import abc from dataclasses import dataclass, field, asdict import re import ast import yaml import evaluate import random import itertools import functools from tqdm import tqdm import datasets import numpy as np from typing import Union, List, Any, Tuple, Literal from collections.abc import Callable from lm_eval import utils from lm_eval.api import samplers from lm_eval.api.instance import Instance from lm_eval.api.filter import FilterEnsemble from lm_eval.logger import eval_logger from lm_eval.prompts import get_prompt from lm_eval.filters import build_filter_ensemble from lm_eval.api.metrics import ( mean, weighted_perplexity, bits_per_byte, metric_max_over_ground_truths, ) from lm_eval.api.registry import ( get_metric, get_aggregation, get_default_aggregation, is_higher_better, DEFAULT_METRIC_REGISTRY, OUTPUT_TYPE_REGISTRY, AGGREGATION_REGISTRY, ) ALL_OUTPUT_TYPES = [ "loglikelihood", "multiple_choice", "loglikelihood_rolling", "greedy_until", ] @dataclass class TaskConfig(dict): # task naming/registry task: str = None group: Union[str, list] = None # HF dataset options. # which dataset to use, # and what splits for what purpose dataset_path: str = None dataset_name: str = None dataset_kwargs: dict = None training_split: str = None validation_split: str = None test_split: str = None fewshot_split: str = None # TODO: assert that this not None if num_fewshot > 0. (?) assert if this is same split as one evaling (?) # formatting / prompting options. # see docs/advanced_task_guide.md for more info process_docs: Callable = None doc_to_text: Union[Callable, str] = None doc_to_target: Union[Callable, str] = None doc_to_choice: Union[Callable, str, dict, list] = None gold_alias: Union[Callable, str] = None process_results: Union[Callable, str] = None use_prompt: str = None description: str = "" target_delimiter: str = " " fewshot_delimiter: str = "\n\n" fewshot_config: dict = None # runtime configuration options num_fewshot: int = 0 # scoring options metric_list: list = None output_type: str = "greedy_until" generation_kwargs: dict = None repeats: int = 1 filter_list: Union[str, list] = None should_decontaminate: bool = False doc_to_decontamination_query: str = None metadata: str = None # by default, not used in the code. allows for users to pass arbitrary info to tasks def __post_init__(self) -> None: if "." in self.dataset_path: import inspect from importlib import import_module self.dataset_path = inspect.getfile(import_module(self.dataset_path)) if self.generation_kwargs is not None: if self.output_type != "greedy_until": eval_logger.warning( "passed `generation_kwargs`, but not using `output_type: greedy_until`!" ) assert self.output_type != "greedy_until" if "temperature" in self.generation_kwargs: self.generation_kwargs["temperature"] = float( self.generation_kwargs["temperature"] ) if "until" not in self.generation_kwargs: self.generation_kwargs["until"] = [self.fewshot_delimiter] else: if self.output_type == "greedy_until": # ensure that we greedily generate in absence of explicit arguments otherwise self.generation_kwargs = { "until": None if self.fewshot_delimiter is None else [self.fewshot_delimiter], "do_sample": False, } # TODO: how to make TaskConfigs be de- and re-serializable, even when using the !function constructor? def __getitem__(self, item): return getattr(self, item) def __setitem__(self, item, value): return setattr(self, item, value) def to_dict(self): """dumps the current config as a dictionary object, as a printable format. null fields will not be printed. Used for dumping results alongside full task configuration :return: dict A printable dictionary version of the TaskConfig object. # TODO: should any default value in the TaskConfig not be printed? """ cfg_dict = asdict(self) # remove values that are `None` for k, v in list(cfg_dict.items()): if v is None: cfg_dict.pop(k) elif isinstance(v, Callable): # TODO: this should handle Promptsource template objects as a separate case? cfg_dict[k] = str(v) return cfg_dict class Task(abc.ABC): """A task represents an entire benchmark including its dataset, problems, answers, and evaluation methods. See BoolQ for a simple example implementation A `doc` can be any python object which represents one instance of evaluation. This is usually a dictionary e.g. {"question": ..., "answer": ...