOGGER = logging.getLogger(__name__)
SEQ_PROVIDER = SeqCountProvider(bit_width=14)
@dataclasses.dataclass
class LoadableSegment:
name: str
offset: int
size: int
data: bytes
class Target(enum.Enum):
BOOTLOADER = 0
APP_A = 1
APP_B = 2
class AppSel(enum.IntEnum):
APP_A = 0
APP_B = 1
class ImageLoader:
def __init__(self, com_if: ComInterface, verificator: PusVerificator) -> None:
self.com_if = com_if
self.verificator = verificator
def handle_boot_sel_cmd(self, target: AppSel):
_LOGGER.info("Sending ping command")
action_tc = PusTc(
apid=0x00,
service=PusService.S8_FUNC_CMD,
subservice=ActionId.SET_BOOT_SLOT,
seq_count=SEQ_PROVIDER.get_and_increment(),
app_data=bytes([target]),
)
self.verificator.add_tc(action_tc)
self.com_if.send(bytes(action_tc.pack()))
data_available = self.com_if.data_available(0.4)
if not data_available:
_LOGGER.warning("no reply received for boot image selection command")
for reply in self.com_if.receive():
result = self.verificator.add_tm(
Service1Tm.from_tm(PusTm.unpack(reply, 0), UnpackParams(0))
)
if result is not None and result.completed:
_LOGGER.info("received boot image selection command confirmation")
def handle_ping_cmd(self):
_LOGGER.info("Sending ping command")
ping_tc = PusTc(
apid=0x00,
service=PusService.S17_TEST,
subservice=1,
seq_count=SEQ_PROVIDER.get_and_increment(),
app_data=bytes(PING_PAYLOAD_SIZE),
)
self.verificator.add_tc(ping_tc)
self.com_if.send(bytes(ping_tc.pack()))
data_available = self.com_if.data_available(0.4)
if not data_available:
_LOGGER.warning("no ping reply received")
for reply in self.com_if.receive():
result = self.verificator.add_tm(
Service1Tm.from_tm(PusTm.unpack(reply, 0), UnpackParams(0))
)
if result is not None and result.completed:
_LOGGER.info("received ping completion reply")
def handle_corruption_cmd(self, target: Target):
if target == Target.BOOTLOADER:
_LOGGER.error("can not corrupt bootloader")
if target == Target.APP_A:
self.send_tc(
PusTc(
apid=0,
service=ACTION_SERVICE,
subservice=ActionId.CORRUPT_APP_A,
),
)
if target == Target.APP_B:
self.send_tc(
PusTc(
apid=0,
service=ACTION_SERVICE,
subservice=ActionId.CORRUPT_APP_B,
),
)
def handle_flash_cmd(self, target: Target, file_path: Path) -> int:
loadable_segments = []
_LOGGER.info("Parsing ELF file for loadable sections")
total_size = 0
loadable_segments, total_size = create_loadable_segments(target, file_path)
check_segments(target, total_size)
print_segments_info(target, loadable_segments, total_size, file_path)
result = self._perform_flashing_algorithm(loadable_segments)
if result != 0:
return result
self._crc_and_app_size_postprocessing(target, total_size, loadable_segments)
return 0
def _perform_flashing_algorithm(
self,
loadable_segments: List[LoadableSegment],
) -> int:
# Perform the flashing algorithm.
for segment in loadable_segments:
segment_end = segment.offset + segment.size
current_addr = segment.offset
pos_in_segment = 0
while pos_in_segment < segment.size:
next_chunk_size = min(segment_end - current_addr, CHUNK_SIZE)
data = segment.data[pos_in_segment : pos_in_segment + next_chunk_size]
next_packet = pack_memory_write_command(current_addr, data)
_LOGGER.info(
f"Sending memory write command for address {current_addr:#08x} and data with "
f"length {len(data)}"
)
self.verificator.add_tc(next_packet)
self.com_if.send(bytes(next_packet.pack()))
current_addr += next_chunk_size
pos_in_segment += next_chunk_size
start_time = time.time()
while True:
if time.time() - start_time > 1.0:
_LOGGER.error("Timeout while waiting for reply")
return -1
data_available = self.com_if.data_available(0.1)
done = False
if not data_available:
continue
replies = self.com_if.receive()
for reply in replies:
tm = PusTm.unpack(reply, 0)
if tm.service != 1:
continue
service_1_tm = Service1Tm.from_tm(tm, UnpackParams(0))
check_result = self.verificator.add_tm(service_1_tm)
# We could send after we have received the step reply, but that can
# somehow lead to overrun errors. I think it's okay to do it like
# this as long as the flash loader only uses polling..
if (
check_result is not None
and check_result.status.completed == StatusField.SUCCESS
):
done = True
# This is an optimized variant, but I think the small delay is not an issue.
"""
if (
check_result is not None
and check_result.status.step == StatusField.SUCCESS
and len(check_result.status.step_list) == 1
):
done = True
"""
self.verificator.remove_completed_entries()
if done:
break
return 0
def _crc_and_app_size_postprocessing(
self,
target: Target,
total_size: int,
loadable_segments: List[LoadableSegment],
):
if target == Target.BOOTLOADER:
_LOGGER.info("Blanking the bootloader checksum")
# Blank the checksum. For the bootloader, the bootloader will calculate the
# checksum itself on the initial run.
checksum_write_packet = pack_memory_write_command(
BOOTLOADER_CRC_ADDR, bytes([0x00, 0x00])
)
self.send_tc(checksum_write_packet)
else:
crc_addr = None
size_addr = None
if target == Target.APP_A:
crc_addr = APP_A_CRC_ADDR
size_addr = APP_A_SIZE_ADDR
elif target == Target.APP_B:
crc_addr = APP_B_CRC_ADDR
size_addr = APP_B_SIZE_ADDR
assert crc_addr is not None
assert size_addr is not None
_LOGGER.info(f"Writing app size {total_size} at address {size_addr:#08x}")
size_write_packet = pack_memory_write_command(
size_addr, struct.pack("!I", total_size)
)
self.com_if.send(bytes(size_write_packet.pack()))
time.sleep(0.2)
crc_calc = PredefinedCrc("crc-ccitt-false")
for segment in loadable_segments:
crc_calc.update(segment.data)
checksum = crc_calc.digest()
_LOGGER.info(
f"Writing checksum 0x[{checksum.hex(sep=',')}] at address {crc_addr:#08x}"
)
self.send_tc(pack_memory_write_command(crc_addr, checksum))
def send_tc(self, tc: PusTc):
self.com_if.send(bytes(tc.pack()))
def main() -> int:
print("Python VA108XX Image Loader Application")
logging.basicConfig(
format="[%(asctime)s] [%(levelname)s] %(message)s", level=logging.DEBUG
)
parser = argparse.ArgumentParser(
prog="image-loader", description="Python VA416XX Image Loader Application"
)
parser.add_argument("-p", "--ping", action="store_true", help="Send ping command")
parser.add_argument(
"-s", "--sel", choices=["a", "b"], help="Set boot slot (Slot A or B)"
)
parser.add_argument("-c", "--corrupt", action="store_true", help="Corrupt a target")
parser.add_argument(
"-t",
"--target",
choices=["bl", "a", "b"],
help="Target (Bootloader or slot A or B)",
)
parser.add_argument(
"path", nargs="?", default=None, help="Path to the App to flash"
)
args = parser.parse_args()
serial_port = None
if Path("loader.toml").exists():
with open("loader.toml", "r") as toml_file:
parsed_toml = toml.loads(toml_file.read())
if "serial_port" in parsed_toml:
serial_port = parsed_toml["serial_port"]
if serial_port is None:
serial_port = prompt_com_port()
serial_cfg = SerialCfg(
com_if_id="ser_cobs",
serial_port=serial_port,
baud_rate=BAUD_RATE,
serial_timeout=0.1,
)
verificator = PusVerificator()
com_if = SerialCobsComIF(serial_cfg)
com_if.open()
target = None
if args.target == "bl":
target = Target.BOOTLOADER
elif args.target == "a":
target = Target.APP_A
elif args.target == "b":
target = Target.APP_B
boot_sel = None
if args.sel:
if args.sel == "a":
boot_sel = AppSel.APP_A
elif args.sel == "b":
boot_sel = AppSel.APP_B
image_loader = ImageLoader(com_if, verificator)
file_path = None
result = -1
if args.ping:
image_loader.handle_ping_cmd()
com_if.close()
return 0
if args.sel and boot_sel is not None:
image_loader.handle_boot_sel_cmd(boot_sel)
if target:
if not args.corrupt:
if not args.path:
_LOGGER.error("App Path needs to be specified for the flash process")
file_path = Path(args.path)
if not file_path.exists():
_LOGGER.error("File does not exist")
if args.corrupt:
if not target:
_LOGGER.error("target for corruption command required")
com_if.close()
return -1
image_loader.handle_corruption_cmd(target)
else:
if file_path is not None:
assert target is not None
result = image_loader.handle_flash_cmd(target, file_path)
com_if.close()
return result
def create_loadable_segments(
target: Target, file_path: Path
) -> Tuple[List[LoadableSegment], int]:
loadable_segments = []
total_size = 0
with open(file_path, "rb") as app_file:
elf_file = ELFFile(app_file)
for idx, segment in enumerate(elf_file.iter_segments("PT_LOAD")):
if segment.header.p_filesz == 0:
continue
# Basic validity checks of the base addresses.
if idx == 0:
if (
target == Target.BOOTLOADER
and segment.header.p_paddr != BOOTLOADER_START_ADDR
):
raise ValueError(
f"detected possibly invalid start address {segment.header.p_paddr:#08x} for "
f"bootloader, expected {BOOTLOADER_START_ADDR}"
)
if (
target == Target.APP_A
and segment.header.p_paddr != APP_A_START_ADDR
):
raise ValueError(
f"detected possibly invalid start address {segment.header.p_paddr:#08x} for "
f"App A, expected {APP_A_START_ADDR}"
)
if (
target == Target.APP_B
and segment.header.p_paddr != APP_B_START_ADDR
):
raise ValueError(
f"detected possibly invalid start address {segment.header.p_paddr:#08x} for "
f"App B, expected {APP_B_START_ADDR}"
)
name = None
for section in elf_file.iter_sections():
if (
section.header.sh_offset == segment.header.p_offset
and section.header.sh_size > 0
):
name = section.name
if name is None:
_LOGGER.warning("no fitting section found for segment")
continue
# print(f"Segment Addr: {segment.header.p_paddr}")
# print(f"Segment Offset: {segment.header.p_offset}")
# print(f"Segment Filesize: {segment.header.p_filesz}")
loadable_segments.append(
LoadableSegment(
name=name,
offset=segment.header.p_paddr,
size=segment.header.p_filesz,
data=segment.data(),
)
)
total_size += segment.header.p_filesz
return loadable_segments, total_size
def check_segments(
target: Target,
total_size: int,
):
# Set context string and perform basic sanity checks.
if target == Target.BOOTLOADER and total_size > BOOTLOADER_MAX_SIZE:
raise ValueError(
f"provided bootloader app larger than allowed {total_size} bytes"
)
elif target == Target.APP_A and total_size > APP_A_MAX_SIZE:
raise ValueError(f"provided App A larger than allowed {total_size} bytes")
elif target == Target.APP_B and total_size > APP_B_MAX_SIZE:
raise ValueError(f"provided App B larger than allowed {total_size} bytes")
def print_segments_info(
target: Target,
loadable_segments: List[LoadableSegment],
total_size: int,
file_path: Path,
):
# Set context string and perform basic sanity checks.
if target == Target.BOOTLOADER:
context_str = "Bootloader"
elif target == Target.APP_A:
context_str = "App Slot A"
elif target == Target.APP_B:
context_str = "App Slot B"
_LOGGER.info(f"Flashing {context_str} with image {file_path} (size {total_size})")
for idx, segment in enumerate(loadable_segments):
_LOGGER.info(
f"Loadable section {idx} {segment.name} with offset {segment.offset:#08x} and "
f"size {segment.size}"
)
def pack_memory_write_command(addr: int, data: bytes) -> PusTc:
app_data = bytearray()
app_data.append(BOOT_NVM_MEMORY_ID)
# N parameter is always 1 here.
app_data.append(1)
app_data.extend(struct.pack("!I", addr))
app_data.extend(struct.pack("!I", len(data)))
app_data.extend(data)
return PusTc(
apid=0,
service=MEMORY_SERVICE,
subservice=RAW_MEMORY_WRITE_SUBSERVICE,
seq_count=SEQ_PROVIDER.get_and_increment(),
app_data=bytes(app_data),
)
if __name__ == "__main__":
main()

1
flashloader/loader.toml Normal file
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@ -0,0 +1 @@
serial_port = "/dev/ttyUSB0"

5
flashloader/requirements.txt Normal file
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@ -0,0 +1,5 @@
spacepackets == 0.24
tmtccmd == 8.0.2
toml == 0.10
pyelftools == 0.31
crcmod == 1.7

2
flashloader/slot-a-blinky/.gitignore vendored Normal file
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@ -0,0 +1,2 @@
/target
/app.map

42
flashloader/slot-a-blinky/Cargo.toml Normal file
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@ -0,0 +1,42 @@
[package]
name = "slot-a-blinky"
version = "0.1.0"
edition = "2021"
[workspace]
[dependencies]
cortex-m-rt = "0.7"
panic-rtt-target = { version = "0.1.3" }
rtt-target = { version = "0.5" }
cortex-m = { version = "0.7", features = ["critical-section-single-core"] }
embedded-hal = "1"
va108xx-hal = { path = "../../va108xx-hal" }
[profile.dev]
codegen-units = 1
debug = 2
debug-assertions = true # <-
incremental = false
# This is problematic for stepping..
# opt-level = 'z' # <-
overflow-checks = true # <-
# cargo build/run --release
[profile.release]
codegen-units = 1
debug = 2
debug-assertions = false # <-
incremental = false
lto = 'fat'
opt-level = 3 # <-
overflow-checks = false # <-
[profile.small]
inherits = "release"
codegen-units = 1
debug-assertions = false # <-
lto = true
opt-level = 'z' # <-
overflow-checks = false # <-
# strip = true # Automatically strip symbols from the binary.

11
flashloader/slot-a-blinky/memory.x Normal file
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@ -0,0 +1,11 @@
/* Special linker script for application slot A with an offset at address 0x3000 */
MEMORY
{
FLASH : ORIGIN = 0x00003000, LENGTH = 0xE7FC
RAM : ORIGIN = 0x10000000, LENGTH = 0x08000 /* 32K */
}
/* This is where the call stack will be allocated. */
/* The stack is of the full descending type. */
/* NOTE Do NOT modify `_stack_start` unless you know what you are doing */
_stack_start = ORIGIN(RAM) + LENGTH(RAM);

25
flashloader/slot-a-blinky/src/main.rs Normal file
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@ -0,0 +1,25 @@
//! Simple blinky example using the HAL
#![no_main]
#![no_std]
use cortex_m_rt::entry;
use embedded_hal::{delay::DelayNs, digital::StatefulOutputPin};
use panic_rtt_target as _;
use rtt_target::{rprintln, rtt_init_print};
use va108xx_hal::{gpio::PinsA, pac, prelude::*, timer::CountdownTimer};
#[entry]
fn main() -> ! {
rtt_init_print!();
rprintln!("VA108xx HAL blinky example for App Slot A");
let mut dp = pac::Peripherals::take().unwrap();
let mut timer = CountdownTimer::new(&mut dp.sysconfig, 50.MHz(), dp.tim0);
let porta = PinsA::new(&mut dp.sysconfig, Some(dp.ioconfig), dp.porta);
let mut led1 = porta.pa10.into_readable_push_pull_output();
loop {
led1.toggle().ok();
timer.delay_ms(500);
}
}

2
flashloader/slot-b-blinky/.gitignore vendored Normal file
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@ -0,0 +1,2 @@
/target
/app.map

42
flashloader/slot-b-blinky/Cargo.toml Normal file
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@ -0,0 +1,42 @@
[package]
name = "slot-b-blinky"
version = "0.1.0"
edition = "2021"
[workspace]
[dependencies]
cortex-m-rt = "0.7"
panic-rtt-target = { version = "0.1.3" }
rtt-target = { version = "0.5" }
cortex-m = { version = "0.7", features = ["critical-section-single-core"] }
embedded-hal = "1"
va108xx-hal = { path = "../../va108xx-hal" }
[profile.dev]
codegen-units = 1
debug = 2
debug-assertions = true # <-
incremental = false
# This is problematic for stepping..
# opt-level = 'z' # <-
overflow-checks = true # <-
# cargo build/run --release
[profile.release]
codegen-units = 1
debug = 2
debug-assertions = false # <-
incremental = false
lto = 'fat'
opt-level = 3 # <-
overflow-checks = false # <-
[profile.small]
inherits = "release"
codegen-units = 1
debug-assertions = false # <-
lto = true
opt-level = 'z' # <-
overflow-checks = false # <-
# strip = true # Automatically strip symbols from the binary.

11
flashloader/slot-b-blinky/memory.x Normal file
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@ -0,0 +1,11 @@
/* Special linker script for application slot B */
MEMORY
{
FLASH : ORIGIN = 0x000117FC, LENGTH = 0xE7FC
RAM : ORIGIN = 0x10000000, LENGTH = 0x08000 /* 32K */
}
/* This is where the call stack will be allocated. */
/* The stack is of the full descending type. */
/* NOTE Do NOT modify `_stack_start` unless you know what you are doing */
_stack_start = ORIGIN(RAM) + LENGTH(RAM);

25
flashloader/slot-b-blinky/src/main.rs Normal file
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@ -0,0 +1,25 @@
//! Simple blinky example using the HAL
#![no_main]
#![no_std]
use cortex_m_rt::entry;
use embedded_hal::{delay::DelayNs, digital::StatefulOutputPin};
use panic_rtt_target as _;
use rtt_target::{rprintln, rtt_init_print};
use va108xx_hal::{gpio::PinsA, pac, prelude::*, timer::CountdownTimer};
#[entry]
fn main() -> ! {
rtt_init_print!();
rprintln!("VA108xx HAL blinky example for App Slot B");
let mut dp = pac::Peripherals::take().unwrap();
let mut timer = CountdownTimer::new(&mut dp.sysconfig, 50.MHz(), dp.tim0);
let porta = PinsA::new(&mut dp.sysconfig, Some(dp.ioconfig), dp.porta);
let mut led2 = porta.pa7.into_readable_push_pull_output();
loop {
led2.toggle().ok();
timer.delay_ms(1000);
}
}

9
flashloader/src/lib.rs Normal file
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@ -0,0 +1,9 @@
#![no_std]
#[cfg(test)]
mod tests {
#[test]
fn simple() {
assert_eq!(1 + 1, 2);
}
}

468
flashloader/src/main.rs Normal file
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@ -0,0 +1,468 @@
//! Vorago flashloader which can be used to flash image A and image B via a simple
//! low-level CCSDS memory interface via a UART interface.
#![no_main]
#![no_std]
use num_enum::TryFromPrimitive;
use panic_rtt_target as _;
use ringbuf::{
traits::{Consumer, Observer, Producer},
StaticRb,
};
use va108xx_hal::prelude::*;
const SYSCLK_FREQ: Hertz = Hertz::from_raw(50_000_000);
const MAX_TC_SIZE: usize = 524;
const MAX_TC_FRAME_SIZE: usize = cobs::max_encoding_length(MAX_TC_SIZE);
const MAX_TM_SIZE: usize = 128;
const MAX_TM_FRAME_SIZE: usize = cobs::max_encoding_length(MAX_TM_SIZE);
const UART_BAUDRATE: u32 = 115200;
const BOOT_NVM_MEMORY_ID: u8 = 1;
const RX_DEBUGGING: bool = false;
pub enum ActionId {
CorruptImageA = 128,
CorruptImageB = 129,
SetBootSlot = 130,
}
#[derive(Debug, Copy, Clone, PartialEq, Eq, TryFromPrimitive)]
#[repr(u8)]
enum AppSel {
A = 0,
B = 1,
}
// Larger buffer for TC to be able to hold the possibly large memory write packets.
const BUF_RB_SIZE_TC: usize = 1024;
const SIZES_RB_SIZE_TC: usize = 16;
const BUF_RB_SIZE_TM: usize = 256;
const SIZES_RB_SIZE_TM: usize = 16;
pub struct RingBufWrapper<const BUF_SIZE: usize, const SIZES_LEN: usize> {
pub buf: StaticRb<u8, BUF_SIZE>,
pub sizes: StaticRb<usize, SIZES_LEN>,
}
pub const APP_A_START_ADDR: u32 = 0x3000;
pub const APP_A_END_ADDR: u32 = 0x117FC;
pub const APP_B_START_ADDR: u32 = APP_A_END_ADDR;
pub const APP_B_END_ADDR: u32 = 0x20000;
pub const PREFERRED_SLOT_OFFSET: u32 = 0x20000 - 1;
#[rtic::app(device = pac, dispatchers = [OC20, OC21, OC22])]
mod app {
use super::*;
use cortex_m::asm;
use embedded_io::Write;
use panic_rtt_target as _;
use rtic::Mutex;
use rtic_monotonics::systick::prelude::*;
use rtt_target::rprintln;
use satrs::pus::verification::{FailParams, VerificationReportCreator};
use spacepackets::ecss::PusServiceId;
use spacepackets::ecss::{
tc::PusTcReader, tm::PusTmCreator, EcssEnumU8, PusPacket, WritablePusPacket,
};
use va108xx_hal::gpio::PinsA;
use va108xx_hal::uart::IrqContextTimeoutOrMaxSize;
use va108xx_hal::{pac, uart, InterruptConfig};
use vorago_reb1::m95m01::M95M01;
#[derive(Default, Debug, Copy, Clone, PartialEq, Eq)]
pub enum CobsReaderStates {
#[default]
WaitingForStart,
WatingForEnd,
FrameOverflow,
}
#[local]
struct Local {
uart_rx: uart::RxWithInterrupt<pac::Uarta>,
uart_tx: uart::Tx<pac::Uarta>,
rx_context: IrqContextTimeoutOrMaxSize,
verif_reporter: VerificationReportCreator,
nvm: M95M01,
}
#[shared]
struct Shared {
// Having this shared allows multiple tasks to generate telemetry.
tm_rb: RingBufWrapper<BUF_RB_SIZE_TM, SIZES_RB_SIZE_TM>,
tc_rb: RingBufWrapper<BUF_RB_SIZE_TC, SIZES_RB_SIZE_TC>,
}
rtic_monotonics::systick_monotonic!(Mono, 1000);
#[init]
fn init(cx: init::Context) -> (Shared, Local) {
rtt_log::init();
rprintln!("-- Vorago flashloader --");
Mono::start(cx.core.SYST, SYSCLK_FREQ.raw());
let mut dp = cx.device;
let nvm = M95M01::new(&mut dp.sysconfig, SYSCLK_FREQ, dp.spic);
let gpioa = PinsA::new(&mut dp.sysconfig, dp.porta);
let tx = gpioa.pa9.into_funsel_2();
let rx = gpioa.pa8.into_funsel_2();
let irq_uart = uart::Uart::new_with_interrupt(
&mut dp.sysconfig,
SYSCLK_FREQ,
dp.uarta,
(tx, rx),
UART_BAUDRATE.Hz(),
InterruptConfig::new(pac::Interrupt::OC0, true, true),
);
let (tx, rx) = irq_uart.split();
// Unwrap is okay, we explicitely set the interrupt ID.
let mut rx = rx.into_rx_with_irq();
let verif_reporter = VerificationReportCreator::new(0).unwrap();
let mut rx_context = IrqContextTimeoutOrMaxSize::new(MAX_TC_FRAME_SIZE);
rx.read_fixed_len_or_timeout_based_using_irq(&mut rx_context)
.expect("initiating UART RX failed");
pus_tc_handler::spawn().unwrap();
pus_tm_tx_handler::spawn().unwrap();
(
Shared {
tc_rb: RingBufWrapper {
buf: StaticRb::default(),
sizes: StaticRb::default(),
},
tm_rb: RingBufWrapper {
buf: StaticRb::default(),
sizes: StaticRb::default(),
},
},
Local {
uart_rx: rx,
uart_tx: tx,
rx_context,
verif_reporter,
nvm,
},
)
}
// `shared` cannot be accessed from this context
#[idle]
fn idle(_cx: idle::Context) -> ! {
loop {
asm::nop();
}
}
// This is the interrupt handler to read all bytes received on the UART0.
#[task(
binds = OC0,
local = [
cnt: u32 = 0,
rx_buf: [u8; MAX_TC_FRAME_SIZE] = [0; MAX_TC_FRAME_SIZE],
rx_context,
uart_rx,
],
shared = [tc_rb]
)]
fn uart_rx_irq(mut cx: uart_rx_irq::Context) {
match cx
.local
.uart_rx
.on_interrupt_max_size_or_timeout_based(cx.local.rx_context, cx.local.rx_buf)
{
Ok(result) => {
if RX_DEBUGGING {
log::debug!("RX Info: {:?}", cx.local.rx_context);
log::debug!("RX Result: {:?}", result);
}
if result.complete() {
// Check frame validity (must have COBS format) and decode the frame.
// Currently, we expect a full frame or a frame received through a timeout
// to be one COBS frame. We could parse for multiple COBS packets in one
// frame, but the additional complexity is not necessary here..
if cx.local.rx_buf[0] == 0 && cx.local.rx_buf[result.bytes_read - 1] == 0 {
let decoded_size =
cobs::decode_in_place(&mut cx.local.rx_buf[1..result.bytes_read]);
if decoded_size.is_err() {
log::warn!("COBS decoding failed");
} else {
let decoded_size = decoded_size.unwrap();
let mut tc_rb_full = false;
cx.shared.tc_rb.lock(|rb| {
if rb.sizes.vacant_len() >= 1 && rb.buf.vacant_len() >= decoded_size
{
rb.sizes.try_push(decoded_size).unwrap();
rb.buf.push_slice(&cx.local.rx_buf[1..1 + decoded_size]);
} else {
tc_rb_full = true;
}
});
if tc_rb_full {
log::warn!("COBS TC queue full");
}
}
} else {
log::warn!("COBS frame with invalid format, start and end bytes are not 0");
}
// Initiate next transfer.
cx.local
.uart_rx
.read_fixed_len_or_timeout_based_using_irq(cx.local.rx_context)
.expect("read operation failed");
}
if result.has_errors() {
log::warn!("UART error: {:?}", result.errors.unwrap());
}
}
Err(e) => {
log::warn!("UART error: {:?}", e);
}
}
}
#[task(
priority = 2,
local=[
tc_buf: [u8; MAX_TC_SIZE] = [0; MAX_TC_SIZE],
readback_buf: [u8; MAX_TC_SIZE] = [0; MAX_TC_SIZE],
src_data_buf: [u8; 16] = [0; 16],
verif_buf: [u8; 32] = [0; 32],
nvm,
verif_reporter
],
shared=[tm_rb, tc_rb]
)]
async fn pus_tc_handler(mut cx: pus_tc_handler::Context) {
loop {
// Try to read a TC from the ring buffer.
let packet_len = cx.shared.tc_rb.lock(|rb| rb.sizes.try_pop());
if packet_len.is_none() {
// Small delay, TCs might arrive very quickly.
Mono::delay(20.millis()).await;
continue;
}
let packet_len = packet_len.unwrap();
log::info!(target: "TC Handler", "received packet with length {}", packet_len);
let popped_packet_len = cx
.shared
.tc_rb
.lock(|rb| rb.buf.pop_slice(&mut cx.local.tc_buf[0..packet_len]));
assert_eq!(popped_packet_len, packet_len);
// Read a telecommand, now handle it.
handle_valid_pus_tc(&mut cx);
}
}
fn handle_valid_pus_tc(cx: &mut pus_tc_handler::Context) {
let pus_tc = PusTcReader::new(cx.local.tc_buf);
if pus_tc.is_err() {
log::warn!(target: "TC Handler", "PUS TC error: {}", pus_tc.unwrap_err());
return;
}
let (pus_tc, _) = pus_tc.unwrap();
let mut write_and_send = |tm: &PusTmCreator| {
let written_size = tm.write_to_bytes(cx.local.verif_buf).unwrap();
cx.shared.tm_rb.lock(|prod| {
prod.sizes.try_push(tm.len_written()).unwrap();
prod.buf.push_slice(&cx.local.verif_buf[0..written_size]);
});
};
let token = cx.local.verif_reporter.add_tc(&pus_tc);
let (tm, accepted_token) = cx
.local
.verif_reporter
.acceptance_success(cx.local.src_data_buf, token, 0, 0, &[])
.expect("acceptance success failed");
write_and_send(&tm);
let (tm, started_token) = cx
.local
.verif_reporter
.start_success(cx.local.src_data_buf, accepted_token, 0, 0, &[])
.expect("acceptance success failed");
write_and_send(&tm);
if pus_tc.service() == PusServiceId::Action as u8 {
let mut corrupt_image = |base_addr: u32| {
let mut buf = [0u8; 4];
cx.local
.nvm
.read(base_addr as usize + 32, &mut buf)
.expect("reading from NVM failed");
buf[0] += 1;
cx.local
.nvm
.write(base_addr as usize + 32, &buf)
.expect("writing to NVM failed");
let tm = cx
.local
.verif_reporter
.completion_success(cx.local.src_data_buf, started_token, 0, 0, &[])
.expect("completion success failed");
write_and_send(&tm);
};
if pus_tc.subservice() == ActionId::CorruptImageA as u8 {
rprintln!("corrupting App Image A");
corrupt_image(APP_A_START_ADDR);
}
if pus_tc.subservice() == ActionId::CorruptImageB as u8 {
rprintln!("corrupting App Image B");
corrupt_image(APP_B_START_ADDR);
}
if pus_tc.subservice() == ActionId::SetBootSlot as u8 {
if pus_tc.app_data().is_empty() {
log::warn!(target: "TC Handler", "App data for preferred image command too short");
}
let app_sel_result = AppSel::try_from(pus_tc.app_data()[0]);
if app_sel_result.is_err() {
log::warn!("Invalid app selection value: {}", pus_tc.app_data()[0]);
}
log::info!(target: "TC Handler", "received boot selection command with app select: {:?}", app_sel_result.unwrap());
cx.local
.nvm
.write(PREFERRED_SLOT_OFFSET as usize, &[pus_tc.app_data()[0]])
.expect("writing to NVM failed");
let tm = cx
.local
.verif_reporter
.completion_success(cx.local.src_data_buf, started_token, 0, 0, &[])
.expect("completion success failed");
write_and_send(&tm);
}
}
if pus_tc.service() == PusServiceId::Test as u8 && pus_tc.subservice() == 1 {
log::info!(target: "TC Handler", "received ping TC");
let tm = cx
.local
.verif_reporter
.completion_success(cx.local.src_data_buf, started_token, 0, 0, &[])
.expect("completion success failed");
write_and_send(&tm);
} else if pus_tc.service() == PusServiceId::MemoryManagement as u8 {
let tm = cx
.local
.verif_reporter
.step_success(
cx.local.src_data_buf,
&started_token,
0,
0,
&[],
EcssEnumU8::new(0),
)
.expect("step success failed");
write_and_send(&tm);
// Raw memory write TC
if pus_tc.subservice() == 2 {
let app_data = pus_tc.app_data();
if app_data.len() < 10 {
log::warn!(
target: "TC Handler",
"app data for raw memory write is too short: {}",
app_data.len()
);
}
let memory_id = app_data[0];
if memory_id != BOOT_NVM_MEMORY_ID {
log::warn!(target: "TC Handler", "memory ID {} not supported", memory_id);
// TODO: Error reporting
return;
}
let offset = u32::from_be_bytes(app_data[2..6].try_into().unwrap());
let data_len = u32::from_be_bytes(app_data[6..10].try_into().unwrap());
if 10 + data_len as usize > app_data.len() {
log::warn!(
target: "TC Handler",
"invalid data length {} for raw mem write detected",
data_len
);
// TODO: Error reporting
return;
}
let data = &app_data[10..10 + data_len as usize];
log::info!(
target: "TC Handler",
"writing {} bytes at offset {} to NVM",
data_len,
offset
);
cx.local
.nvm
.write(offset as usize, data)
.expect("writing to NVM failed");
let tm = if !cx
.local
.nvm
.verify(offset as usize, data)
.expect("NVM verification failed")
{
log::warn!("verification of data written to NVM failed");
cx.local
.verif_reporter
.completion_failure(
cx.local.src_data_buf,
started_token,
0,
0,
FailParams::new(&[], &EcssEnumU8::new(0), &[]),
)
.expect("completion success failed")
} else {
cx.local
.verif_reporter
.completion_success(cx.local.src_data_buf, started_token, 0, 0, &[])
.expect("completion success failed")
};
write_and_send(&tm);
log::info!(
target: "TC Handler",
"NVM operation done");
}
}
}
#[task(
priority = 1,
local=[
read_buf: [u8;MAX_TM_SIZE] = [0; MAX_TM_SIZE],
encoded_buf: [u8;MAX_TM_FRAME_SIZE] = [0; MAX_TM_FRAME_SIZE],
uart_tx,
],
shared=[tm_rb]
)]
async fn pus_tm_tx_handler(mut cx: pus_tm_tx_handler::Context) {
loop {
let mut occupied_len = cx.shared.tm_rb.lock(|rb| rb.sizes.occupied_len());
while occupied_len > 0 {
let next_size = cx.shared.tm_rb.lock(|rb| {
let next_size = rb.sizes.try_pop().unwrap();
rb.buf.pop_slice(&mut cx.local.read_buf[0..next_size]);
next_size
});
cx.local.encoded_buf[0] = 0;
let send_size = cobs::encode(
&cx.local.read_buf[0..next_size],
&mut cx.local.encoded_buf[1..],
);
cx.local.encoded_buf[send_size + 1] = 0;
cx.local
.uart_tx
.write(&cx.local.encoded_buf[0..send_size + 2])
.unwrap();
occupied_len -= 1;
Mono::delay(2.millis()).await;
}
Mono::delay(50.millis()).await;
}
}
}

2
jlink-gdb.sh
View File

@ -1,3 +1,3 @@
#!/bin/bash
JLinkGDBServer -select USB -device Cortex-M0 -endian little -if JTAG-speed auto \
JLinkGDBServer -select USB -device Cortex-M0 -endian little -if JTAG -speed auto \
-LocalhostOnly

35
scripts/VA108xx_Series.yaml
View File

@ -9,27 +9,56 @@ variants:
core_access_options: !Arm
ap: 0
psel: 0x0
jtag_tap: 1
memory_map:
- !Ram
name: IRAM1
name: DRAM
range:
start: 0x10000000
end: 0x10008000
cores:
- main
- !Nvm
name: IROM1
name: NVM
range:
start: 0x0
end: 0x20000
is_boot_memory: true
cores:
- main
access:
write: false
boot: true
flash_algorithms:
- va108xx_fm25v20a_fram_128kb_prog
- va108xx_m95m01_128kb_prog
- va108xx_mr25h10_1mb_prog
- va108xx_ttflash_prog
- name: VA108xx_RAM
cores:
- name: main
type: armv6m
core_access_options: !Arm
ap: 0
psel: 0x0
jtag_tap: 1
memory_map:
- !Ram
name: DRAM
range:
start: 0x10000000
end: 0x10008000
cores:
- main
- !Ram
name: IRAM
range:
start: 0x0
end: 0x20000
cores:
- main
access:
write: false
boot: true
flash_algorithms:
- name: va108xx_fm25v20a_fram_128kb_prog
description: VA108_FM25V20A_FRAM_128KB

10
scripts/memory_app_a.x Normal file
View File

@ -0,0 +1,10 @@
MEMORY
{
FLASH : ORIGIN = 0x00003000, LENGTH = 0xE7F8 /* (128k - 12k) / 2 - 8 */
RAM : ORIGIN = 0x10000000, LENGTH = 0x08000 /* 32K */
}
/* This is where the call stack will be allocated. */
/* The stack is of the full descending type. */
/* NOTE Do NOT modify `_stack_start` unless you know what you are doing */
_stack_start = ORIGIN(RAM) + LENGTH(RAM);

10
scripts/memory_app_b.x Normal file
View File

@ -0,0 +1,10 @@
MEMORY
{
FLASH : ORIGIN = 0x00011800, LENGTH = 0xE7F8 /* (128k - 12k) / 2 - 8 */
RAM : ORIGIN = 0x10000000, LENGTH = 0x08000 /* 32K */
}
/* This is where the call stack will be allocated. */
/* The stack is of the full descending type. */
/* NOTE Do NOT modify `_stack_start` unless you know what you are doing */
_stack_start = ORIGIN(RAM) + LENGTH(RAM);

27
va108xx-embassy/Cargo.toml Normal file
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@ -0,0 +1,27 @@
[package]
name = "va108xx-embassy"
version = "0.1.0"
edition = "2021"
[dependencies]
critical-section = "1"
portable-atomic = { version = "1", features = ["unsafe-assume-single-core"]}
embassy-sync = "0.6"
embassy-executor = "0.7"
embassy-time-driver = "0.2"
embassy-time-queue-utils = "0.1"
once_cell = { version = "1", default-features = false, features = ["critical-section"] }
[dependencies.va108xx-hal]
path = "../va108xx-hal"
[features]
default = ["irq-oc30-oc31"]
irqs-in-lib = []
# This determines the reserved interrupt functions for the embassy time drivers. Only one
# is allowed to be selected!
irq-oc28-oc29 = ["irqs-in-lib"]
irq-oc29-oc30 = ["irqs-in-lib"]
irq-oc30-oc31 = ["irqs-in-lib"]

10
va108xx-embassy/README.md Normal file
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@ -0,0 +1,10 @@
[![Crates.io](https://img.shields.io/crates/v/va108xx-embassy)](https://crates.io/crates/va108xx-embassy)
[![docs.rs](https://img.shields.io/docsrs/va108xx-embassy)](https://docs.rs/va108xx-embassy)
# Embassy-rs support for the Vorago VA108xx MCU family
This repository contains the [embassy-rs](https://github.com/embassy-rs/embassy) support for the
VA108xx family. Currently, it contains the time driver to allow using embassy-rs. It uses the TIM
peripherals provided by the VA108xx family for this purpose.
The documentation contains more information on how to use this crate.

