02764cd443be15005858fb10df020f4f1f770d66/fr/canvas__animated_8cpp_source.html

// Copyright 2021 Arthur Sonzogni. All rights reserved.

// L'utilisation de ce code source est régie par la licence MIT qui peut être trouvée dans

// le fichier LICENSED.

#include <cmath>                   // for sin, cos

#include <ftxui/dom/elements.hpp>  // for canvas, Element, separator, hbox, operator|, border

#include <ftxui/screen/screen.hpp>  // for Pixel

#include <memory>   // for allocator, shared_ptr, __shared_ptr_access

#include <string>   // for string, basic_string

#include <utility>  // for move

#include <vector>   // for vector, __alloc_traits<>::value_type


#include "ftxui/component/component.hpp"  // for Renderer, CatchEvent, Horizontal, Menu, Tab

#include "ftxui/component/component_base.hpp"      // for ComponentBase

#include "ftxui/component/event.hpp"               // for Event

#include "ftxui/component/mouse.hpp"               // for Mouse

#include "ftxui/component/screen_interactive.hpp"  // for ScreenInteractive

#include "ftxui/dom/canvas.hpp"                    // for Canvas

#include "ftxui/screen/color.hpp"  // for Color, Color::Red, Color::Blue, Color::Green, ftxui


int main() {

  using namespace ftxui;


  int mouse_x = 0;

  int mouse_y = 0;


  // Un triangle suivant la souris, utilisant des caractères braille.

  auto renderer_line_braille = Renderer([&] {

    auto c = Canvas(100, 100);

    c.DrawText(0, 0, "Plusieurs lignes (braille)");

    c.DrawPointLine(mouse_x, mouse_y, 80, 10, Color::Red);

    c.DrawPointLine(80, 10, 80, 40, Color::Blue);

    c.DrawPointLine(80, 40, mouse_x, mouse_y, Color::Green);

    return canvas(std::move(c));

  });


  // Un triangle suivant la souris, utilisant des caractères de bloc.

  auto renderer_line_block = Renderer([&] {

    auto c = Canvas(100, 100);

    c.DrawText(0, 0, "Plusieurs lignes (bloc)");

    c.DrawBlockLine(mouse_x, mouse_y, 80, 10, Color::Red);

    c.DrawBlockLine(80, 10, 80, 40, Color::Blue);

    c.DrawBlockLine(80, 40, mouse_x, mouse_y, Color::Green);

    return canvas(std::move(c));

  });


  // Un cercle suivant la souris, utilisant des caractères braille.

  auto renderer_circle_braille = Renderer([&] {

    auto c = Canvas(100, 100);

    c.DrawText(0, 0, "Un cercle (braille)");

    c.DrawPointCircle(mouse_x, mouse_y, 30);

    return canvas(std::move(c));

  });


  // Un cercle suivant la souris, utilisant des caractères de bloc.

  auto renderer_circle_block = Renderer([&] {

    auto c = Canvas(100, 100);

    c.DrawText(0, 0, "Un cercle (bloc)");

    c.DrawBlockCircle(mouse_x, mouse_y, 30);

    return canvas(std::move(c));

  });


  // Un cercle rempli suivant la souris, utilisant des caractères braille.

  auto renderer_circle_filled_braille = Renderer([&] {

    auto c = Canvas(100, 100);

    c.DrawText(0, 0, "Un cercle rempli (braille)");

    c.DrawPointCircleFilled(mouse_x, mouse_y, 30);

    return canvas(std::move(c));

  });


  // Un cercle rempli suivant la souris, utilisant des caractères de bloc.

  auto renderer_circle_filled_block = Renderer([&] {

    auto c = Canvas(100, 100);

    c.DrawText(0, 0, "Un cercle rempli (bloc)");

    c.DrawBlockCircleFilled(mouse_x, mouse_y, 30);

    return canvas(std::move(c));

  });


  // Une ellipse suivant la souris, utilisant des caractères braille.

