# SPDX-License-Identifier: Apache-2.0 # SPDX-FileCopyrightText: Copyright contributors to the vLLM project import itertools import math from collections.abc import Generator from typing import get_args import pytest import torch from tests.utils import large_gpu_mark from tests.v1.sample.utils import ( BatchLogprobsComposition, BatchLogprobsSpecType, assert_incr_detok_str_matches_non_incr_detok_str, compute_correct_cumulative_logprob, get_test_batch, ) from vllm import SamplingParams from vllm.config.model import LogprobsMode from vllm.distributed import cleanup_dist_env_and_memory from vllm.platforms import current_platform from ...conftest import HfRunner, VllmRunner MODEL = "meta-llama/Llama-3.2-1B-Instruct" DTYPE = "half" NONE = BatchLogprobsComposition.NONE SAMPLE = BatchLogprobsComposition.SAMPLE PROMPT = BatchLogprobsComposition.PROMPT SAMPLE_PROMPT = BatchLogprobsComposition.SAMPLE_PROMPT # On ROCm, floating-point reductions in attention and GEMM kernels are # non-associative and sensitive to batch geometry. The ref LLM (no spec # decode, default scheduling) and the spec-decode LLM (chunked prefill, # different effective batch sizes) follow different reduction orders, # producing numerically divergent logprobs that get mis-attributed to # spec-decode incorrectness. # # Force LLM instances into an identical, deterministic execution # mode so the test isolates spec-decode correctness only: ROCM_DETERMINISM_KWARGS: dict = ( dict( max_num_seqs=1, ) if current_platform.is_rocm() else {} ) @pytest.fixture( scope="module", # Parameterize APC params=[False, True], ) def vllm_model(vllm_runner, request) -> Generator[VllmRunner, None, None]: with vllm_runner( MODEL, dtype=DTYPE, max_logprobs=7, # Very small number of batched tokens to ensure # that we test chunking. max_num_batched_tokens=16, max_num_seqs=16, max_model_len=128, enable_chunked_prefill=True, enforce_eager=True, # TODO: enable this once we support it for # prompt logprobs. enable_prefix_caching=request.param, gpu_memory_utilization=0.4, ) as vllm_model: yield vllm_model @pytest.fixture(scope="module") def hf_model(hf_runner) -> Generator[HfRunner, None, None]: with hf_runner(MODEL, dtype=DTYPE) as hf_model: yield hf_model def _repeat_logprob_config( test_prompts, logprob_prompt_logprob_list: BatchLogprobsSpecType, ) -> BatchLogprobsSpecType: """Ensure each test prompt has a logprob config. A logprob config specifies the optional (i.e. may-be-`None`) number of sample logprobs and the optional number of prompt logprobs. If more test prompts than logprob configs are provided, the provided logprob configs are tiled to match the number of test prompts. If fewer test prompts than logprob configs are provided, the list of logprob configs is truncated to match the number of test prompts. Otherwise, the list of logprob configs is returned as-is. Args: test_prompts: list of prompts under test logprob_prompt_logprob_list: list of (optional num sample logprob, optional num prompt logprob) tuples Returns: list of (optional num sample logprob,optional num prompt logprob) tuples which is either identical to `logprob_prompt_logprob_list`, or else repeats `logprob_prompt_logprob_list` enough times to match the number of `test_prompts`, or else is truncated to match the number of `test_prompts` """ num_test_prompts = len(test_prompts) # Make sure there is a logprobs configuration for each test prompt logprob_prompt_logprob_list = list( itertools.islice(itertools.cycle(logprob_prompt_logprob_list), num_test_prompts) ) # Now the number of prompts should match the number of sample params combos assert num_test_prompts == len(logprob_prompt_logprob_list) return logprob_prompt_logprob_list def _run_and_validate( vllm_model: VllmRunner, test_prompts: list[str], vllm_sampling_params: SamplingParams, hf_logprobs: list[list[torch.Tensor]], hf_outputs: list[tuple[list[int], str]], logprob_prompt_logprob_list: BatchLogprobsSpecType, temperature: float, max_tokens: int, do_apc: bool, ) -> None: vllm_results = vllm_model.llm.generate( test_prompts, sampling_params=vllm_sampling_params ) for vllm_result, hf_logprob, hf_output, logprob_prompt_logprob in zip( vllm_results, hf_logprobs, hf_outputs, logprob_prompt_logprob_list ): # Extract request-level (prompt)logprobs config num_top_logprobs, num_top_prompt_logprobs = logprob_prompt_logprob # Test whether sampled token output is consistent between vLLM and HF # vLLM