Merge pull request #106 from GHOSCHT/dev-moderncpp-control

Dev moderncpp control
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GHOSCHT 2023-12-22 15:50:53 +00:00 committed by GitHub
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46 changed files with 1341 additions and 563 deletions

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This directory is intended for project header files.
A header file is a file containing C declarations and macro definitions
to be shared between several project source files. You request the use of a
header file in your project source file (C, C++, etc) located in `src` folder
by including it, with the C preprocessing directive `#include'.
```src/main.c
#include "header.h"
int main (void)
{
...
}
```
Including a header file produces the same results as copying the header file
into each source file that needs it. Such copying would be time-consuming
and error-prone. With a header file, the related declarations appear
in only one place. If they need to be changed, they can be changed in one
place, and programs that include the header file will automatically use the
new version when next recompiled. The header file eliminates the labor of
finding and changing all the copies as well as the risk that a failure to
find one copy will result in inconsistencies within a program.
In C, the usual convention is to give header files names that end with `.h'.
It is most portable to use only letters, digits, dashes, and underscores in
header file names, and at most one dot.
Read more about using header files in official GCC documentation:
* Include Syntax
* Include Operation
* Once-Only Headers
* Computed Includes
https://gcc.gnu.org/onlinedocs/cpp/Header-Files.html

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#include <BluetoothCommunicator.h>
#include <BluetoothSerial.h>
BluetoothCommunicator::BluetoothCommunicator(BluetoothSerial &p_out, int timeout, __SIZE_TYPE__ bufferSize) : StreamCommunicator(p_out, bufferSize)
{
p_out.begin("Heliox");
p_out.setTimeout(timeout);
}

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#include <StreamCommunicator.h>
#include "BluetoothSerial.h"
class BluetoothCommunicator : public StreamCommunicator
{
public:
BluetoothCommunicator(BluetoothSerial &p_out, int timeout, __SIZE_TYPE__ bufferSize);
};

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#include <Communicator.h>
#include <cstring>
#include <WString.h>
Communicator::Communicator(__SIZE_TYPE__ bufferSize){
this->messageBuffer = new char[bufferSize];
this->bufferSize = bufferSize;
}
void Communicator::sendMessage(int *values, __SIZE_TYPE__ numberOfValues)
{
}
void Communicator::sendMessage(const char message[])
{
}
char *Communicator::receiveMessage()
{
}
__SIZE_TYPE__ Communicator::calculateMessageOutSize(__SIZE_TYPE__ numberOfValues)
{
return numberOfValues + (numberOfValues - 1) + 1;
}
void Communicator::parseIDs(const int values[], __SIZE_TYPE__ numberOfValues, char *output)
{
String out = "";
__SIZE_TYPE__ outputSize = calculateMessageOutSize(numberOfValues);
__SIZE_TYPE__ outputCharPointer = 0;
for (__SIZE_TYPE__ i = 0; i < numberOfValues; i++)
{
out += values[i];
outputCharPointer++;
if (outputCharPointer < outputSize - 1)
{
out += ',';
outputCharPointer++;
}
}
strcpy(output, out.c_str());
}
char *Communicator::getBuffer()
{
return messageBuffer;
}
void Communicator::clearBuffer()
{
memset(getBuffer(), '\0', getBufferSize());
}
int Communicator::getBufferSize()
{
return this->bufferSize;
}

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#ifndef _COMMUNICATOR_INCLUDED_
#define _COMMUNICATOR_INCLUDED_
class Communicator
{
protected:
char *messageBuffer;
__SIZE_TYPE__ bufferSize;
__SIZE_TYPE__ calculateMessageOutSize(__SIZE_TYPE__ numberOfValues);
void parseIDs(const int values[], __SIZE_TYPE__ numberOfValues, char *out);
public:
Communicator(__SIZE_TYPE__ bufferSize);
virtual void sendMessage(int *values, __SIZE_TYPE__ numberOfValues);
virtual void sendMessage(const char message[]);
virtual char *receiveMessage();
char *getBuffer();
void clearBuffer();
int getBufferSize();
};
#endif

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#include <I2CCommunicator.h>
#include <Wire.h>
I2CCommunicator::I2CCommunicator(TwoWire &w_out, int slaveAddr, int timeout, __SIZE_TYPE__ bufferSize) : StreamCommunicator(w_out, bufferSize)
{
w_out.begin(slaveAddr);
w_out.setTimeout(timeout);
}

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#include <StreamCommunicator.h>
#include <Wire.h>
class I2CCommunicator : public StreamCommunicator
{
public:
I2CCommunicator(TwoWire &w_out, int slaveAddr, int timeout, __SIZE_TYPE__ bufferSize);
};

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#include <LightController.h>
#include <string.h>
#include <Arduino.h>
#include <EEPROM.h>
#include <analogWrite.h>
LightController::LightController(const int bjtPins[], __SIZE_TYPE__ bjtCount)
{
this->bjtCount = bjtCount;
this->bjtPins = bjtPins;
this->bjtState = new int[bjtCount];
EEPROM.begin(64);
initializePins();
initializeState();
}
void LightController::initializeState()
{
initializeStateDefaultValues();
restoreState();
}
void LightController::initializePins()
{
for (__SIZE_TYPE__ i = 0; i < bjtCount; i++)
{
pinMode(bjtPins[i], OUTPUT);
}
}
void LightController::initializeStateDefaultValues()
{
for (__SIZE_TYPE__ i = 0; i < bjtCount; i++)
{
bjtState[i] = 20;
}
}
void LightController::restoreState()
{
for (__SIZE_TYPE__ i = 0; i < bjtCount; i++)
{
bjtState[i] = EEPROM.readInt(i * sizeof(bjtState[i]));
commitPinState(i);
}
}
void LightController::updateState(const char data[], int steps)
{
for (__SIZE_TYPE__ i = 0; i < bjtCount; i++)
{
parseRelativeState(data, i, steps);
setAbsoluteState(data, i);
commitState(i);
}
}
void LightController::parseRelativeState(const char data[], int index, int steps)
{
char numChar[2];
itoa(index, numChar, 10);
if (data[0] == numChar[0])
{
if (data[1] == 't')
{
if (bjtState[index] != 0)
{
bjtState[index] = 0;
}
else
{
bjtState[index] = 255;
}
}
else if (data[1] == 'i')
{
bjtState[index] = clampState(bjtState[index] + steps);
}
else if (data[1] == 'd')
{
bjtState[index] = clampState(bjtState[index] - steps);
}
}
}
void LightController::setAbsoluteState(const char data[], int index)
{
if (strcmp(data, "off") == 0)
{
bjtState[index] = 0;
}
if (strcmp(data, "on") == 0)
{
bjtState[index] = 255;
}
}
int LightController::clampState(int stateValue)
{
int clampedState = stateValue;
if (stateValue > 255)
{
clampedState = 255;
}
else if (stateValue < 0)
{
clampedState = 0;
}
return clampedState;
}
void LightController::commitState(int index)
{
commitPinState(index);
EEPROM.writeInt(index * sizeof(bjtState[index]), bjtState[index]);
EEPROM.commit();
}
void LightController::commitPinState(int index)
{
analogWrite(bjtPins[index], bjtState[index]);
}
int LightController::getBjtCount()
{
return bjtCount;
}
const int *LightController::getBjtPins()
{
return bjtPins;
}
int *LightController::getBjtState()
{
return bjtState;
}

