Merge pull request #4423 from esphome/bump-2023.2.0b4

2023.2.0b4
This commit is contained in:
Jesse Hills 2023-02-13 15:17:05 +13:00 committed by GitHub
commit 4899dfe642
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GPG key ID: 4AEE18F83AFDEB23
7 changed files with 227 additions and 18 deletions

2
.gitignore vendored
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@ -128,3 +128,5 @@ tests/.esphome/
sdkconfig.* sdkconfig.*
!sdkconfig.defaults !sdkconfig.defaults
.tests/

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@ -15,6 +15,84 @@ static const char *const TAG = "display";
const Color COLOR_OFF(0, 0, 0, 0); const Color COLOR_OFF(0, 0, 0, 0);
const Color COLOR_ON(255, 255, 255, 255); const Color COLOR_ON(255, 255, 255, 255);
void Rect::expand(int16_t horizontal, int16_t vertical) {
if (this->is_set() && (this->w >= (-2 * horizontal)) && (this->h >= (-2 * vertical))) {
this->x = this->x - horizontal;
this->y = this->y - vertical;
this->w = this->w + (2 * horizontal);
this->h = this->h + (2 * vertical);
}
}
void Rect::extend(Rect rect) {
if (!this->is_set()) {
this->x = rect.x;
this->y = rect.y;
this->w = rect.w;
this->h = rect.h;
} else {
if (this->x > rect.x) {
this->x = rect.x;
}
if (this->y > rect.y) {
this->y = rect.y;
}
if (this->x2() < rect.x2()) {
this->w = rect.x2() - this->x;
}
if (this->y2() < rect.y2()) {
this->h = rect.y2() - this->y;
}
}
}
void Rect::shrink(Rect rect) {
if (!this->inside(rect)) {
(*this) = Rect();
} else {
if (this->x < rect.x) {
this->x = rect.x;
}
if (this->y < rect.y) {
this->y = rect.y;
}
if (this->x2() > rect.x2()) {
this->w = rect.x2() - this->x;
}
if (this->y2() > rect.y2()) {
this->h = rect.y2() - this->y;
}
}
}
bool Rect::inside(int16_t x, int16_t y, bool absolute) { // NOLINT
if (!this->is_set()) {
return true;
}
if (absolute) {
return ((x >= 0) && (x <= this->w) && (y >= 0) && (y <= this->h));
} else {
return ((x >= this->x) && (x <= this->x2()) && (y >= this->y) && (y <= this->y2()));
}
}
bool Rect::inside(Rect rect, bool absolute) {
if (!this->is_set() || !rect.is_set()) {
return true;
}
if (absolute) {
return ((rect.x <= this->w) && (rect.w >= 0) && (rect.y <= this->h) && (rect.h >= 0));
} else {
return ((rect.x <= this->x2()) && (rect.x2() >= this->x) && (rect.y <= this->y2()) && (rect.y2() >= this->y));
}
}
void Rect::info(const std::string &prefix) {
if (this->is_set()) {
ESP_LOGI(TAG, "%s [%3d,%3d,%3d,%3d]", prefix.c_str(), this->x, this->y, this->w, this->h);
} else
ESP_LOGI(TAG, "%s ** IS NOT SET **", prefix.c_str());
}
void DisplayBuffer::init_internal_(uint32_t buffer_length) { void DisplayBuffer::init_internal_(uint32_t buffer_length) {
ExternalRAMAllocator<uint8_t> allocator(ExternalRAMAllocator<uint8_t>::ALLOW_FAILURE); ExternalRAMAllocator<uint8_t> allocator(ExternalRAMAllocator<uint8_t>::ALLOW_FAILURE);
this->buffer_ = allocator.allocate(buffer_length); this->buffer_ = allocator.allocate(buffer_length);
@ -24,6 +102,7 @@ void DisplayBuffer::init_internal_(uint32_t buffer_length) {
} }
this->clear(); this->clear();
} }
void DisplayBuffer::fill(Color color) { this->filled_rectangle(0, 0, this->get_width(), this->get_height(), color); } void DisplayBuffer::fill(Color color) { this->filled_rectangle(0, 0, this->get_width(), this->get_height(), color); }
void DisplayBuffer::clear() { this->fill(COLOR_OFF); } void DisplayBuffer::clear() { this->fill(COLOR_OFF); }