} or {"question": ..., question, answer) """ VERSION = None # The name of the `Task` benchmark as denoted in the HuggingFace datasets Hub # or a path to a custom `datasets` loading script. DATASET_PATH: str = None # The name of a subset within `DATASET_PATH`. DATASET_NAME: str = None OUTPUT_TYPE: str = None def __init__( self, data_dir=None, cache_dir=None, download_mode=None, config=None, ) -> None: """ :param data_dir: str Stores the path to a local folder containing the `Task`'s data files. Use this to specify the path to manually downloaded data (usually when the dataset is not publicly accessible). :param cache_dir: str The directory to read/write the `Task` dataset. This follows the HuggingFace `datasets` API with the default cache directory located at: `~/.cache/huggingface/datasets` NOTE: You can change the cache location globally for a given process to another directory: `export HF_DATASETS_CACHE="/path/to/another/directory"` :param download_mode: datasets.DownloadMode How to treat pre-existing `Task` downloads and data. - `datasets.DownloadMode.REUSE_DATASET_IF_EXISTS` Reuse download and reuse dataset. - `datasets.DownloadMode.REUSE_CACHE_IF_EXISTS` Reuse download with fresh dataset. - `datasets.DownloadMode.FORCE_REDOWNLOAD` Fresh download and fresh dataset. """ self.download(data_dir, cache_dir, download_mode) self._training_docs = None self._fewshot_docs = None self._instances = None self._config = TaskConfig(**config) if config else TaskConfig() if not hasattr(self, "_filters"): self._filters = [] for name, components in self._config.get( "filters", [["none", [["take_first", None]]]] ): filter_pipeline = build_filter_ensemble(name, components) self._filters.append(filter_pipeline) self.sampler = samplers.Sampler( list(self.fewshot_docs()), self, rnd=random.Random(1234) ) def download(self, data_dir=None, cache_dir=None, download_mode=None) -> None: """Downloads and returns the task dataset. Override this method to download the dataset from a custom API. :param data_dir: str Stores the path to a local folder containing the `Task`'s data files. Use this to specify the path to manually downloaded data (usually when the dataset is not publicly accessible). :param cache_dir: str The directory to read/write the `Task` dataset. This follows the HuggingFace `datasets` API with the default cache directory located at: `~/.cache/huggingface/datasets` NOTE: You can change the cache location globally for a given process by setting the shell environment variable, `HF_DATASETS_CACHE`, to another directory: `export HF_DATASETS_CACHE="/path/to/another/directory"` :param download_mode: datasets.DownloadMode How to treat pre-existing `Task` downloads and data. - `datasets.DownloadMode.REUSE_DATASET_IF_EXISTS` Reuse download and reuse dataset. - `datasets.DownloadMode.REUSE_CACHE_IF_EXISTS` Reuse download with fresh dataset. - `datasets.DownloadMode.FORCE_REDOWNLOAD` Fresh download and fresh dataset. """ self.dataset = datasets.load_dataset( path=self.DATASET_PATH, name=self.DATASET_NAME, data_dir=data_dir, cache_dir=cache_dir, download_mode=download_mode, ) @property def config(self): """Returns the TaskConfig associated with this class.""" return self._config @abc.abstractmethod def has_training_docs(self): """Whether the task has a training set""" pass @abc.abstractmethod def has_validation_docs(self): """Whether the task has a validation set""" pass @abc.abstractmethod def has_test_docs(self): """Whether the task has a test set""" pass def training_docs(self): """ :return: Iterable[obj] A iterable of any object, that doc_to_text can handle """ return [] def validation_docs(self): """ :return: Iterable[obj] A iterable of any object, that doc_to_text can handle """ return [] def test_docs(self): """ :return: Iterable[obj] A iterable of any object, that doc_to_text can handle """ return [] def fewshot_docs(self): """ :return: Iterable[obj] A iterable of any object, that doc_to_text can handle """ if self.has_training_docs(): return self.training_docs() elif self.has_validation_docs(): return self.validation_docs() else: eval_logger.warning( "has_training_docs and has_validation_docs are False" ", using test_docs as fewshot_docs but this is not recommended." ) return self.test_docs() def _process_doc(self, doc): """ Override this to process (detokenize, strip, replace, etc.) individual documents. This can be used in a map over documents of a data split. E.g. `map(self._process_doc, self.dataset["validation"])` :return: dict The processed version of the