esphome/esphome/components/graph/graph.cpp
2021-12-02 09:03:51 +13:00

362 lines
11 KiB
C++

#include "graph.h"
#include "esphome/components/display/display_buffer.h"
#include "esphome/core/color.h"
#include "esphome/core/log.h"
#include "esphome/core/hal.h"
#include <algorithm>
#include <sstream>
#include <iostream> // std::cout, std::fixed
#include <iomanip>
namespace esphome {
namespace graph {
using namespace display;
static const char *const TAG = "graph";
static const char *const TAGL = "graphlegend";
void HistoryData::init(int length) {
this->length_ = length;
this->samples_.resize(length, NAN);
this->last_sample_ = millis();
}
void HistoryData::take_sample(float data) {
uint32_t tm = millis();
uint32_t dt = tm - last_sample_;
last_sample_ = tm;
// Step data based on time
this->period_ += dt;
while (this->period_ >= this->update_time_) {
this->samples_[this->count_] = data;
this->period_ -= this->update_time_;
this->count_ = (this->count_ + 1) % this->length_;
ESP_LOGV(TAG, "Updating trace with value: %f", data);
}
if (!std::isnan(data)) {
// Recalc recent max/min
this->recent_min_ = data;
this->recent_max_ = data;
for (int i = 0; i < this->length_; i++) {
if (!std::isnan(this->samples_[i])) {
if (this->recent_max_ < this->samples_[i])
this->recent_max_ = this->samples_[i];
if (this->recent_min_ > this->samples_[i])
this->recent_min_ = this->samples_[i];
}
}
}
}
void GraphTrace::init(Graph *g) {
ESP_LOGI(TAG, "Init trace for sensor %s", this->get_name().c_str());
this->data_.init(g->get_width());
sensor_->add_on_state_callback([this](float state) { this->data_.take_sample(state); });
this->data_.set_update_time_ms(g->get_duration() * 1000 / g->get_width());
}
void Graph::draw(DisplayBuffer *buff, uint16_t x_offset, uint16_t y_offset, Color color) {
/// Plot border
if (this->border_) {
buff->horizontal_line(x_offset, y_offset, this->width_, color);
buff->horizontal_line(x_offset, y_offset + this->height_ - 1, this->width_, color);
buff->vertical_line(x_offset, y_offset, this->height_, color);
buff->vertical_line(x_offset + this->width_ - 1, y_offset, this->height_, color);
}
/// Determine best y-axis scale and range
float ymin = NAN;
float ymax = NAN;
for (auto *trace : traces_) {
float mx = trace->get_tracedata()->get_recent_max();
float mn = trace->get_tracedata()->get_recent_min();
if (std::isnan(ymax) || (ymax < mx))
ymax = mx;
if (std::isnan(ymin) || (ymin > mn))
ymin = mn;
}
// Adjust if manually overridden
if (!std::isnan(this->min_value_))
ymin = this->min_value_;
if (!std::isnan(this->max_value_))
ymax = this->max_value_;
float yrange = ymax - ymin;
if (yrange > this->max_range_) {
// Look back in trace data to best-fit into local range
float mx = NAN;
float mn = NAN;
for (uint32_t i = 0; i < this->width_; i++) {
for (auto *trace : traces_) {
float v = trace->get_tracedata()->get_value(i);
if (!std::isnan(v)) {
if ((v - mn) > this->max_range_)
break;
if ((mx - v) > this->max_range_)
break;
if (std::isnan(mx) || (v > mx))
mx = v;
if (std::isnan(mn) || (v < mn))
mn = v;
}
}
}
yrange = this->max_range_;
if (!std::isnan(mn)) {
ymin = mn;
ymax = ymin + this->max_range_;
}
ESP_LOGV(TAG, "Graphing at max_range. Using local min %f, max %f", mn, mx);
}
float y_per_div = this->min_range_;
if (!std::isnan(this->gridspacing_y_)) {
y_per_div = this->gridspacing_y_;
}
// Restrict drawing too many gridlines
if (yrange > 10 * y_per_div) {
