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Klagarge:main Klagarge:develop Klagarge:FEAT/bootloader
Klagarge:Phase3 Klagarge:Phase2 Klagarge:Part1 Klagarge:Phase1 Klagarge:Phase-1
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compare: Klagarge:1f9e4ebd3c188cec1c0ff2796ed9bfad9b188229
Branches Tags
Klagarge:main Klagarge:develop Klagarge:FEAT/bootloader
Klagarge:Phase3 Klagarge:Phase2 Klagarge:Part1 Klagarge:Phase1 Klagarge:Phase-1

23 Commits
Part1 ... 1f9e4ebd3c

Author SHA1 Message Date
Klagarge
1f9e4ebd3c FIX cast with chrono duration 2024-12-30 17:02:16 +01:00
fastium
7d7fb400ff FIX tests namespaces 2024-12-30 13:57:42 +01:00
fastium
db834de1fd ADD cpplint args in action file 2024-12-30 13:57:42 +01:00
fastium
84bd49be80 FIX delete flag unused function 2024-12-30 13:57:42 +01:00
fastium
ebfcef2c57 ADD suppress args for cppcheck 2024-12-30 13:57:42 +01:00
fastium
e7a2a7da59 ADD files to pre-commit 2024-12-30 13:57:42 +01:00
fastium
9aa656c7ac ADD test pre-commit 2024-12-30 13:57:42 +01:00
fastium
9c104fc3a2 ADD project folders to pre-commit 2024-12-30 13:57:42 +01:00
Klagarge
1ba466569e FIX delta to use GCC rather than ARMC6 2024-11-19 14:38:42 +01:00
Klagarge
60baebd59b Merge branch 'main' into develop 2024-11-19 11:53:56 +01:00
Klagarge
eeb88edba3 UPD CI workflow 2024-11-18 10:13:01 +01:00
Klagarge
ac4067e5a4 RM folder ignore for tests 2024-11-18 10:13:01 +01:00
Klagarge
86e033fe2f ADD answer to questions 2024-11-18 10:13:01 +01:00
Klagarge
f6f3d59ef3 ADD run configurations 2024-11-18 10:13:01 +01:00
Klagarge
20406664c3 FIX reset task 2024-11-18 10:13:01 +01:00
Klagarge
62d7d7b376 FIX Static scheduling with event 2024-11-18 10:13:01 +01:00
Klagarge
35d2d76bca ADD [WIP] Static scheduling with event 2024-11-18 10:13:01 +01:00
Klagarge
0bd561b947 ADD EventQueue for static_scheduling 2024-11-18 10:13:01 +01:00
Klagarge
b52f476124 ADD Thread sleep 2024-11-18 10:13:01 +01:00
Klagarge
c66c8a0963 ADD cpu logger 2024-11-18 10:13:01 +01:00
Klagarge
4c174ce444 ADD bike-system super-loop with while 2024-11-18 10:13:01 +01:00
Klagarge
15d1183bac FIX raw + unique ptr tests 
FIX issues on raw and unique pointer tests
+ Merge individual test files for unique and raw pointers and merged their test cases into a single test file for simplicity.
 2024-11-05 16:36:29 +01:00
Fastium
df8edf3c34 Merge pull request #4 from Fastium/develop
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develop
 2024-10-21 17:34:29 +02:00
28 changed files with 1540 additions and 176 deletions
Expand all files Collapse all files

8
.github/workflows/build-test.yml vendored
View File

@ -1,6 +1,6 @@
name: Build test application name: Build test application
on: on:
pull_request: push:
jobs: jobs:
build-cli-v1: build-cli-v1:
@ -14,11 +14,9 @@ jobs:
target: [DISCO_H747I] target: [DISCO_H747I]
profile: [debug] profile: [debug]
tests: [ tests: [
tests-simple-test-always-succeed,
tests-simple-test-test-ptr,
advdembsof_library-tests-sensors-hdc1000,
tests-bike-computer-sensor-device, tests-bike-computer-sensor-device,
tests-bike-computer-speedometer tests-bike-computer-speedometer,
tests-bike-computer-bike-system,
] ]

18
.pre-commit-config.yaml
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@ -1,24 +1,26 @@
files: ^main.cpp files: ^main.cpp|^static_scheduling|^static_scheduling_with_event|^TESTS
repos: repos:
- repo: https://github.com/pre-commit/pre-commit-hooks - repo: https://github.com/pre-commit/pre-commit-hooks
rev: v4.3.0 rev: v4.3.0
hooks: hooks:
- id: check-yaml - id: check-yaml
args: [--allow-multiple-documents] args: [--allow-multiple-documents]
- id: end-of-file-fixer - id: end-of-file-fixer
- id: trailing-whitespace - id: trailing-whitespace
- repo: https://github.com/pre-commit/mirrors-clang-format - repo: https://github.com/pre-commit/mirrors-clang-format
rev: 'v14.0.6' rev: "v14.0.6"
hooks: hooks:
- id: clang-format - id: clang-format
- repo: https://github.com/cpplint/cpplint - repo: https://github.com/cpplint/cpplint
rev: '1.6.1' rev: "1.6.1"
hooks: hooks:
- id: cpplint - id: cpplint
- repo: local name: cpplint
entry: cpplint --linelength=90 --filter=-build/include_subdir,-whitespace/indent,-build/namespaces,-build/c++11
- repo: local
hooks: hooks:
- id: cppcheck - id: cppcheck
name: cppcheck name: cppcheck
require_serial: true require_serial: true
entry: cppcheck --enable=all --suppress=missingInclude:* --inline-suppr -i mbed-os --std=c++14 --error-exitcode=1 entry: cppcheck --enable=all --suppress=missingInclude --suppress=missingIncludeSystem --inline-suppr -i mbed-os --std=c++14 --error-exitcode=1
language: system language: system

66
README.md
View File

@ -22,3 +22,69 @@ Test sensor libraries :
```terminal ```terminal
mbed test -m DISCO_H747I -t GCC_ARM -n advdembsof_library-tests-sensors-hdc1000 --compile --run mbed test -m DISCO_H747I -t GCC_ARM -n advdembsof_library-tests-sensors-hdc1000 --compile --run
``` ```
## Run static scheduling
On `.mbedignore` put at the end of the file
```
static_scheduling_with_event/*
```
On main.cpp include `"static_scheduling/bike_system.hpp"` and use :
```cpp
static_scheduling::BikeSystem bikeSystem;
bikeSystem.start();
```
## Run static scheduling with event queue
On `.mbedignore` put at the end of the file :
```
static_scheduling_with_event/*
```
On main.cpp include `"static_scheduling/bike_system.hpp"` and use :
```cpp
static_scheduling::BikeSystem bikeSystem;
bikeSystem.startWithEventQueue();
```
## Run static scheduling with event scheduling
On `.mbedignore` put at the end of the file
```
static_scheduling/*
```
On main.cpp include `"static_scheduling_with_event/bike_system.hpp"` and use :
```cpp
static_scheduling_with_event::BikeSystem bikeSystem;
bikeSystem.start();
```
# Some questions
## Question 1
`If you print CPU statistics at the end of every major cycle (in the super-loop), what CPU usage do you observe? How can you explain the observed CPU uptime?`
We observe a 100% usage because on each CPU cycle it compare if time is done.
## Question 2
`If you run the program after the change from busy wait to sleep calls, what CPU usage do you observe? How can you explain the observed CPU uptime?`
We can observe only a usage of 75% because the CPU is more on Idle with Thread sleep.
## Question 3
`If you run the static_scheduling_with_event program, what CPU usage do you observe? How can you explain the observed CPU uptime?`
We observe a light usage of 1% of CPU. The CPU is now sleeping all the time and doing small task only on event.
## Question 4
`When you run multiple tests for computing the response time of the reset event, what do you observe? Is there an improvement as compared to the static_scheduling::BikeSystem implementation?`
` - If you do not press long enough on the push button, the event may be missed and no reset happens.`
`Based on the program itself and on the task scheduling, explain these two behaviors. Explain also why such behaviors may be problematic.`
We notice, that we miss such less event when is event driven (or not at all). But with a static scheduling the response time is still long because the reset task is call with a certain period.
# Issues
When compile with GCC, the full loop of static scheduling is 2 to 3 ms faster than expected.
This problem doesn't occur if we compile with ARMC6.
As the acceptable delta is 2ms and the teacher test is done with GCC, we modify the delta on the test to be 3ms