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class LightController
{
protected:
__SIZE_TYPE__ bjtCount;
const int *bjtPins;
int *bjtState;
private:
void setAbsoluteState(const char data[], int index);
void parseRelativeState(const char data[], int index, int steps);
int clampState(int stateValue);
void commitState(int index);
void commitPinState(int index);
void initializeStateDefaultValues();
void restoreState();
void initializeState();
void initializePins();
public:
LightController(const int bjtPins[], __SIZE_TYPE__ bjtCount);
void updateState(const char data[], int steps);
int getBjtCount();
const int *getBjtPins();
int *getBjtState();
};

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This directory is intended for project specific (private) libraries.
PlatformIO will compile them to static libraries and link into executable file.
The source code of each library should be placed in a an own separate directory
("lib/your_library_name/[here are source files]").
For example, see a structure of the following two libraries `Foo` and `Bar`:
|--lib
| |
| |--Bar
| | |--docs
| | |--examples
| | |--src
| | |- Bar.c
| | |- Bar.h
| | |- library.json (optional, custom build options, etc) https://docs.platformio.org/page/librarymanager/config.html
| |
| |--Foo
| | |- Foo.c
| | |- Foo.h
| |
| |- README --> THIS FILE
|
|- platformio.ini
|--src
|- main.c
and a contents of `src/main.c`:
```
#include <Foo.h>
#include <Bar.h>
int main (void)
{
...
}
```
PlatformIO Library Dependency Finder will find automatically dependent
libraries scanning project source files.
More information about PlatformIO Library Dependency Finder
- https://docs.platformio.org/page/librarymanager/ldf.html

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#include <SerialCommunicator.h>
#include <HardwareSerial.h>
SerialCommunicator::SerialCommunicator(HardwareSerial &p_out, int baudRate, int timeout, __SIZE_TYPE__ bufferSize) : StreamCommunicator(p_out, bufferSize)
{
p_out.begin(baudRate);
p_out.setTimeout(timeout);
}

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#include <StreamCommunicator.h>
#include <HardwareSerial.h>
class SerialCommunicator : public StreamCommunicator
{
public:
SerialCommunicator(HardwareSerial &p_out, int baudRate, int timeout, __SIZE_TYPE__ bufferSize);
};

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#include <StreamCommunicator.h>
StreamCommunicator::StreamCommunicator(Stream &s_out, __SIZE_TYPE__ bufferSize) : Communicator(bufferSize), stream(s_out)
{
}
void StreamCommunicator::sendMessage(int *values, __SIZE_TYPE__ numberOfValues)
{
char message[calculateMessageOutSize(numberOfValues)];
parseIDs(values, numberOfValues, message);
sendMessage(message);
}
void StreamCommunicator::sendMessage(const char message[])
{
stream.println(message);
}
char *StreamCommunicator::receiveMessage()
{
if (stream.available())
{
clearBuffer();
stream.readBytesUntil('\n', getBuffer(), getBufferSize());
}
return getBuffer();
}

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#include "Stream.h"
#include "Communicator.h"
#ifndef _STREAM_COMMUNICATOR_INCLUDED_
#define _STREAM_COMMUNICATOR_INCLUDED_
class StreamCommunicator: public Communicator
{
protected:
Stream &stream;
public:
StreamCommunicator(Stream &s_out, __SIZE_TYPE__ bufferSize);
void sendMessage(int *values, __SIZE_TYPE__ numberOfValues) override;
void sendMessage(const char message[]) override;
char *receiveMessage() override;
};
#endif

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#include <WebsocketCommunicator.h>
#include <ESPAsyncWebServer.h>
WebsocketCommunicator::WebsocketCommunicator(AsyncWebSocket &socket, AsyncWebServer &server, __SIZE_TYPE__ bufferSize) : Communicator(bufferSize), socket(socket), server(server)
{
AwsEventHandler onEvent = [this](AsyncWebSocket *server, AsyncWebSocketClient *client, AwsEventType type,
void *arg, uint8_t *data, size_t len)
{
switch (type)
{
case WS_EVT_CONNECT:
Serial.printf("WebSocket client #%u connected from %s\n", client->id(), client->remoteIP().toString().c_str());
break;
case WS_EVT_DISCONNECT:
Serial.printf("WebSocket client #%u disconnected\n", client->id());
break;
case WS_EVT_DATA:
handleMessage(arg, data, len);
break;
case WS_EVT_PONG:
case WS_EVT_ERROR:
break;
}
};
msgRead = false;
socket.onEvent(onEvent);
server.addHandler(&socket);
}
void WebsocketCommunicator::sendMessage(int *values, __SIZE_TYPE__ numberOfValues)
{
char message[calculateMessageOutSize(numberOfValues)];
parseIDs(values, numberOfValues, message);
sendMessage(message);
}
void WebsocketCommunicator::sendMessage(const char message[])
{
socket.textAll(message);
}
char *WebsocketCommunicator::receiveMessage()
{
msgRead = true;
return getBuffer();
}
void WebsocketCommunicator::clearBufferSafely()
{
if (msgRead)
{
clearBuffer();
}
}
void WebsocketCommunicator::handleMessage(void *arg, uint8_t *data, size_t len)
{
msgRead = false;
int effectiveLen = len < bufferSize ? len : bufferSize;
strncpy(messageBuffer, (char *)data, effectiveLen);
}

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#include <Communicator.h>
#include <ESPAsyncWebServer.h>
class WebsocketCommunicator : public Communicator
{
private:
void handleMessage(void *arg, uint8_t *data, size_t len);
bool msgRead;
protected:
AsyncWebSocket &socket;
AsyncWebServer &server;
public:
WebsocketCommunicator(AsyncWebSocket &socket, AsyncWebServer &server, __SIZE_TYPE__ bufferSize);
void sendMessage(int *values, __SIZE_TYPE__ numberOfValues) override;
void sendMessage(const char message[]) override;
char *receiveMessage() override;
void clearBufferSafely();
};

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; PlatformIO Project Configuration File
;
; Build options: build flags, source filter
; Upload options: custom upload port, speed and extra flags
; Library options: dependencies, extra library storages
; Advanced options: extra scripting
;
; Please visit documentation for the other options and examples
; https://docs.platformio.org/page/projectconf.html
[platformio]
default_envs = Upload_UART
[env]
platform = espressif32
board = az-delivery-devkit-v4
framework = arduino
lib_deps =
erropix/ESP32 AnalogWrite@^0.2
ESP Async WebServer
board_build.partitions = huge_app.csv
[env:Upload_UART]
upload_port = COM9
monitor_port = COM9
[env:CI_Build]
build_flags = -D DEBUG=1
; PlatformIO Project Configuration File
;
; Build options: build flags, source filter
; Upload options: custom upload port, speed and extra flags
; Library options: dependencies, extra library storages
; Advanced options: extra scripting
;
; Please visit documentation for the other options and examples
; https://docs.platformio.org/page/projectconf.html
[env:esp32dev]
platform = espressif32
board = esp32dev
framework = arduino
board_build.partitions = huge_app.csv
lib_deps = etlcpp/Embedded Template Library@^20.35.12
monitor_speed=115200
build_flags=-Wall
check_tool = clangtidy
check_flags =
clangtidy: --checks=-*,clang-diagnostic-*,-clang-diagnostic-unused-value,clang-analyzer-*,-*,bugprone-*,performance-*,readability-*,-readability-magic-numbers,-readability-braces-around-statements,-readability-inconsistent-declaration-parameter-name,-readability-named-parameter --fix

