"""A layer that samples the next tokens from the model's outputs.""" import itertools from typing import Dict, List, Optional, Tuple import torch import torch.nn as nn from vllm.model_executor.layers.ops.sample import sample as sample_triton from vllm.model_executor.sampling_metadata import (SamplingMetadata, SamplingTensors) from vllm.sampling_params import SamplingParams, SamplingType from vllm.sequence import (Logprob, PromptLogprobs, SampleLogprobs, SamplerOutput, SequenceData, SequenceGroupOutput, SequenceOutput) class Sampler(nn.Module): """Samples the next tokens from the model's outputs. This layer does the following: 1. Discard the hidden states that are not used for sampling (i.e., all tokens except the final one in each prompt). 2. Compute the logits for the next tokens. 3. Apply presence, frequency and repetition penalties. 4. Apply temperature scaling. 5. Apply top-p and top-k truncation. 6. Sample the next tokens. Here, each sequence group within the batch can have different sampling parameters (e.g., sampling method, temperature, top-p, top-k, etc.). The structure of the logits tensor is coupled with the seq_groups in sampling_metadata. Typically, each sequence in each seq_group has one row in logits for the next token to be sampled; however, for a seq_group with a prompt request with the prompt_logprobs sampling parameter, there are rows in logits for each token in the input prompt. """ def __init__(self, cfg_scale=1.0): super().__init__() self.cfg_scale = cfg_scale # Whether or not the SamplerOutput should have on-device tensors # containing the sampled token ids and probabilities. This is used by # speculative decoding. self.include_gpu_probs_tensor = False def forward( self, logits: torch.Tensor, sampling_metadata: SamplingMetadata, ) -> Optional[SamplerOutput]: assert logits is not None _, vocab_size = logits.shape if self.cfg_scale > 1.0: logits_combined = logits cond_logits, uncond_logits = torch.split(logits_combined, len(logits_combined) // 2, dim=0) logits = uncond_logits + (cond_logits - uncond_logits) * self.cfg_scale logits = torch.cat([logits, logits], dim=0) # Apply min_tokens penalty which sets stop tokens to -inf if min_tokens # have not been generated yet logits = _apply_min_tokens_penalty(logits, sampling_metadata) # Prepare sampling tensors with pinned memory to avoid blocking. (sampling_tensors, do_penalties, do_top_p_top_k, do_min_p) = SamplingTensors.from_sampling_metadata( sampling_metadata, vocab_size, logits.device, logits.dtype) # Apply presence and frequency penalties. if do_penalties: logits = _apply_penalties(logits, sampling_tensors.prompt_tokens, sampling_tensors.output_tokens, sampling_tensors.presence_penalties, sampling_tensors.frequency_penalties, sampling_tensors.repetition_penalties) # Apply temperature scaling. # Use in-place division to avoid creating a new tensor. logits.div_(sampling_tensors.temperatures.unsqueeze_(dim=1)) if do_top_p_top_k: logits = _apply_top_k_top_p(logits, sampling_tensors.top_ps, sampling_tensors.top_ks) if do_min_p: logits = _apply_min_p(logits, sampling_tensors.min_ps) # We use float32 for probabilities and log probabilities. # Compute the probabilities. probs = torch.softmax(logits, dim=-1, dtype=torch.float) # Compute the log probabilities. # Use log_softmax to ensure numerical stability. logprobs = torch.log_softmax(logits, dim=-1, dtype=torch.float) # Sample the next tokens. sample_results, maybe_sampled_tokens_tensor = _sample( probs, logprobs, sampling_metadata, sampling_tensors, include_gpu_probs_tensor=self.include_gpu_probs_tensor, modify_greedy_probs=self._should_modify_greedy_probs_inplace, ) if self.cfg_scale > 1.0: cond_result = sample_results[:len(sample_results) // 2] sample_results = cond_result + cond_result if self.include_gpu_probs_tensor: assert maybe_sampled_tokens_tensor is not None sampled_tokens_tensor = maybe_sampled_tokens_tensor on_device_tensors = (probs, sampled_tokens_tensor) else: on_device_tensors = None # Get the logprobs query results. prompt_logprobs, sample_logprobs = _get_logprobs( logprobs, sampling_metadata, sample_results) return _build_sampler_output(sample_results, sampling_metadata, prompt_logprobs, sample_logprobs, on_device_tensors=on_device_tensors) @property def _should_modify_greedy_probs_inplace(self) -> bool: """Whether or not the sampler should modify the probability distribution of greedily-sampled tokens such that multinomial sampling would sample the greedily-sampled token. In other words, if True then we set the probability of the greedily- sampled token to 1. This is used by speculative decoding, which requires that the sampling method be encoded into the probability distribution. """ # Modify greedy probs if include_gpu_probs_tensor is set. return self.include_gpu_probs_tensor def _get_bin_counts_and_mask( tokens: torch.Tensor, vocab_size: int, num_seqs: int, ) -> Tuple[torch.Tensor, torch.Tensor]: # Compute the bin counts for the tokens. # vocab_size + 1 for padding. bin_counts = torch.zeros((num_seqs, vocab_size + 1), dtype=torch.long, device=tokens.device) bin_counts.scatter_add_(1, tokens, torch.ones_like(tokens)) bin_counts = bin_counts[:, :vocab_size] mask = bin_counts > 0 return bin_counts, mask def _apply_min_tokens_penalty( logits: torch.Tensor, sampling_metadata: SamplingMetadata, ) -> torch.Tensor: # list of indices in logits that will be set to -inf logits_to_penalize = [] start_idx = 0 for i, seq_group in enumerate(sampling_metadata.seq_groups): seq_ids, sampling_params = seq_group # handle prompt_logprobs by skipping rows in logits added for the prompt # tokens (prompt logprobs are not penalized) if (i < sampling_metadata.num_prompts and sampling_params.prompt_logprobs is not None): assert len(seq_ids) == 1 start_idx += sampling_metadata.prompt_lens[i] - 1 min_tokens = sampling_params.min_tokens if min_tokens > 0: seqs_to_penalize = [] for i, seq_id in enumerate(seq_ids): seq_data = sampling_metadata.seq_data[seq_id] if len(seq_data.output_token_ids) < min_tokens: seqs_to_penalize.append(i) if seqs_to_penalize: # convert to the index into logits seqs_to_penalize = [start_idx + i for i in seqs_to_penalize] # use set() to remove any duplicates token_ids_to_penalize = set(sampling_params.stop_token_ids + [sampling_params.eos_token_id]) # itertools.product pairs each seq index with every token id logits_to_penalize.extend( itertools.product(seqs_to_penalize, token_ids_to_penalize)) start_idx += len(seq_ids) if logits_to_penalize: # use zip and * to group indices along each dimension # eg. [ (1,2), (1,3), (5,6) ] -> ( (1,1,5), (2,3,6) ) logits[tuple(zip(*logits_to_penalize))] = -float("inf") # verifies that no rows in logits were missed unexpectedly assert start_idx == logits.shape[0] return logits def _apply_penalties(logits: torch.Tensor, prompt_tokens_tensor: torch.Tensor, output_tokens_tensor: torch.Tensor, presence_penalties: torch.Tensor, frequency_penalties: torch.Tensor, repetition_penalties: torch.Tensor) -> torch.Tensor: num_seqs, vocab_size = logits.shape _, prompt_mask = _get_bin_counts_and_mask(prompt_tokens_tensor, vocab_size, num_seqs) output_bin_counts, output_mask = _get_bin_counts_and_mask( output_tokens_tensor, vocab_size, num_seqs) repetition_penalties = repetition_penalties[:, None].repeat(1, vocab_size) repetition_penalties[~(prompt_mask | output_mask)] = 1.0 logits = torch.where(logits > 0, logits / repetition_penalties, logits * repetition_penalties) # We follow the