163
TESTS/bike-computer/bike-system/main.cpp Normal file
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@ -0,0 +1,163 @@
// Copyright 2022 Haute école d'ingénierie et d'architecture de Fribourg
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
/****************************************************************************
* @file main.cpp
* @author Serge Ayer <serge.ayer@hefr.ch>
*
* @brief Bike computer test suite: scheduling
*
* @date 2023-08-26
* @version 0.1.0
***************************************************************************/
#include <chrono>
#include "greentea-client/test_env.h"
#include "mbed.h"
#include "static_scheduling/bike_system.hpp"
#include "static_scheduling_with_event/bike_system.hpp"
#include "task_logger.hpp"
#include "unity/unity.h"
#include "utest/utest.h"
namespace utest {
namespace v1 {
// test_bike_system handler function
static void test_bike_system() {
// create the BikeSystem instance
static_scheduling::BikeSystem bikeSystem;
// run the bike system in a separate thread
Thread thread;
thread.start(callback(&bikeSystem, &static_scheduling::BikeSystem::start));
// let the bike system run for 20 secs
ThisThread::sleep_for(20s);
// stop the bike system
bikeSystem.stop();
// check whether scheduling was correct
// Order is kGearTaskIndex, kSpeedTaskIndex, kTemperatureTaskIndex,
// kResetTaskIndex, kDisplayTask1Index, kDisplayTask2Index
constexpr std::chrono::microseconds taskComputationTimes[] = {
100000us, 200000us, 100000us, 100000us, 200000us, 100000us};
constexpr std::chrono::microseconds taskPeriods[] = {
800000us, 400000us, 1600000us, 800000us, 1600000us, 1600000us};
// allow for 2 msecs offset
uint64_t deltaUs = 3000;
for (uint8_t taskIndex = 0; taskIndex < advembsof::TaskLogger::kNbrOfTasks;
taskIndex++) {
TEST_ASSERT_UINT64_WITHIN(
deltaUs,
taskPeriods[taskIndex].count(),
bikeSystem.getTaskLogger().getPeriod(taskIndex).count());
TEST_ASSERT_UINT64_WITHIN(
deltaUs,
taskComputationTimes[taskIndex].count(),
bikeSystem.getTaskLogger().getComputationTime(taskIndex).count());
}
}
// test_bike_system_event_queue handler function
static void test_bike_system_event_queue() {
// create the BikeSystem instance
static_scheduling::BikeSystem bikeSystem;
// run the bike system in a separate thread
Thread thread;
thread.start(
callback(&bikeSystem, &static_scheduling::BikeSystem::startWithEventQueue));
// let the bike system run for 20 secs
ThisThread::sleep_for(20s);
// stop the bike system
bikeSystem.stop();
// check whether scheduling was correct
// Order is kGearTaskIndex, kSpeedTaskIndex, kTemperatureTaskIndex,
// kResetTaskIndex, kDisplayTask1Index, kDisplayTask2Index
// When we use the event queue, we do not check the computation time
constexpr std::chrono::microseconds taskPeriods[] = {
800000us, 400000us, 1600000us, 800000us, 1600000us, 1600000us};
// allow for 2 msecs offset (with EventQueue)
uint64_t deltaUs = 3000;
for (uint8_t taskIndex = 0; taskIndex < advembsof::TaskLogger::kNbrOfTasks;
taskIndex++) {
TEST_ASSERT_UINT64_WITHIN(
deltaUs,
taskPeriods[taskIndex].count(),
bikeSystem.getTaskLogger().getPeriod(taskIndex).count());
}
}
// test_bike_system_with_event handler function
static void test_bike_system_with_event() {
// create the BikeSystem instance
static_scheduling_with_event::BikeSystem bikeSystem;
// run the bike system in a separate thread
Thread thread;
thread.start(callback(&bikeSystem, &static_scheduling_with_event::BikeSystem::start));
// let the bike system run for 20 secs
ThisThread::sleep_for(20s);
// stop the bike system
bikeSystem.stop();
// check whether scheduling was correct
// Order is kGearTaskIndex, kSpeedTaskIndex, kTemperatureTaskIndex,
// kResetTaskIndex, kDisplayTask1Index, kDisplayTask2Index
// When we use event handling, we do not check the computation time
constexpr std::chrono::microseconds taskPeriods[] = {
800000us, 400000us, 1600000us, 800000us, 1600000us, 1600000us};
// allow for 2 msecs offset (with EventQueue)
uint64_t deltaUs = 3000;
for (uint8_t taskIndex = 0; taskIndex < advembsof::TaskLogger::kNbrOfTasks;
taskIndex++) {
TEST_ASSERT_UINT64_WITHIN(
deltaUs,
taskPeriods[taskIndex].count(),
bikeSystem.getTaskLogger().getPeriod(taskIndex).count());
}
}
static status_t greentea_setup(const size_t number_of_cases) {
// Here, we specify the timeout (60s) and the host test (a built-in host test
// or the name of our Python file)
GREENTEA_SETUP(180, "default_auto");
return greentea_test_setup_handler(number_of_cases);
}
// List of test cases in this file
static Case cases[] = {
Case("test bike system", test_bike_system),
Case("test bike system with event queue", test_bike_system_event_queue),
Case("test bike system with event handling", test_bike_system_with_event),
};
static Specification specification(greentea_setup, cases);
}; // namespace v1
}; // namespace utest
int main() { return !utest::v1::Harness::run(utest::v1::specification); }

13
TESTS/bike-computer/sensor-device/main.cpp
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@ -29,7 +29,8 @@
#include "unity/unity.h" #include "unity/unity.h"
#include "utest/utest.h" #include "utest/utest.h"
using namespace utest::v1; namespace utest {
namespace v1 {
// test_hdc1000 test handler function // test_hdc1000 test handler function
static control_t test_sensor_device(const size_t call_count) { static control_t test_sensor_device(const size_t call_count) {
@ -53,9 +54,9 @@ static control_t test_sensor_device(const size_t call_count) {
return CaseNext; return CaseNext;
} }
static utest::v1::status_t greentea_setup(const size_t number_of_cases) { static status_t greentea_setup(const size_t number_of_cases) {
// Here, we specify the timeout (60s) and the host test (a built-in host test or the // Here, we specify the timeout (60s) and the host test (a built-in host test
// name of our Python file) // or the name of our Python file)
GREENTEA_SETUP(60, "default_auto"); GREENTEA_SETUP(60, "default_auto");
return greentea_test_setup_handler(number_of_cases); return greentea_test_setup_handler(number_of_cases);
@ -65,5 +66,7 @@ static utest::v1::status_t greentea_setup(const size_t number_of_cases) {
static Case cases[] = {Case("test sensor device", test_sensor_device)}; static Case cases[] = {Case("test sensor device", test_sensor_device)};
static Specification specification(greentea_setup, cases); static Specification specification(greentea_setup, cases);
}; // namespace v1
}; // namespace utest
int main() { return !Harness::run(specification); } int main() { return !utest::v1::Harness::run(utest::v1::specification); }

21
TESTS/bike-computer/speedometer/main.cpp
View File

@ -32,13 +32,14 @@
#include "unity/unity.h" #include "unity/unity.h"
#include "utest/utest.h" #include "utest/utest.h"
using namespace utest::v1;
// allow for 0.1 km/h difference // allow for 0.1 km/h difference
static constexpr float kAllowedSpeedDelta = 0.1f; static constexpr float kAllowedSpeedDelta = 0.1f;
// allow for 1m difference // allow for 1m difference
static constexpr float kAllowedDistanceDelta = 1.0f / 1000.0; static constexpr float kAllowedDistanceDelta = 1.0f / 1000.0;
namespace utest {
namespace v1 {
// function called by test handler functions for verifying the current speed // function called by test handler functions for verifying the current speed
void check_current_speed(const std::chrono::milliseconds& pedalRotationTime, void check_current_speed(const std::chrono::milliseconds& pedalRotationTime,
uint8_t traySize, uint8_t traySize,
@ -75,7 +76,8 @@ float compute_distance(const std::chrono::milliseconds& pedalRotationTime,
float trayGearRatio = static_cast<float>(traySize) / static_cast<float>(gearSize); float trayGearRatio = static_cast<float>(traySize) / static_cast<float>(gearSize);
float distancePerPedalTurn = trayGearRatio * wheelCircumference; float distancePerPedalTurn = trayGearRatio * wheelCircumference;
// distancePerPedalTurn is expressed in m, divide per 1000 for a distance in km // distancePerPedalTurn is expressed in m, divide per 1000 for a distance in
// km
return (distancePerPedalTurn * pedalRotations) / 1000.0; return (distancePerPedalTurn * pedalRotations) / 1000.0;
} }
@ -86,7 +88,8 @@ void check_distance(const std::chrono::milliseconds& pedalRotationTime,
float wheelCircumference, float wheelCircumference,
const std::chrono::milliseconds& travelTime, const std::chrono::milliseconds& travelTime,
float distance) { float distance) {
// distancePerPedalTurn is expressed in m, divide per 1000 for a distance in km // distancePerPedalTurn is expressed in m, divide per 1000 for a distance in
// km
float expectedDistance = compute_distance( float expectedDistance = compute_distance(
pedalRotationTime, traySize, gearSize, wheelCircumference, travelTime); pedalRotationTime, traySize, gearSize, wheelCircumference, travelTime);
printf(" Expected distance is %f, current distance is %f\n", printf(" Expected distance is %f, current distance is %f\n",
@ -334,9 +337,9 @@ static control_t test_reset(const size_t call_count) {
return CaseNext; return CaseNext;
} }
static utest::v1::status_t greentea_setup(const size_t number_of_cases) { static status_t greentea_setup(const size_t number_of_cases) {
// Here, we specify the timeout (60s) and the host test (a built-in host test or the // Here, we specify the timeout (60s) and the host test (a built-in host test
// name of our Python file) // or the name of our Python file)
GREENTEA_SETUP(180, "default_auto"); GREENTEA_SETUP(180, "default_auto");
return greentea_test_setup_handler(number_of_cases); return greentea_test_setup_handler(number_of_cases);
@ -350,5 +353,7 @@ static Case cases[] = {
Case("test speedometer reset", test_reset)}; Case("test speedometer reset", test_reset)};
static Specification specification(greentea_setup, cases); static Specification specification(greentea_setup, cases);
}; // namespace v1
}; // namespace utest
int main() { return !Harness::run(specification); } int main() { return !utest::v1::Harness::run(utest::v1::specification); }