416
va108xx-embassy/src/lib.rs Normal file
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@ -0,0 +1,416 @@
//! # Embassy-rs support for the Vorago VA108xx MCU family
//!
//! This repository contains the [embassy-rs](https://github.com/embassy-rs/embassy) support for the
//! VA108xx family. Currently, it contains the time driver to allow using embassy-rs. It uses the TIM
//! peripherals provided by the VA108xx family for this purpose.
//!
//! ## Usage
//!
//! This library only exposes the [embassy::init] method which sets up the time driver. This
//! function must be called once at the start of the application.
//!
//! This implementation requires two TIM peripherals provided by the VA108xx device.
//! The user can freely specify the two used TIM peripheral by passing the concrete TIM instances
//! into the [embassy::init_with_custom_irqs] and [embassy::init] method.
//!
//! The application also requires two interrupt handlers to handle the timekeeper and alarm
//! interrupts. By default, this library will define the interrupt handler inside the library
//! itself by using the `irq-oc30-oc31` feature flag. This library exposes three combinations:
//!
//! - `irq-oc30-oc31`: Uses [pac::Interrupt::OC30] and [pac::Interrupt::OC31]
//! - `irq-oc29-oc30`: Uses [pac::Interrupt::OC29] and [pac::Interrupt::OC30]
//! - `irq-oc28-oc29`: Uses [pac::Interrupt::OC28] and [pac::Interrupt::OC20]
//!
//! You can disable the default features and then specify one of the features above to use the
//! documented combination of IRQs. It is also possible to specify custom IRQs by importing and
//! using the [embassy::embassy_time_driver_irqs] macro to declare the IRQ handlers in the
//! application code. If this is done, [embassy::init_with_custom_irqs] must be used
//! method to pass the IRQ numbers to the library.
//!
//! ## Examples
//!
//! [embassy example project](https://egit.irs.uni-stuttgart.de/rust/va108xx-rs/src/branch/main/examples/embassy)
#![no_std]
use core::cell::{Cell, RefCell};
use critical_section::CriticalSection;
use embassy_sync::blocking_mutex::CriticalSectionMutex as Mutex;
use portable_atomic::{AtomicU32, Ordering};
use embassy_time_driver::{time_driver_impl, Driver, TICK_HZ};
use embassy_time_queue_utils::Queue;
use once_cell::sync::OnceCell;
#[cfg(feature = "irqs-in-lib")]
use va108xx_hal::pac::interrupt;
use va108xx_hal::{
clock::enable_peripheral_clock,
enable_nvic_interrupt, pac,
prelude::*,
timer::{enable_tim_clk, get_tim_raw, TimRegInterface},
PeripheralSelect,
};
time_driver_impl!(
static TIME_DRIVER: TimerDriver = TimerDriver {
periods: AtomicU32::new(0),
alarms: Mutex::new(AlarmState::new()),
queue: Mutex::new(RefCell::new(Queue::new())),
});
/// Macro to define the IRQ handlers for the time driver.
///
/// By default, the code generated by this macro will be defined inside the library depending on
/// the feature flags specified. However, the macro is exported to allow users to specify the
/// interrupt handlers themselves.
///
/// Please note that you have to explicitely import the [va108xx_hal::pac::interrupt]
/// macro in the application code in case this macro is used there.
#[macro_export]
macro_rules! embassy_time_driver_irqs {
(
timekeeper_irq = $timekeeper_irq:ident,
alarm_irq = $alarm_irq:ident
) => {
const TIMEKEEPER_IRQ: pac::Interrupt = pac::Interrupt::$timekeeper_irq;
#[interrupt]
#[allow(non_snake_case)]
fn $timekeeper_irq() {
// Safety: We call it once here.
unsafe { $crate::embassy::time_driver().on_interrupt_timekeeping() }
}
const ALARM_IRQ: pac::Interrupt = pac::Interrupt::$alarm_irq;
#[interrupt]
#[allow(non_snake_case)]
fn $alarm_irq() {
// Safety: We call it once here.
unsafe { $crate::embassy::time_driver().on_interrupt_alarm() }
}
};
}
// Provide three combinations of IRQs for the time driver by default.
#[cfg(feature = "irq-oc30-oc31")]
embassy_time_driver_irqs!(timekeeper_irq = OC31, alarm_irq = OC30);
#[cfg(feature = "irq-oc29-oc30")]
embassy_time_driver_irqs!(timekeeper_irq = OC30, alarm_irq = OC29);
#[cfg(feature = "irq-oc28-oc29")]
embassy_time_driver_irqs!(timekeeper_irq = OC29, alarm_irq = OC28);
pub mod embassy {
use super::*;
use va108xx_hal::{pac, timer::TimRegInterface};
/// Expose the time driver so the user can specify the IRQ handlers themselves.
pub fn time_driver() -> &'static TimerDriver {
&TIME_DRIVER
}
/// Initialization method for embassy
///
/// # Safety
///
/// This has to be called once at initialization time to initiate the time driver for
/// embassy.
#[cfg(feature = "irqs-in-lib")]
pub unsafe fn init(
syscfg: &mut pac::Sysconfig,
irqsel: &pac::Irqsel,
sysclk: impl Into<Hertz>,
timekeeper_tim: impl TimRegInterface,
alarm_tim: impl TimRegInterface,
) {
TIME_DRIVER.init(
syscfg,
irqsel,
sysclk,
timekeeper_tim,
alarm_tim,
TIMEKEEPER_IRQ,
ALARM_IRQ,
)
}
/// Initialization method for embassy
///
/// # Safety
///
/// This has to be called once at initialization time to initiate the time driver for
/// embassy.
pub unsafe fn init_with_custom_irqs(
syscfg: &mut pac::Sysconfig,
irqsel: &pac::Irqsel,
sysclk: impl Into<Hertz>,
timekeeper_tim: impl TimRegInterface,
alarm_tim: impl TimRegInterface,
timekeeper_irq: pac::Interrupt,
alarm_irq: pac::Interrupt,
) {
TIME_DRIVER.init(
syscfg,
irqsel,
sysclk,
timekeeper_tim,
alarm_tim,
timekeeper_irq,
alarm_irq,
)
}
}
struct AlarmState {
timestamp: Cell<u64>,
}
impl AlarmState {
const fn new() -> Self {
Self {
timestamp: Cell::new(u64::MAX),
}
}
}
unsafe impl Send for AlarmState {}
static SCALE: OnceCell<u64> = OnceCell::new();
static TIMEKEEPER_TIM: OnceCell<u8> = OnceCell::new();
static ALARM_TIM: OnceCell<u8> = OnceCell::new();
pub struct TimerDriver {
periods: AtomicU32,
/// Timestamp at which to fire alarm. u64::MAX if no alarm is scheduled.
alarms: Mutex<AlarmState>,
queue: Mutex<RefCell<Queue>>,
}
impl TimerDriver {
#[allow(clippy::too_many_arguments)]
fn init(
&self,
syscfg: &mut pac::Sysconfig,
irqsel: &pac::Irqsel,
sysclk: impl Into<Hertz>,
timekeeper_tim: impl TimRegInterface,
alarm_tim: impl TimRegInterface,
timekeeper_irq: pac::Interrupt,
alarm_irq: pac::Interrupt,
) {
if ALARM_TIM.get().is_some() {
return;
}
ALARM_TIM.set(alarm_tim.tim_id()).ok();
TIMEKEEPER_TIM.set(timekeeper_tim.tim_id()).ok();
enable_peripheral_clock(syscfg, PeripheralSelect::Irqsel);
enable_tim_clk(syscfg, timekeeper_tim.tim_id());
let timekeeper_reg_block = timekeeper_tim.reg_block();
let alarm_tim_reg_block = alarm_tim.reg_block();
let sysclk = sysclk.into();
// Initiate scale value here. This is required to convert timer ticks back to a timestamp.
SCALE.set((sysclk.raw() / TICK_HZ as u32) as u64).unwrap();
timekeeper_reg_block
.rst_value()
.write(|w| unsafe { w.bits(u32::MAX) });
// Decrementing counter.
timekeeper_reg_block
.cnt_value()
.write(|w| unsafe { w.bits(u32::MAX) });
// Switch on. Timekeeping should always be done.
irqsel
.tim0(timekeeper_tim.tim_id() as usize)
.write(|w| unsafe { w.bits(timekeeper_irq as u32) });
unsafe {
enable_nvic_interrupt(timekeeper_irq);
}
timekeeper_reg_block
.ctrl()
.modify(|_, w| w.irq_enb().set_bit());
timekeeper_reg_block
.enable()
.write(|w| unsafe { w.bits(1) });
enable_tim_clk(syscfg, alarm_tim.tim_id());
// Explicitely disable alarm timer until needed.
alarm_tim_reg_block.ctrl().modify(|_, w| {
w.irq_enb().clear_bit();
w.enable().clear_bit()
});
// Enable general interrupts. The IRQ enable of the peripheral remains cleared.
unsafe {
enable_nvic_interrupt(alarm_irq);
}
irqsel
.tim0(alarm_tim.tim_id() as usize)
.write(|w| unsafe { w.bits(alarm_irq as u32) });
}
/// Should be called inside the IRQ of the timekeeper timer.
///
/// # Safety
///
/// This function has to be called once by the TIM IRQ used for the timekeeping.
pub unsafe fn on_interrupt_timekeeping(&self) {
self.next_period();
}
/// Should be called inside the IRQ of the alarm timer.
///
/// # Safety
///
///This function has to be called once by the TIM IRQ used for the timekeeping.
pub unsafe fn on_interrupt_alarm(&self) {
critical_section::with(|cs| {
if self.alarms.borrow(cs).timestamp.get() <= self.now() {
self.trigger_alarm(cs)
}
})
}
fn timekeeper_tim() -> &'static pac::tim0::RegisterBlock {
TIMEKEEPER_TIM
.get()
.map(|idx| unsafe { get_tim_raw(*idx as usize) })
.unwrap()
}
fn alarm_tim() -> &'static pac::tim0::RegisterBlock {
ALARM_TIM
.get()
.map(|idx| unsafe { get_tim_raw(*idx as usize) })
.unwrap()
}
fn next_period(&self) {
let period = self.periods.fetch_add(1, Ordering::AcqRel) + 1;
let t = (period as u64) << 32;
critical_section::with(|cs| {
let alarm = &self.alarms.borrow(cs);
let at = alarm.timestamp.get();
if at < t {
self.trigger_alarm(cs);
} else {
let alarm_tim = Self::alarm_tim();
let remaining_ticks = (at - t).checked_mul(*SCALE.get().unwrap());
if remaining_ticks.is_some_and(|v| v <= u32::MAX as u64) {
alarm_tim.enable().write(|w| unsafe { w.bits(0) });
alarm_tim
.cnt_value()
.write(|w| unsafe { w.bits(remaining_ticks.unwrap() as u32) });
alarm_tim.ctrl().modify(|_, w| w.irq_enb().set_bit());
alarm_tim.enable().write(|w| unsafe { w.bits(1) });
}
}
})
}
fn trigger_alarm(&self, cs: CriticalSection) {
Self::alarm_tim().ctrl().modify(|_, w| {
w.irq_enb().clear_bit();
w.enable().clear_bit()
});
let alarm = &self.alarms.borrow(cs);
// Setting the maximum value disables the alarm.
alarm.timestamp.set(u64::MAX);
// Call after clearing alarm, so the callback can set another alarm.
let mut next = self
.queue
.borrow(cs)
.borrow_mut()
.next_expiration(self.now());
while !self.set_alarm(cs, next) {
next = self
.queue
.borrow(cs)
.borrow_mut()
.next_expiration(self.now());
}
}
fn set_alarm(&self, cs: CriticalSection, timestamp: u64) -> bool {
if SCALE.get().is_none() {
return false;
}
let alarm_tim = Self::alarm_tim();
alarm_tim.ctrl().modify(|_, w| {
w.irq_enb().clear_bit();
w.enable().clear_bit()
});
let alarm = self.alarms.borrow(cs);
alarm.timestamp.set(timestamp);
let t = self.now();
if timestamp <= t {
alarm.timestamp.set(u64::MAX);
return false;
}
// If it hasn't triggered yet, setup the relevant reset value, regardless of whether
// the interrupts are enabled or not. When they are enabled at a later point, the
// right value is already set.
// If the timestamp is in the next few ticks, add a bit of buffer to be sure the alarm
// is not missed.
//
// This means that an alarm can be delayed for up to 2 ticks (from t+1 to t+3), but this is allowed
// by the Alarm trait contract. What's not allowed is triggering alarms *before* their scheduled time,
// and we don't do that here.
let safe_timestamp = timestamp.max(t + 3);
let timer_ticks = (safe_timestamp - t).checked_mul(*SCALE.get().unwrap());
alarm_tim.rst_value().write(|w| unsafe { w.bits(u32::MAX) });
if timer_ticks.is_some_and(|v| v <= u32::MAX as u64) {
alarm_tim
.cnt_value()
.write(|w| unsafe { w.bits(timer_ticks.unwrap() as u32) });
alarm_tim.ctrl().modify(|_, w| w.irq_enb().set_bit());
alarm_tim.enable().write(|w| unsafe { w.bits(1) });
}
// If it's too far in the future, don't enable timer yet.
// It will be enabled later by `next_period`.
true
}
}
impl Driver for TimerDriver {
fn now(&self) -> u64 {
if SCALE.get().is_none() {
return 0;
}
let mut period1: u32;
let mut period2: u32;
let mut counter_val: u32;
loop {
// Acquire ensures that we get the latest value of `periods` and
// no instructions can be reordered before the load.
period1 = self.periods.load(Ordering::Acquire);
counter_val = u32::MAX - Self::timekeeper_tim().cnt_value().read().bits();
// Double read to protect against race conditions when the counter is overflowing.
period2 = self.periods.load(Ordering::Relaxed);
if period1 == period2 {
let now = (((period1 as u64) << 32) | counter_val as u64) / *SCALE.get().unwrap();
return now;
}
}
}
fn schedule_wake(&self, at: u64, waker: &core::task::Waker) {
critical_section::with(|cs| {
let mut queue = self.queue.borrow(cs).borrow_mut();
if queue.schedule_wake(at, waker) {
let mut next = queue.next_expiration(self.now());
while !self.set_alarm(cs, next) {
next = queue.next_expiration(self.now());
}
}
})
}
}

73
va108xx-hal/CHANGELOG.md
View File

@ -6,6 +6,79 @@ All notable changes to this project will be documented in this file.
The format is based on [Keep a Changelog](http://keepachangelog.com/)
and this project adheres to [Semantic Versioning](http://semver.org/).
## [unreleased]
## [v0.9.0]
## Fixed
- Important bugfix for UART driver which causes UART B drivers not to work.
## Removed
- Deleted some HAL re-exports in the PWM module
## Changed
- GPIO API: Interrupt, pulse and filter and `set_datamask` and `clear_datamask` APIs are now
methods which mutable modify the pin instead of consuming and returning it.
- Simplified PWM module implementation.
- All error types now implement `core::error::Error` by using the `thiserror::Error` derive.
- `InvalidPinTypeError` now wraps the pin mode.
- I2C `TimingCfg` constructor now returns explicit error instead of generic Error.
Removed the timing configuration error type from the generic I2C error enumeration.
- `PinsA` and `PinsB` constructor do not expect an optional `pac::Ioconfig` argument anymore.
- `IrqCfg` renamed to `InterruptConfig`, kept alias for old name.
- All library provided interrupt handlers now start with common prefix `on_interrupt_*`
- `RxWithIrq` renamed to `RxWithInterrupt`
- `Rx::into_rx_with_irq` does not expect any arguments any more.
- `filter_type` renamed to `configure_filter_type`.
- `level_irq` renamed to `configure_level_interrupt`.
- `edge_irq` renamed to `configure_edge_interrupt`.
- `PinsA` and `PinsB` constructor do not expect an optional IOCONFIG argument anymore.
- UART interrupt management is now handled by the main constructor instead of later stages to
statically ensure one interrupt vector for the UART peripheral. `Uart::new` expects an
optional `InterruptConfig` argument.
- `enable_interrupt` and `disable_interrupt` renamed to `enable_nvic_interrupt` and
`disable_nvic_interrupt` to distinguish them from peripheral interrupts more clearly.
- `port_mux` renamed to `port_function_select`
- Renamed `IrqUartErrors` to `UartErrors`.
## Added
- Add `downgrade` method for `Pin` and `upgrade` method for `DynPin` as explicit conversion
methods.
- Asynchronous GPIO support.
- Asynchronous UART TX support.
- Asynchronous UART RX support.
- Add new `get_tim_raw` unsafe method to retrieve TIM peripheral blocks.
- `Uart::with_with_interrupt` and `Uart::new_without_interrupt`
## [v0.8.0] 2024-09-30
## Changed
- Improves `CascardSource` handling and general API when chosing cascade sources.
- Replaced `utility::unmask_irq` by `enable_interrupt` and `disable_interrupt` API.
- Improve and fix SPI abstractions. Add new low level interface. The primary SPI constructor now
only expects a configuration structure and the transfer configuration needs to be applied in a
separate step.
- Removed complete `timer` module re-export in `pwm` module
- `CountDownTimer` renamed to `CountdownTimer`
## Fixes
- Fixes for SPI peripheral: Flush implementation was incorrect and should now flush properly.
## [v0.7.0] 2024-07-04
- Replace `uarta` and `uartb` `Uart` constructors by `new` constructor
- Replace SPI `spia`, `spib` and `spic` constructors by `new` constructor
- Replace I2C `i2ca`, `i2cb` constructors by `new` constructor. Update constructor
to fail on invalid fast I2C speed system clock values
- Renamed `gpio::pins` to `gpio::pin` and `gpio::dynpins` to `gpio::dynpin`
- Simplify UART clock divider calculations and remove `libm` dependency consequently
## [v0.6.0] 2024-06-16
- Updated `embedded-hal` to v1

39
va108xx-hal/Cargo.toml
View File

@ -1,6 +1,6 @@
[package]
name = "va108xx-hal"
version = "0.6.0"
version = "0.9.0"
authors = ["Robin Mueller <muellerr@irs.uni-stuttgart.de>"]
edition = "2021"
description = "HAL for the Vorago VA108xx family of microcontrollers"
@ -15,34 +15,35 @@ cortex-m = { version = "0.7", features = ["critical-section-single-core"]}
cortex-m-rt = "0.7"
nb = "1"
paste = "1"
embedded-hal = "1"
embedded-hal-async = "1"
embedded-hal-nb = "1"
libm = "0.2"
embedded-io = "0.6"
embedded-io-async = "0.6"
fugit = "0.3"
typenum = "1"
critical-section = "1"
delegate = ">=0.12, <=0.13"
heapless = "0.8"
static_cell = "2"
thiserror = { version = "2", default-features = false }
void = { version = "1", default-features = false }
once_cell = {version = "1", default-features = false }
va108xx = { version = "0.4", default-features = false, features = ["critical-section"] }
embassy-sync = "0.6"
defmt = { version = "0.3", optional = true }
delegate = "0.12"
[dependencies.va108xx]
version = "0.3"
default-features = false
features = ["critical-section"]
[dependencies.embedded-hal]
version = "1"
[dependencies.void]
version = "1"
default-features = false
[dependencies.once_cell]
version = "1.14"
default-features = false
[target.'cfg(all(target_arch = "arm", target_os = "none"))'.dependencies]
portable-atomic = { version = "1", features = ["unsafe-assume-single-core"] }
[target.'cfg(not(all(target_arch = "arm", target_os = "none")))'.dependencies]
portable-atomic = "1"
[features]
default = ["rt"]
rt = ["va108xx/rt"]
defmt = ["dep:defmt", "fugit/defmt"]
[package.metadata.docs.rs]
all-features = true
rustdoc-args = ["--cfg", "docs_rs", "--generate-link-to-definition"]
rustdoc-args = ["--generate-link-to-definition"]

18
va108xx-hal/README.md
View File

@ -4,7 +4,7 @@
# HAL for the Vorago VA108xx MCU family
This repository contains the **H**ardware **A**bstraction **L**ayer (HAL), which is an additional
hardware abstraction on top of the [peripheral access API](https://egit.irs.uni-stuttgart.de/rust/va108xx).
hardware abstraction on top of the [peripheral access API](https://egit.irs.uni-stuttgart.de/rust/va108xx-rs/src/branch/main/va108xx).
It is the result of reading the datasheet for the device and encoding a type-safe layer over the
raw PAC. This crate also implements traits specified by the
@ -25,12 +25,6 @@ rustup target add thumbv6m-none-eabi
After that, you can use `cargo build` to build the development version of the crate.
If you have not done this yet, it is recommended to read some of the excellent resources
available to learn Rust:
- [Rust Embedded Book](https://docs.rust-embedded.org/book/)
- [Rust Discovery Book](https://docs.rust-embedded.org/discovery/)
## Setting up your own binary crate
If you have a custom board, you might be interested in setting up a new binary crate for your
@ -39,7 +33,7 @@ your custom board.
The hello world of embedded development is usually to blinky a LED. This example
is contained within the
[examples folder](https://egit.irs.uni-stuttgart.de/rust/va108xx-hal/src/branch/main/examples/blinky.rs).
[examples folder](https://egit.irs.uni-stuttgart.de/rust/va108xx-rs/src/branch/main/examples/simple/examples/blinky.rs).
1. Set up your Rust cross-compiler if you have not done so yet. See more in the [build chapter](#Building)
2. Create a new binary crate with `cargo init`
@ -65,3 +59,11 @@ is contained within the
7. Flashing the board might work differently for different boards and there is usually
more than one way. You can find example instructions in primary README.
## Embedded Rust
If you have not done this yet, it is recommended to read some of the excellent resources available
to learn Rust:
- [Rust Embedded Book](https://docs.rust-embedded.org/book/)
- [Rust Discovery Book](https://docs.rust-embedded.org/discovery/)

3
va108xx-hal/docs.sh Executable file
View File

@ -0,0 +1,3 @@
#!/bin/sh
export RUSTDOCFLAGS="--cfg docsrs --generate-link-to-definition -Z unstable-options"
cargo +nightly doc --all-features --open

29
va108xx-hal/src/clock.rs
View File

@ -11,6 +11,7 @@ static SYS_CLOCK: Mutex<OnceCell<Hertz>> = Mutex::new(OnceCell::new());
pub type PeripheralClocks = PeripheralSelect;
#[derive(Debug, PartialEq, Eq)]
#[cfg_attr(feature = "defmt", derive(defmt::Format))]
pub enum FilterClkSel {
SysClk = 0,
Clk1 = 1,
@ -39,13 +40,27 @@ pub fn get_sys_clock() -> Option<Hertz> {
pub fn set_clk_div_register(syscfg: &mut va108xx::Sysconfig, clk_sel: FilterClkSel, div: u32) {
match clk_sel {
FilterClkSel::SysClk => (),
FilterClkSel::Clk1 => syscfg.ioconfig_clkdiv1().write(|w| unsafe { w.bits(div) }),
FilterClkSel::Clk2 => syscfg.ioconfig_clkdiv2().write(|w| unsafe { w.bits(div) }),
FilterClkSel::Clk3 => syscfg.ioconfig_clkdiv3().write(|w| unsafe { w.bits(div) }),
FilterClkSel::Clk4 => syscfg.ioconfig_clkdiv4().write(|w| unsafe { w.bits(div) }),
FilterClkSel::Clk5 => syscfg.ioconfig_clkdiv5().write(|w| unsafe { w.bits(div) }),
FilterClkSel::Clk6 => syscfg.ioconfig_clkdiv6().write(|w| unsafe { w.bits(div) }),
FilterClkSel::Clk7 => syscfg.ioconfig_clkdiv7().write(|w| unsafe { w.bits(div) }),
FilterClkSel::Clk1 => {
syscfg.ioconfig_clkdiv1().write(|w| unsafe { w.bits(div) });
}
FilterClkSel::Clk2 => {
syscfg.ioconfig_clkdiv2().write(|w| unsafe { w.bits(div) });
}
FilterClkSel::Clk3 => {
syscfg.ioconfig_clkdiv3().write(|w| unsafe { w.bits(div) });
}
FilterClkSel::Clk4 => {
syscfg.ioconfig_clkdiv4().write(|w| unsafe { w.bits(div) });
}
FilterClkSel::Clk5 => {
syscfg.ioconfig_clkdiv5().write(|w| unsafe { w.bits(div) });
}
FilterClkSel::Clk6 => {
syscfg.ioconfig_clkdiv6().write(|w| unsafe { w.bits(div) });
}
FilterClkSel::Clk7 => {
syscfg.ioconfig_clkdiv7().write(|w| unsafe { w.bits(div) });
}
}
}