definition in OpenAI API. # Refer to https://platform.openai.com/docs/api-reference/parameter-details logits -= frequency_penalties.unsqueeze_(dim=1) * output_bin_counts logits -= presence_penalties.unsqueeze_(dim=1) * output_mask return logits def _apply_top_k_top_p( logits: torch.Tensor, p: torch.Tensor, k: torch.Tensor, ) -> torch.Tensor: logits_sort, logits_idx = logits.sort(dim=-1, descending=False) # Apply top-k. top_k_mask = logits_sort.size(1) - k.to(torch.long) # Get all the top_k values. top_k_mask = logits_sort.gather(1, top_k_mask.unsqueeze(dim=1)) top_k_mask = logits_sort < top_k_mask logits_sort.masked_fill_(top_k_mask, -float("inf")) # Apply top-p. probs_sort = logits_sort.softmax(dim=-1) probs_sum = probs_sort.cumsum(dim=-1) top_p_mask = probs_sum <= 1 - p.unsqueeze(dim=1) # at least one top_p_mask[:, -1] = False logits_sort.masked_fill_(top_p_mask, -float("inf")) # Re-sort the probabilities. src = torch.arange(logits_idx.shape[-1], device=logits_idx.device).expand_as(logits_idx) logits_idx_inv = torch.empty_like(logits_idx).scatter_(dim=-1, index=logits_idx, src=src) logits = torch.gather(logits_sort, dim=-1, index=logits_idx_inv) return logits def _apply_min_p( logits: torch.Tensor, min_p: torch.Tensor, ) -> torch.Tensor: """ Adapted from https://github.com/oobabooga/text-generation-webui/blob/3146124ec01f02c8fb1650a6517cf1b60b537aaf/modules/sampler_hijack.py#L16C17-L16C17 """ probs = torch.softmax(logits, dim=-1) top_probs, _ = probs.max(dim=-1, keepdim=True) scaled_min_p = min_p.unsqueeze_(dim=1) * top_probs tokens_to_remove = probs < scaled_min_p logits = logits.masked_fill_(tokens_to_remove, -float("inf")) return logits def _greedy_sample( selected_seq_groups: List[Tuple[List[int], SamplingParams]], samples: torch.Tensor, ) -> List[Tuple[List[int], List[int]]]: samples = samples.tolist() sample_idx = 0 results = [] for seq_group in selected_seq_groups: seq_ids, _ = seq_group num_parent_seqs = len(seq_ids) assert num_parent_seqs == 1, ( "Greedy sampling should have only one seq.") parent_ids = list(range(num_parent_seqs)) next_token_ids = [samples[sample_idx]] results.append((next_token_ids, parent_ids)) sample_idx += num_parent_seqs return results def _random_sample( selected_seq_groups: List[Tuple[List[int], SamplingParams]], is_prompts: List[bool], random_samples: torch.Tensor, ) -> List[Tuple[List[int], List[int]]]: # Find the maximum best_of value of the prompt phase requests. random_samples = random_samples.cpu() sample_idx = 0 results = [] for seq_group, is_prompt in zip(selected_seq_groups, is_prompts): seq_ids, sampling_params = seq_group num_parent_seqs = len(seq_ids) if is_prompt: # Prompt phase. parent_ids = [0] * sampling_params.best_of next_token_ids = random_samples[ sample_idx, :sampling_params.best_of].tolist() else: # Generation phase. parent_ids = list(range(num_parent_seqs)) next_token_ids = random_samples[sample_idx:sample_idx + num_parent_seqs, 0].tolist() results.append((next_token_ids, parent_ids)) sample_idx += num_parent_seqs return results def _beam_search_sample( selected_seq_groups: List[Tuple[List[int], SamplingParams]], is_prompts: List[bool], seq_data: Dict[int, SequenceData], logprobs: torch.Tensor, ) -> List[Tuple[List[int], List[int]]]: # We sample 2 * beam_width candidates to make sure that with high # probability we can get `beam_width` candidates in addition to # the finished sequences for the next iteration. See # https://github.com/tensorflow/tensor2tensor/blob/bafdc1b67730430d38d6ab802cbd51f9d053ba2e/tensor2tensor/utils/beam_search.py#L557-L563 # for details. See also HF reference: # https://github.com/huggingface/transformers/blob/a4dd53d88e4852f023332d284ff07a01afcd5681/src/transformers/generation/utils.py#L3063-L3065 # # NOTE: Beam search is not vectorized, so its speed can be slower than # other sampling methods. sample_idx = 0 results = [] for seq_group, is_prompt in zip(selected_seq_groups, is_prompts): seq_ids, sampling_params = seq_group num_parent_seqs = len(seq_ids) beam_width = sampling_params.best_of seq_group_logprobs = logprobs[sample_idx:sample_idx + num_parent_seqs] if is_prompt: # Prompt phase. assert num_parent_seqs == 1, ( "Prompt input should have only one seq.") parent_ids = [0] * (2 * beam_width) _, next_token_ids = torch.topk(seq_group_logprobs[0], 2 * beam_width) next_token_ids = next_token_ids.tolist() else: # Generation phase. cumulative_logprobs = [ seq_data[seq_id].cumulative_logprob for seq_id in seq_ids ] cumulative_logprobs = torch.tensor( cumulative_logprobs, dtype=torch.float, device=seq_group_logprobs.device) seq_group_logprobs = (seq_group_logprobs + cumulative_logprobs.unsqueeze(dim=1)) _, topk_ids = torch.topk(seq_group_logprobs.flatten(), 2 * beam_width) topk_ids = topk_ids.tolist() vocab_size = seq_group_logprobs.size(-1) parent_ids = [i // vocab_size for i in topk_ids] next_token_ids = [i % vocab_size for i in topk_ids] results.append((next_token_ids, parent_ids)) sample_idx += num_parent_seqs assert sample_idx == logprobs.size(0) return results # torch.multinomial forces a GPU<->CPU sync. # Therefore, we use an optimized implementation instead. # Note that we always sample with replacement. # probs will be modified in place, but this is fine, as we pass # in a copy already. def _multinomial( probs: torch.Tensor, num_samples: int, seq_groups: Optional[List[Tuple[List[int], SamplingParams]]] = None, generators: Optional[List[torch.Generator]] = None, ) -> torch.Tensor: if num_samples > 1: # This is equivalent to torch.repeat_interleaved (which also # forces a GPU<->CPU sync). # This allows us to do sampling with replacement by creating # num_samples copies of each row in the tensor, and then # batch sampling the resulting tensor. probs = probs[:, None, :].expand(probs.shape[0], num_samples, probs.shape[1]).contiguous().view( -1, probs.shape[1]) q = torch.empty_like(probs) if seq_groups is None: q.exponential_() else: sample_idx = 0 for (seq_ids, _), generator in zip(seq_groups, generators): next_sample_idx = sample_idx + len(seq_ids) * num_samples q[sample_idx:next_sample_idx].exponential_(generator=generator) sample_idx = next_sample_idx return probs.div_(q).argmax(dim=1).view(-1, num_samples) def _sample_with_torch( probs: torch.Tensor, logprobs: torch.Tensor, sampling_metadata: SamplingMetadata, include_gpu_probs_tensor: bool, modify_greedy_probs: bool, ) -> Tuple[List[Tuple[List[int], List[int]]], Optional[torch.Tensor]]: categorized_seq_group_ids = {t: [] for t in SamplingType} categorized_sample_indices = sampling_metadata.categorized_sample_indices for i, seq_group in enumerate(sampling_metadata.seq_groups): _, sampling_params = seq_group sampling_type = sampling_params.sampling_type categorized_seq_group_ids[sampling_type].append(i) sample_results_dict: Dict[int, Tuple[List[int], List[int]]] = {} sample_metadata = {} multinomial_samples = {} # Create output tensor for sampled token ids. if include_gpu_probs_tensor: sampled_token_ids_tensor = torch.empty(logprobs.shape[0], 1, dtype=torch.long, device=logprobs.device) else: sampled_token_ids_tensor = None # Counterintiutively, having two loops here is actually faster. # The first loop can run without waiting on GPU<->CPU sync. for sampling_type in SamplingType: sample_indices = categorized_sample_indices[sampling_type][:, 0] num_tokens = len(sample_indices) if num_tokens == 0: continue seq_group_ids = categorized_seq_group_ids[sampling_type] seq_groups = [sampling_metadata.seq_groups[i] for