14
TESTS/simple-test/always-succeed/main.cpp
View File

@ -27,7 +27,8 @@
#include "unity/unity.h" #include "unity/unity.h"
#include "utest/utest.h" #include "utest/utest.h"
using namespace utest::v1; namespace utest {
namespace v1 {
// test handler function // test handler function
static control_t always_succeed(const size_t call_count) { static control_t always_succeed(const size_t call_count) {
@ -38,9 +39,9 @@ static control_t always_succeed(const size_t call_count) {
return CaseNext; return CaseNext;
} }
static utest::v1::status_t greentea_setup(const size_t number_of_cases) { static status_t greentea_setup(const size_t number_of_cases) {
// Here, we specify the timeout (60s) and the host test (a built-in host test or the // Here, we specify the timeout (60s) and the host test (a built-in host test
// name of our Python file) // or the name of our Python file)
GREENTEA_SETUP(60, "default_auto"); GREENTEA_SETUP(60, "default_auto");
return greentea_test_setup_handler(number_of_cases); return greentea_test_setup_handler(number_of_cases);
@ -51,4 +52,7 @@ static Case cases[] = {Case("always succeed test", always_succeed)};
static Specification specification(greentea_setup, cases); static Specification specification(greentea_setup, cases);
int main() { return !Harness::run(specification); } }; // namespace v1
}; // namespace utest
int main() { return !utest::v1::Harness::run(utest::v1::specification); }

63
TESTS/simple-test/test-ptr/main.cpp
View File

@ -24,12 +24,14 @@
* @version 0.2.0 * @version 0.2.0
***************************************************************************/ ***************************************************************************/
#include "greentea-client/test_env.h" #include "greentea-client/test_env.h" // NOLINT
#include "mbed.h" #include "mbed.h" // NOLINT
#include "unity/unity.h" #include "unity/unity.h" // NOLINT
#include "utest/utest.h" #include "utest/utest.h" // NOLINT
namespace utest {
namespace v1 {
using namespace utest::v1;
struct Test { struct Test {
Test() { Test() {
_instanceCount++; _instanceCount++;
@ -48,7 +50,8 @@ struct Test {
uint32_t Test::_instanceCount = 0; uint32_t Test::_instanceCount = 0;
/** /**
* Test that a shared pointer correctly manages the lifetime of the underlying raw pointer * Test that a shared pointer correctly manages the lifetime of the underlying
* raw pointer
*/ */
void test_single_sharedptr_lifetime() { void test_single_sharedptr_lifetime() {
// Sanity-check value of counter // Sanity-check value of counter
@ -66,8 +69,8 @@ void test_single_sharedptr_lifetime() {
} }
/** /**
* Test that multiple instances of shared pointers correctly manage the reference count * Test that multiple instances of shared pointers correctly manage the
* to release the object at the correct point * reference count to release the object at the correct point
*/ */
void test_instance_sharing() { void test_instance_sharing() {
std::shared_ptr<Test> shared_ptr1(nullptr); std::shared_ptr<Test> shared_ptr1(nullptr);
@ -97,8 +100,8 @@ void test_instance_sharing() {
} }
/********************** /**********************
* UNIQUE PTR EXERCISE * * UNIQUE PTR EXERCISE *
**********************/ **********************/
/* /*
* Check normal lifetime on a unique_ptr * Check normal lifetime on a unique_ptr
@ -132,12 +135,12 @@ void test_unique_ptr_transfer() {
TEST_ASSERT_EQUAL(0, Test::_instanceCount); TEST_ASSERT_EQUAL(0, Test::_instanceCount);
{ {
//create p1 // create p1
std::unique_ptr<Test> p1 = std::make_unique<Test>(); std::unique_ptr<Test> p1 = std::make_unique<Test>();
TEST_ASSERT_EQUAL(Test::kMagicNumber, p1->_value); TEST_ASSERT_EQUAL(Test::kMagicNumber, p1->_value);
TEST_ASSERT_EQUAL(1, Test::_instanceCount); TEST_ASSERT_EQUAL(1, Test::_instanceCount);
//transfer p1 to p2 // transfer p1 to p2
std::unique_ptr<Test> p2 = std::move(p1); std::unique_ptr<Test> p2 = std::move(p1);
TEST_ASSERT_EQUAL(Test::kMagicNumber, p2->_value); TEST_ASSERT_EQUAL(Test::kMagicNumber, p2->_value);
TEST_ASSERT_EQUAL(1, Test::_instanceCount); TEST_ASSERT_EQUAL(1, Test::_instanceCount);
@ -145,7 +148,7 @@ void test_unique_ptr_transfer() {
p2.reset(); p2.reset();
TEST_ASSERT_EQUAL(0, Test::_instanceCount); TEST_ASSERT_EQUAL(0, Test::_instanceCount);
TEST_ASSERT(!p1); TEST_ASSERT(!p1); // cppcheck-suppress accessMoved
TEST_ASSERT(!p2); TEST_ASSERT(!p2);
} }
@ -160,13 +163,13 @@ void test_unique_ptr_release() {
TEST_ASSERT_EQUAL(0, Test::_instanceCount); TEST_ASSERT_EQUAL(0, Test::_instanceCount);
{ {
//create p1 // create p1
std::unique_ptr<Test> p1 = std::make_unique<Test>(); std::unique_ptr<Test> p1 = std::make_unique<Test>();
TEST_ASSERT_EQUAL(Test::kMagicNumber, p1->_value); TEST_ASSERT_EQUAL(Test::kMagicNumber, p1->_value);
TEST_ASSERT_EQUAL(1, Test::_instanceCount); TEST_ASSERT_EQUAL(1, Test::_instanceCount);
//transfer and release p1 to p2 // transfer and release p1 to p2
Test * p2 = p1.release(); Test* p2 = p1.release();
TEST_ASSERT_EQUAL(Test::kMagicNumber, p2->_value); TEST_ASSERT_EQUAL(Test::kMagicNumber, p2->_value);
TEST_ASSERT_EQUAL(1, Test::_instanceCount); TEST_ASSERT_EQUAL(1, Test::_instanceCount);
@ -192,21 +195,21 @@ void test_unique_ptr_swap() {
const uint32_t number1 = 65; const uint32_t number1 = 65;
const uint32_t number2 = 42; const uint32_t number2 = 42;
//create p1 // create p1
std::unique_ptr<Test> p1 = std::make_unique<Test>(); std::unique_ptr<Test> p1 = std::make_unique<Test>();
TEST_ASSERT_EQUAL(Test::kMagicNumber, p1->_value); TEST_ASSERT_EQUAL(Test::kMagicNumber, p1->_value);
TEST_ASSERT_EQUAL(1, Test::_instanceCount); TEST_ASSERT_EQUAL(1, Test::_instanceCount);
p1->_value = number1; p1->_value = number1;
TEST_ASSERT_EQUAL(number1, p1->_value); TEST_ASSERT_EQUAL(number1, p1->_value);
//create p2 // create p2
std::unique_ptr<Test> p2 = std::make_unique<Test>(); std::unique_ptr<Test> p2 = std::make_unique<Test>();
TEST_ASSERT_EQUAL(Test::kMagicNumber, p2->_value); TEST_ASSERT_EQUAL(Test::kMagicNumber, p2->_value);
TEST_ASSERT_EQUAL(2, Test::_instanceCount); TEST_ASSERT_EQUAL(2, Test::_instanceCount);
p2->_value = number2; p2->_value = number2;
TEST_ASSERT_EQUAL(number2, p2->_value); TEST_ASSERT_EQUAL(number2, p2->_value);
//swap // swap
p1.swap(p2); p1.swap(p2);
TEST_ASSERT_EQUAL(number1, p2->_value); TEST_ASSERT_EQUAL(number1, p2->_value);
@ -223,14 +226,13 @@ void test_unique_ptr_swap() {
TEST_ASSERT_EQUAL(0, Test::_instanceCount); TEST_ASSERT_EQUAL(0, Test::_instanceCount);
} }
/******************* /*******************
* RAW PTR EXERCISE * * RAW PTR EXERCISE *
*******************/ *******************/
/** /**
* Test that a shared pointer correctly manages the lifetime of the underlying raw pointer * Test that a shared pointer correctly manages the lifetime of the underlying
* raw pointer
*/ */
void test_single_raw_ptr_lifetime() { void test_single_raw_ptr_lifetime() {
// Sanity-check value of counter // Sanity-check value of counter
@ -242,7 +244,7 @@ void test_single_raw_ptr_lifetime() {
TEST_ASSERT_EQUAL(1, Test::_instanceCount); TEST_ASSERT_EQUAL(1, Test::_instanceCount);
TEST_ASSERT_EQUAL(Test::kMagicNumber, t1._value); TEST_ASSERT_EQUAL(Test::kMagicNumber, t1._value);
Test * p1 = &t1; Test* p1 = &t1;
TEST_ASSERT_EQUAL(1, Test::_instanceCount); TEST_ASSERT_EQUAL(1, Test::_instanceCount);
TEST_ASSERT_EQUAL(Test::kMagicNumber, p1->_value); TEST_ASSERT_EQUAL(Test::kMagicNumber, p1->_value);
@ -260,9 +262,9 @@ void test_single_raw_ptr_lifetime() {
TEST_ASSERT_EQUAL(0, Test::_instanceCount); TEST_ASSERT_EQUAL(0, Test::_instanceCount);
} }
static utest::v1::status_t greentea_setup(const size_t number_of_cases) { static status_t greentea_setup(const size_t number_of_cases) {
// Here, we specify the timeout (60s) and the host test (a built-in host test or the // Here, we specify the timeout (60s) and the host test (a built-in host test
// name of our Python file) // or the name of our Python file)
GREENTEA_SETUP(60, "default_auto"); GREENTEA_SETUP(60, "default_auto");
return greentea_test_setup_handler(number_of_cases); return greentea_test_setup_handler(number_of_cases);
} }
@ -285,4 +287,7 @@ static Case cases[] = {
static Specification specification(greentea_setup, cases); static Specification specification(greentea_setup, cases);
int main() { return !Harness::run(specification); } }; // namespace v1
}; // namespace utest
int main() { return !utest::v1::Harness::run(utest::v1::specification); }