449
va108xx-hal/src/gpio/asynch.rs Normal file
View File

@ -0,0 +1,449 @@
//! # Async GPIO functionality for the VA108xx family.
//!
//! This module provides the [InputPinAsync] and [InputDynPinAsync] which both implement
//! the [embedded_hal_async::digital::Wait] trait. These types allow for asynchronous waiting
//! on GPIO pins. Please note that this module does not specify/declare the interrupt handlers
//! which must be provided for async support to work. However, it provides one generic
//! [handler][on_interrupt_for_asynch_gpio] which should be called in ALL user interrupt handlers
//! which handle GPIO interrupts.
//!
//! # Example
//!
//! - [Async GPIO example](https://egit.irs.uni-stuttgart.de/rust/va108xx-rs/src/branch/main/examples/embassy/src/bin/async-gpio.rs)
use core::future::Future;
use embassy_sync::waitqueue::AtomicWaker;
use embedded_hal::digital::InputPin;
use embedded_hal_async::digital::Wait;
use portable_atomic::AtomicBool;
use va108xx::{self as pac, Irqsel, Sysconfig};
use crate::InterruptConfig;
use super::{
pin, DynGroup, DynPin, DynPinId, InputConfig, InterruptEdge, InvalidPinTypeError, Pin, PinId,
NUM_GPIO_PINS, NUM_PINS_PORT_A,
};
static WAKERS: [AtomicWaker; NUM_GPIO_PINS] = [const { AtomicWaker::new() }; NUM_GPIO_PINS];
static EDGE_DETECTION: [AtomicBool; NUM_GPIO_PINS] =
[const { AtomicBool::new(false) }; NUM_GPIO_PINS];
#[inline]
fn pin_id_to_offset(dyn_pin_id: DynPinId) -> usize {
match dyn_pin_id.group {
DynGroup::A => dyn_pin_id.num as usize,
DynGroup::B => NUM_PINS_PORT_A + dyn_pin_id.num as usize,
}
}
/// Generic interrupt handler for GPIO interrupts to support the async functionalities.
///
/// This handler will wake the correspoding wakers for the pins which triggered an interrupt
/// as well as updating the static edge detection structures. This allows the pin future to
/// complete async operations. The user should call this function in ALL interrupt handlers
/// which handle any GPIO interrupts.
#[inline]
pub fn on_interrupt_for_asynch_gpio() {
let periphs = unsafe { pac::Peripherals::steal() };
handle_interrupt_for_gpio_and_port(
periphs.porta.irq_enb().read().bits(),
periphs.porta.edge_status().read().bits(),
0,
);
handle_interrupt_for_gpio_and_port(
periphs.portb.irq_enb().read().bits(),
periphs.portb.edge_status().read().bits(),
NUM_PINS_PORT_A,
);
}
// Uses the enabled interrupt register and the persistent edge status to capture all GPIO events.
#[inline]
fn handle_interrupt_for_gpio_and_port(mut irq_enb: u32, edge_status: u32, pin_base_offset: usize) {
while irq_enb != 0 {
let bit_pos = irq_enb.trailing_zeros() as usize;
let bit_mask = 1 << bit_pos;
WAKERS[pin_base_offset + bit_pos].wake();
if edge_status & bit_mask != 0 {
EDGE_DETECTION[pin_base_offset + bit_pos]
.store(true, core::sync::atomic::Ordering::Relaxed);
}
// Clear the processed bit
irq_enb &= !bit_mask;
}
}
/// Input pin future which implements the [Future] trait.
///
/// Generally, you want to use the [InputPinAsync] or [InputDynPinAsync] types instead of this
/// which also implements the [embedded_hal_async::digital::Wait] trait. However, access to this
/// struture is granted to allow writing custom async structures.
pub struct InputPinFuture {
pin_id: DynPinId,
}
impl InputPinFuture {
/// # Safety
///
/// This calls [Self::new_with_dyn_pin] but uses [pac::Peripherals::steal] to get the system configuration
/// and IRQ selection peripherals. Users must ensure that the registers and configuration
/// related to this input pin are not being used elsewhere concurrently.
pub unsafe fn new_unchecked_with_dyn_pin(
pin: &mut DynPin,
irq: pac::Interrupt,
edge: InterruptEdge,
) -> Result<Self, InvalidPinTypeError> {
let mut periphs = pac::Peripherals::steal();
Self::new_with_dyn_pin(pin, irq, edge, &mut periphs.sysconfig, &mut periphs.irqsel)
}
pub fn new_with_dyn_pin(
pin: &mut DynPin,
irq: pac::Interrupt,
edge: InterruptEdge,
sys_cfg: &mut Sysconfig,
irq_sel: &mut Irqsel,
) -> Result<Self, InvalidPinTypeError> {
if !pin.is_input_pin() {
return Err(InvalidPinTypeError(pin.mode()));
}
EDGE_DETECTION[pin_id_to_offset(pin.id())]
.store(false, core::sync::atomic::Ordering::Relaxed);
pin.interrupt_edge(
edge,
InterruptConfig::new(irq, true, true),
Some(sys_cfg),
Some(irq_sel),
)
.unwrap();
Ok(Self { pin_id: pin.id() })
}
/// # Safety
///
/// This calls [Self::new_with_pin] but uses [pac::Peripherals::steal] to get the system configuration
/// and IRQ selection peripherals. Users must ensure that the registers and configuration
/// related to this input pin are not being used elsewhere concurrently.
pub unsafe fn new_unchecked_with_pin<I: PinId, C: InputConfig>(
pin: &mut Pin<I, pin::Input<C>>,
irq: pac::Interrupt,
edge: InterruptEdge,
) -> Self {
let mut periphs = pac::Peripherals::steal();
Self::new_with_pin(pin, irq, edge, &mut periphs.sysconfig, &mut periphs.irqsel)
}
pub fn new_with_pin<I: PinId, C: InputConfig>(
pin: &mut Pin<I, pin::Input<C>>,
irq: pac::Interrupt,
edge: InterruptEdge,
sys_cfg: &mut Sysconfig,
irq_sel: &mut Irqsel,
) -> Self {
EDGE_DETECTION[pin_id_to_offset(pin.id())]
.store(false, core::sync::atomic::Ordering::Relaxed);
pin.configure_edge_interrupt(
edge,
InterruptConfig::new(irq, true, true),
Some(sys_cfg),
Some(irq_sel),
);
Self { pin_id: pin.id() }
}
}
impl Drop for InputPinFuture {
fn drop(&mut self) {
let periphs = unsafe { pac::Peripherals::steal() };
if self.pin_id.group == DynGroup::A {
periphs
.porta
.irq_enb()
.modify(|r, w| unsafe { w.bits(r.bits() & !(1 << self.pin_id.num)) });
} else {
periphs
.porta
.irq_enb()
.modify(|r, w| unsafe { w.bits(r.bits() & !(1 << self.pin_id.num)) });
}
}
}
impl Future for InputPinFuture {
type Output = ();
fn poll(
self: core::pin::Pin<&mut Self>,
cx: &mut core::task::Context<'_>,
) -> core::task::Poll<Self::Output> {
let idx = pin_id_to_offset(self.pin_id);
WAKERS[idx].register(cx.waker());
if EDGE_DETECTION[idx].swap(false, core::sync::atomic::Ordering::Relaxed) {
return core::task::Poll::Ready(());
}
core::task::Poll::Pending
}
}
pub struct InputDynPinAsync {
pin: DynPin,
irq: pac::Interrupt,
}
impl InputDynPinAsync {
/// Create a new asynchronous input pin from a [DynPin]. The interrupt ID to be used must be
/// passed as well and is used to route and enable the interrupt.
///
/// Please note that the interrupt handler itself must be provided by the user and the
/// generic [on_interrupt_for_asynch_gpio] function must be called inside that function for
/// the asynchronous functionality to work.
pub fn new(pin: DynPin, irq: pac::Interrupt) -> Result<Self, InvalidPinTypeError> {
if !pin.is_input_pin() {
return Err(InvalidPinTypeError(pin.mode()));
}
Ok(Self { pin, irq })
}
/// Asynchronously wait until the pin is high.
///
/// This returns immediately if the pin is already high.
pub async fn wait_for_high(&mut self) {
let fut = unsafe {
// Unwrap okay, checked pin in constructor.
InputPinFuture::new_unchecked_with_dyn_pin(
&mut self.pin,
self.irq,
InterruptEdge::LowToHigh,
)
.unwrap()
};
if self.pin.is_high().unwrap() {
return;
}
fut.await;
}
/// Asynchronously wait until the pin is low.
///
/// This returns immediately if the pin is already high.
pub async fn wait_for_low(&mut self) {
let fut = unsafe {
// Unwrap okay, checked pin in constructor.
InputPinFuture::new_unchecked_with_dyn_pin(
&mut self.pin,
self.irq,
InterruptEdge::HighToLow,
)
.unwrap()
};
if self.pin.is_low().unwrap() {
return;
}
fut.await;
}
/// Asynchronously wait until the pin sees a falling edge.
pub async fn wait_for_falling_edge(&mut self) {
unsafe {
// Unwrap okay, checked pin in constructor.
InputPinFuture::new_unchecked_with_dyn_pin(
&mut self.pin,
self.irq,
InterruptEdge::HighToLow,
)
.unwrap()
}
.await;
}
/// Asynchronously wait until the pin sees a rising edge.
pub async fn wait_for_rising_edge(&mut self) {
unsafe {
// Unwrap okay, checked pin in constructor.
InputPinFuture::new_unchecked_with_dyn_pin(
&mut self.pin,
self.irq,
InterruptEdge::LowToHigh,
)
.unwrap()
}
.await;
}
/// Asynchronously wait until the pin sees any edge (either rising or falling).
pub async fn wait_for_any_edge(&mut self) {
unsafe {
// Unwrap okay, checked pin in constructor.
InputPinFuture::new_unchecked_with_dyn_pin(
&mut self.pin,
self.irq,
InterruptEdge::BothEdges,
)
.unwrap()
}
.await;
}
pub fn release(self) -> DynPin {
self.pin
}
}
impl embedded_hal::digital::ErrorType for InputDynPinAsync {
type Error = core::convert::Infallible;
}
impl Wait for InputDynPinAsync {
async fn wait_for_high(&mut self) -> Result<(), Self::Error> {
self.wait_for_high().await;
Ok(())
}
async fn wait_for_low(&mut self) -> Result<(), Self::Error> {
self.wait_for_low().await;
Ok(())
}
async fn wait_for_rising_edge(&mut self) -> Result<(), Self::Error> {
self.wait_for_rising_edge().await;
Ok(())
}
async fn wait_for_falling_edge(&mut self) -> Result<(), Self::Error> {
self.wait_for_falling_edge().await;
Ok(())
}
async fn wait_for_any_edge(&mut self) -> Result<(), Self::Error> {
self.wait_for_any_edge().await;
Ok(())
}
}
pub struct InputPinAsync<I: PinId, C: InputConfig> {
pin: Pin<I, pin::Input<C>>,
irq: pac::Interrupt,
}
impl<I: PinId, C: InputConfig> InputPinAsync<I, C> {
/// Create a new asynchronous input pin from a typed [Pin]. The interrupt ID to be used must be
/// passed as well and is used to route and enable the interrupt.
///
/// Please note that the interrupt handler itself must be provided by the user and the
/// generic [on_interrupt_for_asynch_gpio] function must be called inside that function for
/// the asynchronous functionality to work.
pub fn new(pin: Pin<I, pin::Input<C>>, irq: pac::Interrupt) -> Self {
Self { pin, irq }
}
/// Asynchronously wait until the pin is high.
///
/// This returns immediately if the pin is already high.
pub async fn wait_for_high(&mut self) {
let fut = unsafe {
InputPinFuture::new_unchecked_with_pin(
&mut self.pin,
self.irq,
InterruptEdge::LowToHigh,
)
};
if self.pin.is_high().unwrap() {
return;
}
fut.await;
}
/// Asynchronously wait until the pin is low.
///
/// This returns immediately if the pin is already high.
pub async fn wait_for_low(&mut self) {
let fut = unsafe {
InputPinFuture::new_unchecked_with_pin(
&mut self.pin,
self.irq,
InterruptEdge::HighToLow,
)
};
if self.pin.is_low().unwrap() {
return;
}
fut.await;
}
/// Asynchronously wait until the pin sees falling edge.
pub async fn wait_for_falling_edge(&mut self) {
unsafe {
// Unwrap okay, checked pin in constructor.
InputPinFuture::new_unchecked_with_pin(
&mut self.pin,
self.irq,
InterruptEdge::HighToLow,
)
}
.await;
}
/// Asynchronously wait until the pin sees rising edge.
pub async fn wait_for_rising_edge(&mut self) {
unsafe {
// Unwrap okay, checked pin in constructor.
InputPinFuture::new_unchecked_with_pin(
&mut self.pin,
self.irq,
InterruptEdge::LowToHigh,
)
}
.await;
}
/// Asynchronously wait until the pin sees any edge (either rising or falling).
pub async fn wait_for_any_edge(&mut self) {
unsafe {
InputPinFuture::new_unchecked_with_pin(
&mut self.pin,
self.irq,
InterruptEdge::BothEdges,
)
}
.await;
}
pub fn release(self) -> Pin<I, pin::Input<C>> {
self.pin
}
}
impl<I: PinId, C: InputConfig> embedded_hal::digital::ErrorType for InputPinAsync<I, C> {
type Error = core::convert::Infallible;
}
impl<I: PinId, C: InputConfig> Wait for InputPinAsync<I, C> {
async fn wait_for_high(&mut self) -> Result<(), Self::Error> {
self.wait_for_high().await;
Ok(())
}
async fn wait_for_low(&mut self) -> Result<(), Self::Error> {
self.wait_for_low().await;
Ok(())
}
async fn wait_for_rising_edge(&mut self) -> Result<(), Self::Error> {
self.wait_for_rising_edge().await;
Ok(())
}
async fn wait_for_falling_edge(&mut self) -> Result<(), Self::Error> {
self.wait_for_falling_edge().await;
Ok(())
}
async fn wait_for_any_edge(&mut self) -> Result<(), Self::Error> {
self.wait_for_any_edge().await;
Ok(())
}
}

206
va108xx-hal/src/gpio/dynpins.rs → va108xx-hal/src/gpio/dynpin.rs
View File

@ -36,8 +36,7 @@
//! Users may try to convert value-level pins back to their type-level
//! equivalents. However, this option is fallible, because the compiler cannot
//! guarantee the pin has the correct ID or is in the correct mode at
//! compile-time. Use [`TryFrom`](core::convert::TryFrom)/
//! [`TryInto`](core::convert::TryInto) for this conversion.
//! compile-time. Use [TryFrom]/[TryInto] for this conversion.
//!
//! ```
//! // Convert to a `DynPin`
@ -55,13 +54,14 @@
//! `Error = core::convert::Infallible`, the value-level API can return a real
//! error. If the [`DynPin`] is not in the correct [`DynPinMode`] for the
//! operation, the trait functions will return
//! [`InvalidPinType`](PinError::InvalidPinType).
//! [InvalidPinTypeError].
use super::{
pins::{FilterType, InterruptEdge, InterruptLevel, Pin, PinId, PinMode, PinState},
pin::{FilterType, InterruptEdge, InterruptLevel, Pin, PinId, PinMode, PinState},
reg::RegisterInterface,
InputDynPinAsync,
};
use crate::{clock::FilterClkSel, pac, FunSel, IrqCfg};
use crate::{clock::FilterClkSel, enable_nvic_interrupt, pac, FunSel, InterruptConfig};
//==================================================================================================
// DynPinMode configurations
@ -69,6 +69,7 @@ use crate::{clock::FilterClkSel, pac, FunSel, IrqCfg};
/// Value-level `enum` for disabled configurations
#[derive(PartialEq, Eq, Clone, Copy)]
#[cfg_attr(feature = "defmt", derive(defmt::Format))]
pub enum DynDisabled {
Floating,
PullDown,
@ -76,7 +77,8 @@ pub enum DynDisabled {
}
/// Value-level `enum` for input configurations
#[derive(PartialEq, Eq, Clone, Copy)]
#[derive(Debug, PartialEq, Eq, Clone, Copy)]
#[cfg_attr(feature = "defmt", derive(defmt::Format))]
pub enum DynInput {
Floating,
PullDown,
@ -84,7 +86,8 @@ pub enum DynInput {
}
/// Value-level `enum` for output configurations
#[derive(PartialEq, Eq, Clone, Copy)]
#[derive(Debug, PartialEq, Eq, Clone, Copy)]
#[cfg_attr(feature = "defmt", derive(defmt::Format))]
pub enum DynOutput {
PushPull,
OpenDrain,
@ -102,9 +105,10 @@ pub type DynAlternate = FunSel;
///
/// [`DynPin`]s are not tracked and verified at compile-time, so run-time
/// operations are fallible. This `enum` represents the corresponding errors.
#[derive(Debug, PartialEq, Eq)]
#[derive(Debug, PartialEq, Eq, thiserror::Error)]
#[cfg_attr(feature = "defmt", derive(defmt::Format))]
pub struct InvalidPinTypeError;
#[error("Invalid pin type for operation: {0:?}")]
pub struct InvalidPinTypeError(pub DynPinMode);
impl embedded_hal::digital::Error for InvalidPinTypeError {
fn kind(&self) -> embedded_hal::digital::ErrorKind {
@ -117,7 +121,8 @@ impl embedded_hal::digital::Error for InvalidPinTypeError {
//==================================================================================================
/// Value-level `enum` representing pin modes
#[derive(PartialEq, Eq, Clone, Copy)]
#[derive(Debug, PartialEq, Eq, Clone, Copy)]
#[cfg_attr(feature = "defmt", derive(defmt::Format))]
pub enum DynPinMode {
Input(DynInput),
Output(DynOutput),
@ -152,14 +157,16 @@ pub const DYN_ALT_FUNC_3: DynPinMode = DynPinMode::Alternate(DynAlternate::Sel3)
//==================================================================================================
/// Value-level `enum` for pin groups
#[derive(PartialEq, Eq, Clone, Copy)]
#[derive(Debug, PartialEq, Eq, Clone, Copy)]
#[cfg_attr(feature = "defmt", derive(defmt::Format))]
pub enum DynGroup {
A,
B,
}
/// Value-level `struct` representing pin IDs
#[derive(PartialEq, Eq, Clone, Copy)]
#[derive(Debug, PartialEq, Eq, Clone, Copy)]
#[cfg_attr(feature = "defmt", derive(defmt::Format))]
pub struct DynPinId {
pub group: DynGroup,
pub num: u8,
@ -173,16 +180,15 @@ pub struct DynPinId {
///
/// This `struct` takes ownership of a [`DynPinId`] and provides an API to
/// access the corresponding regsiters.
struct DynRegisters {
id: DynPinId,
}
#[derive(Debug)]
pub(crate) struct DynRegisters(DynPinId);
// [`DynRegisters`] takes ownership of the [`DynPinId`], and [`DynPin`]
// guarantees that each pin is a singleton, so this implementation is safe.
unsafe impl RegisterInterface for DynRegisters {
#[inline]
fn id(&self) -> DynPinId {
self.id
self.0
}
}
@ -195,7 +201,7 @@ impl DynRegisters {
/// the same [`DynPinId`]
#[inline]
unsafe fn new(id: DynPinId) -> Self {
DynRegisters { id }
DynRegisters(id)
}
}
@ -207,8 +213,9 @@ impl DynRegisters {
///
/// This type acts as a type-erased version of [`Pin`]. Every pin is represented
/// by the same type, and pins are tracked and distinguished at run-time.
#[derive(Debug)]
pub struct DynPin {
regs: DynRegisters,
pub(crate) regs: DynRegisters,
mode: DynPinMode,
}
@ -221,7 +228,7 @@ impl DynPin {
/// must be at most one corresponding [`DynPin`] in existence at any given
/// time. Violating this requirement is `unsafe`.
#[inline]
unsafe fn new(id: DynPinId, mode: DynPinMode) -> Self {
pub(crate) unsafe fn new(id: DynPinId, mode: DynPinMode) -> Self {
DynPin {
regs: DynRegisters::new(id),
mode,
@ -231,7 +238,7 @@ impl DynPin {
/// Return a copy of the pin ID
#[inline]
pub fn id(&self) -> DynPinId {
self.regs.id
self.regs.0
}
/// Return a copy of the pin mode
@ -250,6 +257,11 @@ impl DynPin {
}
}
#[inline]
pub fn is_input_pin(&self) -> bool {
matches!(self.mode, DynPinMode::Input(_))
}
#[inline]
pub fn into_funsel_1(&mut self) {
self.into_mode(DYN_ALT_FUNC_1);
@ -307,7 +319,72 @@ impl DynPin {
self.into_mode(DYN_RD_OPEN_DRAIN_OUTPUT);
}
common_reg_if_functions!();
#[inline]
pub fn datamask(&self) -> bool {
self.regs.datamask()
}
#[inline]
pub fn clear_datamask(&mut self) {
self.regs.clear_datamask();
}
#[inline]
pub fn set_datamask(&mut self) {
self.regs.set_datamask();
}
#[inline]
pub fn is_high_masked(&self) -> Result<bool, crate::gpio::IsMaskedError> {
self.regs.read_pin_masked()
}
#[inline]
pub fn is_low_masked(&self) -> Result<bool, crate::gpio::IsMaskedError> {
self.regs.read_pin_masked().map(|v| !v)
}
#[inline]
pub fn set_high_masked(&mut self) -> Result<(), crate::gpio::IsMaskedError> {
self.regs.write_pin_masked(true)
}
#[inline]
pub fn set_low_masked(&mut self) -> Result<(), crate::gpio::IsMaskedError> {
self.regs.write_pin_masked(false)
}
pub(crate) fn irq_enb(
&mut self,
irq_cfg: crate::InterruptConfig,
syscfg: Option<&mut va108xx::Sysconfig>,
irqsel: Option<&mut va108xx::Irqsel>,
) {
if let Some(syscfg) = syscfg {
crate::clock::enable_peripheral_clock(syscfg, crate::clock::PeripheralClocks::Irqsel);
}
self.regs.enable_irq();
if let Some(irqsel) = irqsel {
if irq_cfg.route {
match self.regs.id().group {
// Set the correct interrupt number in the IRQSEL register
DynGroup::A => {
irqsel
.porta0(self.regs.id().num as usize)
.write(|w| unsafe { w.bits(irq_cfg.id as u32) });
}
DynGroup::B => {
irqsel
.portb0(self.regs.id().num as usize)
.write(|w| unsafe { w.bits(irq_cfg.id as u32) });
}
}
}
}
if irq_cfg.enable_in_nvic {
unsafe { enable_nvic_interrupt(irq_cfg.id) };
}
}
/// See p.53 of the programmers guide for more information.
/// Possible delays in clock cycles:
@ -321,74 +398,77 @@ impl DynPin {
self.regs.delay(delay_1, delay_2);
Ok(self)
}
_ => Err(InvalidPinTypeError),
_ => Err(InvalidPinTypeError(self.mode)),
}
}
/// See p.52 of the programmers guide for more information.
/// When configured for pulse mode, a given pin will set the non-default state for exactly
/// one clock cycle before returning to the configured default state
#[inline]
pub fn pulse_mode(
self,
&mut self,
enable: bool,
default_state: PinState,
) -> Result<Self, InvalidPinTypeError> {
) -> Result<(), InvalidPinTypeError> {
match self.mode {
DynPinMode::Output(_) => {
self.regs.pulse_mode(enable, default_state);
Ok(self)
Ok(())
}
_ => Err(InvalidPinTypeError),
_ => Err(InvalidPinTypeError(self.mode)),
}
}
/// See p.37 and p.38 of the programmers guide for more information.
#[inline]
pub fn filter_type(
self,
&mut self,
filter: FilterType,
clksel: FilterClkSel,
) -> Result<Self, InvalidPinTypeError> {
) -> Result<(), InvalidPinTypeError> {
match self.mode {
DynPinMode::Input(_) => {
self.regs.filter_type(filter, clksel);
Ok(self)
Ok(())
}
_ => Err(InvalidPinTypeError),
_ => Err(InvalidPinTypeError(self.mode)),
}
}
#[inline]
pub fn interrupt_edge(
mut self,
&mut self,
edge_type: InterruptEdge,
irq_cfg: IrqCfg,
irq_cfg: InterruptConfig,
syscfg: Option<&mut pac::Sysconfig>,
irqsel: Option<&mut pac::Irqsel>,
) -> Result<Self, InvalidPinTypeError> {
) -> Result<(), InvalidPinTypeError> {
match self.mode {
DynPinMode::Input(_) | DynPinMode::Output(_) => {
self.regs.interrupt_edge(edge_type);
self.irq_enb(irq_cfg, syscfg, irqsel);
Ok(self)
Ok(())
}
_ => Err(InvalidPinTypeError),
_ => Err(InvalidPinTypeError(self.mode)),
}
}
#[inline]
pub fn interrupt_level(
mut self,
&mut self,
level_type: InterruptLevel,
irq_cfg: IrqCfg,
irq_cfg: InterruptConfig,
syscfg: Option<&mut pac::Sysconfig>,
irqsel: Option<&mut pac::Irqsel>,
) -> Result<Self, InvalidPinTypeError> {
) -> Result<(), InvalidPinTypeError> {
match self.mode {
DynPinMode::Input(_) | DynPinMode::Output(_) => {
self.regs.interrupt_level(level_type);
self.irq_enb(irq_cfg, syscfg, irqsel);
Ok(self)
Ok(())
}
_ => Err(InvalidPinTypeError),
_ => Err(InvalidPinTypeError(self.mode)),
}
}
@ -399,7 +479,7 @@ impl DynPin {
self.regs.toggle();
Ok(())
}
_ => Err(InvalidPinTypeError),
_ => Err(InvalidPinTypeError(self.mode)),
}
}
@ -409,7 +489,7 @@ impl DynPin {
DynPinMode::Input(_) | DYN_RD_OPEN_DRAIN_OUTPUT | DYN_RD_PUSH_PULL_OUTPUT => {
Ok(self.regs.read_pin())
}
_ => Err(InvalidPinTypeError),
_ => Err(InvalidPinTypeError(self.mode)),
}
}
#[inline]
@ -419,7 +499,7 @@ impl DynPin {
self.regs.write_pin(bit);
Ok(())
}
_ => Err(InvalidPinTypeError),
_ => Err(InvalidPinTypeError(self.mode)),
}
}
@ -439,6 +519,30 @@ impl DynPin {
fn _set_high(&mut self) -> Result<(), InvalidPinTypeError> {
self._write(true)
}
/// Try to recreate a type-level [`Pin`] from a value-level [`DynPin`]
///
/// There is no way for the compiler to know if the conversion will be
/// successful at compile-time. We must verify the conversion at run-time
/// or refuse to perform it.
#[inline]
pub fn upgrade<I: PinId, M: PinMode>(self) -> Result<Pin<I, M>, InvalidPinTypeError> {
if self.regs.0 == I::DYN && self.mode == M::DYN {
// The `DynPin` is consumed, so it is safe to replace it with the
// corresponding `Pin`
return Ok(unsafe { Pin::new() });
}
Err(InvalidPinTypeError(self.mode))
}
/// Convert the pin into an async pin. The pin can be converted back by calling
/// [InputDynPinAsync::release]
pub fn into_async_input(
self,
irq: crate::pac::Interrupt,
) -> Result<InputDynPinAsync, InvalidPinTypeError> {
InputDynPinAsync::new(self, irq)
}
}
//==================================================================================================
@ -449,10 +553,8 @@ impl<I: PinId, M: PinMode> From<Pin<I, M>> for DynPin {
/// Erase the type-level information in a [`Pin`] and return a value-level
/// [`DynPin`]
#[inline]
fn from(_pin: Pin<I, M>) -> Self {
// The `Pin` is consumed, so it is safe to replace it with the
// corresponding `DynPin`
unsafe { DynPin::new(I::DYN, M::DYN) }
fn from(pin: Pin<I, M>) -> Self {
pin.downgrade()
}
}
@ -466,13 +568,7 @@ impl<I: PinId, M: PinMode> TryFrom<DynPin> for Pin<I, M> {
/// or refuse to perform it.
#[inline]
fn try_from(pin: DynPin) -> Result<Self, Self::Error> {
if pin.regs.id == I::DYN && pin.mode == M::DYN {
// The `DynPin` is consumed, so it is safe to replace it with the
// corresponding `Pin`
Ok(unsafe { Self::new() })
} else {
Err(InvalidPinTypeError)
}
pin.upgrade()
}
}
@ -507,10 +603,12 @@ impl embedded_hal::digital::InputPin for DynPin {
}
impl embedded_hal::digital::StatefulOutputPin for DynPin {
#[inline]
fn is_set_high(&mut self) -> Result<bool, Self::Error> {
self._is_high()
}
#[inline]
fn is_set_low(&mut self) -> Result<bool, Self::Error> {
self._is_low()
}

100
va108xx-hal/src/gpio/mod.rs
View File

@ -3,10 +3,10 @@
//! The implementation of this GPIO module is heavily based on the
//! [ATSAMD HAL implementation](https://docs.rs/atsamd-hal/latest/atsamd_hal/gpio/index.html).
//!
//! This API provides two different submodules, [`mod@pins`] and [`dynpins`],
//! representing two different ways to handle GPIO pins. The default, [`mod@pins`],
//! This API provides two different submodules, [pin] and [dynpin],
//! representing two different ways to handle GPIO pins. The default, [pin],
//! is a type-level API that tracks the state of each pin at compile-time. The
//! alternative, [`dynpins`] is a type-erased, value-level API that tracks the
//! alternative, [dynpin] is a type-erased, value-level API that tracks the
//! state of each pin at run-time.
//!
//! The type-level API is strongly preferred. By representing the state of each
@ -14,98 +14,30 @@
//! compile-time. Furthermore, the type-level API has absolutely zero run-time
//! cost.
//!
//! If needed, [`dynpins`] can be used to erase the type-level differences
//! If needed, [dynpin] can be used to erase the type-level differences
//! between pins. However, by doing so, pins must now be tracked at run-time,
//! and each pin has a non-zero memory footprint.
//!
//! ## Examples
//!
//! - [Blinky example](https://egit.irs.uni-stuttgart.de/rust/va108xx-hal/src/branch/main/examples/blinky.rs)
//!
//! - [Blinky example](https://egit.irs.uni-stuttgart.de/rust/va108xx-rs/src/branch/main/examples/simple/examples/blinky.rs)
#[derive(Debug, PartialEq, Eq)]
#[derive(Debug, PartialEq, Eq, thiserror::Error)]
#[cfg_attr(feature = "defmt", derive(defmt::Format))]
#[error("The pin is masked")]
pub struct IsMaskedError;
macro_rules! common_reg_if_functions {
() => {
paste::paste!(
#[inline]
pub fn datamask(&self) -> bool {
self.regs.datamask()
}
pub const NUM_PINS_PORT_A: usize = 32;
pub const NUM_PINS_PORT_B: usize = 24;
pub const NUM_GPIO_PINS: usize = NUM_PINS_PORT_A + NUM_PINS_PORT_B;
#[inline]
pub fn clear_datamask(self) -> Self {
self.regs.clear_datamask();
self
}
pub mod dynpin;
pub use dynpin::*;
#[inline]
pub fn set_datamask(self) -> Self {
self.regs.set_datamask();
self
}
pub mod pin;
pub use pin::*;
#[inline]
pub fn is_high_masked(&self) -> Result<bool, crate::gpio::IsMaskedError> {
self.regs.read_pin_masked()
}
#[inline]
pub fn is_low_masked(&self) -> Result<bool, crate::gpio::IsMaskedError> {
self.regs.read_pin_masked().map(|v| !v)
}
#[inline]
pub fn set_high_masked(&mut self) -> Result<(), crate::gpio::IsMaskedError> {
self.regs.write_pin_masked(true)
}
#[inline]
pub fn set_low_masked(&mut self) -> Result<(), crate::gpio::IsMaskedError> {
self.regs.write_pin_masked(false)
}
fn irq_enb(
&mut self,
irq_cfg: crate::IrqCfg,
syscfg: Option<&mut va108xx::Sysconfig>,
irqsel: Option<&mut va108xx::Irqsel>,
) {
if syscfg.is_some() {
crate::clock::enable_peripheral_clock(
syscfg.unwrap(),
crate::clock::PeripheralClocks::Irqsel,
);
}
self.regs.enable_irq();
if let Some(irqsel) = irqsel {
if irq_cfg.route {
match self.regs.id().group {
// Set the correct interrupt number in the IRQSEL register
DynGroup::A => {
irqsel
.porta0(self.regs.id().num as usize)
.write(|w| unsafe { w.bits(irq_cfg.irq as u32) });
}
DynGroup::B => {
irqsel
.portb0(self.regs.id().num as usize)
.write(|w| unsafe { w.bits(irq_cfg.irq as u32) });
}
}
}
}
}
);
};
}
pub mod dynpins;
pub use dynpins::*;
pub mod pins;
pub use pins::*;
pub mod asynch;
pub use asynch::*;
mod reg;

