from typing import List, Set, Tuple import numpy as np import pytest import torch from vllm.utils import make_tensor_with_pad from vllm.v1.sample.metadata import SamplingMetadata from vllm.v1.sample.sampler import Sampler VOCAB_SIZE = 1024 NUM_OUTPUT_TOKENS = 20 CUDA_DEVICES = [ f"cuda:{i}" for i in range(1 if torch.cuda.device_count() == 1 else 2) ] MAX_NUM_PROMPT_TOKENS = 64 def _create_fake_logits(batch_size: int, vocab_size: int) -> torch.Tensor: fake_logits = torch.full((batch_size, vocab_size), 1e-2, dtype=torch.float) return fake_logits def _create_penalty_tensor(batch_size: int, penalty_value: float, device: torch.device) -> torch.Tensor: return torch.full((batch_size, ), fill_value=penalty_value, dtype=torch.float, device=device) def _create_prompt_tokens_tensor( prompt_token_ids: List[List[int]], vocab_size: int, device: torch.device, ) -> torch.Tensor: return make_tensor_with_pad( prompt_token_ids, pad=vocab_size, device=device, dtype=torch.int64, pin_memory=False, ) def _create_default_sampling_metadata( num_output_tokens: int, batch_size: int, vocab_size: int, device: torch.device, ) -> SamplingMetadata: output_token_ids: List[List[int]] = [] prompt_token_ids: List[List[int]] = [] for _ in range(batch_size): output_token_ids.append( np.random.randint(0, vocab_size, size=num_output_tokens).tolist()) prompt_token_ids.append( np.random.randint(0, vocab_size, size=np.random.randint( 1, MAX_NUM_PROMPT_TOKENS)).tolist()) fake_sampling_metadata = SamplingMetadata( temperature=torch.full((batch_size, ), 0.0), all_greedy=True, all_random=False, top_p=torch.empty(batch_size, ), top_k=torch.empty(batch_size, ), no_top_p=True, no_top_k=True, generators={}, max_num_logprobs=0, prompt_token_ids=_create_prompt_tokens_tensor(prompt_token_ids, vocab_size, device), output_token_ids=output_token_ids, frequency_penalties=_create_penalty_tensor(batch_size, 0.0, device), presence_penalties=_create_penalty_tensor(batch_size, 0.0, device), repetition_penalties=_create_penalty_tensor(batch_size, 1.0, device), no_penalties=True, min_tokens=[], stop_token_ids=[], ) return fake_sampling_metadata def _generate_min_token_penalties_and_stop_tokens( num_output_tokens: int, batch_size: int, vocab_size: int, batch_indices_for_min_token_penalty: List[int] ) -> Tuple[List[int], List[Set[int]]]: """ Generates and returns a list of minimum token penalties (`min_tokens`) and a corresponding list of stop token IDs (`stop_token_ids`) for each batch. If a batch index is included in `batch_indices_for_min_token_penalty`, a higher `min_tokens` value is assigned (within a randomized range), and a random set of stop token IDs is created. Otherwise, a lower `min_tokens` value is assigned, and the stop token IDs set is empty. """ stop_token_ids: List[Set[int]] = [] min_tokens: List[int] = [] for index in range(batch_size): if index in batch_indices_for_min_token_penalty: min_tokens.append( np.random.randint(num_output_tokens + 1, 2 * num_output_tokens)) stop_token_ids.append( set( np.random.randint(0, vocab_size - 1) for _ in range(np.random.randint(0, vocab_size)))) else: min_tokens.append(np.random.randint(0, num_output_tokens)) stop_token_ids.append(set()) return (min_tokens, stop_token_ids) def _create_weighted_output_token_list( batch_size: int, vocab_size: int) -> Tuple[List[List[int]], List[List[int]]]: """ Creates an output token list where each token occurs a distinct number of times. For each batch, a random subset of token IDs is selected from the vocabulary. The selected tokens are then added to the output token list, each with a different frequency. Returns: Tuple[List[List[int]], List[List[int]]]: - The first element is the output token list, where each sublist corresponds to a batch and contains tokens with weighted frequencies. - The second element is a list of distinct token IDs for each batch, ordered by their frequency in the corresponding output list. """ output_token_ids: List[List[int]] = [] sorted_token_ids_in_output: List[List[int]] = [] for _ in