UgPod/old_app.py

import pyray as pr
import math
from ctypes import c_float
from gapless_player import GaplessPlayer, Song, song_data_to_Song
from scrolling_text import ScrollingText
import numpy as np
import threading
import time
import os
from jelly import server, client

# # --- Configuration Constants ---
# INITIAL_SCREEN_WIDTH = 240
# INITIAL_SCREEN_HEIGHT = 240
# TARGET_FPS =60

# # --- State Variables ---
# state = {
#     "screen_width": INITIAL_SCREEN_WIDTH,
#     "screen_height": INITIAL_SCREEN_HEIGHT,
# }

# # --- Utility Functions ---


# def format_time_mm_ss(seconds):
#     """Converts a time in seconds to an 'MM:SS' string format."""
#     seconds = int(seconds)
#     minutes = seconds // 60
#     seconds_remainder = seconds % 60
#     return f"{minutes:02d}:{seconds_remainder:02d}"


# def get_progress_bar_rect(screen_width, screen_height):
#     width = screen_width
#     height = screen_height*0.021
#     x = (screen_width - width) / 2
#     y = screen_height - height
#     return pr.Rectangle(x, y, width, height)


# def draw_progress_bar(rect, current_time, total_time):
#     if total_time > 0:
#         progress_ratio = current_time / total_time
#     else:
#         progress_ratio = 0.0

#     pr.draw_rectangle_rec(rect, pr.Color(100, 100, 100, 255))
#     progress_width = rect.width * progress_ratio
#     pr.draw_rectangle(
#         int(rect.x),
#         int(rect.y)+1,
#         int(progress_width),
#         int(rect.height),
#         pr.Color(200, 50, 50, 255),
#     )
#     # pr.draw_rectangle_lines_ex(rect, 2, pr.Color(50, 50, 50, 255))

#     time_text = f"{format_time_mm_ss(current_time)} / {format_time_mm_ss(total_time)}"
#     text_width = pr.measure_text(time_text, int(rect.height * 0.7))
#     # pr.draw_text(
#     #     time_text,
#     #     int(rect.x + rect.width / 2 - text_width / 2),
#     #     int(rect.y + rect.height * 0.15),
#     #     int(rect.height * 0.7),
#     #     pr.WHITE,
#     # )

# pr.set_config_flags(pr.ConfigFlags.FLAG_WINDOW_RESIZABLE)
# # pr.set_config_flags(pr.FLAG_MSAA_4X_HINT)
# #pr.set_config_flags(pr.FLAG_FULLSCREEN_MODE)
# pr.init_window(state["screen_width"], state["screen_height"], "UgPod")
# pr.set_target_fps(TARGET_FPS)

player = GaplessPlayer()

print("add queue")

player.add_to_queue(
    Song(
        "bruhh",
        "music/pink floyd/dark side of the moon/06 Money.flac",
        "Money",
        382.200000,
        "The Dark Side Of The Moon",
        "",
        "Pink Floyd",
    )
)

player.add_to_queue(
    Song(
        "bruhh",
        "music/pink floyd/dark side of the moon/07 Us and Them.flac",
        "Us and Them",
        470.333333,
        "The Dark Side Of The Moon",
        "",
        "Pink Floyd",
    )
)

# albums = client.jellyfin.user_items(
#     params={
#         "IncludeItemTypes": "MusicAlbum",
#         "SearchTerm": "Dawn FM",  # album name
#         "Recursive": True,
#     },
# )

# album = albums["Items"][0]  # pick the album you want
# album_id = album["Id"]


# tracks = client.jellyfin.user_items(
#     params={
#         "ParentId": album_id,
#         "IncludeItemTypes": "Audio",
#         "SortBy": "IndexNumber",
#         "SortOrder": "Ascending",
#     },
# )

# for track in tracks["Items"]:
#     player.add_to_queue(
#         song_data_to_Song(
#             track, server
#         )
#     )

# print("add queue done")
# player.load_state("data/player.json")
# close_event = threading.Event()
# def save_state_loop():
#     while not close_event.wait(10):
#         player.save_state("data/player.lock.json")
#         os.rename("data/player.lock.json", "data/player.json")
# # save_state_thread = threading.Thread(target=save_state_loop)
# # save_state_thread.start()

# current_path = None
# texture = None


# def load_texture(path):
#     global texture, current_path

#     if not path:
#         return

#     if path == current_path:
#         return

#     if texture is not None:
#         pr.unload_texture(texture)

#     texture = pr.load_texture(path)
#     current_path = path


# def draw_play_pause_button(pos: pr.Vector2, size: pr.Vector2, is_playing: bool) -> bool:
#     clicked = False

#     rect = pr.Rectangle(pos.x, pos.y, size.x, size.y)

#     # Optional hover background
#     if pr.check_collision_point_rec(pr.get_mouse_position(), rect):
#         pr.draw_rectangle_rec(rect, pr.fade(pr.BLACK, 0.4))
#         if pr.is_mouse_button_pressed(pr.MOUSE_LEFT_BUTTON):
#             clicked = True
#     cx = pos.x + size.x / 2
#     cy = pos.y + size.y / 2

