Split display_buffer sub-components into own files (#4950)

* Split display_buffer sub-components into own files Move the Image, Animation and Font classes to their own h/cpp pairs, instead of having everything into the display_buffer h/cpp files. * Fixed COLOR_ON duplicate definition
2024-11-17 10:55:36 +01:00 · 2023-06-17 10:32:07 +02:00 · 2023-06-17 10:32:07 +02:00 · ffa669899a
commit ffa669899a
parent 17fed954bf
9 changed files with 502 additions and 431 deletions
--- a/esphome/components/display/animation.cpp
+++ b/esphome/components/display/animation.cpp
@ -0,0 +1,69 @@
 #include "animation.h"
 #include "esphome/core/hal.h"
 namespace esphome {
 namespace display {
 Animation::Animation(const uint8_t *data_start, int width, int height, uint32_t animation_frame_count, ImageType type)
    : Image(data_start, width, height, type),
      animation_data_start_(data_start),
      current_frame_(0),
      animation_frame_count_(animation_frame_count),
      loop_start_frame_(0),
      loop_end_frame_(animation_frame_count_),
      loop_count_(0),
      loop_current_iteration_(1) {}
 void Animation::set_loop(uint32_t start_frame, uint32_t end_frame, int count) {
  loop_start_frame_ = std::min(start_frame, animation_frame_count_);
  loop_end_frame_ = std::min(end_frame, animation_frame_count_);
  loop_count_ = count;
  loop_current_iteration_ = 1;
 }
 uint32_t Animation::get_animation_frame_count() const { return this->animation_frame_count_; }
 int Animation::get_current_frame() const { return this->current_frame_; }
 void Animation::next_frame() {
  this->current_frame_++;
  if (loop_count_ && this->current_frame_ == loop_end_frame_ &&
      (this->loop_current_iteration_ < loop_count_ || loop_count_ < 0)) {
    this->current_frame_ = loop_start_frame_;
    this->loop_current_iteration_++;
  }
  if (this->current_frame_ >= animation_frame_count_) {
    this->loop_current_iteration_ = 1;
    this->current_frame_ = 0;
  }
  this->update_data_start_();
 }
 void Animation::prev_frame() {
  this->current_frame_--;
  if (this->current_frame_ < 0) {
    this->current_frame_ = this->animation_frame_count_ - 1;
  }
  this->update_data_start_();
 }
 void Animation::set_frame(int frame) {
  unsigned abs_frame = abs(frame);
  if (abs_frame < this->animation_frame_count_) {
    if (frame >= 0) {
      this->current_frame_ = frame;
    } else {
      this->current_frame_ = this->animation_frame_count_ - abs_frame;
    }
  }
  this->update_data_start_();
 }
 void Animation::update_data_start_() {
  const uint32_t image_size = image_type_to_width_stride(this->width_, this->type_) * this->height_;
  this->data_start_ = this->animation_data_start_ + image_size * this->current_frame_;
 }
 }  // namespace display
 }  // namespace esphome
--- a/esphome/components/display/animation.h
+++ b/esphome/components/display/animation.h
@ -0,0 +1,37 @@
 #pragma once
 #include "image.h"
 namespace esphome {
 namespace display {
 class Animation : public Image {
 public:
  Animation(const uint8_t *data_start, int width, int height, uint32_t animation_frame_count, ImageType type);
  uint32_t get_animation_frame_count() const;
  int get_current_frame() const;
  void next_frame();
  void prev_frame();
  /** Selects a specific frame within the animation.
   *
   * @param frame If possitive, advance to the frame. If negative, recede to that frame from the end frame.