  auto renderer_ellipse_braille = Renderer([&] {

    auto c = Canvas(100, 100);

    c.DrawText(0, 0, "Une ellipse (braille)");

    c.DrawPointEllipse(mouse_x / 2, mouse_y / 2, mouse_x / 2, mouse_y / 2);

    return canvas(std::move(c));

  });


  // Une ellipse suivant la souris, utilisant des caractères de bloc.

  auto renderer_ellipse_block = Renderer([&] {

    auto c = Canvas(100, 100);

    c.DrawText(0, 0, "Une ellipse (bloc)");

    c.DrawBlockEllipse(mouse_x / 2, mouse_y / 2, mouse_x / 2, mouse_y / 2);

    return canvas(std::move(c));

  });


  // Une ellipse remplie suivant la souris, utilisant des caractères braille.

  auto renderer_ellipse_filled_braille = Renderer([&] {

    auto c = Canvas(100, 100);

    c.DrawText(0, 0, "Une ellipse remplie (braille)");

    c.DrawPointEllipseFilled(mouse_x / 2, mouse_y / 2, mouse_x / 2,

                             mouse_y / 2);

    return canvas(std::move(c));

  });


  // Une ellipse remplie suivant la souris, utilisant des caractères de bloc.

  auto renderer_ellipse_filled_block = Renderer([&] {

    auto c = Canvas(100, 100);

    c.DrawText(0, 0, "Une ellipse remplie (bloc)");

    c.DrawBlockEllipseFilled(mouse_x / 2, mouse_y / 2, mouse_x / 2,

                             mouse_y / 2);

    c.DrawBlockEllipse(mouse_x / 2, mouse_y / 2, mouse_x / 2, mouse_y / 2);

    return canvas(std::move(c));

  });


  // Un texte suivant la souris

  auto renderer_text = Renderer([&] {

    auto c = Canvas(100, 100);

    c.DrawText(0, 0, "Un morceau de texte");

    c.DrawText(mouse_x, mouse_y, "Ceci est un morceau de texte avec des effets",

               [](Pixel& p) {

                 p.foreground_color = Color::Red;

                 p.underlined = true;

                 p.bold = true;

               });

    return canvas(std::move(c));

  });


  auto renderer_plot_1 = Renderer([&] {

    auto c = Canvas(100, 100);

    c.DrawText(0, 0, "Un graphique");


    std::vector<int> ys(100);

    for (int x = 0; x < 100; x++) {

      float dx = float(x - mouse_x);

      float dy = 50.f;

      ys[x] = int(dy + 20 * cos(dx * 0.14) + 10 * sin(dx * 0.42));

    }

    for (int x = 1; x < 99; x++) {

      c.DrawPointLine(x, ys[x], x + 1, ys[x + 1]);

    }


    return canvas(std::move(c));

  });


  auto renderer_plot_2 = Renderer([&] {

    auto c = Canvas(100, 100);

    c.DrawText(0, 0, "Un graphique symétrique rempli");

    std::vector<int> ys(100);

    for (int x = 0; x < 100; x++) {

      ys[x] = int(30 +                                  //

                  10 * cos(x * 0.2 - mouse_x * 0.05) +  //

                  5 * sin(x * 0.4) +                    //

                  5 * sin(x * 0.3 - mouse_y * 0.05));   //

    }

    for (int x = 0; x < 100; x++) {

      c.DrawPointLine(x, 50 + ys[x], x, 50 - ys[x], Color::Red);

    }


    return canvas(std::move(c));

  });


  auto renderer_plot_3 = Renderer([&] {

    auto c = Canvas(100, 100);

    c.DrawText(0, 0, "Un tracé gaussien 2D");

    int size = 15;


    // mouse_x = 5mx + 3*my

    // mouse_y = 0mx + -5my + 90

    float my = (mouse_y - 90) / -5.f;

    float mx = (mouse_x - 3 * my) / 5.f;

    std::vector<std::vector<float>> ys(size, std::vector<float>(size));

    for (int y = 0; y < size; y++) {

      for (int x = 0; x < size; x++) {

        float dx = x - mx;

        float dy = y - my;

        ys[y][x] = -1.5 + 3.0 * std::exp(-0.2f * (dx * dx + dy * dy));