prompt+completion should match HF output if temperature == 0.0: assert ( vllm_result.prompt_token_ids + vllm_result.outputs[0].token_ids == hf_output[0] ) else: # Sampled tokens won't match if not greedy assert ( vllm_result.prompt_token_ids == hf_output[0][: len(vllm_result.prompt_token_ids)] ) # Validate sample logprobs if num_top_logprobs is not None: assert num_top_logprobs is not None # Confirm that the structure of the sample logprobs in the result is # correct assert vllm_result.outputs[0].logprobs is not None assert len(vllm_result.outputs[0].logprobs) == max_tokens for logprobs, token_id in zip( vllm_result.outputs[0].logprobs, vllm_result.outputs[0].token_ids ): assert logprobs is not None # Confirm that the output token appears among the logprobs assert token_id in logprobs token_in_topk = logprobs[token_id].rank <= num_top_logprobs # If the output token is not included in the top K # logprob, it can return 1 more data if token_in_topk and num_top_logprobs != 0: assert len(logprobs) == num_top_logprobs else: assert len(logprobs) == num_top_logprobs + 1 if num_top_logprobs > 0: # We should have an entry for each of the topk ranks all_ranks = {lp.rank for lp in logprobs.values()} assert all(r in all_ranks for r in range(1, num_top_logprobs + 1)) output_text = vllm_result.outputs[0].text output_string_from_most_likely_tokens_lst: list[str] = [] for top_logprobs in vllm_result.outputs[0].logprobs: top_logprob = next(iter(top_logprobs.values())) output_string_from_most_likely_tokens_lst.append( top_logprob.decoded_token ) output_string_from_most_likely_tokens = "".join( output_string_from_most_likely_tokens_lst ) assert_incr_detok_str_matches_non_incr_detok_str( output_text, output_string_from_most_likely_tokens, "The output text from the top logprob for each token " "position should be the same as the output text in the " "result.", ) # Compare vLLM sample logprobs to HF vllm_sample_logprobs = vllm_result.outputs[0].logprobs for i, top_logprobs in enumerate(vllm_sample_logprobs): for token_id, sample_logprob in top_logprobs.items(): if temperature == 0.0 or i == 0: logprob = sample_logprob.logprob torch.testing.assert_close( logprob, hf_logprob[i][-1][token_id].item(), atol=1e-2, rtol=1e-2, ) assert isinstance(sample_logprob.decoded_token, str), ( "The token should be decoded by the time it is" " returned to the user." ) # At this point we know the sample logprobs are correct for this # request. Validate that cumulative_logprob is actually the sum. # For each request, assert that the returned cumulative logprob # matches the correct value, which is computed below. torch.testing.assert_close( vllm_result.outputs[0].cumulative_logprob, compute_correct_cumulative_logprob(vllm_result.outputs[0]), atol=1e-6, rtol=1e-6, ) else: # Logprobs disabled for this request; should be None assert vllm_result.outputs[0].logprobs is None # Validate prompt logprobs if num_top_prompt_logprobs is not None: # Confirm that structure of prompt logprobs in result is correct assert vllm_result.prompt_logprobs is not None # - The first prompt logprob is always None assert vllm_result.prompt_logprobs[0] is None # - Prompt logprobs are returned for all indices in # the prompt assert len(vllm_result.prompt_logprobs) == len(vllm_result.prompt_token_ids) for prompt_logprobs, prompt_token_id in zip( vllm_result.prompt_logprobs[1:], vllm_result.prompt_token_ids[1:] ): assert prompt_logprobs is not None # Confirm that the prompt token appears among the logprobs assert prompt_token_id in prompt_logprobs token_in_topk = ( prompt_logprobs[prompt_token_id].rank <= num_top_prompt_logprobs ) # If the prompt token is not included in the top K # logprob, it can return 1 more data if token_in_topk and num_top_prompt_logprobs != 0: assert len(prompt_logprobs) == num_top_prompt_logprobs else: assert len(prompt_logprobs) == num_top_prompt_logprobs + 1 if num_top_prompt_logprobs > 0: # We should have an entry for each of the topk ranks all_ranks = {lp.rank for lp in prompt_logprobs.values()} assert all( r in all_ranks for r in range(1, num_top_prompt_logprobs + 1) ) # Compare prompt logprobs to HF # The first prompt logprob is always None, so we compare it from # 1:. vllm_prompt_logprobs = vllm_result.prompt_logprobs[1:] for i, vllm_prompt_logprob_dict in enumerate(vllm_prompt_logprobs): for token_id, logprob in vllm_prompt_logprob_dict.items(): torch.testing.assert_close( logprob.logprob, hf_logprob[0][i][token_id].item(), atol=2e-2, rtol=2e-2, ) else: assert vllm_result.prompt_logprobs is None @pytest.mark.parametrize( "batch_logprobs_composition", [NONE, SAMPLE, PROMPT, SAMPLE_PROMPT] ) @pytest.mark.parametrize("temperature", [0.0, 2.0]) def test_get_logprobs_and_prompt_logprobs( hf_model, vllm_model, batch_logprobs_composition: BatchLogprobsComposition, temperature: float, example_prompts: list[str], ) -> None: """Test V1 Engine logprobs & prompt logprobs Exercise a variety of combinations of `logprobs` and `prompt_logprobs` settings and validate that * The generated logprobs and prompt logprobs are consistent with the configuration settings, in terms of whether or not the logprobs (of either type) were requested and how many were requested * The generated logprobs are consistent with the generated tokens * The generated (prompt)logprobs are consistent with HuggingFace (prompt)logprobs, as a reference batch_logprobs_composition controls the logprobs configurations for requests in the batch under test. APC tests run two test iterations so that cache hits occur. To save time, only test one APC-enabled scenario (sample & prompt logprobs enabled, temperature>0.0). Args: hf_model: HuggingFace reference model fixture vllm_model: vLLM model fixture batch_logprobs_composition: logprobs configuration for test batch temperature: "temperature" sampling parameter example_prompts: example prompt fixture """ vllm_config = vllm_model.llm.llm_engine.vllm_config do_apc = vllm_config.cache_config.enable_prefix_caching if do_apc and (temperature < 2.0 or batch_logprobs_composition != SAMPLE_PROMPT): # Skip some test-cases to save time. pytest.skip() test_prompts = example_prompts max_tokens = 5 hf_outputs = hf_model.generate_greedy( test_prompts, max_tokens=max_tokens, ) hf_logprobs = hf_model.generate_greedy_logprobs( test_prompts, max_tokens=max_tokens, ) # Batch has mixed sample params # (different logprobs/prompt logprobs combos) logprob_prompt_logprob_list = get_test_batch(batch_logprobs_composition) # Ensure that each test prompt has a logprob config for testing logprob_prompt_logprob_list = _repeat_logprob_config( test_prompts, logprob_prompt_logprob_list ) # Generate SamplingParams vllm_sampling_params = [ SamplingParams( max_tokens=max_tokens, logprobs=num_lp, prompt_logprobs=num_plp, temperature=temperature, seed=1984, ) for num_lp, num_plp in logprob_prompt_logprob_list ] for _ in range(2 if do_apc else 1): _run_and_validate( vllm_model=vllm_model, test_prompts=test_prompts, vllm_sampling_params=vllm_sampling_params, hf_logprobs=hf_logprobs, hf_outputs=hf_outputs, logprob_prompt_logprob_list=logprob_prompt_logprob_list, temperature=temperature, max_tokens=max_tokens, do_apc=do_apc, ) def test_max_logprobs(): """vLLM v1 engine should fail a request with `logprobs > max_logprobs` Should also fail for `prompt_logprobs > max_logprobs` APC should not matter as this test checks basic request validation. """ with VllmRunner( "facebook/opt-125m", max_logprobs=1, enable_prefix_caching=False, gpu_memory_utilization=0.15, max_model_len=256, ) as runner: vllm_sampling_params = SamplingParams(logprobs=1) # should pass runner.generate(["Hello world"], sampling_params=vllm_sampling_params) bad_sampling_params = SamplingParams(logprobs=2) with pytest.raises(ValueError): runner.generate(["Hello world"], sampling_params=bad_sampling_params) def test_none_logprobs(vllm_model, example_prompts): """Engine should return `logprobs` and `prompt_logprobs` as `None` Args: vllm_model: vLLM model fixture example_prompts: list of example prompts (test fixture) """ max_tokens = 5 sampling_params_logprobs_none = SamplingParams( max_tokens=max_tokens, logprobs=None, prompt_logprobs=None, temperature=0.0, ) results_logprobs_none = vllm_model.llm.generate( example_prompts, sampling_params=sampling_params_logprobs_none, ) for i in range(len(results_logprobs_none)): # Check sample logprobs are None assert results_logprobs_none[i].outputs[0].logprobs is None assert results_logprobs_none[i].outputs[0].cumulative_logprob is None # Check prompt logprobs are None assert results_logprobs_none[i].prompt_logprobs is None def test_zero_logprobs(vllm_model, example_prompts): """Engine should return sampled token and prompt token logprobs Args: vllm_model: vLLM model fixture example_prompts: list of example prompts (test fixture) """ max_tokens = 5 sampling_params_logprobs_zero = SamplingParams( max_tokens=max_tokens, logprobs=0, prompt_logprobs=0, temperature=0.0 ) results_logprobs_zero = vllm_model.llm.generate( example_prompts, sampling_params=sampling_params_logprobs_zero ) for i in range(len(results_logprobs_zero)): # Check that there is one sample logprob dict for each # sample token logprobs = results_logprobs_zero[i].outputs[0].logprobs prompt_logprobs = results_logprobs_zero[i].prompt_logprobs sampled_token_ids = results_logprobs_zero[i].outputs[0].token_ids prompt_token_ids = results_logprobs_zero[i].prompt_token_ids assert logprobs is not None assert len(sampled_token_ids) == len(logprobs) assert results_logprobs_zero[i].outputs[0].cumulative_logprob is not None # Check that there is one prompt logprob dict for each # prompt token assert prompt_logprobs is not None assert len(prompt_token_ids) == len(prompt_logprobs) def test_all_logprobs(example_prompts): """Engine should return all vocabulary logprobs and prompt logprobs Args: example_prompts: list of example prompts (test fixture) """ with VllmRunner( "facebook/opt-125m", max_logprobs=-1, enable_prefix_caching=False, gpu_memory_utilization=0.15, max_model_len=256, ) as runner: sampling_params_logprobs_all = SamplingParams( max_tokens=5, logprobs=-1, prompt_logprobs=-1 ) results_logprobs_all = runner.llm.generate( example_prompts, sampling_params=sampling_params_logprobs_all ) vocab_size = runner.llm.llm_engine.model_config.get_vocab_size() for i in range(len(results_logprobs_all)): logprobs = results_logprobs_all[i].outputs[0].logprobs prompt_logprobs = results_logprobs_all[i].prompt_logprobs assert logprobs is not None for logprob in logprobs: assert len(logprob) == vocab_size assert prompt_logprobs is not None assert prompt_logprobs[0] is None for prompt_logprob in prompt_logprobs[1:]: assert len(prompt_logprob) == vocab_size @pytest.mark.parametrize("logprobs_mode", get_args(LogprobsMode)) def test_logprobs_mode(logprobs_mode: LogprobsMode): """Test with LLM engine with different logprobs_mode. For logprobs, we should have non-positive values. For logits, we should expect at least one positive values. """ from vllm import LLM llm = LLM( "facebook/opt-125m", max_logprobs=5, enable_prefix_caching=False, # 2 other llms alive during whole session gpu_memory_utilization=0.05, max_model_len=16, logprobs_mode=logprobs_mode, ) try: vllm_sampling_params = SamplingParams(logprobs=1) results = llm.generate(["Hello world"], sampling_params=vllm_sampling_params) total_token_with_logprobs = 0 positive_values = 0 for output in results[0].outputs: for logprobs in output.logprobs: for token_id in logprobs: logprob = logprobs[token_id] if logprobs_mode in ("raw_logprobs", "processed_logprobs"): assert logprob.logprob <= 0 if logprob.logprob > 0: positive_values = positive_values + 1 total_token_with_logprobs = total_token_with_logprobs + 1 assert total_token_with_logprobs >= len(results[0].outputs) if logprobs_mode in ("raw_logits", "processed_logits"): assert positive_values > 0 finally: del llm torch.cuda.empty_cache() cleanup_dist_env_and_memory() class TestCorrectDecodedToken: """Unit tests for _correct_decoded_token method in LogprobsProcessor. This method handles UTF-8 decoding issues where incomplete byte sequences result in the Unicode replacement character "�" (U+FFFD). This commonly happens with byte-fallback tokenization when multi-byte UTF-8 characters are split across tokens. """ @pytest.fixture def mock_tokenizer(self): """Create a mock tokenizer for testing.""" from unittest.mock import Mock tokenizer = Mock() return tokenizer @pytest.fixture def processor_with_empty_logprobs(self, mock_tokenizer): """Create a LogprobsProcessor with empty logprobs.""" from vllm.v1.engine.logprobs import LogprobsProcessor processor = LogprobsProcessor( tokenizer=mock_tokenizer, logprobs=[], prompt_logprobs=None, cumulative_logprob=0.0, num_logprobs=1, num_prompt_logprobs=None, ) return processor @pytest.fixture def processor_with_previous_logprobs(self, mock_tokenizer): """Create a LogprobsProcessor with previous logprobs.""" from vllm.v1.engine.logprobs import LogprobsProcessor processor = LogprobsProcessor( tokenizer=mock_tokenizer, logprobs=[{123: None}], # Previous token ID is 123 prompt_logprobs=None, cumulative_logprob=0.0, num_logprobs=1, num_prompt_logprobs=None, ) return processor def test_correction_with_previous_token_in_list( self, processor_with_empty_logprobs ): """Test