289
va108xx-hal/src/gpio/pins.rs → va108xx-hal/src/gpio/pin.rs
View File

@ -29,78 +29,54 @@
//! }
//! ```
//!
//! A `PinId` identifies a pin by it's group (A, B, C or D) and pin number. Each
//! `PinId` instance is named according to its datasheet identifier, e.g.
//! [`PA02`].
//! A [PinId] identifies a pin by it's group (A or B) and pin number. Each
//! [PinId] instance is named according to its datasheet identifier, e.g.
//! [PA2].
//!
//! A `PinMode` represents the various pin modes. The available `PinMode`
//! variants are [`Disabled`], [`Input`], [`Interrupt`], [`Output`] and
//! [`Alternate`], each with its own corresponding configurations.
//! A [PinMode] represents the various pin modes. The available [PinMode]
//! variants are [`Input`], [`Output`] and [`Alternate`], each with its own
//! corresponding configurations.
//!
//! It is not possible for users to create new instances of a [`Pin`]. Singleton
//! instances of each pin are made available to users through the [`Pins`]
//! instances of each pin are made available to users through the PinsX
//! struct.
//!
//! To create the [`Pins`] struct, users must supply the PAC
//! [`PORT`](crate::pac::PORT) peripheral. The [`Pins`] struct takes
//! ownership of the [`PORT`] and provides the corresponding pins. Each [`Pin`]
//! within the [`Pins`] struct can be moved out and used individually.
//! Example for the pins of PORT A:
//!
//! To create the [PinsA] struct, users must supply the PAC
//! [Port](crate::pac::Porta) peripheral. The [PinsA] struct takes
//! ownership of the [Porta] and provides the corresponding pins. Each [`Pin`]
//! within the [PinsA] struct can be moved out and used individually.
//!
//!
//! ```
//! let mut peripherals = Peripherals::take().unwrap();
//! let pins = Pins::new(peripherals.PORT);
//! let pinsa = PinsA::new(peripherals.PORT);
//! ```
//!
//! Pins can be converted between modes using several different methods.
//!
//! ```
//! ```no_run
//! // Use one of the literal function names
//! let pa27 = pins.pa27.into_floating_input();
//! let pa0 = pinsa.pa0.into_floating_input();
//! // Use a generic method and one of the `PinMode` variant types
//! let pa27 = pins.pa27.into_mode::<FloatingInput>();
//! let pa0 = pinsa.pa0.into_mode::<FloatingInput>();
//! // Specify the target type and use `From`/`Into`
//! let pa27: Pin<PA27, FloatingInput> = pins.pa27.into();
//! let pa0: Pin<PA0, FloatingInput> = pinsa.pa27.into();
//! ```
//!
//! # Embedded HAL traits
//!
//! This module implements all of the embedded HAL GPIO traits for each [`Pin`]
//! in the corresponding [`PinMode`]s, namely: [`InputPin`], [`OutputPin`],
//! [`ToggleableOutputPin`] and [`StatefulOutputPin`].
//!
//! For example, you can control the logic level of an `OutputPin` like so
//!
//! ```
//! use atsamd_hal::pac::Peripherals;
//! use atsamd_hal::gpio::Pins;
//! use crate::ehal_02::digital::v2::OutputPin;
//!
//! let mut peripherals = Peripherals::take().unwrap();
//! let mut pins = Pins::new(peripherals.PORT);
//! pins.pa27.set_high();
//! ```
//!
//! # Type-level features
//!
//! This module also provides additional, type-level tools to work with GPIO
//! pins.
//!
//! The [`OptionalPinId`] and [`OptionalPin`] traits use the [`OptionalKind`]
//! pattern to act as type-level versions of [`Option`] for `PinId` and `Pin`
//! respectively. And the [`AnyPin`] trait defines an [`AnyKind`] type class
//! for all `Pin` types.
//!
//! [type classes]: crate::typelevel#type-classes
//! [type-level enum]: crate::typelevel#type-level-enum
//! [`OptionalKind`]: crate::typelevel#optionalkind-trait-pattern
//! [`AnyKind`]: crate::typelevel#anykind-trait-pattern
use super::dynpins::{DynAlternate, DynGroup, DynInput, DynOutput, DynPinId, DynPinMode};
//! and [`StatefulOutputPin`].
use super::dynpin::{DynAlternate, DynGroup, DynInput, DynOutput, DynPinId, DynPinMode};
use super::reg::RegisterInterface;
use super::{DynPin, InputPinAsync};
use crate::{
pac::{Irqsel, Porta, Portb, Sysconfig},
typelevel::Sealed,
IrqCfg,
InterruptConfig,
};
use core::convert::Infallible;
use core::marker::PhantomData;
@ -137,14 +113,17 @@ pub enum PinState {
/// Type-level enum for input configurations
///
/// The valid options are [`Floating`], [`PullDown`] and [`PullUp`].
/// The valid options are [Floating], [PullDown] and [PullUp].
pub trait InputConfig: Sealed {
/// Corresponding [`DynInput`](super::DynInput)
/// Corresponding [DynInput]
const DYN: DynInput;
}
#[derive(Debug)]
pub enum Floating {}
#[derive(Debug)]
pub enum PullDown {}
#[derive(Debug)]
pub enum PullUp {}
impl InputConfig for Floating {
@ -172,6 +151,7 @@ pub type InputPullUp = Input<PullUp>;
///
/// Type `C` is one of three input configurations: [`Floating`], [`PullDown`] or
/// [`PullUp`]
#[derive(Debug)]
pub struct Input<C: InputConfig> {
cfg: PhantomData<C>,
}
@ -201,13 +181,17 @@ pub trait OutputConfig: Sealed {
pub trait ReadableOutput: Sealed {}
/// Type-level variant of [`OutputConfig`] for a push-pull configuration
#[derive(Debug)]
pub enum PushPull {}
/// Type-level variant of [`OutputConfig`] for an open drain configuration
#[derive(Debug)]
pub enum OpenDrain {}
/// Type-level variant of [`OutputConfig`] for a readable push-pull configuration
#[derive(Debug)]
pub enum ReadablePushPull {}
/// Type-level variant of [`OutputConfig`] for a readable open-drain configuration
#[derive(Debug)]
pub enum ReadableOpenDrain {}
impl Sealed for PushPull {}
@ -234,6 +218,7 @@ impl OutputConfig for ReadableOpenDrain {
///
/// Type `C` is one of four output configurations: [`PushPull`], [`OpenDrain`] or
/// their respective readable versions
#[derive(Debug)]
pub struct Output<C: OutputConfig> {
cfg: PhantomData<C>,
}
@ -297,9 +282,9 @@ pub type Reset = InputFloating;
/// Type-level enum representing pin modes
///
/// The valid options are [`Input`], [`Output`] and [`Alternate`].
/// The valid options are [Input], [Output] and [Alternate].
pub trait PinMode: Sealed {
/// Corresponding [`DynPinMode`](super::DynPinMode)
/// Corresponding [DynPinMode]
const DYN: DynPinMode;
}
@ -319,7 +304,7 @@ impl<C: AlternateConfig> PinMode for Alternate<C> {
/// Type-level enum for pin IDs
pub trait PinId: Sealed {
/// Corresponding [`DynPinId`](super::DynPinId)
/// Corresponding [DynPinId]
const DYN: DynPinId;
}
@ -328,6 +313,7 @@ macro_rules! pin_id {
// Need paste macro to use ident in doc attribute
paste! {
#[doc = "Pin ID representing pin " $Id]
#[derive(Debug)]
pub enum $Id {}
impl Sealed for $Id {}
impl PinId for $Id {
@ -344,36 +330,40 @@ macro_rules! pin_id {
// Pin
//==================================================================================================
/// A type-level GPIO pin, parameterized by [`PinId`] and [`PinMode`] types
/// A type-level GPIO pin, parameterized by [PinId] and [PinMode] types
#[derive(Debug)]
pub struct Pin<I: PinId, M: PinMode> {
pub(in crate::gpio) regs: Registers<I>,
mode: PhantomData<M>,
inner: DynPin,
phantom: PhantomData<(I, M)>,
}
impl<I: PinId, M: PinMode> Pin<I, M> {
/// Create a new [`Pin`]
/// Create a new [Pin]
///
/// # Safety
///
/// Each [`Pin`] must be a singleton. For a given [`PinId`], there must be
/// at most one corresponding [`Pin`] in existence at any given time.
/// Each [Pin] must be a singleton. For a given [PinId], there must be
/// at most one corresponding [Pin] in existence at any given time.
/// Violating this requirement is `unsafe`.
#[inline]
pub(crate) unsafe fn new() -> Pin<I, M> {
Pin {
regs: Registers::new(),
mode: PhantomData,
inner: DynPin::new(I::DYN, M::DYN),
phantom: PhantomData,
}
}
pub fn id(&self) -> DynPinId {
self.inner.id()
}
/// Convert the pin to the requested [`PinMode`]
#[inline]
pub fn into_mode<N: PinMode>(mut self) -> Pin<I, N> {
// Only modify registers if we are actually changing pin mode
// This check should compile away
if N::DYN != M::DYN {
self.regs.change_mode::<N>();
self.inner.regs.change_mode(N::DYN);
}
// Safe because we drop the existing Pin
unsafe { Pin::new() }
@ -433,31 +423,78 @@ impl<I: PinId, M: PinMode> Pin<I, M> {
self.into_mode()
}
common_reg_if_functions!();
#[inline]
pub fn datamask(&self) -> bool {
self.inner.datamask()
}
#[inline]
pub fn clear_datamask(&mut self) {
self.inner.clear_datamask()
}
#[inline]
pub fn set_datamask(&mut self) {
self.inner.set_datamask()
}
#[inline]
pub fn is_high_masked(&self) -> Result<bool, crate::gpio::IsMaskedError> {
self.inner.is_high_masked()
}
#[inline]
pub fn is_low_masked(&self) -> Result<bool, crate::gpio::IsMaskedError> {
self.inner.is_low_masked()
}
#[inline]
pub fn set_high_masked(&mut self) -> Result<(), crate::gpio::IsMaskedError> {
self.inner.set_high_masked()
}
#[inline]
pub fn set_low_masked(&mut self) -> Result<(), crate::gpio::IsMaskedError> {
self.inner.set_low_masked()
}
#[inline]
pub fn downgrade(self) -> DynPin {
self.inner
}
fn irq_enb(
&mut self,
irq_cfg: crate::InterruptConfig,
syscfg: Option<&mut va108xx::Sysconfig>,
irqsel: Option<&mut va108xx::Irqsel>,
) {
self.inner.irq_enb(irq_cfg, syscfg, irqsel);
}
#[inline]
pub(crate) fn _set_high(&mut self) {
self.regs.write_pin(true)
self.inner.regs.write_pin(true)
}
#[inline]
pub(crate) fn _set_low(&mut self) {
self.regs.write_pin(false)
self.inner.regs.write_pin(false)
}
#[inline]
pub(crate) fn _toggle_with_toggle_reg(&mut self) {
self.regs.toggle();
self.inner.regs.toggle();
}
#[inline]
pub(crate) fn _is_low(&self) -> bool {
!self.regs.read_pin()
!self.inner.regs.read_pin()
}
#[inline]
pub(crate) fn _is_high(&self) -> bool {
self.regs.read_pin()
self.inner.regs.read_pin()
}
}
@ -549,28 +586,32 @@ impl<P: AnyPin> AsMut<P> for SpecificPin<P> {
//==================================================================================================
impl<I: PinId, C: InputConfig> Pin<I, Input<C>> {
pub fn interrupt_edge(
mut self,
edge_type: InterruptEdge,
irq_cfg: IrqCfg,
syscfg: Option<&mut Sysconfig>,
irqsel: Option<&mut Irqsel>,
) -> Self {
self.regs.interrupt_edge(edge_type);
self.irq_enb(irq_cfg, syscfg, irqsel);
self
/// Convert the pin into an async pin. The pin can be converted back by calling
/// [InputPinAsync::release]
pub fn into_async_input(self, irq: crate::pac::Interrupt) -> InputPinAsync<I, C> {
InputPinAsync::new(self, irq)
}
pub fn interrupt_level(
mut self,
level_type: InterruptLevel,
irq_cfg: IrqCfg,
pub fn configure_edge_interrupt(
&mut self,
edge_type: InterruptEdge,
irq_cfg: InterruptConfig,
syscfg: Option<&mut Sysconfig>,
irqsel: Option<&mut Irqsel>,
) -> Self {
self.regs.interrupt_level(level_type);
) {
self.inner.regs.interrupt_edge(edge_type);
self.irq_enb(irq_cfg, syscfg, irqsel);
}
pub fn configure_level_interrupt(
&mut self,
level_type: InterruptLevel,
irq_cfg: InterruptConfig,
syscfg: Option<&mut Sysconfig>,
irqsel: Option<&mut Irqsel>,
) {
self.inner.regs.interrupt_level(level_type);
self.irq_enb(irq_cfg, syscfg, irqsel);
self
}
}
@ -582,7 +623,7 @@ impl<I: PinId, C: OutputConfig> Pin<I, Output<C>> {
/// - Delay 1 + Delay 2: 3
#[inline]
pub fn delay(self, delay_1: bool, delay_2: bool) -> Self {
self.regs.delay(delay_1, delay_2);
self.inner.regs.delay(delay_1, delay_2);
self
}
@ -594,42 +635,38 @@ impl<I: PinId, C: OutputConfig> Pin<I, Output<C>> {
/// See p.52 of the programmers guide for more information.
/// When configured for pulse mode, a given pin will set the non-default state for exactly
/// one clock cycle before returning to the configured default state
pub fn pulse_mode(self, enable: bool, default_state: PinState) -> Self {
self.regs.pulse_mode(enable, default_state);
self
pub fn pulse_mode(&mut self, enable: bool, default_state: PinState) {
self.inner.regs.pulse_mode(enable, default_state);
}
pub fn interrupt_edge(
mut self,
&mut self,
edge_type: InterruptEdge,
irq_cfg: IrqCfg,
irq_cfg: InterruptConfig,
syscfg: Option<&mut Sysconfig>,
irqsel: Option<&mut Irqsel>,
) -> Self {
self.regs.interrupt_edge(edge_type);
) {
self.inner.regs.interrupt_edge(edge_type);
self.irq_enb(irq_cfg, syscfg, irqsel);
self
}
pub fn interrupt_level(
mut self,
&mut self,
level_type: InterruptLevel,
irq_cfg: IrqCfg,
irq_cfg: InterruptConfig,
syscfg: Option<&mut Sysconfig>,
irqsel: Option<&mut Irqsel>,
) -> Self {
self.regs.interrupt_level(level_type);
) {
self.inner.regs.interrupt_level(level_type);
self.irq_enb(irq_cfg, syscfg, irqsel);
self
}
}
impl<I: PinId, C: InputConfig> Pin<I, Input<C>> {
/// See p.37 and p.38 of the programmers guide for more information.
#[inline]
pub fn filter_type(self, filter: FilterType, clksel: FilterClkSel) -> Self {
self.regs.filter_type(filter, clksel);
self
pub fn configure_filter_type(&mut self, filter: FilterType, clksel: FilterClkSel) {
self.inner.regs.filter_type(filter, clksel);
}
}
@ -705,47 +742,6 @@ where
}
}
//==================================================================================================
// Registers
//==================================================================================================
/// Provide a safe register interface for [`Pin`]s
///
/// This `struct` takes ownership of a [`PinId`] and provides an API to
/// access the corresponding registers.
pub(in crate::gpio) struct Registers<I: PinId> {
id: PhantomData<I>,
}
// [`Registers`] takes ownership of the [`PinId`], and [`Pin`] guarantees that
// each pin is a singleton, so this implementation is safe.
unsafe impl<I: PinId> RegisterInterface for Registers<I> {
#[inline]
fn id(&self) -> DynPinId {
I::DYN
}
}
impl<I: PinId> Registers<I> {
/// Create a new instance of [`Registers`]
///
/// # Safety
///
/// Users must never create two simultaneous instances of this `struct` with
/// the same [`PinId`]
#[inline]
unsafe fn new() -> Self {
Registers { id: PhantomData }
}
/// Provide a type-level equivalent for the
/// [`RegisterInterface::change_mode`] method.
#[inline]
pub(in crate::gpio) fn change_mode<M: PinMode>(&mut self) {
RegisterInterface::change_mode(self, M::DYN);
}
}
//==================================================================================================
// Pin definitions
//==================================================================================================
@ -756,8 +752,8 @@ macro_rules! pins {
) => {
paste!(
/// Collection of all the individual [`Pin`]s for a given port (PORTA or PORTB)
#[derive(Debug)]
pub struct $PinsName {
iocfg: Option<va108xx::Ioconfig>,
port: $Port,
$(
#[doc = "Pin " $Id]
@ -772,7 +768,6 @@ macro_rules! pins {
#[inline]
pub fn new(
syscfg: &mut va108xx::Sysconfig,
iocfg: Option<va108xx::Ioconfig>,
port: $Port
) -> $PinsName {
syscfg.peripheral_clk_enable().modify(|_, w| {
@ -781,7 +776,7 @@ macro_rules! pins {
w.ioconfig().set_bit()
});
$PinsName {
iocfg,
//iocfg,
port,
// Safe because we only create one `Pin` per `PinId`
$(
@ -798,8 +793,8 @@ macro_rules! pins {
}
/// Consumes the Pins struct and returns the port definitions
pub fn release(self) -> (Option<va108xx::Ioconfig>, $Port) {
(self.iocfg, self.port)
pub fn release(self) -> $Port {
self.port
}
}
);

23
va108xx-hal/src/gpio/reg.rs
View File

@ -1,5 +1,5 @@
use super::dynpins::{self, DynGroup, DynPinId, DynPinMode};
use super::pins::{FilterType, InterruptEdge, InterruptLevel, PinState};
use super::dynpin::{self, DynGroup, DynPinId, DynPinMode};
use super::pin::{FilterType, InterruptEdge, InterruptLevel, PinState};
use super::IsMaskedError;
use crate::clock::FilterClkSel;
use va108xx::{ioconfig, porta};
@ -30,7 +30,7 @@ impl From<DynPinMode> for ModeFields {
use DynPinMode::*;
match mode {
Input(config) => {
use dynpins::DynInput::*;
use dynpin::DynInput::*;
fields.dir = false;
match config {
Floating => (),
@ -44,7 +44,7 @@ impl From<DynPinMode> for ModeFields {
}
}
Output(config) => {
use dynpins::DynOutput::*;
use dynpin::DynOutput::*;
fields.dir = true;
match config {
PushPull => (),
@ -73,13 +73,6 @@ impl From<DynPinMode> for ModeFields {
//==================================================================================================
pub type PortReg = ioconfig::Porta;
/*
pub type IocfgPort = ioconfig::Porta;
#[repr(C)]
pub(super) struct IocfgPortGroup {
port: [IocfgPort; 32],
}
*/
/// Provide a safe register interface for pin objects
///
@ -293,7 +286,7 @@ pub(super) unsafe trait RegisterInterface {
/// Only useful for input pins
#[inline]
fn filter_type(&self, filter: FilterType, clksel: FilterClkSel) {
fn filter_type(&mut self, filter: FilterType, clksel: FilterClkSel) {
self.iocfg_port().modify(|_, w| {
// Safety: Only write to register for this Pin ID
unsafe {
@ -311,7 +304,7 @@ pub(super) unsafe trait RegisterInterface {
unsafe {
portreg
.datamask()
.modify(|r, w| w.bits(r.bits() | self.mask_32()))
.modify(|r, w| w.bits(r.bits() | self.mask_32()));
}
}
@ -323,7 +316,7 @@ pub(super) unsafe trait RegisterInterface {
unsafe {
portreg
.datamask()
.modify(|r, w| w.bits(r.bits() & !self.mask_32()))
.modify(|r, w| w.bits(r.bits() & !self.mask_32()));
}
}
@ -331,7 +324,7 @@ pub(super) unsafe trait RegisterInterface {
/// See p.52 of the programmers guide for more information.
/// When configured for pulse mode, a given pin will set the non-default state for exactly
/// one clock cycle before returning to the configured default state
fn pulse_mode(&self, enable: bool, default_state: PinState) {
fn pulse_mode(&mut self, enable: bool, default_state: PinState) {
let portreg = self.port_reg();
unsafe {
if enable {

960
va108xx-hal/src/i2c.rs
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File diff suppressed because it is too large Load Diff

56
va108xx-hal/src/lib.rs
View File

@ -1,5 +1,5 @@
#![no_std]
#![cfg_attr(docs_rs, feature(doc_auto_cfg))]
#![cfg_attr(docsrs, feature(doc_auto_cfg))]
pub use va108xx;
pub use va108xx as pac;
@ -15,9 +15,9 @@ pub mod time;
pub mod timer;
pub mod typelevel;
pub mod uart;
pub mod utility;
#[derive(Debug, Eq, Copy, Clone, PartialEq)]
#[cfg_attr(feature = "defmt", derive(defmt::Format))]
pub enum FunSel {
Sel1 = 0b01,
Sel2 = 0b10,
@ -25,12 +25,14 @@ pub enum FunSel {
}
#[derive(Debug, Copy, Clone, PartialEq, Eq)]
#[cfg_attr(feature = "defmt", derive(defmt::Format))]
pub enum PortSel {
PortA,
PortB,
}
#[derive(Copy, Clone, PartialEq, Eq)]
#[cfg_attr(feature = "defmt", derive(defmt::Format))]
pub enum PeripheralSelect {
PortA = 0,
PortB = 1,
@ -47,31 +49,39 @@ pub enum PeripheralSelect {
Gpio = 24,
}
/// Generic IRQ config which can be used to specify whether the HAL driver will
/// Generic interrupt config which can be used to specify whether the HAL driver will
/// use the IRQSEL register to route an interrupt, and whether the IRQ will be unmasked in the
/// Cortex-M0 NVIC. Both are generally necessary for IRQs to work, but the user might perform
/// this steps themselves
/// Cortex-M0 NVIC. Both are generally necessary for IRQs to work, but the user might want to
/// perform those steps themselves.
#[derive(Debug, PartialEq, Eq, Clone, Copy)]
pub struct IrqCfg {
pub struct InterruptConfig {
/// Interrupt target vector. Should always be set, might be required for disabling IRQs
pub irq: pac::Interrupt,
/// Specfiy whether IRQ should be routed to an IRQ vector using the IRQSEL peripheral
pub id: pac::Interrupt,
/// Specfiy whether IRQ should be routed to an IRQ vector using the IRQSEL peripheral.
pub route: bool,
/// Specify whether the IRQ is unmasked in the Cortex-M NVIC
pub enable: bool,
/// Specify whether the IRQ is unmasked in the Cortex-M NVIC. If an interrupt is used for
/// multiple purposes, the user can enable the interrupts themselves.
pub enable_in_nvic: bool,
}
impl IrqCfg {
pub fn new(irq: pac::Interrupt, route: bool, enable: bool) -> Self {
IrqCfg { irq, route, enable }
impl InterruptConfig {
pub fn new(id: pac::Interrupt, route: bool, enable_in_nvic: bool) -> Self {
InterruptConfig {
id,
route,
enable_in_nvic,
}
}
}
pub type IrqCfg = InterruptConfig;
#[derive(Debug, PartialEq, Eq)]
#[cfg_attr(feature = "defmt", derive(defmt::Format))]
pub struct InvalidPin(pub(crate) ());
/// Can be used to manually manipulate the function select of port pins
pub fn port_mux(
pub fn port_function_select(
ioconfig: &mut pac::Ioconfig,
port: PortSel,
pin: u8,
@ -98,3 +108,21 @@ pub fn port_mux(
}
}
}
/// Enable a specific interrupt using the NVIC peripheral.
///
/// # Safety
///
/// This function is `unsafe` because it can break mask-based critical sections.
#[inline]
pub unsafe fn enable_nvic_interrupt(irq: pac::Interrupt) {
unsafe {
cortex_m::peripheral::NVIC::unmask(irq);
}
}
/// Disable a specific interrupt using the NVIC peripheral.
#[inline]
pub fn disable_nvic_interrupt(irq: pac::Interrupt) {
cortex_m::peripheral::NVIC::mask(irq);
}

2
va108xx-hal/src/prelude.rs
View File

@ -1,3 +1,5 @@
//! Prelude
pub use fugit::ExtU32 as _;
pub use fugit::RateExtU32 as _;
pub use crate::time::*;

430
va108xx-hal/src/pwm.rs
View File

@ -4,17 +4,20 @@
//!
//! ## Examples
//!
//! - [PWM example](https://egit.irs.uni-stuttgart.de/rust/va108xx-hal/src/branch/main/examples/pwm.rs)
//! - [PWM example](https://egit.irs.uni-stuttgart.de/rust/va108xx-rs/src/branch/main/examples/simple/examples/pwm.rs)
use core::convert::Infallible;
use core::marker::PhantomData;
use crate::pac;
use crate::time::Hertz;
use crate::timer::{TimDynRegister, TimPin, TimRegInterface, ValidTim, ValidTimAndPin};
use crate::{clock::enable_peripheral_clock, gpio::DynPinId};
pub use crate::{gpio::PinId, time::Hertz, timer::*};
const DUTY_MAX: u16 = u16::MAX;
pub struct PwmBase {
#[derive(Debug)]
#[cfg_attr(feature = "defmt", derive(defmt::Format))]
pub(crate) struct PwmCommon {
sys_clk: Hertz,
/// For PWMB, this is the upper limit
current_duty: u16,
@ -32,123 +35,13 @@ enum StatusSelPwm {
pub struct PwmA {}
pub struct PwmB {}
//==================================================================================================
// Common
//==================================================================================================
macro_rules! pwm_common_func {
() => {
#[inline]
fn enable_pwm_a(&mut self) {
self.reg
.reg()
.ctrl()
.modify(|_, w| unsafe { w.status_sel().bits(StatusSelPwm::PwmA as u8) });
}
#[inline]
fn enable_pwm_b(&mut self) {
self.reg
.reg()
.ctrl()
.modify(|_, w| unsafe { w.status_sel().bits(StatusSelPwm::PwmB as u8) });
}
#[inline]
pub fn get_period(&self) -> Hertz {
self.pwm_base.current_period
}
#[inline]
pub fn set_period(&mut self, period: impl Into<Hertz>) {
self.pwm_base.current_period = period.into();
// Avoid division by 0
if self.pwm_base.current_period.raw() == 0 {
return;
}
self.pwm_base.current_rst_val =
self.pwm_base.sys_clk.raw() / self.pwm_base.current_period.raw();
self.reg
.reg()
.rst_value()
.write(|w| unsafe { w.bits(self.pwm_base.current_rst_val) });
}
#[inline]
pub fn disable(&mut self) {
self.reg.reg().ctrl().modify(|_, w| w.enable().clear_bit());
}
#[inline]
pub fn enable(&mut self) {
self.reg.reg().ctrl().modify(|_, w| w.enable().set_bit());
}
#[inline]
pub fn period(&self) -> Hertz {
self.pwm_base.current_period
}
#[inline(always)]
pub fn duty(&self) -> u16 {
self.pwm_base.current_duty
}
};
}
macro_rules! pwmb_func {
() => {
pub fn pwmb_lower_limit(&self) -> u16 {
self.pwm_base.current_lower_limit
}
pub fn pwmb_upper_limit(&self) -> u16 {
self.pwm_base.current_duty
}
/// Set the lower limit for PWMB
///
/// The PWM signal will be 1 as long as the current RST counter is larger than
/// the lower limit. For example, with a lower limit of 0.5 and and an upper limit
/// of 0.7, Only a fixed period between 0.5 * period and 0.7 * period will be in a high
/// state
pub fn set_pwmb_lower_limit(&mut self, duty: u16) {
self.pwm_base.current_lower_limit = duty;
let pwmb_val: u64 = (self.pwm_base.current_rst_val as u64
* self.pwm_base.current_lower_limit as u64)
/ DUTY_MAX as u64;
self.reg
.reg()
.pwmb_value()
.write(|w| unsafe { w.bits(pwmb_val as u32) });
}
/// Set the higher limit for PWMB
///
/// The PWM signal will be 1 as long as the current RST counter is smaller than
/// the higher limit. For example, with a lower limit of 0.5 and and an upper limit
/// of 0.7, Only a fixed period between 0.5 * period and 0.7 * period will be in a high
/// state
pub fn set_pwmb_upper_limit(&mut self, duty: u16) {
self.pwm_base.current_duty = duty;
let pwma_val: u64 = (self.pwm_base.current_rst_val as u64
* self.pwm_base.current_duty as u64)
/ DUTY_MAX as u64;
self.reg
.reg()
.pwma_value()
.write(|w| unsafe { w.bits(pwma_val as u32) });
}
};
}
//==================================================================================================
// Strongly typed PWM pin
//==================================================================================================
pub struct PwmPin<Pin: TimPin, Tim: ValidTim, Mode = PwmA> {
reg: TimAndPinRegister<Pin, Tim>,
pwm_base: PwmBase,
pin_and_tim: (Pin, Tim),
inner: ReducedPwmPin<Mode>,
mode: PhantomData<Mode>,
}
@ -158,36 +51,84 @@ where
{
/// Create a new stronlgy typed PWM pin
pub fn new(
vtp: (Pin, Tim),
sys_clk: impl Into<Hertz> + Copy,
sys_cfg: &mut pac::Sysconfig,
sys_clk: impl Into<Hertz> + Copy,
pin_and_tim: (Pin, Tim),
initial_period: impl Into<Hertz> + Copy,
) -> Self {
let mut pin = PwmPin {
pwm_base: PwmBase {
current_duty: 0,
current_lower_limit: 0,
current_period: initial_period.into(),
current_rst_val: 0,
sys_clk: sys_clk.into(),
},
reg: unsafe { TimAndPinRegister::new(vtp.0, vtp.1) },
pin_and_tim,
inner: ReducedPwmPin::<Mode>::new(
Tim::TIM_ID,
Pin::DYN,
PwmCommon {
current_duty: 0,
current_lower_limit: 0,
current_period: initial_period.into(),
current_rst_val: 0,
sys_clk: sys_clk.into(),
},
),
//unsafe { TimAndPin::new(tim_and_pin.0, tim_and_pin.1) },
mode: PhantomData,
};
enable_peripheral_clock(sys_cfg, crate::clock::PeripheralClocks::Gpio);
enable_peripheral_clock(sys_cfg, crate::clock::PeripheralClocks::Ioconfig);
sys_cfg
.tim_clk_enable()
.modify(|r, w| unsafe { w.bits(r.bits() | pin.reg.mask_32()) });
.modify(|r, w| unsafe { w.bits(r.bits() | pin.pin_and_tim.1.mask_32()) });
pin.enable_pwm_a();
pin.set_period(initial_period);
pin
}
pub fn release(self) -> (Pin, Tim) {
self.reg.release()
pub fn downgrade(self) -> ReducedPwmPin<Mode> {
self.inner
}
pwm_common_func!();
pub fn release(self) -> (Pin, Tim) {
self.pin_and_tim
}
#[inline]
fn enable_pwm_a(&mut self) {
self.inner.enable_pwm_a();
}
#[inline]
fn enable_pwm_b(&mut self) {
self.inner.enable_pwm_b();
}
#[inline]
pub fn get_period(&self) -> Hertz {
self.inner.get_period()
}
#[inline]
pub fn set_period(&mut self, period: impl Into<Hertz>) {
self.inner.set_period(period);
}
#[inline]
pub fn disable(&mut self) {
self.inner.disable();
}
#[inline]
pub fn enable(&mut self) {
self.inner.enable();
}
#[inline]
pub fn period(&self) -> Hertz {
self.inner.period()
}
#[inline(always)]
pub fn duty(&self) -> u16 {
self.inner.duty()
}
}
impl<Pin: TimPin, Tim: ValidTim> From<PwmPin<Pin, Tim, PwmA>> for PwmPin<Pin, Tim, PwmB>
@ -196,9 +137,9 @@ where
{
fn from(other: PwmPin<Pin, Tim, PwmA>) -> Self {
let mut pwmb = Self {
reg: other.reg,
pwm_base: other.pwm_base,
mode: PhantomData,
pin_and_tim: other.pin_and_tim,
inner: other.inner.into(),
};
pwmb.enable_pwm_b();
pwmb
@ -210,13 +151,13 @@ where
(PIN, TIM): ValidTimAndPin<PIN, TIM>,
{
fn from(other: PwmPin<PIN, TIM, PwmB>) -> Self {
let mut pwmb = Self {
reg: other.reg,
pwm_base: other.pwm_base,
let mut pwma = Self {
mode: PhantomData,
pin_and_tim: other.pin_and_tim,
inner: other.inner.into(),
};
pwmb.enable_pwm_a();
pwmb
pwma.enable_pwm_a();
pwma
}
}
@ -225,12 +166,13 @@ where
(Pin, Tim): ValidTimAndPin<Pin, Tim>,
{
pub fn pwma(
vtp: (Pin, Tim),
sys_clk: impl Into<Hertz> + Copy,
sys_cfg: &mut pac::Sysconfig,
sys_clk: impl Into<Hertz> + Copy,
pin_and_tim: (Pin, Tim),
initial_period: impl Into<Hertz> + Copy,
) -> Self {
let mut pin: PwmPin<Pin, Tim, PwmA> = Self::new(vtp, sys_clk, sys_cfg, initial_period);
let mut pin: PwmPin<Pin, Tim, PwmA> =
Self::new(sys_cfg, sys_clk, pin_and_tim, initial_period);
pin.enable_pwm_a();
pin
}
@ -241,12 +183,13 @@ where
(Pin, Tim): ValidTimAndPin<Pin, Tim>,
{
pub fn pwmb(
vtp: (Pin, Tim),
sys_clk: impl Into<Hertz> + Copy,
sys_cfg: &mut pac::Sysconfig,
sys_clk: impl Into<Hertz> + Copy,
pin_and_tim: (Pin, Tim),
initial_period: impl Into<Hertz> + Copy,
) -> Self {
let mut pin: PwmPin<Pin, Tim, PwmB> = Self::new(vtp, sys_clk, sys_cfg, initial_period);
let mut pin: PwmPin<Pin, Tim, PwmB> =
Self::new(sys_cfg, sys_clk, pin_and_tim, initial_period);
pin.enable_pwm_b();
pin
}
@ -258,33 +201,107 @@ where
/// Reduced version where type information is deleted
pub struct ReducedPwmPin<Mode = PwmA> {
reg: TimDynRegister,
pwm_base: PwmBase,
pin_id: DynPinId,
dyn_reg: TimDynRegister,
common: PwmCommon,
mode: PhantomData<Mode>,
}
impl<PIN: TimPin, TIM: ValidTim> From<PwmPin<PIN, TIM>> for ReducedPwmPin<PwmA> {
fn from(pwm_pin: PwmPin<PIN, TIM>) -> Self {
ReducedPwmPin {
reg: TimDynRegister::from(pwm_pin.reg),
pwm_base: pwm_pin.pwm_base,
pin_id: PIN::DYN,
impl<Mode> ReducedPwmPin<Mode> {
pub(crate) fn new(tim_id: u8, pin_id: DynPinId, common: PwmCommon) -> Self {
Self {
dyn_reg: TimDynRegister { tim_id, pin_id },
common,
mode: PhantomData,
}
}
}
impl<MODE> ReducedPwmPin<MODE> {
pwm_common_func!();
impl<Mode> ReducedPwmPin<Mode> {
#[inline]
fn enable_pwm_a(&mut self) {
self.dyn_reg
.reg_block()
.ctrl()
.modify(|_, w| unsafe { w.status_sel().bits(StatusSelPwm::PwmA as u8) });
}
#[inline]
fn enable_pwm_b(&mut self) {
self.dyn_reg
.reg_block()
.ctrl()
.modify(|_, w| unsafe { w.status_sel().bits(StatusSelPwm::PwmB as u8) });
}
#[inline]
pub fn get_period(&self) -> Hertz {
self.common.current_period
}
#[inline]
pub fn set_period(&mut self, period: impl Into<Hertz>) {
self.common.current_period = period.into();
// Avoid division by 0
if self.common.current_period.raw() == 0 {
return;
}
self.common.current_rst_val = self.common.sys_clk.raw() / self.common.current_period.raw();
self.dyn_reg
.reg_block()
.rst_value()
.write(|w| unsafe { w.bits(self.common.current_rst_val) });
}
#[inline]
pub fn disable(&mut self) {
self.dyn_reg
.reg_block()
.ctrl()
.modify(|_, w| w.enable().clear_bit());
}
#[inline]
pub fn enable(&mut self) {
self.dyn_reg
.reg_block()
.ctrl()
.modify(|_, w| w.enable().set_bit());
}
#[inline]
pub fn period(&self) -> Hertz {
self.common.current_period
}
#[inline(always)]
pub fn duty(&self) -> u16 {
self.common.current_duty
}
}
impl<Pin: TimPin, Tim: ValidTim> From<PwmPin<Pin, Tim, PwmA>> for ReducedPwmPin<PwmA>
where
(Pin, Tim): ValidTimAndPin<Pin, Tim>,
{
fn from(value: PwmPin<Pin, Tim, PwmA>) -> Self {
value.downgrade()
}
}
impl<Pin: TimPin, Tim: ValidTim> From<PwmPin<Pin, Tim, PwmB>> for ReducedPwmPin<PwmB>
where
(Pin, Tim): ValidTimAndPin<Pin, Tim>,
{
fn from(value: PwmPin<Pin, Tim, PwmB>) -> Self {
value.downgrade()
}
}
impl From<ReducedPwmPin<PwmA>> for ReducedPwmPin<PwmB> {
fn from(other: ReducedPwmPin<PwmA>) -> Self {
let mut pwmb = Self {
reg: other.reg,
pwm_base: other.pwm_base,
pin_id: other.pin_id,
dyn_reg: other.dyn_reg,
common: other.common,
mode: PhantomData,
};
pwmb.enable_pwm_b();
@ -295,9 +312,8 @@ impl From<ReducedPwmPin<PwmA>> for ReducedPwmPin<PwmB> {
impl From<ReducedPwmPin<PwmB>> for ReducedPwmPin<PwmA> {
fn from(other: ReducedPwmPin<PwmB>) -> Self {
let mut pwmb = Self {
reg: other.reg,
pwm_base: other.pwm_base,
pin_id: other.pin_id,
dyn_reg: other.dyn_reg,
common: other.common,
mode: PhantomData,
};
pwmb.enable_pwm_a();
@ -309,15 +325,83 @@ impl From<ReducedPwmPin<PwmB>> for ReducedPwmPin<PwmA> {
// PWMB implementations
//==================================================================================================
impl<PIN: TimPin, TIM: ValidTim> PwmPin<PIN, TIM, PwmB>
impl<Pin: TimPin, Tim: ValidTim> PwmPin<Pin, Tim, PwmB>
where
(PIN, TIM): ValidTimAndPin<PIN, TIM>,
(Pin, Tim): ValidTimAndPin<Pin, Tim>,
{
pwmb_func!();
pub fn pwmb_lower_limit(&self) -> u16 {
self.inner.pwmb_lower_limit()
}
pub fn pwmb_upper_limit(&self) -> u16 {
self.inner.pwmb_upper_limit()
}
/// Set the lower limit for PWMB
///
/// The PWM signal will be 1 as long as the current RST counter is larger than
/// the lower limit. For example, with a lower limit of 0.5 and and an upper limit
/// of 0.7, Only a fixed period between 0.5 * period and 0.7 * period will be in a high
/// state
pub fn set_pwmb_lower_limit(&mut self, duty: u16) {
self.inner.set_pwmb_lower_limit(duty);
}
/// Set the higher limit for PWMB
///
/// The PWM signal will be 1 as long as the current RST counter is smaller than
/// the higher limit. For example, with a lower limit of 0.5 and and an upper limit
/// of 0.7, Only a fixed period between 0.5 * period and 0.7 * period will be in a high
/// state
pub fn set_pwmb_upper_limit(&mut self, duty: u16) {
self.inner.set_pwmb_upper_limit(duty);
}
}
impl ReducedPwmPin<PwmB> {
pwmb_func!();
#[inline(always)]
pub fn pwmb_lower_limit(&self) -> u16 {
self.common.current_lower_limit
}
#[inline(always)]
pub fn pwmb_upper_limit(&self) -> u16 {
self.common.current_duty
}
/// Set the lower limit for PWMB
///
/// The PWM signal will be 1 as long as the current RST counter is larger than
/// the lower limit. For example, with a lower limit of 0.5 and and an upper limit
/// of 0.7, Only a fixed period between 0.5 * period and 0.7 * period will be in a high
/// state
#[inline(always)]
pub fn set_pwmb_lower_limit(&mut self, duty: u16) {
self.common.current_lower_limit = duty;
let pwmb_val: u64 = (self.common.current_rst_val as u64
* self.common.current_lower_limit as u64)
/ DUTY_MAX as u64;
self.dyn_reg
.reg_block()
.pwmb_value()
.write(|w| unsafe { w.bits(pwmb_val as u32) });
}
/// Set the higher limit for PWMB
///
/// The PWM signal will be 1 as long as the current RST counter is smaller than
/// the higher limit. For example, with a lower limit of 0.5 and and an upper limit
/// of 0.7, Only a fixed period between 0.5 * period and 0.7 * period will be in a high
/// state
pub fn set_pwmb_upper_limit(&mut self, duty: u16) {
self.common.current_duty = duty;
let pwma_val: u64 = (self.common.current_rst_val as u64 * self.common.current_duty as u64)
/ DUTY_MAX as u64;
self.dyn_reg
.reg_block()
.pwma_value()
.write(|w| unsafe { w.bits(pwma_val as u32) });
}
}
//==================================================================================================
@ -340,12 +424,12 @@ impl embedded_hal::pwm::SetDutyCycle for ReducedPwmPin {
#[inline]
fn set_duty_cycle(&mut self, duty: u16) -> Result<(), Self::Error> {
self.pwm_base.current_duty = duty;
let pwma_val: u64 = (self.pwm_base.current_rst_val as u64
* (DUTY_MAX as u64 - self.pwm_base.current_duty as u64))
self.common.current_duty = duty;
let pwma_val: u64 = (self.common.current_rst_val as u64
* (DUTY_MAX as u64 - self.common.current_duty as u64))
/ DUTY_MAX as u64;
self.reg
.reg()
self.dyn_reg
.reg_block()
.pwma_value()
.write(|w| unsafe { w.bits(pwma_val as u32) });
Ok(())
@ -360,15 +444,7 @@ impl<Pin: TimPin, Tim: ValidTim> embedded_hal::pwm::SetDutyCycle for PwmPin<Pin,
#[inline]
fn set_duty_cycle(&mut self, duty: u16) -> Result<(), Self::Error> {
self.pwm_base.current_duty = duty;
let pwma_val: u64 = (self.pwm_base.current_rst_val as u64
* (DUTY_MAX as u64 - self.pwm_base.current_duty as u64))
/ DUTY_MAX as u64;
self.reg
.reg()
.pwma_value()
.write(|w| unsafe { w.bits(pwma_val as u32) });
Ok(())
self.inner.set_duty_cycle(duty)
}
}

