esphome/esphome/components/remote_base/remote_base.h
2022-01-23 20:34:43 +13:00

372 lines
10 KiB
C++

#include <utility>
#pragma once
#include "esphome/core/component.h"
#include "esphome/core/hal.h"
#include "esphome/core/automation.h"
#include "esphome/components/binary_sensor/binary_sensor.h"
#ifdef USE_ESP32
#include <driver/rmt.h>
#endif
namespace esphome {
namespace remote_base {
class RemoteTransmitData {
public:
void mark(uint32_t length) { this->data_.push_back(length); }
void space(uint32_t length) { this->data_.push_back(-length); }
void item(uint32_t mark, uint32_t space) {
this->mark(mark);
this->space(space);
}
void reserve(uint32_t len) { this->data_.reserve(len); }
void set_carrier_frequency(uint32_t carrier_frequency) { this->carrier_frequency_ = carrier_frequency; }
uint32_t get_carrier_frequency() const { return this->carrier_frequency_; }
const std::vector<int32_t> &get_data() const { return this->data_; }
void set_data(const std::vector<int32_t> &data) {
this->data_.clear();
this->data_.reserve(data.size());
for (auto dat : data)
this->data_.push_back(dat);
}
void reset() {
this->data_.clear();
this->carrier_frequency_ = 0;
}
std::vector<int32_t>::iterator begin() { return this->data_.begin(); }
std::vector<int32_t>::iterator end() { return this->data_.end(); }
protected:
std::vector<int32_t> data_{};
uint32_t carrier_frequency_{0};
};
class RemoteReceiveData {
public:
RemoteReceiveData(std::vector<int32_t> *data, uint8_t tolerance) : data_(data), tolerance_(tolerance) {}
bool peek_mark(uint32_t length, uint32_t offset = 0) {
if (int32_t(this->index_ + offset) >= this->size())
return false;
int32_t value = this->peek(offset);
const int32_t lo = this->lower_bound_(length);
const int32_t hi = this->upper_bound_(length);
return value >= 0 && lo <= value && value <= hi;
}
bool peek_space(uint32_t length, uint32_t offset = 0) {
if (int32_t(this->index_ + offset) >= this->size())
return false;
int32_t value = this->peek(offset);
const int32_t lo = this->lower_bound_(length);
const int32_t hi = this->upper_bound_(length);
return value <= 0 && lo <= -value && -value <= hi;
}
bool peek_space_at_least(uint32_t length, uint32_t offset = 0) {
if (int32_t(this->index_ + offset) >= this->size())
return false;
int32_t value = this->pos(this->index_ + offset);
const int32_t lo = this->lower_bound_(length);
return value <= 0 && lo <= -value;
}
bool peek_item(uint32_t mark, uint32_t space, uint32_t offset = 0) {
return this->peek_mark(mark, offset) && this->peek_space(space, offset + 1);
}
int32_t peek(uint32_t offset = 0) { return (*this)[this->index_ + offset]; }
void advance(uint32_t amount = 1) { this->index_ += amount; }
bool expect_mark(uint32_t length) {
if (this->peek_mark(length)) {
this->advance();
return true;
}
return false;
}
bool expect_space(uint32_t length) {
if (this->peek_space(length)) {
this->advance();
return true;
}
return false;
}
bool expect_item(uint32_t mark, uint32_t space) {
if (this->peek_item(mark, space)) {
this->advance(2);
return true;
}
return false;
}
bool expect_pulse_with_gap(uint32_t mark, uint32_t space) {
if (this->peek_mark(mark, 0) && this->peek_space_at_least(space, 1)) {
this->advance(2);
return true;
}
return false;
}
uint32_t get_index() { return index_; }
void reset() { this->index_ = 0; }
int32_t pos(uint32_t index) const { return (*this->data_)[index]; }
int32_t operator[](uint32_t index) const { return this->pos(index); }
int32_t size() const { return this->data_->size(); }
std::vector<int32_t> *get_raw_data() { return this->data_; }
protected:
int32_t lower_bound_(uint32_t length) { return int32_t(100 - this->tolerance_) * length / 100U; }
int32_t upper_bound_(uint32_t length) { return int32_t(100 + this->tolerance_) * length / 100U; }
uint32_t index_{0};
std::vector<int32_t> *data_;
uint8_t tolerance_;
};
template<typename T> class RemoteProtocol {
public:
virtual void encode(RemoteTransmitData *dst, const T &data) = 0;
virtual optional<T> decode(RemoteReceiveData src) = 0;
virtual void dump(const T &data) = 0;
};
class RemoteComponentBase {
public:
explicit RemoteComponentBase(InternalGPIOPin *pin) : pin_(pin){};
protected:
InternalGPIOPin *pin_;
};
#ifdef USE_ESP32
class RemoteRMTChannel {
public:
explicit RemoteRMTChannel(uint8_t mem_block_num = 1);
void config_rmt(rmt_config_t &rmt);
void set_clock_divider(uint8_t clock_divider) { this->clock_divider_ = clock_divider; }
protected:
uint32_t from_microseconds_(uint32_t us) {
const uint32_t ticks_per_ten_us = 80000000u / this->clock_divider_ / 100000u;
return us * ticks_per_ten_us / 10;
}
uint32_t to_microseconds_(uint32_t ticks) {
const uint32_t ticks_per_ten_us = 80000000u / this->clock_divider_ / 100000u;
return (ticks * 10) / ticks_per_ten_us;
}
RemoteComponentBase *remote_base_;
rmt_channel_t channel_{RMT_CHANNEL_0};
uint8_t mem_block_num_;
uint8_t clock_divider_{80};
};
#endif
class RemoteTransmitterBase : public RemoteComponentBase {
public:
RemoteTransmitterBase(InternalGPIOPin *pin) : RemoteComponentBase(pin) {}
class TransmitCall {
public:
explicit TransmitCall(RemoteTransmitterBase *parent) : parent_(parent) {}
RemoteTransmitData *get_data() { return &this->parent_->temp_; }
void set_send_times(uint32_t send_times) { send_times_ = send_times; }
void set_send_wait(uint32_t send_wait) { send_wait_ = send_wait; }
void perform() { this->parent_->send_(this->send_times_, this->send_wait_); }
protected:
RemoteTransmitterBase *parent_;
uint32_t send_times_{1};
uint32_t send_wait_{0};
};
TransmitCall transmit() {
this->temp_.reset();
return TransmitCall(this);
}
protected:
void send_(uint32_t send_times, uint32_t send_wait);
virtual void send_internal(uint32_t send_times, uint32_t send_wait) = 0;
void send_single_() { this->send_(1, 0); }
/// Use same vector for all transmits, avoids many allocations
RemoteTransmitData temp_;
};
class RemoteReceiverListener {
public:
virtual bool on_receive(RemoteReceiveData data) = 0;
};
class RemoteReceiverDumperBase {
public:
virtual bool dump(RemoteReceiveData src) = 0;
virtual bool is_secondary() { return false; }
};
class RemoteReceiverBase : public RemoteComponentBase {
public:
RemoteReceiverBase(InternalGPIOPin *pin) : RemoteComponentBase(pin) {}
void register_listener(RemoteReceiverListener *listener) { this->listeners_.push_back(listener); }
void register_dumper(RemoteReceiverDumperBase *dumper) {
if (dumper->is_secondary()) {
this->secondary_dumpers_.push_back(dumper);
} else {
this->dumpers_.push_back(dumper);
}
}
void set_tolerance(uint8_t tolerance) { tolerance_ = tolerance; }
protected:
bool call_listeners_() {
bool success = false;
for (auto *listener : this->listeners_) {
auto data = RemoteReceiveData(&this->temp_, this->tolerance_);
if (listener->on_receive(data))
success = true;
}
return success;
}
void call_dumpers_() {
bool success = false;
for (auto *dumper : this->dumpers_) {
auto data = RemoteReceiveData(&this->temp_, this->tolerance_);
if (dumper->dump(data))
success = true;
}
if (!success) {
for (auto *dumper : this->secondary_dumpers_) {
auto data = RemoteReceiveData(&this->temp_, this->tolerance_);
dumper->dump(data);
}
}
}
void call_listeners_dumpers_() {
if (this->call_listeners_())
return;
// If a listener handled, then do not dump
this->call_dumpers_();
}
std::vector<RemoteReceiverListener *> listeners_;
std::vector<RemoteReceiverDumperBase *> dumpers_;
std::vector<RemoteReceiverDumperBase *> secondary_dumpers_;
std::vector<int32_t> temp_;
uint8_t tolerance_{25};
};
class RemoteReceiverBinarySensorBase : public binary_sensor::BinarySensorInitiallyOff,
public Component,
public RemoteReceiverListener {
public:
explicit RemoteReceiverBinarySensorBase() {}
void dump_config() override;
virtual bool matches(RemoteReceiveData src) = 0;
bool on_receive(RemoteReceiveData src) override {
if (this->matches(src)) {
this->publish_state(true);
yield();
this->publish_state(false);
return true;
}
return false;
}
};
template<typename T, typename D> class RemoteReceiverBinarySensor : public RemoteReceiverBinarySensorBase {
public:
RemoteReceiverBinarySensor() : RemoteReceiverBinarySensorBase() {}
protected:
bool matches(RemoteReceiveData src) override {
auto proto = T();
auto res = proto.decode(src);
return res.has_value() && *res == this->data_;
}
public:
void set_data(D data) { data_ = data; }
protected:
D data_;
};
template<typename T, typename D> class RemoteReceiverTrigger : public Trigger<D>, public RemoteReceiverListener {
protected:
bool on_receive(RemoteReceiveData src) override {
auto proto = T();
auto res = proto.decode(src);
if (res.has_value()) {
this->trigger(*res);
return true;
}
return false;
}
};
template<typename... Ts> class RemoteTransmitterActionBase : public Action<Ts...> {
public:
void set_parent(RemoteTransmitterBase *parent) { this->parent_ = parent; }
TEMPLATABLE_VALUE(uint32_t, send_times);
TEMPLATABLE_VALUE(uint32_t, send_wait);
void play(Ts... x) override {
auto call = this->parent_->transmit();
this->encode(call.get_data(), x...);
call.set_send_times(this->send_times_.value_or(x..., 1));
call.set_send_wait(this->send_wait_.value_or(x..., 0));
call.perform();
}
protected:
virtual void encode(RemoteTransmitData *dst, Ts... x) = 0;
RemoteTransmitterBase *parent_{};
};
template<typename T, typename D> class RemoteReceiverDumper : public RemoteReceiverDumperBase {
public:
bool dump(RemoteReceiveData src) override {
auto proto = T();
auto decoded = proto.decode(src);
if (!decoded.has_value())
return false;
proto.dump(*decoded);
return true;
}
};
#define DECLARE_REMOTE_PROTOCOL_(prefix) \
using prefix##BinarySensor = RemoteReceiverBinarySensor<prefix##Protocol, prefix##Data>; \
using prefix##Trigger = RemoteReceiverTrigger<prefix##Protocol, prefix##Data>; \
using prefix##Dumper = RemoteReceiverDumper<prefix##Protocol, prefix##Data>;
#define DECLARE_REMOTE_PROTOCOL(prefix) DECLARE_REMOTE_PROTOCOL_(prefix)
} // namespace remote_base
} // namespace esphome