   */
  void set_frame(int frame);
  void set_loop(uint32_t start_frame, uint32_t end_frame, int count);
 protected:
  void update_data_start_();
  const uint8_t *animation_data_start_;
  int current_frame_;
  uint32_t animation_frame_count_;
  uint32_t loop_start_frame_;
  uint32_t loop_end_frame_;
  int loop_count_;
  int loop_current_iteration_;
 };
 }  // namespace display
 }  // namespace esphome
--- a/esphome/components/display/display_buffer.cpp
+++ b/esphome/components/display/display_buffer.cpp
@ -7,6 +7,10 @@
 #include "esphome/core/helpers.h"
 #include "esphome/core/log.h"
 #include "animation.h"
 #include "image.h"
 #include "font.h"
 namespace esphome {
 namespace display {
@ -15,25 +19,6 @@ static const char *const TAG = "display";
 const Color COLOR_OFF(0, 0, 0, 255);
 const Color COLOR_ON(255, 255, 255, 255);
 static int image_type_to_bpp(ImageType type) {
  switch (type) {
    case IMAGE_TYPE_BINARY:
      return 1;
    case IMAGE_TYPE_GRAYSCALE:
      return 8;
    case IMAGE_TYPE_RGB565:
      return 16;
    case IMAGE_TYPE_RGB24:
      return 24;
    case IMAGE_TYPE_RGBA:
      return 32;
    default:
      return 0;
  }
 }
 static int image_type_to_width_stride(int width, ImageType type) { return (width * image_type_to_bpp(type) + 7u) / 8u; }
 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;
@ -505,286 +490,6 @@ Rect DisplayBuffer::get_clipping() {
    return this->clipping_rectangle_.back();
  }
 }
 bool Glyph::get_pixel(int x, int y) const {
  const int x_data = x - this->glyph_data_->offset_x;
  const int y_data = y - this->glyph_data_->offset_y;
  if (x_data < 0 || x_data >= this->glyph_data_->width || y_data < 0 || y_data >= this->glyph_data_->height)
    return false;
  const uint32_t width_8 = ((this->glyph_data_->width + 7u) / 8u) * 8u;
  const uint32_t pos = x_data + y_data * width_8;
  return progmem_read_byte(this->glyph_data_->data + (pos / 8u)) & (0x80 >> (pos % 8u));
 }
 const char *Glyph::get_char() const { return this->glyph_data_->a_char; }
 bool Glyph::compare_to(const char *str) const {
  // 1 -> this->char_
  // 2 -> str
  for (uint32_t i = 0;; i++) {
    if (this->glyph_data_->a_char[i] == '\0')
      return true;
    if (str[i] == '\0')
      return false;
    if (this->glyph_data_->a_char[i] > str[i])
      return false;
    if (this->glyph_data_->a_char[i] < str[i])
      return true;
  }
  // this should not happen
  return false;
 }
 int Glyph::match_length(const char *str) const {
  for (uint32_t i = 0;; i++) {
    if (this->glyph_data_->a_char[i] == '\0')
      return i;
    if (str[i] != this->glyph_data_->a_char[i])
      return 0;
  }
  // this should not happen
  return 0;
 }
 void Glyph::scan_area(int *x1, int *y1, int *width, int *height) const {
  *x1 = this->glyph_data_->offset_x;
  *y1 = this->glyph_data_->offset_y;
  *width = this->glyph_data_->width;
  *height = this->glyph_data_->height;
 }
 int Font::match_next_glyph(const char *str, int *match_length) {
  int lo = 0;
  int hi = this->glyphs_.size() - 1;
  while (lo != hi) {
    int mid = (lo + hi + 1) / 2;
    if (this->glyphs_[mid].compare_to(str)) {
      lo = mid;
    } else {
      hi = mid - 1;
    }
  }
  *match_length = this->glyphs_[lo].match_length(str);
  if (*match_length <= 0)
    return -1;
  return lo;
 }
 void Font::measure(const char *str, int *width, int *x_offset, int *baseline, int *height) {
  *baseline = this->baseline_;
  *height = this->height_;
  int i = 0;
  int min_x = 0;
  bool has_char = false;
  int x = 0;
  while (str[i] != '\0') {
    int match_length;
    int glyph_n = this->match_next_glyph(str + i, &match_length);
    if (glyph_n < 0) {
      // Unknown char, skip
      if (!this->get_glyphs().empty())
        x += this->get_glyphs()[0].glyph_data_->width;
      i++;
      continue;
    }
    const Glyph &glyph = this->glyphs_[glyph_n];
    if (!has_char) {
      min_x = glyph.glyph_data_->offset_x;
    } else {
      min_x = std::min(min_x, x + glyph.glyph_data_->offset_x);
    }
    x += glyph.glyph_data_->width + glyph.glyph_data_->offset_x;
    i += match_length;
    has_char = true;
  }
  *x_offset = min_x;
  *width = x - min_x;
 }
 Font::Font(const GlyphData *data, int data_nr, int baseline, int height) : baseline_(baseline), height_(height) {
  glyphs_.reserve(data_nr);
