import torch from transformers import AutoModelForCausalLM, AutoTokenizer import numpy as np import gradio as gr import spaces tokenizer = AutoTokenizer.from_pretrained("gpt2") model = AutoModelForCausalLM.from_pretrained("gpt2") tokenizer.pad_token_id = tokenizer.eos_token_id print("Loading finished.") print(f"Is CUDA available: {torch.cuda.is_available()}") # True if torch.cuda.is_available(): print(f"CUDA device: {torch.cuda.get_device_name(torch.cuda.current_device())}") STYLE = """ .custom-container { width: 100%; display: grid; align-items: center; margin: 0!important; overflow: scroll; } .prose ul ul { margin: 0!important; font-size: 10px!important; } .prose td, th { padding-left: 2px; padding-right: 2px; padding-top: 0; padding-bottom: 0; } .tree { padding: 0px; margin: 0!important; box-sizing: border-box; font-size: 10px; width: 100%; min-width: 2000px; height: auto; text-align: center; } .tree ul { padding-top: 20px; position: relative; transition: .5s; margin: 0!important; display: flex; flex-direction: row; justify-content: center; gap:10px; } .tree li { display: inline-table; text-align: center; list-style-type: none; position: relative; padding-top: 10px; transition: .5s; } .tree li::before, .tree li::after { content: ''; position: absolute; top: 0; right: 50%; border-top: 1px solid #ccc; width: 51%; height: 10px; } .tree li::after { right: auto; left: 50%; border-left: 1px solid #ccc; } .tree li:only-child::after, .tree li:only-child::before { display: none; } .tree li:first-child::before, .tree li:last-child::after { border: 0 none; } .tree li:last-child::before { border-right: 1px solid #ccc; border-radius: 0 5px 0 0; -webkit-border-radius: 0 5px 0 0; -moz-border-radius: 0 5px 0 0; } .tree li:first-child::after { border-radius: 5px 0 0 0; -webkit-border-radius: 5px 0 0 0; -moz-border-radius: 5px 0 0 0; } .tree ul ul::before { content: ''; position: absolute; top: 0; left: 50%; border-left: 1px solid #ccc; width: 0; height: 20px; } .tree li a { border: 1px solid #ccc; padding: 5px; display: inline-grid; border-radius: 5px; text-decoration-line: none; border-radius: 5px; transition: .5s; } .tree li a span { color: #666; padding: 5px; font-size: 12px; text-transform: uppercase; letter-spacing: 1px; font-weight: 500; } /*Hover-Section*/ .tree li a:hover, .tree li a:hover+ul li a { background: #c8e4f8; color: #000; } .tree li a:hover+ul li::after, .tree li a:hover+ul li::before, .tree li a:hover+ul::before, .tree li a:hover+ul ul::before { border-color: #94a0b4; } .chosen { background-color: red; } """ def generate_nodes(token, node): """Recursively generate HTML for the tree nodes.""" html_content = f"
  • {token} " html_content += node.table if node.table is not None else "" html_content += "" if len(node.children.keys()) > 0: html_content += "" html_content += "
  • " return html_content def generate_markdown_table(scores, sequence_prob, top_k=4, chosen_tokens=None): markdown_table = """ """ for token_idx in np.array(np.argsort(scores)[-top_k:])[::-1]: token = tokenizer.decode([token_idx]) style = "" if chosen_tokens and token in chosen_tokens: style = "background-color:red" markdown_table += f""" """ markdown_table += """
    Token Step score Total score
    {token} {scores[token_idx]:.4f} {scores[token_idx] + sequence_prob:.4f}
    """ return markdown_table def generate_html(start_sentence, original_tree): html_output = """
