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import diffusers
import torch
import random
from tqdm import tqdm
from constants import SUBJECTS, MEDIUMS
from PIL import Image

class CLIPSlider:
    def __init__(
            self,
            sd_pipe,
            device: torch.device,
            target_word: str = "",
            opposite: str = "",
            target_word_2nd: str = "",
            opposite_2nd: str = "",
            iterations: int = 300,
             
    ):

        self.device = device
        self.pipe = sd_pipe.to(self.device, torch.float16)
        self.iterations = iterations
        if target_word != "" or opposite != "":
            self.avg_diff = self.find_latent_direction(target_word, opposite)
        else:
            self.avg_diff = None
        if target_word_2nd != "" or opposite_2nd != "":
            self.avg_diff_2nd = self.find_latent_direction(target_word_2nd, opposite_2nd)
        else:
            self.avg_diff_2nd = None


    def find_latent_direction(self,
                              target_word:str,
                              opposite:str):

        # lets identify a latent direction by taking differences between opposites
        # target_word = "happy"
        # opposite = "sad"


        with torch.no_grad():
            positives = []
            negatives = []
            for i in tqdm(range(self.iterations)):
                medium = random.choice(MEDIUMS)
                subject = random.choice(SUBJECTS)
                pos_prompt = f"a {medium} of a {target_word} {subject}"
                neg_prompt = f"a {medium} of a {opposite} {subject}"
                pos_toks = self.pipe.tokenizer(pos_prompt, return_tensors="pt", padding="max_length", truncation=True,
                                          max_length=self.pipe.tokenizer.model_max_length).input_ids.cuda()
                neg_toks = self.pipe.tokenizer(neg_prompt, return_tensors="pt", padding="max_length", truncation=True,
                                          max_length=self.pipe.tokenizer.model_max_length).input_ids.cuda()
                pos = self.pipe.text_encoder(pos_toks).pooler_output
                neg = self.pipe.text_encoder(neg_toks).pooler_output
                positives.append(pos)
                negatives.append(neg)

        positives = torch.cat(positives, dim=0)
        negatives = torch.cat(negatives, dim=0)

        diffs = positives - negatives

        avg_diff = diffs.mean(0, keepdim=True)
        return avg_diff


    def generate(self,
        prompt = "a photo of a house",
        scale = 2.,
        scale_2nd = 0., # scale for the 2nd dim directions when avg_diff_2nd is not None
        seed = 15,
        only_pooler = False,
        normalize_scales = False, # whether to normalize the scales when avg_diff_2nd is not None
        correlation_weight_factor = 1.0,
        **pipeline_kwargs
        ):
        # if doing full sequence, [-0.3,0.3] work well, higher if correlation weighted is true
        # if pooler token only [-4,4] work well

        with torch.no_grad():
            toks = self.pipe.tokenizer(prompt, return_tensors="pt", padding="max_length", truncation=True,
                                  max_length=self.pipe.tokenizer.model_max_length).input_ids.cuda()
        prompt_embeds = self.pipe.text_encoder(toks).last_hidden_state

        if self.avg_diff_2nd and normalize_scales:
            denominator = abs(scale) + abs(scale_2nd)
            scale = scale / denominator
            scale_2nd = scale_2nd / denominator
        if only_pooler:
            prompt_embeds[:, toks.argmax()] = prompt_embeds[:, toks.argmax()] + self.avg_diff * scale
            if self.avg_diff_2nd:
                prompt_embeds[:, toks.argmax()] += self.avg_diff_2nd * scale_2nd
        else:
            normed_prompt_embeds = prompt_embeds / prompt_embeds.norm(dim=-1, keepdim=True)
        sims = normed_prompt_embeds[0] @ normed_prompt_embeds[0].T
        weights = sims[toks.argmax(), :][None, :, None].repeat(1, 1, 768)

        standard_weights = torch.ones_like(weights)

        weights = standard_weights + (weights - standard_weights) * correlation_weight_factor