  for (int i = 0; i < data_nr; ++i)
    glyphs_.emplace_back(&data[i]);
 }
 void Image::draw(int x, int y, DisplayBuffer *display, Color color_on, Color color_off) {
  switch (type_) {
    case IMAGE_TYPE_BINARY: {
      for (int img_x = 0; img_x < width_; img_x++) {
        for (int img_y = 0; img_y < height_; img_y++) {
          if (this->get_binary_pixel_(img_x, img_y)) {
            display->draw_pixel_at(x + img_x, y + img_y, color_on);
          } else if (!this->transparent_) {
            display->draw_pixel_at(x + img_x, y + img_y, color_off);
          }
        }
      }
      break;
    }
    case IMAGE_TYPE_GRAYSCALE:
      for (int img_x = 0; img_x < width_; img_x++) {
        for (int img_y = 0; img_y < height_; img_y++) {
          auto color = this->get_grayscale_pixel_(img_x, img_y);
          if (color.w >= 0x80) {
            display->draw_pixel_at(x + img_x, y + img_y, color);
          }
        }
      }
      break;
    case IMAGE_TYPE_RGB565:
      for (int img_x = 0; img_x < width_; img_x++) {
        for (int img_y = 0; img_y < height_; img_y++) {
          auto color = this->get_rgb565_pixel_(img_x, img_y);
          if (color.w >= 0x80) {
            display->draw_pixel_at(x + img_x, y + img_y, color);
          }
        }
      }
      break;
    case IMAGE_TYPE_RGB24:
      for (int img_x = 0; img_x < width_; img_x++) {
        for (int img_y = 0; img_y < height_; img_y++) {
          auto color = this->get_rgb24_pixel_(img_x, img_y);
          if (color.w >= 0x80) {
            display->draw_pixel_at(x + img_x, y + img_y, color);
          }
        }
      }
      break;
    case IMAGE_TYPE_RGBA:
      for (int img_x = 0; img_x < width_; img_x++) {
        for (int img_y = 0; img_y < height_; img_y++) {
          auto color = this->get_rgba_pixel_(img_x, img_y);
          if (color.w >= 0x80) {
            display->draw_pixel_at(x + img_x, y + img_y, color);
          }
        }
      }
      break;
  }
 }
 Color Image::get_pixel(int x, int y, Color color_on, Color color_off) const {
  if (x < 0 || x >= this->width_ || y < 0 || y >= this->height_)
    return color_off;
  switch (this->type_) {
    case IMAGE_TYPE_BINARY:
      return this->get_binary_pixel_(x, y) ? color_on : color_off;
    case IMAGE_TYPE_GRAYSCALE:
      return this->get_grayscale_pixel_(x, y);
    case IMAGE_TYPE_RGB565:
      return this->get_rgb565_pixel_(x, y);
    case IMAGE_TYPE_RGB24:
      return this->get_rgb24_pixel_(x, y);
    case IMAGE_TYPE_RGBA:
      return this->get_rgba_pixel_(x, y);
    default:
      return color_off;
  }
 }
 bool Image::get_binary_pixel_(int x, int y) const {
  const uint32_t width_8 = ((this->width_ + 7u) / 8u) * 8u;
  const uint32_t pos = x + y * width_8;
  return progmem_read_byte(this->data_start_ + (pos / 8u)) & (0x80 >> (pos % 8u));
 }
 Color Image::get_rgba_pixel_(int x, int y) const {
  const uint32_t pos = (x + y * this->width_) * 4;
  return Color(progmem_read_byte(this->data_start_ + pos + 0), progmem_read_byte(this->data_start_ + pos + 1),
               progmem_read_byte(this->data_start_ + pos + 2), progmem_read_byte(this->data_start_ + pos + 3));
 }
 Color Image::get_rgb24_pixel_(int x, int y) const {
  const uint32_t pos = (x + y * this->width_) * 3;
  Color color = Color(progmem_read_byte(this->data_start_ + pos + 0), progmem_read_byte(this->data_start_ + pos + 1),
                      progmem_read_byte(this->data_start_ + pos + 2));
  if (color.b == 1 && color.r == 0 && color.g == 0 && transparent_) {
    // (0, 0, 1) has been defined as transparent color for non-alpha images.
    // putting blue == 1 as a first condition for performance reasons (least likely value to short-cut the if)
    color.w = 0;
  } else {
    color.w = 0xFF;
  }
  return color;
 }
 Color Image::get_rgb565_pixel_(int x, int y) const {
  const uint32_t pos = (x + y * this->width_) * 2;
  uint16_t rgb565 =
      progmem_read_byte(this->data_start_ + pos + 0) << 8 | progmem_read_byte(this->data_start_ + pos + 1);
  auto r = (rgb565 & 0xF800) >> 11;
  auto g = (rgb565 & 0x07E0) >> 5;
  auto b = rgb565 & 0x001F;
  Color color = Color((r << 3) | (r >> 2), (g << 2) | (g >> 4), (b << 3) | (b >> 2));
  if (rgb565 == 0x0020 && transparent_) {
    // darkest green has been defined as transparent color for transparent RGB565 images.