while (yrange > 10 * y_per_div) {
y_per_div *= 2;
}
ESP_LOGW(TAG, "Graphing reducing y-scale to prevent too many gridlines");
}
// Adjust limits to nice y_per_div boundaries
int yn = int(ymin / y_per_div);
int ym = int(ymax / y_per_div) + int(1 * (fmodf(ymax, y_per_div) != 0));
ymin = yn * y_per_div;
ymax = ym * y_per_div;
yrange = ymax - ymin;
/// Draw grid
if (!std::isnan(this->gridspacing_y_)) {
for (int y = yn; y <= ym; y++) {
int16_t py = (int16_t) roundf((this->height_ - 1) * (1.0 - (float) (y - yn) / (ym - yn)));
for (uint32_t x = 0; x < this->width_; x += 2) {
buff->draw_pixel_at(x_offset + x, y_offset + py, color);
}
}
}
if (!std::isnan(this->gridspacing_x_) && (this->gridspacing_x_ > 0)) {
int n = this->duration_ / this->gridspacing_x_;
// Restrict drawing too many gridlines
if (n > 20) {
while (n > 20) {
n /= 2;
}
ESP_LOGW(TAG, "Graphing reducing x-scale to prevent too many gridlines");
}
for (int i = 0; i <= n; i++) {
for (uint32_t y = 0; y < this->height_; y += 2) {
buff->draw_pixel_at(x_offset + i * (this->width_ - 1) / n, y_offset + y, color);
}
}
}
/// Draw traces
ESP_LOGV(TAG, "Updating graph. ymin %f, ymax %f", ymin, ymax);
for (auto *trace : traces_) {
Color c = trace->get_line_color();
uint16_t thick = trace->get_line_thickness();
for (uint32_t i = 0; i < this->width_; i++) {
float v = (trace->get_tracedata()->get_value(i) - ymin) / yrange;
if (!std::isnan(v) && (thick > 0)) {
int16_t x = this->width_ - 1 - i;
uint8_t b = (i % (thick * LineType::PATTERN_LENGTH)) / thick;
if (((uint8_t) trace->get_line_type() & (1 << b)) == (1 << b)) {
int16_t y = (int16_t) roundf((this->height_ - 1) * (1.0 - v)) - thick / 2;
for (uint16_t t = 0; t < thick; t++) {
buff->draw_pixel_at(x_offset + x, y_offset + y + t, c);
}
}
}
}
}
}
/// Determine the best coordinates of drawing text + lines
void GraphLegend::init(Graph *g) {
parent_ = g;
// Determine maximum expected text and value width / height
int txtw = 0, txth = 0;
int valw = 0, valh = 0;
int lt = 0;
for (auto *trace : g->traces_) {
std::string txtstr = trace->get_name();
int fw, fos, fbl, fh;
this->font_label_->measure(txtstr.c_str(), &fw, &fos, &fbl, &fh);
if (fw > txtw)
txtw = fw;
if (fh > txth)
txth = fh;
if (trace->get_line_thickness() > lt)
lt = trace->get_line_thickness();
ESP_LOGI(TAGL, " %s %d %d", txtstr.c_str(), fw, fh);
if (this->values_ != VALUE_POSITION_TYPE_NONE) {
std::stringstream ss;
ss << std::fixed << std::setprecision(trace->sensor_->get_accuracy_decimals()) << trace->sensor_->get_state();
std::string valstr = ss.str();
if (this->units_) {
valstr += trace->sensor_->get_unit_of_measurement();
}
this->font_value_->measure(valstr.c_str(), &fw, &fos, &fbl, &fh);
if (fw > valw)
valw = fw;
if (fh > valh)
valh = fh;
ESP_LOGI(TAGL, " %s %d %d", valstr.c_str(), fw, fh);
}
}
// Add extra margin
txtw *= 1.2;
valw *= 1.2;
uint8_t n = g->traces_.size();
uint16_t w = this->width_;
uint16_t h = this->height_;
DirectionType dir = this->direction_;
ValuePositionType valpos = this->values_;
if (!this->font_value_) {
valpos = VALUE_POSITION_TYPE_NONE;
}
// Line sample always goes below text for compactness
this->yl_ = txth + (txth / 4) + lt / 2;
if (dir == DIRECTION_TYPE_AUTO) {
dir = DIRECTION_TYPE_HORIZONTAL; // as default
if (h > 0) {
dir = DIRECTION_TYPE_VERTICAL;
}
}
if (valpos == VALUE_POSITION_TYPE_AUTO) {
// TODO: do something smarter?? - fit to w and h?