6
common/constants.hpp
View File

@ -51,4 +51,10 @@ static constexpr std::chrono::milliseconds kMaxPedalRotationTime = 1500ms;
// definition of pedal rotation time change upon acceleration/deceleration // definition of pedal rotation time change upon acceleration/deceleration
static constexpr std::chrono::milliseconds kDeltaPedalRotationTime = 25ms; static constexpr std::chrono::milliseconds kDeltaPedalRotationTime = 25ms;
static constexpr uint32_t kNbrOfSteps = static_cast<uint32_t>(
(
bike_computer::kMaxPedalRotationTime - bike_computer::kMinPedalRotationTime
).count() / bike_computer::kDeltaPedalRotationTime.count()
);
} // namespace bike_computer } // namespace bike_computer

2
common/speedometer.cpp
View File

@ -110,7 +110,7 @@ void Speedometer::computeSpeed() {
// TODO : done // TODO : done
//Distance run with one pedal turn = tray size / rear gear size * circumference of the wheel //Distance run with one pedal turn = tray size / rear gear size * circumference of the wheel
constexpr float ms_in_hour = static_cast<float>(3600 * 1000); constexpr float ms_in_hour = static_cast<float>(3600 * 1000);
float pedal_rotation_per_hour = ms_in_hour / static_cast<float>(_pedalRotationTime.count()); float pedal_rotation_per_hour = ms_in_hour / std::chrono::duration_cast<std::chrono::milliseconds>(_pedalRotationTime).count();
float gear_ratio = static_cast<float>(kTraySize) / static_cast<float>(this->_gearSize); float gear_ratio = static_cast<float>(kTraySize) / static_cast<float>(this->_gearSize);
float wheel_dist_km = static_cast<float>(this->kWheelCircumference) / 1000.0; float wheel_dist_km = static_cast<float>(this->kWheelCircumference) / 1000.0;
this->_currentSpeed = gear_ratio * wheel_dist_km * pedal_rotation_per_hour; this->_currentSpeed = gear_ratio * wheel_dist_km * pedal_rotation_per_hour;

22
main.cpp
View File

@ -6,19 +6,25 @@
#if !MBED_TEST_MODE #if !MBED_TEST_MODE
#include "mbed.h" // NOLINT #include "mbed.h" // NOLINT
#include "mbed_trace.h"
// #include "static_scheduling/bike_system.hpp"
#include "static_scheduling_with_event/bike_system.hpp"
// Blinking rate in milliseconds #if defined(MBED_CONF_MBED_TRACE_ENABLE)
#define BLINKING_RATE 500ms #define TRACE_GROUP "MAIN"
#endif // MBED_CONF_MBED_TRACE_ENAB
int main() { int main() {
// Initialise the digital pin LED1 as an output #if defined(MBED_CONF_MBED_TRACE_ENABLE)
mbed_trace_init();
#endif
DigitalOut led(LED1); // static_scheduling::BikeSystem bikeSystem;
// bikeSystem.start();
// bikeSystem.startWithEventQueue();
while (true) { static_scheduling_with_event::BikeSystem bikeSystem;
led = !led; bikeSystem.start();
ThisThread::sleep_for(BLINKING_RATE);
}
} }
#endif // MBED_TEST_MODE #endif // MBED_TEST_MODE

1
mbed_app.json
View File

@ -14,6 +14,7 @@
"platform.stdio-baud-rate": 115200, "platform.stdio-baud-rate": 115200,
"platform.default-serial-baud-rate": 115200, "platform.default-serial-baud-rate": 115200,
"platform.stdio-buffered-serial": true, "platform.stdio-buffered-serial": true,
"platform.all-stats-enabled": true,
"target.printf_lib":"minimal-printf", "target.printf_lib":"minimal-printf",
"platform.minimal-printf-enable-floating-point": true, "platform.minimal-printf-enable-floating-point": true,
"platform.minimal-printf-set-floating-point-max-decimals": 2 "platform.minimal-printf-set-floating-point-max-decimals": 2