int DisplayBuffer::get_width() { int DisplayBuffer::get_width() {
@ -50,6 +129,9 @@ int DisplayBuffer::get_height() {
} }
void DisplayBuffer::set_rotation(DisplayRotation rotation) { this->rotation_ = rotation; } void DisplayBuffer::set_rotation(DisplayRotation rotation) { this->rotation_ = rotation; }
void HOT DisplayBuffer::draw_pixel_at(int x, int y, Color color) { void HOT DisplayBuffer::draw_pixel_at(int x, int y, Color color) {
if (!this->get_clipping().inside(x, y))
return; // NOLINT
switch (this->rotation_) { switch (this->rotation_) {
case DISPLAY_ROTATION_0_DEGREES: case DISPLAY_ROTATION_0_DEGREES:
break; break;
@ -368,6 +450,10 @@ void DisplayBuffer::do_update_() {
} else if (this->writer_.has_value()) { } else if (this->writer_.has_value()) {
(*this->writer_)(*this); (*this->writer_)(*this);
} }
// remove all not ended clipping regions
while (is_clipping()) {
end_clipping();
}
} }
void DisplayOnPageChangeTrigger::process(DisplayPage *from, DisplayPage *to) { void DisplayOnPageChangeTrigger::process(DisplayPage *from, DisplayPage *to) {
if ((this->from_ == nullptr || this->from_ == from) && (this->to_ == nullptr || this->to_ == to)) if ((this->from_ == nullptr || this->from_ == from) && (this->to_ == nullptr || this->to_ == to))
@ -392,6 +478,41 @@ void DisplayBuffer::strftime(int x, int y, Font *font, const char *format, time:
} }
#endif #endif
void DisplayBuffer::start_clipping(Rect rect) {
if (!this->clipping_rectangle_.empty()) {
Rect r = this->clipping_rectangle_.back();
rect.shrink(r);
}
this->clipping_rectangle_.push_back(rect);
}
void DisplayBuffer::end_clipping() {
if (this->clipping_rectangle_.empty()) {
ESP_LOGE(TAG, "clear: Clipping is not set.");
} else {
this->clipping_rectangle_.pop_back();
}
}
void DisplayBuffer::extend_clipping(Rect add_rect) {
if (this->clipping_rectangle_.empty()) {
ESP_LOGE(TAG, "add: Clipping is not set.");
} else {
this->clipping_rectangle_.back().extend(add_rect);
}
}
void DisplayBuffer::shrink_clipping(Rect add_rect) {
if (this->clipping_rectangle_.empty()) {
ESP_LOGE(TAG, "add: Clipping is not set.");
} else {
this->clipping_rectangle_.back().shrink(add_rect);
}
}
Rect DisplayBuffer::get_clipping() {
if (this->clipping_rectangle_.empty()) {
return Rect();
} else {
return this->clipping_rectangle_.back();
}
}
bool Glyph::get_pixel(int x, int y) const { bool Glyph::get_pixel(int x, int y) const {
const int x_data = x - this->glyph_data_->offset_x; const int x_data = x - this->glyph_data_->offset_x;
const int y_data = y - this->glyph_data_->offset_y; const int y_data = y - this->glyph_data_->offset_y;

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@ -4,7 +4,6 @@
#include "esphome/core/defines.h" #include "esphome/core/defines.h"
#include "esphome/core/automation.h" #include "esphome/core/automation.h"
#include "display_color_utils.h" #include "display_color_utils.h"
#include <cstdarg> #include <cstdarg>
#include <vector> #include <vector>
@ -100,6 +99,32 @@ enum DisplayRotation {
DISPLAY_ROTATION_270_DEGREES = 270, DISPLAY_ROTATION_270_DEGREES = 270,
}; };
static const int16_t VALUE_NO_SET = 32766;
class Rect {
public:
int16_t x; ///< X coordinate of corner
int16_t y; ///< Y coordinate of corner
int16_t w; ///< Width of region
int16_t h; ///< Height of region
Rect() : x(VALUE_NO_SET), y(VALUE_NO_SET), w(VALUE_NO_SET), h(VALUE_NO_SET) {} // NOLINT
