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import gradio as gr
import spaces
from clip_slider_pipeline import CLIPSliderFlux
from diffusers import FluxPipeline
import torch
import numpy as np
import cv2
from PIL import Image
from diffusers.utils import load_image
from diffusers.pipelines.flux.pipeline_flux_controlnet import FluxControlNetPipeline
from diffusers.models.controlnet_flux import FluxControlNetModel


def process_controlnet_img(image):
    controlnet_img = np.array(image)
    controlnet_img = cv2.Canny(controlnet_img, 100, 200)
    controlnet_img = HWC3(controlnet_img)
    controlnet_img = Image.fromarray(controlnet_img)

# load pipelines
pipe = FluxPipeline.from_pretrained("black-forest-labs/FLUX.1-schnell", 
                                    torch_dtype=torch.bfloat16)
#pipe.enable_model_cpu_offload()
clip_slider = CLIPSliderFlux(pipe, device=torch.device("cuda"))

base_model = 'black-forest-labs/FLUX.1-schnell'
controlnet_model = 'InstantX/FLUX.1-dev-Controlnet-Canny-alpha'
# controlnet = FluxControlNetModel.from_pretrained(controlnet_model, torch_dtype=torch.bfloat16)
# pipe_controlnet = FluxControlNetPipeline.from_pretrained(base_model, controlnet=controlnet, torch_dtype=torch.bfloat16)
# t5_slider_controlnet = T5SliderFlux(sd_pipe=pipe_controlnet,device=torch.device("cuda"))


@spaces.GPU(duration=200)
def generate(slider_x, prompt, seed, recalc_directions, iterations, steps, guidance_scale,
             x_concept_1, x_concept_2, 
             avg_diff_x, 
             img2img_type = None, img = None, 
             controlnet_scale= None, ip_adapter_scale=None,
             
             ):

    # check if avg diff for directions need to be re-calculated
    print("slider_x", slider_x)
    print("x_concept_1", x_concept_1, "x_concept_2", x_concept_2)
    torch.manual_seed(seed)
    
    if not sorted(slider_x) == sorted([x_concept_1, x_concept_2]) or recalc_directions:
        avg_diff = clip_slider.find_latent_direction(slider_x[0], slider_x[1], num_iterations=iterations).to(torch.float16)
        x_concept_1, x_concept_2 = slider_x[0], slider_x[1]

    if img2img_type=="controlnet canny" and img is not None:
        control_img = process_controlnet_img(img)
        image = clip_slider.generate(prompt, guidance_scale=guidance_scale, image=control_img, controlnet_conditioning_scale =controlnet_scale, scale=0, scale_2nd=0, seed=seed, num_inference_steps=steps, avg_diff=avg_diff, avg_diff_2nd=avg_diff_2nd)
    elif img2img_type=="ip adapter" and img is not None:
        image = clip_slider.generate(prompt, guidance_scale=guidance_scale, ip_adapter_image=img, scale=0, scale_2nd=0, seed=seed, num_inference_steps=steps, avg_diff=avg_diff, avg_diff_2nd=avg_diff_2nd)
    else: # text to image
        image = clip_slider.generate(prompt, guidance_scale=guidance_scale, scale=0, scale_2nd=0, seed=seed, num_inference_steps=steps, avg_diff=avg_diff)
    
    
    #comma_concepts_x = ', '.join(slider_x)
    comma_concepts_x = f"{slider_x[1]}, {slider_x[0]}"

    avg_diff_x = avg_diff.cpu()
  
    return gr.update(label=comma_concepts_x, interactive=True), x_concept_1, x_concept_2, avg_diff_x, image

@spaces.GPU
def update_scales(x,prompt,seed, steps, guidance_scale,
                  avg_diff_x, 
                  img2img_type = None, img = None,
                  controlnet_scale= None, ip_adapter_scale=None,):
    avg_diff = avg_diff_x.cuda()
    torch.manual_seed(seed)
    if img2img_type=="controlnet canny" and img is not None:
        control_img = process_controlnet_img(img)
        image = t5_slider_controlnet.generate(prompt, guidance_scale=guidance_scale, image=control_img, controlnet_conditioning_scale =controlnet_scale, scale=x, seed=seed, num_inference_steps=steps, avg_diff=avg_diff) 
    elif img2img_type=="ip adapter" and img is not None:
        image = clip_slider.generate(prompt, guidance_scale=guidance_scale, ip_adapter_image=img, scale=x,seed=seed, num_inference_steps=steps, avg_diff=avg_diff) 
    else:     
        image = clip_slider.generate(prompt, guidance_scale=guidance_scale, scale=x,  seed=seed, num_inference_steps=steps, avg_diff=avg_diff) 
    return image