290
static_scheduling/bike_system.cpp Normal file
View File

@ -0,0 +1,290 @@
// Copyright 2022 Haute école d'ingénierie et d'architecture de Fribourg
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
/****************************************************************************
* @file bike_system.cpp
* @author Serge Ayer <serge.ayer@hefr.ch>
* @author Rémi Heredero <remi@heredero.ch>
* @author Yann Sierro <yannsierro.pro@gmail.com>
*
* @brief Bike System implementation (static scheduling)
*
* @date 2023-11-15
* @version 1.1.0
***************************************************************************/
#include "bike_system.hpp"
#include <chrono>
#include "mbed_trace.h"
#if MBED_CONF_MBED_TRACE_ENABLE
#define TRACE_GROUP "BikeSystem"
#endif // MBED_CONF_MBED_TRACE_ENABLE
namespace static_scheduling {
static constexpr std::chrono::milliseconds kGearTaskPeriod = 800ms;
static constexpr std::chrono::milliseconds kGearTaskDelay = 0ms;
static constexpr std::chrono::milliseconds kGearTaskComputationTime = 100ms;
static constexpr std::chrono::milliseconds kSpeedDistanceTaskPeriod = 400ms;
static constexpr std::chrono::milliseconds kSpeedDistanceTaskDelay = 0ms; // 0 or 100ms
static constexpr std::chrono::milliseconds kSpeedDistanceTaskComputationTime = 200ms;
static constexpr std::chrono::milliseconds kDisplayTask1Period = 1600ms;
static constexpr std::chrono::milliseconds kDisplayTask1Delay = 300ms;
static constexpr std::chrono::milliseconds kDisplayTask1ComputationTime = 200ms;
static constexpr std::chrono::milliseconds kResetTaskPeriod = 800ms;
static constexpr std::chrono::milliseconds kResetTaskDelay = 700ms;
static constexpr std::chrono::milliseconds kResetTaskComputationTime = 100ms;
static constexpr std::chrono::milliseconds kTemperatureTaskPeriod = 1600ms;
static constexpr std::chrono::milliseconds kTemperatureTaskDelay = 1100ms;
static constexpr std::chrono::milliseconds kTemperatureTaskComputationTime = 100ms;
static constexpr std::chrono::milliseconds kDisplayTask2Period = 1600ms;
static constexpr std::chrono::milliseconds kDisplayTask2Delay = 1200ms;
static constexpr std::chrono::milliseconds kDisplayTask2ComputationTime = 100ms;
static constexpr std::chrono::milliseconds kCPUTaskPeriod = 1600ms;
static constexpr std::chrono::milliseconds kCPUTaskDelay = 0ms;
static constexpr std::chrono::milliseconds kCPUTaskComputationTime = 0ms;
BikeSystem::BikeSystem()
: _gearDevice(_timer),
_pedalDevice(_timer),
_resetDevice(_timer),
_speedometer(_timer),
_cpuLogger(_timer) {}
void BikeSystem::start() {
tr_info("Starting Super-Loop without event handling");
init();
while (true) {
auto startTime = _timer.elapsed_time();
gearTask(); // 100ms : 0ms -> 100ms
speedDistanceTask(); // 200ms : 100ms -> 300ms
displayTask1(); // 200ms : 300ms -> 500ms
speedDistanceTask(); // 200ms : 500ms -> 700ms
resetTask(); // 100ms : 700ms -> 800ms
gearTask(); // 100ms : 800ms -> 900ms
speedDistanceTask(); // 200ms : 900ms -> 1100ms
temperatureTask(); // 100ms : 1100ms -> 1200ms
displayTask2(); // 100ms : 1200ms -> 1300ms
speedDistanceTask(); // 200ms : 1300ms -> 1500ms
resetTask(); // 100ms : 1500ms -> 1600ms
// register the time at the end of the cyclic schedule period and print the
// elapsed time for the period
std::chrono::microseconds endTime = _timer.elapsed_time();
const auto cycle =
std::chrono::duration_cast<std::chrono::milliseconds>(endTime - startTime);
tr_debug("Repeating cycle time is %" PRIu64 " milliseconds", cycle.count());
bool fStop = false;
core_util_atomic_load(&fStop);
if (fStop) {
break;
}
#if !defined(MBED_TEST_MODE)
_cpuLogger.printStats();
#endif
}
}
void BikeSystem::startWithEventQueue() {
tr_info("Starting Super-Loop with event handling");
init();
EventQueue eventQueue;
Event<void()> gearEvent(&eventQueue, callback(this, &BikeSystem::gearTask));
gearEvent.delay(kGearTaskDelay);
gearEvent.period(kGearTaskPeriod);
gearEvent.post();
Event<void()> speedDistanceEvent(&eventQueue,
callback(this, &BikeSystem::speedDistanceTask));
speedDistanceEvent.delay(kSpeedDistanceTaskDelay);
speedDistanceEvent.period(kSpeedDistanceTaskPeriod);
speedDistanceEvent.post();
Event<void()> display1Event(&eventQueue, callback(this, &BikeSystem::displayTask1));
display1Event.delay(kDisplayTask1Delay);
display1Event.period(kDisplayTask1Period);
display1Event.post();
Event<void()> resetEvent(&eventQueue, callback(this, &BikeSystem::resetTask));
resetEvent.delay(kResetTaskDelay);
resetEvent.period(kResetTaskPeriod);
resetEvent.post();
Event<void()> temperatureEvent(&eventQueue,
callback(this, &BikeSystem::temperatureTask));
temperatureEvent.delay(kTemperatureTaskDelay);
temperatureEvent.period(kTemperatureTaskPeriod);
temperatureEvent.post();
Event<void()> display2Event(&eventQueue, callback(this, &BikeSystem::displayTask2));
display2Event.delay(kDisplayTask2Delay);
display2Event.period(kDisplayTask2Period);
display2Event.post();
#if !defined(MBED_TEST_MODE)
Event<void()> cpuEvent(&eventQueue, callback(this, &BikeSystem::cpuTask));
cpuEvent.delay(kCPUTaskDelay);
cpuEvent.period(kCPUTaskPeriod);
cpuEvent.post();
#endif
eventQueue.dispatch_forever();
}
void BikeSystem::stop() { core_util_atomic_store_bool(&_stopFlag, true); }
#if defined(MBED_TEST_MODE)
const advembsof::TaskLogger& BikeSystem::getTaskLogger() { return _taskLogger; }
#endif // defined(MBED_TEST_MODE)
void BikeSystem::init() {
// start the timer
_timer.start();
// initialize the lcd display
disco::ReturnCode rc = _displayDevice.init();
if (rc != disco::ReturnCode::Ok) {
tr_error("Failed to initialized the lcd display: %d", static_cast<int>(rc));
}
// initialize the sensor device
bool present = _sensorDevice.init();
if (!present) {
tr_error("Sensor not present or initialization failed");
}
// enable/disable task logging
_taskLogger.enable(true);
}
void BikeSystem::gearTask() {
// gear task
auto taskStartTime = _timer.elapsed_time();
// no need to protect access to data members (single threaded)
_currentGear = _gearDevice.getCurrentGear();
_currentGearSize = _gearDevice.getCurrentGearSize();
_taskLogger.logPeriodAndExecutionTime(
_timer, advembsof::TaskLogger::kGearTaskIndex, taskStartTime);
}
void BikeSystem::speedDistanceTask() {
// speed and distance task
auto taskStartTime = _timer.elapsed_time();
const auto pedalRotationTime = _pedalDevice.getCurrentRotationTime();
_speedometer.setCurrentRotationTime(pedalRotationTime);
_speedometer.setGearSize(_currentGearSize);
// no need to protect access to data members (single threaded)
_currentSpeed = _speedometer.getCurrentSpeed();
_traveledDistance = _speedometer.getDistance();
_taskLogger.logPeriodAndExecutionTime(
_timer, advembsof::TaskLogger::kSpeedTaskIndex, taskStartTime);
}
void BikeSystem::temperatureTask() {
auto taskStartTime = _timer.elapsed_time();
tr_warn("Tick1 %" PRIu64, _timer.elapsed_time().count());
// no need to protect access to data members (single threaded)
_currentTemperature = _sensorDevice.readTemperature();
tr_warn("Tick2 %" PRIu64, _timer.elapsed_time().count());
ThisThread::sleep_for(std::chrono::duration_cast<std::chrono::milliseconds>(
kTemperatureTaskComputationTime - (_timer.elapsed_time() - taskStartTime)));
// simulate task computation by waiting for the required task computation time
// std::chrono::microseconds elapsedTime =
// std::chrono::microseconds::zero(); while (elapsedTime <
// kTemperatureTaskComputationTime) {
// elapsedTime = _timer.elapsed_time() - taskStartTime;
// }
_taskLogger.logPeriodAndExecutionTime(
_timer, advembsof::TaskLogger::kTemperatureTaskIndex, taskStartTime);
}
void BikeSystem::resetTask() {
auto taskStartTime = _timer.elapsed_time();
if (_resetDevice.checkReset()) {
std::chrono::microseconds responseTime =
_timer.elapsed_time() - _resetDevice.getPressTime();
tr_info("Reset task: response time is %" PRIu64 " usecs", responseTime.count());
_speedometer.reset();
}
_taskLogger.logPeriodAndExecutionTime(
_timer, advembsof::TaskLogger::kResetTaskIndex, taskStartTime);
}
void BikeSystem::displayTask1() {
auto taskStartTime = _timer.elapsed_time();
_displayDevice.displayGear(_currentGear);
_displayDevice.displaySpeed(_currentSpeed);
_displayDevice.displayDistance(_traveledDistance);
ThisThread::sleep_for(std::chrono::duration_cast<std::chrono::milliseconds>(
kDisplayTask1ComputationTime - (_timer.elapsed_time() - taskStartTime)));
// simulate task computation by waiting for the required task computation time
// std::chrono::microseconds elapsedTime =
// std::chrono::microseconds::zero(); while (elapsedTime <
// kDisplayTask1ComputationTime) {
// elapsedTime = _timer.elapsed_time() - taskStartTime;
// }
_taskLogger.logPeriodAndExecutionTime(
_timer, advembsof::TaskLogger::kDisplayTask1Index, taskStartTime);
}
void BikeSystem::displayTask2() {
auto taskStartTime = _timer.elapsed_time();
_displayDevice.displayTemperature(_currentTemperature);
ThisThread::sleep_for(std::chrono::duration_cast<std::chrono::milliseconds>(
kDisplayTask2ComputationTime - (_timer.elapsed_time() - taskStartTime)));
// simulate task computation by waiting for the required task computation time
// std::chrono::microseconds elapsedTime =
// std::chrono::microseconds::zero(); while (elapsedTime <
// kDisplayTask2ComputationTime) {
// elapsedTime = _timer.elapsed_time() - taskStartTime;
// }
_taskLogger.logPeriodAndExecutionTime(
_timer, advembsof::TaskLogger::kDisplayTask2Index, taskStartTime);
}
void BikeSystem::cpuTask() { _cpuLogger.printStats(); }
} // namespace static_scheduling