inline Rect(int16_t x, int16_t y, int16_t w, int16_t h) ALWAYS_INLINE : x(x), y(y), w(w), h(h) {}
inline int16_t x2() { return this->x + this->w; }; ///< X coordinate of corner
inline int16_t y2() { return this->y + this->h; }; ///< Y coordinate of corner
inline bool is_set() ALWAYS_INLINE { return (this->h != VALUE_NO_SET) && (this->w != VALUE_NO_SET); }
void expand(int16_t horizontal, int16_t vertical);
void extend(Rect rect);
void shrink(Rect rect);
bool inside(Rect rect, bool absolute = false);
bool inside(int16_t x, int16_t y, bool absolute = false);
void info(const std::string &prefix = "rect info:");
};
class Font; class Font;
class Image; class Image;
class DisplayBuffer; class DisplayBuffer;
@ -126,6 +151,7 @@ class DisplayBuffer {
int get_width(); int get_width();
/// Get the height of the image in pixels with rotation applied. /// Get the height of the image in pixels with rotation applied.
int get_height(); int get_height();
/// Set a single pixel at the specified coordinates to the given color. /// Set a single pixel at the specified coordinates to the given color.
void draw_pixel_at(int x, int y, Color color = COLOR_ON); void draw_pixel_at(int x, int y, Color color = COLOR_ON);
@ -374,6 +400,49 @@ class DisplayBuffer {
*/ */
virtual DisplayType get_display_type() = 0; virtual DisplayType get_display_type() = 0;
/** Set the clipping rectangle for further drawing
*
* @param[in] rect: Pointer to Rect for clipping (or NULL for entire screen)
*
* return true if success, false if error
*/
void start_clipping(Rect rect);
void start_clipping(int16_t left, int16_t top, int16_t right, int16_t bottom) {
start_clipping(Rect(left, top, right - left, bottom - top));
};
/** Add a rectangular region to the invalidation region
* - This is usually called when an element has been modified
*
* @param[in] rect: Rectangle to add to the invalidation region
*/
void extend_clipping(Rect rect);
void extend_clipping(int16_t left, int16_t top, int16_t right, int16_t bottom) {
this->extend_clipping(Rect(left, top, right - left, bottom - top));
};
/** substract a rectangular region to the invalidation region
* - This is usually called when an element has been modified
*
* @param[in] rect: Rectangle to add to the invalidation region
*/
void shrink_clipping(Rect rect);
void shrink_clipping(uint16_t left, uint16_t top, uint16_t right, uint16_t bottom) {
this->shrink_clipping(Rect(left, top, right - left, bottom - top));
};
/** Reset the invalidation region
*/
void end_clipping();
/** Get the current the clipping rectangle
*
* return rect for active clipping region
*/
Rect get_clipping();
bool is_clipping() const { return !this->clipping_rectangle_.empty(); }
protected: protected:
void vprintf_(int x, int y, Font *font, Color color, TextAlign align, const char *format, va_list arg); void vprintf_(int x, int y, Font *font, Color color, TextAlign align, const char *format, va_list arg);
@ -390,6 +459,7 @@ class DisplayBuffer {
DisplayPage *previous_page_{nullptr}; DisplayPage *previous_page_{nullptr};
std::vector<DisplayOnPageChangeTrigger *> on_page_change_triggers_; std::vector<DisplayOnPageChangeTrigger *> on_page_change_triggers_;
bool auto_clear_enabled_{true}; bool auto_clear_enabled_{true};
std::vector<Rect> clipping_rectangle_;
}; };
class DisplayPage { class DisplayPage {

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@ -1,6 +1,10 @@