@spaces.GPU
def update_x(x,y,prompt,seed, steps, 
             avg_diff_x, avg_diff_y,
             img2img_type = None,
             img = None):
    avg_diff = avg_diff_x.cuda()
    avg_diff_2nd = avg_diff_y.cuda()
    image = clip_slider.generate(prompt, scale=x, scale_2nd=y, seed=seed, num_inference_steps=steps, avg_diff=avg_diff,avg_diff_2nd=avg_diff_2nd) 
    return image

@spaces.GPU
def update_y(x,y,prompt,seed, steps, 
             avg_diff_x, avg_diff_y,
             img2img_type = None,
             img = None):
    avg_diff = avg_diff_x.cuda()
    avg_diff_2nd = avg_diff_y.cuda()
    image = clip_slider.generate(prompt, scale=x, scale_2nd=y, seed=seed, num_inference_steps=steps, avg_diff=avg_diff,avg_diff_2nd=avg_diff_2nd) 
    return image

def reset_recalc_directions():
    return True

css = '''
#group {
    position: relative;
    width: 600px; /* Increased width */
    height: 600px; /* Increased height */
    margin-bottom: 20px;
    background-color: white;
}

#x {
    position: absolute;
    bottom: 180px; /* Moved further down */
    left: 30px; /* Adjusted left margin */
    width: 540px; /* Increased width to match the new container size */
}

#y {
    position: absolute;
    bottom: 200px; /* Increased bottom margin to ensure proper spacing from #x */
    left: 20px; /* Adjusted left margin */
    width: 540px; /* Increased width to match the new container size */
    transform: rotate(-90deg);
    transform-origin: left bottom;
}

#image_out {
    position: absolute;
    width: 80%; /* Adjust width as needed */
    right: 10px;
    top: 10px; /* Increased top margin to clear space occupied by #x */
}

'''
with gr.Blocks(css=css) as demo:
    gr.Markdown(f"""# Latent Navigation 
## Exploring CLIP text space with FLUX.1 schnell 🪐
[[code](https://github.com/linoytsaban/semantic-sliders)]
        """)
    
    x_concept_1 = gr.State("")
    x_concept_2 = gr.State("")
    # y_concept_1 = gr.State("")
    # y_concept_2 = gr.State("")

    avg_diff_x = gr.State()
    #avg_diff_y = gr.State()

    recalc_directions = gr.State(False)
    
    #with gr.Tab("text2image"):
    with gr.Row():
        with gr.Column():
            slider_x = gr.Dropdown(label="Slider concept range", allow_custom_value=True, multiselect=True, max_choices=2)
            #slider_y = gr.Dropdown(label="Slider Y concept range", allow_custom_value=True, multiselect=True, max_choices=2)
            prompt = gr.Textbox(label="Prompt")
            submit = gr.Button("find directions")
        with gr.Column():
            with gr.Group(elem_id="group"):
              x = gr.Slider(minimum=-3, value=0, maximum=3.5, elem_id="x", interactive=False)
              #y = gr.Slider(minimum=-10, value=0, maximum=10, elem_id="y", interactive=False)
              output_image = gr.Image(elem_id="image_out")
            # with gr.Row():
            #     generate_butt = gr.Button("generate")
    
    with gr.Accordion(label="advanced options", open=False):
        iterations = gr.Slider(label = "num iterations", minimum=0, value=200, maximum=400)
        steps = gr.Slider(label = "num inference steps", minimum=1, value=4, maximum=10)
        guidance_scale = gr.Slider(
                label="Guidance scale",
                minimum=0.1,
                maximum=10.0,
                step=0.1,
                value=5,
            )
        # correlation = gr.Slider(
        #         label="correlation",
        #         minimum=0.1,
        #         maximum=1.0,
        #         step=0.05,
        #         value=0.6,
        #     )
        seed  = gr.Slider(minimum=0, maximum=np.iinfo(np.int32).max, label="Seed", interactive=True, randomize=True)
        