    color.w = 0;
  } else {
    color.w = 0xFF;
  }
  return color;
 }
 Color Image::get_grayscale_pixel_(int x, int y) const {
  const uint32_t pos = (x + y * this->width_);
  const uint8_t gray = progmem_read_byte(this->data_start_ + pos);
  uint8_t alpha = (gray == 1 && transparent_) ? 0 : 0xFF;
  return Color(gray, gray, gray, alpha);
 }
 int Image::get_width() const { return this->width_; }
 int Image::get_height() const { return this->height_; }
 ImageType Image::get_type() const { return this->type_; }
 Image::Image(const uint8_t *data_start, int width, int height, ImageType type)
    : width_(width), height_(height), type_(type), data_start_(data_start) {}
 Animation::Animation(const uint8_t *data_start, int width, int height, uint32_t animation_frame_count, ImageType type)
    : Image(data_start, width, height, type),
      animation_data_start_(data_start),
      current_frame_(0),
      animation_frame_count_(animation_frame_count),
      loop_start_frame_(0),
      loop_end_frame_(animation_frame_count_),
      loop_count_(0),
      loop_current_iteration_(1) {}
 void Animation::set_loop(uint32_t start_frame, uint32_t end_frame, int count) {
  loop_start_frame_ = std::min(start_frame, animation_frame_count_);
  loop_end_frame_ = std::min(end_frame, animation_frame_count_);
  loop_count_ = count;
  loop_current_iteration_ = 1;
 }
 uint32_t Animation::get_animation_frame_count() const { return this->animation_frame_count_; }
 int Animation::get_current_frame() const { return this->current_frame_; }
 void Animation::next_frame() {
  this->current_frame_++;
  if (loop_count_ && this->current_frame_ == loop_end_frame_ &&
      (this->loop_current_iteration_ < loop_count_ || loop_count_ < 0)) {
    this->current_frame_ = loop_start_frame_;
    this->loop_current_iteration_++;
  }
  if (this->current_frame_ >= animation_frame_count_) {
    this->loop_current_iteration_ = 1;
    this->current_frame_ = 0;
  }
  this->update_data_start_();
 }
 void Animation::prev_frame() {
  this->current_frame_--;
  if (this->current_frame_ < 0) {
    this->current_frame_ = this->animation_frame_count_ - 1;
  }
  this->update_data_start_();
 }
 void Animation::set_frame(int frame) {
  unsigned abs_frame = abs(frame);
  if (abs_frame < this->animation_frame_count_) {
    if (frame >= 0) {
      this->current_frame_ = frame;
    } else {
      this->current_frame_ = this->animation_frame_count_ - abs_frame;
    }
  }
  this->update_data_start_();
 }
 void Animation::update_data_start_() {
  const uint32_t image_size = image_type_to_width_stride(this->width_, this->type_) * this->height_;
  this->data_start_ = this->animation_data_start_ + image_size * this->current_frame_;
 }
 DisplayPage::DisplayPage(display_writer_t writer) : writer_(std::move(writer)) {}
 void DisplayPage::show() { this->parent_->show_page(this); }
--- a/esphome/components/display/display_buffer.h
+++ b/esphome/components/display/display_buffer.h
@ -16,6 +16,10 @@
 #include "esphome/components/qr_code/qr_code.h"
 #endif
 #include "animation.h"
 #include "font.h"
 #include "image.h"
 namespace esphome {
 namespace display {
@ -70,19 +74,6 @@ enum class TextAlign {
  BOTTOM_RIGHT = BOTTOM | RIGHT,
 };
 /// Turn the pixel OFF.
 extern const Color COLOR_OFF;
 /// Turn the pixel ON.