#include "pid_autotuner.h" #include "pid_autotuner.h"
#include "esphome/core/log.h" #include "esphome/core/log.h"
#ifndef M_PI
#define M_PI 3.1415926535897932384626433
#endif
namespace esphome { namespace esphome {
namespace pid { namespace pid {
@ -73,7 +77,7 @@ PIDAutotuner::PIDAutotuneResult PIDAutotuner::update(float setpoint, float proce
} }
if (!std::isnan(this->setpoint_) && this->setpoint_ != setpoint) { if (!std::isnan(this->setpoint_) && this->setpoint_ != setpoint) {
ESP_LOGW(TAG, "Setpoint changed during autotune! The result will not be accurate!"); ESP_LOGW(TAG, "%s: Setpoint changed during autotune! The result will not be accurate!", this->id_.c_str());
} }
this->setpoint_ = setpoint; this->setpoint_ = setpoint;
@ -87,7 +91,7 @@ PIDAutotuner::PIDAutotuneResult PIDAutotuner::update(float setpoint, float proce
if (!this->frequency_detector_.has_enough_data() || !this->amplitude_detector_.has_enough_data()) { if (!this->frequency_detector_.has_enough_data() || !this->amplitude_detector_.has_enough_data()) {
// not enough data for calculation yet // not enough data for calculation yet
ESP_LOGV(TAG, " Not enough data yet for aututuner"); ESP_LOGV(TAG, "%s: Not enough data yet for autotuner", this->id_.c_str());
return res; return res;
} }
@ -97,12 +101,13 @@ PIDAutotuner::PIDAutotuneResult PIDAutotuner::update(float setpoint, float proce
// The frequency/amplitude is not fully accurate yet, try to wait // The frequency/amplitude is not fully accurate yet, try to wait
// until the fault clears, or terminate after a while anyway // until the fault clears, or terminate after a while anyway
if (zc_symmetrical) { if (zc_symmetrical) {
ESP_LOGVV(TAG, " ZC is not symmetrical"); ESP_LOGVV(TAG, "%s: ZC is not symmetrical", this->id_.c_str());
} }
if (amplitude_convergent) { if (amplitude_convergent) {
ESP_LOGVV(TAG, " Amplitude is not convergent"); ESP_LOGVV(TAG, "%s: Amplitude is not convergent", this->id_.c_str());
} }
uint32_t phase = this->relay_function_.phase_count; uint32_t phase = this->relay_function_.phase_count;
ESP_LOGVV(TAG, "%s: >", this->id_.c_str());
ESP_LOGVV(TAG, " Phase %u, enough=%u", phase, enough_data_phase_); ESP_LOGVV(TAG, " Phase %u, enough=%u", phase, enough_data_phase_);
if (this->enough_data_phase_ == 0) { if (this->enough_data_phase_ == 0) {
@ -116,7 +121,7 @@ PIDAutotuner::PIDAutotuneResult PIDAutotuner::update(float setpoint, float proce
} }
} }
ESP_LOGI(TAG, "PID Autotune finished!"); ESP_LOGI(TAG, "%s: PID Autotune finished!", this->id_.c_str());
float osc_ampl = this->amplitude_detector_.get_mean_oscillation_amplitude(); float osc_ampl = this->amplitude_detector_.get_mean_oscillation_amplitude();
float d = (this->relay_function_.output_positive - this->relay_function_.output_negative) / 2.0f; float d = (this->relay_function_.output_positive - this->relay_function_.output_negative) / 2.0f;
@ -131,12 +136,12 @@ PIDAutotuner::PIDAutotuneResult PIDAutotuner::update(float setpoint, float proce
return res; return res;
} }
void PIDAutotuner::dump_config() { void PIDAutotuner::dump_config() {
ESP_LOGI(TAG, "PID Autotune:");
if (this->state_ == AUTOTUNE_SUCCEEDED) { if (this->state_ == AUTOTUNE_SUCCEEDED) {
ESP_LOGI(TAG, "%s: PID Autotune:", this->id_.c_str());
ESP_LOGI(TAG, " State: Succeeded!"); ESP_LOGI(TAG, " State: Succeeded!");
bool has_issue = false; bool has_issue = false;