        # weights = torch.sigmoid((weights-0.5)*7)
        prompt_embeds = prompt_embeds + (
                    weights * self.avg_diff[None, :].repeat(1, self.pipe.tokenizer.model_max_length, 1) * scale)
        if self.avg_diff_2nd:
            prompt_embeds += weights * self.avg_diff_2nd[None, :].repeat(1, self.pipe.tokenizer.model_max_length, 1) * scale_2nd


        torch.manual_seed(seed)
        images = self.pipe(prompt_embeds=prompt_embeds, **pipeline_kwargs).images

        return images

    def spectrum(self,
                 prompt="a photo of a house",
                 low_scale=-2,
                 low_scale_2nd=-2,
                 high_scale=2,
                 high_scale_2nd=2,
                 steps=5,
                 seed=15,
                 only_pooler=False,
                 normalize_scales=False,
                 correlation_weight_factor=1.0,
                 **pipeline_kwargs
                 ):

        images = []
        for i in range(steps):
            scale = low_scale + (high_scale - low_scale) * i / (steps - 1)
            scale_2nd = low_scale_2nd + (high_scale_2nd - low_scale_2nd) * i / (steps - 1)
            image = self.generate(prompt, scale, scale_2nd, seed, only_pooler, normalize_scales, correlation_weight_factor, **pipeline_kwargs)
            images.append(image[0])

        canvas = Image.new('RGB', (640 * steps, 640))
        for i, im in enumerate(images):
            canvas.paste(im, (640 * i, 0))

        return canvas

class CLIPSliderXL(CLIPSlider):

    def find_latent_direction(self,
                              target_word:str,
                              opposite:str):

        # lets identify a latent direction by taking differences between opposites
        # target_word = "happy"
        # opposite = "sad"


        with torch.no_grad():
            positives = []
            negatives = []
            positives2 = []
            negatives2 = []
            for i in tqdm(range(self.iterations)):
                medium = random.choice(MEDIUMS)
                subject = random.choice(SUBJECTS)
                pos_prompt = f"a {medium} of a {target_word} {subject}"
                neg_prompt = f"a {medium} of a {opposite} {subject}"

                pos_toks = self.pipe.tokenizer(pos_prompt, return_tensors="pt", padding="max_length", truncation=True,
                                          max_length=self.pipe.tokenizer.model_max_length).input_ids.cuda()
                neg_toks = self.pipe.tokenizer(neg_prompt, return_tensors="pt", padding="max_length", truncation=True,
                                          max_length=self.pipe.tokenizer.model_max_length).input_ids.cuda()
                pos = self.pipe.text_encoder(pos_toks).pooler_output
                neg = self.pipe.text_encoder(neg_toks).pooler_output
                positives.append(pos)
                negatives.append(neg)

                pos_toks2 = self.pipe.tokenizer_2(pos_prompt, return_tensors="pt", padding="max_length", truncation=True,
                                             max_length=self.pipe.tokenizer_2.model_max_length).input_ids.cuda()
                neg_toks2 = self.pipe.tokenizer_2(neg_prompt, return_tensors="pt", padding="max_length", truncation=True,
                                             max_length=self.pipe.tokenizer_2.model_max_length).input_ids.cuda()
                pos2 = self.pipe.text_encoder_2(pos_toks2).text_embeds
                neg2 = self.pipe.text_encoder_2(neg_toks2).text_embeds
                positives2.append(pos2)
                negatives2.append(neg2)

        positives = torch.cat(positives, dim=0)
        negatives = torch.cat(negatives, dim=0)
        diffs = positives - negatives
        avg_diff = diffs.mean(0, keepdim=True)

        positives2 = torch.cat(positives2, dim=0)
        negatives2 = torch.cat(negatives2, dim=0)
        diffs2 = positives2 - negatives2
        avg_diff2 = diffs2.mean(0, keepdim=True)
        return (avg_diff, avg_diff2)

    def generate(self,
        prompt = "a photo of a house",
        scale = 2,
        scale_2nd = 2,
        seed = 15,
        only_pooler = False,
        normalize_scales = False,
        correlation_weight_factor = 1.0,
        **pipeline_kwargs
        ):
        # if doing full sequence, [-0.3,0.3] work well, higher if correlation weighted is true
        # if pooler token only [-4,4] work well