correction using previous token in the same list. Scenario: Token at idx=1 ends with "�", but when decoded with the previous token (idx=0), it forms a valid UTF-8 sequence. Example: token[0]="�", token[1]="�" -> together form "polarized" """ processor = processor_with_empty_logprobs tokens = [100, 101, 102] # token IDs # Mock tokenizer behavior: # - decode([102]) returns "�" (ends with replacement char) # - decode([101, 102]) returns "valid" (no replacement char) processor.tokenizer.decode.side_effect = lambda ids: ( "valid" if ids == [101, 102] else "�" ) result = processor._correct_decoded_token(2, tokens) assert result == "valid" processor.tokenizer.decode.assert_called_with([101, 102]) def test_correction_with_previous_logprob_token( self, processor_with_previous_logprobs ): """Test correction using previous logprob token. Scenario: Cannot correct with previous token in list (idx=0), but can correct with previous logprob token. """ processor = processor_with_previous_logprobs tokens = [100] # single token # Mock tokenizer behavior: # - decode([100]) returns "�" (ends with replacement char) # - decode([123, 100]) returns " "polarized" (no replacement char) # Token 123 is from previous logprobs def mock_decode(ids): if ids == [123, 100]: return ' "polarized"' return "�" processor.tokenizer.decode.side_effect = mock_decode result = processor._correct_decoded_token(0, tokens) assert result == ' "polarized"' def test_correction_at_idx_zero_no_previous_logprobs( self, processor_with_empty_logprobs ): """Test correction at idx=0 with no previous logprobs. Scenario: First token in list, no previous logprobs available. Should return empty string as fallback. """ processor = processor_with_empty_logprobs tokens = [100] # Mock tokenizer always returns "�" processor.tokenizer.decode.return_value = "�" result = processor._correct_decoded_token(0, tokens) assert result == "" def test_correction_at_idx_zero_with_previous_logprobs( self, processor_with_previous_logprobs ): """Test correction at idx=0 with previous logprobs available. Scenario: First token in list, but previous logprobs exist. Should try correction with previous logprob token. """ processor = processor_with_previous_logprobs tokens = [200] # Mock tokenizer behavior def mock_decode(ids): if ids == [123, 200]: return "corrected" return "�" processor.tokenizer.decode.side_effect = mock_decode result = processor._correct_decoded_token(0, tokens) assert result == "corrected" def test_no_correction_needed_returns_fallback( self, processor_with_previous_logprobs ): """Test fallback to empty string when no correction works. Scenario: All correction attempts still end with "�". Should return empty string as final fallback. """ processor = processor_with_previous_logprobs tokens = [100, 101, 102] # Mock tokenizer always returns text ending with "�" processor.tokenizer.decode.return_value = "still�" result = processor._correct_decoded_token(2, tokens) assert result == "" def test_middle_token_correction(self, processor_with_previous_logprobs): """Test correction for a token in the middle of the list. Scenario: Token at idx=5 in a longer list needs correction. """ processor = processor_with_previous_logprobs tokens = [10, 20, 30, 40, 50, 60, 70, 80] # Mock tokenizer behavior for middle token def mock_decode(ids): if ids == [50, 60]: return "olar" return "�" processor.tokenizer.decode.side_effect = mock_decode result = processor._correct_decoded_token(5, tokens) assert result == "olar" def test_multiple_consecutive_replacement_chars( self, processor_with_previous_logprobs ): """Test handling of multiple consecutive replacement characters. Scenario: Sequence like ["�", "�", "p"] where first two should become empty strings. """ processor = processor_with_previous_logprobs # Test first replacement char tokens = [100, 101, 102] processor.tokenizer.decode.return_value = "still�" result1 = processor._correct_decoded_token(0, tokens) assert result1 == "" # Test second replacement char result2 = processor._correct_decoded_token(1, tokens) assert result2 == "" def test_correction_with_multibyte_utf8(self, processor_with_previous_logprobs): """Test correction involving multi-byte UTF-8 characters. Scenario: Byte-fallback tokenization splits multi-byte UTF-8 characters (e.g., curly quotes, Chinese characters, emojis). Example from user: "�", "�" -> "", "\"" """ processor = processor_with_previous_logprobs tokens = [200, 