 extern const Color COLOR_ON;
 enum ImageType {
  IMAGE_TYPE_BINARY = 0,
  IMAGE_TYPE_GRAYSCALE = 1,
  IMAGE_TYPE_RGB24 = 2,
  IMAGE_TYPE_RGB565 = 3,
  IMAGE_TYPE_RGBA = 4,
 };
 enum DisplayType {
  DISPLAY_TYPE_BINARY = 1,
  DISPLAY_TYPE_GRAYSCALE = 2,
@ -123,8 +114,6 @@ class Rect {
  void info(const std::string &prefix = "rect info:");
 };
 class BaseImage;
 class Font;
 class DisplayBuffer;
 class DisplayPage;
 class DisplayOnPageChangeTrigger;
@ -475,123 +464,6 @@ class DisplayPage {
  DisplayPage *next_{nullptr};
 };
 struct GlyphData {
  const char *a_char;
  const uint8_t *data;
  int offset_x;
  int offset_y;
  int width;
  int height;
 };
 class Glyph {
 public:
  Glyph(const GlyphData *data) : glyph_data_(data) {}
  bool get_pixel(int x, int y) const;
  const char *get_char() const;
  bool compare_to(const char *str) const;
  int match_length(const char *str) const;
  void scan_area(int *x1, int *y1, int *width, int *height) const;
 protected:
  friend Font;
  friend DisplayBuffer;
  const GlyphData *glyph_data_;
 };
 class Font {
 public:
  /** Construct the font with the given glyphs.
   *
   * @param glyphs A vector of glyphs, must be sorted lexicographically.
   * @param baseline The y-offset from the top of the text to the baseline.
   * @param bottom The y-offset from the top of the text to the bottom (i.e. height).
   */
  Font(const GlyphData *data, int data_nr, int baseline, int height);
  int match_next_glyph(const char *str, int *match_length);
  void measure(const char *str, int *width, int *x_offset, int *baseline, int *height);
  inline int get_baseline() { return this->baseline_; }
  inline int get_height() { return this->height_; }
  const std::vector<Glyph, ExternalRAMAllocator<Glyph>> &get_glyphs() const { return glyphs_; }
 protected:
  std::vector<Glyph, ExternalRAMAllocator<Glyph>> glyphs_;
  int baseline_;
  int height_;
 };
 class BaseImage {
 public:
  virtual void draw(int x, int y, DisplayBuffer *display, Color color_on, Color color_off) = 0;
  virtual int get_width() const = 0;
  virtual int get_height() const = 0;
 };
 class Image : public BaseImage {
 public:
  Image(const uint8_t *data_start, int width, int height, ImageType type);
  Color get_pixel(int x, int y, Color color_on = COLOR_ON, Color color_off = COLOR_OFF) const;
  int get_width() const override;
  int get_height() const override;
  ImageType get_type() const;
  void draw(int x, int y, DisplayBuffer *display, Color color_on, Color color_off) override;
  void set_transparency(bool transparent) { transparent_ = transparent; }
  bool has_transparency() const { return transparent_; }
 protected:
  bool get_binary_pixel_(int x, int y) const;
  Color get_rgb24_pixel_(int x, int y) const;
  Color get_rgba_pixel_(int x, int y) const;
  Color get_rgb565_pixel_(int x, int y) const;
  Color get_grayscale_pixel_(int x, int y) const;
  int width_;
  int height_;
  ImageType type_;
  const uint8_t *data_start_;
  bool transparent_;
 };
 class Animation : public Image {
 public:
  Animation(const uint8_t *data_start, int width, int height, uint32_t animation_frame_count, ImageType type);
  uint32_t get_animation_frame_count() const;
  int get_current_frame() const;
  void next_frame();
  void prev_frame();
  /** Selects a specific frame within the animation.
   *
   * @param frame If possitive, advance to the frame. If negative, recede to that frame from the end frame.
   */
  void set_frame(int frame);
  void set_loop(uint32_t start_frame, uint32_t end_frame, int count);
 protected:
  void update_data_start_();
  const uint8_t *animation_data_start_;
  int current_frame_;
  uint32_t animation_frame_count_;
  uint32_t loop_start_frame_;
  uint32_t loop_end_frame_;
  int loop_count_;
  int loop_current_iteration_;
 };
 template<typename... Ts> class DisplayPageShowAction : public Action<Ts...> {
 public:
  TEMPLATABLE_VALUE(DisplayPage *, page)
--- a/esphome/components/display/font.cpp
+++ b/esphome/components/display/font.cpp
@ -0,0 +1,105 @@
 #include "font.h"
 #include "esphome/core/hal.h"