specified `doc`. """ return doc @property def instances(self): """After calling `task.build_all_requests()`, tasks maintain a list of the dataset instances which will be evaluated. """ return self._instances def fewshot_examples(self, k, rnd): if self._training_docs is None: self._training_docs = list(self.training_docs()) return rnd.sample(self._training_docs, k) def doc_to_decontamination_query(self, doc) -> None: print( "Override doc_to_decontamination_query with document specific decontamination query." ) assert False @abc.abstractmethod def doc_to_text(self, doc): pass @abc.abstractmethod def doc_to_target(self, doc): pass def build_all_requests(self, limit=None, rank=None, world_size=None) -> None: """Build a set of Instances for a task, and store them in task.instances""" if self.has_test_docs(): docs = self.test_docs() elif self.has_validation_docs(): docs = self.validation_docs() else: assert ( False ), f"Task dataset (path={self.DATASET_PATH}, name={self.DATASET_NAME}) must have valid or test docs!" eval_logger.info( f"Building contexts for task '{self.config.task}' on rank {rank}..." ) instances = [] for doc_id, doc in utils.create_iterator( enumerate(docs), rank, world_size, limit ): # sample fewshot context #TODO: need to offset doc_id by rank now! fewshot_ctx = self.fewshot_context( doc, self.config.num_fewshot, ) # TODO: we should override self.config.repeats if doing greedy gen so users don't waste time+compute inst = self.construct_requests( doc=doc, ctx=fewshot_ctx, metadata=(self.config["task"], doc_id, self.config.repeats), ) if not isinstance(inst, list): inst = [inst] instances.extend(inst) self._instances = instances assert len(self._instances) != 0, "task.build_requests() did not find any docs!" @abc.abstractmethod def construct_requests(self, doc, ctx, **kwargs): """Uses RequestFactory to construct Requests and returns an iterable of Requests which will be sent to the LM. :param doc: The document as returned from training_docs, validation_docs, or test_docs. :param ctx: str The context string, generated by fewshot_context. This includes the natural language description, as well as the few shot examples, and the question part of the document for `doc`. :param doc_idx: int The index of a document within `self.test_docs()` or `self.validation_docs()`, whichever is the main split used. :param repeats: int TODO: update this docstring The number of times each instance in a dataset is inferred on. Defaults to 1, can be increased for techniques like majority voting. """ pass @abc.abstractmethod def process_results(self, doc, results): """Take a single document and the LM results and evaluates, returning a dict where keys are the names of submetrics and values are the values of the metric for that one document :param doc: The document as returned from training_docs, validation_docs, or test_docs. :param results: The results of the requests created in construct_requests. """ pass @abc.abstractmethod def aggregation(self): """ :returns: {str: [metric_score] -> float} A dictionary where keys are the names of submetrics and values are functions that aggregate a list of metric scores """ pass @abc.abstractmethod def higher_is_better(self): """ :returns: {str: bool} A dictionary where keys are the names of submetrics and values are whether a higher value of the submetric is better """ pass @classmethod def count_bytes(cls, doc): """Used for byte-level perplexity metrics in rolling loglikelihood""" return len(doc.encode("utf-8")) @classmethod def count_words(cls, doc): """Downstream loglikelihood_rolling perplexity tasks with custom word boundaries should override this!""" return len(re.split(r"\s+", doc)) @utils.positional_deprecated def fewshot_context(self, doc, num_fewshot): """Returns a fewshot context string that is made up of a prepended description (if provided), the `num_fewshot` number of examples, and an appended prompt example. :param doc: str The document as returned from training_docs, validation_docs, or test_docs. :param num_fewshot: int The number of fewshot examples to provide in the returned context string. :returns: str The fewshot context. """ if num_fewshot == 0: # always prepend the (possibly empty) task description labeled_examples = self.config.description else: labeled_examples = self.config.description + self.sampler.get_context( doc, num_fewshot ) example = self.doc_to_text(doc) if type(example) == str: return