i in seq_group_ids] is_prompts = [i < sampling_metadata.num_prompts for i in seq_group_ids] sample_metadata[sampling_type] = (seq_group_ids, seq_groups, is_prompts, sample_indices) long_sample_indices = sample_indices.long() if sampling_type == SamplingType.GREEDY: greedy_samples = torch.argmax(logprobs[long_sample_indices], dim=-1) if include_gpu_probs_tensor: # Store sampled tokens in output tensor. sampled_token_ids_tensor[ long_sample_indices] = greedy_samples.unsqueeze(-1) if modify_greedy_probs: # If required, modify the probabilities such that sampling from # the modified distribution would always sample the argmax # token id. _modify_greedy_probs_inplace(logprobs, probs, long_sample_indices, greedy_samples) elif sampling_type in (SamplingType.RANDOM, SamplingType.RANDOM_SEED): max_best_of_in_batch = 1 for seq_group, is_prompt in zip(seq_groups, is_prompts): if is_prompt: _, sampling_params = seq_group max_best_of_in_batch = max(max_best_of_in_batch, sampling_params.best_of) seeded_args = {} if sampling_type == SamplingType.RANDOM else { "seq_groups": seq_groups, "generators": sampling_metadata.generators, } multinomial_samples[sampling_type] = _multinomial( probs[long_sample_indices], max_best_of_in_batch, **seeded_args) if include_gpu_probs_tensor: # Store sampled tokens in output tensor. sampled_token_ids_tensor[ long_sample_indices] = multinomial_samples[sampling_type] elif sampling_type == SamplingType.BEAM: beam_search_logprobs = logprobs[sample_indices] else: raise ValueError(f"Unsupported sampling type: {sampling_type}") # GPU<->CPU sync happens in the loop below. # This also converts the sample output to Python objects. for sampling_type in SamplingType: if sampling_type not in sample_metadata: continue seq_group_ids, seq_groups, is_prompts, sample_indices = sample_metadata[ sampling_type] if sampling_type == SamplingType.GREEDY: sample_results = _greedy_sample(seq_groups, greedy_samples) elif sampling_type in (SamplingType.RANDOM, SamplingType.RANDOM_SEED): sample_results = _random_sample(seq_groups, is_prompts, multinomial_samples[sampling_type]) elif sampling_type == SamplingType.BEAM: sample_results = _beam_search_sample(seq_groups, is_prompts, sampling_metadata.seq_data, beam_search_logprobs) sample_results_dict.update(zip(seq_group_ids, sample_results)) sample_results = [ sample_results_dict[i] for i in range(len(sampling_metadata.seq_groups)) ] return sample_results, sampled_token_ids_tensor def _sample_with_triton_kernel( probs: torch.Tensor, logprobs: torch.Tensor, sampling_metadata: SamplingMetadata, sampling_tensors: SamplingTensors, ) -> List[Tuple[List[int], List[int]]]: categorized_seq_group_ids = {t: [] for t in SamplingType} categorized_sample_indices = sampling_metadata.categorized_sample_indices for i, seq_group in enumerate(sampling_metadata.seq_groups): _, sampling_params = seq_group sampling_type = sampling_params.sampling_type categorized_seq_group_ids[sampling_type].append(i) sample_results_dict: Dict[int, Tuple[List[int], List[int]]] = {} sample_metadata = {} max_best_of_in_batch = 1 # Counterintiutively, having two loops here is actually faster. # The first loop can run without waiting on GPU<->CPU sync. for sampling_type in SamplingType: sample_indices = categorized_sample_indices[sampling_type][:, 0] sampled_token_indices = categorized_sample_indices[sampling_type][:, 1] num_tokens = len(sample_indices) if num_tokens == 0: continue seq_group_ids = categorized_seq_group_ids[sampling_type] seq_groups = [sampling_metadata.seq_groups[i] for i in seq_group_ids] is_prompts = [i < sampling_metadata.num_prompts for i in seq_group_ids] sample_metadata[sampling_type] = (seq_group_ids, seq_groups, is_prompts, sample_indices, sampled_token_indices) if