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from utils import download_url
import argparse
import numpy as np
import PIL.Image
import dnnlib
import dnnlib.tflib as tflib
import re
import sys
from io import BytesIO
import IPython.display
from math import ceil
from PIL import Image, ImageDraw
import os
import pickle
from utils import log_progress, imshow, create_image_grid, show_animation
import imageio
import glob
import gdown 
import gradio as gr

class Rasm:

    def __init__(self, mode = 'calligraphy'):

        if mode == 'calligraphy':
            url = 'https://drive.google.com/uc?id=138fdURGxdkOwZq7IWvnrGLcfo5VI8O1R'

        else:
            url = 'https://drive.google.com/uc?id=13h-alXGI0hbNOJy1qbmeoroXZSPBHEG2'

        output = 'model.pkl'
        print('Downloading networks from "%s"...' %url)
        gdown.download(url, output, quiet=False)
        dnnlib.tflib.init_tf()
        with dnnlib.util.open_url(output) as fp:
            self._G, self._D, self.Gs = pickle.load(fp)
        self.noise_vars = [var for name, var in self.Gs.components.synthesis.vars.items() if name.startswith('noise')]
    
    # Generates a list of images, based on a list of latent vectors (Z), and a list (or a single constant) of truncation_psi's.
    def generate_images_in_w_space(self, dlatents, truncation_psi):
        Gs_kwargs = dnnlib.EasyDict()
        Gs_kwargs.output_transform = dict(func=tflib.convert_images_to_uint8, nchw_to_nhwc=True)
        Gs_kwargs.randomize_noise = False
        Gs_kwargs.truncation_psi = truncation_psi
        # dlatent_avg = self.Gs.get_var('dlatent_avg') # [component]

        imgs = []
        for _, dlatent in log_progress(enumerate(dlatents), name = "Generating images"):
            #row_dlatents = (dlatent[np.newaxis] - dlatent_avg) * np.reshape(truncation_psi, [-1, 1, 1]) + dlatent_avg
            # dl = (dlatent-dlatent_avg)*truncation_psi   + dlatent_avg
            row_images = self.Gs.components.synthesis.run(dlatent,  **Gs_kwargs)
            imgs.append(PIL.Image.fromarray(row_images[0], 'RGB'))
        return imgs       

    def generate_images(self, zs, truncation_psi, class_idx = None):
        Gs_kwargs = dnnlib.EasyDict()
        Gs_kwargs.output_transform = dict(func=tflib.convert_images_to_uint8, nchw_to_nhwc=True)
        Gs_kwargs.randomize_noise = False
        if not isinstance(truncation_psi, list):
            truncation_psi = [truncation_psi] * len(zs)
            
        imgs = []
        label = np.zeros([1] + self.Gs.input_shapes[1][1:])
        if class_idx is not None:
            label[:, class_idx] = 1
        else:
            label = None
        for z_idx, z in log_progress(enumerate(zs), size = len(zs), name = "Generating images"):
            Gs_kwargs.truncation_psi = truncation_psi[z_idx]
            noise_rnd = np.random.RandomState(1) # fix noise
            tflib.set_vars({var: noise_rnd.randn(*var.shape.as_list()) for var in self.noise_vars}) # [height, width]
            images = self.Gs.run(z, label, **Gs_kwargs) # [minibatch, height, width, channel]
            imgs.append(PIL.Image.fromarray(images[0], 'RGB'))
        return imgs
    
    def generate_from_zs(self, zs, truncation_psi = 0.5):
        Gs_kwargs = dnnlib.EasyDict()
        Gs_kwargs.output_transform = dict(func=tflib.convert_images_to_uint8, nchw_to_nhwc=True)
        Gs_kwargs.randomize_noise = False
        if not isinstance(truncation_psi, list):
            truncation_psi = [truncation_psi] * len(zs)
            