        text_encoders = [self.pipe.text_encoder, self.pipe.text_encoder_2]
        tokenizers = [self.pipe.tokenizer, self.pipe.tokenizer_2]
        with torch.no_grad():
            # toks = pipe.tokenizer(prompt, return_tensors="pt", padding="max_length", truncation=True, max_length=77).input_ids.cuda()
            # prompt_embeds = pipe.text_encoder(toks).last_hidden_state

            prompt_embeds_list = []

            for i, text_encoder in enumerate(text_encoders):

                tokenizer = tokenizers[i]
                text_inputs = tokenizer(
                    prompt,
                    padding="max_length",
                    max_length=tokenizer.model_max_length,
                    truncation=True,
                    return_tensors="pt",
                )
                toks = text_inputs.input_ids

                prompt_embeds = text_encoder(
                    toks.to(text_encoder.device),
                    output_hidden_states=True,
                )

                # We are only ALWAYS interested in the pooled output of the final text encoder
                pooled_prompt_embeds = prompt_embeds[0]
                prompt_embeds = prompt_embeds.hidden_states[-2]

                if self.avg_diff_2nd and normalize_scales:
                    denominator = abs(scale) + abs(scale_2nd)
                    scale = scale / denominator
                    scale_2nd = scale_2nd / denominator
                if only_pooler:
                    prompt_embeds[:, toks.argmax()] = prompt_embeds[:, toks.argmax()] + self.avg_diff[0] * scale
                    if self.avg_diff_2nd:
                        prompt_embeds[:, toks.argmax()] += self.avg_diff_2nd[0] * scale_2nd
                else:
                    normed_prompt_embeds = prompt_embeds / prompt_embeds.norm(dim=-1, keepdim=True)
                    sims = normed_prompt_embeds[0] @ normed_prompt_embeds[0].T

                    if i == 0:
                        weights = sims[toks.argmax(), :][None, :, None].repeat(1, 1, 768)

                        standard_weights = torch.ones_like(weights)

                        weights = standard_weights + (weights - standard_weights) * correlation_weight_factor
                        prompt_embeds = prompt_embeds + (weights * self.avg_diff[0][None, :].repeat(1, self.pipe.tokenizer.model_max_length, 1) * scale)
                        if self.avg_diff_2nd:
                            prompt_embeds += (weights * self.avg_diff_2nd[0][None, :].repeat(1, self.pipe.tokenizer.model_max_length, 1) * scale_2nd)
                    else:
                        weights = sims[toks.argmax(), :][None, :, None].repeat(1, 1, 1280)

                        standard_weights = torch.ones_like(weights)

                        weights = standard_weights + (weights - standard_weights) * correlation_weight_factor
                        prompt_embeds = prompt_embeds + (weights * self.avg_diff[1][None, :].repeat(1, self.pipe.tokenizer_2.model_max_length, 1) * scale)
                        if self.avg_diff_2nd:
                            prompt_embeds += (weights * self.avg_diff_2nd[1][None, :].repeat(1, self.pipe.tokenizer_2.model_max_length, 1) * scale_2nd)

                bs_embed, seq_len, _ = prompt_embeds.shape
                prompt_embeds = prompt_embeds.view(bs_embed, seq_len, -1)
                prompt_embeds_list.append(prompt_embeds)

            prompt_embeds = torch.concat(prompt_embeds_list, dim=-1)
            pooled_prompt_embeds = pooled_prompt_embeds.view(bs_embed, -1)

            torch.manual_seed(seed)
            images = self.pipe(prompt_embeds=prompt_embeds, pooled_prompt_embeds=pooled_prompt_embeds,
                         **pipeline_kwargs).images

        return images

class CLIPSliderXL_inv(CLIPSlider):

    def find_latent_direction(self,
                              target_word:str,
                              opposite:str):