1947
va108xx-hal/src/spi.rs
View File

File diff suppressed because it is too large Load Diff

19
va108xx-hal/src/sysconfig.rs
View File

@ -1,44 +1,45 @@
use crate::{pac, PeripheralSelect};
#[derive(PartialEq, Eq, Debug)]
pub struct InvalidounterResetVal(pub(crate) ());
#[cfg_attr(feature = "defmt", derive(defmt::Format))]
pub struct InvalidCounterResetVal(pub(crate) ());
/// Enable scrubbing for the ROM
///
/// Returns [`UtilityError::InvalidCounterResetVal`] if the scrub rate is 0
/// Returns [InvalidCounterResetVal] if the scrub rate is 0
/// (equivalent to disabling) or larger than 24 bits
pub fn enable_rom_scrubbing(
syscfg: &mut pac::Sysconfig,
scrub_rate: u32,
) -> Result<(), InvalidounterResetVal> {
) -> Result<(), InvalidCounterResetVal> {
if scrub_rate == 0 || scrub_rate > u32::pow(2, 24) {
return Err(InvalidounterResetVal(()));
return Err(InvalidCounterResetVal(()));
}
syscfg.rom_scrub().write(|w| unsafe { w.bits(scrub_rate) });
Ok(())
}
pub fn disable_rom_scrubbing(syscfg: &mut pac::Sysconfig) {
syscfg.rom_scrub().write(|w| unsafe { w.bits(0) })
syscfg.rom_scrub().write(|w| unsafe { w.bits(0) });
}
/// Enable scrubbing for the RAM
///
/// Returns [`UtilityError::InvalidCounterResetVal`] if the scrub rate is 0
/// Returns [InvalidCounterResetVal] if the scrub rate is 0
/// (equivalent to disabling) or larger than 24 bits
pub fn enable_ram_scrubbing(
syscfg: &mut pac::Sysconfig,
scrub_rate: u32,
) -> Result<(), InvalidounterResetVal> {
) -> Result<(), InvalidCounterResetVal> {
if scrub_rate == 0 || scrub_rate > u32::pow(2, 24) {
return Err(InvalidounterResetVal(()));
return Err(InvalidCounterResetVal(()));
}
syscfg.ram_scrub().write(|w| unsafe { w.bits(scrub_rate) });
Ok(())
}
pub fn disable_ram_scrubbing(syscfg: &mut pac::Sysconfig) {
syscfg.ram_scrub().write(|w| unsafe { w.bits(0) })
syscfg.ram_scrub().write(|w| unsafe { w.bits(0) });
}
/// Clear the reset bit. This register is active low, so doing this will hold the peripheral

407
va108xx-hal/src/timer.rs
View File

@ -2,11 +2,12 @@
//!
//! ## Examples
//!
//! - [MS and second tick implementation](https://egit.irs.uni-stuttgart.de/rust/va108xx-hal/src/branch/main/examples/timer-ticks.rs)
//! - [Cascade feature example](https://egit.irs.uni-stuttgart.de/rust/va108xx-hal/src/branch/main/examples/cascade.rs)
pub use crate::IrqCfg;
//! - [MS and second tick implementation](https://egit.irs.uni-stuttgart.de/rust/va108xx-rs/src/branch/main/examples/simple/examples/timer-ticks.rs)
//! - [Cascade feature example](https://egit.irs.uni-stuttgart.de/rust/va108xx-rs/src/branch/main/examples/simple/examples/cascade.rs)
pub use crate::InterruptConfig;
use crate::{
clock::{enable_peripheral_clock, PeripheralClocks},
enable_nvic_interrupt,
gpio::{
AltFunc1, AltFunc2, AltFunc3, DynPinId, Pin, PinId, PA0, PA1, PA10, PA11, PA12, PA13, PA14,
PA15, PA2, PA24, PA25, PA26, PA27, PA28, PA29, PA3, PA30, PA31, PA4, PA5, PA6, PA7, PA8,
@ -17,15 +18,56 @@ use crate::{
time::Hertz,
timer,
typelevel::Sealed,
utility::unmask_irq,
};
use core::cell::Cell;
use cortex_m::interrupt::Mutex;
use critical_section::Mutex;
use fugit::RateExtU32;
const IRQ_DST_NONE: u32 = 0xffffffff;
pub static MS_COUNTER: Mutex<Cell<u32>> = Mutex::new(Cell::new(0));
/// Get the peripheral block of a TIM peripheral given the index.
///
/// This function panics if the given index is greater than 23.
///
/// # Safety
///
/// This returns a direct handle to the peripheral block, which allows to circumvent ownership
/// rules for the peripheral block. You have to ensure that the retrieved peripheral block is not
/// used by any other software component.
#[inline(always)]
pub const unsafe fn get_tim_raw(tim_idx: usize) -> &'static pac::tim0::RegisterBlock {
match tim_idx {
0 => unsafe { &*pac::Tim0::ptr() },
1 => unsafe { &*pac::Tim1::ptr() },
2 => unsafe { &*pac::Tim2::ptr() },
3 => unsafe { &*pac::Tim3::ptr() },
4 => unsafe { &*pac::Tim4::ptr() },
5 => unsafe { &*pac::Tim5::ptr() },
6 => unsafe { &*pac::Tim6::ptr() },
7 => unsafe { &*pac::Tim7::ptr() },
8 => unsafe { &*pac::Tim8::ptr() },
9 => unsafe { &*pac::Tim9::ptr() },
10 => unsafe { &*pac::Tim10::ptr() },
11 => unsafe { &*pac::Tim11::ptr() },
12 => unsafe { &*pac::Tim12::ptr() },
13 => unsafe { &*pac::Tim13::ptr() },
14 => unsafe { &*pac::Tim14::ptr() },
15 => unsafe { &*pac::Tim15::ptr() },
16 => unsafe { &*pac::Tim16::ptr() },
17 => unsafe { &*pac::Tim17::ptr() },
18 => unsafe { &*pac::Tim18::ptr() },
19 => unsafe { &*pac::Tim19::ptr() },
20 => unsafe { &*pac::Tim20::ptr() },
21 => unsafe { &*pac::Tim21::ptr() },
22 => unsafe { &*pac::Tim22::ptr() },
23 => unsafe { &*pac::Tim23::ptr() },
_ => {
panic!("invalid alarm timer index")
}
}
}
//==================================================================================================
// Defintions
//==================================================================================================
@ -37,6 +79,7 @@ pub enum Event {
}
#[derive(Default, Debug, PartialEq, Eq, Copy, Clone)]
#[cfg_attr(feature = "defmt", derive(defmt::Format))]
pub struct CascadeCtrl {
/// Enable Cascade 0 signal active as a requirement for counting
pub enb_start_src_csd0: bool,
@ -66,31 +109,53 @@ pub struct CascadeCtrl {
}
#[derive(Debug, PartialEq, Eq)]
#[cfg_attr(feature = "defmt", derive(defmt::Format))]
pub enum CascadeSel {
Csd0 = 0,
Csd1 = 1,
Csd2 = 2,
}
#[derive(Debug, PartialEq, Eq)]
#[cfg_attr(feature = "defmt", derive(defmt::Format))]
pub struct InvalidCascadeSourceId;
/// The numbers are the base numbers for bundles like PORTA, PORTB or TIM
#[derive(Debug, PartialEq, Eq)]
#[cfg_attr(feature = "defmt", derive(defmt::Format))]
#[repr(u8)]
pub enum CascadeSource {
PortABase = 0,
PortBBase = 32,
TimBase = 64,
PortA(u8),
PortB(u8),
Tim(u8),
RamSbe = 96,
RamMbe = 97,
RomSbe = 98,
RomMbe = 99,
Txev = 100,
ClockDividerBase = 120,
ClockDivider(u8),
}
#[derive(Debug, PartialEq, Eq)]
pub enum TimerErrors {
Canceled,
/// Invalid input for Cascade source
InvalidCsdSourceInput,
impl CascadeSource {
fn id(&self) -> Result<u8, InvalidCascadeSourceId> {
let port_check = |base: u8, id: u8, len: u8| {
if id > len - 1 {
return Err(InvalidCascadeSourceId);
}
Ok(base + id)
};
match self {
CascadeSource::PortA(id) => port_check(0, *id, 32),
CascadeSource::PortB(id) => port_check(32, *id, 32),
CascadeSource::Tim(id) => port_check(64, *id, 24),
CascadeSource::RamSbe => Ok(96),
CascadeSource::RamMbe => Ok(97),
CascadeSource::RomSbe => Ok(98),
CascadeSource::RomMbe => Ok(99),
CascadeSource::Txev => Ok(100),
CascadeSource::ClockDivider(id) => port_check(120, *id, 8),
}
}
}
//==================================================================================================
@ -223,11 +288,11 @@ pub type TimRegBlock = tim0::RegisterBlock;
///
/// # Safety
///
/// Users should only implement the [`tim_id`] function. No default function
/// Users should only implement the [Self::tim_id] function. No default function
/// implementations should be overridden. The implementing type must also have
/// "control" over the corresponding pin ID, i.e. it must guarantee that a each
/// pin ID is a singleton.
pub(super) unsafe trait TimRegInterface {
pub unsafe trait TimRegInterface {
fn tim_id(&self) -> u8;
const PORT_BASE: *const tim0::RegisterBlock = pac::Tim0::ptr() as *const _;
@ -235,7 +300,7 @@ pub(super) unsafe trait TimRegInterface {
/// All 24 TIM blocks are identical. This helper functions returns the correct
/// memory mapped peripheral depending on the TIM ID.
#[inline(always)]
fn reg(&self) -> &TimRegBlock {
fn reg_block(&self) -> &TimRegBlock {
unsafe { &*Self::PORT_BASE.offset(self.tim_id() as isize) }
}
@ -256,7 +321,7 @@ pub(super) unsafe trait TimRegInterface {
va108xx::Peripherals::steal()
.sysconfig
.tim_reset()
.modify(|r, w| w.bits(r.bits() & !self.mask_32()))
.modify(|r, w| w.bits(r.bits() & !self.mask_32()));
}
}
@ -267,75 +332,21 @@ pub(super) unsafe trait TimRegInterface {
va108xx::Peripherals::steal()
.sysconfig
.tim_reset()
.modify(|r, w| w.bits(r.bits() | self.mask_32()))
.modify(|r, w| w.bits(r.bits() | self.mask_32()));
}
}
}
/// Provide a safe register interface for [`ValidTimAndPin`]s
///
/// This `struct` takes ownership of a [`ValidTimAndPin`] and provides an API to
/// access the corresponding registers.
pub(super) struct TimAndPinRegister<Pin: TimPin, Tim: ValidTim> {
pin: Pin,
tim: Tim,
}
pub(super) struct TimRegister<TIM: ValidTim> {
tim: TIM,
}
impl<TIM: ValidTim> TimRegister<TIM> {
#[inline]
pub(super) unsafe fn new(tim: TIM) -> Self {
TimRegister { tim }
}
pub(super) fn release(self) -> TIM {
self.tim
}
}
unsafe impl<TIM: ValidTim> TimRegInterface for TimRegister<TIM> {
unsafe impl<Tim: ValidTim> TimRegInterface for Tim {
fn tim_id(&self) -> u8 {
TIM::TIM_ID
Tim::TIM_ID
}
}
impl<PIN: TimPin, TIM: ValidTim> TimAndPinRegister<PIN, TIM>
where
(PIN, TIM): ValidTimAndPin<PIN, TIM>,
{
#[inline]
pub(super) unsafe fn new(pin: PIN, tim: TIM) -> Self {
TimAndPinRegister { pin, tim }
}
pub(super) fn release(self) -> (PIN, TIM) {
(self.pin, self.tim)
}
}
unsafe impl<PIN: TimPin, TIM: ValidTim> TimRegInterface for TimAndPinRegister<PIN, TIM> {
#[inline(always)]
fn tim_id(&self) -> u8 {
TIM::TIM_ID
}
}
pub(super) struct TimDynRegister {
tim_id: u8,
pub(crate) struct TimDynRegister {
pub(crate) tim_id: u8,
#[allow(dead_code)]
pin_id: DynPinId,
}
impl<PIN: TimPin, TIM: ValidTim> From<TimAndPinRegister<PIN, TIM>> for TimDynRegister {
fn from(_reg: TimAndPinRegister<PIN, TIM>) -> Self {
Self {
tim_id: TIM::TIM_ID,
pin_id: PIN::DYN,
}
}
pub(crate) pin_id: DynPinId,
}
unsafe impl TimRegInterface for TimDynRegister {
@ -350,105 +361,42 @@ unsafe impl TimRegInterface for TimDynRegister {
//==================================================================================================
/// Hardware timers
pub struct CountDownTimer<TIM: ValidTim> {
tim: TimRegister<TIM>,
pub struct CountdownTimer<Tim: ValidTim> {
tim: Tim,
curr_freq: Hertz,
irq_cfg: Option<IrqCfg>,
irq_cfg: Option<InterruptConfig>,
sys_clk: Hertz,
rst_val: u32,
last_cnt: u32,
listening: bool,
}
fn enable_tim_clk(syscfg: &mut pac::Sysconfig, idx: u8) {
#[inline(always)]
pub fn enable_tim_clk(syscfg: &mut pac::Sysconfig, idx: u8) {
syscfg
.tim_clk_enable()
.modify(|r, w| unsafe { w.bits(r.bits() | (1 << idx)) });
}
unsafe impl<TIM: ValidTim> TimRegInterface for CountDownTimer<TIM> {
#[inline(always)]
pub fn disable_tim_clk(syscfg: &mut pac::Sysconfig, idx: u8) {
syscfg
.tim_clk_enable()
.modify(|r, w| unsafe { w.bits(r.bits() & !(1 << idx)) });
}
unsafe impl<TIM: ValidTim> TimRegInterface for CountdownTimer<TIM> {
fn tim_id(&self) -> u8 {
TIM::TIM_ID
}
}
macro_rules! csd_sel {
($func_name:ident, $csd_reg:ident) => {
/// Configure the Cascade sources
pub fn $func_name(
&mut self,
src: CascadeSource,
id: Option<u8>,
) -> Result<(), TimerErrors> {
let mut id_num = 0;
if let CascadeSource::PortABase
| CascadeSource::PortBBase
| CascadeSource::ClockDividerBase
| CascadeSource::TimBase = src
{
if id.is_none() {
return Err(TimerErrors::InvalidCsdSourceInput);
}
}
if id.is_some() {
id_num = id.unwrap();
}
match src {
CascadeSource::PortABase => {
if id_num > 55 {
return Err(TimerErrors::InvalidCsdSourceInput);
}
self.tim.reg().$csd_reg().write(|w| unsafe {
w.cassel().bits(CascadeSource::PortABase as u8 + id_num)
});
Ok(())
}
CascadeSource::PortBBase => {
if id_num > 23 {
return Err(TimerErrors::InvalidCsdSourceInput);
}
self.tim.reg().$csd_reg().write(|w| unsafe {
w.cassel().bits(CascadeSource::PortBBase as u8 + id_num)
});
Ok(())
}
CascadeSource::TimBase => {
if id_num > 23 {
return Err(TimerErrors::InvalidCsdSourceInput);
}
self.tim.reg().$csd_reg().write(|w| unsafe {
w.cassel().bits(CascadeSource::TimBase as u8 + id_num)
});
Ok(())
}
CascadeSource::ClockDividerBase => {
if id_num > 7 {
return Err(TimerErrors::InvalidCsdSourceInput);
}
self.tim.reg().cascade0().write(|w| unsafe {
w.cassel()
.bits(CascadeSource::ClockDividerBase as u8 + id_num)
});
Ok(())
}
_ => {
self.tim
.reg()
.$csd_reg()
.write(|w| unsafe { w.cassel().bits(src as u8) });
Ok(())
}
}
}
};
}
impl<TIM: ValidTim> CountDownTimer<TIM> {
impl<Tim: ValidTim> CountdownTimer<Tim> {
/// Configures a TIM peripheral as a periodic count down timer
pub fn new(syscfg: &mut pac::Sysconfig, sys_clk: impl Into<Hertz>, tim: TIM) -> Self {
enable_tim_clk(syscfg, TIM::TIM_ID);
let cd_timer = CountDownTimer {
tim: unsafe { TimRegister::new(tim) },
pub fn new(syscfg: &mut pac::Sysconfig, sys_clk: impl Into<Hertz>, tim: Tim) -> Self {
enable_tim_clk(syscfg, Tim::TIM_ID);
let cd_timer = CountdownTimer {
tim,
sys_clk: sys_clk.into(),
irq_cfg: None,
rst_val: 0,
@ -458,7 +406,7 @@ impl<TIM: ValidTim> CountDownTimer<TIM> {
};
cd_timer
.tim
.reg()
.reg_block()
.ctrl()
.modify(|_, w| w.enable().set_bit());
cd_timer
@ -469,13 +417,13 @@ impl<TIM: ValidTim> CountDownTimer<TIM> {
pub fn listen(
&mut self,
event: Event,
irq_cfg: IrqCfg,
irq_cfg: InterruptConfig,
irq_sel: Option<&mut pac::Irqsel>,
sys_cfg: Option<&mut pac::Sysconfig>,
) {
match event {
Event::TimeOut => {
cortex_m::peripheral::NVIC::mask(irq_cfg.irq);
cortex_m::peripheral::NVIC::mask(irq_cfg.id);
self.irq_cfg = Some(irq_cfg);
if irq_cfg.route {
if let Some(sys_cfg) = sys_cfg {
@ -483,8 +431,8 @@ impl<TIM: ValidTim> CountDownTimer<TIM> {
}
if let Some(irq_sel) = irq_sel {
irq_sel
.tim0(TIM::TIM_ID as usize)
.write(|w| unsafe { w.bits(irq_cfg.irq as u32) });
.tim0(Tim::TIM_ID as usize)
.write(|w| unsafe { w.bits(irq_cfg.id as u32) });
}
}
self.listening = true;
@ -502,7 +450,7 @@ impl<TIM: ValidTim> CountDownTimer<TIM> {
Event::TimeOut => {
enable_peripheral_clock(syscfg, PeripheralClocks::Irqsel);
irqsel
.tim0(TIM::TIM_ID as usize)
.tim0(Tim::TIM_ID as usize)
.write(|w| unsafe { w.bits(IRQ_DST_NONE) });
self.disable_interrupt();
self.listening = false;
@ -512,25 +460,37 @@ impl<TIM: ValidTim> CountDownTimer<TIM> {
#[inline(always)]
pub fn enable_interrupt(&mut self) {
self.tim.reg().ctrl().modify(|_, w| w.irq_enb().set_bit());
self.tim
.reg_block()
.ctrl()
.modify(|_, w| w.irq_enb().set_bit());
}
#[inline(always)]
pub fn disable_interrupt(&mut self) {
self.tim.reg().ctrl().modify(|_, w| w.irq_enb().clear_bit());
self.tim
.reg_block()
.ctrl()
.modify(|_, w| w.irq_enb().clear_bit());
}
pub fn release(self, syscfg: &mut pac::Sysconfig) -> TIM {
self.tim.reg().ctrl().write(|w| w.enable().clear_bit());
pub fn release(self, syscfg: &mut pac::Sysconfig) -> Tim {
self.tim
.reg_block()
.ctrl()
.write(|w| w.enable().clear_bit());
syscfg
.tim_clk_enable()
.modify(|r, w| unsafe { w.bits(r.bits() & !(1 << TIM::TIM_ID)) });
self.tim.release()
.modify(|r, w| unsafe { w.bits(r.bits() & !(1 << Tim::TIM_ID)) });
self.tim
}
/// Load the count down timer with a timeout but do not start it.
pub fn load(&mut self, timeout: impl Into<Hertz>) {
self.tim.reg().ctrl().modify(|_, w| w.enable().clear_bit());
self.tim
.reg_block()
.ctrl()
.modify(|_, w| w.enable().clear_bit());
self.curr_freq = timeout.into();
self.rst_val = self.sys_clk.raw() / self.curr_freq.raw();
self.set_reload(self.rst_val);
@ -539,45 +499,57 @@ impl<TIM: ValidTim> CountDownTimer<TIM> {
#[inline(always)]
pub fn set_reload(&mut self, val: u32) {
self.tim.reg().rst_value().write(|w| unsafe { w.bits(val) });
self.tim
.reg_block()
.rst_value()
.write(|w| unsafe { w.bits(val) });
}
#[inline(always)]
pub fn set_count(&mut self, val: u32) {
self.tim.reg().cnt_value().write(|w| unsafe { w.bits(val) });
self.tim
.reg_block()
.cnt_value()
.write(|w| unsafe { w.bits(val) });
}
#[inline(always)]
pub fn count(&self) -> u32 {
self.tim.reg().cnt_value().read().bits()
self.tim.reg_block().cnt_value().read().bits()
}
#[inline(always)]
pub fn enable(&mut self) {
self.tim.reg().ctrl().modify(|_, w| w.enable().set_bit());
if let Some(irq_cfg) = self.irq_cfg {
self.enable_interrupt();
if irq_cfg.enable {
unmask_irq(irq_cfg.irq);
if irq_cfg.enable_in_nvic {
unsafe { enable_nvic_interrupt(irq_cfg.id) };
}
}
self.tim
.reg_block()
.enable()
.write(|w| unsafe { w.bits(1) });
}
#[inline(always)]
pub fn disable(&mut self) {
self.tim.reg().ctrl().modify(|_, w| w.enable().clear_bit());
self.tim
.reg_block()
.enable()
.write(|w| unsafe { w.bits(0) });
}
/// Disable the counter, setting both enable and active bit to 0
pub fn auto_disable(self, enable: bool) -> Self {
if enable {
self.tim
.reg()
.reg_block()
.ctrl()
.modify(|_, w| w.auto_disable().set_bit());
} else {
self.tim
.reg()
.reg_block()
.ctrl()
.modify(|_, w| w.auto_disable().clear_bit());
}
@ -591,12 +563,12 @@ impl<TIM: ValidTim> CountDownTimer<TIM> {
pub fn auto_deactivate(self, enable: bool) -> Self {
if enable {
self.tim
.reg()
.reg_block()
.ctrl()
.modify(|_, w| w.auto_deactivate().set_bit());
} else {
self.tim
.reg()
.reg_block()
.ctrl()
.modify(|_, w| w.auto_deactivate().clear_bit());
}
@ -605,7 +577,7 @@ impl<TIM: ValidTim> CountDownTimer<TIM> {
/// Configure the cascade parameters
pub fn cascade_control(&mut self, ctrl: CascadeCtrl) {
self.tim.reg().csd_ctrl().write(|w| {
self.tim.reg_block().csd_ctrl().write(|w| {
w.csden0().bit(ctrl.enb_start_src_csd0);
w.csdinv0().bit(ctrl.inv_csd0);
w.csden1().bit(ctrl.enb_start_src_csd1);
@ -619,9 +591,32 @@ impl<TIM: ValidTim> CountDownTimer<TIM> {
});
}
csd_sel!(cascade_0_source, cascade0);
csd_sel!(cascade_1_source, cascade1);
csd_sel!(cascade_2_source, cascade2);
pub fn cascade_0_source(&mut self, src: CascadeSource) -> Result<(), InvalidCascadeSourceId> {
let id = src.id()?;
self.tim
.reg_block()
.cascade0()
.write(|w| unsafe { w.cassel().bits(id) });
Ok(())
}
pub fn cascade_1_source(&mut self, src: CascadeSource) -> Result<(), InvalidCascadeSourceId> {
let id = src.id()?;
self.tim
.reg_block()
.cascade1()
.write(|w| unsafe { w.cassel().bits(id) });
Ok(())
}
pub fn cascade_2_source(&mut self, src: CascadeSource) -> Result<(), InvalidCascadeSourceId> {
let id = src.id()?;
self.tim
.reg_block()
.cascade2()
.write(|w| unsafe { w.cassel().bits(id) });
Ok(())
}
pub fn curr_freq(&self) -> Hertz {
self.curr_freq
@ -633,7 +628,7 @@ impl<TIM: ValidTim> CountDownTimer<TIM> {
}
/// CountDown implementation for TIMx
impl<TIM: ValidTim> CountDownTimer<TIM> {
impl<TIM: ValidTim> CountdownTimer<TIM> {
#[inline]
pub fn start<T>(&mut self, timeout: T)
where
@ -646,7 +641,7 @@ impl<TIM: ValidTim> CountDownTimer<TIM> {
/// Return `Ok` if the timer has wrapped. Peripheral will automatically clear the
/// flag and restart the time if configured correctly
pub fn wait(&mut self) -> nb::Result<(), void::Void> {
let cnt = self.tim.reg().cnt_value().read().bits();
let cnt = self.tim.reg_block().cnt_value().read().bits();
if (cnt > self.last_cnt) || cnt == 0 {
self.last_cnt = self.rst_val;
Ok(())
@ -656,16 +651,20 @@ impl<TIM: ValidTim> CountDownTimer<TIM> {
}
}
pub fn cancel(&mut self) -> Result<(), TimerErrors> {
if !self.tim.reg().ctrl().read().enable().bit_is_set() {
return Err(TimerErrors::Canceled);
/// Returns [false] if the timer was not active, and true otherwise.
pub fn cancel(&mut self) -> bool {
if !self.tim.reg_block().ctrl().read().enable().bit_is_set() {
return false;
}
self.tim.reg().ctrl().write(|w| w.enable().clear_bit());
Ok(())
self.tim
.reg_block()
.ctrl()
.write(|w| w.enable().clear_bit());
true
}
}
impl<TIM: ValidTim> embedded_hal::delay::DelayNs for CountDownTimer<TIM> {
impl<TIM: ValidTim> embedded_hal::delay::DelayNs for CountdownTimer<TIM> {
fn delay_ns(&mut self, ns: u32) {
let ticks = (u64::from(ns)) * (u64::from(self.sys_clk.raw())) / 1_000_000_000;
@ -722,13 +721,13 @@ impl<TIM: ValidTim> embedded_hal::delay::DelayNs for CountDownTimer<TIM> {
// Set up a millisecond timer on TIM0. Please note that the user still has to provide an IRQ handler
// which should call [default_ms_irq_handler].
pub fn set_up_ms_tick<TIM: ValidTim>(
irq_cfg: IrqCfg,
irq_cfg: InterruptConfig,
sys_cfg: &mut pac::Sysconfig,
irq_sel: Option<&mut pac::Irqsel>,
sys_clk: impl Into<Hertz>,
tim0: TIM,
) -> CountDownTimer<TIM> {
let mut ms_timer = CountDownTimer::new(sys_cfg, sys_clk, tim0);
) -> CountdownTimer<TIM> {
let mut ms_timer = CountdownTimer::new(sys_cfg, sys_clk, tim0);
ms_timer.listen(timer::Event::TimeOut, irq_cfg, irq_sel, Some(sys_cfg));
ms_timer.start(1000.Hz());
ms_timer
@ -738,8 +737,8 @@ pub fn set_up_ms_delay_provider<TIM: ValidTim>(
sys_cfg: &mut pac::Sysconfig,
sys_clk: impl Into<Hertz>,
tim: TIM,
) -> CountDownTimer<TIM> {
let mut provider = CountDownTimer::new(sys_cfg, sys_clk, tim);
) -> CountdownTimer<TIM> {
let mut provider = CountdownTimer::new(sys_cfg, sys_clk, tim);
provider.start(1000.Hz());
provider
}
@ -747,7 +746,7 @@ pub fn set_up_ms_delay_provider<TIM: ValidTim>(
/// This function can be called in a specified interrupt handler to increment
/// the MS counter
pub fn default_ms_irq_handler() {
cortex_m::interrupt::free(|cs| {
critical_section::with(|cs| {
let mut ms = MS_COUNTER.borrow(cs).get();
ms += 1;
MS_COUNTER.borrow(cs).set(ms);
@ -756,17 +755,17 @@ pub fn default_ms_irq_handler() {
/// Get the current MS tick count
pub fn get_ms_ticks() -> u32 {
cortex_m::interrupt::free(|cs| MS_COUNTER.borrow(cs).get())
critical_section::with(|cs| MS_COUNTER.borrow(cs).get())
}
//==================================================================================================
// Delay implementations
//==================================================================================================
pub struct DelayMs(CountDownTimer<pac::Tim0>);
pub struct DelayMs(CountdownTimer<pac::Tim0>);
impl DelayMs {
pub fn new(timer: CountDownTimer<pac::Tim0>) -> Option<Self> {
pub fn new(timer: CountdownTimer<pac::Tim0>) -> Option<Self> {
if timer.curr_freq() != Hertz::from_raw(1000) || !timer.listening() {
return None;
}