range(batch_size): distinct_token_ids = np.random.choice(vocab_size, size=np.random.randint(1, 10), replace=False).tolist() sorted_token_ids_in_output.append(distinct_token_ids) output_token_ids_for_batch = [] for index, token_id in enumerate(distinct_token_ids): output_token_ids_for_batch.extend( [token_id for _ in range(index + 1)]) output_token_ids.append(output_token_ids_for_batch) return (output_token_ids, sorted_token_ids_in_output) @pytest.mark.parametrize("device", CUDA_DEVICES) @pytest.mark.parametrize("batch_size", [1, 2, 32]) def test_sampler_min_tokens_penalty(device: str, batch_size: int): """ Tests that if the number of output tokens is less than SamplingParams.min_tokens then we will set the logits for the stop token ids to -inf. """ torch.set_default_device(device) fake_logits = _create_fake_logits(batch_size, VOCAB_SIZE) sampling_metadata = _create_default_sampling_metadata( NUM_OUTPUT_TOKENS, batch_size, VOCAB_SIZE, torch.device(device)) batch_indices_for_min_token_penalty = np.random.randint( 0, batch_size - 1, size=np.random.randint(0, batch_size)).tolist() min_tokens, stop_token_ids = _generate_min_token_penalties_and_stop_tokens( NUM_OUTPUT_TOKENS, batch_size, VOCAB_SIZE, batch_indices_for_min_token_penalty) sampling_metadata.min_tokens = min_tokens sampling_metadata.stop_token_ids = stop_token_ids sampler = Sampler() logits = sampler.apply_penalties(fake_logits, sampling_metadata) logits = logits.cpu() for batch_idx in range(batch_size): for token_id in range(VOCAB_SIZE): if token_id in stop_token_ids[batch_idx]: assert logits[batch_idx][token_id] == -float("inf") else: assert logits[batch_idx][token_id] != -float("inf") @pytest.mark.parametrize("device", CUDA_DEVICES) @pytest.mark.parametrize("batch_size", [1, 2, 32]) @pytest.mark.parametrize("presence_penalty", [-2.0, 2.0]) def test_sampler_presence_penalty(device: str, batch_size: int, presence_penalty: float): """ Test to verify that if presence penalty is enabled then tokens are penalized as per their presence in the existing output. """ torch.set_default_device(device) # Create fake logits where each token is assigned the same # logit value. fake_logits = _create_fake_logits(batch_size, VOCAB_SIZE) sampling_metadata = _create_default_sampling_metadata( NUM_OUTPUT_TOKENS, batch_size, VOCAB_SIZE, torch.device(device)) output_token_ids = sampling_metadata.output_token_ids sampling_metadata.presence_penalties = _create_penalty_tensor( batch_size, presence_penalty, torch.device(device)) sampling_metadata.no_penalties = False sampler = Sampler() logits = sampler.apply_penalties(fake_logits, sampling_metadata) logits = logits.cpu() for batch_idx in range(batch_size): # Since all tokens initially have the same logits, the non-penalized # token ID will be the one with the highest logit value, while the # penalized token ID will be the one with the lowest logit value. non_penalized_token_id = logits[batch_idx].argmax().item() penalized_token_id = logits[batch_idx].argmin().item() if presence_penalty > 0: # If `presence_penalty` is set to a value greater than 0, it # indicates a preference for new tokens over those already # present in the output. # Verify that the penalized token ID exists in the output, while the # non-penalized token ID does not. assert penalized_token_id in output_token_ids[batch_idx] assert non_penalized_token_id not in output_token_ids[batch_idx] elif presence_penalty < 0: # If `presence_penalty` is set to a value less than 0, it indicates # a preference for existing tokens over new ones. Verify that the # non-penalized token ID exists in the output, while the penalized # token ID does not. assert non_penalized_token_id in output_token_ids[batch_idx] assert penalized_token_id not in output_token_ids[batch_idx] @pytest.mark.parametrize("device", CUDA_DEVICES) @pytest.mark.parametrize("batch_size", [1, 2, 32]) @pytest.mark.parametrize("frequency_penalty", [-2.0, 2.0]) def test_sampler_frequency_penalty(device: str, batch_size: int, frequency_penalty: float): """ Test to