 namespace esphome {
 namespace display {
 bool Glyph::get_pixel(int x, int y) const {
  const int x_data = x - this->glyph_data_->offset_x;
  const int y_data = y - this->glyph_data_->offset_y;
  if (x_data < 0 || x_data >= this->glyph_data_->width || y_data < 0 || y_data >= this->glyph_data_->height)
    return false;
  const uint32_t width_8 = ((this->glyph_data_->width + 7u) / 8u) * 8u;
  const uint32_t pos = x_data + y_data * width_8;
  return progmem_read_byte(this->glyph_data_->data + (pos / 8u)) & (0x80 >> (pos % 8u));
 }
 const char *Glyph::get_char() const { return this->glyph_data_->a_char; }
 bool Glyph::compare_to(const char *str) const {
  // 1 -> this->char_
  // 2 -> str
  for (uint32_t i = 0;; i++) {
    if (this->glyph_data_->a_char[i] == '\0')
      return true;
    if (str[i] == '\0')
      return false;
    if (this->glyph_data_->a_char[i] > str[i])
      return false;
    if (this->glyph_data_->a_char[i] < str[i])
      return true;
  }
  // this should not happen
  return false;
 }
 int Glyph::match_length(const char *str) const {
  for (uint32_t i = 0;; i++) {
    if (this->glyph_data_->a_char[i] == '\0')
      return i;
    if (str[i] != this->glyph_data_->a_char[i])
      return 0;
  }
  // this should not happen
  return 0;
 }
 void Glyph::scan_area(int *x1, int *y1, int *width, int *height) const {
  *x1 = this->glyph_data_->offset_x;
  *y1 = this->glyph_data_->offset_y;
  *width = this->glyph_data_->width;
  *height = this->glyph_data_->height;
 }
 int Font::match_next_glyph(const char *str, int *match_length) {
  int lo = 0;
  int hi = this->glyphs_.size() - 1;
  while (lo != hi) {
    int mid = (lo + hi + 1) / 2;
    if (this->glyphs_[mid].compare_to(str)) {
      lo = mid;
    } else {
      hi = mid - 1;
    }
  }
  *match_length = this->glyphs_[lo].match_length(str);
  if (*match_length <= 0)
    return -1;
  return lo;
 }
 void Font::measure(const char *str, int *width, int *x_offset, int *baseline, int *height) {
  *baseline = this->baseline_;
  *height = this->height_;
  int i = 0;
  int min_x = 0;
  bool has_char = false;
  int x = 0;
  while (str[i] != '\0') {
    int match_length;
    int glyph_n = this->match_next_glyph(str + i, &match_length);
    if (glyph_n < 0) {
      // Unknown char, skip
      if (!this->get_glyphs().empty())
        x += this->get_glyphs()[0].glyph_data_->width;
      i++;
      continue;
    }
    const Glyph &glyph = this->glyphs_[glyph_n];
    if (!has_char) {
      min_x = glyph.glyph_data_->offset_x;
    } else {
      min_x = std::min(min_x, x + glyph.glyph_data_->offset_x);
    }
    x += glyph.glyph_data_->width + glyph.glyph_data_->offset_x;
    i += match_length;
    has_char = true;
  }
  *x_offset = min_x;
  *width = x - min_x;
 }
 Font::Font(const GlyphData *data, int data_nr, int baseline, int height) : baseline_(baseline), height_(height) {
  glyphs_.reserve(data_nr);
  for (int i = 0; i < data_nr; ++i)
    glyphs_.emplace_back(&data[i]);
 }
 }  // namespace display
 }  // namespace esphome
--- a/esphome/components/display/font.h
+++ b/esphome/components/display/font.h
@ -0,0 +1,66 @@
 #pragma once
 #include "esphome/core/datatypes.h"
 namespace esphome {
 namespace display {
 class DisplayBuffer;
 class Font;
 struct GlyphData {
  const char *a_char;
  const uint8_t *data;
  int offset_x;
  int offset_y;
  int width;
  int height;
 };
 class Glyph {
 public:
  Glyph(const GlyphData *data) : glyph_data_(data) {}
  bool get_pixel(int x, int y) const;
  const char *get_char() const;
  bool compare_to(const char *str) const;
  int match_length(const char *str) const;
  void scan_area(int *x1, int *y1, int *width, int *height) const;
 protected:
  friend Font;
  friend DisplayBuffer;
  const GlyphData *glyph_data_;
 };
 class Font {
 public:
  /** Construct the font with the given glyphs.
   *
   * @param glyphs A vector of glyphs, must be sorted lexicographically.
   * @param baseline The y-offset from the top of the text to the baseline.
   * @param bottom The y-offset from the top of the text to the bottom (i.e. height).