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#pragma once
#include <Arduino.h>
#include <FreeRTOS/Queue.h>
#include <FreeRTOS/Task.h>
#include <FreeRTOS/Util.h>
#include <Messages/Message.h>
#include <Util/CircularBuffer.h>
#include <etl/string.h>
namespace comm {
namespace serial {
template <size_t bufferSize = 20> class SerialReceiver {
public:
SerialReceiver(HardwareSerial &port,
freertos::Queue<message::Message *> &messageQueue,
UBaseType_t priority, BaseType_t coreID)
: port{port}, messageQueue{messageQueue},
serialReceiverTask{
exec, "receive serial data", stackDepth, this, priority, coreID} {
for (size_t i = 0; i < bufferSize; ++i) {
message::Message &msg = buffer.pop();
msg.second.give();
}
}
private:
static void exec(void *receiverPtr) {
freertos::sleep(20); // wait until Serial port has been initialized
SerialReceiver<bufferSize> *receiver =
static_cast<SerialReceiver<bufferSize> *>(receiverPtr);
while (true) {
receiver->magicNumberBuf.clear();
receiver->magicNumberBuf.resize(receiver->magicNumber.length());
size_t availableBytes = receiver->port.available();
if (receiver->port.available() > 0 && receiver->port.peek() != 'H') {
receiver->port.read();
receiver->port.println("flush");
} else if (availableBytes >= receiver->magicNumber.length() + 1) {
receiver->port.readBytes(receiver->magicNumberBuf.data(),
receiver->magicNumber.length());
receiver->port.println("Received Magic Number:");
receiver->port.println(receiver->magicNumberBuf == receiver->magicNumber
? "correct"
: "incorrect");
if (receiver->magicNumberBuf == receiver->magicNumber) {
uint8_t size;
receiver->port.readBytes(&size, sizeof(size));
if (receiver->port.available() >= size) {
message::Message &msg = receiver->buffer.pop();
receiver->port.printf("Current semaphore count: %u\n",
msg.second.getCount());
msg.second.take();
msg.first.clear();
msg.first.resize(size);
receiver->port.readBytes(msg.first.data(), size);
// msg.second.unlock();
receiver->port.println("Push message to queue");
receiver->messageQueue.push(&msg);
}
}
}
}
}
HardwareSerial &port;
freertos::Queue<message::Message *> &messageQueue;
etl::string<4> magicNumberBuf;
const etl::string<2> magicNumber{"HX"};
util::CircularBuffer<message::Message, bufferSize> buffer;
freertos::Task serialReceiverTask;
static const uint32_t stackDepth = 2048;
};
} // namespace serial
} // namespace comm

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#include <Communication/Serial/SerialSender.h>
comm::serial::SerialSender::SerialSender(HardwareSerial &port,
UBaseType_t queueCapacity,
UBaseType_t priority,
BaseType_t coreID)
: port{port}, messages{queueCapacity}, SerialSenderTask{
exec, "send serial data",
stackDepth, this,
priority, coreID} {}
void comm::serial::SerialSender::exec(void *senderPtr) {
SerialSender *sender = static_cast<SerialSender *>(senderPtr);
freertos::sleep(20); // wait until Serial port has been initialized
while (true) {
if (!sender->port.availableForWrite()) {
continue;
}
auto message = sender->messages.pop();
if (message.has_value()) {
sender->port.write(message.value().data(), message.value().size());
}
}
}

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#pragma once
#include <Arduino.h>
#include <FreeRTOS/Queue.h>
#include <FreeRTOS/Task.h>
#include <FreeRTOS/Util.h>
#include <Messages/Message.h>
#include <Util/CircularBuffer.h>
#include <etl/span.h>
#include <etl/string.h>
namespace comm {
namespace serial {
class SerialSender {
public:
SerialSender(HardwareSerial &port, UBaseType_t queueCapacity,
UBaseType_t priority, BaseType_t coreID);
freertos::Queue<etl::span<uint8_t>> &getMessageQueue() { return messages; }
private:
static void exec(void *senderPtr);
HardwareSerial &port;
freertos::Queue<etl::span<uint8_t>> messages;
freertos::Task SerialSenderTask;
static const uint32_t stackDepth = 2048;
};
} // namespace serial
} // namespace comm

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#ifndef DEBUG
#include <Credentials/Credentials.h>
#include "Credentials/Credentials.h"
#endif
#ifdef DEBUG
#define WIFI_SSID "ssid"

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#include <FreeRTOS/BinarySemaphore.h>
#include <etl/utility.h>
freertos::BinarySemaphore::BinarySemaphore()
: handle{xSemaphoreCreateBinary()} {}
freertos::BinarySemaphore::BinarySemaphore(BinarySemaphore &&other) noexcept {
handle = etl::move(other.handle);
}
freertos::BinarySemaphore::~BinarySemaphore() { vSemaphoreDelete(handle); }
auto freertos::BinarySemaphore::operator=(
const BinarySemaphore &&other) noexcept -> BinarySemaphore & {
handle = etl::move(other.handle);
return *this;
}
auto freertos::BinarySemaphore::take(TickType_t timeout) -> bool {
BaseType_t success = xSemaphoreTake(handle, timeout);
return success == pdTRUE;
}
auto freertos::BinarySemaphore::give() -> bool {
BaseType_t success = xSemaphoreGive(handle);
return success == pdTRUE;
}
auto freertos::BinarySemaphore::getCount() -> size_t {
return uxSemaphoreGetCount(handle);
}

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#pragma once
#include <Arduino.h>
namespace freertos {
class BinarySemaphore {
public:
BinarySemaphore();
BinarySemaphore(const BinarySemaphore &other) = delete;
BinarySemaphore(BinarySemaphore &&other) noexcept;
~BinarySemaphore();
BinarySemaphore &operator=(const BinarySemaphore &other) = delete;
BinarySemaphore &operator=(const BinarySemaphore &&other) noexcept;
bool take(TickType_t timeout = portMAX_DELAY);
bool give();
size_t getCount();
private:
SemaphoreHandle_t handle;
};
} // namespace freertos

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#include "Mutex.h"
#include <etl/utility.h>
freertos::Mutex::Mutex() : handle{xSemaphoreCreateMutex()} {}
freertos::Mutex::Mutex(Mutex &&other) noexcept {
handle = etl::move(other.handle);
}
freertos::Mutex::~Mutex() { vSemaphoreDelete(handle); }
auto freertos::Mutex::operator=(const Mutex &&other) noexcept -> Mutex & {
handle = etl::move(other.handle);
return *this;
}
auto freertos::Mutex::lock(TickType_t timeout) -> bool{
BaseType_t success = xSemaphoreTake(handle, timeout);
return success == pdTRUE;
}
auto freertos::Mutex::unlock() -> bool {
BaseType_t success = xSemaphoreGive(handle);
return success == pdTRUE;
}

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#pragma once
#include <Arduino.h>
namespace freertos {
class Mutex {
public:
Mutex();
Mutex(const Mutex &other) = delete;
Mutex(Mutex &&other) noexcept;
~Mutex();
Mutex &operator=(const Mutex &other) = delete;
Mutex &operator=(const Mutex &&other) noexcept;
bool lock(TickType_t timeout = portMAX_DELAY);
bool unlock();
private:
SemaphoreHandle_t handle;
};
} // namespace freertos

