esphome/esphome/core/component.cpp
2023-10-03 09:25:13 +13:00

220 lines
8.2 KiB
C++

#include "esphome/core/component.h"
#include "esphome/core/application.h"
#include "esphome/core/hal.h"
#include "esphome/core/helpers.h"
#include "esphome/core/log.h"
#include <utility>
namespace esphome {
static const char *const TAG = "component";
namespace setup_priority {
const float BUS = 1000.0f;
const float IO = 900.0f;
const float HARDWARE = 800.0f;
const float DATA = 600.0f;
const float PROCESSOR = 400.0;
const float BLUETOOTH = 350.0f;
const float AFTER_BLUETOOTH = 300.0f;
const float WIFI = 250.0f;
const float ETHERNET = 250.0f;
const float BEFORE_CONNECTION = 220.0f;
const float AFTER_WIFI = 200.0f;
const float AFTER_CONNECTION = 100.0f;
const float LATE = -100.0f;
} // namespace setup_priority
const uint32_t COMPONENT_STATE_MASK = 0xFF;
const uint32_t COMPONENT_STATE_CONSTRUCTION = 0x00;
const uint32_t COMPONENT_STATE_SETUP = 0x01;
const uint32_t COMPONENT_STATE_LOOP = 0x02;
const uint32_t COMPONENT_STATE_FAILED = 0x03;
const uint32_t STATUS_LED_MASK = 0xFF00;
const uint32_t STATUS_LED_OK = 0x0000;
const uint32_t STATUS_LED_WARNING = 0x0100;
const uint32_t STATUS_LED_ERROR = 0x0200;
uint32_t global_state = 0; // NOLINT(cppcoreguidelines-avoid-non-const-global-variables)
float Component::get_loop_priority() const { return 0.0f; }
float Component::get_setup_priority() const { return setup_priority::DATA; }
void Component::setup() {}
void Component::loop() {}
void Component::set_interval(const std::string &name, uint32_t interval, std::function<void()> &&f) { // NOLINT
App.scheduler.set_interval(this, name, interval, std::move(f));
}
bool Component::cancel_interval(const std::string &name) { // NOLINT
return App.scheduler.cancel_interval(this, name);
}
void Component::set_retry(const std::string &name, uint32_t initial_wait_time, uint8_t max_attempts,
std::function<RetryResult(uint8_t)> &&f, float backoff_increase_factor) { // NOLINT
App.scheduler.set_retry(this, name, initial_wait_time, max_attempts, std::move(f), backoff_increase_factor);
}
bool Component::cancel_retry(const std::string &name) { // NOLINT
return App.scheduler.cancel_retry(this, name);
}
void Component::set_timeout(const std::string &name, uint32_t timeout, std::function<void()> &&f) { // NOLINT
return App.scheduler.set_timeout(this, name, timeout, std::move(f));
}
bool Component::cancel_timeout(const std::string &name) { // NOLINT
return App.scheduler.cancel_timeout(this, name);
}
void Component::call_loop() { this->loop(); }
void Component::call_setup() { this->setup(); }
void Component::call_dump_config() { this->dump_config(); }
uint32_t Component::get_component_state() const { return this->component_state_; }
void Component::call() {
uint32_t state = this->component_state_ & COMPONENT_STATE_MASK;
switch (state) {
case COMPONENT_STATE_CONSTRUCTION:
// State Construction: Call setup and set state to setup
this->component_state_ &= ~COMPONENT_STATE_MASK;
this->component_state_ |= COMPONENT_STATE_SETUP;
this->call_setup();
break;
case COMPONENT_STATE_SETUP:
// State setup: Call first loop and set state to loop
this->component_state_ &= ~COMPONENT_STATE_MASK;
this->component_state_ |= COMPONENT_STATE_LOOP;
this->call_loop();
break;
case COMPONENT_STATE_LOOP:
// State loop: Call loop
this->call_loop();
break;
case COMPONENT_STATE_FAILED: // NOLINT(bugprone-branch-clone)
// State failed: Do nothing
break;
default:
break;
}
}
const char *Component::get_component_source() const {
if (this->component_source_ == nullptr)
return "<unknown>";
return this->component_source_;
}
void Component::mark_failed() {
ESP_LOGE(TAG, "Component %s was marked as failed.", this->get_component_source());
this->component_state_ &= ~COMPONENT_STATE_MASK;
this->component_state_ |= COMPONENT_STATE_FAILED;
this->status_set_error();
}
void Component::defer(std::function<void()> &&f) { // NOLINT
App.scheduler.set_timeout(this, "", 0, std::move(f));
}
bool Component::cancel_defer(const std::string &name) { // NOLINT
return App.scheduler.cancel_timeout(this, name);
}