   */
  Font(const GlyphData *data, int data_nr, int baseline, int height);
  int match_next_glyph(const char *str, int *match_length);
  void measure(const char *str, int *width, int *x_offset, int *baseline, int *height);
  inline int get_baseline() { return this->baseline_; }
  inline int get_height() { return this->height_; }
  const std::vector<Glyph, ExternalRAMAllocator<Glyph>> &get_glyphs() const { return glyphs_; }
 protected:
  std::vector<Glyph, ExternalRAMAllocator<Glyph>> glyphs_;
  int baseline_;
  int height_;
 };
 }  // namespace display
 }  // namespace esphome
--- a/esphome/components/display/image.cpp
+++ b/esphome/components/display/image.cpp
@ -0,0 +1,135 @@
 #include "image.h"
 #include "esphome/core/hal.h"
 #include "display_buffer.h"
 namespace esphome {
 namespace display {
 void Image::draw(int x, int y, DisplayBuffer *display, Color color_on, Color color_off) {
  switch (type_) {
    case IMAGE_TYPE_BINARY: {
      for (int img_x = 0; img_x < width_; img_x++) {
        for (int img_y = 0; img_y < height_; img_y++) {
          if (this->get_binary_pixel_(img_x, img_y)) {
            display->draw_pixel_at(x + img_x, y + img_y, color_on);
          } else if (!this->transparent_) {
            display->draw_pixel_at(x + img_x, y + img_y, color_off);
          }
        }
      }
      break;
    }
    case IMAGE_TYPE_GRAYSCALE:
      for (int img_x = 0; img_x < width_; img_x++) {
        for (int img_y = 0; img_y < height_; img_y++) {
          auto color = this->get_grayscale_pixel_(img_x, img_y);
          if (color.w >= 0x80) {
            display->draw_pixel_at(x + img_x, y + img_y, color);
          }
        }
      }
      break;
    case IMAGE_TYPE_RGB565:
      for (int img_x = 0; img_x < width_; img_x++) {
        for (int img_y = 0; img_y < height_; img_y++) {
          auto color = this->get_rgb565_pixel_(img_x, img_y);
          if (color.w >= 0x80) {
            display->draw_pixel_at(x + img_x, y + img_y, color);
          }
        }
      }
      break;
    case IMAGE_TYPE_RGB24:
      for (int img_x = 0; img_x < width_; img_x++) {
        for (int img_y = 0; img_y < height_; img_y++) {
          auto color = this->get_rgb24_pixel_(img_x, img_y);
          if (color.w >= 0x80) {
            display->draw_pixel_at(x + img_x, y + img_y, color);
          }
        }
      }
      break;
    case IMAGE_TYPE_RGBA:
      for (int img_x = 0; img_x < width_; img_x++) {
        for (int img_y = 0; img_y < height_; img_y++) {
          auto color = this->get_rgba_pixel_(img_x, img_y);
          if (color.w >= 0x80) {
            display->draw_pixel_at(x + img_x, y + img_y, color);
          }
        }
      }
      break;
  }
 }
 Color Image::get_pixel(int x, int y, Color color_on, Color color_off) const {
  if (x < 0 || x >= this->width_ || y < 0 || y >= this->height_)
    return color_off;
  switch (this->type_) {
    case IMAGE_TYPE_BINARY:
      return this->get_binary_pixel_(x, y) ? color_on : color_off;
    case IMAGE_TYPE_GRAYSCALE:
      return this->get_grayscale_pixel_(x, y);
    case IMAGE_TYPE_RGB565:
      return this->get_rgb565_pixel_(x, y);
    case IMAGE_TYPE_RGB24:
      return this->get_rgb24_pixel_(x, y);
    case IMAGE_TYPE_RGBA:
      return this->get_rgba_pixel_(x, y);
    default:
      return color_off;
  }
 }
 bool Image::get_binary_pixel_(int x, int y) const {
  const uint32_t width_8 = ((this->width_ + 7u) / 8u) * 8u;
  const uint32_t pos = x + y * width_8;
  return progmem_read_byte(this->data_start_ + (pos / 8u)) & (0x80 >> (pos % 8u));
 }
 Color Image::get_rgba_pixel_(int x, int y) const {
  const uint32_t pos = (x + y * this->width_) * 4;
  return Color(progmem_read_byte(this->data_start_ + pos + 0), progmem_read_byte(this->data_start_ + pos + 1),
               progmem_read_byte(this->data_start_ + pos + 2), progmem_read_byte(this->data_start_ + pos + 3));
 }
 Color Image::get_rgb24_pixel_(int x, int y) const {
  const uint32_t pos = (x + y * this->width_) * 3;
  Color color = Color(progmem_read_byte(this->data_start_ + pos + 0), progmem_read_byte(this->data_start_ + pos + 1),
                      progmem_read_byte(this->data_start_ + pos + 2));
  if (color.b == 1 && color.r == 0 && color.g == 0 && transparent_) {
    // (0, 0, 1) has been defined as transparent color for non-alpha images.