201] # Mock tokenizer behavior for multi-byte UTF-8 correction def mock_decode(ids): # When decoding first token (idx=0) with previous logprob token if ids == [123, 200]: return ' "' # Space + left curly quote # When decoding second token (idx=1) with previous token in list elif ids == [200, 201]: return '"' # Right curly quote # When decoding second token (idx=1) with previous logprob + prev token elif ids == [123, 200, 201]: return ' ""' # Full sequence return "�" processor.tokenizer.decode.side_effect = mock_decode # First token correction (idx=0) # Will call decode([123, 200]) since idx=0 uses previous logprob token result1 = processor._correct_decoded_token(0, tokens) assert result1 == ' "' # Second token correction (idx=1) # Will call decode([200, 201]) since idx>0 uses previous token in list result2 = processor._correct_decoded_token(1, tokens) assert result2 == '"' def test_real_world_opt125m_scenario(self, mock_tokenizer): """Test the real-world scenario from user's example. User's example with facebook/opt-125m: Before: [" the", " term", " �", "�", "p", "olar", "ized", "�", "�", ...] After: [" the", " term", "", " "", "p", "olar", "ized", "", "\"", ...] """ from vllm.v1.engine.logprobs import LogprobsProcessor # Simulate the sequence of tokens processor = LogprobsProcessor( tokenizer=mock_tokenizer, logprobs=[], prompt_logprobs=None, cumulative_logprob=0.0, num_logprobs=1, num_prompt_logprobs=None, ) # Token IDs representing the problematic sequence tokens = [1, 2, 3, 4, 5, 6, 7, 8, 9] # placeholder IDs # Mock decode behavior simulating the real scenario def mock_decode(ids): # Simulate cases where individual tokens decode to "�" # but combinations decode correctly if len(ids) == 1: if ids[0] in (3, 4, 8, 9): return "�" elif len(ids) == 2: if ids == [2, 3]: return " term�" # Still ends with �, need more context elif ids == [3, 4]: return ' "' # Corrected to space + left curly quote elif ids == [7, 8]: return "ized�" # Still ends with � elif ids == [8, 9]: return '"' # Corrected to right curly quote elif len(ids) == 3: if ids == [1, 2, 3]: return " the term�" # Still ends with issue elif ids == [2, 3, 4]: return ' term "' # With all context return "normal_text" mock_tokenizer.decode.side_effect = mock_decode # Test token at index 2 (should fail to correct, return "") # Token 3 individually is "�" # decode([2, 3]) = " term�" (still ends with �) # No previous logprobs, so fallback to "" result = processor._correct_decoded_token(2, tokens) assert result == "" # Test token at index 3 (should correct to " "") # Token 4 individually is "�" # decode([3, 4]) = " "" (corrected!) processor.logprobs = [{2: None}] # Add previous logprob result = processor._correct_decoded_token(3, tokens) assert result == ' "' def test_verify_tokens_integration(): """Integration test for _verify_tokens with real model. This test validates that _verify_tokens correctly identifies and corrects tokens ending with the replacement character "�". Uses facebook/opt-125m which is known to produce these issues. """ with VllmRunner( "facebook/opt-125m", max_logprobs=0, enable_prefix_caching=False, gpu_memory_utilization=0.15, max_model_len=256, ) as runner: # Use a prompt that triggers multi-byte UTF-8 issues # Based on user's example: "In this example," test_prompts = ["In this example,"] sampling_params = SamplingParams( max_tokens=16, temperature=0, logprobs=0, ) results = runner.llm.generate(test_prompts, sampling_params=sampling_params) # Verify that decoded tokens don't contain replacement characters for result in results: assert result.outputs[0].logprobs is not None for logprob_dict in result.outputs[0].logprobs: for token_id, logprob_info in logprob_dict.items(): decoded_token = logprob_info.decoded_token # Decoded tokens should not end with replacement character # They should either be corrected or empty string assert not decoded_token.endswith("�"), ( f"Token {token_id} decoded to '{decoded_token}' which " f"ends with replacement character" ) # Decoded tokens should not contain lone replacement characters assert decoded_token != "�", ( f"Token {token_id} is a lone replacement character" ) def test_utf8_edge_cases_with_real_model(): """Test various UTF-8 edge cases with a real model. Tests prompts that are likely to trigger byte-fallback tokenization and multi-byte UTF-8 splitting. """ with VllmRunner( "facebook/opt-125m", max_logprobs=1, enable_prefix_caching=False, gpu_memory_utilization=0.15, max_model_len=256, ) as