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@@ -2,11 +2,11 @@
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void draw_game(Game_Data *data)
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{
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//draw the player and the lines
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- drawPlayer(&(data->cam), data->player_angle, data->nb_lines);
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- drawDiagonals(data->cam, data->nb_lines);
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+ drawPlayer(&(data->cam), data->player_angle, data->nb_lines, data->line_transition);
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+ drawDiagonals(data->cam, data->nb_lines, data->line_transition);
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//showing the walls
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- if(data->list != NULL)
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- drawWalls(data->list, &(data->cam), data->nb_lines);
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+ //if(data->list != NULL)
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+ // drawWalls(data->list, &(data->cam), data->nb_lines);
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}
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void draw_title(Game_Data *data)
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{
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@@ -25,37 +25,51 @@ void draw_game_over(Game_Data *data)
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//at first, was supposed to draw an hexagon in the center, plus a triangle to show the player,
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//but the hexagon was not visible, and it was a pixel mess, so we're showing a circle instead.
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//there is still for code to calculate the vertices of the hexagon, in case we want to change that again
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-void drawPlayer(Camera *cam, int player_angle, int nb_lines)
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+void drawPlayer(Camera *cam, int player_angle, int nb_lines, Line_Transition line_transition)
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{
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- int x[32];
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- int y[32];
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- int i = 0;
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- int angle = 0;
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- for(i = 0; i < nb_lines; ++i)
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- {
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- angle = i * 360 / nb_lines;
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- x[i] = (8. + cam->zoom)*cos(PI * (angle + cam->angle)/180.) + cam->cX;
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- y[i] = (8. + cam->zoom)*sin(PI * (angle + cam->angle)/180.) + cam->cY;
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- }
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+ int x[32];
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+ int y[32];
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+ int i = 0;
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+ int angle = 0;
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+ for(i = 0; i < nb_lines; ++i)
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+ {
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+ angle = i * 360/nb_lines;
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+ x[i] = (8. + cam->zoom)*cos(PI * (angle + cam->angle)/180.) + cam->cX;
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+ y[i] = (8. + cam->zoom)*sin(PI * (angle + cam->angle)/180.) + cam->cY;
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+ }
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//draw the aforementionned circle, depending on the camera's center
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- //ML_filled_circle(cam.cX, cam.cY, 6, BLACK);
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+ //ML_filled_circle(cam.cX, cam.cY, 6, BLACK);
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ML_polygone(x, y, nb_lines, BLACK);
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//draw the player. At such a low scale, it was impossible to draw a rotating triangle, so its a radius 1 circle instead.
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- ML_filled_circle((9. + cam->zoom)*cos( PI*(player_angle + cam->angle)/180) + cam->cX, (9. + cam->zoom)*sin( PI*(player_angle+cam->angle)/180) + cam->cY, 1, BLACK);
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+ ML_filled_circle((9. + cam->zoom)*cos( PI*(player_angle + cam->angle)/180) + cam->cX, (9. + cam->zoom)*sin( PI*(player_angle+cam->angle)/180) + cam->cY, 1, BLACK);
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}
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//draws one of the three rotating lines
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-void drawDiagonals(Camera cam, int nb_lines)
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+void drawDiagonals(Camera cam, int nb_lines, Line_Transition line_transition)
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{
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int tmp_angle = cam.angle;
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float tmp_angle_rad = 0.0f;
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int i = 0;
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-
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+
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float x1 = 0.0f, y1 = 0.0f, x2 = 0.0f, y2 = 0.0f;
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- do{
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+ float delta_angle = 0.0;
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+
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+ float coeff = 0.0;
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+ float transition_angle = 0.0;
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+
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+ delta_angle = 360.0 / nb_lines;
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+
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+ if(line_transition.delta_nb_lines == 1)
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+ nb_lines ++;
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+
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+ if(line_transition.counter_start != 0)
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+ coeff = (float)line_transition.counter / (float)line_transition.counter_start;
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+ transition_angle = delta_angle * coeff;
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+
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+ do{
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tmp_angle_rad = tmp_angle * PI / 180.0f;
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x1 = 9.0f * cos(tmp_angle_rad);
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y1 = 9.0f * sin(tmp_angle_rad);
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@@ -63,8 +77,31 @@ void drawDiagonals(Camera cam, int nb_lines)
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y2 = 64.0f * sin(tmp_angle_rad);
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ML_line(x1 + cam.cX, y1 + cam.cY, x2 + cam.cX, y2 + cam.cY, BLACK);
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- tmp_angle += (360 / nb_lines);
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- if(tmp_angle >= 360)tmp_angle = tmp_angle - 359;
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i++;
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+
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+ switch(line_transition.delta_nb_lines){
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+ case 0:
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+ tmp_angle += 360/nb_lines;
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+ break;
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+
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+ case 1:
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+ if(i < nb_lines - 1)
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+ {
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+ tmp_angle += (360 - (delta_angle - transition_angle)) / (nb_lines - 1);
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+ }else{
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+ tmp_angle += delta_angle - transition_angle;
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+ }
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+ break;
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+
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+ case -1:
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+ if(i < nb_lines - 1)
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+ {
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+ tmp_angle += (360 - transition_angle) / (nb_lines - 1);
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+ }else{
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+ tmp_angle += transition_angle;
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+ }
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+ break;
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+ }
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+ if(tmp_angle >= 360)tmp_angle = tmp_angle - 359;
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}while(i < nb_lines);
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}
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Adrien Boucaud