        for z_idx, z in log_progress(enumerate(zs), size = len(zs), name = "Generating images"):
            Gs_kwargs.truncation_psi = truncation_psi[z_idx]
            noise_rnd = np.random.RandomState(1) # fix noise
            tflib.set_vars({var: noise_rnd.randn(*var.shape.as_list()) for var in self.noise_vars}) # [height, width]
            images = self.Gs.run(z, None, **Gs_kwargs) # [minibatch, height, width, channel]
            img = PIL.Image.fromarray(images[0], 'RGB')
            imshow(img)

    def generate_random_zs(self, size):
        seeds = np.random.randint(2**32, size=size)
        zs = []
        for _, seed in enumerate(seeds):
            rnd = np.random.RandomState(seed)
            z = rnd.randn(1, *self.Gs.input_shape[1:]) # [minibatch, component]
            zs.append(z)
        return zs


    def generate_zs_from_seeds(self, seeds):
        zs = []
        for _, seed in enumerate(seeds):
            rnd = np.random.RandomState(seed)
            z = rnd.randn(1, *self.Gs.input_shape[1:]) # [minibatch, component]
            zs.append(z)
        return zs

    # Generates a list of images, based on a list of seed for latent vectors (Z), and a list (or a single constant) of truncation_psi's.
    def generate_images_from_seeds(self, seeds, truncation_psi):
        ima = self.generate_images(self.generate_zs_from_seeds(seeds), truncation_psi)[0]
        return ima, imshow(ima)

    def generate_randomly(self, truncation_psi = 0.5):
        ima, dis = self.generate_images_from_seeds(np.random.randint(4294967295, size=1), truncation_psi=truncation_psi)
        return ima, dis 

    def generate_grid(self, truncation_psi = 0.7): 
      seeds = np.random.randint((2**32 - 1), size=9)
      return create_image_grid(self.generate_images(self.generate_zs_from_seeds(seeds), truncation_psi), 0.7 , 3)
    
    def generate_animation(self, size = 9, steps = 10, trunc_psi = 0.5):
      seeds = list(np.random.randint((2**32) - 1, size=size))
      seeds = seeds + [seeds[0]]
      zs = self.generate_zs_from_seeds(seeds)

      imgs = self.generate_images(self.interpolate(zs, steps = steps), trunc_psi)
      movie_name = 'animation.mp4'
      with imageio.get_writer(movie_name, mode='I') as writer:
        for image in log_progress(list(imgs), name = "Creating animation"):
            writer.append_data(np.array(image))
      return show_animation(movie_name)

    def convertZtoW(self, latent, truncation_psi=0.7, truncation_cutoff=9):
        dlatent = self.Gs.components.mapping.run(latent, None) # [seed, layer, component]
        dlatent_avg = self.Gs.get_var('dlatent_avg') # [component]
        for i in range(truncation_cutoff):
            dlatent[0][i] = (dlatent[0][i]-dlatent_avg)*truncation_psi + dlatent_avg
            
        return dlatent

    def interpolate(self, zs, steps = 10):
        out = []
        for i in range(len(zs)-1):
            for index in range(steps):
                fraction = index/float(steps) 
                out.append(zs[i+1]*fraction + zs[i]*(1-fraction))
        return out
        
        
                        #-------------------- Rasm Demo--------------------------
                        
def model(mode, output):
  model=rasm.Rasm(mode=mode)
  if output=='Generate Art Randomly':
   ima,res= model.generate_randomly()
  elif output=='Generate Art Grid':
    ima = model.generate_grid()
  elif output=='Generate Art Animation':
    ima = model.generate_animation(size = 2, steps = 20)
  return ima
  
imageout=gr.outputs.Image(model,
    [
     gr.Radio(["calligraphy", "mosaics"],label="Type of Arbic Art"),
     gr.Radio(["Generate Art Randomly", "Generate Art Grid", "Generate Art Animation"],label="How do you prefer the output visualization" ),
    ],
    outputs=imageout
)
demo.launch()