1018
va108xx-hal/src/uart.rs
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1396
va108xx-hal/src/uart/mod.rs Normal file
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419
va108xx-hal/src/uart/rx_asynch.rs Normal file
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@ -0,0 +1,419 @@
//! # Async UART reception functionality for the VA108xx family.
//!
//! This module provides the [RxAsync] and [RxAsyncSharedConsumer] struct which both implement the
//! [embedded_io_async::Read] trait.
//! This trait allows for asynchronous reception of data streams. Please note that this module does
//! not specify/declare the interrupt handlers which must be provided for async support to work.
//! However, it provides four interrupt handlers:
//!
//! - [on_interrupt_uart_a]
//! - [on_interrupt_uart_b]
//! - [on_interrupt_uart_a_overwriting]
//! - [on_interrupt_uart_b_overwriting]
//!
//! The first two are used for the [RxAsync] struct, while the latter two are used with the
//! [RxAsyncSharedConsumer] struct. The later two will overwrite old values in the used ring buffer.
//!
//! Error handling is performed in the user interrupt handler by checking the [AsyncUartErrors]
//! structure returned by the interrupt handlers.
//!
//! # Example
//!
//! - [Async UART RX example](https://egit.irs.uni-stuttgart.de/rust/va108xx-rs/src/branch/main/examples/embassy/src/bin/async-uart-rx.rs)
use core::{cell::RefCell, convert::Infallible, future::Future, sync::atomic::Ordering};
use critical_section::Mutex;
use embassy_sync::waitqueue::AtomicWaker;
use embedded_io::ErrorType;
use heapless::spsc::Consumer;
use portable_atomic::AtomicBool;
use va108xx as pac;
use super::{Instance, Rx, RxError, UartErrors};
static UART_RX_WAKERS: [AtomicWaker; 2] = [const { AtomicWaker::new() }; 2];
static RX_READ_ACTIVE: [AtomicBool; 2] = [const { AtomicBool::new(false) }; 2];
static RX_HAS_DATA: [AtomicBool; 2] = [const { AtomicBool::new(false) }; 2];
struct RxFuture {
uart_idx: usize,
}
impl RxFuture {
pub fn new<Uart: Instance>(_rx: &mut Rx<Uart>) -> Self {
RX_READ_ACTIVE[Uart::IDX as usize].store(true, Ordering::Relaxed);
Self {
uart_idx: Uart::IDX as usize,
}
}
}
impl Future for RxFuture {
type Output = Result<(), RxError>;
fn poll(
self: core::pin::Pin<&mut Self>,
cx: &mut core::task::Context<'_>,
) -> core::task::Poll<Self::Output> {
UART_RX_WAKERS[self.uart_idx].register(cx.waker());
if RX_HAS_DATA[self.uart_idx].load(Ordering::Relaxed) {
return core::task::Poll::Ready(Ok(()));
}
core::task::Poll::Pending
}
}
#[derive(Debug, Clone, Copy)]
#[cfg_attr(feature = "defmt", derive(defmt::Format))]
pub struct AsyncUartErrors {
/// Queue has overflowed, data might have been lost.
pub queue_overflow: bool,
/// UART errors.
pub uart_errors: UartErrors,
}
fn on_interrupt_handle_rx_errors<Uart: Instance>(uart: &Uart) -> Option<UartErrors> {
let rx_status = uart.rxstatus().read();
if rx_status.rxovr().bit_is_set()
|| rx_status.rxfrm().bit_is_set()
|| rx_status.rxpar().bit_is_set()
{
let mut errors_val = UartErrors::default();
if rx_status.rxovr().bit_is_set() {
errors_val.overflow = true;
}
if rx_status.rxfrm().bit_is_set() {
errors_val.framing = true;
}
if rx_status.rxpar().bit_is_set() {
errors_val.parity = true;
}
return Some(errors_val);
}
None
}
fn on_interrupt_rx_common_post_processing<Uart: Instance>(
uart: &Uart,
rx_enabled: bool,
read_some_data: bool,
irq_end: u32,
) -> Option<UartErrors> {
if read_some_data {
RX_HAS_DATA[Uart::IDX as usize].store(true, Ordering::Relaxed);
if RX_READ_ACTIVE[Uart::IDX as usize].load(Ordering::Relaxed) {
UART_RX_WAKERS[Uart::IDX as usize].wake();
}
}
let mut errors = None;
// Check for RX errors
if rx_enabled {
errors = on_interrupt_handle_rx_errors(uart);
}
// Clear the interrupt status bits
uart.irq_clr().write(|w| unsafe { w.bits(irq_end) });
errors
}
/// Interrupt handler for UART A.
///
/// Should be called in the user interrupt handler to enable
/// asynchronous reception. This variant will overwrite old data in the ring buffer in case
/// the ring buffer is full.
pub fn on_interrupt_uart_a_overwriting<const N: usize>(
prod: &mut heapless::spsc::Producer<u8, N>,
shared_consumer: &Mutex<RefCell<Option<heapless::spsc::Consumer<'static, u8, N>>>>,
) -> Result<(), AsyncUartErrors> {
on_interrupt_rx_async_heapless_queue_overwriting(
unsafe { pac::Uarta::steal() },
prod,
shared_consumer,
)
}
/// Interrupt handler for UART B.
///
/// Should be called in the user interrupt handler to enable
/// asynchronous reception. This variant will overwrite old data in the ring buffer in case
/// the ring buffer is full.
pub fn on_interrupt_uart_b_overwriting<const N: usize>(
prod: &mut heapless::spsc::Producer<u8, N>,
shared_consumer: &Mutex<RefCell<Option<heapless::spsc::Consumer<'static, u8, N>>>>,
) -> Result<(), AsyncUartErrors> {
on_interrupt_rx_async_heapless_queue_overwriting(
unsafe { pac::Uartb::steal() },
prod,
shared_consumer,
)
}
pub fn on_interrupt_rx_async_heapless_queue_overwriting<Uart: Instance, const N: usize>(
uart: Uart,
prod: &mut heapless::spsc::Producer<u8, N>,
shared_consumer: &Mutex<RefCell<Option<heapless::spsc::Consumer<'static, u8, N>>>>,
) -> Result<(), AsyncUartErrors> {
let irq_end = uart.irq_end().read();
let enb_status = uart.enable().read();
let rx_enabled = enb_status.rxenable().bit_is_set();
let mut read_some_data = false;
let mut queue_overflow = false;
// Half-Full interrupt. We have a guaranteed amount of data we can read.
if irq_end.irq_rx().bit_is_set() {
let available_bytes = uart.rxfifoirqtrg().read().bits() as usize;
// If this interrupt bit is set, the trigger level is available at the very least.
// Read everything as fast as possible
for _ in 0..available_bytes {
let byte = uart.data().read().bits();
if !prod.ready() {
queue_overflow = true;
critical_section::with(|cs| {
let mut cons_ref = shared_consumer.borrow(cs).borrow_mut();
cons_ref.as_mut().unwrap().dequeue();
});
}
prod.enqueue(byte as u8).ok();
}
read_some_data = true;
}
// Timeout, empty the FIFO completely.
if irq_end.irq_rx_to().bit_is_set() {
while uart.rxstatus().read().rdavl().bit_is_set() {
// While there is data in the FIFO, write it into the reception buffer
let byte = uart.data().read().bits();
if !prod.ready() {
queue_overflow = true;
critical_section::with(|cs| {
let mut cons_ref = shared_consumer.borrow(cs).borrow_mut();
cons_ref.as_mut().unwrap().dequeue();
});
}
prod.enqueue(byte as u8).ok();
}
read_some_data = true;
}
let uart_errors =
on_interrupt_rx_common_post_processing(&uart, rx_enabled, read_some_data, irq_end.bits());
if uart_errors.is_some() || queue_overflow {
return Err(AsyncUartErrors {
queue_overflow,
uart_errors: uart_errors.unwrap_or_default(),
});
}
Ok(())
}
/// Interrupt handler for UART A.
///
/// Should be called in the user interrupt handler to enable asynchronous reception.
pub fn on_interrupt_uart_a<const N: usize>(
prod: &mut heapless::spsc::Producer<'_, u8, N>,
) -> Result<(), AsyncUartErrors> {
on_interrupt_rx_async_heapless_queue(unsafe { pac::Uarta::steal() }, prod)
}
/// Interrupt handler for UART B.
///
/// Should be called in the user interrupt handler to enable asynchronous reception.
pub fn on_interrupt_uart_b<const N: usize>(
prod: &mut heapless::spsc::Producer<'_, u8, N>,
) -> Result<(), AsyncUartErrors> {
on_interrupt_rx_async_heapless_queue(unsafe { pac::Uartb::steal() }, prod)
}
pub fn on_interrupt_rx_async_heapless_queue<Uart: Instance, const N: usize>(
uart: Uart,
prod: &mut heapless::spsc::Producer<'_, u8, N>,
) -> Result<(), AsyncUartErrors> {
//let uart = unsafe { Uart::steal() };
let irq_end = uart.irq_end().read();
let enb_status = uart.enable().read();
let rx_enabled = enb_status.rxenable().bit_is_set();
let mut read_some_data = false;
let mut queue_overflow = false;
// Half-Full interrupt. We have a guaranteed amount of data we can read.
if irq_end.irq_rx().bit_is_set() {
let available_bytes = uart.rxfifoirqtrg().read().bits() as usize;
// If this interrupt bit is set, the trigger level is available at the very least.
// Read everything as fast as possible
for _ in 0..available_bytes {
let byte = uart.data().read().bits();
if !prod.ready() {
queue_overflow = true;
}
prod.enqueue(byte as u8).ok();
}
read_some_data = true;
}
// Timeout, empty the FIFO completely.
if irq_end.irq_rx_to().bit_is_set() {
while uart.rxstatus().read().rdavl().bit_is_set() {
// While there is data in the FIFO, write it into the reception buffer
let byte = uart.data().read().bits();
if !prod.ready() {
queue_overflow = true;
}
prod.enqueue(byte as u8).ok();
}
read_some_data = true;
}
let uart_errors =
on_interrupt_rx_common_post_processing(&uart, rx_enabled, read_some_data, irq_end.bits());
if uart_errors.is_some() || queue_overflow {
return Err(AsyncUartErrors {
queue_overflow,
uart_errors: uart_errors.unwrap_or_default(),
});
}
Ok(())
}
struct ActiveReadGuard(usize);
impl Drop for ActiveReadGuard {
fn drop(&mut self) {
RX_READ_ACTIVE[self.0].store(false, Ordering::Relaxed);
}
}
/// Core data structure to allow asynchronous UART reception.
///
/// If the ring buffer becomes full, data will be lost.
pub struct RxAsync<Uart: Instance, const N: usize> {
rx: Rx<Uart>,
pub queue: heapless::spsc::Consumer<'static, u8, N>,
}
impl<Uart: Instance, const N: usize> ErrorType for RxAsync<Uart, N> {
/// Error reporting is done using the result of the interrupt functions.
type Error = Infallible;
}
impl<Uart: Instance, const N: usize> RxAsync<Uart, N> {
/// Create a new asynchronous receiver.
///
/// The passed [heapless::spsc::Consumer] will be used to asynchronously receive data which
/// is filled by the interrupt handler.
pub fn new(mut rx: Rx<Uart>, queue: heapless::spsc::Consumer<'static, u8, N>) -> Self {
rx.disable_interrupts();
rx.disable();
rx.clear_fifo();
// Enable those together.
critical_section::with(|_| {
rx.enable_interrupts();
rx.enable();
});
Self { rx, queue }
}
}
impl<Uart: Instance, const N: usize> embedded_io_async::Read for RxAsync<Uart, N> {
async fn read(&mut self, buf: &mut [u8]) -> Result<usize, Self::Error> {
// Need to wait for the IRQ to read data and set this flag. If the queue is not
// empty, we can read data immediately.
if self.queue.len() == 0 {
RX_HAS_DATA[Uart::IDX as usize].store(false, Ordering::Relaxed);
}
let _guard = ActiveReadGuard(Uart::IDX as usize);
let mut handle_data_in_queue = |consumer: &mut heapless::spsc::Consumer<'static, u8, N>| {
let data_to_read = consumer.len().min(buf.len());
for byte in buf.iter_mut().take(data_to_read) {
// We own the consumer and we checked that the amount of data is guaranteed to be available.
*byte = unsafe { consumer.dequeue_unchecked() };
}
data_to_read
};
let fut = RxFuture::new(&mut self.rx);
// Data is available, so read that data immediately.
let read_data = handle_data_in_queue(&mut self.queue);
if read_data > 0 {
return Ok(read_data);
}
// Await data.
let _ = fut.await;
Ok(handle_data_in_queue(&mut self.queue))
}
}
/// Core data structure to allow asynchronous UART reception.
///
/// If the ring buffer becomes full, the oldest data will be overwritten when using the
/// [on_interrupt_uart_a_overwriting] and [on_interrupt_uart_b_overwriting] interrupt handlers.
pub struct RxAsyncSharedConsumer<Uart: Instance, const N: usize> {
rx: Rx<Uart>,
queue: &'static Mutex<RefCell<Option<Consumer<'static, u8, N>>>>,
}
impl<Uart: Instance, const N: usize> ErrorType for RxAsyncSharedConsumer<Uart, N> {
/// Error reporting is done using the result of the interrupt functions.
type Error = Infallible;
}
impl<Uart: Instance, const N: usize> RxAsyncSharedConsumer<Uart, N> {
/// Create a new asynchronous receiver.
///
/// The passed shared [heapless::spsc::Consumer] will be used to asynchronously receive data
/// which is filled by the interrupt handler. The shared property allows using it in the
/// interrupt handler to overwrite old data.
pub fn new(
mut rx: Rx<Uart>,
queue: &'static Mutex<RefCell<Option<heapless::spsc::Consumer<'static, u8, N>>>>,
) -> Self {
rx.disable_interrupts();
rx.disable();
rx.clear_fifo();
// Enable those together.
critical_section::with(|_| {
rx.enable_interrupts();
rx.enable();
});
Self { rx, queue }
}
}
impl<Uart: Instance, const N: usize> embedded_io_async::Read for RxAsyncSharedConsumer<Uart, N> {
async fn read(&mut self, buf: &mut [u8]) -> Result<usize, Self::Error> {
// Need to wait for the IRQ to read data and set this flag. If the queue is not
// empty, we can read data immediately.
critical_section::with(|cs| {
let queue = self.queue.borrow(cs);
if queue.borrow().as_ref().unwrap().len() == 0 {
RX_HAS_DATA[Uart::IDX as usize].store(false, Ordering::Relaxed);
}
});
let _guard = ActiveReadGuard(Uart::IDX as usize);
let mut handle_data_in_queue = || {
critical_section::with(|cs| {
let mut consumer_ref = self.queue.borrow(cs).borrow_mut();
let consumer = consumer_ref.as_mut().unwrap();
let data_to_read = consumer.len().min(buf.len());
for byte in buf.iter_mut().take(data_to_read) {
// We own the consumer and we checked that the amount of data is guaranteed to be available.
*byte = unsafe { consumer.dequeue_unchecked() };
}
data_to_read
})
};
let fut = RxFuture::new(&mut self.rx);
// Data is available, so read that data immediately.
let read_data = handle_data_in_queue();
if read_data > 0 {
return Ok(read_data);
}
// Await data.
let _ = fut.await;
let read_data = handle_data_in_queue();
Ok(read_data)
}
}

264
va108xx-hal/src/uart/tx_asynch.rs Normal file
View File

@ -0,0 +1,264 @@
//! # Async UART transmission functionality for the VA108xx family.
//!
//! This module provides the [TxAsync] struct which implements the [embedded_io_async::Write] trait.
//! This trait allows for asynchronous sending of data streams. Please note that this module does
//! not specify/declare the interrupt handlers which must be provided for async support to work.
//! However, it provides two interrupt handlers:
//!
//! - [on_interrupt_uart_a_tx]
//! - [on_interrupt_uart_b_tx]
//!
//! Those should be called in ALL user interrupt handlers which handle UART TX interrupts,
//! depending on which UARTs are used.
//!
//! # Example
//!
//! - [Async UART TX example](https://egit.irs.uni-stuttgart.de/rust/va108xx-rs/src/branch/main/examples/embassy/src/bin/async-uart-tx.rs)
use core::{cell::RefCell, future::Future};
use critical_section::Mutex;
use embassy_sync::waitqueue::AtomicWaker;
use embedded_io_async::Write;
use portable_atomic::AtomicBool;
use super::*;
static UART_TX_WAKERS: [AtomicWaker; 2] = [const { AtomicWaker::new() }; 2];
static TX_CONTEXTS: [Mutex<RefCell<TxContext>>; 2] =
[const { Mutex::new(RefCell::new(TxContext::new())) }; 2];
// Completion flag. Kept outside of the context structure as an atomic to avoid
// critical section.
static TX_DONE: [AtomicBool; 2] = [const { AtomicBool::new(false) }; 2];
/// This is a generic interrupt handler to handle asynchronous UART TX operations. The user
/// has to call this once in the interrupt handler responsible for UART A TX interrupts for
/// asynchronous operations to work.
pub fn on_interrupt_uart_a_tx() {
on_interrupt_uart_tx(unsafe { pac::Uarta::steal() });
}
/// This is a generic interrupt handler to handle asynchronous UART TX operations. The user
/// has to call this once in the interrupt handler responsible for UART B TX interrupts for
/// asynchronous operations to work.
pub fn on_interrupt_uart_b_tx() {
on_interrupt_uart_tx(unsafe { pac::Uartb::steal() });
}
fn on_interrupt_uart_tx<Uart: Instance>(uart: Uart) {
let irq_enb = uart.irq_enb().read();
// IRQ is not related to TX.
if irq_enb.irq_tx().bit_is_clear() || irq_enb.irq_tx_empty().bit_is_clear() {
return;
}
let tx_status = uart.txstatus().read();
let unexpected_overrun = tx_status.wrlost().bit_is_set();
let mut context = critical_section::with(|cs| {
let context_ref = TX_CONTEXTS[Uart::IDX as usize].borrow(cs);
*context_ref.borrow()
});
context.tx_overrun = unexpected_overrun;
if context.progress >= context.slice.len && !tx_status.wrbusy().bit_is_set() {
uart.irq_enb().modify(|_, w| {
w.irq_tx().clear_bit();
w.irq_tx_empty().clear_bit();
w.irq_tx_status().clear_bit()
});
uart.enable().modify(|_, w| w.txenable().clear_bit());
// Write back updated context structure.
critical_section::with(|cs| {
let context_ref = TX_CONTEXTS[Uart::IDX as usize].borrow(cs);
*context_ref.borrow_mut() = context;
});
// Transfer is done.
TX_DONE[Uart::IDX as usize].store(true, core::sync::atomic::Ordering::Relaxed);
UART_TX_WAKERS[Uart::IDX as usize].wake();
return;
}
// Safety: We documented that the user provided slice must outlive the future, so we convert
// the raw pointer back to the slice here.
let slice = unsafe { core::slice::from_raw_parts(context.slice.data, context.slice.len) };
while context.progress < context.slice.len {
let wrrdy = uart.txstatus().read().wrrdy().bit_is_set();
if !wrrdy {
break;
}
// Safety: TX structure is owned by the future which does not write into the the data
// register, so we can assume we are the only one writing to the data register.
uart.data()
.write(|w| unsafe { w.bits(slice[context.progress] as u32) });
context.progress += 1;
}
// Write back updated context structure.
critical_section::with(|cs| {
let context_ref = TX_CONTEXTS[Uart::IDX as usize].borrow(cs);
*context_ref.borrow_mut() = context;
});
}
#[derive(Debug, Copy, Clone)]
pub struct TxContext {
progress: usize,
tx_overrun: bool,
slice: RawBufSlice,
}
#[allow(clippy::new_without_default)]
impl TxContext {
pub const fn new() -> Self {
Self {
progress: 0,
tx_overrun: false,
slice: RawBufSlice::new_empty(),
}
}
}
#[derive(Debug, Copy, Clone)]
struct RawBufSlice {
data: *const u8,
len: usize,
}
/// Safety: This type MUST be used with mutex to ensure concurrent access is valid.
unsafe impl Send for RawBufSlice {}
impl RawBufSlice {
/// # Safety
///
/// This function stores the raw pointer of the passed data slice. The user MUST ensure
/// that the slice outlives the data structure.
#[allow(dead_code)]
const unsafe fn new(data: &[u8]) -> Self {
Self {
data: data.as_ptr(),
len: data.len(),
}
}
const fn new_empty() -> Self {
Self {
data: core::ptr::null(),
len: 0,
}
}
/// # Safety
///
/// This function stores the raw pointer of the passed data slice. The user MUST ensure
/// that the slice outlives the data structure.
pub unsafe fn set(&mut self, data: &[u8]) {
self.data = data.as_ptr();
self.len = data.len();
}
}
pub struct TxFuture {
uart_idx: usize,
}
impl TxFuture {
/// # Safety
///
/// This function stores the raw pointer of the passed data slice. The user MUST ensure
/// that the slice outlives the data structure.
pub unsafe fn new<Uart: Instance>(tx: &mut Tx<Uart>, data: &[u8]) -> Self {
TX_DONE[Uart::IDX as usize].store(false, core::sync::atomic::Ordering::Relaxed);
tx.disable_interrupts();
tx.disable();
tx.clear_fifo();
let uart_tx = unsafe { tx.uart() };
let init_fill_count = core::cmp::min(data.len(), 16);
// We fill the FIFO.
for data in data.iter().take(init_fill_count) {
uart_tx.data().write(|w| unsafe { w.bits(*data as u32) });
}
critical_section::with(|cs| {
let context_ref = TX_CONTEXTS[Uart::IDX as usize].borrow(cs);
let mut context = context_ref.borrow_mut();
context.slice.set(data);
context.progress = init_fill_count;
// Ensure those are enabled inside a critical section at the same time. Can lead to
// weird glitches otherwise.
tx.enable_interrupts();
tx.enable();
});
Self {
uart_idx: Uart::IDX as usize,
}
}
}
impl Future for TxFuture {
type Output = Result<usize, TxOverrunError>;
fn poll(
self: core::pin::Pin<&mut Self>,
cx: &mut core::task::Context<'_>,
) -> core::task::Poll<Self::Output> {
UART_TX_WAKERS[self.uart_idx].register(cx.waker());
if TX_DONE[self.uart_idx].swap(false, core::sync::atomic::Ordering::Relaxed) {
let progress = critical_section::with(|cs| {
TX_CONTEXTS[self.uart_idx].borrow(cs).borrow().progress
});
return core::task::Poll::Ready(Ok(progress));
}
core::task::Poll::Pending
}
}
impl Drop for TxFuture {
fn drop(&mut self) {
let reg_block = match self.uart_idx {
0 => unsafe { pac::Uarta::reg_block() },
1 => unsafe { pac::Uartb::reg_block() },
_ => unreachable!(),
};
disable_tx_interrupts(reg_block);
disable_tx(reg_block);
}
}
pub struct TxAsync<Uart: Instance> {
tx: Tx<Uart>,
}
impl<Uart: Instance> TxAsync<Uart> {
pub fn new(tx: Tx<Uart>) -> Self {
Self { tx }
}
pub fn release(self) -> Tx<Uart> {
self.tx
}
}
#[derive(Debug, thiserror::Error)]
#[cfg_attr(feature = "defmt", derive(defmt::Format))]
#[error("TX overrun error")]
pub struct TxOverrunError;
impl embedded_io_async::Error for TxOverrunError {
fn kind(&self) -> embedded_io_async::ErrorKind {
embedded_io_async::ErrorKind::Other
}
}
impl<Uart: Instance> embedded_io::ErrorType for TxAsync<Uart> {
type Error = TxOverrunError;
}
impl<Uart: Instance> Write for TxAsync<Uart> {
/// Write a buffer asynchronously.
///
/// This implementation is not side effect free, and a started future might have already
/// written part of the passed buffer.
async fn write(&mut self, buf: &[u8]) -> Result<usize, Self::Error> {
let fut = unsafe { TxFuture::new(&mut self.tx, buf) };
fut.await
}
}

16
va108xx-hal/src/utility.rs
View File

@ -1,16 +0,0 @@
//! # API for utility functions like the Error Detection and Correction (EDAC) block
//!
//! Some more information about the recommended scrub rates can be found on the
//! [Vorago White Paper website](https://www.voragotech.com/resources) in the
//! application note AN1212
use crate::pac;
/// Unmask and enable an IRQ with the given interrupt number
///
/// ## Safety
///
/// The unmask function can break mask-based critical sections
#[inline]
pub(crate) fn unmask_irq(irq: pac::Interrupt) {
unsafe { cortex_m::peripheral::NVIC::unmask(irq) };
}

4
va108xx/CHANGELOG.md
View File

@ -8,6 +8,10 @@ and this project adheres to [Semantic Versioning](http://semver.org/).
## [unreleased]
## [v0.4.0] 2025-02-12
- Re-generated PAC with `svd2rust` v0.35.0
## [v0.3.0] 2024-06-16
- Re-generated PAC with `svd2rust` v0.33.3

4
va108xx/Cargo.toml
View File

@ -1,6 +1,6 @@
[package]
name = "va108xx"
version = "0.3.0"
version = "0.4.0"
authors = ["Robin Mueller <muellerr@irs.uni-stuttgart.de>"]
edition = "2021"
description = "PAC for the Vorago VA108xx family of microcontrollers"
@ -24,4 +24,4 @@ rt = ["cortex-m-rt/device"]
[package.metadata.docs.rs]
all-features = true
rustdoc-args = ["--cfg", "docs_rs", "--generate-link-to-definition"]
rustdoc-args = ["--generate-link-to-definition"]

2
va108xx/README.md
View File

@ -24,7 +24,7 @@ features = ["rt"]
The `rt` feature is optional and recommended. It brings in support for `cortex-m-rt`.
For full details on the autgenerated API, please see the
[svd2rust documentation](https://docs.rs/svd2rust/0.19.0/svd2rust/#peripheral-api).
[svd2rust documentation](https://docs.rs/svd2rust/latest/svd2rust/#peripheral-api).
## Regenerating the PAC

3
va108xx/docs.sh Executable file
View File

@ -0,0 +1,3 @@
#!/bin/sh
export RUSTDOCFLAGS="--cfg docsrs --generate-link-to-definition -Z unstable-options"
cargo +nightly doc --all-features --open

2
va108xx/gen-helper.sh
View File

@ -1,4 +1,4 @@
#!/bin/sh
#!/bin/bash
# Use installed tool by default
svd2rust_bin="svd2rust"