runner: # Prompts with various multi-byte UTF-8 characters test_prompts = [ 'Smart quotes: "Hello"', # Curly quotes "Em dash — test", # Em dash "Ellipsis… continues", # Ellipsis "Chinese: 你好", # Chinese characters "Emoji: 😀 🎉", # Emojis 'Mixed: "quoted" — with symbols', # Mixed ] sampling_params = SamplingParams( max_tokens=10, temperature=0, logprobs=1, ) results = runner.llm.generate(test_prompts, sampling_params=sampling_params) for i, result in enumerate(results): prompt = test_prompts[i] assert result.outputs[0].logprobs is not None # Check that no decoded tokens end with replacement character for logprob_dict in result.outputs[0].logprobs: for token_id, logprob_info in logprob_dict.items(): decoded_token = logprob_info.decoded_token assert not decoded_token.endswith("�"), ( f"Prompt: '{prompt}'\n" f"Token {token_id} decoded to '{decoded_token}' which " f"ends with replacement character" ) def test_correct_decoded_token_preserves_valid_tokens(): """Test that valid tokens (not ending with �) are not modified. The _correct_decoded_token method should only be called for tokens ending with "�", but this test verifies the broader _verify_tokens logic doesn't affect valid tokens. """ with VllmRunner( "facebook/opt-125m", max_logprobs=2, enable_prefix_caching=False, gpu_memory_utilization=0.15, max_model_len=256, ) as runner: # Simple prompt with standard ASCII characters test_prompts = ["Hello world, this is a test."] sampling_params = SamplingParams( max_tokens=10, temperature=0, logprobs=2, ) results = runner.llm.generate(test_prompts, sampling_params=sampling_params) for result in results: assert result.outputs[0].logprobs is not None # All decoded tokens should be valid strings for logprob_dict in result.outputs[0].logprobs: for token_id, logprob_info in logprob_dict.items(): decoded_token = logprob_info.decoded_token # Valid tokens should be non-empty strings (or empty if corrected) assert isinstance(decoded_token, str) # Should not contain replacement character assert "�" not in decoded_token @pytest.mark.parametrize("logprobs_mode", get_args(LogprobsMode)) @pytest.mark.parametrize( "model_setup", [ pytest.param( ( "eagle", "meta-llama/Llama-3.2-1B-Instruct", { "method": "eagle", "model": "nm-testing/Llama3_2_1B_speculator.eagle3", "num_speculative_tokens": 3, }, 0, ), marks=large_gpu_mark(min_gb=32), id="eagle0", ), pytest.param( ( "eagle", "meta-llama/Llama-3.2-1B-Instruct", { "method": "eagle", "model": "nm-testing/Llama3_2_1B_speculator.eagle3", "num_speculative_tokens": 3, }, 3, ), marks=large_gpu_mark(min_gb=32), id="eagle3", ), pytest.param( ( "ngram", "meta-llama/Llama-3.2-1B-Instruct", { "method": "ngram", "prompt_lookup_max": 5, "prompt_lookup_min": 3, "num_speculative_tokens": 3, }, 3, ), marks=large_gpu_mark(min_gb=32), id="ngram", ), ], ) def test_spec_decode_logprobs( logprobs_mode: LogprobsMode, model_setup: tuple[str, str, dict, int], monkeypatch, ): """Spec decode logprobs should match those of the base model. Runs the base model and spec decode model sequentially, ensuring only one LLM instance is alive at a time to avoid GPU memory contention. Both use identical chunked prefill settings and eager mode to control for infrastructure differences. Args: logprobs_mode: logprobs mode. model_setup: Tuple of (method, base model name, speculative_config dict, top_logprobs). monkeypatch: pytest fixture for setting env vars. """ from vllm import LLM # The ROCm skinny GEMM kernels (gemm_kernels.cu) are # non-deterministic across LLM instantiations due to persistent # workgroup scheduling and wave-level shuffle reductions, which # causes logprob differences that get misattributed to spec decode. # Disable them so this test isolates spec decode correctness only. # TODO(akaratza): Remove this workaround once the follow-up to # https://github.com/vllm-project/vllm/pull/33493#issuecomment-3906083975 # lands with a determinism fix for wvSplitK kernels. monkeypatch.setenv("VLLM_ROCM_USE_SKINNY_GEMM", "0") method, model_name, spec_config, top_logprobs = model_setup prompt = "Hello world " * 50 sampling_params = SamplingParams( temperature=0, logprobs=top_logprobs, max_tokens=10, ignore_eos=False ) penalty_sampling_params = SamplingParams( temperature=0, logprobs=top_logprobs, max_tokens=10, ignore_eos=False, presence_penalty=-1.0, ) max_model_len = 256 # Run base LLM. ref_llm = LLM( model=model_name, max_logprobs=5, max_model_len=max_model_len, seed=42, logprobs_mode=logprobs_mode, gpu_memory_utilization=0.4, enable_prefix_caching=False, **ROCM_DETERMINISM_KWARGS, ) ref_results = ref_llm.generate( [prompt, prompt], [sampling_params, penalty_sampling_params] ) # Collect logprobs outputs from reference LLM. ref_logprobs = [] for results in ref_results: for output in results.outputs: for logprobs in output.logprobs: ref_logprobs.extend(logprobs.values()) del ref_llm torch.cuda.empty_cache() cleanup_dist_env_and_memory() # Run spec decode LLM. # Add max_model_len to spec_config if not present spec_config_with_len = {**spec_config, "max_model_len": max_model_len} spec_llm = LLM( model_name, speculative_config=spec_config_with_len, max_logprobs=5, max_model_len=max_model_len, seed=42, logprobs_mode=logprobs_mode, gpu_memory_utilization=0.4, # Force prefill chunking enable_chunked_prefill=True, max_num_batched_tokens=32, enable_prefix_caching=False, **ROCM_DETERMINISM_KWARGS, ) spec_results = spec_llm.generate( [prompt, prompt], [sampling_params, penalty_sampling_params] ) # Collect logprobs outputs from spec decode LLM. spec_logprobs = [] for results in spec_results: for output in results.outputs: for logprobs in output.logprobs: spec_logprobs.extend(logprobs.values()) del spec_llm torch.cuda.empty_cache() cleanup_dist_env_and_memory() # Per-token logprobs are expected to be the same. assert len(ref_logprobs) == len(spec_logprobs) for ref_logprob, spec_logprob in zip(ref_logprobs, spec_logprobs): assert math.isclose( ref_logprob.logprob, spec_logprob.logprob, rel_tol=5e-2, abs_tol=1e-1 ), ( f"Logprob mismatch: ref={ref_logprob.logprob} " f"spec={spec_logprob.logprob} " f"diff={abs(ref_logprob.logprob - spec_logprob.logprob)} " f"(token={ref_logprob.decoded_token!r})" ) assert ref_logprob.rank == spec_logprob.rank, ( f"Rank mismatch: ref={ref_logprob.rank} " f"spec={spec_logprob.rank} " f"(token={ref_logprob.decoded_token!r})" ) assert ref_logprob.decoded_token == spec_logprob.decoded_token def test_prompt_logprobs_with_chunking_and_preemption(): """Test that prompt logprobs are correctly returned when using both chunked prefill and preemption. This test ensures that the num_prompt_logprobs tracking persists across preemptions and prefill chunks. """ # Create prompts that will trigger chunking and preemption prompts = [ "The following numbers of the sequence " + ", ".join(str(i) for i in range(10)) + " are:", "In one word, the capital of France is ", ] + [f"Tell me about the number {i}: " for i in range(32)] sampling_params = SamplingParams( temperature=0.0, max_tokens=40, min_tokens=20, prompt_logprobs=2, # Request prompt logprobs ) with VllmRunner( "Qwen/Qwen3-0.6B", max_model_len=512, enable_chunked_prefill=True, max_num_batched_tokens=48, # Force prefill chunking num_gpu_blocks_override=32, # Force preemptions disable_log_stats=False, gpu_memory_utilization=0.25, ) as vllm_model: metrics_before = vllm_model.llm.get_metrics() # Generate with prompt logprobs using generate_w_logprobs which # returns (output_ids, output_str, output_logprobs, prompt_logprobs) outputs = vllm_model.generate_w_logprobs( prompts, sampling_params=sampling_params, include_prompt_token_ids=True ) # Verify that all outputs have prompt logprobs for i, output in enumerate(outputs): _, _, _, prompt_token_ids, prompt_logprobs = output assert prompt_logprobs is not None and len(prompt_logprobs) > 0, ( f"Output {i} missing prompt logprobs" ) assert len(prompt_logprobs) == len(prompt_token_ids), ( "Unexpected number of prompt logprob positions" ) # Each position should have the requested number of logprobs for pos, logprobs_dict in enumerate(prompt_logprobs): if logprobs_dict is not None: # First token may be None assert ( sampling_params.prompt_logprobs <= len(logprobs_dict) <= sampling_params.prompt_logprobs + 1 ), ( f"Output {i} position {pos} has {len(logprobs_dict)} " f"logprobs, expected {sampling_params.prompt_logprobs}" ) # Check that we actually had preemptions metrics_after = vllm_model.llm.get_metrics() preemptions_before = next( (m.value for m in metrics_before if m.name == "vllm:num_preemptions"), 0 ) preemptions_after = next( (m.value for m in metrics_after if m.name == "vllm:num_preemptions"), 0 ) preemptions = preemptions_after - preemptions_before assert preemptions > 0, "Test did not trigger any preemptions" print(f"Test passed with {preemptions} preemptions")