106
static_scheduling/bike_system.hpp Normal file
View File

@ -0,0 +1,106 @@
// Copyright 2022 Haute école d'ingénierie et d'architecture de Fribourg
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
/****************************************************************************
* @file bike_system.hpp
* @author Serge Ayer <serge.ayer@hefr.ch>
*
* @brief Bike System header file (static scheduling)
*
* @date 2023-08-20
* @version 1.0.0
***************************************************************************/
#pragma once
// from advembsof
#include "cpu_logger.hpp"
#include "display_device.hpp"
#include "task_logger.hpp"
// from common
#include "sensor_device.hpp"
#include "speedometer.hpp"
// local
#include "gear_device.hpp"
#include "pedal_device.hpp"
#include "reset_device.hpp"
namespace static_scheduling {
class BikeSystem {
public:
// constructor
BikeSystem();
// make the class non copyable
BikeSystem(BikeSystem&) = delete;
BikeSystem& operator=(BikeSystem&) = delete;
// method called in main() for starting the system
void start();
// method called in main() for starting the sysytem with the event queue
void startWithEventQueue();
// method called for stopping the system
void stop();
#if defined(MBED_TEST_MODE)
const advembsof::TaskLogger& getTaskLogger();
#endif // defined(MBED_TEST_MODE)
private:
// private methods
void init();
void gearTask();
void speedDistanceTask();
void temperatureTask();
void resetTask();
void displayTask1();
void displayTask2();
void cpuTask();
// stop flag, used for stopping the super-loop (set in stop())
bool _stopFlag = false;
// timer instance used for loggint task time and used by ResetDevice
Timer _timer;
// data member that represents the device for manipulating the gear
GearDevice _gearDevice;
uint8_t _currentGear = bike_computer::kMinGear;
uint8_t _currentGearSize = bike_computer::kMinGearSize;
// data member that represents the device for manipulating the pedal rotation
// speed/time
PedalDevice _pedalDevice;
float _currentSpeed = 0.0f;
float _traveledDistance = 0.0f;
// data member that represents the device used for resetting
ResetDevice _resetDevice;
// data member that represents the device display
advembsof::DisplayDevice _displayDevice;
// data member that represents the device for counting wheel rotations
bike_computer::Speedometer _speedometer;
// data member that represents the sensor device
bike_computer::SensorDevice _sensorDevice;
float _currentTemperature = 0.0f;
// used for logging task info
advembsof::TaskLogger _taskLogger;
// cpu logger to measure cpu usage
advembsof::CPULogger _cpuLogger;
};
} // namespace static_scheduling

60
static_scheduling/pedal_device.cpp
View File

@ -1,12 +1,25 @@
// Copyright 2022 Haute école d'ingénierie et d'architecture de Fribourg
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
/**************************************************************************** /****************************************************************************
* @file pedal_device.cpp * @file pedal_device.cpp
* @author Rémi Heredero <remi@heredero.ch> * @author Rémi Heredero <remi@heredero.ch>
* @author Yann Sierro <yannsierro.pro@gmail.com> * @author Yann Sierro <yannsierro.pro@gmail.com>
* *
* @brief Pedal Device implementation (static scheduling) * @brief Pedal Device implementation (static scheduling)
* @date 2024-11-09 * @date 2024-11-09
* @version 0.1.0 * @version 0.1.0
****************************************************************************/ ****************************************************************************/
#include "pedal_device.hpp" #include "pedal_device.hpp"
@ -22,20 +35,19 @@
namespace static_scheduling { namespace static_scheduling {
static constexpr std::chrono::microseconds kTaskRunTime = 200000us; static constexpr std::chrono::microseconds kTaskRunTime = 200000us;
PedalDevice::PedalDevice(Timer& timer) : _timer(timer) {} PedalDevice::PedalDevice(Timer& timer) : _timer(timer) {}
std::chrono::milliseconds PedalDevice::getCurrentRotationTime() {
std::chrono::milliseconds PedalDevice::getCurrentRotationTime() {
// TODO
std::chrono::microseconds initialTime = _timer.elapsed_time(); std::chrono::microseconds initialTime = _timer.elapsed_time();
std::chrono::microseconds elapsedTime = std::chrono::microseconds::zero(); std::chrono::microseconds elapsedTime = std::chrono::microseconds::zero();
// we bound the change to one increment/decrement per call // we bound the change to one increment/decrement per call
bool hasChanged = false; bool hasChanged = false;
while (elapsedTime < kTaskRunTime) { while (elapsedTime < kTaskRunTime) {
if (!hasChanged) { if (!hasChanged) {
disco::Joystick::State joystickState = disco::Joystick::getInstance().getState(); disco::Joystick::State joystickState =
disco::Joystick::getInstance().getState();
switch (joystickState) { switch (joystickState) {
case disco::Joystick::State::LeftPressed: case disco::Joystick::State::LeftPressed:
@ -59,14 +71,14 @@ namespace static_scheduling {
elapsedTime = _timer.elapsed_time() - initialTime; elapsedTime = _timer.elapsed_time() - initialTime;
} }
return _pedalRotationTime; return _pedalRotationTime;
}
void PedalDevice::increaseRotationSpeed() {
_pedalRotationTime -= bike_computer::kDeltaPedalRotationTime;
}
void PedalDevice::decreaseRotationSpeed() {
_pedalRotationTime += bike_computer::kDeltaPedalRotationTime;
}
} }
void PedalDevice::increaseRotationSpeed() {
_pedalRotationTime -= bike_computer::kDeltaPedalRotationTime;
}
void PedalDevice::decreaseRotationSpeed() {
_pedalRotationTime += bike_computer::kDeltaPedalRotationTime;
}
} // namespace static_scheduling

62
static_scheduling/reset_device.cpp
View File

@ -1,12 +1,26 @@
// Copyright 2022 Haute école d'ingénierie et d'architecture de Fribourg
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
/**************************************************************************** /****************************************************************************
* @file reset_device.cpp * @file reset_device.cpp
* @author Rémi Heredero <remi@heredero.ch> * @author Rémi Heredero <remi@heredero.ch>
* @author Yann Sierro <yannsierro.pro@gmail.com> * @author Yann Sierro <yannsierro.pro@gmail.com>
* *
* @brief Reset Device implementation (static scheduling) * @brief Reset Device implementation (static scheduling)
* @date 2024-11-12 * @date 2024-11-12
* @version 0.1.0 * @version 0.1.0
****************************************************************************/ ****************************************************************************/
#include "reset_device.hpp" #include "reset_device.hpp"
@ -21,43 +35,35 @@
static constexpr uint8_t kPolarityPressed = 1; static constexpr uint8_t kPolarityPressed = 1;
#endif #endif
#if MBED_CONF_MBED_TRACE_ENABLE #if MBED_CONF_MBED_TRACE_ENABLE
#define TRACE_GROUP "PedalDevice" #define TRACE_GROUP "ResetDevice"
#endif // MBED_CONF_MBED_TRACE_ENABLE #endif // MBED_CONF_MBED_TRACE_ENABLE
namespace static_scheduling { namespace static_scheduling {
static constexpr std::chrono::microseconds kTaskRunTime = 1000000us; static constexpr std::chrono::microseconds kTaskRunTime = 100000us;
ResetDevice::ResetDevice(Timer& timer) : _timer(timer), _resetButton(PUSH_BUTTON) { ResetDevice::ResetDevice(Timer& timer) : _timer(timer), _resetButton(PUSH_BUTTON) {
_resetButton.rise(callback(this, &ResetDevice::onRise)); _resetButton.rise(callback(this, &ResetDevice::onRise));
} }
bool ResetDevice::checkReset() { bool ResetDevice::checkReset() {
std::chrono::microseconds initialTime = _timer.elapsed_time(); std::chrono::microseconds initialTime = _timer.elapsed_time();
std::chrono::microseconds elapsedTime = std::chrono::microseconds::zero(); std::chrono::microseconds elapsedTime = std::chrono::microseconds::zero();
// we bound the change to one increment/decrement per call // we bound the change to one increment/decrement per call
bool isPressed = false; bool isPressed = false;
while (elapsedTime < kTaskRunTime) { while (elapsedTime < kTaskRunTime) {
if(!isPressed) { if (!isPressed) {
isPressed = _resetButton.read() == kPolarityPressed; isPressed = _resetButton.read() == kPolarityPressed;
} }
elapsedTime = _timer.elapsed_time() - initialTime; elapsedTime = _timer.elapsed_time() - initialTime;
} }
return isPressed; return isPressed;
}
std::chrono::microseconds ResetDevice::getPressTime() {
return _pressTime;
}
void ResetDevice::onRise() {
_pressTime = _timer.elapsed_time();
}
} }
std::chrono::microseconds ResetDevice::getPressTime() { return _pressTime; }
void ResetDevice::onRise() { _pressTime = _timer.elapsed_time(); }
} // namespace static_scheduling