void Component::defer(const std::string &name, std::function<void()> &&f) { // NOLINT
App.scheduler.set_timeout(this, name, 0, std::move(f));
}
void Component::set_timeout(uint32_t timeout, std::function<void()> &&f) { // NOLINT
App.scheduler.set_timeout(this, "", timeout, std::move(f));
}
void Component::set_interval(uint32_t interval, std::function<void()> &&f) { // NOLINT
App.scheduler.set_interval(this, "", interval, std::move(f));
}
void Component::set_retry(uint32_t initial_wait_time, uint8_t max_attempts, std::function<RetryResult(uint8_t)> &&f,
float backoff_increase_factor) { // NOLINT
App.scheduler.set_retry(this, "", initial_wait_time, max_attempts, std::move(f), backoff_increase_factor);
}
bool Component::is_failed() { return (this->component_state_ & COMPONENT_STATE_MASK) == COMPONENT_STATE_FAILED; }
bool Component::is_ready() {
return (this->component_state_ & COMPONENT_STATE_MASK) == COMPONENT_STATE_LOOP ||
(this->component_state_ & COMPONENT_STATE_MASK) == COMPONENT_STATE_SETUP;
}
bool Component::can_proceed() { return true; }
bool Component::status_has_warning() { return this->component_state_ & STATUS_LED_WARNING; }
bool Component::status_has_error() { return this->component_state_ & STATUS_LED_ERROR; }
void Component::status_set_warning() {
this->component_state_ |= STATUS_LED_WARNING;
App.app_state_ |= STATUS_LED_WARNING;
}
void Component::status_set_error() {
this->component_state_ |= STATUS_LED_ERROR;
App.app_state_ |= STATUS_LED_ERROR;
}
void Component::status_clear_warning() { this->component_state_ &= ~STATUS_LED_WARNING; }
void Component::status_clear_error() { this->component_state_ &= ~STATUS_LED_ERROR; }
void Component::status_momentary_warning(const std::string &name, uint32_t length) {
this->status_set_warning();
this->set_timeout(name, length, [this]() { this->status_clear_warning(); });
}
void Component::status_momentary_error(const std::string &name, uint32_t length) {
this->status_set_error();
this->set_timeout(name, length, [this]() { this->status_clear_error(); });
}
void Component::dump_config() {}
float Component::get_actual_setup_priority() const {
if (std::isnan(this->setup_priority_override_))
return this->get_setup_priority();
return this->setup_priority_override_;
}
void Component::set_setup_priority(float priority) { this->setup_priority_override_ = priority; }
bool Component::has_overridden_loop() const {
#ifdef CLANG_TIDY
bool loop_overridden = true;
bool call_loop_overridden = true;
#else
#pragma GCC diagnostic push
#pragma GCC diagnostic ignored "-Wpmf-conversions"
bool loop_overridden = (void *) (this->*(&Component::loop)) != (void *) (&Component::loop);
bool call_loop_overridden = (void *) (this->*(&Component::call_loop)) != (void *) (&Component::call_loop);
#pragma GCC diagnostic pop
#endif
return loop_overridden || call_loop_overridden;
}
PollingComponent::PollingComponent(uint32_t update_interval) : update_interval_(update_interval) {}
void PollingComponent::call_setup() {
// Let the polling component subclass setup their HW.
this->setup();
// init the poller
this->start_poller();
}
void PollingComponent::start_poller() {
// Register interval.
this->set_interval("update", this->get_update_interval(), [this]() { this->update(); });
}
void PollingComponent::stop_poller() {
// Clear the interval to suspend component
this->cancel_interval("update");
}
uint32_t PollingComponent::get_update_interval() const { return this->update_interval_; }
void PollingComponent::set_update_interval(uint32_t update_interval) { this->update_interval_ = update_interval; }
WarnIfComponentBlockingGuard::WarnIfComponentBlockingGuard(Component *component)
: started_(millis()), component_(component) {}
WarnIfComponentBlockingGuard::~WarnIfComponentBlockingGuard() {
uint32_t now = millis();
if (now - started_ > 50) {
const char *src = component_ == nullptr ? "<null>" : component_->get_component_source();
ESP_LOGW(TAG, "Component %s took a long time for an operation (%.2f s).", src, (now - started_) / 1e3f);
ESP_LOGW(TAG, "Components should block for at most 20-30ms.");
;
}
}
} // namespace esphome