        # lets identify a latent direction by taking differences between opposites
        # target_word = "happy"
        # opposite = "sad"


        with torch.no_grad():
            positives = []
            negatives = []
            positives2 = []
            negatives2 = []
            for i in tqdm(range(self.iterations)):
                medium = random.choice(MEDIUMS)
                subject = random.choice(SUBJECTS)
                pos_prompt = f"a {medium} of a {target_word} {subject}"
                neg_prompt = f"a {medium} of a {opposite} {subject}"

                pos_toks = self.pipe.tokenizer(pos_prompt, return_tensors="pt", padding="max_length", truncation=True,
                                          max_length=self.pipe.tokenizer.model_max_length).input_ids.cuda()
                neg_toks = self.pipe.tokenizer(neg_prompt, return_tensors="pt", padding="max_length", truncation=True,
                                          max_length=self.pipe.tokenizer.model_max_length).input_ids.cuda()
                pos = self.pipe.text_encoder(pos_toks).pooler_output
                neg = self.pipe.text_encoder(neg_toks).pooler_output
                positives.append(pos)
                negatives.append(neg)

                pos_toks2 = self.pipe.tokenizer_2(pos_prompt, return_tensors="pt", padding="max_length", truncation=True,
                                             max_length=self.pipe.tokenizer_2.model_max_length).input_ids.cuda()
                neg_toks2 = self.pipe.tokenizer_2(neg_prompt, return_tensors="pt", padding="max_length", truncation=True,
                                             max_length=self.pipe.tokenizer_2.model_max_length).input_ids.cuda()
                pos2 = self.pipe.text_encoder_2(pos_toks2).text_embeds
                neg2 = self.pipe.text_encoder_2(neg_toks2).text_embeds
                positives2.append(pos2)
                negatives2.append(neg2)

        positives = torch.cat(positives, dim=0)
        negatives = torch.cat(negatives, dim=0)
        diffs = positives - negatives
        avg_diff = diffs.mean(0, keepdim=True)

        positives2 = torch.cat(positives2, dim=0)
        negatives2 = torch.cat(negatives2, dim=0)
        diffs2 = positives2 - negatives2
        avg_diff2 = diffs2.mean(0, keepdim=True)
        return (avg_diff, avg_diff2)

    def generate(self,
        prompt = "a photo of a house",
        scale = 2,
        scale_2nd = 2,
        seed = 15,
        only_pooler = False,
        normalize_scales = False,
        correlation_weight_factor = 1.0,
        **pipeline_kwargs
        ):

        with torch.no_grad():
            torch.manual_seed(seed)
            images = self.pipe(editing_prompt=prompt,
                               avg_diff=self.avg_diff, avg_diff_2nd=self.avg_diff_2nd,
                               scale=scale, scale_2nd=scale_2nd,
                               **pipeline_kwargs).images

        return images

class CLIPSliderFlux(CLIPSlider):
    def find_latent_direction(self,
                              target_word:str,
                              opposite:str,
                             num_iterations: int = None):

        # lets identify a latent direction by taking differences between opposites
        # target_word = "happy"
        # opposite = "sad"

        if num_iterations is not None: 
            iterations = num_iterations
        else:
            iterations = self.iterations
            
        with torch.no_grad():
            positives = []
            negatives = []
            for i in tqdm(range(iterations)):
                medium = random.choice(MEDIUMS)
                subject = random.choice(SUBJECTS)
                pos_prompt = f"a {medium} of a {target_word} {subject}"
                neg_prompt = f"a {medium} of a {opposite} {subject}"
                pos_toks = self.pipe.tokenizer(pos_prompt,
                                               padding="max_length",
                                               max_length=self.pipe.tokenizer_max_length,
                                               truncation=True,
                                               return_overflowing_tokens=False,
                                               return_length=False,
                                               return_tensors="pt",).input_ids.cuda()
                neg_toks = self.pipe.tokenizer(neg_prompt,
                                               padding="max_length",
                                               max_length=self.pipe.tokenizer_max_length,
                                               truncation=True,
                                               return_overflowing_tokens=False,
                                               return_length=False,
                                               return_tensors="pt",).input_ids.cuda()
                pos = self.pipe.text_encoder(pos_toks).pooler_output
                neg = self.pipe.text_encoder(neg_toks).pooler_output
                positives.append(pos)
                negatives.append(neg)