440
va108xx/src/generic.rs
View File

@ -82,169 +82,6 @@ pub trait Resettable: RegisterSpec {
Self::RESET_VALUE
}
}
#[doc = " This structure provides volatile access to registers."]
#[repr(transparent)]
pub struct Reg<REG: RegisterSpec> {
register: vcell::VolatileCell<REG::Ux>,
_marker: marker::PhantomData<REG>,
}
unsafe impl<REG: RegisterSpec> Send for Reg<REG> where REG::Ux: Send {}
impl<REG: RegisterSpec> Reg<REG> {
#[doc = " Returns the underlying memory address of register."]
#[doc = ""]
#[doc = " ```ignore"]
#[doc = " let reg_ptr = periph.reg.as_ptr();"]
#[doc = " ```"]
#[inline(always)]
pub fn as_ptr(&self) -> *mut REG::Ux {
self.register.as_ptr()
}
}
impl<REG: Readable> Reg<REG> {
#[doc = " Reads the contents of a `Readable` register."]
#[doc = ""]
#[doc = " You can read the raw contents of a register by using `bits`:"]
#[doc = " ```ignore"]
#[doc = " let bits = periph.reg.read().bits();"]
#[doc = " ```"]
#[doc = " or get the content of a particular field of a register:"]
#[doc = " ```ignore"]
#[doc = " let reader = periph.reg.read();"]
#[doc = " let bits = reader.field1().bits();"]
#[doc = " let flag = reader.field2().bit_is_set();"]
#[doc = " ```"]
#[inline(always)]
pub fn read(&self) -> R<REG> {
R {
bits: self.register.get(),
_reg: marker::PhantomData,
}
}
}
impl<REG: Resettable + Writable> Reg<REG> {
#[doc = " Writes the reset value to `Writable` register."]
#[doc = ""]
#[doc = " Resets the register to its initial state."]
#[inline(always)]
pub fn reset(&self) {
self.register.set(REG::RESET_VALUE)
}
#[doc = " Writes bits to a `Writable` register."]
#[doc = ""]
#[doc = " You can write raw bits into a register:"]
#[doc = " ```ignore"]
#[doc = " periph.reg.write(|w| unsafe { w.bits(rawbits) });"]
#[doc = " ```"]
#[doc = " or write only the fields you need:"]
#[doc = " ```ignore"]
#[doc = " periph.reg.write(|w| w"]
#[doc = " .field1().bits(newfield1bits)"]
#[doc = " .field2().set_bit()"]
#[doc = " .field3().variant(VARIANT)"]
#[doc = " );"]
#[doc = " ```"]
#[doc = " or an alternative way of saying the same:"]
#[doc = " ```ignore"]
#[doc = " periph.reg.write(|w| {"]
#[doc = " w.field1().bits(newfield1bits);"]
#[doc = " w.field2().set_bit();"]
#[doc = " w.field3().variant(VARIANT)"]
#[doc = " });"]
#[doc = " ```"]
#[doc = " In the latter case, other fields will be set to their reset value."]
#[inline(always)]
pub fn write<F>(&self, f: F)
where
F: FnOnce(&mut W<REG>) -> &mut W<REG>,
{
self.register.set(
f(&mut W {
bits: REG::RESET_VALUE & !REG::ONE_TO_MODIFY_FIELDS_BITMAP
| REG::ZERO_TO_MODIFY_FIELDS_BITMAP,
_reg: marker::PhantomData,
})
.bits,
);
}
}
impl<REG: Writable> Reg<REG> {
#[doc = " Writes 0 to a `Writable` register."]
#[doc = ""]
#[doc = " Similar to `write`, but unused bits will contain 0."]
#[doc = ""]
#[doc = " # Safety"]
#[doc = ""]
#[doc = " Unsafe to use with registers which don't allow to write 0."]
#[inline(always)]
pub unsafe fn write_with_zero<F>(&self, f: F)
where
F: FnOnce(&mut W<REG>) -> &mut W<REG>,
{
self.register.set(
f(&mut W {
bits: REG::Ux::default(),
_reg: marker::PhantomData,
})
.bits,
);
}
}
impl<REG: Readable + Writable> Reg<REG> {
#[doc = " Modifies the contents of the register by reading and then writing it."]
#[doc = ""]
#[doc = " E.g. to do a read-modify-write sequence to change parts of a register:"]
#[doc = " ```ignore"]
#[doc = " periph.reg.modify(|r, w| unsafe { w.bits("]
#[doc = " r.bits() | 3"]
#[doc = " ) });"]
#[doc = " ```"]
#[doc = " or"]
#[doc = " ```ignore"]
#[doc = " periph.reg.modify(|_, w| w"]
#[doc = " .field1().bits(newfield1bits)"]
#[doc = " .field2().set_bit()"]
#[doc = " .field3().variant(VARIANT)"]
#[doc = " );"]
#[doc = " ```"]
#[doc = " or an alternative way of saying the same:"]
#[doc = " ```ignore"]
#[doc = " periph.reg.modify(|_, w| {"]
#[doc = " w.field1().bits(newfield1bits);"]
#[doc = " w.field2().set_bit();"]
#[doc = " w.field3().variant(VARIANT)"]
#[doc = " });"]
#[doc = " ```"]
#[doc = " Other fields will have the value they had before the call to `modify`."]
#[inline(always)]
pub fn modify<F>(&self, f: F)
where
for<'w> F: FnOnce(&R<REG>, &'w mut W<REG>) -> &'w mut W<REG>,
{
let bits = self.register.get();
self.register.set(
f(
&R {
bits,
_reg: marker::PhantomData,
},
&mut W {
bits: bits & !REG::ONE_TO_MODIFY_FIELDS_BITMAP
| REG::ZERO_TO_MODIFY_FIELDS_BITMAP,
_reg: marker::PhantomData,
},
)
.bits,
);
}
}
impl<REG: Readable> core::fmt::Debug for crate::generic::Reg<REG>
where
R<REG>: core::fmt::Debug,
{
fn fmt(&self, f: &mut core::fmt::Formatter<'_>) -> core::fmt::Result {
core::fmt::Debug::fmt(&self.read(), f)
}
}
#[doc(hidden)]
pub mod raw;
#[doc = " Register reader."]
@ -369,7 +206,7 @@ pub struct RangeTo<const MAX: u64>;
#[doc = " Write field Proxy"]
pub type FieldWriter<'a, REG, const WI: u8, FI = u8, Safety = Unsafe> =
raw::FieldWriter<'a, REG, WI, FI, Safety>;
impl<'a, REG, const WI: u8, FI, Safety> FieldWriter<'a, REG, WI, FI, Safety>
impl<REG, const WI: u8, FI, Safety> FieldWriter<'_, REG, WI, FI, Safety>
where
REG: Writable + RegisterSpec,
FI: FieldSpec,
@ -616,3 +453,278 @@ where
self.w
}
}
#[doc = " This structure provides volatile access to registers."]
#[repr(transparent)]
pub struct Reg<REG: RegisterSpec> {
register: vcell::VolatileCell<REG::Ux>,
_marker: marker::PhantomData<REG>,
}
unsafe impl<REG: RegisterSpec> Send for Reg<REG> where REG::Ux: Send {}
impl<REG: RegisterSpec> Reg<REG> {
#[doc = " Returns the underlying memory address of register."]
#[doc = ""]
#[doc = " ```ignore"]
#[doc = " let reg_ptr = periph.reg.as_ptr();"]
#[doc = " ```"]
#[inline(always)]
pub fn as_ptr(&self) -> *mut REG::Ux {
self.register.as_ptr()
}
}
impl<REG: Readable> Reg<REG> {
#[doc = " Reads the contents of a `Readable` register."]
#[doc = ""]
#[doc = " You can read the raw contents of a register by using `bits`:"]
#[doc = " ```ignore"]
#[doc = " let bits = periph.reg.read().bits();"]
#[doc = " ```"]
#[doc = " or get the content of a particular field of a register:"]
#[doc = " ```ignore"]
#[doc = " let reader = periph.reg.read();"]
#[doc = " let bits = reader.field1().bits();"]
#[doc = " let flag = reader.field2().bit_is_set();"]
#[doc = " ```"]
#[inline(always)]
pub fn read(&self) -> R<REG> {
R {
bits: self.register.get(),
_reg: marker::PhantomData,
}
}
}
impl<REG: Resettable + Writable> Reg<REG> {
#[doc = " Writes the reset value to `Writable` register."]
#[doc = ""]
#[doc = " Resets the register to its initial state."]
#[inline(always)]
pub fn reset(&self) {
self.register.set(REG::RESET_VALUE)
}
#[doc = " Writes bits to a `Writable` register."]
#[doc = ""]
#[doc = " You can write raw bits into a register:"]
#[doc = " ```ignore"]
#[doc = " periph.reg.write(|w| unsafe { w.bits(rawbits) });"]
#[doc = " ```"]
#[doc = " or write only the fields you need:"]
#[doc = " ```ignore"]
#[doc = " periph.reg.write(|w| w"]
#[doc = " .field1().bits(newfield1bits)"]
#[doc = " .field2().set_bit()"]
#[doc = " .field3().variant(VARIANT)"]
#[doc = " );"]
#[doc = " ```"]
#[doc = " or an alternative way of saying the same:"]
#[doc = " ```ignore"]
#[doc = " periph.reg.write(|w| {"]
#[doc = " w.field1().bits(newfield1bits);"]
#[doc = " w.field2().set_bit();"]
#[doc = " w.field3().variant(VARIANT)"]
#[doc = " });"]
#[doc = " ```"]
#[doc = " In the latter case, other fields will be set to their reset value."]
#[inline(always)]
pub fn write<F>(&self, f: F) -> REG::Ux
where
F: FnOnce(&mut W<REG>) -> &mut W<REG>,
{
let value = f(&mut W {
bits: REG::RESET_VALUE & !REG::ONE_TO_MODIFY_FIELDS_BITMAP
| REG::ZERO_TO_MODIFY_FIELDS_BITMAP,
_reg: marker::PhantomData,
})
.bits;
self.register.set(value);
value
}
#[doc = " Writes bits to a `Writable` register and produce a value."]
#[doc = ""]
#[doc = " You can write raw bits into a register:"]
#[doc = " ```ignore"]
#[doc = " periph.reg.write_and(|w| unsafe { w.bits(rawbits); });"]
#[doc = " ```"]
#[doc = " or write only the fields you need:"]
#[doc = " ```ignore"]
#[doc = " periph.reg.write_and(|w| {"]
#[doc = " w.field1().bits(newfield1bits)"]
#[doc = " .field2().set_bit()"]
#[doc = " .field3().variant(VARIANT);"]
#[doc = " });"]
#[doc = " ```"]
#[doc = " or an alternative way of saying the same:"]
#[doc = " ```ignore"]
#[doc = " periph.reg.write_and(|w| {"]
#[doc = " w.field1().bits(newfield1bits);"]
#[doc = " w.field2().set_bit();"]
#[doc = " w.field3().variant(VARIANT);"]
#[doc = " });"]
#[doc = " ```"]
#[doc = " In the latter case, other fields will be set to their reset value."]
#[doc = ""]
#[doc = " Values can be returned from the closure:"]
#[doc = " ```ignore"]
#[doc = " let state = periph.reg.write_and(|w| State::set(w.field1()));"]
#[doc = " ```"]
#[inline(always)]
pub fn from_write<F, T>(&self, f: F) -> T
where
F: FnOnce(&mut W<REG>) -> T,
{
let mut writer = W {
bits: REG::RESET_VALUE & !REG::ONE_TO_MODIFY_FIELDS_BITMAP
| REG::ZERO_TO_MODIFY_FIELDS_BITMAP,
_reg: marker::PhantomData,
};
let result = f(&mut writer);
self.register.set(writer.bits);
result
}
}
impl<REG: Writable> Reg<REG> {
#[doc = " Writes 0 to a `Writable` register."]
#[doc = ""]
#[doc = " Similar to `write`, but unused bits will contain 0."]
#[doc = ""]
#[doc = " # Safety"]
#[doc = ""]
#[doc = " Unsafe to use with registers which don't allow to write 0."]
#[inline(always)]
pub unsafe fn write_with_zero<F>(&self, f: F) -> REG::Ux
where
F: FnOnce(&mut W<REG>) -> &mut W<REG>,
{
let value = f(&mut W {
bits: REG::Ux::default(),
_reg: marker::PhantomData,
})
.bits;
self.register.set(value);
value
}
#[doc = " Writes 0 to a `Writable` register and produces a value."]
#[doc = ""]
#[doc = " Similar to `write`, but unused bits will contain 0."]
#[doc = ""]
#[doc = " # Safety"]
#[doc = ""]
#[doc = " Unsafe to use with registers which don't allow to write 0."]
#[inline(always)]
pub unsafe fn from_write_with_zero<F, T>(&self, f: F) -> T
where
F: FnOnce(&mut W<REG>) -> T,
{
let mut writer = W {
bits: REG::Ux::default(),
_reg: marker::PhantomData,
};
let result = f(&mut writer);
self.register.set(writer.bits);
result
}
}
impl<REG: Readable + Writable> Reg<REG> {
#[doc = " Modifies the contents of the register by reading and then writing it."]
#[doc = ""]
#[doc = " E.g. to do a read-modify-write sequence to change parts of a register:"]
#[doc = " ```ignore"]
#[doc = " periph.reg.modify(|r, w| unsafe { w.bits("]
#[doc = " r.bits() | 3"]
#[doc = " ) });"]
#[doc = " ```"]
#[doc = " or"]
#[doc = " ```ignore"]
#[doc = " periph.reg.modify(|_, w| w"]
#[doc = " .field1().bits(newfield1bits)"]
#[doc = " .field2().set_bit()"]
#[doc = " .field3().variant(VARIANT)"]
#[doc = " );"]
#[doc = " ```"]
#[doc = " or an alternative way of saying the same:"]
#[doc = " ```ignore"]
#[doc = " periph.reg.modify(|_, w| {"]
#[doc = " w.field1().bits(newfield1bits);"]
#[doc = " w.field2().set_bit();"]
#[doc = " w.field3().variant(VARIANT)"]
#[doc = " });"]
#[doc = " ```"]
#[doc = " Other fields will have the value they had before the call to `modify`."]
#[inline(always)]
pub fn modify<F>(&self, f: F) -> REG::Ux
where
for<'w> F: FnOnce(&R<REG>, &'w mut W<REG>) -> &'w mut W<REG>,
{
let bits = self.register.get();
let value = f(
&R {
bits,
_reg: marker::PhantomData,
},
&mut W {
bits: bits & !REG::ONE_TO_MODIFY_FIELDS_BITMAP | REG::ZERO_TO_MODIFY_FIELDS_BITMAP,
_reg: marker::PhantomData,
},
)
.bits;
self.register.set(value);
value
}
#[doc = " Modifies the contents of the register by reading and then writing it"]
#[doc = " and produces a value."]
#[doc = ""]
#[doc = " E.g. to do a read-modify-write sequence to change parts of a register:"]
#[doc = " ```ignore"]
#[doc = " let bits = periph.reg.modify(|r, w| {"]
#[doc = " let new_bits = r.bits() | 3;"]
#[doc = " unsafe {"]
#[doc = " w.bits(new_bits);"]
#[doc = " }"]
#[doc = ""]
#[doc = " new_bits"]
#[doc = " });"]
#[doc = " ```"]
#[doc = " or"]
#[doc = " ```ignore"]
#[doc = " periph.reg.modify(|_, w| {"]
#[doc = " w.field1().bits(newfield1bits)"]
#[doc = " .field2().set_bit()"]
#[doc = " .field3().variant(VARIANT);"]
#[doc = " });"]
#[doc = " ```"]
#[doc = " or an alternative way of saying the same:"]
#[doc = " ```ignore"]
#[doc = " periph.reg.modify(|_, w| {"]
#[doc = " w.field1().bits(newfield1bits);"]
#[doc = " w.field2().set_bit();"]
#[doc = " w.field3().variant(VARIANT);"]
#[doc = " });"]
#[doc = " ```"]
#[doc = " Other fields will have the value they had before the call to `modify`."]
#[inline(always)]
pub fn from_modify<F, T>(&self, f: F) -> T
where
for<'w> F: FnOnce(&R<REG>, &'w mut W<REG>) -> T,
{
let bits = self.register.get();
let mut writer = W {
bits: bits & !REG::ONE_TO_MODIFY_FIELDS_BITMAP | REG::ZERO_TO_MODIFY_FIELDS_BITMAP,
_reg: marker::PhantomData,
};
let result = f(
&R {
bits,
_reg: marker::PhantomData,
},
&mut writer,
);
self.register.set(writer.bits);
result
}
}
impl<REG: Readable> core::fmt::Debug for crate::generic::Reg<REG>
where
R<REG>: core::fmt::Debug,
{
fn fmt(&self, f: &mut core::fmt::Formatter<'_>) -> core::fmt::Result {
core::fmt::Debug::fmt(&self.read(), f)
}
}

2
va108xx/src/generic/raw.rs
View File

@ -41,6 +41,7 @@ impl<FI> BitReader<FI> {
}
}
}
#[must_use = "after creating `FieldWriter` you need to call field value setting method"]
pub struct FieldWriter<'a, REG, const WI: u8, FI = u8, Safety = Unsafe>
where
REG: Writable + RegisterSpec,
@ -66,6 +67,7 @@ where
}
}
}
#[must_use = "after creating `BitWriter` you need to call bit setting method"]
pub struct BitWriter<'a, REG, FI = bool, M = BitM>
where
REG: Writable + RegisterSpec,

66
va108xx/src/i2ca.rs
View File

@ -240,67 +240,67 @@ impl RegisterBlock {
&self.perid
}
}
#[doc = "CTRL (rw) register accessor: Control Register\n\nYou can [`read`](crate::generic::Reg::read) this register and get [`ctrl::R`]. You can [`reset`](crate::generic::Reg::reset), [`write`](crate::generic::Reg::write), [`write_with_zero`](crate::generic::Reg::write_with_zero) this register using [`ctrl::W`]. You can also [`modify`](crate::generic::Reg::modify) this register. See [API](https://docs.rs/svd2rust/#read--modify--write-api).\n\nFor information about available fields see [`mod@ctrl`]
#[doc = "CTRL (rw) register accessor: Control Register\n\nYou can [`read`](crate::Reg::read) this register and get [`ctrl::R`]. You can [`reset`](crate::Reg::reset), [`write`](crate::Reg::write), [`write_with_zero`](crate::Reg::write_with_zero) this register using [`ctrl::W`]. You can also [`modify`](crate::Reg::modify) this register. See [API](https://docs.rs/svd2rust/#read--modify--write-api).\n\nFor information about available fields see [`mod@ctrl`]
module"]
#[doc(alias = "CTRL")]
pub type Ctrl = crate::Reg<ctrl::CtrlSpec>;
#[doc = "Control Register"]
pub mod ctrl;
#[doc = "CLKSCALE (rw) register accessor: Clock Scale divide value\n\nYou can [`read`](crate::generic::Reg::read) this register and get [`clkscale::R`]. You can [`reset`](crate::generic::Reg::reset), [`write`](crate::generic::Reg::write), [`write_with_zero`](crate::generic::Reg::write_with_zero) this register using [`clkscale::W`]. You can also [`modify`](crate::generic::Reg::modify) this register. See [API](https://docs.rs/svd2rust/#read--modify--write-api).\n\nFor information about available fields see [`mod@clkscale`]
#[doc = "CLKSCALE (rw) register accessor: Clock Scale divide value\n\nYou can [`read`](crate::Reg::read) this register and get [`clkscale::R`]. You can [`reset`](crate::Reg::reset), [`write`](crate::Reg::write), [`write_with_zero`](crate::Reg::write_with_zero) this register using [`clkscale::W`]. You can also [`modify`](crate::Reg::modify) this register. See [API](https://docs.rs/svd2rust/#read--modify--write-api).\n\nFor information about available fields see [`mod@clkscale`]
module"]
#[doc(alias = "CLKSCALE")]
pub type Clkscale = crate::Reg<clkscale::ClkscaleSpec>;
#[doc = "Clock Scale divide value"]
pub mod clkscale;
#[doc = "WORDS (rw) register accessor: Word Count value\n\nYou can [`read`](crate::generic::Reg::read) this register and get [`words::R`]. You can [`reset`](crate::generic::Reg::reset), [`write`](crate::generic::Reg::write), [`write_with_zero`](crate::generic::Reg::write_with_zero) this register using [`words::W`]. You can also [`modify`](crate::generic::Reg::modify) this register. See [API](https://docs.rs/svd2rust/#read--modify--write-api).\n\nFor information about available fields see [`mod@words`]
#[doc = "WORDS (rw) register accessor: Word Count value\n\nYou can [`read`](crate::Reg::read) this register and get [`words::R`]. You can [`reset`](crate::Reg::reset), [`write`](crate::Reg::write), [`write_with_zero`](crate::Reg::write_with_zero) this register using [`words::W`]. You can also [`modify`](crate::Reg::modify) this register. See [API](https://docs.rs/svd2rust/#read--modify--write-api).\n\nFor information about available fields see [`mod@words`]
module"]
#[doc(alias = "WORDS")]
pub type Words = crate::Reg<words::WordsSpec>;
#[doc = "Word Count value"]
pub mod words;
#[doc = "ADDRESS (rw) register accessor: I2C Address value\n\nYou can [`read`](crate::generic::Reg::read) this register and get [`address::R`]. You can [`reset`](crate::generic::Reg::reset), [`write`](crate::generic::Reg::write), [`write_with_zero`](crate::generic::Reg::write_with_zero) this register using [`address::W`]. You can also [`modify`](crate::generic::Reg::modify) this register. See [API](https://docs.rs/svd2rust/#read--modify--write-api).\n\nFor information about available fields see [`mod@address`]
#[doc = "ADDRESS (rw) register accessor: I2C Address value\n\nYou can [`read`](crate::Reg::read) this register and get [`address::R`]. You can [`reset`](crate::Reg::reset), [`write`](crate::Reg::write), [`write_with_zero`](crate::Reg::write_with_zero) this register using [`address::W`]. You can also [`modify`](crate::Reg::modify) this register. See [API](https://docs.rs/svd2rust/#read--modify--write-api).\n\nFor information about available fields see [`mod@address`]
module"]
#[doc(alias = "ADDRESS")]
pub type Address = crate::Reg<address::AddressSpec>;
#[doc = "I2C Address value"]
pub mod address;
#[doc = "DATA (rw) register accessor: Data Input/Output\n\nYou can [`read`](crate::generic::Reg::read) this register and get [`data::R`]. You can [`reset`](crate::generic::Reg::reset), [`write`](crate::generic::Reg::write), [`write_with_zero`](crate::generic::Reg::write_with_zero) this register using [`data::W`]. You can also [`modify`](crate::generic::Reg::modify) this register. See [API](https://docs.rs/svd2rust/#read--modify--write-api).\n\nFor information about available fields see [`mod@data`]
#[doc = "DATA (rw) register accessor: Data Input/Output\n\nYou can [`read`](crate::Reg::read) this register and get [`data::R`]. You can [`reset`](crate::Reg::reset), [`write`](crate::Reg::write), [`write_with_zero`](crate::Reg::write_with_zero) this register using [`data::W`]. You can also [`modify`](crate::Reg::modify) this register. See [API](https://docs.rs/svd2rust/#read--modify--write-api).\n\nFor information about available fields see [`mod@data`]
module"]
#[doc(alias = "DATA")]
pub type Data = crate::Reg<data::DataSpec>;
#[doc = "Data Input/Output"]
pub mod data;
#[doc = "CMD (rw) register accessor: Command Register\n\nYou can [`read`](crate::generic::Reg::read) this register and get [`cmd::R`]. You can [`reset`](crate::generic::Reg::reset), [`write`](crate::generic::Reg::write), [`write_with_zero`](crate::generic::Reg::write_with_zero) this register using [`cmd::W`]. You can also [`modify`](crate::generic::Reg::modify) this register. See [API](https://docs.rs/svd2rust/#read--modify--write-api).\n\nFor information about available fields see [`mod@cmd`]
#[doc = "CMD (rw) register accessor: Command Register\n\nYou can [`read`](crate::Reg::read) this register and get [`cmd::R`]. You can [`reset`](crate::Reg::reset), [`write`](crate::Reg::write), [`write_with_zero`](crate::Reg::write_with_zero) this register using [`cmd::W`]. You can also [`modify`](crate::Reg::modify) this register. See [API](https://docs.rs/svd2rust/#read--modify--write-api).\n\nFor information about available fields see [`mod@cmd`]
module"]
#[doc(alias = "CMD")]
pub type Cmd = crate::Reg<cmd::CmdSpec>;
#[doc = "Command Register"]
pub mod cmd;
#[doc = "STATUS (r) register accessor: I2C Controller Status Register\n\nYou can [`read`](crate::generic::Reg::read) this register and get [`status::R`]. See [API](https://docs.rs/svd2rust/#read--modify--write-api).\n\nFor information about available fields see [`mod@status`]
#[doc = "STATUS (r) register accessor: I2C Controller Status Register\n\nYou can [`read`](crate::Reg::read) this register and get [`status::R`]. See [API](https://docs.rs/svd2rust/#read--modify--write-api).\n\nFor information about available fields see [`mod@status`]
module"]
#[doc(alias = "STATUS")]
pub type Status = crate::Reg<status::StatusSpec>;
#[doc = "I2C Controller Status Register"]
pub mod status;
#[doc = "STATE (r) register accessor: Internal STATE of I2C Master Controller\n\nYou can [`read`](crate::generic::Reg::read) this register and get [`state::R`]. See [API](https://docs.rs/svd2rust/#read--modify--write-api).\n\nFor information about available fields see [`mod@state`]
#[doc = "STATE (r) register accessor: Internal STATE of I2C Master Controller\n\nYou can [`read`](crate::Reg::read) this register and get [`state::R`]. See [API](https://docs.rs/svd2rust/#read--modify--write-api).\n\nFor information about available fields see [`mod@state`]
module"]
#[doc(alias = "STATE")]
pub type State = crate::Reg<state::StateSpec>;
#[doc = "Internal STATE of I2C Master Controller"]
pub mod state;
#[doc = "TXCOUNT (r) register accessor: TX Count Register\n\nYou can [`read`](crate::generic::Reg::read) this register and get [`txcount::R`]. See [API](https://docs.rs/svd2rust/#read--modify--write-api).\n\nFor information about available fields see [`mod@txcount`]
#[doc = "TXCOUNT (r) register accessor: TX Count Register\n\nYou can [`read`](crate::Reg::read) this register and get [`txcount::R`]. See [API](https://docs.rs/svd2rust/#read--modify--write-api).\n\nFor information about available fields see [`mod@txcount`]
module"]
#[doc(alias = "TXCOUNT")]
pub type Txcount = crate::Reg<txcount::TxcountSpec>;
#[doc = "TX Count Register"]
pub mod txcount;
#[doc = "RXCOUNT (r) register accessor: RX Count Register\n\nYou can [`read`](crate::generic::Reg::read) this register and get [`rxcount::R`]. See [API](https://docs.rs/svd2rust/#read--modify--write-api).\n\nFor information about available fields see [`mod@rxcount`]
#[doc = "RXCOUNT (r) register accessor: RX Count Register\n\nYou can [`read`](crate::Reg::read) this register and get [`rxcount::R`]. See [API](https://docs.rs/svd2rust/#read--modify--write-api).\n\nFor information about available fields see [`mod@rxcount`]
module"]
#[doc(alias = "RXCOUNT")]
pub type Rxcount = crate::Reg<rxcount::RxcountSpec>;
#[doc = "RX Count Register"]
pub mod rxcount;
#[doc = "IRQ_ENB (rw) register accessor: Interrupt Enable Register\n\nYou can [`read`](crate::generic::Reg::read) this register and get [`irq_enb::R`]. You can [`reset`](crate::generic::Reg::reset), [`write`](crate::generic::Reg::write), [`write_with_zero`](crate::generic::Reg::write_with_zero) this register using [`irq_enb::W`]. You can also [`modify`](crate::generic::Reg::modify) this register. See [API](https://docs.rs/svd2rust/#read--modify--write-api).\n\nFor information about available fields see [`mod@irq_enb`]
#[doc = "IRQ_ENB (rw) register accessor: Interrupt Enable Register\n\nYou can [`read`](crate::Reg::read) this register and get [`irq_enb::R`]. You can [`reset`](crate::Reg::reset), [`write`](crate::Reg::write), [`write_with_zero`](crate::Reg::write_with_zero) this register using [`irq_enb::W`]. You can also [`modify`](crate::Reg::modify) this register. See [API](https://docs.rs/svd2rust/#read--modify--write-api).\n\nFor information about available fields see [`mod@irq_enb`]
module"]
#[doc(alias = "IRQ_ENB")]
pub type IrqEnb = crate::Reg<irq_enb::IrqEnbSpec>;
@ -312,97 +312,97 @@ pub use irq_enb as irq_clr;
pub use IrqEnb as IrqRaw;
pub use IrqEnb as IrqEnd;
pub use IrqEnb as IrqClr;
#[doc = "RXFIFOIRQTRG (rw) register accessor: Rx FIFO IRQ Trigger Level\n\nYou can [`read`](crate::generic::Reg::read) this register and get [`rxfifoirqtrg::R`]. You can [`reset`](crate::generic::Reg::reset), [`write`](crate::generic::Reg::write), [`write_with_zero`](crate::generic::Reg::write_with_zero) this register using [`rxfifoirqtrg::W`]. You can also [`modify`](crate::generic::Reg::modify) this register. See [API](https://docs.rs/svd2rust/#read--modify--write-api).\n\nFor information about available fields see [`mod@rxfifoirqtrg`]
#[doc = "RXFIFOIRQTRG (rw) register accessor: Rx FIFO IRQ Trigger Level\n\nYou can [`read`](crate::Reg::read) this register and get [`rxfifoirqtrg::R`]. You can [`reset`](crate::Reg::reset), [`write`](crate::Reg::write), [`write_with_zero`](crate::Reg::write_with_zero) this register using [`rxfifoirqtrg::W`]. You can also [`modify`](crate::Reg::modify) this register. See [API](https://docs.rs/svd2rust/#read--modify--write-api).\n\nFor information about available fields see [`mod@rxfifoirqtrg`]
module"]
#[doc(alias = "RXFIFOIRQTRG")]
pub type Rxfifoirqtrg = crate::Reg<rxfifoirqtrg::RxfifoirqtrgSpec>;
#[doc = "Rx FIFO IRQ Trigger Level"]
pub mod rxfifoirqtrg;
#[doc = "TXFIFOIRQTRG (rw) register accessor: Tx FIFO IRQ Trigger Level\n\nYou can [`read`](crate::generic::Reg::read) this register and get [`txfifoirqtrg::R`]. You can [`reset`](crate::generic::Reg::reset), [`write`](crate::generic::Reg::write), [`write_with_zero`](crate::generic::Reg::write_with_zero) this register using [`txfifoirqtrg::W`]. You can also [`modify`](crate::generic::Reg::modify) this register. See [API](https://docs.rs/svd2rust/#read--modify--write-api).\n\nFor information about available fields see [`mod@txfifoirqtrg`]
#[doc = "TXFIFOIRQTRG (rw) register accessor: Tx FIFO IRQ Trigger Level\n\nYou can [`read`](crate::Reg::read) this register and get [`txfifoirqtrg::R`]. You can [`reset`](crate::Reg::reset), [`write`](crate::Reg::write), [`write_with_zero`](crate::Reg::write_with_zero) this register using [`txfifoirqtrg::W`]. You can also [`modify`](crate::Reg::modify) this register. See [API](https://docs.rs/svd2rust/#read--modify--write-api).\n\nFor information about available fields see [`mod@txfifoirqtrg`]
module"]
#[doc(alias = "TXFIFOIRQTRG")]
pub type Txfifoirqtrg = crate::Reg<txfifoirqtrg::TxfifoirqtrgSpec>;
#[doc = "Tx FIFO IRQ Trigger Level"]
pub mod txfifoirqtrg;
#[doc = "FIFO_CLR (w) register accessor: Clear FIFO Register\n\nYou can [`reset`](crate::generic::Reg::reset), [`write`](crate::generic::Reg::write), [`write_with_zero`](crate::generic::Reg::write_with_zero) this register using [`fifo_clr::W`]. See [API](https://docs.rs/svd2rust/#read--modify--write-api).\n\nFor information about available fields see [`mod@fifo_clr`]
#[doc = "FIFO_CLR (w) register accessor: Clear FIFO Register\n\nYou can [`reset`](crate::Reg::reset), [`write`](crate::Reg::write), [`write_with_zero`](crate::Reg::write_with_zero) this register using [`fifo_clr::W`]. See [API](https://docs.rs/svd2rust/#read--modify--write-api).\n\nFor information about available fields see [`mod@fifo_clr`]
module"]
#[doc(alias = "FIFO_CLR")]
pub type FifoClr = crate::Reg<fifo_clr::FifoClrSpec>;
#[doc = "Clear FIFO Register"]
pub mod fifo_clr;
#[doc = "TMCONFIG (rw) register accessor: Timing Config Register\n\nYou can [`read`](crate::generic::Reg::read) this register and get [`tmconfig::R`]. You can [`reset`](crate::generic::Reg::reset), [`write`](crate::generic::Reg::write), [`write_with_zero`](crate::generic::Reg::write_with_zero) this register using [`tmconfig::W`]. You can also [`modify`](crate::generic::Reg::modify) this register. See [API](https://docs.rs/svd2rust/#read--modify--write-api).\n\nFor information about available fields see [`mod@tmconfig`]
#[doc = "TMCONFIG (rw) register accessor: Timing Config Register\n\nYou can [`read`](crate::Reg::read) this register and get [`tmconfig::R`]. You can [`reset`](crate::Reg::reset), [`write`](crate::Reg::write), [`write_with_zero`](crate::Reg::write_with_zero) this register using [`tmconfig::W`]. You can also [`modify`](crate::Reg::modify) this register. See [API](https://docs.rs/svd2rust/#read--modify--write-api).\n\nFor information about available fields see [`mod@tmconfig`]
module"]
#[doc(alias = "TMCONFIG")]
pub type Tmconfig = crate::Reg<tmconfig::TmconfigSpec>;
#[doc = "Timing Config Register"]
pub mod tmconfig;
#[doc = "CLKTOLIMIT (rw) register accessor: Clock Low Timeout Limit Register\n\nYou can [`read`](crate::generic::Reg::read) this register and get [`clktolimit::R`]. You can [`reset`](crate::generic::Reg::reset), [`write`](crate::generic::Reg::write), [`write_with_zero`](crate::generic::Reg::write_with_zero) this register using [`clktolimit::W`]. You can also [`modify`](crate::generic::Reg::modify) this register. See [API](https://docs.rs/svd2rust/#read--modify--write-api).\n\nFor information about available fields see [`mod@clktolimit`]
#[doc = "CLKTOLIMIT (rw) register accessor: Clock Low Timeout Limit Register\n\nYou can [`read`](crate::Reg::read) this register and get [`clktolimit::R`]. You can [`reset`](crate::Reg::reset), [`write`](crate::Reg::write), [`write_with_zero`](crate::Reg::write_with_zero) this register using [`clktolimit::W`]. You can also [`modify`](crate::Reg::modify) this register. See [API](https://docs.rs/svd2rust/#read--modify--write-api).\n\nFor information about available fields see [`mod@clktolimit`]
module"]
#[doc(alias = "CLKTOLIMIT")]
pub type Clktolimit = crate::Reg<clktolimit::ClktolimitSpec>;
#[doc = "Clock Low Timeout Limit Register"]
pub mod clktolimit;
#[doc = "S0_CTRL (rw) register accessor: Slave Control Register\n\nYou can [`read`](crate::generic::Reg::read) this register and get [`s0_ctrl::R`]. You can [`reset`](crate::generic::Reg::reset), [`write`](crate::generic::Reg::write), [`write_with_zero`](crate::generic::Reg::write_with_zero) this register using [`s0_ctrl::W`]. You can also [`modify`](crate::generic::Reg::modify) this register. See [API](https://docs.rs/svd2rust/#read--modify--write-api).\n\nFor information about available fields see [`mod@s0_ctrl`]
#[doc = "S0_CTRL (rw) register accessor: Slave Control Register\n\nYou can [`read`](crate::Reg::read) this register and get [`s0_ctrl::R`]. You can [`reset`](crate::Reg::reset), [`write`](crate::Reg::write), [`write_with_zero`](crate::Reg::write_with_zero) this register using [`s0_ctrl::W`]. You can also [`modify`](crate::Reg::modify) this register. See [API](https://docs.rs/svd2rust/#read--modify--write-api).\n\nFor information about available fields see [`mod@s0_ctrl`]
module"]
#[doc(alias = "S0_CTRL")]
pub type S0Ctrl = crate::Reg<s0_ctrl::S0CtrlSpec>;
#[doc = "Slave Control Register"]
pub mod s0_ctrl;
#[doc = "S0_MAXWORDS (rw) register accessor: Slave MaxWords Register\n\nYou can [`read`](crate::generic::Reg::read) this register and get [`s0_maxwords::R`]. You can [`reset`](crate::generic::Reg::reset), [`write`](crate::generic::Reg::write), [`write_with_zero`](crate::generic::Reg::write_with_zero) this register using [`s0_maxwords::W`]. You can also [`modify`](crate::generic::Reg::modify) this register. See [API](https://docs.rs/svd2rust/#read--modify--write-api).\n\nFor information about available fields see [`mod@s0_maxwords`]
#[doc = "S0_MAXWORDS (rw) register accessor: Slave MaxWords Register\n\nYou can [`read`](crate::Reg::read) this register and get [`s0_maxwords::R`]. You can [`reset`](crate::Reg::reset), [`write`](crate::Reg::write), [`write_with_zero`](crate::Reg::write_with_zero) this register using [`s0_maxwords::W`]. You can also [`modify`](crate::Reg::modify) this register. See [API](https://docs.rs/svd2rust/#read--modify--write-api).\n\nFor information about available fields see [`mod@s0_maxwords`]
module"]
#[doc(alias = "S0_MAXWORDS")]
pub type S0Maxwords = crate::Reg<s0_maxwords::S0MaxwordsSpec>;
#[doc = "Slave MaxWords Register"]
pub mod s0_maxwords;
#[doc = "S0_ADDRESS (rw) register accessor: Slave I2C Address Value\n\nYou can [`read`](crate::generic::Reg::read) this register and get [`s0_address::R`]. You can [`reset`](crate::generic::Reg::reset), [`write`](crate::generic::Reg::write), [`write_with_zero`](crate::generic::Reg::write_with_zero) this register using [`s0_address::W`]. You can also [`modify`](crate::generic::Reg::modify) this register. See [API](https://docs.rs/svd2rust/#read--modify--write-api).\n\nFor information about available fields see [`mod@s0_address`]
#[doc = "S0_ADDRESS (rw) register accessor: Slave I2C Address Value\n\nYou can [`read`](crate::Reg::read) this register and get [`s0_address::R`]. You can [`reset`](crate::Reg::reset), [`write`](crate::Reg::write), [`write_with_zero`](crate::Reg::write_with_zero) this register using [`s0_address::W`]. You can also [`modify`](crate::Reg::modify) this register. See [API](https://docs.rs/svd2rust/#read--modify--write-api).\n\nFor information about available fields see [`mod@s0_address`]
module"]
#[doc(alias = "S0_ADDRESS")]
pub type S0Address = crate::Reg<s0_address::S0AddressSpec>;
#[doc = "Slave I2C Address Value"]
pub mod s0_address;
#[doc = "S0_ADDRESSMASK (rw) register accessor: Slave I2C Address Mask value\n\nYou can [`read`](crate::generic::Reg::read) this register and get [`s0_addressmask::R`]. You can [`reset`](crate::generic::Reg::reset), [`write`](crate::generic::Reg::write), [`write_with_zero`](crate::generic::Reg::write_with_zero) this register using [`s0_addressmask::W`]. You can also [`modify`](crate::generic::Reg::modify) this register. See [API](https://docs.rs/svd2rust/#read--modify--write-api).\n\nFor information about available fields see [`mod@s0_addressmask`]
#[doc = "S0_ADDRESSMASK (rw) register accessor: Slave I2C Address Mask value\n\nYou can [`read`](crate::Reg::read) this register and get [`s0_addressmask::R`]. You can [`reset`](crate::Reg::reset), [`write`](crate::Reg::write), [`write_with_zero`](crate::Reg::write_with_zero) this register using [`s0_addressmask::W`]. You can also [`modify`](crate::Reg::modify) this register. See [API](https://docs.rs/svd2rust/#read--modify--write-api).\n\nFor information about available fields see [`mod@s0_addressmask`]
module"]
#[doc(alias = "S0_ADDRESSMASK")]
pub type S0Addressmask = crate::Reg<s0_addressmask::S0AddressmaskSpec>;
#[doc = "Slave I2C Address Mask value"]
pub mod s0_addressmask;
#[doc = "S0_DATA (rw) register accessor: Slave Data Input/Output\n\nYou can [`read`](crate::generic::Reg::read) this register and get [`s0_data::R`]. You can [`reset`](crate::generic::Reg::reset), [`write`](crate::generic::Reg::write), [`write_with_zero`](crate::generic::Reg::write_with_zero) this register using [`s0_data::W`]. You can also [`modify`](crate::generic::Reg::modify) this register. See [API](https://docs.rs/svd2rust/#read--modify--write-api).\n\nFor information about available fields see [`mod@s0_data`]
#[doc = "S0_DATA (rw) register accessor: Slave Data Input/Output\n\nYou can [`read`](crate::Reg::read) this register and get [`s0_data::R`]. You can [`reset`](crate::Reg::reset), [`write`](crate::Reg::write), [`write_with_zero`](crate::Reg::write_with_zero) this register using [`s0_data::W`]. You can also [`modify`](crate::Reg::modify) this register. See [API](https://docs.rs/svd2rust/#read--modify--write-api).\n\nFor information about available fields see [`mod@s0_data`]
module"]
#[doc(alias = "S0_DATA")]
pub type S0Data = crate::Reg<s0_data::S0DataSpec>;
#[doc = "Slave Data Input/Output"]
pub mod s0_data;
#[doc = "S0_LASTADDRESS (r) register accessor: Slave I2C Last Address value\n\nYou can [`read`](crate::generic::Reg::read) this register and get [`s0_lastaddress::R`]. See [API](https://docs.rs/svd2rust/#read--modify--write-api).\n\nFor information about available fields see [`mod@s0_lastaddress`]
#[doc = "S0_LASTADDRESS (r) register accessor: Slave I2C Last Address value\n\nYou can [`read`](crate::Reg::read) this register and get [`s0_lastaddress::R`]. See [API](https://docs.rs/svd2rust/#read--modify--write-api).\n\nFor information about available fields see [`mod@s0_lastaddress`]
module"]
#[doc(alias = "S0_LASTADDRESS")]
pub type S0Lastaddress = crate::Reg<s0_lastaddress::S0LastaddressSpec>;
#[doc = "Slave I2C Last Address value"]
pub mod s0_lastaddress;
#[doc = "S0_STATUS (r) register accessor: Slave I2C Controller Status Register\n\nYou can [`read`](crate::generic::Reg::read) this register and get [`s0_status::R`]. See [API](https://docs.rs/svd2rust/#read--modify--write-api).\n\nFor information about available fields see [`mod@s0_status`]
#[doc = "S0_STATUS (r) register accessor: Slave I2C Controller Status Register\n\nYou can [`read`](crate::Reg::read) this register and get [`s0_status::R`]. See [API](https://docs.rs/svd2rust/#read--modify--write-api).\n\nFor information about available fields see [`mod@s0_status`]
module"]
#[doc(alias = "S0_STATUS")]
pub type S0Status = crate::Reg<s0_status::S0StatusSpec>;
#[doc = "Slave I2C Controller Status Register"]
pub mod s0_status;
#[doc = "S0_STATE (r) register accessor: Internal STATE of I2C Slave Controller\n\nYou can [`read`](crate::generic::Reg::read) this register and get [`s0_state::R`]. See [API](https://docs.rs/svd2rust/#read--modify--write-api).\n\nFor information about available fields see [`mod@s0_state`]
#[doc = "S0_STATE (r) register accessor: Internal STATE of I2C Slave Controller\n\nYou can [`read`](crate::Reg::read) this register and get [`s0_state::R`]. See [API](https://docs.rs/svd2rust/#read--modify--write-api).\n\nFor information about available fields see [`mod@s0_state`]
module"]
#[doc(alias = "S0_STATE")]
pub type S0State = crate::Reg<s0_state::S0StateSpec>;
#[doc = "Internal STATE of I2C Slave Controller"]
pub mod s0_state;
#[doc = "S0_TXCOUNT (r) register accessor: Slave TX Count Register\n\nYou can [`read`](crate::generic::Reg::read) this register and get [`s0_txcount::R`]. See [API](https://docs.rs/svd2rust/#read--modify--write-api).\n\nFor information about available fields see [`mod@s0_txcount`]
#[doc = "S0_TXCOUNT (r) register accessor: Slave TX Count Register\n\nYou can [`read`](crate::Reg::read) this register and get [`s0_txcount::R`]. See [API](https://docs.rs/svd2rust/#read--modify--write-api).\n\nFor information about available fields see [`mod@s0_txcount`]
module"]
#[doc(alias = "S0_TXCOUNT")]
pub type S0Txcount = crate::Reg<s0_txcount::S0TxcountSpec>;
#[doc = "Slave TX Count Register"]
pub mod s0_txcount;
#[doc = "S0_RXCOUNT (r) register accessor: Slave RX Count Register\n\nYou can [`read`](crate::generic::Reg::read) this register and get [`s0_rxcount::R`]. See [API](https://docs.rs/svd2rust/#read--modify--write-api).\n\nFor information about available fields see [`mod@s0_rxcount`]
#[doc = "S0_RXCOUNT (r) register accessor: Slave RX Count Register\n\nYou can [`read`](crate::Reg::read) this register and get [`s0_rxcount::R`]. See [API](https://docs.rs/svd2rust/#read--modify--write-api).\n\nFor information about available fields see [`mod@s0_rxcount`]
module"]
#[doc(alias = "S0_RXCOUNT")]
pub type S0Rxcount = crate::Reg<s0_rxcount::S0RxcountSpec>;
#[doc = "Slave RX Count Register"]
pub mod s0_rxcount;
#[doc = "S0_IRQ_ENB (rw) register accessor: Slave Interrupt Enable Register\n\nYou can [`read`](crate::generic::Reg::read) this register and get [`s0_irq_enb::R`]. You can [`reset`](crate::generic::Reg::reset), [`write`](crate::generic::Reg::write), [`write_with_zero`](crate::generic::Reg::write_with_zero) this register using [`s0_irq_enb::W`]. You can also [`modify`](crate::generic::Reg::modify) this register. See [API](https://docs.rs/svd2rust/#read--modify--write-api).\n\nFor information about available fields see [`mod@s0_irq_enb`]
#[doc = "S0_IRQ_ENB (rw) register accessor: Slave Interrupt Enable Register\n\nYou can [`read`](crate::Reg::read) this register and get [`s0_irq_enb::R`]. You can [`reset`](crate::Reg::reset), [`write`](crate::Reg::write), [`write_with_zero`](crate::Reg::write_with_zero) this register using [`s0_irq_enb::W`]. You can also [`modify`](crate::Reg::modify) this register. See [API](https://docs.rs/svd2rust/#read--modify--write-api).\n\nFor information about available fields see [`mod@s0_irq_enb`]
module"]
#[doc(alias = "S0_IRQ_ENB")]
pub type S0IrqEnb = crate::Reg<s0_irq_enb::S0IrqEnbSpec>;
@ -414,37 +414,37 @@ pub use s0_irq_enb as s0_irq_clr;
pub use S0IrqEnb as S0IrqRaw;
pub use S0IrqEnb as S0IrqEnd;
pub use S0IrqEnb as S0IrqClr;
#[doc = "S0_RXFIFOIRQTRG (rw) register accessor: Slave Rx FIFO IRQ Trigger Level\n\nYou can [`read`](crate::generic::Reg::read) this register and get [`s0_rxfifoirqtrg::R`]. You can [`reset`](crate::generic::Reg::reset), [`write`](crate::generic::Reg::write), [`write_with_zero`](crate::generic::Reg::write_with_zero) this register using [`s0_rxfifoirqtrg::W`]. You can also [`modify`](crate::generic::Reg::modify) this register. See [API](https://docs.rs/svd2rust/#read--modify--write-api).\n\nFor information about available fields see [`mod@s0_rxfifoirqtrg`]
#[doc = "S0_RXFIFOIRQTRG (rw) register accessor: Slave Rx FIFO IRQ Trigger Level\n\nYou can [`read`](crate::Reg::read) this register and get [`s0_rxfifoirqtrg::R`]. You can [`reset`](crate::Reg::reset), [`write`](crate::Reg::write), [`write_with_zero`](crate::Reg::write_with_zero) this register using [`s0_rxfifoirqtrg::W`]. You can also [`modify`](crate::Reg::modify) this register. See [API](https://docs.rs/svd2rust/#read--modify--write-api).\n\nFor information about available fields see [`mod@s0_rxfifoirqtrg`]
module"]
#[doc(alias = "S0_RXFIFOIRQTRG")]
pub type S0Rxfifoirqtrg = crate::Reg<s0_rxfifoirqtrg::S0RxfifoirqtrgSpec>;
#[doc = "Slave Rx FIFO IRQ Trigger Level"]
pub mod s0_rxfifoirqtrg;
#[doc = "S0_TXFIFOIRQTRG (rw) register accessor: Slave Tx FIFO IRQ Trigger Level\n\nYou can [`read`](crate::generic::Reg::read) this register and get [`s0_txfifoirqtrg::R`]. You can [`reset`](crate::generic::Reg::reset), [`write`](crate::generic::Reg::write), [`write_with_zero`](crate::generic::Reg::write_with_zero) this register using [`s0_txfifoirqtrg::W`]. You can also [`modify`](crate::generic::Reg::modify) this register. See [API](https://docs.rs/svd2rust/#read--modify--write-api).\n\nFor information about available fields see [`mod@s0_txfifoirqtrg`]
#[doc = "S0_TXFIFOIRQTRG (rw) register accessor: Slave Tx FIFO IRQ Trigger Level\n\nYou can [`read`](crate::Reg::read) this register and get [`s0_txfifoirqtrg::R`]. You can [`reset`](crate::Reg::reset), [`write`](crate::Reg::write), [`write_with_zero`](crate::Reg::write_with_zero) this register using [`s0_txfifoirqtrg::W`]. You can also [`modify`](crate::Reg::modify) this register. See [API](https://docs.rs/svd2rust/#read--modify--write-api).\n\nFor information about available fields see [`mod@s0_txfifoirqtrg`]
module"]
#[doc(alias = "S0_TXFIFOIRQTRG")]
pub type S0Txfifoirqtrg = crate::Reg<s0_txfifoirqtrg::S0TxfifoirqtrgSpec>;
#[doc = "Slave Tx FIFO IRQ Trigger Level"]
pub mod s0_txfifoirqtrg;
#[doc = "S0_FIFO_CLR (w) register accessor: Slave Clear FIFO Register\n\nYou can [`reset`](crate::generic::Reg::reset), [`write`](crate::generic::Reg::write), [`write_with_zero`](crate::generic::Reg::write_with_zero) this register using [`s0_fifo_clr::W`]. See [API](https://docs.rs/svd2rust/#read--modify--write-api).\n\nFor information about available fields see [`mod@s0_fifo_clr`]
#[doc = "S0_FIFO_CLR (w) register accessor: Slave Clear FIFO Register\n\nYou can [`reset`](crate::Reg::reset), [`write`](crate::Reg::write), [`write_with_zero`](crate::Reg::write_with_zero) this register using [`s0_fifo_clr::W`]. See [API](https://docs.rs/svd2rust/#read--modify--write-api).\n\nFor information about available fields see [`mod@s0_fifo_clr`]
module"]
#[doc(alias = "S0_FIFO_CLR")]
pub type S0FifoClr = crate::Reg<s0_fifo_clr::S0FifoClrSpec>;
#[doc = "Slave Clear FIFO Register"]
pub mod s0_fifo_clr;
#[doc = "S0_ADDRESSB (rw) register accessor: Slave I2C Address B Value\n\nYou can [`read`](crate::generic::Reg::read) this register and get [`s0_addressb::R`]. You can [`reset`](crate::generic::Reg::reset), [`write`](crate::generic::Reg::write), [`write_with_zero`](crate::generic::Reg::write_with_zero) this register using [`s0_addressb::W`]. You can also [`modify`](crate::generic::Reg::modify) this register. See [API](https://docs.rs/svd2rust/#read--modify--write-api).\n\nFor information about available fields see [`mod@s0_addressb`]
#[doc = "S0_ADDRESSB (rw) register accessor: Slave I2C Address B Value\n\nYou can [`read`](crate::Reg::read) this register and get [`s0_addressb::R`]. You can [`reset`](crate::Reg::reset), [`write`](crate::Reg::write), [`write_with_zero`](crate::Reg::write_with_zero) this register using [`s0_addressb::W`]. You can also [`modify`](crate::Reg::modify) this register. See [API](https://docs.rs/svd2rust/#read--modify--write-api).\n\nFor information about available fields see [`mod@s0_addressb`]
module"]
#[doc(alias = "S0_ADDRESSB")]
pub type S0Addressb = crate::Reg<s0_addressb::S0AddressbSpec>;
#[doc = "Slave I2C Address B Value"]
pub mod s0_addressb;
#[doc = "S0_ADDRESSMASKB (rw) register accessor: Slave I2C Address B Mask value\n\nYou can [`read`](crate::generic::Reg::read) this register and get [`s0_addressmaskb::R`]. You can [`reset`](crate::generic::Reg::reset), [`write`](crate::generic::Reg::write), [`write_with_zero`](crate::generic::Reg::write_with_zero) this register using [`s0_addressmaskb::W`]. You can also [`modify`](crate::generic::Reg::modify) this register. See [API](https://docs.rs/svd2rust/#read--modify--write-api).\n\nFor information about available fields see [`mod@s0_addressmaskb`]
#[doc = "S0_ADDRESSMASKB (rw) register accessor: Slave I2C Address B Mask value\n\nYou can [`read`](crate::Reg::read) this register and get [`s0_addressmaskb::R`]. You can [`reset`](crate::Reg::reset), [`write`](crate::Reg::write), [`write_with_zero`](crate::Reg::write_with_zero) this register using [`s0_addressmaskb::W`]. You can also [`modify`](crate::Reg::modify) this register. See [API](https://docs.rs/svd2rust/#read--modify--write-api).\n\nFor information about available fields see [`mod@s0_addressmaskb`]
module"]
#[doc(alias = "S0_ADDRESSMASKB")]
pub type S0Addressmaskb = crate::Reg<s0_addressmaskb::S0AddressmaskbSpec>;
#[doc = "Slave I2C Address B Mask value"]
pub mod s0_addressmaskb;
#[doc = "PERID (r) register accessor: Peripheral ID Register\n\nYou can [`read`](crate::generic::Reg::read) this register and get [`perid::R`]. See [API](https://docs.rs/svd2rust/#read--modify--write-api).\n\nFor information about available fields see [`mod@perid`]
#[doc = "PERID (r) register accessor: Peripheral ID Register\n\nYou can [`read`](crate::Reg::read) this register and get [`perid::R`]. See [API](https://docs.rs/svd2rust/#read--modify--write-api).\n\nFor information about available fields see [`mod@perid`]
module"]
#[doc(alias = "PERID")]
pub type Perid = crate::Reg<perid::PeridSpec>;

