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persian-poem-recommender-based-on-text / inference.py

mojtaba-nafez

fix app.py to read from saved poem_embeddings.json

fd6aade about 1 year ago

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	from __future__ import annotations
	import torch
	import cv2
	import torch.nn.functional as F
	import numpy as np
	import config as CFG
	from datasets import get_transforms

	#for running this script as main
	from utils import get_datasets, build_loaders
	from models import PoemTextModel
	from utils import get_poem_embeddings
	import json
	import os
	import regex


	def predict_poems_from_text(model, poem_embeddings, query, poems, text_tokenizer=None, n=10, return_similarities=False):
	"""
	Returns n poems which are the most similar to a text query

	Parameters:
	-----------
	model: PoemTextModel
	model to compute text query's embeddings
	poem_embeddings: sequence with shape (#poems, CFG.projection_dim)
	poem embeddings to check similarity
	query: str
	text query
	poems: list of str
	poems corresponding to poem_embeddings
	text_tokenizer: huggingface Tokenizer, optional
	tokenizer to tokenize query with. if none, will instantiate a new text tokenizer using configs.
	n: int, optional
	number of poems to return
	return_similarities: bool, optional
	if True, a dictionary will be returned which has the poem beyts and their similarities to the text

	Returns:
	--------
	A list of n poem strings whose embeddings are the most similar to query text's embedding.

	"""
	#Tokenizing and Encoding the query text
	if not text_tokenizer:
	text_tokenizer = CFG.tokenizers[CFG.text_encoder_model].from_pretrained(CFG.text_tokenizer)

	encoded_query = text_tokenizer([query])
	batch = {
	key: torch.tensor(values).to(CFG.device)
	for key, values in encoded_query.items()
	}

	# getting query text's embeddings
	model.eval()
	with torch.no_grad():
	text_features = model.text_encoder(
	input_ids= batch["input_ids"], attention_mask=batch["attention_mask"]
	)
	text_embeddings = model.text_projection(text_features)

	# normalizing and computing dot similarity of poem and text embeddings
	poem_embeddings_n = F.normalize(poem_embeddings, p=2, dim=-1)
	text_embeddings_n = F.normalize(text_embeddings, p=2, dim=-1)

	dot_similarity = text_embeddings_n @ poem_embeddings_n.T

	# returning top n poems based on embedding similarity
	values, indices = torch.topk(dot_similarity.squeeze(0), len(poems))

	# since we collected poems from many sources, some of them are equal (the same beyt with different meanings),
	# so we must check the poems added to result not to be duplicates
	def is_poem_duplicate(poem, poems):
	poem = regex.findall(r'\p{L}+', poem.replace('\u200c', ''))
	for other_poem in poems:
	other_poem = regex.findall(r'\p{L}+', other_poem.replace('\u200c', ''))
	if poem == other_poem:
	return True
	return False

	results = []
	computed_k = 0
	for i in range(len(poems)):
	if computed_k == n:
	break
	if not is_poem_duplicate(poems[indices[i]], [res['beyt'] for res in results]):
	results.append({
	'beyt': poems[indices[i]].replace(' * * ', ' * ').replace('*** * ', ''),
	'similarity': values[i]
	})
	computed_k += 1
	if return_similarities:
	return results
	else:
	return [res['beyt'] for res in results]


	def predict_poems_from_image(model, poem_embeddings, image_filename, poems, n=10, return_similarities=False):
	"""
	Returns n poems which are the most similar to an image query

	Parameters:
	-----------
	model: CLIPModel
	model to compute image query's embeddings
	poem_embeddings: sequence with shape (#poems, CFG.projection_dim)
	poem embeddings to check similarity
	image_filename: str
	path and file name for the image query
	poems: list of str
	poems corresponding to poem_embeddings
	n: int, optional
	number of poems to return
	return_similarities: bool, optional
	if True, a dictionary will be returned which has the poem beyts and their similarities to the text

	Returns:
	--------
	A list of n poem strings whose embeddings are the most similar to image query's embedding.