labeled_examples + example elif type(example) == list: return [labeled_examples + ex for ex in example] elif type(example) == int: if self.config.doc_to_choice is not None: choices = self.doc_to_choice(doc) return labeled_examples + choices[example] else: return labeled_examples + str(example) def apply_filters(self): if hasattr(self, "_filters"): for f in self._filters: f.apply(self._instances) else: eval_logger.warning("No filter defined, passing through instances") return self._instances def dump_config(self) -> dict: """Returns a dictionary representing the task's config. :returns: str The fewshot context. """ # TODO: this should only return the overrides applied to a non-YAML task's configuration. # (num_fewshot) return self.config.to_dict() class ConfigurableTask(Task): VERSION = "Yaml" OUTPUT_TYPE = None CONFIG = None def __init__( self, data_dir=None, cache_dir=None, download_mode=None, config: dict = None ) -> None: # TODO no super() call here # Get pre-configured attributes self._config = self.CONFIG # Use new configurations if there was no preconfiguration if self.config is None: self._config = TaskConfig(**config) # Overwrite configs else: if config is not None: self._config.__dict__.update(config) if self.config is None: raise ValueError( "Must pass a config to ConfigurableTask, either in cls.CONFIG or `config` kwarg" ) if self.config.output_type is not None: assert self.config.output_type in ALL_OUTPUT_TYPES self.OUTPUT_TYPE = self.config.output_type if self.config.dataset_path is not None: self.DATASET_PATH = self.config.dataset_path if self.config.dataset_name is not None: self.DATASET_NAME = self.config.dataset_name self._metric_fn_list = {} self._metric_fn_kwargs = {} self._aggregation_list = {} self._higher_is_better = {} _metric_list = DEFAULT_METRIC_REGISTRY[self.config.output_type] if self.config.metric_list is None: # TODO: handle this in TaskConfig.__post_init__ ? for metric_name in _metric_list: self._metric_fn_list[metric_name] = get_metric(metric_name) self._aggregation_list[metric_name] = get_default_aggregation( metric_name ) self._higher_is_better[metric_name] = is_higher_better(metric_name) else: for metric_config in self.config.metric_list: assert "metric" in metric_config metric_name = metric_config["metric"] kwargs = { key: metric_config[key] for key in metric_config if key not in ["metric", "aggregation", "higher_is_better", "hf_evaluate"] } hf_evaluate_metric = ( "hf_evaluate" in metric_config and metric_config["hf_evaluate"] is True ) if self.config.process_results is not None: self._metric_fn_list[metric_name] = None self._metric_fn_kwargs[metric_name] = {} elif callable(metric_name): metric_fn = metric_name.__call__ metric_name = metric_name.__name__ self._metric_fn_list[metric_name] = metric_fn self._metric_fn_kwargs[metric_name] = kwargs else: self._metric_fn_list[metric_name] = get_metric( metric_name, hf_evaluate_metric ) self._metric_fn_kwargs[metric_name] = kwargs if "aggregation" in metric_config: agg_name = metric_config["aggregation"] if type(agg_name) == str: self._aggregation_list[metric_name] = get_aggregation(agg_name) elif callable(agg_name): self._aggregation_list[metric_name] = metric_config[ "aggregation" ] else: INV_AGG_REGISTRY = {v: k for k, v in AGGREGATION_REGISTRY.items()} metric_agg = get_default_aggregation(metric_name) eval_logger.warning( f"[Task: {self._config.task}] metric {metric_name} is defined, but aggregation is not. " f"using default " f"aggregation={INV_AGG_REGISTRY[metric_agg]}" ) self._aggregation_list[metric_name] = metric_agg if "higher_is_better" in metric_config: self._higher_is_better[metric_name] = metric_config[ "higher_is_better" ] else: eval_logger.warning( f"[Task: {self._config.task}] metric {metric_name} is defined, but higher_is_better is not. " f"using default " f"higher_is_better={is_higher_better(metric_name)}" ) self._higher_is_better[metric_name] = is_higher_better(metric_name) self.download(self.config.dataset_kwargs) self._training_docs = None self._fewshot_docs = None if self.config.filter_list is not None: self._filters = [] for filter_config in self.config.filter_list: for filter_pipeline in filter_config: filter_name = filter_config["name"] filter_functions = filter_config["filter"] components = [] for function in filter_functions: kwargs = { key: function[key] for key in function if key != "function" } components.append([function["function"], kwargs]) filter_pipeline = build_filter_ensemble(filter_name, components) self._filters.append(filter_pipeline) else: self._filters = [build_filter_ensemble("none", [["take_first", None]])] if self.config.use_prompt is not None: eval_logger.info(f"loading prompt {self.config.use_prompt}") self.prompt = get_prompt( self.config.use_prompt, self.DATASET_PATH, self.DATASET_NAME ) else: self.prompt = None if self.fewshot_docs() is not None: self.sampler = samplers.get_sampler( self.config.fewshot_config.get("sampler", "default") if self.config.fewshot_config else "default" )(list(self.fewshot_docs()), self, rnd=random.Random(1234)) if self.has_test_docs(): self.task_docs = self.test_docs() elif self.has_validation_docs(): self.task_docs = self.validation_docs() else: assert ( False ), f"Task dataset (path={self.DATASET_PATH}, name={self.DATASET_NAME}) must have valid or test docs!" # Test One Doc self.features = list(self.task_docs.features.keys()) self.multiple_input = 0 self.multiple_target = 0 test_doc = self.task_docs[0] test_text = self.doc_to_text(test_doc) test_target = self.doc_to_target(test_doc) if self.config.doc_to_choice is not None: test_choice = self.doc_to_choice(test_doc) if type(test_choice) is not list: eval_logger.error("doc_to_choice must return list") else: num_choice = len(test_choice) if type(test_text) is int: self.multiple_input = num_choice else: test_choice = None if type(test_target) is list: self.multiple_target = len(test_target) else: if (type(test_target) is int) and (test_choice is not None): test_target = test_choice[test_target] else: test_target = str(test_target) if test_choice is not None: check_choices = test_choice else: check_choices = [test_target] if self.config.doc_to_choice is not None: for choice in check_choices: choice_has_whitespace = True if choice[0].isspace() else False delimiter_has_whitespace = ( True if self.config.target_delimiter[-1].isspace() else False ) if delimiter_has_whitespace and choice_has_whitespace: eval_logger.warning( f'Both target_delimiter and target choice: "{choice}" have whitespace' ) elif (not delimiter_has_whitespace) and (not choice_has_whitespace): eval_logger.warning( f'Both target_delimiter and target choice: "{choice}" does not have whitespace, ignore if the language you are evaluating on does not require/use whitespace' ) def download(self, dataset_kwargs=None) -> None: self.dataset = datasets.load_dataset( path=self.DATASET_PATH, name=self.DATASET_NAME, **dataset_kwargs if dataset_kwargs is not None else {}, ) def has_training_docs(self) -> bool: if self.config.training_split is not None: return True else: return False def has_validation_docs(self) -> bool: if self.config.validation_split is not None: return True else: return False def has_test_docs(self) -> bool: if self.config.test_split is not None: return True else: return False def training_docs(self) -> datasets.Dataset: if self.has_training_docs(): if self.config.process_docs is not None: return self.config.process_docs( self.dataset[self.config.training_split] ) return self.dataset[self.config.training_split] def validation_docs(self) -> datasets.Dataset: if self.has_validation_docs(): if self.config.process_docs is not None: return self.config.process_docs( self.dataset[self.config.validation_split] ) return self.dataset[self.config.validation_split] def test_docs(self) -> datasets.Dataset: if self.has_test_docs(): if self.config.process_docs is not None: return self.config.process_docs(self.dataset[self.config.test_split]) return self.dataset[self.config.test_split] def fewshot_docs(self): if self.config.fewshot_split is not None: return self.dataset[self.config.fewshot_split] else: if self.config.num_fewshot > 0: eval_logger.warning( f"Task '{self.config.task}': " "num_fewshot > 0 but fewshot_split is None. " "using preconfigured rule." ) return super().fewshot_docs() def apply_filters(self): if hasattr(self, "_filters"): for f in self._filters: f.apply(self._instances, self.task_docs) else: eval_logger.warning("No filter defined, passing through instances") return self._instances def should_decontaminate(self): return self.config.should_decontaminate def doc_to_decontamination_query(self, doc): if self.config.should_decontaminate: if self.config.doc_to_decontamination_query in self.features: return doc[self.config.doc_to_decontamination_query] else: return ast.literal_eval( utils.apply_template(self.config.doc_to_decontamination_query, doc) ) def _process_doc(self, doc): """ Override this to process (detokenize, strip, replace, etc.) individual documents. This can be used in a map over documents of a data split. E.g. `map(self._process_doc, self.dataset["validation"])` :return: dict The processed version of the specified `doc`. """ return doc def doc_to_text(self, doc): if self.prompt is not None: doc_to_text = self.prompt else: doc_to_text = self.config.doc_to_text if type(doc_to_text) == int: return doc_to_text elif type(doc_to_text) == str: if doc_to_text in self.features: # if self.config.doc_to_choice is not None: # return self.doc_to_choice(doc)[doc[doc_to_text]] # else: return doc[doc_to_text] else: text_string = utils.apply_template(doc_to_text, doc) if text_string.isdigit() and self._config.doc_to_choice is not None: return ast.literal_eval(text_string) else: return text_string elif callable(doc_to_text): return doc_to_text(doc) # Used when applying a Promptsource template elif hasattr(doc_to_text, "apply"): applied_prompt = doc_to_text.apply(doc) if len(applied_prompt) == 2: return applied_prompt[0] else: eval_logger.warning("Applied prompt returns empty string") return self.config.fewshot_delimiter else: print(type(doc_to_text)) raise TypeError def doc_to_target(self, doc: dict) -> Union[int, str, list]: if self.prompt is not None: doc_to_target = self.prompt else: doc_to_target = self.config.doc_to_target if type(doc_to_target) == int: return doc_to_target elif type(doc_to_target) == str: if doc_to_target in self.features: # if self.config.doc_to_choice is not None: # return self.doc_to_choice(doc)[doc[doc_to_target]] # else: return doc[doc_to_target] else: target_string = utils.apply_template(doc_to_target, doc) if target_string.isdigit() and self._config.doc_to_choice is not None: return ast.literal_eval(target_string) elif ( len(target_string) >= 2 and (target_string[0] == "[") and (target_string[-1] == "]") ): try: return ast.literal_eval(target_string) except (SyntaxError, ValueError): return target_string else: return target_string elif type(doc_to_target) == list: return doc_to_target elif callable(doc_to_target): return doc_to_target(doc) # Used when applying a Promptsource template elif hasattr(doc_to_target, "apply"): applied_prompt = doc_to_target.apply(doc) if len(applied_prompt) == 2: return applied_prompt[1] else: eval_logger.warning("Applied prompt returns empty string") return self.config.fewshot_delimiter else: raise TypeError def doc_to_choice(self, doc: Any) -> List[str]: if self.prompt is not None: doc_to_choice = self.prompt elif self.config.doc_to_choice is None: eval_logger.error("doc_to_choice was called but not set in config") else: doc_to_choice = self.config.doc_to_choice if type(doc_to_choice) == str: return ast.literal_eval(utils.apply_template(doc_to_choice, doc)) elif type(doc_to_choice) == list: return doc_to_choice elif type(doc_to_choice) == dict: return list(doc_to_choice.values()) elif callable(doc_to_choice): return doc_to_choice(doc) elif hasattr(doc_to_choice, "get_answer_choices_list"): return doc_to_choice.get_answer_choices_list(doc) else: raise TypeError def gold_alias(self, doc): # returns a version of the gold target answer to a document, # which should be passed into metric for scoring as the ground truth. # in multiple_choice tasks, this should be castable to an int corresponding to the index # within the answer choices, while doc_to_target is the string version of {{answer_choices[gold]}}. if self.config.gold_alias is not None: doc_to_target = self.config.gold_alias else: return self.doc_to_target(doc) if type(doc_to_target) == str: return utils.apply_template(doc_to_target, doc) elif callable(doc_to_target): return doc_to_target(doc) elif hasattr(doc_to_target, "apply"): return doc_to_target.apply(doc)[1] else: raise TypeError def construct_requests( self, doc: dict, ctx: str, **kwargs ) -> Union[List[Instance], Instance]: if self.OUTPUT_TYPE == "loglikelihood": arguments = (ctx, self.doc_to_target(doc)) elif self.OUTPUT_TYPE == "loglikelihood_rolling": arguments = (self.doc_to_target(doc),) elif self.OUTPUT_TYPE == "multiple_choice": choices = self.doc_to_choice(doc) target_delimiter = self.config.target_delimiter if self.multiple_input: # If there are multiple inputs, choices are placed in the ctx cont = self.doc_to_target(doc) arguments = [(ctx, f"{target_delimiter}{cont}") for ctx in choices] else: # Otherwise