if (!this->amplitude_detector_.is_amplitude_convergent()) { if (!this->amplitude_detector_.is_amplitude_convergent()) {
ESP_LOGW(TAG, " Could not reliable determine oscillation amplitude, PID parameters may be inaccurate!"); ESP_LOGW(TAG, " Could not reliably determine oscillation amplitude, PID parameters may be inaccurate!");
ESP_LOGW(TAG, " Please make sure you eliminate all outside influences on the measured temperature."); ESP_LOGW(TAG, " Please make sure you eliminate all outside influences on the measured temperature.");
has_issue = true; has_issue = true;
} }
@ -173,10 +178,12 @@ void PIDAutotuner::dump_config() {
print_rule_("Pessen Integral PID", 0.7f, 1.75f, 0.105f); print_rule_("Pessen Integral PID", 0.7f, 1.75f, 0.105f);
print_rule_("Some Overshoot PID", 0.333f, 0.667f, 0.111f); print_rule_("Some Overshoot PID", 0.333f, 0.667f, 0.111f);
print_rule_("No Overshoot PID", 0.2f, 0.4f, 0.0625f); print_rule_("No Overshoot PID", 0.2f, 0.4f, 0.0625f);
ESP_LOGI(TAG, "%s: Autotune completed", this->id_.c_str());
} }
if (this->state_ == AUTOTUNE_RUNNING) { if (this->state_ == AUTOTUNE_RUNNING) {
ESP_LOGI(TAG, " Autotune is still running!"); ESP_LOGD(TAG, "%s: PID Autotune:", this->id_.c_str());
ESP_LOGD(TAG, " Autotune is still running!");
ESP_LOGD(TAG, " Status: Trying to reach %.2f °C", setpoint_ - relay_function_.current_target_error()); ESP_LOGD(TAG, " Status: Trying to reach %.2f °C", setpoint_ - relay_function_.current_target_error());
ESP_LOGD(TAG, " Stats so far:"); ESP_LOGD(TAG, " Stats so far:");
ESP_LOGD(TAG, " Phases: %u", relay_function_.phase_count); ESP_LOGD(TAG, " Phases: %u", relay_function_.phase_count);
@ -221,7 +228,6 @@ float PIDAutotuner::RelayFunction::update(float error) {
float output = state == RELAY_FUNCTION_POSITIVE ? output_positive : output_negative; float output = state == RELAY_FUNCTION_POSITIVE ? output_positive : output_negative;
if (change) { if (change) {
this->phase_count++; this->phase_count++;
ESP_LOGV(TAG, "Autotune: Turning output to %.1f%%", output * 100);
} }
return output; return output;
@ -245,10 +251,8 @@ void PIDAutotuner::OscillationFrequencyDetector::update(uint32_t now, float erro
if (had_crossing) { if (had_crossing) {
// Had crossing above hysteresis threshold, record // Had crossing above hysteresis threshold, record
ESP_LOGV(TAG, "Autotune: Detected Zero-Cross at %u", now);
if (this->last_zerocross != 0) { if (this->last_zerocross != 0) {
uint32_t dt = now - this->last_zerocross; uint32_t dt = now - this->last_zerocross;
ESP_LOGV(TAG, " dt: %u", dt);
this->zerocrossing_intervals.push_back(dt); this->zerocrossing_intervals.push_back(dt);
} }
this->last_zerocross = now; this->last_zerocross = now;
@ -297,13 +301,11 @@ void PIDAutotuner::OscillationAmplitudeDetector::update(float error,
// The positive error peak must have been in previous segment (180° shifted) // The positive error peak must have been in previous segment (180° shifted)
// record phase_max // record phase_max
this->phase_maxs.push_back(phase_max); this->phase_maxs.push_back(phase_max);
ESP_LOGV(TAG, "Autotune: Phase Max: %f", phase_max);
} else if (last_relay_state == RelayFunction::RELAY_FUNCTION_NEGATIVE) { } else if (last_relay_state == RelayFunction::RELAY_FUNCTION_NEGATIVE) {
// Transitioned from negative error to positive error. // Transitioned from negative error to positive error.