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#pragma once
#include <Arduino.h>
#include <etl/optional.h>
namespace freertos {
template <typename T> class Queue {
public:
Queue(UBaseType_t capacity) : queueCapacity{capacity} {
handle = xQueueCreate(capacity, sizeof(T));
}
Queue(const Queue &other) = delete;
Queue(Queue &&other)
: handle{etl::move(other.handle)}, queueCapacity{
etl::move(other.queueCapacity)} {}
~Queue() { vQueueDelete(handle); }
Queue &operator=(const Queue &other) = delete;
Queue &operator=(const Queue &&other) {
handle = etl::move(other.handle);
queueCapacity = etl::move(other.queueCapacity);
}
etl::optional<T> peek(const TickType_t ticksToWait = portMAX_DELAY) {
T buf;
BaseType_t status = xQueuePeek(handle, &buf, ticksToWait);
return status == pdTRUE ? etl::make_optional<T>(buf) : etl::nullopt;
}
size_t size() { return uxQueueMessagesWaiting(handle); }
size_t available() { return uxQueueSpacesAvailable(handle); }
size_t capacity() { return queueCapacity; }
bool push(const T item, const TickType_t ticksToWait = portMAX_DELAY) {
return xQueueSend(handle, &item, ticksToWait) == pdTRUE;
}
etl::optional<T> pop(const TickType_t ticksToWait = portMAX_DELAY) {
T buf;
BaseType_t status = xQueueReceive(handle, &buf, ticksToWait);
return status == pdTRUE ? etl::make_optional<T>(buf) : etl::nullopt;
}
void clear() { xQueueReset(handle); }
bool isValid() { return handle != NULL; }
private:
QueueHandle_t handle;
UBaseType_t queueCapacity;
};
} // namespace freertos

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#include "Task.h"
freertos::Task::Task(TaskFunction_t taskFunction, const etl::string_view name,
const uint32_t stackDepth, void *const params,
UBaseType_t priority, const BaseType_t coreID)
: name{name}, stackDepth{stackDepth}, priority{priority}, coreID{coreID} {
status = xTaskCreatePinnedToCore(taskFunction, name.data(), stackDepth,
params, priority, &handle, coreID);
}
freertos::Task::Task(Task &&other) noexcept
: name{etl::move(other.name)}, handle{etl::move(other.handle)},
stackDepth{etl::move(other.stackDepth)},
priority{etl::move(other.priority)}, coreID{etl::move(other.coreID)} {}
freertos::Task::~Task() {
if (status == pdPASS) {
vTaskDelete(handle);
}
}
auto freertos::Task::operator=(const Task &&other) noexcept -> Task & {
name = etl::move(other.name);
handle = etl::move(other.handle);
stackDepth = etl::move(other.stackDepth);
priority = etl::move(other.priority);
coreID = etl::move(other.coreID);
return *this;
}
auto freertos::Task::getName() const -> etl::string_view { return name; }
auto freertos::Task::getStackDepth() const -> uint32_t { return stackDepth; }
auto freertos::Task::getPriority() const -> UBaseType_t { return priority; }
auto freertos::Task::setPriority(const UBaseType_t newPriority) -> void {
vTaskPrioritySet(handle, newPriority);
}
auto freertos::Task::getCoreID() const -> BaseType_t { return coreID; }
auto freertos::Task::isValid() const -> bool { return status == pdPASS; }

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#pragma once
#include <Arduino.h>
#include <etl/string.h>
namespace freertos {
class Task {
public:
Task(TaskFunction_t taskFunction, const etl::string_view name,
const uint32_t stackDepth, void *const params, UBaseType_t priority,
const BaseType_t coreID);
Task(const Task &other) = delete;
Task(Task &&other) noexcept;
~Task();
Task &operator=(const Task &other) = delete;
Task &operator=(const Task &&other) noexcept;
etl::string_view getName() const;
uint32_t getStackDepth() const;
UBaseType_t getPriority() const;
void setPriority(const UBaseType_t newPriority);
BaseType_t getCoreID() const;
bool isValid() const;
private:
etl::string_view name;
TaskHandle_t handle;
uint32_t stackDepth;
UBaseType_t priority;
BaseType_t coreID;
BaseType_t status;
};
} // namespace freertos

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#include "Util.h"
void freertos::sleep(int time) { vTaskDelay(time * portTICK_PERIOD_MS); }
void freertos::sleepForever() { vTaskDelay(portMAX_DELAY); }

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#pragma once
#include <Arduino.h>
namespace freertos {
/// @brief Blocks the task for the specified amount of time
/// @param time in milliseconds
void sleep(int time);
/// @brief Sleep for the maximum delay possible
void sleepForever();
} // namespace freertos

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#pragma once
#include <Arduino.h>
#include <FreeRTOS/Mutex.h>
#include <FreeRTOS/Queue.h>
#include <FreeRTOS/Task.h>
#include <FreeRTOS/Util.h>
#include <etl/optional.h>
#include <etl/span.h>
namespace LightController {
enum class LightActionType { INCREASE, DECREASE, TOGGLE, ON, OFF };
using LightAction = etl::pair<LightActionType, etl::optional<uint8_t>>;
template <int... PIN> class Controller {
public:
Controller(size_t actionQueueSize, UBaseType_t controllerPriority,
BaseType_t controllerCoreID, UBaseType_t faderPriority,
BaseType_t faderCoreID)
: lightPins{PIN...}, lightActions{actionQueueSize},
lightControllerTask{exec, "control lights", stackDepth,
this, controllerPriority, controllerCoreID},
lightFaderTask{execFade, "fade lights", stackDepth,
this, faderPriority, faderCoreID} {
for (int pin : lightPins) {
pinMode(pin, OUTPUT);
}
lightStatesCurrent.second.unlock();
}
freertos::Queue<LightAction> &getActionQueue() { return lightActions; }
constexpr size_t lightCount() { return lightPins.size(); }
const etl::span<int> getPins() { return lightPins; }
private:
static void exec(void *controllerPtr) {
Controller *controller{static_cast<Controller *>(controllerPtr)};
while (true) {
auto action{controller->getActionQueue().pop()};
if (action.has_value()) {
LightActionType type{action.value().first};
etl::optional<uint8_t> index{action.value().second};
switch (type) {
case LightActionType::INCREASE:
if (index.has_value() &&
index.value() < controller->lightStatesFinal.size() &&
controller->lightStatesFinal[index.value()] <=
255 - controller->step) {
controller->lightStatesFinal[index.value()] += controller->step;
}
break;
case LightActionType::DECREASE:
if (index.has_value() &&
index.value() < controller->lightStatesFinal.size() &&
controller->lightStatesFinal[index.value()] >= 0) {
controller->lightStatesFinal[index.value()] -= controller->step;
}
break;
case LightActionType::TOGGLE:
if (index.has_value() &&
index.value() < controller->lightStatesFinal.size()) {
controller->lightStatesCurrent.second.lock();
controller->lightStatesFinal[index.value()] =
controller->lightStatesFinal[index.value()] == 0 ? 255 : 0;
controller->lightStatesCurrent.first[index.value()] =
controller->lightStatesFinal[index.value()];
controller->lightStatesCurrent.second.unlock();
}
break;
case LightActionType::ON:
controller->lightStatesCurrent.second.lock();
controller->lightStatesFinal.fill(255);
controller->lightStatesCurrent.first.fill(255);
controller->lightStatesCurrent.second.unlock();
break;
case LightActionType::OFF:
controller->lightStatesCurrent.second.lock();
controller->lightStatesFinal.fill(0);
controller->lightStatesCurrent.first.fill(0);
controller->lightStatesCurrent.second.unlock();
break;
default:
break;
}
}
}
}
static void execFade(void *controllerPtr) {
Controller *controller{static_cast<Controller *>(controllerPtr)};
while (true) {
freertos::sleep(controller->fadeRate);
controller->lightStatesCurrent.second.lock();
for (size_t i = 0; i < controller->lightStatesFinal.size(); i++) {
if (controller->lightStatesCurrent.first[i] <
controller->lightStatesFinal[i]) {
controller->lightStatesCurrent.first[i] += 1;
} else if (controller->lightStatesCurrent.first[i] >
controller->lightStatesFinal[i]) {
controller->lightStatesCurrent.first[i] -= 1;
}
}
for (size_t lightIndex = 0;
lightIndex < controller->lightStatesCurrent.first.size();
++lightIndex) {
analogWrite(controller->getPins()[lightIndex],
controller->lightStatesCurrent.first[lightIndex]);
}
controller->lightStatesCurrent.second.unlock();
}
}
static const uint32_t stackDepth = 2048;
const uint8_t step = 5;
const size_t fadeRate = 50;
etl::array<int, sizeof...(PIN)> lightPins;
freertos::Queue<LightAction> lightActions;
freertos::Task lightControllerTask;
freertos::Task lightFaderTask;
etl::array<uint8_t, sizeof...(PIN)> lightStatesFinal;
etl::pair<etl::array<uint8_t, sizeof...(PIN)>, freertos::Mutex>
lightStatesCurrent;
};
} // namespace LightController