        positives = torch.cat(positives, dim=0)
        negatives = torch.cat(negatives, dim=0)

        diffs = positives - negatives

        avg_diff = diffs.mean(0, keepdim=True)
        return avg_diff

    def generate(self,
        prompt = "a photo of a house",
        scale = 2,
        scale_2nd = 2,
        seed = 15,
        normalize_scales = False,
        avg_diff = None,
        avg_diff_2nd = None, 
        **pipeline_kwargs
        ):
        # if doing full sequence, [-0.3,0.3] work well, higher if correlation weighted is true
        # if pooler token only [-4,4] work well

        with torch.no_grad():
            text_inputs = self.pipe.tokenizer(
                prompt,
                padding="max_length",
                max_length=77,
                truncation=True,
                return_overflowing_tokens=False,
                return_length=False,
                return_tensors="pt",
            )

            text_input_ids = text_inputs.input_ids
            prompt_embeds = self.pipe.text_encoder(text_input_ids.to(self.device), output_hidden_states=False)

            # Use pooled output of CLIPTextModel
            prompt_embeds = prompt_embeds.pooler_output
            pooled_prompt_embeds = prompt_embeds.to(dtype=self.pipe.text_encoder.dtype, device=self.device)

            # Use pooled output of CLIPTextModel

            text_inputs = self.pipe.tokenizer_2(
                prompt,
                padding="max_length",
                max_length=512,
                truncation=True,
                return_length=False,
                return_overflowing_tokens=False,
                return_tensors="pt",
            )
            toks = text_inputs.input_ids
            prompt_embeds = self.pipe.text_encoder_2(toks.to(self.device), output_hidden_states=False)[0]
            dtype = self.pipe.text_encoder_2.dtype
            prompt_embeds = prompt_embeds.to(dtype=dtype, device=self.device)
            if avg_diff_2nd is not None and normalize_scales:
                denominator = abs(scale) + abs(scale_2nd)
                scale = scale / denominator
                scale_2nd = scale_2nd / denominator

            pooled_prompt_embeds = pooled_prompt_embeds + avg_diff * scale
            if avg_diff_2nd is not None:
                pooled_prompt_embeds += avg_diff_2nd * scale_2nd

            torch.manual_seed(seed)
            images = self.pipe(prompt_embeds=prompt_embeds, pooled_prompt_embeds=pooled_prompt_embeds,
                               **pipeline_kwargs).images

        return images

    def spectrum(self,
                 prompt="a photo of a house",
                 low_scale=-2,
                 low_scale_2nd=-2,
                 high_scale=2,
                 high_scale_2nd=2,
                 steps=5,
                 seed=15,
                 normalize_scales=False,
                 **pipeline_kwargs
                 ):

        images = []
        for i in range(steps):
            scale = low_scale + (high_scale - low_scale) * i / (steps - 1)
            scale_2nd = low_scale_2nd + (high_scale_2nd - low_scale_2nd) * i / (steps - 1)
            image = self.generate(prompt, scale, scale_2nd, seed, normalize_scales, **pipeline_kwargs)
            images.append(image[0].resize((512,512)))

        canvas = Image.new('RGB', (640 * steps, 640))
        for i, im in enumerate(images):
            canvas.paste(im, (640 * i, 0))

        return canvas
class T5SliderFlux(CLIPSlider):

    def find_latent_direction(self,
                              target_word:str,
                              opposite:str):