valpos = VALUE_POSITION_TYPE_BELOW;
}
if (valpos == VALUE_POSITION_TYPE_BELOW) {
this->yv_ = txth + (txth / 4);
if (this->lines_)
this->yv_ += txth / 4 + lt;
} else if (valpos == VALUE_POSITION_TYPE_BESIDE) {
this->xv_ = (txtw + valw) / 2;
}
// If width or height is specified we divide evenly within, else we do tight-fit
if (w == 0) {
this->x0_ = txtw / 2;
this->xs_ = txtw;
if (valpos == VALUE_POSITION_TYPE_BELOW) {
this->xs_ = std::max(txtw, valw);
;
this->x0_ = this->xs_ / 2;
} else if (valpos == VALUE_POSITION_TYPE_BESIDE) {
this->xs_ = txtw + valw;
}
if (dir == DIRECTION_TYPE_VERTICAL) {
this->width_ = this->xs_;
} else {
this->width_ = this->xs_ * n;
}
} else {
this->xs_ = w / n;
this->x0_ = this->xs_ / 2;
}
if (h == 0) {
this->ys_ = txth;
if (valpos == VALUE_POSITION_TYPE_BELOW) {
this->ys_ = txth + txth / 2 + valh;
if (this->lines_) {
this->ys_ += lt;
}
} else if (valpos == VALUE_POSITION_TYPE_BESIDE) {
if (this->lines_) {
this->ys_ = std::max(txth + txth / 4 + lt + txth / 4, valh + valh / 4);
} else {
this->ys_ = std::max(txth + txth / 4, valh + valh / 4);
}
this->height_ = this->ys_ * n;
}
if (dir == DIRECTION_TYPE_HORIZONTAL) {
this->height_ = this->ys_;
} else {
this->height_ = this->ys_ * n;
}
} else {
this->ys_ = h / n;
}
if (dir == DIRECTION_TYPE_HORIZONTAL) {
this->ys_ = 0;
} else {
this->xs_ = 0;
}
}
void Graph::draw_legend(display::DisplayBuffer *buff, uint16_t x_offset, uint16_t y_offset, Color color) {
if (!legend_)
return;
/// Plot border
if (this->border_) {
int w = legend_->width_;
int h = legend_->height_;
buff->horizontal_line(x_offset, y_offset, w, color);
buff->horizontal_line(x_offset, y_offset + h - 1, w, color);
buff->vertical_line(x_offset, y_offset, h, color);
buff->vertical_line(x_offset + w - 1, y_offset, h, color);
}
int x = x_offset + legend_->x0_;
int y = y_offset;
for (auto *trace : traces_) {
std::string txtstr = trace->get_name();
ESP_LOGV(TAG, " %s", txtstr.c_str());
buff->printf(x, y, legend_->font_label_, trace->get_line_color(), TextAlign::TOP_CENTER, "%s", txtstr.c_str());
if (legend_->lines_) {
uint16_t thick = trace->get_line_thickness();
for (int i = 0; i < legend_->x0_ * 4 / 3; i++) {
uint8_t b = (i % (thick * LineType::PATTERN_LENGTH)) / thick;
if (((uint8_t) trace->get_line_type() & (1 << b)) == (1 << b)) {
buff->vertical_line(x - legend_->x0_ * 2 / 3 + i, y + legend_->yl_ - thick / 2, thick,
trace->get_line_color());
}
}
}
if (legend_->values_ != VALUE_POSITION_TYPE_NONE) {
int xv = x + legend_->xv_;
int yv = y + legend_->yv_;
std::stringstream ss;
ss << std::fixed << std::setprecision(trace->sensor_->get_accuracy_decimals()) << trace->sensor_->get_state();
std::string valstr = ss.str();
if (legend_->units_) {
valstr += trace->sensor_->get_unit_of_measurement();
}
buff->printf(xv, yv, legend_->font_value_, trace->get_line_color(), TextAlign::TOP_CENTER, "%s", valstr.c_str());
ESP_LOGV(TAG, " value: %s", valstr.c_str());
}
x += legend_->xs_;
y += legend_->ys_;
}
}
void Graph::setup() {
for (auto *trace : traces_) {
trace->init(this);
}
}
void Graph::dump_config() {
for (auto *trace : traces_) {
ESP_LOGCONFIG(TAG, "Graph for sensor %s", trace->get_name().c_str());
}
}
} // namespace graph
} // namespace esphome