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#include "Composer.h"
bool message::composer::sendMessage(protocol::Message type,
etl::string_view content) {
if (content.length() > protocol::MAX_PAYLOAD_LEN) {
return false;
}
uint8_t length =
protocol::HEADER_LEN + static_cast<uint8_t>(content.length());
// Serial.write("HX");
// Serial.write(length);
// Serial.write(protocol::to_underlying(type));
// Serial.write(content.data());
return true;
};

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#pragma once
#include "Protocol.h"
#include <etl/optional.h>
#include <etl/span.h>
#include <etl/string.h>
namespace message {
namespace composer {
enum class ComposableType {
MESSAGE_LIGHTDATA,
MESSAGE_INFO,
MESSAGE_WARNING,
MESSAGE_ERROR,
MESSAGE_SUCCESS,
COMMAND_HELP,
COMMAND_VERSION,
};
using Composable = etl::pair<ComposableType, etl::optional<etl::span<uint8_t>>>;
bool sendMessage(protocol::Message type, etl::string_view content);
} // namespace composer
} // namespace message

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#pragma once
#include <Arduino.h>
#include <FreeRTOS/BinarySemaphore.h>
#include <Messages/Protocol.h>
#include <etl/utility.h>
#include <etl/vector.h>
namespace message {
/// @brief first: data, second: data ready to reuse
using Message =
etl::pair<etl::vector<uint8_t, message::protocol::MAX_PAYLOAD_LEN>,
freertos::BinarySemaphore>;
} // namespace message