they are placed in the continuation arguments = [(ctx, f"{target_delimiter}{cont}") for cont in choices] request_list = [ Instance( request_type="loglikelihood", doc=doc, arguments=arg, idx=i, **kwargs, ) for i, arg in enumerate(arguments) ] # TODO: we should raise a warning telling users this will at most ~2x runtime. if "acc_mutual_info" in self._metric_fn_list.keys(): # if we are calculating multiple choice accuracy # using mutual information instead of raw loglikelihood as metric, need unconditional lls. # here mutual info refers to calculating # log(P(choice|ctx) / P(choice)) = log(P(choice|ctx)) - log(P(choice)) # in other words normalizing by subtracting the unconditional logprob of each choice. request_list.extend( [ Instance( request_type="loglikelihood", doc=doc, arguments=("", "{}".format(choice)), idx=i, **kwargs, ) for i, choice in enumerate(choices) ] ) return request_list elif self.OUTPUT_TYPE == "greedy_until": arguments = (ctx, self.config.generation_kwargs) return Instance( request_type=self.OUTPUT_TYPE, doc=doc, arguments=arguments, idx=0, **kwargs ) def process_results(self, doc, results): if callable(self.config.process_results): return self.config.process_results(doc, results) result_dict = {} use_metric = list(self._metric_fn_list.keys()) if self.OUTPUT_TYPE == "loglikelihood": results = results[0] ll, is_greedy = results return { **({"perplexity": ll} if "perplexity" in use_metric else {}), **({"acc": int(is_greedy)} if "acc" in use_metric else {}), } elif self.OUTPUT_TYPE == "loglikelihood_rolling": (loglikelihood,) = results _words = self.count_words(self.doc_to_target(doc)) _bytes = self.count_bytes(self.doc_to_target(doc)) return { **( {"word_perplexity": (loglikelihood, _words)} if "word_perplexity" in use_metric else {} ), **( {"byte_perplexity": (loglikelihood, _bytes)} if "byte_perplexity" in use_metric else {} ), **( {"bits_per_byte": (loglikelihood, _bytes)} if "bits_per_byte" in use_metric else {} ), } elif self.OUTPUT_TYPE == "multiple_choice": lls, is_greedy = zip(*results) # retrieve choices in List[str] form, to compute choice lengths, etc. choices = self.doc_to_choice(doc) completion_len = np.array([float(len(i)) for i in choices]) if ( 2 * len(choices) == len(lls) and "acc_mutual_info" in self._metric_fn_list.keys() ): # then we are doing mutual info. # this stores the "dryrun" / unconditional answer loglikelihoods lls_unconditional = lls[1::2] assert len(lls_unconditional) == len(choices) # and this stores our "regular" conditional loglikelihoods lls = lls[::2] pred = np.argmax(lls) pred_norm = np.argmax(lls / completion_len) if self.multiple_input: gold = self.doc_to_text(doc) else: gold = self.doc_to_target(doc) gold_index_error = False if type(gold) is list: gold = [i if i < len(choices) else -100 for i in gold] if -100 in gold: gold_index_error = True else: if type(gold) is int: gold = gold if gold < len(choices) else -100 elif type(gold) is str: gold = choices.index(gold) if gold in choices else -100 if gold == -100: gold_index_error = True if gold_index_error: eval_logger.warning( f"Label index was not in within range of available choices," f"Sample:\n\n{doc}\n\n" ) if self.multiple_target: acc = 1.0 if pred in gold else 0.0 acc_norm = 1.0 if pred_norm in gold else 0.0 exact_match = int(any([is_greedy[i] if i != -100 else 0 for i in gold])) else: acc = 1.0 if pred == gold else 0.0 acc_norm = 1.0 if pred_norm == gold else 0.0 # TODO: this gets score of 0 on arc_challenge for pythia-70m. need to test that this works properly exact_match = int(is_greedy[gold]) if gold != -100 else 0 result_dict = { **({"acc": acc} if "acc" in use_metric else {}), **({"f1": (gold, pred)} if "f1" in use_metric else {}), **({"mcc": (gold, pred)} if "mcc" in use_metric else {}), **({"acc_norm": acc_norm} if "acc_norm" in use_metric else {}), **({"exact_match": exact_match} if "exact_match" in use_metric else {}), } if "acc_mutual_info" in use_metric: lls_mutual_info = [ ll_c - ll_u for ll_c, ll_u in zip(lls, lls_unconditional) ] acc_mutual_info = 1.0 if np.argmax(lls_mutual_info) == gold else 0.0 result_dict["acc_mutual_info"] = acc_mutual_info elif self.OUTPUT_TYPE == "greedy_until": gold = self.doc_to_target(doc) result = results[0] if self.config.doc_to_choice is not None: # If you set doc_to_choice, # it assumes that doc_to_target returns a number. choices = self.doc_to_choice(doc) gold = choices[gold] # we expect