    // putting blue == 1 as a first condition for performance reasons (least likely value to short-cut the if)
    color.w = 0;
  } else {
    color.w = 0xFF;
  }
  return color;
 }
 Color Image::get_rgb565_pixel_(int x, int y) const {
  const uint32_t pos = (x + y * this->width_) * 2;
  uint16_t rgb565 =
      progmem_read_byte(this->data_start_ + pos + 0) << 8 | progmem_read_byte(this->data_start_ + pos + 1);
  auto r = (rgb565 & 0xF800) >> 11;
  auto g = (rgb565 & 0x07E0) >> 5;
  auto b = rgb565 & 0x001F;
  Color color = Color((r << 3) | (r >> 2), (g << 2) | (g >> 4), (b << 3) | (b >> 2));
  if (rgb565 == 0x0020 && transparent_) {
    // darkest green has been defined as transparent color for transparent RGB565 images.
    color.w = 0;
  } else {
    color.w = 0xFF;
  }
  return color;
 }
 Color Image::get_grayscale_pixel_(int x, int y) const {
  const uint32_t pos = (x + y * this->width_);
  const uint8_t gray = progmem_read_byte(this->data_start_ + pos);
  uint8_t alpha = (gray == 1 && transparent_) ? 0 : 0xFF;
  return Color(gray, gray, gray, alpha);
 }
 int Image::get_width() const { return this->width_; }
 int Image::get_height() const { return this->height_; }
 ImageType Image::get_type() const { return this->type_; }
 Image::Image(const uint8_t *data_start, int width, int height, ImageType type)
    : width_(width), height_(height), type_(type), data_start_(data_start) {}
 }  // namespace display
 }  // namespace esphome
--- a/esphome/components/display/image.h
+++ b/esphome/components/display/image.h
@ -0,0 +1,75 @@
 #pragma once
 #include "esphome/core/color.h"
 namespace esphome {
 namespace display {
 enum ImageType {
  IMAGE_TYPE_BINARY = 0,
  IMAGE_TYPE_GRAYSCALE = 1,
  IMAGE_TYPE_RGB24 = 2,
  IMAGE_TYPE_RGB565 = 3,
  IMAGE_TYPE_RGBA = 4,
 };
 inline int image_type_to_bpp(ImageType type) {
  switch (type) {
    case IMAGE_TYPE_BINARY:
      return 1;
    case IMAGE_TYPE_GRAYSCALE:
      return 8;
    case IMAGE_TYPE_RGB565:
      return 16;
    case IMAGE_TYPE_RGB24:
      return 24;
    case IMAGE_TYPE_RGBA:
      return 32;
  }
  return 0;
 }
 inline int image_type_to_width_stride(int width, ImageType type) { return (width * image_type_to_bpp(type) + 7u) / 8u; }
 /// Turn the pixel OFF.
 extern const Color COLOR_OFF;
 /// Turn the pixel ON.
 extern const Color COLOR_ON;
 class DisplayBuffer;
 class BaseImage {
 public:
  virtual void draw(int x, int y, DisplayBuffer *display, Color color_on, Color color_off) = 0;
  virtual int get_width() const = 0;
  virtual int get_height() const = 0;
 };
 class Image : public BaseImage {
 public:
  Image(const uint8_t *data_start, int width, int height, ImageType type);
  Color get_pixel(int x, int y, Color color_on = COLOR_ON, Color color_off = COLOR_OFF) const;
  int get_width() const override;
  int get_height() const override;
  ImageType get_type() const;
  void draw(int x, int y, DisplayBuffer *display, Color color_on, Color color_off) override;
  void set_transparency(bool transparent) { transparent_ = transparent; }
  bool has_transparency() const { return transparent_; }
 protected:
  bool get_binary_pixel_(int x, int y) const;
  Color get_rgb24_pixel_(int x, int y) const;
  Color get_rgba_pixel_(int x, int y) const;
  Color get_rgb565_pixel_(int x, int y) const;
  Color get_grayscale_pixel_(int x, int y) const;
  int width_;
  int height_;
  ImageType type_;
  const uint8_t *data_start_;
  bool transparent_;
 };
 }  // namespace display
 }  // namespace esphome
--- a/tests/test2.yaml
+++ b/tests/test2.yaml
@ -695,6 +695,13 @@ image:
    file: mdi:alert-outline
    type: BINARY
 graph:
  - id: my_graph
    sensor: ha_hello_world_temperature
    duration: 1h
    width: 100
    height: 100
 cap1188:
  id: cap1188_component
  address: 0x29