    """ return html_output import pandas as pd from typing import Dict from dataclasses import dataclass @dataclass class BeamNode: cumulative_score: float table: str current_sentence: str children: Dict[str, "BeamNode"] def generate_beams(start_sentence, scores, sequences, beam_indices): print(tokenizer.batch_decode(sequences)) sequences = sequences.cpu().numpy() original_tree = BeamNode( cumulative_score=0, table=None, current_sentence=start_sentence, children={} ) n_beams = len(scores[0]) beam_trees = [original_tree] * n_beams for step, step_scores in enumerate(scores): ( top_token_indexes, top_cumulative_scores, beam_indexes, current_completions, top_tokens, ) = ([], [], [], [], []) for beam_ix in range(n_beams): current_beam = beam_trees[beam_ix] # Get top cumulative scores for the current beam current_top_token_indexes = list( np.array(scores[step][beam_ix].argsort()[-n_beams:])[::-1] ) top_token_indexes += current_top_token_indexes top_cumulative_scores += list( np.array(scores[step][beam_ix][current_top_token_indexes]) + current_beam.cumulative_score ) beam_indexes += [beam_ix] * n_beams current_completions += [beam_trees[beam_ix].current_sentence] * n_beams top_tokens += [ tokenizer.decode([el]) for el in current_top_token_indexes ] top_df = pd.DataFrame.from_dict( { "token_index": top_token_indexes, "cumulative_score": top_cumulative_scores, "beam_index": beam_indexes, "current_completions": current_completions, "token": top_tokens, } ) maxes = top_df.groupby(["token_index", "current_completions"])[ "cumulative_score" ].idxmax() top_df = top_df.loc[maxes] # Sort all top probabilities and keep top n_beams top_df_selected = top_df.sort_values("cumulative_score", ascending=False).iloc[ :n_beams ] # Write the scores table - one per beam source? # Edge case: if several beam indexes are actually on the same beam, the selected tokens by beam_index for the second one will be empty. So we reverse for beam_ix in reversed(list(range(n_beams))): current_beam = beam_trees[beam_ix] selected_tokens = top_df_selected.loc[top_df_selected["beam_index"] == beam_ix] markdown_table = generate_markdown_table( step_scores[beam_ix, :], current_beam.cumulative_score, chosen_tokens=list(selected_tokens["token"].values), ) beam_trees[beam_ix].table = markdown_table # Add new children for each beam cumulative_scores = [beam.cumulative_score for beam in beam_trees] for beam_ix in range(n_beams): current_token_choice_ix = top_df_selected.iloc[beam_ix]["token_index"] current_token_choice = tokenizer.decode([current_token_choice_ix]) # Update the source tree source_beam_ix = int(top_df_selected.iloc[beam_ix]["beam_index"]) previous_len = len(str(original_tree)) beam_trees[source_beam_ix].children[current_token_choice] = BeamNode( table=None, children={}, current_sentence=beam_trees[source_beam_ix].current_sentence + current_token_choice, cumulative_score=cumulative_scores[source_beam_ix] + scores[step][source_beam_ix][current_token_choice_ix].numpy(), ) assert ( len(str(original_tree)) > previous_len ), "Original tree has not increased size" # Reassign all beams at once beam_trees = [ beam_trees[int(top_df_selected.iloc[beam_ix]["beam_index"])] for beam_ix in range(n_beams) ] # Advance all beams by one token for beam_ix in range(n_beams): current_token_choice_ix = top_df_selected.iloc[beam_ix]["token_index"] current_token_choice = tokenizer.decode([current_token_choice_ix]) beam_trees[beam_ix] = beam_trees[beam_ix].children[current_token_choice] return original_tree @spaces.GPU def get_beam_search_html(input_text, number_steps, number_beams): inputs = tokenizer([input_text], return_tensors="pt") outputs = model.generate( **inputs, max_new_tokens=number_steps, num_beams=number_beams, num_return_sequences=number_beams, return_dict_in_generate=True, output_scores=True, top_k=5, do_sample=False, ) original_tree = generate_beams( input_text, outputs.scores[:], outputs.sequences[:, :], outputs.beam_indices[:, :], ) html = generate_html(input_text, original_tree) print(html) return html with gr.Blocks( theme=gr.themes.Soft( text_size="lg", font=["monospace"], primary_hue=gr.themes.colors.orange ), css=STYLE, ) as demo: text = gr.Textbox(label="Sentence to decode from", value="Today is") steps = gr.Slider(label="Number of steps", minimum=1, maximum=10, step=1, value=4) beams = gr.Slider(label="Number of beams", minimum=2, maximum=4, step=1, value=3) button = gr.Button() out = gr.Markdown(label="Output") button.click(get_beam_search_html, inputs=[text, steps, beams], outputs=out) demo.launch()