verify that if frequency penalty is enabled then tokens are penalized as per their frequency of occurrence. """ torch.set_default_device(device) # Create fake logits where each token is assigned the same # logit value. fake_logits = _create_fake_logits(batch_size, VOCAB_SIZE) sampling_metadata = _create_default_sampling_metadata( NUM_OUTPUT_TOKENS, batch_size, VOCAB_SIZE, torch.device(device)) sampling_metadata.frequency_penalties = _create_penalty_tensor( batch_size, frequency_penalty, torch.device(device)) output_token_ids, sorted_token_ids_in_output = \ _create_weighted_output_token_list(batch_size, VOCAB_SIZE) sampling_metadata.output_token_ids = output_token_ids sampling_metadata.no_penalties = False sampler = Sampler() logits = sampler.apply_penalties(fake_logits, sampling_metadata) logits = logits.cpu() for batch_idx in range(batch_size): non_penalized_token_id = logits[batch_idx].argmax().item() penalized_token_id = logits[batch_idx].argmin().item() distinct_sorted_token_ids_in_output = \ sorted_token_ids_in_output[batch_idx] most_frequent_token_id = distinct_sorted_token_ids_in_output[ len(distinct_sorted_token_ids_in_output) - 1] if frequency_penalty > 0: # If `frequency_penalty` is set to > 0, it indicates # a preference for new tokens over existing ones. Verify that the # non-penalized token ID is not present in the output, while the # most penalized token is the one that occurs most frequently in # the output. assert non_penalized_token_id \ not in distinct_sorted_token_ids_in_output assert penalized_token_id == most_frequent_token_id elif frequency_penalty < 0: # If `frequency_penalty` is set to < 0, it indicates # a preference for existing tokens over new ones. Verify that the # non-penalized token ID is the one that occurs most frequently # in the output, while the penalized token ID is one that has not # yet appeared. assert non_penalized_token_id == most_frequent_token_id assert penalized_token_id \ not in distinct_sorted_token_ids_in_output @pytest.mark.parametrize("device", CUDA_DEVICES) @pytest.mark.parametrize("batch_size", [1, 2, 32]) @pytest.mark.parametrize("repetition_penalty", [0.1, 1.9]) def test_sampler_repetition_penalty(device: str, batch_size: int, repetition_penalty: float): """ Test to verify that when the repetition penalty is enabled, tokens are penalized based on their presence in the prompt or the existing output. """ torch.set_default_device(device) # Create fake logits where each token is assigned the same # logit value. fake_logits = _create_fake_logits(batch_size, VOCAB_SIZE) sampling_metadata = _create_default_sampling_metadata( NUM_OUTPUT_TOKENS, batch_size, VOCAB_SIZE, torch.device(device)) sampling_metadata.repetition_penalties = _create_penalty_tensor( batch_size, repetition_penalty, torch.device(device)) sampling_metadata.no_penalties = False sampler = Sampler() logits = sampler.apply_penalties(fake_logits, sampling_metadata) logits = logits.cpu() for batch_idx in range(batch_size): non_penalized_token_id = logits[batch_idx].argmax().item() penalized_token_id = logits[batch_idx].argmin().item() prompt_tokens = sampling_metadata.prompt_token_ids[ batch_idx][:].tolist() output_tokens = sampling_metadata.output_token_ids[batch_idx] if repetition_penalty > 1.0: # If `repetition_penalty` > 1.0, verify that the non-penalized # token ID has not been seen before, while the penalized token ID # exists either in the prompt or the output. assert (non_penalized_token_id not in prompt_tokens and \ non_penalized_token_id not in output_tokens) assert (penalized_token_id in prompt_tokens or \ penalized_token_id in output_tokens) elif repetition_penalty < 1.0: # If `repetition_penalty` < 1.0, verify that the penalized # token ID has not been seen before, while the non-penalized # token ID exists either in the prompt or the output. assert (penalized_token_id not in prompt_tokens and \ penalized_token_id not in output_tokens) assert (non_penalized_token_id in prompt_tokens or \ non_penalized_token_id in output_tokens)