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#include "Parser.h"
#include <FreeRTOS/Util.h>
#include <PinMap/PinMap.h>
#include <etl/vector.h>
message::parser::StateVisitor::StateVisitor(
message::Message *message,
freertos::Queue<LightController::LightAction> &lightActionQueue)
: stream{message->first.begin(), message->first.size(), etl::endian::big},
message{message}, lightActionQueue{lightActionQueue} {}
auto message::parser::StateVisitor::operator()(state::ModeSelection) -> State {
if (!stream.available<uint8_t>()) {
// invalidCallback("ModeSelection: Stream not available");
return state::Invalid{};
}
auto mode = stream.read<uint8_t>();
if (!mode.has_value()) {
// invalidCallback("ModeSelection: Mode has no value");
return state::Invalid{};
}
switch (mode.value()) {
case static_cast<uint8_t>(protocol::Mode::Message):
return state::Message{};
case static_cast<uint8_t>(protocol::Mode::Settings):
return state::Settings{};
case static_cast<uint8_t>(protocol::Mode::LightControl):
return state::LightControl{};
case static_cast<uint8_t>(protocol::Mode::Command):
return state::Command{};
default:
// invalidCallback("ModeSelection: Invalid index");
return state::Invalid{};
}
}
auto message::parser::StateVisitor::operator()(state::Message) -> State {
if (!stream.available<uint8_t>()) {
// invalidCallback("Message: Stream not available");
return state::Invalid{};
}
auto mode = stream.read<uint8_t>();
if (!mode.has_value()) {
// invalidCallback("Message: Mode has no value");
return state::Invalid{};
}
switch (mode.value()) {
case static_cast<uint8_t>(protocol::Message::LightData):
return state::MessageLightData{};
case static_cast<uint8_t>(protocol::Message::Info):
return state::MessageInfo{};
case static_cast<uint8_t>(protocol::Message::Warning):
return state::MessageWarning{};
case static_cast<uint8_t>(protocol::Message::Error):
return state::MessageError{};
case static_cast<uint8_t>(protocol::Message::Success):
return state::MessageSuccess{};
default:
// invalidCallback("Message: Invalid index");
return state::Invalid{};
}
}
auto message::parser::StateVisitor::operator()(state::MessageLightData)
-> State {
if (!stream.available<char>()) {
// invalidCallback("MessageLightData: Stream not available");
return state::Invalid{};
}
auto msg = stream.read<char>(stream.available<char>());
if (!msg.has_value()) {
// invalidCallback("MessageLightData: Message has no value");
return state::Invalid{};
}
return state::Invalid{};
}
auto message::parser::StateVisitor::operator()(state::MessageInfo) -> State {
if (!stream.available<char>()) {
// invalidCallback("MessageInfo: Stream not available");
return state::Invalid{};
}
auto msg = stream.read<char>(stream.available<char>());
if (!msg.has_value()) {
// invalidCallback("MessageInfo: Message has no value");
return state::Invalid{};
}
return state::Invalid{};
}
auto message::parser::StateVisitor::operator()(state::MessageWarning) -> State {
if (!stream.available<char>()) {
// invalidCallback("MessageWarning: Stream not available");
return state::Invalid{};
}
auto msg = stream.read<char>(stream.available<char>());
if (!msg.has_value()) {
// invalidCallback("MessageWarning: Message has no value");
return state::Invalid{};
}
return state::Invalid{};
}
auto message::parser::StateVisitor::operator()(state::MessageError) -> State {
if (!stream.available<char>()) {
// invalidCallback("MessageError: Stream not available");
return state::Invalid{};
}
auto msg = stream.read<char>(stream.available<char>());
if (!msg.has_value()) {
// invalidCallback("MessageError: Message has no value");
return state::Invalid{};
}
return state::Invalid{};
}
auto message::parser::StateVisitor::operator()(state::MessageSuccess) -> State {
if (!stream.available<char>()) {
// invalidCallback("MessageSuccess: Stream not available");
return state::Invalid{};
}
auto msg = stream.read<char>(stream.available<char>());
if (!msg.has_value()) {
// invalidCallback("MessageSuccess: Message has no value");
return state::Invalid{};
}
return state::Invalid{};
}
auto message::parser::StateVisitor::operator()(state::Settings) -> State {
if (!stream.available<uint8_t>()) {
// invalidCallback("Settings: Stream not available");
return state::Invalid{};
}
auto mode = stream.read<uint8_t>();
if (!mode.has_value()) {
// invalidCallback("Settings: Mode has no value");
return state::Invalid{};
}
switch (mode.value()) {
case static_cast<uint8_t>(protocol::Settings::SetBaud):
return state::SettingsSetBaud{};
case static_cast<uint8_t>(protocol::Settings::SetWifiPassword):
return state::SettingsWifiPassword{};
case static_cast<uint8_t>(protocol::Settings::SetWifiSSID):
return state::SettingsWifiSSID{};
default:
// invalidCallback("Settings: Invalid index");
return state::Invalid{};
}
}
auto message::parser::StateVisitor::operator()(state::SettingsSetBaud)
-> State {
if (!stream.available<uint32_t>()) {
// invalidCallback("Settings: Stream not available");
return state::Invalid{};
}
auto baud = stream.read<uint32_t>();
if (!baud.has_value()) {
// invalidCallback("SettingsSetBaud: Baud has no value");
return state::Invalid{};
}
return state::Invalid{};
}
auto message::parser::StateVisitor::operator()(state::SettingsWifiPassword)
-> State {
if (!stream.available<char>()) {
// invalidCallback("SettingsWifiPassword: Stream not available");
return state::Invalid{};
}
auto passwd = stream.read<char>(stream.available<char>());
if (!passwd.has_value()) {
// invalidCallback("SettingsWifiPassword: Passwd has no value");
return state::Invalid{};
}
return state::Invalid{};
}
auto message::parser::StateVisitor::operator()(state::SettingsWifiSSID)
-> State {
if (!stream.available<char>()) {
// invalidCallback("SettingsWifiSSID: Stream not available");
return state::Invalid{};
}
auto ssid = stream.read<char>(stream.available<char>());
if (!ssid.has_value()) {
// invalidCallback("SettingsWifiSSID: SSID has no value");
return state::Invalid{};
}
return state::Invalid{};
}
auto message::parser::StateVisitor::operator()(state::LightControl) -> State {
if (!stream.available<uint8_t>()) {
// invalidCallback("LightControl: Stream not available");
return state::Invalid{};
}
auto mode = stream.read<uint8_t>();
if (!mode.has_value()) {
// invalidCallback("LightControl: Mode has no value");
return state::Invalid{};
}
switch (mode.value()) {
case static_cast<uint8_t>(protocol::LightControl::On):
return state::LightControlOn{};
case static_cast<uint8_t>(protocol::LightControl::Off):
return state::LightControlOff{};
case static_cast<uint8_t>(protocol::LightControl::Toggle):
return state::LightControlToggle{};
case static_cast<uint8_t>(protocol::LightControl::Increase):
return state::LightControlIncrease{};
case static_cast<uint8_t>(protocol::LightControl::Decrease):
return state::LightControlDecrease{};
default:
// invalidCallback("LightControl: Invalid index");
return state::Invalid{};
}
}
auto message::parser::StateVisitor::operator()(state::LightControlOn) -> State {
if (stream.available_bytes() > 0) {
// invalidCallback("LightControlOn: Too many bytes left");
return state::Invalid{};
}
message->second.give();
Serial.println("ON");
lightActionQueue.push({LightController::LightActionType::ON, etl::nullopt});
return state::Complete{};
}
auto message::parser::StateVisitor::operator()(state::LightControlOff)
-> State {
if (stream.available_bytes() > 0) {
// invalidCallback("LightControlOff: Too many bytes left");
return state::Invalid{};
}
message->second.give();
Serial.println("OFF");
lightActionQueue.push({LightController::LightActionType::OFF, etl::nullopt});
return state::Complete{};
}
auto message::parser::StateVisitor::operator()(state::LightControlToggle)
-> State {
if (stream.available_bytes() > 1) {
// invalidCallback("LightControlToggle: Too many bytes left");
return state::Invalid{};
} else if (!stream.available<uint8_t>()) {
// invalidCallback("LightControlToggle: Stream not available");
return state::Invalid{};
}
auto id = stream.read<uint8_t>();
message->second.give();
Serial.println("Toggle");
lightActionQueue.push({LightController::LightActionType::TOGGLE, id});
return state::Complete{};
}
auto message::parser::StateVisitor::operator()(state::LightControlIncrease)
-> State {
if (stream.available_bytes() > 1) {
// invalidCallback("LightControlIncrease: Too many bytes left");
return state::Invalid{};
} else if (!stream.available<uint8_t>()) {
// invalidCallback("LightControlIncrease: Stream not available");
return state::Invalid{};
}
auto id = stream.read<uint8_t>();
message->second.give();
Serial.println("Increase");
lightActionQueue.push({LightController::LightActionType::INCREASE, id});
return state::Complete{};
}
auto message::parser::StateVisitor::operator()(state::LightControlDecrease)
-> State {
if (stream.available_bytes() > 1) {
// invalidCallback("LightControlDecrease: Too many bytes left");
return state::Invalid{};
} else if (!stream.available<uint8_t>()) {
// invalidCallback("LightControlDecrease: Stream not available");
return state::Invalid{};
}
auto id = stream.read<uint8_t>();
message->second.give();
Serial.println("Decrease");
lightActionQueue.push({LightController::LightActionType::DECREASE, id});
return state::Complete{};
}
auto message::parser::StateVisitor::operator()(state::Command) -> State {
if (!stream.available<uint8_t>()) {
// invalidCallback("Command: Stream not available");
return state::Invalid{};
}
auto mode = stream.read<uint8_t>();
if (!mode.has_value()) {
// invalidCallback("Command: Mode has no value");
return state::Invalid{};
}
switch (mode.value()) {
case static_cast<uint8_t>(protocol::Command::RequestLightData):
return state::CommandRequestLightData{};
case static_cast<uint8_t>(protocol::Command::EnterConsoleFlashing):
return state::CommandEnterConsoleFlashing{};
case static_cast<uint8_t>(protocol::Command::ExitConsoleFlashing):
return state::CommandExitConsoleFlashing{};
case static_cast<uint8_t>(protocol::Command::PairBluetooth):
return state::CommandPairBluetooth{};
case static_cast<uint8_t>(protocol::Command::Help):
return state::CommandHelp{};
case static_cast<uint8_t>(protocol::Command::Version):
return state::CommandVersion{};
case static_cast<uint8_t>(protocol::Command::Reset):
return state::CommandReset{};
default:
// invalidCallback("Command: Invalid index");
return state::Invalid{};
}
}
auto message::parser::StateVisitor::operator()(state::CommandRequestLightData)
-> State {
return state::Invalid{};
}
auto message::parser::StateVisitor::operator()(
state::CommandEnterConsoleFlashing) -> State {
if (stream.available_bytes() > 0) {
// invalidCallback("CommandEnterConsoleFlashing: Too many bytes left");
return state::Invalid{};
}
return state::Invalid{};
}
auto message::parser::StateVisitor::operator()(
state::CommandExitConsoleFlashing) -> State {
if (stream.available_bytes() > 0) {
// invalidCallback("CommandExitConsoleFlashing: Too many bytes left");
return state::Invalid{};
}
return state::Invalid{};
}
auto message::parser::StateVisitor::operator()(state::CommandPairBluetooth)
-> State {
if (stream.available_bytes() > 0) {
// invalidCallback("CommandPairBluetooth: Too many bytes left");
return state::Invalid{};
}
return state::Invalid{};
}
auto message::parser::StateVisitor::operator()(state::CommandHelp) -> State {
if (stream.available_bytes() > 0) {
// invalidCallback("CommandHelp: Too many bytes left");
return state::Invalid{};
}
return state::Invalid{};
}
auto message::parser::StateVisitor::operator()(state::CommandVersion) -> State {
if (stream.available_bytes() > 0) {
// invalidCallback("CommandVersion: Too many bytes left");
return state::Invalid{};
}
return state::Invalid{};
}
auto message::parser::StateVisitor::operator()(state::CommandReset) -> State {
if (stream.available_bytes() > 0) {
// invalidCallback("CommandVersion: Too many bytes left");
return state::Invalid{};
}
ESP.restart();
return state::Complete{};
}
auto message::parser::StateVisitor::operator()(state::Complete) -> State {
return state::Complete{};
}
auto message::parser::StateVisitor::operator()(state::Invalid) -> State {
message->second.give();
return state::Complete{};
}
auto message::parser::parse(
message::Message *message,
freertos::Queue<LightController::LightAction> &lightActionQueue) -> void {
StateVisitor visitor{message, lightActionQueue};
State state{state::ModeSelection{}};
while (!etl::holds_alternative<state::Complete>(state)) {
state = etl::visit(visitor, state);
}
}
message::parser::Parser::Parser(
freertos::Queue<LightController::LightAction> &lightActionQueue,
UBaseType_t queueCapacity, UBaseType_t priority, BaseType_t coreID)
: parserTask{exec, "parse received data", stackDepth, this, priority,
coreID},
messages{queueCapacity}, lightActionQueue{lightActionQueue} {}
void message::parser::Parser::exec(void *parserPtr) {
Parser *parser = static_cast<Parser *>(parserPtr);
while (true) {
auto message = parser->messages.pop();
Serial.println("starting parse");
if (message.has_value()) {
parse(message.value(), parser->lightActionQueue);
}
}
}