       
    # with gr.Tab(label="image2image"):
    #     with gr.Row():
    #         with gr.Column():
    #             image = gr.ImageEditor(type="pil", image_mode="L", crop_size=(512, 512))
    #             slider_x_a = gr.Dropdown(label="Slider X concept range", allow_custom_value=True, multiselect=True, max_choices=2)
    #             slider_y_a = gr.Dropdown(label="Slider X concept range", allow_custom_value=True, multiselect=True, max_choices=2)
    #             img2img_type = gr.Radio(["controlnet canny", "ip adapter"], label="", info="", visible=False, value="controlnet canny")
    #             prompt_a = gr.Textbox(label="Prompt")
    #             submit_a = gr.Button("Submit")
    #         with gr.Column():
    #             with gr.Group(elem_id="group"):
    #               x_a = gr.Slider(minimum=-10, value=0, maximum=10, elem_id="x", interactive=False)
    #               y_a = gr.Slider(minimum=-10, value=0, maximum=10, elem_id="y", interactive=False)
    #               output_image_a = gr.Image(elem_id="image_out")
    #             with gr.Row():
    #                 generate_butt_a = gr.Button("generate")
        
    #     with gr.Accordion(label="advanced options", open=False):
    #         iterations_a = gr.Slider(label = "num iterations", minimum=0, value=200, maximum=300)
    #         steps_a = gr.Slider(label = "num inference steps", minimum=1, value=8, maximum=30)
    #         guidance_scale_a = gr.Slider(
    #                 label="Guidance scale",
    #                 minimum=0.1,
    #                 maximum=10.0,
    #                 step=0.1,
    #                 value=5,
    #             )
    #         controlnet_conditioning_scale = gr.Slider(
    #                 label="controlnet conditioning scale",
    #                 minimum=0.5,
    #                 maximum=5.0,
    #                 step=0.1,
    #                 value=0.7,
    #             )
    #         ip_adapter_scale = gr.Slider(
    #                 label="ip adapter scale",
    #                 minimum=0.5,
    #                 maximum=5.0,
    #                 step=0.1,
    #                 value=0.8,
    #                 visible=False
    #             )
    #         seed_a  = gr.Slider(minimum=0, maximum=np.iinfo(np.int32).max, label="Seed", interactive=True, randomize=True)
        
    # submit.click(fn=generate,
    #                  inputs=[slider_x, slider_y, prompt, seed, iterations, steps, guidance_scale, x_concept_1, x_concept_2, y_concept_1, y_concept_2, avg_diff_x, avg_diff_y],
    #                  outputs=[x, y, x_concept_1, x_concept_2, y_concept_1, y_concept_2, avg_diff_x, avg_diff_y, output_image])
    submit.click(fn=generate,
                     inputs=[slider_x, prompt, seed, recalc_directions, iterations, steps, guidance_scale, x_concept_1, x_concept_2, avg_diff_x],
                     outputs=[x, x_concept_1, x_concept_2, avg_diff_x, output_image])

    iterations.change(fn=reset_recalc_directions, outputs=[recalc_directions])
    seed.change(fn=reset_recalc_directions, outputs=[recalc_directions])
    x.change(fn=update_scales, inputs=[x, prompt, seed, steps, guidance_scale, avg_diff_x], outputs=[output_image])
    # generate_butt_a.click(fn=update_scales, inputs=[x_a,y_a, prompt_a, seed_a, steps_a, guidance_scale_a, avg_diff_x, avg_diff_y, img2img_type, image, controlnet_conditioning_scale, ip_adapter_scale], outputs=[output_image_a])
    # submit_a.click(fn=generate,
    #                  inputs=[slider_x_a, slider_y_a, prompt_a, seed_a, iterations_a, steps_a, guidance_scale_a, x_concept_1, x_concept_2, y_concept_1, y_concept_2, avg_diff_x, avg_diff_y, img2img_type, image, controlnet_conditioning_scale, ip_adapter_scale],
    #                  outputs=[x_a, y_a, x_concept_1, x_concept_2, y_concept_1, y_concept_2, avg_diff_x, avg_diff_y, output_image_a])

        
if __name__ == "__main__":
    demo.launch()