#     icon_padding = size.x * 0.25
#     icon_size = size.x - icon_padding * 2

#     if is_playing:
#         # PAUSE (two bars centered, same visual weight as play)
#         bar_width = icon_size * 0.25
#         bar_height = icon_size

#         left_x = cx - bar_width - bar_width * 0.4
#         right_x = cx + bar_width * 0.4
#         top_y = 1+cy - bar_height / 2

#         pr.draw_rectangle(
#             int(left_x),
#             int(top_y),
#             int(bar_width),
#             int(bar_height),
#             pr.WHITE,
#         )
#         pr.draw_rectangle(
#             int(right_x),
#             int(top_y),
#             int(bar_width),
#             int(bar_height),
#             pr.WHITE,
#         )
#     else:
#         # PLAY (centered triangle)
#         p1 = pr.Vector2(cx - icon_size / 2, cy - icon_size / 2)
#         p2 = pr.Vector2(cx - icon_size / 2, cy + icon_size / 2)
#         p3 = pr.Vector2(cx + icon_size / 2, cy)

#         pr.draw_triangle(p1, p2, p3, pr.WHITE)

#     return clicked


# title = ScrollingText(
#     "",
#     15
# )

# # --- Main Game Loop ---
# while not pr.window_should_close():
#     # 1. Update
#     current_width = pr.get_screen_width()
#     current_height = pr.get_screen_height()

#     if pr.is_key_pressed(pr.KEY_F11):
#         pr.toggle_fullscreen()
#     if pr.is_key_pressed(pr.KeyboardKey.KEY_SPACE):
#         if player.playing:
#             player.pause()
#         else:
#             player.play()
#     if pr.is_key_pressed(pr.KeyboardKey.KEY_LEFT):
#         player.seek(player.position - 5)
#     if pr.is_key_pressed(pr.KeyboardKey.KEY_RIGHT):
#         player.seek(player.position + 5)

#     pr.begin_drawing()
#     pr.clear_background(pr.Color(40, 40, 40, 255))
#     dt = pr.get_frame_time()

#     progress_rect = get_progress_bar_rect(current_width, current_height)

#     # pr.draw_text(
#     #     "UgPod",
#     #     int(current_width * 0.05),
#     #     int(current_height * 0.05),
#     #     int(current_height * 0.05),
#     #     pr.SKYBLUE,
#     # )

#     current_song = player.get_current_song()


#     draw_progress_bar(
#         progress_rect,
#         player.position,
#         (current_song and current_song.duration) or 0.0,
#     )
#     if current_song:
#         load_texture(current_song.album_cover_path)
#         title_font_size = int(current_height*0.05)
#         album_cover_size = int(min(current_width, current_height*0.7))
#         title.speed = title_font_size*2.5
#         title_size = pr.Vector2(current_width-int(current_height * 0.01)*2, title_font_size)
#         title.update(dt,title_size)
#         title.set_text(f"{current_song.name} - {current_song.artist_name}", title_font_size)
#         title.draw(pr.Vector2(int(current_height * 0.01),int(current_height * 0.8)),title_size)
#         # pr.draw_text(
#         #     ,
#         #     ,
#         #     int(current_height * 0.03),
#         #     pr.WHITE,
#         # )
#         points = player.oscilloscope_data_points
#         if texture is not None:
#             scale = min(album_cover_size / texture.width, album_cover_size / texture.height)

#             dest_rect = pr.Rectangle(
#                 current_width//2 - album_cover_size//2,
#                 (current_height*0.8)//2 - album_cover_size//2,
#                 texture.width * scale,
#                 texture.height * scale,
#             )

#             src_rect = pr.Rectangle(0, 0, texture.width, texture.height)

#             pr.draw_texture_pro(
#                 texture, src_rect, dest_rect, pr.Vector2(0, 0), 0.0, pr.WHITE
#             )
#         else:
#             clip = pr.Rectangle(int(current_width//2 - album_cover_size//2),
#                 int((current_height*0.8)//2 - album_cover_size//2),
#                 int(album_cover_size),
#                 int(album_cover_size))
#             pr.begin_scissor_mode(
#                 int(clip.x),
#                 int(clip.y),
#                 int(clip.width),
#                 int(clip.height),
#             )
#             pr.draw_rectangle(
#                 int(clip.x),
#                 int(clip.y),
#                 int(clip.width),
#                 int(clip.height), pr.BLACK)

#             # cx = current_width * 0.5+1
#             # cy = current_height * 0.4+1

#             # MAX_LEN = album_cover_size * 0.25   # tune this
#             # MIN_ALPHA = 10
#             # MAX_ALPHA = 255