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#pragma once
#include "Protocol.h"
#include <FreeRTOS/Queue.h>
#include <FreeRTOS/Task.h>
#include <LightController/Controller.h>
#include <Messages/Message.h>
#include <etl/byte_stream.h>
#include <etl/function.h>
#include <etl/span.h>
#include <etl/string_view.h>
#include <etl/variant.h>
namespace message {
namespace parser {
namespace state {
struct Invalid {};
struct ModeSelection {};
struct Message {};
struct MessageLightData {};
struct MessageInfo {};
struct MessageWarning {};
struct MessageError {};
struct MessageSuccess {};
struct Settings {};
struct SettingsSetBaud {};
struct SettingsWifiPassword {};
struct SettingsWifiSSID {};
struct LightControl {};
struct LightControlOn {};
struct LightControlOff {};
struct LightControlToggle {};
struct LightControlIncrease {};
struct LightControlDecrease {};
struct Command {};
struct CommandRequestLightData {};
struct CommandEnterConsoleFlashing {};
struct CommandExitConsoleFlashing {};
struct CommandPairBluetooth {};
struct CommandHelp {};
struct CommandVersion {};
struct CommandReset {};
struct Complete {};
} // namespace state
using State = etl::variant<
state::Invalid, state::ModeSelection, state::Message,
state::MessageLightData, state::MessageInfo, state::MessageWarning,
state::MessageError, state::MessageSuccess, state::Settings,
state::SettingsSetBaud, state::SettingsWifiPassword,
state::SettingsWifiSSID, state::LightControl, state::LightControlOn,
state::LightControlOff, state::LightControlToggle,
state::LightControlIncrease, state::LightControlDecrease, state::Command,
state::CommandRequestLightData, state::CommandEnterConsoleFlashing,
state::CommandExitConsoleFlashing, state::CommandPairBluetooth,
state::CommandHelp, state::CommandVersion, state::CommandReset,
state::Complete>;
void parse(message::Message *message,
freertos::Queue<LightController::LightAction> &lightActionQueue);
class StateVisitor {
public:
StateVisitor(message::Message *message,
freertos::Queue<LightController::LightAction> &lightActionQueue);
State operator()(state::ModeSelection);
State operator()(state::Message);
State operator()(state::MessageLightData);
State operator()(state::MessageInfo);
State operator()(state::MessageWarning);
State operator()(state::MessageError);
State operator()(state::MessageSuccess);
State operator()(state::Settings);
State operator()(state::SettingsSetBaud);
State operator()(state::SettingsWifiPassword);
State operator()(state::SettingsWifiSSID);
State operator()(state::LightControl);
State operator()(state::LightControlOn);
State operator()(state::LightControlOff);
State operator()(state::LightControlToggle);
State operator()(state::LightControlIncrease);
State operator()(state::LightControlDecrease);
State operator()(state::Command);
State operator()(state::CommandRequestLightData);
State operator()(state::CommandEnterConsoleFlashing);
State operator()(state::CommandExitConsoleFlashing);
State operator()(state::CommandPairBluetooth);
State operator()(state::CommandHelp);
State operator()(state::CommandVersion);
State operator()(state::CommandReset);
State operator()(state::Complete);
State operator()(state::Invalid);
private:
etl::byte_stream_reader stream;
message::Message *message;
freertos::Queue<LightController::LightAction> &lightActionQueue;
};
class Parser {
public:
Parser(freertos::Queue<LightController::LightAction> &lightActionQueue,
UBaseType_t queueCapacity, UBaseType_t priority, BaseType_t coreID);
freertos::Queue<message::Message *> &getMessageQueue() { return messages; }
private:
static void exec(void *parserPtr);
freertos::Task parserTask;
static const uint32_t stackDepth = 2048;
freertos::Queue<message::Message *> messages;
freertos::Queue<LightController::LightAction> &lightActionQueue;
};
} // namespace parser
} // namespace message

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#pragma once
#include <etl/type_def.h>
#include <etl/type_traits.h>
#include <etl/variant.h>
#include <etl/visitor.h>
#include <type_traits>
namespace message {
namespace protocol {
static const uint8_t HEADER_LEN = 5;
static const uint8_t MAX_TOTAL_LEN = 255;
static const uint8_t MAX_PAYLOAD_LEN = MAX_TOTAL_LEN - HEADER_LEN;
enum class Mode : uint8_t {
Message = 0x0,
Settings = 0x1,
LightControl = 0x2,
Command = 0x3
};
enum class Message : uint8_t {
LightData = 0x0,
Info = 0x1,
Warning = 0x2,
Error = 0x3,
Success = 0x5,
};
enum class Settings : uint8_t {
SetBaud = 0x0,
SetWifiPassword = 0x1,
SetWifiSSID = 0x2,
};
enum class LightControl : uint8_t {
On = 0x0,
Off = 0x1,
Toggle = 0x2,
Increase = 0x3,
Decrease = 0x4,
};
enum class Command : uint8_t {
RequestLightData = 0x0,
EnterConsoleFlashing = 0x1,
ExitConsoleFlashing = 0x2,
PairBluetooth = 0x3,
Help = 0x4,
Version = 0x5,
Reset = 0x6,
};
using Submode = etl::variant<Mode, Message, Settings, LightControl, Command>;
} // namespace protocol
} // namespace message