        # lets identify a latent direction by taking differences between opposites
        # target_word = "happy"
        # opposite = "sad"


        with torch.no_grad():
            positives = []
            negatives = []
            for i in tqdm(range(self.iterations)):
                medium = random.choice(MEDIUMS)
                subject = random.choice(SUBJECTS)
                pos_prompt = f"a {medium} of a {target_word} {subject}"
                neg_prompt = f"a {medium} of a {opposite} {subject}"

                pos_toks = self.pipe.tokenizer_2(pos_prompt,
                                                 return_tensors="pt",
                                                 padding="max_length",
                                                 truncation=True,
                                                 return_length=False,
                                                 return_overflowing_tokens=False,
                                                 max_length=self.pipe.tokenizer_2.model_max_length).input_ids.cuda()
                neg_toks = self.pipe.tokenizer_2(neg_prompt,
                                                 return_tensors="pt",
                                                 padding="max_length",
                                                 truncation=True,
                                                 return_length=False,
                                                 return_overflowing_tokens=False,
                                                 max_length=self.pipe.tokenizer_2.model_max_length).input_ids.cuda()
                pos = self.pipe.text_encoder_2(pos_toks, output_hidden_states=False)[0]
                neg = self.pipe.text_encoder_2(neg_toks, output_hidden_states=False)[0]
                positives.append(pos)
                negatives.append(neg)

        positives = torch.cat(positives, dim=0)
        negatives = torch.cat(negatives, dim=0)
        diffs = positives - negatives
        avg_diff = diffs.mean(0, keepdim=True)

        return avg_diff

    def generate(self,
        prompt = "a photo of a house",
        scale = 2,
        scale_2nd = 2,
        seed = 15,
        only_pooler = False,
        normalize_scales = False,
        correlation_weight_factor = 1.0,
        **pipeline_kwargs
        ):
        # if doing full sequence, [-0.3,0.3] work well, higher if correlation weighted is true
        # if pooler token only [-4,4] work well

        with torch.no_grad():
            text_inputs = self.pipe.tokenizer(
                prompt,
                padding="max_length",
                max_length=77,
                truncation=True,
                return_overflowing_tokens=False,
                return_length=False,
                return_tensors="pt",
            )

            text_input_ids = text_inputs.input_ids
            prompt_embeds = self.pipe.text_encoder(text_input_ids.to(self.device), output_hidden_states=False)

            # Use pooled output of CLIPTextModel
            prompt_embeds = prompt_embeds.pooler_output
            pooled_prompt_embeds = prompt_embeds.to(dtype=self.pipe.text_encoder.dtype, device=self.device)

            # Use pooled output of CLIPTextModel

            text_inputs = self.pipe.tokenizer_2(
                prompt,
                padding="max_length",
                max_length=512,
                truncation=True,
                return_length=False,
                return_overflowing_tokens=False,
                return_tensors="pt",
            )
            toks = text_inputs.input_ids
            prompt_embeds = self.pipe.text_encoder_2(toks.to(self.device), output_hidden_states=False)[0]
            dtype = self.pipe.text_encoder_2.dtype
            prompt_embeds = prompt_embeds.to(dtype=dtype, device=self.device)
            if self.avg_diff_2nd and normalize_scales:
                denominator = abs(scale) + abs(scale_2nd)
                scale = scale / denominator
                scale_2nd = scale_2nd / denominator
            if only_pooler:
                prompt_embeds[:, toks.argmax()] = prompt_embeds[:, toks.argmax()] + self.avg_diff * scale
                if self.avg_diff_2nd:
                    prompt_embeds[:, toks.argmax()] += self.avg_diff_2nd * scale_2nd
            else:
                normed_prompt_embeds = prompt_embeds / prompt_embeds.norm(dim=-1, keepdim=True)
                sims = normed_prompt_embeds[0] @ normed_prompt_embeds[0].T

                weights = sims[toks.argmax(), :][None, :, None].repeat(1, 1, prompt_embeds.shape[2])

                standard_weights = torch.ones_like(weights)

                weights = standard_weights + (weights - standard_weights) * correlation_weight_factor
                prompt_embeds = prompt_embeds + (
                            weights * self.avg_diff * scale)
                if self.avg_diff_2nd:
                    prompt_embeds += (
                                weights * self.avg_diff_2nd * scale_2nd)

            torch.manual_seed(seed)
            images = self.pipe(prompt_embeds=prompt_embeds, pooled_prompt_embeds=pooled_prompt_embeds,
                               **pipeline_kwargs).images

        return images