2
va108xx/src/i2ca/address.rs
View File

@ -8,7 +8,7 @@ impl core::fmt::Debug for R {
}
}
impl W {}
#[doc = "I2C Address value\n\nYou can [`read`](crate::generic::Reg::read) this register and get [`address::R`](R). You can [`reset`](crate::generic::Reg::reset), [`write`](crate::generic::Reg::write), [`write_with_zero`](crate::generic::Reg::write_with_zero) this register using [`address::W`](W). You can also [`modify`](crate::generic::Reg::modify) this register. See [API](https://docs.rs/svd2rust/#read--modify--write-api)."]
#[doc = "I2C Address value\n\nYou can [`read`](crate::Reg::read) this register and get [`address::R`](R). You can [`reset`](crate::Reg::reset), [`write`](crate::Reg::write), [`write_with_zero`](crate::Reg::write_with_zero) this register using [`address::W`](W). You can also [`modify`](crate::Reg::modify) this register. See [API](https://docs.rs/svd2rust/#read--modify--write-api)."]
pub struct AddressSpec;
impl crate::RegisterSpec for AddressSpec {
type Ux = u32;

4
va108xx/src/i2ca/clkscale.rs
View File

@ -25,18 +25,16 @@ impl R {
impl W {
#[doc = "Bits 0:30 - Enable FastMode"]
#[inline(always)]
#[must_use]
pub fn value(&mut self) -> ValueW<ClkscaleSpec> {
ValueW::new(self, 0)
}
#[doc = "Bit 31 - Enable FastMode"]
#[inline(always)]
#[must_use]
pub fn fastmode(&mut self) -> FastmodeW<ClkscaleSpec> {
FastmodeW::new(self, 31)
}
}
#[doc = "Clock Scale divide value\n\nYou can [`read`](crate::generic::Reg::read) this register and get [`clkscale::R`](R). You can [`reset`](crate::generic::Reg::reset), [`write`](crate::generic::Reg::write), [`write_with_zero`](crate::generic::Reg::write_with_zero) this register using [`clkscale::W`](W). You can also [`modify`](crate::generic::Reg::modify) this register. See [API](https://docs.rs/svd2rust/#read--modify--write-api)."]
#[doc = "Clock Scale divide value\n\nYou can [`read`](crate::Reg::read) this register and get [`clkscale::R`](R). You can [`reset`](crate::Reg::reset), [`write`](crate::Reg::write), [`write_with_zero`](crate::Reg::write_with_zero) this register using [`clkscale::W`](W). You can also [`modify`](crate::Reg::modify) this register. See [API](https://docs.rs/svd2rust/#read--modify--write-api)."]
pub struct ClkscaleSpec;
impl crate::RegisterSpec for ClkscaleSpec {
type Ux = u32;

2
va108xx/src/i2ca/clktolimit.rs
View File

@ -8,7 +8,7 @@ impl core::fmt::Debug for R {
}
}
impl W {}
#[doc = "Clock Low Timeout Limit Register\n\nYou can [`read`](crate::generic::Reg::read) this register and get [`clktolimit::R`](R). You can [`reset`](crate::generic::Reg::reset), [`write`](crate::generic::Reg::write), [`write_with_zero`](crate::generic::Reg::write_with_zero) this register using [`clktolimit::W`](W). You can also [`modify`](crate::generic::Reg::modify) this register. See [API](https://docs.rs/svd2rust/#read--modify--write-api)."]
#[doc = "Clock Low Timeout Limit Register\n\nYou can [`read`](crate::Reg::read) this register and get [`clktolimit::R`](R). You can [`reset`](crate::Reg::reset), [`write`](crate::Reg::write), [`write_with_zero`](crate::Reg::write_with_zero) this register using [`clktolimit::W`](W). You can also [`modify`](crate::Reg::modify) this register. See [API](https://docs.rs/svd2rust/#read--modify--write-api)."]
pub struct ClktolimitSpec;
impl crate::RegisterSpec for ClktolimitSpec {
type Ux = u32;

2
va108xx/src/i2ca/cmd.rs
View File

@ -8,7 +8,7 @@ impl core::fmt::Debug for R {
}
}
impl W {}
#[doc = "Command Register\n\nYou can [`read`](crate::generic::Reg::read) this register and get [`cmd::R`](R). You can [`reset`](crate::generic::Reg::reset), [`write`](crate::generic::Reg::write), [`write_with_zero`](crate::generic::Reg::write_with_zero) this register using [`cmd::W`](W). You can also [`modify`](crate::generic::Reg::modify) this register. See [API](https://docs.rs/svd2rust/#read--modify--write-api)."]
#[doc = "Command Register\n\nYou can [`read`](crate::Reg::read) this register and get [`cmd::R`](R). You can [`reset`](crate::Reg::reset), [`write`](crate::Reg::write), [`write_with_zero`](crate::Reg::write_with_zero) this register using [`cmd::W`](W). You can also [`modify`](crate::Reg::modify) this register. See [API](https://docs.rs/svd2rust/#read--modify--write-api)."]
pub struct CmdSpec;
impl crate::RegisterSpec for CmdSpec {
type Ux = u32;

11
va108xx/src/i2ca/ctrl.rs
View File

@ -88,60 +88,51 @@ impl R {
impl W {
#[doc = "Bit 0 - I2C CLK Enabled"]
#[inline(always)]
#[must_use]
pub fn clkenabled(&mut self) -> ClkenabledW<CtrlSpec> {
ClkenabledW::new(self, 0)
}
#[doc = "Bit 1 - I2C Activated"]
#[inline(always)]
#[must_use]
pub fn enabled(&mut self) -> EnabledW<CtrlSpec> {
EnabledW::new(self, 1)
}
#[doc = "Bit 2 - I2C Active"]
#[inline(always)]
#[must_use]
pub fn enable(&mut self) -> EnableW<CtrlSpec> {
EnableW::new(self, 2)
}
#[doc = "Bit 3 - TX FIFIO Empty Mode"]
#[inline(always)]
#[must_use]
pub fn txfemd(&mut self) -> TxfemdW<CtrlSpec> {
TxfemdW::new(self, 3)
}
#[doc = "Bit 4 - RX FIFO Full Mode"]
#[inline(always)]
#[must_use]
pub fn rxffmd(&mut self) -> RxffmdW<CtrlSpec> {
RxffmdW::new(self, 4)
}
#[doc = "Bit 5 - Enable Input Analog Glitch Filter"]
#[inline(always)]
#[must_use]
pub fn algfilter(&mut self) -> AlgfilterW<CtrlSpec> {
AlgfilterW::new(self, 5)
}
#[doc = "Bit 6 - Enable Input Digital Glitch Filter"]
#[inline(always)]
#[must_use]
pub fn dlgfilter(&mut self) -> DlgfilterW<CtrlSpec> {
DlgfilterW::new(self, 6)
}
#[doc = "Bit 8 - Enable LoopBack Mode"]
#[inline(always)]
#[must_use]
pub fn loopback(&mut self) -> LoopbackW<CtrlSpec> {
LoopbackW::new(self, 8)
}
#[doc = "Bit 9 - Enable Timing Config Register"]
#[inline(always)]
#[must_use]
pub fn tmconfigenb(&mut self) -> TmconfigenbW<CtrlSpec> {
TmconfigenbW::new(self, 9)
}
}
#[doc = "Control Register\n\nYou can [`read`](crate::generic::Reg::read) this register and get [`ctrl::R`](R). You can [`reset`](crate::generic::Reg::reset), [`write`](crate::generic::Reg::write), [`write_with_zero`](crate::generic::Reg::write_with_zero) this register using [`ctrl::W`](W). You can also [`modify`](crate::generic::Reg::modify) this register. See [API](https://docs.rs/svd2rust/#read--modify--write-api)."]
#[doc = "Control Register\n\nYou can [`read`](crate::Reg::read) this register and get [`ctrl::R`](R). You can [`reset`](crate::Reg::reset), [`write`](crate::Reg::write), [`write_with_zero`](crate::Reg::write_with_zero) this register using [`ctrl::W`](W). You can also [`modify`](crate::Reg::modify) this register. See [API](https://docs.rs/svd2rust/#read--modify--write-api)."]
pub struct CtrlSpec;
impl crate::RegisterSpec for CtrlSpec {
type Ux = u32;

2
va108xx/src/i2ca/data.rs
View File

@ -8,7 +8,7 @@ impl core::fmt::Debug for R {
}
}
impl W {}
#[doc = "Data Input/Output\n\nYou can [`read`](crate::generic::Reg::read) this register and get [`data::R`](R). You can [`reset`](crate::generic::Reg::reset), [`write`](crate::generic::Reg::write), [`write_with_zero`](crate::generic::Reg::write_with_zero) this register using [`data::W`](W). You can also [`modify`](crate::generic::Reg::modify) this register. See [API](https://docs.rs/svd2rust/#read--modify--write-api)."]
#[doc = "Data Input/Output\n\nYou can [`read`](crate::Reg::read) this register and get [`data::R`](R). You can [`reset`](crate::Reg::reset), [`write`](crate::Reg::write), [`write_with_zero`](crate::Reg::write_with_zero) this register using [`data::W`](W). You can also [`modify`](crate::Reg::modify) this register. See [API](https://docs.rs/svd2rust/#read--modify--write-api)."]
pub struct DataSpec;
impl crate::RegisterSpec for DataSpec {
type Ux = u32;

4
va108xx/src/i2ca/fifo_clr.rs
View File

@ -7,18 +7,16 @@ pub type TxfifoW<'a, REG> = crate::BitWriter<'a, REG>;
impl W {
#[doc = "Bit 0 - Clear Rx FIFO"]
#[inline(always)]
#[must_use]
pub fn rxfifo(&mut self) -> RxfifoW<FifoClrSpec> {
RxfifoW::new(self, 0)
}
#[doc = "Bit 1 - Clear Tx FIFO"]
#[inline(always)]
#[must_use]
pub fn txfifo(&mut self) -> TxfifoW<FifoClrSpec> {
TxfifoW::new(self, 1)
}
}
#[doc = "Clear FIFO Register\n\nYou can [`reset`](crate::generic::Reg::reset), [`write`](crate::generic::Reg::write), [`write_with_zero`](crate::generic::Reg::write_with_zero) this register using [`fifo_clr::W`](W). See [API](https://docs.rs/svd2rust/#read--modify--write-api)."]
#[doc = "Clear FIFO Register\n\nYou can [`reset`](crate::Reg::reset), [`write`](crate::Reg::write), [`write_with_zero`](crate::Reg::write_with_zero) this register using [`fifo_clr::W`](W). See [API](https://docs.rs/svd2rust/#read--modify--write-api)."]
pub struct FifoClrSpec;
impl crate::RegisterSpec for FifoClrSpec {
type Ux = u32;

16
va108xx/src/i2ca/irq_enb.rs
View File

@ -133,90 +133,76 @@ impl R {
impl W {
#[doc = "Bit 0 - I2C Bus is Idle"]
#[inline(always)]
#[must_use]
pub fn i2cidle(&mut self) -> I2cidleW<IrqEnbSpec> {
I2cidleW::new(self, 0)
}
#[doc = "Bit 1 - Controller is Idle"]
#[inline(always)]
#[must_use]
pub fn idle(&mut self) -> IdleW<IrqEnbSpec> {
IdleW::new(self, 1)
}
#[doc = "Bit 2 - Controller is Waiting"]
#[inline(always)]
#[must_use]
pub fn waiting(&mut self) -> WaitingW<IrqEnbSpec> {
WaitingW::new(self, 2)
}
#[doc = "Bit 3 - Controller is Stalled"]
#[inline(always)]
#[must_use]
pub fn stalled(&mut self) -> StalledW<IrqEnbSpec> {
StalledW::new(self, 3)
}
#[doc = "Bit 4 - I2C Arbitration was lost"]
#[inline(always)]
#[must_use]
pub fn arblost(&mut self) -> ArblostW<IrqEnbSpec> {
ArblostW::new(self, 4)
}
#[doc = "Bit 5 - I2C Address was not Acknowledged"]
#[inline(always)]
#[must_use]
pub fn nackaddr(&mut self) -> NackaddrW<IrqEnbSpec> {
NackaddrW::new(self, 5)
}
#[doc = "Bit 6 - I2C Data was not Acknowledged"]
#[inline(always)]
#[must_use]
pub fn nackdata(&mut self) -> NackdataW<IrqEnbSpec> {
NackdataW::new(self, 6)
}
#[doc = "Bit 7 - I2C Clock Low Timeout"]
#[inline(always)]
#[must_use]
pub fn clkloto(&mut self) -> ClklotoW<IrqEnbSpec> {
ClklotoW::new(self, 7)
}
#[doc = "Bit 10 - TX FIFO Overflowed"]
#[inline(always)]
#[must_use]
pub fn txoverflow(&mut self) -> TxoverflowW<IrqEnbSpec> {
TxoverflowW::new(self, 10)
}
#[doc = "Bit 11 - TX FIFO Overflowed"]
#[inline(always)]
#[must_use]
pub fn rxoverflow(&mut self) -> RxoverflowW<IrqEnbSpec> {
RxoverflowW::new(self, 11)
}
#[doc = "Bit 12 - TX FIFO Ready"]
#[inline(always)]
#[must_use]
pub fn txready(&mut self) -> TxreadyW<IrqEnbSpec> {
TxreadyW::new(self, 12)
}
#[doc = "Bit 13 - RX FIFO Ready"]
#[inline(always)]
#[must_use]
pub fn rxready(&mut self) -> RxreadyW<IrqEnbSpec> {
RxreadyW::new(self, 13)
}
#[doc = "Bit 14 - TX FIFO Empty"]
#[inline(always)]
#[must_use]
pub fn txempty(&mut self) -> TxemptyW<IrqEnbSpec> {
TxemptyW::new(self, 14)
}
#[doc = "Bit 15 - RX FIFO Full"]
#[inline(always)]
#[must_use]
pub fn rxfull(&mut self) -> RxfullW<IrqEnbSpec> {
RxfullW::new(self, 15)
}
}
#[doc = "Interrupt Enable Register\n\nYou can [`read`](crate::generic::Reg::read) this register and get [`irq_enb::R`](R). You can [`reset`](crate::generic::Reg::reset), [`write`](crate::generic::Reg::write), [`write_with_zero`](crate::generic::Reg::write_with_zero) this register using [`irq_enb::W`](W). You can also [`modify`](crate::generic::Reg::modify) this register. See [API](https://docs.rs/svd2rust/#read--modify--write-api)."]
#[doc = "Interrupt Enable Register\n\nYou can [`read`](crate::Reg::read) this register and get [`irq_enb::R`](R). You can [`reset`](crate::Reg::reset), [`write`](crate::Reg::write), [`write_with_zero`](crate::Reg::write_with_zero) this register using [`irq_enb::W`](W). You can also [`modify`](crate::Reg::modify) this register. See [API](https://docs.rs/svd2rust/#read--modify--write-api)."]
pub struct IrqEnbSpec;
impl crate::RegisterSpec for IrqEnbSpec {
type Ux = u32;

2
va108xx/src/i2ca/perid.rs
View File

@ -5,7 +5,7 @@ impl core::fmt::Debug for R {
write!(f, "{}", self.bits())
}
}
#[doc = "Peripheral ID Register\n\nYou can [`read`](crate::generic::Reg::read) this register and get [`perid::R`](R). See [API](https://docs.rs/svd2rust/#read--modify--write-api)."]
#[doc = "Peripheral ID Register\n\nYou can [`read`](crate::Reg::read) this register and get [`perid::R`](R). See [API](https://docs.rs/svd2rust/#read--modify--write-api)."]
pub struct PeridSpec;
impl crate::RegisterSpec for PeridSpec {
type Ux = u32;

2
va108xx/src/i2ca/rxcount.rs
View File

@ -5,7 +5,7 @@ impl core::fmt::Debug for R {
write!(f, "{}", self.bits())
}
}
#[doc = "RX Count Register\n\nYou can [`read`](crate::generic::Reg::read) this register and get [`rxcount::R`](R). See [API](https://docs.rs/svd2rust/#read--modify--write-api)."]
#[doc = "RX Count Register\n\nYou can [`read`](crate::Reg::read) this register and get [`rxcount::R`](R). See [API](https://docs.rs/svd2rust/#read--modify--write-api)."]
pub struct RxcountSpec;
impl crate::RegisterSpec for RxcountSpec {
type Ux = u32;

2
va108xx/src/i2ca/rxfifoirqtrg.rs
View File

@ -8,7 +8,7 @@ impl core::fmt::Debug for R {
}
}
impl W {}
#[doc = "Rx FIFO IRQ Trigger Level\n\nYou can [`read`](crate::generic::Reg::read) this register and get [`rxfifoirqtrg::R`](R). You can [`reset`](crate::generic::Reg::reset), [`write`](crate::generic::Reg::write), [`write_with_zero`](crate::generic::Reg::write_with_zero) this register using [`rxfifoirqtrg::W`](W). You can also [`modify`](crate::generic::Reg::modify) this register. See [API](https://docs.rs/svd2rust/#read--modify--write-api)."]
#[doc = "Rx FIFO IRQ Trigger Level\n\nYou can [`read`](crate::Reg::read) this register and get [`rxfifoirqtrg::R`](R). You can [`reset`](crate::Reg::reset), [`write`](crate::Reg::write), [`write_with_zero`](crate::Reg::write_with_zero) this register using [`rxfifoirqtrg::W`](W). You can also [`modify`](crate::Reg::modify) this register. See [API](https://docs.rs/svd2rust/#read--modify--write-api)."]
pub struct RxfifoirqtrgSpec;
impl crate::RegisterSpec for RxfifoirqtrgSpec {
type Ux = u32;

2
va108xx/src/i2ca/s0_address.rs
View File

@ -8,7 +8,7 @@ impl core::fmt::Debug for R {
}
}
impl W {}
#[doc = "Slave I2C Address Value\n\nYou can [`read`](crate::generic::Reg::read) this register and get [`s0_address::R`](R). You can [`reset`](crate::generic::Reg::reset), [`write`](crate::generic::Reg::write), [`write_with_zero`](crate::generic::Reg::write_with_zero) this register using [`s0_address::W`](W). You can also [`modify`](crate::generic::Reg::modify) this register. See [API](https://docs.rs/svd2rust/#read--modify--write-api)."]
#[doc = "Slave I2C Address Value\n\nYou can [`read`](crate::Reg::read) this register and get [`s0_address::R`](R). You can [`reset`](crate::Reg::reset), [`write`](crate::Reg::write), [`write_with_zero`](crate::Reg::write_with_zero) this register using [`s0_address::W`](W). You can also [`modify`](crate::Reg::modify) this register. See [API](https://docs.rs/svd2rust/#read--modify--write-api)."]
pub struct S0AddressSpec;
impl crate::RegisterSpec for S0AddressSpec {
type Ux = u32;

2
va108xx/src/i2ca/s0_addressb.rs
View File

@ -8,7 +8,7 @@ impl core::fmt::Debug for R {
}
}
impl W {}
#[doc = "Slave I2C Address B Value\n\nYou can [`read`](crate::generic::Reg::read) this register and get [`s0_addressb::R`](R). You can [`reset`](crate::generic::Reg::reset), [`write`](crate::generic::Reg::write), [`write_with_zero`](crate::generic::Reg::write_with_zero) this register using [`s0_addressb::W`](W). You can also [`modify`](crate::generic::Reg::modify) this register. See [API](https://docs.rs/svd2rust/#read--modify--write-api)."]
#[doc = "Slave I2C Address B Value\n\nYou can [`read`](crate::Reg::read) this register and get [`s0_addressb::R`](R). You can [`reset`](crate::Reg::reset), [`write`](crate::Reg::write), [`write_with_zero`](crate::Reg::write_with_zero) this register using [`s0_addressb::W`](W). You can also [`modify`](crate::Reg::modify) this register. See [API](https://docs.rs/svd2rust/#read--modify--write-api)."]
pub struct S0AddressbSpec;
impl crate::RegisterSpec for S0AddressbSpec {
type Ux = u32;

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