#             # for i in range(len(points) - 1):
#             #     x1 = cx + points[i][0]   * album_cover_size * 0.5
#             #     y1 = cy + -points[i][1]   * album_cover_size * 0.5
#             #     x2 = cx + points[i+1][0] * album_cover_size * 0.5
#             #     y2 = cy + -points[i+1][1] * album_cover_size * 0.5

#             #     dx = x2 - x1
#             #     dy = y2 - y1
#             #     length = (dx * dx + dy * dy) ** 0.5

#             #     # 1.0 = short line, 0.0 = long line
#             #     t = max(0.0, min(1.0, 1.0 - (length / MAX_LEN)))*math.pow(i/len(points), 2)

#             #     alpha = int(MIN_ALPHA + t * (MAX_ALPHA - MIN_ALPHA))

#             #     color = pr.Color(255, 255, 255, alpha)

#             #     pr.draw_line(int(x1), int(y1), int(x2), int(y2), color)
#         # draw background square
#         if len(points) >= 2:
#             samples = np.fromiter(
#                 ((p[0] + p[1]) * 0.5 for p in points),
#                 dtype=np.float32
#             )

#             # Guard: FFT must have meaningful size
#             if samples.size > 128:
                

#                 rect_x = int(current_width // 2 - album_cover_size // 2)
#                 rect_y = int((current_height * 0.8) // 2 - album_cover_size // 2)

#                 # ---- FFT ----

#                 FFT_SIZE = min(samples.size, 2048)
#                 window = np.hanning(FFT_SIZE)

#                 fft = np.fft.rfft(samples[:FFT_SIZE] * window)
#                 magnitudes = np.abs(fft)

#                 # remove DC component (important for visuals)
#                 magnitudes[0] = 0.0

#                 # ---- LOG BINNING ----

#                 num_bars = album_cover_size//10
#                 num_bins = magnitudes.size

#                 # logarithmic bin edges (low end stretched)
#                 log_min = 1
#                 log_max = math.log10(num_bins)

#                 log_edges = np.logspace(
#                     math.log10(log_min),
#                     log_max,
#                     num_bars + 1
#                 ).astype(int)

#                 bar_values = np.zeros(num_bars, dtype=np.float32)

#                 for i in range(num_bars):
#                     start = log_edges[i]
#                     end = log_edges[i + 1]

#                     if end <= start:
#                         continue

#                     bar_values[i] = np.mean(magnitudes[start:end])

# # ---- STATIC SCALING ----
                    
#                     # Instead of normalizing to the max of the frame, we scale by the FFT size.
#                     # For a Hanning windowed FFT, dividing by (FFT_SIZE / 4) maps 
#                     # maximum possible volume roughly to 1.0.
#                     bar_values = bar_values / (FFT_SIZE / 4.0)

#                     # ---- DRAW ----

#                     def map_to_screen(val):
#                         return rect_x + (math.log10(max(1, val)) / log_max) * album_cover_size

#                     spacing = 0

#                     for i in range(num_bars):
#                         # 1. Calculate integer pixel boundaries first
#                         # This ensures the right edge of one bar is exactly the left edge of the next
#                         x_start_int = int(map_to_screen(log_edges[i]))
#                         x_end_int = int(map_to_screen(log_edges[i+1]))
                        
#                         # 2. Width is the difference between these fixed integer points
#                         w = (x_end_int - x_start_int) - spacing
                        
#                         value = bar_values[i]
#                         h = int(min(1.0, value) * album_cover_size)
                        
#                         # 3. Anchor to bottom
#                         y = (rect_y + album_cover_size) - h

#                         alpha = min(1.0, ((value+1)**2)-1)
#                         r = 255
#                         g = 0
#                         b = 0
                        
#                         # Keep alpha at 255 (fully opaque)
#                         color = pr.Color(r, g, b, int(255 * alpha))

#                         # 4. Draw the bar
#                         # Use max(1, w) to ensure high-frequency bars don't disappear on small screens
#                         pr.draw_rectangle(
#                             x_start_int,
#                             int(y),
#                             max(1, int(w)), 
#                             h,
#                             color
#                         )
#             pr.end_scissor_mode()

#     pos = pr.Vector2(current_width * 0.5 - current_height * 0.05, current_height * 0.9-progress_rect.height)
#     size = pr.Vector2(current_height * 0.1, current_height * 0.1)

#     if draw_play_pause_button(pos, size, player.playing):
#         if player.playing:
#             player.pause()
#         else:
#             player.play()
#     pr.end_drawing()

# # Cleanup
# if texture is not None:
#     pr.unload_texture(texture)

# pr.close_window()
# close_event.set()
# # save_state_thread.join()




player.play()
# while True:
#     time.sleep(1)