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#pragma once
#include <Arduino.h>
#include <etl/array.h>
namespace util {
template <typename T, size_t size> class CircularBuffer {
public:
T &peek() { return buffer[index]; }
/// @brief Warning: Does not deconstruct entry! If necessary use
/// etl::circular_buffer instead!
T &pop() {
index = (index + 1) % buffer.size();
return buffer[index];
}
private:
etl::array<T, size> buffer;
size_t index;
};
} // namespace util

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@ -1,109 +1,9 @@
#include <Arduino.h>
#include <LightController.h>
#include <SerialCommunicator.h>
#include <BluetoothCommunicator.h>
#include <WebsocketCommunicator.h>
#include <PinMap/PinMap.h>
#include <esp_spi_flash.h>
#include <WiFi.h>
#include <ESPAsyncWebServer.h>
#include <Credentials/CredentialManager.h>
const int STEPS = 5;
const int WIFI_TIMEOUT = 20;
const int bjtCount = 4;
const int bjtPin[bjtCount] = {SIG1A, SIG1B, SIG2A, SIG2B};
BluetoothSerial bt;
AsyncWebServer server(80);
AsyncWebSocket ws("/ws");
Communicator *computer;
Communicator *phone;
WebsocketCommunicator *websocket;
LightController *light;
void websocketTask(void *parameter)
{
while (true)
{
websocket->sendMessage(light->getBjtState(), light->getBjtCount());
vTaskDelay(100 / portTICK_PERIOD_MS);
}
vTaskDelete(NULL);
void setup() {
// put your setup code here, to run once:
}
void registerWebSocketTask()
{
xTaskCreate(websocketTask, "websocketTask", 10000, NULL, 1, NULL);
}
void connectWifi(int timeout)
{
int secondsPassed = 0;
WiFi.setHostname("Heliox");
WiFi.begin(WIFI_SSID, WIFI_PW);
Serial.print("Connecting to WiFi");
while (WiFi.status() != WL_CONNECTED)
{
if (secondsPassed < timeout)
{
Serial.print(".");
delay(1000);
secondsPassed++;
}
else
{
Serial.println("");
Serial.println("WiFi timed out");
return;
}
}
Serial.println("");
Serial.println(WiFi.localIP());
digitalWrite(LEDB, HIGH);
}
void setup()
{
pinMode(LEDB, OUTPUT);
digitalWrite(LEDB, LOW);
computer = new SerialCommunicator(Serial, 9600, 5, 50);
phone = new BluetoothCommunicator(bt, 5, 50);
light = new LightController(bjtPin, bjtCount);
websocket = new WebsocketCommunicator(ws, server, 50);
connectWifi(WIFI_TIMEOUT);
server.begin();
registerWebSocketTask();
}
void computerCycle()
{
light->updateState(computer->receiveMessage(), STEPS);
computer->sendMessage(light->getBjtState(), light->getBjtCount());
computer->clearBuffer();
}
void phoneCycle()
{
light->updateState(phone->receiveMessage(), STEPS);
phone->sendMessage(light->getBjtState(), light->getBjtCount());
phone->clearBuffer();
}
void websocketCycle()
{
light->updateState(websocket->receiveMessage(), STEPS);
websocket->clearBufferSafely();
}
void loop()
{
computerCycle();
phoneCycle();
websocketCycle();
ws.cleanupClients();
void loop() {
// put your main code here, to run repeatedly:
}

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@ -1,11 +1,11 @@
This directory is intended for PlatformIO Unit Testing and project tests.
Unit Testing is a software testing method by which individual units of
source code, sets of one or more MCU program modules together with associated
control data, usage procedures, and operating procedures, are tested to
determine whether they are fit for use. Unit testing finds problems early
in the development cycle.
More information about PlatformIO Unit Testing:
- https://docs.platformio.org/page/plus/unit-testing.html
This directory is intended for PlatformIO Test Runner and project tests.
Unit Testing is a software testing method by which individual units of
source code, sets of one or more MCU program modules together with associated
control data, usage procedures, and operating procedures, are tested to
determine whether they are fit for use. Unit testing finds problems early
in the development cycle.
More information about PlatformIO Unit Testing:
- https://docs.platformio.org/en/latest/advanced/unit-testing/index.html

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@ -0,0 +1,10 @@
import serial
import time
ser = serial.Serial(port='/dev/ttyUSB0', baudrate=115200)
ser.write(b'HX\x02\x02\x00')
time.sleep(1)
ser.write(b'HX\x02\x02\x01')
print(f"Listening for messages on {ser.name}:")
while True:
print(ser.readline())
ser.close()

48
modules/debugger/poetry.lock generated Normal file
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@ -0,0 +1,48 @@
# This file is automatically @generated by Poetry 1.4.0 and should not be changed by hand.
[[package]]
name = "autopep8"
version = "2.0.2"
description = "A tool that automatically formats Python code to conform to the PEP 8 style guide"
category = "dev"
optional = false
python-versions = ">=3.6"
files = [
{file = "autopep8-2.0.2-py2.py3-none-any.whl", hash = "sha256:86e9303b5e5c8160872b2f5ef611161b2893e9bfe8ccc7e2f76385947d57a2f1"},
{file = "autopep8-2.0.2.tar.gz", hash = "sha256:f9849cdd62108cb739dbcdbfb7fdcc9a30d1b63c4cc3e1c1f893b5360941b61c"},
]
[package.dependencies]
pycodestyle = ">=2.10.0"
[[package]]
name = "pycodestyle"
version = "2.10.0"
description = "Python style guide checker"
category = "dev"
optional = false
python-versions = ">=3.6"
files = [
{file = "pycodestyle-2.10.0-py2.py3-none-any.whl", hash = "sha256:8a4eaf0d0495c7395bdab3589ac2db602797d76207242c17d470186815706610"},
{file = "pycodestyle-2.10.0.tar.gz", hash = "sha256:347187bdb476329d98f695c213d7295a846d1152ff4fe9bacb8a9590b8ee7053"},
]
[[package]]
name = "pyserial"
version = "3.5"
description = "Python Serial Port Extension"
category = "main"
optional = false
python-versions = "*"
files = [
{file = "pyserial-3.5-py2.py3-none-any.whl", hash = "sha256:c4451db6ba391ca6ca299fb3ec7bae67a5c55dde170964c7a14ceefec02f2cf0"},
{file = "pyserial-3.5.tar.gz", hash = "sha256:3c77e014170dfffbd816e6ffc205e9842efb10be9f58ec16d3e8675b4925cddb"},
]
[package.extras]
cp2110 = ["hidapi"]
[metadata]
lock-version = "2.0"
python-versions = "^3.11"
content-hash = "e62c345d7dc7473afcf2d0b5bdf8471dec4b4834efc156b4cef53daeb59c89ff"

View file

@ -0,0 +1,18 @@
[tool.poetry]
name = "debugger"
version = "0.1.0"
description = ""
authors = ["GHOSCHT <31184695+GHOSCHT@users.noreply.github.com>"]
readme = "README.md"
[tool.poetry.dependencies]
python = "^3.11"
pyserial = "^3.5"
[tool.poetry.group.dev.dependencies]
autopep8 = "^2.0.2"
[build-system]
requires = ["poetry-core"]
build-backend = "poetry.core.masonry.api"