// The negative error peak must have been in previous segment (180° shifted) // The negative error peak must have been in previous segment (180° shifted)
// record phase_min // record phase_min
this->phase_mins.push_back(phase_min); this->phase_mins.push_back(phase_min);
ESP_LOGV(TAG, "Autotune: Phase Min: %f", phase_min);
} }
// reset phase values for next phase // reset phase values for next phase
this->phase_min = error; this->phase_min = error;

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@ -31,6 +31,8 @@ class PIDAutotuner {
void dump_config(); void dump_config();
void set_autotuner_id(std::string id) { this->id_ = std::move(id); }
void set_noiseband(float noiseband) { void set_noiseband(float noiseband) {
relay_function_.noiseband = noiseband; relay_function_.noiseband = noiseband;
// ZC detector uses 1/4 the noiseband of relay function (noise suppression) // ZC detector uses 1/4 the noiseband of relay function (noise suppression)
@ -106,6 +108,7 @@ class PIDAutotuner {
} state_ = AUTOTUNE_RUNNING; } state_ = AUTOTUNE_RUNNING;
float ku_; float ku_;
float pu_; float pu_;
std::string id_;
}; };
} // namespace pid } // namespace pid

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@ -130,9 +130,6 @@ void PIDClimate::update_pid_() {
// keep autotuner instance so that subsequent dump_configs will print the long result message. // keep autotuner instance so that subsequent dump_configs will print the long result message.
} else { } else {
value = res.output; value = res.output;
if (mode != climate::CLIMATE_MODE_HEAT_COOL) {
ESP_LOGW(TAG, "For PID autotuner you need to set AUTO (also called heat/cool) mode!");
}
} }
} }
} }
@ -151,10 +148,24 @@ void PIDClimate::start_autotune(std::unique_ptr<PIDAutotuner> &&autotune) {
float min_value = this->supports_cool_() ? -1.0f : 0.0f; float min_value = this->supports_cool_() ? -1.0f : 0.0f;
float max_value = this->supports_heat_() ? 1.0f : 0.0f; float max_value = this->supports_heat_() ? 1.0f : 0.0f;
this->autotuner_->config(min_value, max_value); this->autotuner_->config(min_value, max_value);
this->autotuner_->set_autotuner_id(this->get_object_id());
ESP_LOGI(TAG,
"%s: Autotune has started. This can take a long time depending on the "
"responsiveness of your system. Your system "
"output will be altered to deliberately oscillate above and below the setpoint multiple times. "
"Until your sensor provides a reading, the autotuner may display \'nan\'",
this->get_object_id().c_str());
this->set_interval("autotune-progress", 10000, [this]() { this->set_interval("autotune-progress", 10000, [this]() {
if (this->autotuner_ != nullptr && !this->autotuner_->is_finished()) if (this->autotuner_ != nullptr && !this->autotuner_->is_finished())
this->autotuner_->dump_config(); this->autotuner_->dump_config();
}); });
if (mode != climate::CLIMATE_MODE_HEAT_COOL) {
ESP_LOGW(TAG, "%s: !!! For PID autotuner you need to set AUTO (also called heat/cool) mode!",
this->get_object_id().c_str());
}
} }
void PIDClimate::reset_integral_term() { this->controller_.reset_accumulated_integral(); } void PIDClimate::reset_integral_term() { this->controller_.reset_accumulated_integral(); }

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@ -1,6 +1,6 @@
"""Constants used by esphome.""" """Constants used by esphome."""
__version__ = "2023.2.0b3" __version__ = "2023.2.0b4"
ALLOWED_NAME_CHARS = "abcdefghijklmnopqrstuvwxyz0123456789-_" ALLOWED_NAME_CHARS = "abcdefghijklmnopqrstuvwxyz0123456789-_"