	"""
	# Reading, Processing and applying transforms to image (all explained in datasets.py)
	image = cv2.imread(f"{image_filename}")
	image = cv2.cvtColor(image, cv2.COLOR_BGR2RGB)
	image = get_transforms(mode="test")(image=image)['image']
	image = torch.tensor(image).permute(2, 0, 1).float()

	# getting image query's embeddings
	model.eval()
	with torch.no_grad():
	image_features = model.image_encoder(torch.unsqueeze(image, 0).to(CFG.device))
	image_embeddings = model.image_projection(image_features)

	# normalizing and computing dot similarity of poem and text embeddings
	poem_embeddings_n = F.normalize(poem_embeddings, p=2, dim=-1)
	image_embeddings_n = F.normalize(image_embeddings, p=2, dim=-1)
	dot_similarity = image_embeddings_n @ poem_embeddings_n.T

	# returning top n poems based on embedding similarity
	values, indices = torch.topk(dot_similarity.squeeze(0), len(poems))

	# since we collected poems from many sources, some of them are equal (the same beyt with different meanings),
	# so we must check the poems added to result not to be duplicates
	def is_poem_duplicate(poem, poems):
	poem = regex.findall(r'\p{L}+', poem.replace('\u200c', ''))
	for other_poem in poems:
	other_poem = regex.findall(r'\p{L}+', other_poem.replace('\u200c', ''))
	if poem == other_poem:
	return True
	return False

	results = []
	computed_k = 0
	for i in range(len(poems)):
	if computed_k == n:
	break
	if not is_poem_duplicate(poems[indices[i]], [res['beyt'] for res in results]):
	results.append({
	'beyt': poems[indices[i]].replace(' * * ', ' * ').replace('*** * ', ''),
	'similarity': values[i]
	})
	computed_k += 1
	if return_similarities:
	return results
	else:
	return [res['beyt'] for res in results]


	if __name__ == "__main__":
	"""
	Creates a PoemTextModel based on configs, and outputs some examples of its prediction.
	"""
	# get dataset from dataset_path (the same datasets as the train, val and test dataset files in the data directory is made)
	train_dataset, val_dataset, test_dataset = get_datasets()

	model = PoemTextModel(poem_encoder_pretrained=True, text_encoder_pretrained=True).to(CFG.device)
	model.eval()
	# Inference: Output some example predictions and write them in a file
	print("_"*20)
	print("Output Examples from test set")
	model, poem_embeddings = get_poem_embeddings(test_dataset, model)
	example = {}
	for i, test_data in enumerate(test_dataset[:100]):
	example[i] = {'Text': test_data["text"], 'True Beyt': test_data["beyt"], "Predicted Beyt":predict_poems_from_text(model, poem_embeddings, test_data["text"], [data['beyt'] for data in test_dataset], n=10)}
	for i in range(10):
	print("Text: ", example[i]['Text'])
	print("True Beyt: ", example[i]['True Beyt'])
	print("predicted Beyts: \n\t", "\n\t".join(example[i]["Predicted Beyt"]))
	with open('example_output__{}_{}.json'.format(CFG.poem_encoder_model, CFG.text_encoder_model),'w', encoding="utf-8") as f:
	f.write(json.dumps(example, ensure_ascii=False, indent= 4))

	print("Preparing model for user input...")
	with open(CFG.dataset_path, encoding="utf-8") as f:
	dataset = json.load(f)

	model, poem_embeddings = get_poem_embeddings(dataset, model)

	while(True):
	user_text = input("Enter a Text to find poem beyts for: ")
	beyts = predict_poems_from_text(model, poem_embeddings, user_text, [data['beyt'] for data in dataset], n=10)
	print("predicted Beyts: \n\t", "\n\t".join(beyts))
	with open('{}_output__{}_{}.json'.format(user_text, CFG.poem_encoder_model, CFG.text_encoder_model),'a+', encoding="utf-8") as f:
	f.write(json.dumps(beyts, ensure_ascii=False, indent= 4))