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// Copyright 2022 Haute école d'ingénierie et d'architecture de Fribourg
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
/****************************************************************************
* @file bike_system.cpp
* @author Serge Ayer <serge.ayer@hefr.ch>
* @author Rémi Heredero <remi@heredero.ch>
* @author Yann Sierro <yannsierro.pro@gmail.com>
*
* @brief Bike System implementation (static scheduling)
*
* @date 2023-11-15
* @version 1.1.0
***************************************************************************/
#include "bike_system.hpp"
#include <chrono>
#include "mbed_trace.h"
#if MBED_CONF_MBED_TRACE_ENABLE
#define TRACE_GROUP "BikeSystem"
#endif // MBED_CONF_MBED_TRACE_ENABLE
namespace static_scheduling_with_event {
static constexpr std::chrono::milliseconds kGearTaskPeriod = 800ms;
static constexpr std::chrono::milliseconds kGearTaskDelay = 0ms;
static constexpr std::chrono::milliseconds kGearTaskComputationTime = 100ms;
static constexpr std::chrono::milliseconds kSpeedDistanceTaskPeriod = 400ms;
static constexpr std::chrono::milliseconds kSpeedDistanceTaskDelay = 100ms;
static constexpr std::chrono::milliseconds kSpeedDistanceTaskComputationTime = 200ms;
static constexpr std::chrono::milliseconds kDisplayTask1Period = 1600ms;
static constexpr std::chrono::milliseconds kDisplayTask1Delay = 300ms;
static constexpr std::chrono::milliseconds kDisplayTask1ComputationTime = 200ms;
static constexpr std::chrono::milliseconds kResetTaskPeriod = 800ms;
static constexpr std::chrono::milliseconds kResetTaskDelay = 700ms;
static constexpr std::chrono::milliseconds kResetTaskComputationTime = 100ms;
static constexpr std::chrono::milliseconds kTemperatureTaskPeriod = 1600ms;
static constexpr std::chrono::milliseconds kTemperatureTaskDelay = 1100ms;
static constexpr std::chrono::milliseconds kTemperatureTaskComputationTime = 100ms;
static constexpr std::chrono::milliseconds kDisplayTask2Period = 1600ms;
static constexpr std::chrono::milliseconds kDisplayTask2Delay = 1200ms;
static constexpr std::chrono::milliseconds kDisplayTask2ComputationTime = 100ms;
static constexpr std::chrono::milliseconds kCPUTaskPeriod = 1600ms;
static constexpr std::chrono::milliseconds kCPUTaskDelay = 1200ms;
static constexpr std::chrono::milliseconds kCPUTaskComputationTime = 100ms;
BikeSystem::BikeSystem()
: _gearDevice(),
_pedalDevice(),
_resetDevice(callback(this, &BikeSystem::onReset)),
_speedometer(_timer),
_cpuLogger(_timer) {}
void BikeSystem::start() {
tr_info("Starting Super-Loop with event handling");
init();
EventQueue eventQueue;
Event<void()> gearEvent(&eventQueue, callback(this, &BikeSystem::gearTask));
gearEvent.delay(kGearTaskDelay);
gearEvent.period(kGearTaskPeriod);
gearEvent.post();
Event<void()> speedDistanceEvent(&eventQueue,
callback(this, &BikeSystem::speedDistanceTask));
speedDistanceEvent.delay(kSpeedDistanceTaskDelay);
speedDistanceEvent.period(kSpeedDistanceTaskPeriod);
speedDistanceEvent.post();
Event<void()> display1Event(&eventQueue, callback(this, &BikeSystem::displayTask1));
display1Event.delay(kDisplayTask1Delay);
display1Event.period(kDisplayTask1Period);
display1Event.post();
Event<void()> resetEvent(&eventQueue, callback(this, &BikeSystem::resetTask));
resetEvent.delay(kResetTaskDelay);
resetEvent.period(kResetTaskPeriod);
resetEvent.post();
Event<void()> temperatureEvent(&eventQueue,
callback(this, &BikeSystem::temperatureTask));
temperatureEvent.delay(kTemperatureTaskDelay);
temperatureEvent.period(kTemperatureTaskPeriod);
temperatureEvent.post();
Event<void()> display2Event(&eventQueue, callback(this, &BikeSystem::displayTask2));
display2Event.delay(kDisplayTask2Delay);
display2Event.period(kDisplayTask2Period);
display2Event.post();
#if !defined(MBED_TEST_MODE)
Event<void()> cpuEvent(&eventQueue, callback(this, &BikeSystem::cpuTask));
cpuEvent.delay(kCPUTaskDelay);
cpuEvent.period(kCPUTaskPeriod);
cpuEvent.post();
#endif
eventQueue.dispatch_forever();
}
void BikeSystem::onReset() {
_resetTime = _timer.elapsed_time();
core_util_atomic_store_bool(&_resetFlag, true);
}
void BikeSystem::stop() { core_util_atomic_store_bool(&_stopFlag, true); }
#if defined(MBED_TEST_MODE)
const advembsof::TaskLogger& BikeSystem::getTaskLogger() { return _taskLogger; }
#endif // defined(MBED_TEST_MODE)
void BikeSystem::init() {
// start the timer
_timer.start();
// initialize the lcd display
disco::ReturnCode rc = _displayDevice.init();
if (rc != disco::ReturnCode::Ok) {
tr_error("Failed to initialized the lcd display: %d", static_cast<int>(rc));
}
// initialize the sensor device
bool present = _sensorDevice.init();
if (!present) {
tr_error("Sensor not present or initialization failed");
}
// enable/disable task logging
_taskLogger.enable(true);
}
void BikeSystem::gearTask() {
// gear task
auto taskStartTime = _timer.elapsed_time();
// no need to protect access to data members (single threaded)
_currentGear = _gearDevice.getCurrentGear();
_currentGearSize = _gearDevice.getCurrentGearSize();
_taskLogger.logPeriodAndExecutionTime(
_timer, advembsof::TaskLogger::kGearTaskIndex, taskStartTime);
}
void BikeSystem::speedDistanceTask() {
auto taskStartTime = _timer.elapsed_time();
const auto pedalRotationTime = _pedalDevice.getCurrentRotationTime();
_speedometer.setCurrentRotationTime(pedalRotationTime);
_speedometer.setGearSize(_currentGearSize);
_currentSpeed = _speedometer.getCurrentSpeed();
_traveledDistance = _speedometer.getDistance();
_taskLogger.logPeriodAndExecutionTime(
_timer, advembsof::TaskLogger::kSpeedTaskIndex, taskStartTime);
}
void BikeSystem::temperatureTask() {
auto taskStartTime = _timer.elapsed_time();
// tr_warn("Tick1 %" PRIu64, _timer.elapsed_time().count());
// no need to protect access to data members (single threaded)
_currentTemperature = _sensorDevice.readTemperature();
// tr_warn("Tick2 %" PRIu64, _timer.elapsed_time().count());
ThisThread::sleep_for(std::chrono::duration_cast<std::chrono::milliseconds>(
kTemperatureTaskComputationTime - (_timer.elapsed_time() - taskStartTime)));
_taskLogger.logPeriodAndExecutionTime(
_timer, advembsof::TaskLogger::kTemperatureTaskIndex, taskStartTime);
}
void BikeSystem::resetTask() {
auto taskStartTime = _timer.elapsed_time();
if (core_util_atomic_load_bool(&_resetFlag)) {
std::chrono::microseconds responseTime = _timer.elapsed_time() - _resetTime;
tr_info("Reset task: response time is %" PRIu64 " usecs", responseTime.count());
_speedometer.reset();
core_util_atomic_store_bool(&_resetFlag, false);
}
_taskLogger.logPeriodAndExecutionTime(
_timer, advembsof::TaskLogger::kResetTaskIndex, taskStartTime);
}
void BikeSystem::displayTask1() {
auto taskStartTime = _timer.elapsed_time();
_displayDevice.displayGear(_currentGear);
_displayDevice.displaySpeed(_currentSpeed);
_displayDevice.displayDistance(_traveledDistance);
ThisThread::sleep_for(std::chrono::duration_cast<std::chrono::milliseconds>(
kDisplayTask1ComputationTime - (_timer.elapsed_time() - taskStartTime)));
_taskLogger.logPeriodAndExecutionTime(
_timer, advembsof::TaskLogger::kDisplayTask1Index, taskStartTime);
}
void BikeSystem::displayTask2() {
auto taskStartTime = _timer.elapsed_time();
_displayDevice.displayTemperature(_currentTemperature);
ThisThread::sleep_for(std::chrono::duration_cast<std::chrono::milliseconds>(
kDisplayTask2ComputationTime - (_timer.elapsed_time() - taskStartTime)));
_taskLogger.logPeriodAndExecutionTime(
_timer, advembsof::TaskLogger::kDisplayTask2Index, taskStartTime);
}
void BikeSystem::cpuTask() { _cpuLogger.printStats(); }
} // namespace static_scheduling_with_event

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// Copyright 2022 Haute école d'ingénierie et d'architecture de Fribourg
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
/****************************************************************************
* @file bike_system.hpp
* @author Serge Ayer <serge.ayer@hefr.ch>
*
* @brief Bike System header file (static scheduling)
*
* @date 2023-08-20
* @version 1.0.0
***************************************************************************/
#pragma once
// from advembsof
#include "cpu_logger.hpp"
#include "display_device.hpp"
#include "task_logger.hpp"
// from common
#include "sensor_device.hpp"
#include "speedometer.hpp"
// local
#include "gear_device.hpp"
#include "pedal_device.hpp"
#include "reset_device.hpp"
namespace static_scheduling_with_event {
class BikeSystem {
public:
// constructor
BikeSystem();
// make the class non copyable
BikeSystem(BikeSystem&) = delete;
BikeSystem& operator=(BikeSystem&) = delete;
// method called in main() for starting the system
void start();
// method called in main() for starting the sysytem with the event queue
void startWithEventQueue();
// method called for stopping the system
void stop();
#if defined(MBED_TEST_MODE)
const advembsof::TaskLogger& getTaskLogger();
#endif // defined(MBED_TEST_MODE)
private:
// private methods
void init();
void onReset();
void gearTask();
void speedDistanceTask();
void temperatureTask();
void resetTask();
void displayTask1();
void displayTask2();
void cpuTask();
// stop flag, used for stopping the super-loop (set in stop())
bool _stopFlag = false;
std::chrono::microseconds _resetTime = std::chrono::microseconds::zero();
volatile bool _resetFlag = false;
// timer instance used for loggint task time and used by ResetDevice
Timer _timer;
// data member that represents the device for manipulating the gear
GearDevice _gearDevice;
uint8_t _currentGear = bike_computer::kMinGear;
uint8_t _currentGearSize = bike_computer::kMinGearSize;
// data member that represents the device for manipulating the pedal rotation
// speed/time
PedalDevice _pedalDevice;
float _currentSpeed = 0.0f;
float _traveledDistance = 0.0f;
// data member that represents the device used for resetting
ResetDevice _resetDevice;
// data member that represents the device display
advembsof::DisplayDevice _displayDevice;
// data member that represents the device for counting wheel rotations
bike_computer::Speedometer _speedometer;
// data member that represents the sensor device
bike_computer::SensorDevice _sensorDevice;
float _currentTemperature = 0.0f;
// used for logging task info
advembsof::TaskLogger _taskLogger;
// cpu logger to measure cpu usage
advembsof::CPULogger _cpuLogger;
};
} // namespace static_scheduling_with_event