      }

    }

    for (int y = 0; y < size; y++) {

      for (int x = 0; x < size; x++) {

        if (x != 0) {

          c.DrawPointLine(

              5 * (x - 1) + 3 * (y - 0), 90 - 5 * (y - 0) - 5 * ys[y][x - 1],

              5 * (x - 0) + 3 * (y - 0), 90 - 5 * (y - 0) - 5 * ys[y][x]);

        }

        if (y != 0) {

          c.DrawPointLine(

              5 * (x - 0) + 3 * (y - 1), 90 - 5 * (y - 1) - 5 * ys[y - 1][x],

              5 * (x - 0) + 3 * (y - 0), 90 - 5 * (y - 0) - 5 * ys[y][x]);

        }

      }

    }


    return canvas(std::move(c));

  });


  int selected_tab = 12;

  auto tab = Container::Tab(

      {

          renderer_line_braille,

          renderer_line_block,

          renderer_circle_braille,

          renderer_circle_block,

          renderer_circle_filled_braille,

          renderer_circle_filled_block,

          renderer_ellipse_braille,

          renderer_ellipse_block,

          renderer_ellipse_filled_braille,

          renderer_ellipse_filled_block,


          renderer_plot_1,

          renderer_plot_2,

          renderer_plot_3,


          renderer_text,

      },

      &selected_tab);


  // Ceci capture la dernière position de la souris.

  auto tab_with_mouse = CatchEvent(tab, [&](Event e) {

    if (e.is_mouse()) {

      mouse_x = (e.mouse().x - 1) * 2;

      mouse_y = (e.mouse().y - 1) * 4;

    }

    return false;

  });


  std::vector<std::string> tab_titles = {

      "ligne (braille)",

      "ligne (bloc)",

      "cercle (braille)",

      "cercle (bloc)",

      "cercle rempli (braille)",

      "cercle rempli (bloc)",

      "ellipse (braille)",

      "ellipse (bloc)",

      "ellipse remplie (braille)",

      "ellipse remplie (bloc)",

      "graphique_1 simple",

      "graphique_2 rempli",

      "graphique_3 3D",

      "texte",

  };

  auto tab_toggle = Menu(&tab_titles, &selected_tab);


  auto component = Container::Horizontal({

      tab_with_mouse,

      tab_toggle,

  });


  // Ajoute un séparateur pour décorer l\'ensemble du composant :

  auto component_renderer = Renderer(component, [&] {

    return hbox({

               tab_with_mouse->Render(),

               separator(),

               tab_toggle->Render(),

           }) |

           border;

  });


  auto screen = ScreenInteractive::FitComponent();

  screen.Loop(component_renderer);


  return 0;

}


canvas.hpp

main
int main()
Definition canvas_animated.cpp:20

color.hpp

component.hpp

component_base.hpp

screen
auto screen
Definition composition.cpp:56

elements.hpp

event.hpp

ftxui::Event::is_mouse
bool is_mouse() const
Definition event.hpp:108

ftxui::Event::mouse
struct Mouse mouse
Definition event.hpp:143

ftxui::Event
Représente un événement. Il peut s'agir d'un événement de touche, d'un redimensionnement de terminal,...
Definition event.hpp:28

ftxui::Canvas
Canvas est un tampon dessinable associé aux opérations de dessin.
Definition canvas.hpp:38

ftxui::Pixel::foreground_color
Color foreground_color
Definition pixel.hpp:49

ftxui::Pixel::bold
bool bold
Definition pixel.hpp:29

ftxui::Pixel::underlined
bool underlined
Definition pixel.hpp:33

ftxui::Pixel
Un caractère Unicode et son style associé.
Definition pixel.hpp:15

mouse.hpp

ftxui
L'espace de noms FTXUI ftxui::
Definition animation.hpp:10

screen.hpp

screen_interactive.hpp