sampling_type in (SamplingType.GREEDY, SamplingType.RANDOM, SamplingType.RANDOM_SEED): for seq_group, is_prompt in zip(seq_groups, is_prompts): if is_prompt: _, sampling_params = seq_group max_best_of_in_batch = max(max_best_of_in_batch, sampling_params.best_of) elif sampling_type == SamplingType.BEAM: beam_search_logprobs = logprobs[sample_indices] else: raise ValueError(f"Unsupported sampling type: {sampling_type}") sampled_tokens, _, _ = sample_triton( probs=probs, seeds=sampling_tensors.sampling_seeds, max_best_of=max_best_of_in_batch, sample_indices=sampling_tensors.sample_indices, logprobs=logprobs, # don't save logprobs because we have logic for that below # TODO: use this instead of the CPU-based logic below save_logprobs=False, ) # GPU<->CPU sync happens in the loop below. for sampling_type in SamplingType: if sampling_type not in sample_metadata: continue (seq_group_ids, seq_groups, is_prompts, sample_indices, sampled_token_indices) = sample_metadata[sampling_type] if sampling_type == SamplingType.GREEDY: sample_results = _greedy_sample( seq_groups, sampled_tokens[sampled_token_indices][:, 0]) elif sampling_type in (SamplingType.RANDOM, SamplingType.RANDOM_SEED): sample_results = _random_sample( seq_groups, is_prompts, sampled_tokens[sampled_token_indices]) elif sampling_type == SamplingType.BEAM: sample_results = _beam_search_sample(seq_groups, is_prompts, sampling_metadata.seq_data, beam_search_logprobs) sample_results_dict.update(zip(seq_group_ids, sample_results)) sample_results = [ sample_results_dict[i] for i in range(len(sampling_metadata.seq_groups)) ] return sample_results def _sample( probs: torch.Tensor, logprobs: torch.Tensor, sampling_metadata: SamplingMetadata, sampling_tensors: SamplingTensors, include_gpu_probs_tensor: bool, modify_greedy_probs: bool ) -> Tuple[List[Tuple[List[int], List[int]]], Optional[torch.Tensor]]: return _sample_with_torch( probs, logprobs, sampling_metadata, include_gpu_probs_tensor=include_gpu_probs_tensor, modify_greedy_probs=modify_greedy_probs, ) # TODO: Enable once Triton kernel & associated code is faster. # return _sample_with_triton_kernel(probs, logprobs, sampling_metadata, # sampling_tensors) def _get_ranks(x: torch.Tensor, indices: torch.Tensor) -> torch.Tensor: """ This function calculates the ranks of the chosen tokens in a logprob tensor. Args: x (torch.Tensor): 2D logprob tensor of shape (N, M) where N is the no. of tokens and M is the vocab dim. indices (torch.Tensor): List of chosen token indices. Returns: torch.Tensor: 1D tensor of shape (N,) where N is the no. of tokens. Each element in the returned tensor represents the rank of the chosen token in the input logprob tensor. """ vals = x[torch.arange(0, len(x), device=x.device, dtype=indices.dtype), indices] return (x > vals[:, None]).long().sum(1).add_(1) def _get_logprobs( logprobs: torch.Tensor, sampling_metadata: SamplingMetadata, sample_results: List[Tuple[List[int], List[int]]], ) -> Tuple[List[Optional[List[Optional[Dict[int, float]]]]], List[List[Dict[ int, float]]]]: # Prepare query indices batched_logprobs_query_seq_indices: List[int] = [] batched_logprobs_query_token_indices: List[int] = [] # at least get one logprob for each token largest_num_logprobs = 1 sample_idx = 0 for i, (seq_group, sample_result) in enumerate( zip(sampling_metadata.seq_groups, sample_results)): seq_ids, sampling_params = seq_group next_token_ids, parent_ids = sample_result num_parent_seqs = len(seq_ids) if (i < sampling_metadata.num_prompts and sampling_params.prompt_logprobs is not None): largest_num_logprobs = max(largest_num_logprobs, sampling_params.prompt_logprobs) prompt_len = sampling_metadata.prompt_lens[i] prompt_tokens = sampling_metadata.seq_data[ seq_ids[0]].prompt_token_ids batched_logprobs_query_seq_indices.extend( sample_idx + j for j in range(prompt_len - 1)) batched_logprobs_query_token_indices.extend( token_id for token_id in prompt_tokens[1:]) sample_idx += prompt_len - 1 batched_logprobs_query_seq_indices.extend( [sample_idx + parent_id for parent_id in parent_ids]) batched_logprobs_query_token_indices.extend(next_token_ids) if sampling_params.logprobs is not None: largest_num_logprobs = max(largest_num_logprobs, sampling_params.logprobs) sample_idx += num_parent_seqs assert sample_idx == logprobs.size(0) batched_logprobs_query_seq_indices_gpu = torch.tensor( batched_logprobs_query_seq_indices, device=logprobs.device) batched_logprobs_query_token_indices_gpu = torch.tensor( batched_logprobs_query_token_indices, device=logprobs.device) # Batched query for logprobs of selected token batched_logprobs_query_result = logprobs[[ batched_logprobs_query_seq_indices_gpu, batched_logprobs_query_token_indices_gpu ]] batched_ranks_query_result = _get_ranks( logprobs[batched_logprobs_query_seq_indices_gpu], batched_logprobs_query_token_indices_gpu) # Batched query for logprobs of topk tokens if largest_num_logprobs > 0: top_logprobs, top_token_ids = torch.topk(logprobs, largest_num_logprobs, dim=-1) top_logprobs = top_logprobs.cpu() top_token_ids = top_token_ids.cpu() else: top_logprobs, top_token_ids = None, None batched_logprobs_query_result = batched_logprobs_query_result.cpu() batched_ranks_query_result = batched_ranks_query_result.cpu() # Gather results result_prompt_logprobs: List[Optional[PromptLogprobs]] = [] result_sample_logprobs: List[SampleLogprobs] = [] sample_idx = 0 query_result_idx = 0 for i, (seq_group, sample_result) in enumerate( zip(sampling_metadata.seq_groups, sample_results)): seq_ids, sampling_params = seq_group next_token_ids, parent_ids = sample_result # Prompt logprobs if (i < sampling_metadata.num_prompts and sampling_params.prompt_logprobs is not None): num_logprobs = sampling_params.prompt_logprobs prompt_tokens = sampling_metadata.seq_data[ seq_ids[0]].prompt_token_ids group_prompt_logprobs: PromptLogprobs = [None] for token_id in prompt_tokens[1:]: prompt_logprobs_dict = { token_id: (batched_logprobs_query_result[query_result_idx].item(), batched_ranks_query_result[query_result_idx].item()) } if num_logprobs > 0: prompt_logprobs_dict.update( zip( top_token_ids[sample_idx, :num_logprobs].tolist(), zip( top_logprobs[ sample_idx, :num_logprobs].tolist(), range(1, num_logprobs + 1)))) group_prompt_logprobs.append({ token_id: Logprob(*logprob_rank) for token_id, logprob_rank in prompt_logprobs_dict.items() }) sample_idx += 1 query_result_idx += 1 result_prompt_logprobs.append(group_prompt_logprobs) else: result_prompt_logprobs.append(None) # Sample logprobs num_logprobs = sampling_params.logprobs if num_logprobs is None: num_logprobs = 0 group_sample_logprobs: SampleLogprobs = [] for next_token_id, parent_id in zip(next_token_ids, parent_ids): sample_logprobs_dict = { next_token_id: (batched_logprobs_query_result[query_result_idx].item(), batched_ranks_query_result[query_result_idx].item()) } query_result_idx += 1 if num_logprobs >= 0: sample_logprobs_dict.update( zip( top_token_ids[sample_idx + parent_id, :num_logprobs].tolist(), zip( top_logprobs[sample_idx + parent_id, :num_logprobs].tolist(), range(1, num_logprobs + 1)))) group_sample_logprobs.append({ token_id: Logprob(*logprob_rank) for token_id, logprob_rank in sample_logprobs_dict.items() }) result_sample_logprobs.append(group_sample_logprobs) sample_idx += len(seq_ids) return result_prompt_logprobs, result_sample_logprobs def _modify_greedy_probs_inplace(logprobs: torch.Tensor, probs: torch.Tensor, sample_indices: torch.Tensor, greedy_samples: torch.Tensor) -> None: """Modify the probability distributions of the greedily-sampled tokens such that each sampled token has a "probability" of 1.0. This is required by speculative decoding, which depends on the sampling method being encoded within the probability distribution for correctness. # Why do we only need to do this for greedy sampling? vLLM's sampler performs the following steps for greedy or multinomial (random) sampling: 1. Get logits from model. 