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// Copyright 2022 Haute école d'ingénierie et d'architecture de Fribourg
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
/****************************************************************************
* @file gear_device.cpp
* @author Serge Ayer <serge.ayer@hefr.ch>
* @author Rémi Heredero <remi@heredero.ch>
* @author Yann Sierro <yannsierro.pro@gmail.com>
*
* @brief Gear Device implementation (static scheduling)
*
* @date 2023-11-17
* @version 1.1.0
***************************************************************************/
#include "gear_device.hpp"
// from disco_h747i/wrappers
#include <chrono>
#include "joystick.hpp"
#include "mbed_trace.h"
#if MBED_CONF_MBED_TRACE_ENABLE
#define TRACE_GROUP "GearDevice"
#endif // MBED_CONF_MBED_TRACE_ENABLE
namespace static_scheduling_with_event {
GearDevice::GearDevice() {
disco::Joystick::getInstance().setUpCallback(callback(this, &GearDevice::onUp));
disco::Joystick::getInstance().setDownCallback(callback(this, &GearDevice::onDown));
}
uint8_t GearDevice::getCurrentGear() { return core_util_atomic_load_u8(&_currentGear); }
uint8_t GearDevice::getCurrentGearSize() const {
return bike_computer::kMaxGearSize - core_util_atomic_load_u8(&_currentGear);
}
void GearDevice::onUp() {
if (_currentGear < bike_computer::kMaxGear) {
core_util_atomic_incr_u8(&_currentGear, 1);
}
}
void GearDevice::onDown() {
if (_currentGear > bike_computer::kMinGear) {
core_util_atomic_decr_u8(&_currentGear, 1);
}
}
} // namespace static_scheduling_with_event

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// Copyright 2022 Haute école d'ingénierie et d'architecture de Fribourg
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
/****************************************************************************
* @file gear_device.hpp
* @author Serge Ayer <serge.ayer@hefr.ch>
* @author Rémi Heredero <remi@heredero.ch>
* @author Yann Sierro <yannsierro.pro@gmail.com>
*
* @brief Gear Device header file (static scheduling)
*
* @date 2023-11-17
* @version 1.1.0
***************************************************************************/
#pragma once
#include "constants.hpp"
#include "mbed.h"
namespace static_scheduling_with_event {
class GearDevice {
public:
GearDevice(); // NOLINT(runtime/references)
// make the class non copyable
GearDevice(GearDevice&) = delete;
GearDevice& operator=(GearDevice&) = delete;
// method called for updating the bike system
uint8_t getCurrentGear();
uint8_t getCurrentGearSize() const;
void onUp();
void onDown();
private:
// data members
volatile uint8_t _currentGear = bike_computer::kMinGear;
};
} // namespace static_scheduling_with_event

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// Copyright 2022 Haute école d'ingénierie et d'architecture de Fribourg
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
/****************************************************************************
* @file pedal_device.cpp
* @author Rémi Heredero <remi@heredero.ch>
* @author Yann Sierro <yannsierro.pro@gmail.com>
*
* @brief Pedal Device implementation (static scheduling)
* @date 2024-11-17
* @version 1.1.0
****************************************************************************/
#include "pedal_device.hpp"
// from disco_h747i/wrappers
#include <chrono>
#include "joystick.hpp"
#include "mbed_trace.h"
#if MBED_CONF_MBED_TRACE_ENABLE
#define TRACE_GROUP "PedalDevice"
#endif // MBED_CONF_MBED_TRACE_ENABLE
namespace static_scheduling_with_event {
PedalDevice::PedalDevice() {
disco::Joystick::getInstance().setLeftCallback(callback(this, &PedalDevice::onLeft));
disco::Joystick::getInstance().setRightCallback(
callback(this, &PedalDevice::onRight));
}
std::chrono::milliseconds PedalDevice::getCurrentRotationTime() {
uint32_t currentStep = core_util_atomic_load_u32(&_currentStep);
return bike_computer::kMinPedalRotationTime +
currentStep * bike_computer::kDeltaPedalRotationTime;
}
void PedalDevice::increaseRotationSpeed() {
uint32_t currentStep = core_util_atomic_load_u32(&_currentStep);
if (currentStep > 0) {
core_util_atomic_decr_u32(&_currentStep, 1);
}
}
void PedalDevice::decreaseRotationSpeed() {
uint32_t currentStep = core_util_atomic_load_u32(&_currentStep);
if (currentStep < bike_computer::kNbrOfSteps) {
core_util_atomic_incr_u32(&_currentStep, 1);
}
}
void PedalDevice::onLeft() { decreaseRotationSpeed(); }
void PedalDevice::onRight() { increaseRotationSpeed(); }
} // namespace static_scheduling_with_event

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// Copyright 2022 Haute école d'ingénierie et d'architecture de Fribourg
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
/****************************************************************************
* @file pedal_device.hpp
* @author Serge Ayer <serge.ayer@hefr.ch>
* @author Rémi Heredero <remi@heredero.ch>
* @author Yann Sierro <yannsierro.pro@gmail.com>
*
* @brief Pedal System header file (static scheduling)
*
* @date 2023-11-17
* @version 1.1.0
***************************************************************************/
#pragma once
#include "constants.hpp"
#include "mbed.h"
namespace static_scheduling_with_event {
class PedalDevice {
public:
PedalDevice(); // NOLINT(runtime/references)
// make the class non copyable
PedalDevice(PedalDevice&) = delete;
PedalDevice& operator=(PedalDevice&) = delete;
// method called for updating the bike system
std::chrono::milliseconds getCurrentRotationTime();
private:
// private methods
void onLeft();
void onRight();
void increaseRotationSpeed();
void decreaseRotationSpeed();
// data members
volatile uint32_t _currentStep = static_cast<uint32_t>(
(bike_computer::kInitialPedalRotationTime - bike_computer::kMinPedalRotationTime)
.count() /
bike_computer::kDeltaPedalRotationTime.count());
};
} // namespace static_scheduling_with_event

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// Copyright 2022 Haute école d'ingénierie et d'architecture de Fribourg
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
/****************************************************************************
* @file reset_device.cpp
* @author Rémi Heredero <remi@heredero.ch>
* @author Yann Sierro <yannsierro.pro@gmail.com>
*
* @brief Reset Device implementation (static scheduling with event)
* @date 2024-11-17
* @version 1.1.0
****************************************************************************/
#include "reset_device.hpp"
// from disco_h747i/wrappers
#include <chrono>
#include "joystick.hpp"
#include "mbed_trace.h"
#if defined(TARGET_DISCO_H747I)
#define PUSH_BUTTON BUTTON1
static constexpr uint8_t kPolarityPressed = 1;
#endif
#if MBED_CONF_MBED_TRACE_ENABLE
#define TRACE_GROUP "ResetDevice"
#endif // MBED_CONF_MBED_TRACE_ENABLE
namespace static_scheduling_with_event {
ResetDevice::ResetDevice(Callback<void()> cb) : _resetButton(PUSH_BUTTON) {
_resetButton.fall(cb);
}
} // namespace static_scheduling_with_event

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// Copyright 2022 Haute école d'ingénierie et d'architecture de Fribourg
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
/****************************************************************************
* @file reset_device.hpp
* @author Serge Ayer <serge.ayer@hefr.ch>
* @author Rémi Heredero <remi@heredero.ch>
* @author Yann Sierro <yannsierro.pro@gmail.com>
*
* @brief ResetDevice header file (static scheduling with event)
*
* @date 2023-11-17
* @version 1.1.0
***************************************************************************/
#pragma once
#include "mbed.h"
namespace static_scheduling_with_event {
class ResetDevice {
public:
explicit ResetDevice(Callback<void()> cb); // NOLINT(runtime/references)
// make the class non copyable
ResetDevice(ResetDevice&) = delete;
ResetDevice& operator=(ResetDevice&) = delete;
private:
// data members
// instance representing the reset button
InterruptIn _resetButton;
};
} // namespace static_scheduling_with_event