multiple_targets to be a list. elif self.multiple_target: gold = list(gold) elif type(gold) != type(result): # cast gold to the same type as result gold = type(result)(gold) for metric in self._metric_fn_list.keys(): if self.multiple_target: # in the case where we have multiple targets, # return true if any are true # TODO: this may break for multipLe_target, non zero-or-1 metrics scores = [] if not isinstance(gold, list): # sometimes, a multiple_target dataset has exceptions where one doc has only one string answer # print(gold) gold = [gold] for gold_option in gold: try: result_score = self._metric_fn_list[metric]( references=[gold_option], predictions=[result], **self._metric_fn_kwargs[metric], ) except TypeError: # TODO: this is hacky and I don't want to do it result_score = self._metric_fn_list[metric]( [gold_option, result] ) if isinstance(result_score, dict): # TODO: this handles the case where HF evaluate returns a dict. result_score = result_score[metric] scores.append(result_score) if any(scores): result_score = 1.0 else: result_score = 0.0 else: try: result_score = self._metric_fn_list[metric]( references=[gold], predictions=[result], **self._metric_fn_kwargs[metric], ) except TypeError: # needed for now in order to use a different interface between our own metrics and HF Evaluate metrics result_score = self._metric_fn_list[metric]([gold, result]) if isinstance(result_score, dict): # TODO: this handles the case where HF evaluate returns a dict. result_score = result_score[metric] result_dict[metric] = result_score else: raise ValueError( f"Passed invalid output_type '{self.OUTPUT_TYPE}' ! Please use one of ", "'loglikelihood', 'loglikelihood_rolling', 'greedy_until' or 'multiple_choice'", ) return result_dict def aggregation(self): return self._aggregation_list def higher_is_better(self): return self._higher_is_better class MultipleChoiceTask(Task): OUTPUT_TYPE: str = "loglikelihood" def doc_to_target(self, doc: dict) -> str: return " " + doc["choices"][doc["gold"]] def construct_requests(self, doc: dict, ctx: str, **kwargs) -> List[Instance]: # TODO: add mutual info here? return [ Instance( request_type="loglikelihood", doc=doc, arguments=(ctx, " {}".format(choice)), idx=i, **kwargs, ) for i, choice in enumerate(doc["choices"]) ] def process_results(self, doc: dict, results: List[Tuple[float, bool]]) -> dict: results = [ res[0] for res in results ] # only retain loglikelihoods, discard is_greedy TODO: do we need is_greedy anywhere? gold = doc["gold"] acc = 1.0 if np.argmax(results) == gold else 0.0 completion_len = np.array([float(len(i)) for i in doc["choices"]]) acc_norm = 1.0 if np.argmax(results / completion_len) == gold else 0.0 return { "acc": acc, "acc_norm": acc_norm, } def higher_is_better(self) -> dict: return { "acc": True, "acc_norm": True, } def aggregation(self) -> dict: return { "acc": mean, "acc_norm": mean, } class PerplexityTask(Task): OUTPUT_TYPE = "loglikelihood_rolling" def has_training_docs(self) -> bool: return False def fewshot_examples(self, k: int, rnd) -> List: assert k == 0 return [] def fewshot_context(self, doc: dict, num_fewshot: int) -> Literal[""]: assert ( num_fewshot == 0 ), "The number of fewshot examples must be 0 for perplexity tasks." return "" def higher_is_better(self) -> dict: return { "word_perplexity": False, "byte_perplexity": False, "bits_per_byte": False, } def doc_to_decontamination_query(self, doc): return doc def doc_to_text(self, doc) -> str: return "" def doc_to_target(self, doc): return doc def construct_requests(self, doc: dict, ctx: Union[str, None], **kwargs): assert not ctx return Instance( request_type=self.OUTPUT_TYPE, doc=doc, arguments=(self.doc_to_target(doc),), idx=0, **kwargs, ) def process_results(self, doc: dict, results: float) -> dict: (loglikelihood,) = results words = self.count_words(self.doc_to_target(doc)) bytes_ = self.count_bytes(self.doc_to_target(doc)) return { "word_perplexity": (loglikelihood, words), "byte_perplexity": (loglikelihood, bytes_), "bits_per_byte": (loglikelihood, bytes_), } def aggregation(self) -> dict: return { "word_perplexity": weighted_perplexity, "byte_perplexity": weighted_perplexity, "bits_per_byte": bits_per_byte, } @classmethod def count_bytes(cls, doc) -> int: return len(doc.encode("utf-8")) @classmethod def count_words(cls, doc) -> int: """Downstream tasks with custom word boundaries should override this!""" return len(re.split(r"\s+", doc))