2. Modify logits according to per-sequence sampling parameters. - Multiply by temperature, top-k and top-p masking, penalize tokens according to their frequency, etc. 3. Sample a token. - Random sampling simply samples from the modified probability distribution. - Greedy sampling performs `argmax` to obtain the token with the highest likelihood. Ignoring greedy sampling for a moment, we find that the computed probability distribution has the following property: we can sample from it independently and find that the token sampled by the Sampler has a frequency corresponding to how often we see it in our sampling. In other words, for tokens sampled with vLLM's random SamplingType, the computed probability distribution encodes the sampling methodology completely. Greedy sampling does not normally have this property. vLLM modifies logits according to sampling params, then performs `argmax`, then returns the sampled token and the computed probability distribution. If we sample from the distribution, we'll find the likelihood of the greedily-sampled token is not always 1.0. Since lossless speculative decoding requires that the sampling methodology be encoded within the probability distribution, we are motivated to modify the probability distribution such that the sampled token has probability 1 when speculative decoding is used. NOTE: Alternatively, we could use an extremely low temperature to achieve greedy sampling using multinomial computation and unite the codepaths. This has implications on the overall design of the sampler, e.g. how to record accurate logprobs for the user, so this improvement is deferred to later. """ logprobs[sample_indices, :] = -float('inf') logprobs[sample_indices, greedy_samples] = 0.0 probs[sample_indices, :] = 0 probs[sample_indices, greedy_samples] = 1.0 def _build_sampler_output( sample_results: List[Tuple[List[int], List[int]]], sampling_metadata: SamplingMetadata, prompt_logprobs: List[Optional[PromptLogprobs]], sample_logprobs: List[SampleLogprobs], on_device_tensors: Optional[Tuple[torch.Tensor, torch.Tensor]], ) -> SamplerOutput: """Construct Python objects with the output of sampling. Args: on_device_tensors: Tuple containing on-device tensors with the probabilities used in sampling and the sampled token ids. This allows post-processing without copies to CPU/serialization, e.g. in speculative decoding rejection sampling. """ sampler_output = [] for (seq_group, sample_result, group_prompt_logprobs, group_sample_logprobs) in zip(sampling_metadata.seq_groups, sample_results, prompt_logprobs, sample_logprobs): seq_ids, _ = seq_group next_token_ids, parent_ids = sample_result seq_outputs = [] for parent_id, next_token_id, logprobs in zip(parent_ids, next_token_ids, group_sample_logprobs): seq_outputs.append( SequenceOutput(seq_ids[parent_id], next_token_id, logprobs)) sampler_output.append( SequenceGroupOutput(seq_outputs, group_prompt_logprobs)) # If not specified, store None values in SamplerOutput. if on_device_tensors is not None: sampled_token_probs, sampled_token_ids = on_device_tensors else: sampled_token_probs, sampled_token_ids = (None, None) return SamplerOutput( outputs=sampler_output, sampled_token_probs=sampled_token_probs, sampled_token_ids=sampled_token_ids, )