interface.md

User Guide

This document details the interface exposed by lm-eval and provides details on what flags are available to users.

Command-line Interface

A majority of users run the library by cloning it from Github, installing the package as editable, and running the python -m lm_eval script.

Equivalently, running the library can be done via the lm-eval entrypoint at the command line.

This mode supports a number of command-line arguments, the details of which can be also be seen via running with -h or --help:

• --model : Selects which model type or provider is evaluated. Must be a string corresponding to the name of the model type/provider being used. See the main README for a full list of enabled model names and supported libraries or APIs.

• --model_args : Controls parameters passed to the model constructor. Accepts a string containing comma-separated keyword arguments to the model class of the format "arg1=val1,arg2=val2,...", such as, for example --model_args pretrained=EleutherAI/pythia-160m,dtype=float32. For a full list of what keyword arguments, see the initialization of the lm_eval.api.model.LM subclass, e.g. HFLM

• --tasks : Determines which tasks or task groups are evaluated. Accepts a comma-separated list of task names or task group names. Must be solely comprised of valid tasks/groups. A list of supported tasks can be viewed with --tasks list.

• --num_fewshot : Sets the number of few-shot examples to place in context. Must be an integer.

• --gen_kwargs : takes an arg string in same format as --model_args and creates a dictionary of keyword arguments. These will be passed to the models for all called generate_until (free-form or greedy generation task) tasks, to set options such as the sampling temperature or top_p / top_k. For a list of what args are supported for each model type, reference the respective library's documentation (for example, the documentation for transformers.AutoModelForCausalLM.generate().) These kwargs will be applied to all generate_until tasks called--we do not currently support unique gen_kwargs or batch_size values per task in a single run of the library. To control these on a per-task level, set them in that task's YAML file.

• --batch_size : Sets the batch size used for evaluation. Can be a positive integer or "auto" to automatically select the largest batch size that will fit in memory, speeding up evaluation. One can pass --batch_size auto:N to re-select the maximum batch size N times during evaluation. This can help accelerate evaluation further, since lm-eval sorts documents in descending order of context length.

• --max_batch_size : Sets the maximum batch size to try to fit in memory, if --batch_size auto is passed.

• --device : Sets which device to place the model onto. Must be a string, for example, "cuda", "cuda:0", "cpu", "mps". Defaults to "cuda", and can be ignored if running multi-GPU or running a non-local model type.

• --output_path : A string of the form dir/file.jsonl or dir/. Provides a path where high-level results will be saved, either into the file named or into the directory named. If --log_samples is passed as well, then per-document outputs and metrics will be saved into the directory as well.

• --log_samples : If this flag is passed, then the model's outputs, and the text fed into the model, will be saved at per-document granularity. Must be used with --output_path.

• --limit : Accepts an integer, or a float between 0.0 and 1.0 . If passed, will limit the number of documents to evaluate to the first X documents (if an integer) per task or first X% of documents per task. Useful for debugging, especially on costly API models.

• --use_cache : Should be a path where a sqlite db file can be written to. Takes a string of format /path/to/sqlite_cache_ in order to create a cache db at /path/to/sqlite_cache_rank{i}.db for each process (0-NUM_GPUS). This allows results of prior runs to be cached, so that there is no need to re-run results in order to re-score or re-run a given (model, task) pair again.

• --cache_requests : Can be "true", "refresh", or "delete". "true" means that the cache should be used. "refresh" means that you wish to regenerate the cache, which you should run if you change your dataset configuration for a given task. "delete" will delete the cache. Cached files are stored under lm_eval/cache/.cache unless you specify a different path via the environment variable: LM_HARNESS_CACHE_PATH. e.g. LM_HARNESS_CACHE_PATH=~/Documents/cache_for_lm_harness.

• --check_integrity : If this flag is used, the library tests for each task selected are run to confirm task integrity.

• --write_out : Used for diagnostic purposes to observe the format of task documents passed to a model. If this flag is used, then prints the prompt and gold target string for the first document of each task.

• --show_config : If used, prints the full lm_eval.api.task.TaskConfig contents (non-default settings the task YAML file) for each task which was run, at the completion of an evaluation. Useful for when one is modifying a task's configuration YAML locally to transmit the exact configurations used for debugging or for reproducibility purposes.

• --include_path : Accepts a path to a folder. If passed, then all YAML files containing lm-eval compatible task configurations will be added to the task registry as available tasks. Used for when one is writing config files for their own task in a folder other than lm_eval/tasks/.

• --system_instruction: Specifies a system instruction string to prepend to the prompt.

• --apply_chat_template : If this flag is on, a chat template will be applied to the prompt. For Hugging Face models, the chat template is taken from the tokenizer, if the tokenizer does not have a chat template, a default one will be applied. For other models, chat templating is not currently implemented.

• --fewshot_as_multiturn : If this flag is on, the Fewshot examples are treated as a multi-turn conversation. Questions are provided as user content and answers are provided as assistant responses. Requires --num_fewshot to be set to be greater than 0, and --apply_chat_template to be on.

• --predict_only: Generates the model outputs without computing metrics. Use with --log_samples to retrieve decoded results.

• --seed: Set seed for python's random, numpy and torch. Accepts a comma-separated list of 3 values for python's random, numpy, and torch seeds, respectively, or a single integer to set the same seed for all three. The values are either an integer or 'None' to not set the seed. Default is 0,1234,1234 (for backward compatibility). E.g. --seed 0,None,8 sets random.seed(0) and torch.manual_seed(8). Here numpy's seed is not set since the second value is None. E.g, --seed 42 sets all three seeds to 42.

• --wandb_args: Tracks logging to Weights and Biases for evaluation runs and includes args passed to wandb.init, such as project and job_type. Full list here. e.g., --wandb_args project=test-project,name=test-run

• --hf_hub_log_args : Logs evaluation results to Hugging Face Hub. Accepts a string with the arguments separated by commas. Available arguments:

  • hub_results_org - organization name on Hugging Face Hub, e.g., EleutherAI. If not provided, the results will be pushed to the owner of the Hugging Face token,
  • hub_repo_name - repository name on Hugging Face Hub, e.g., lm-eval-results,
  • push_results_to_hub - whether to push results to Hugging Face Hub, can be True or False,
  • push_samples_to_hub - whether to push samples results to Hugging Face Hub, can be True or False. Requires --log_samples to be set,
  • public_repo - whether the repository is public, can be True or False,
  • leaderboard_url - URL to the leaderboard, e.g., https://huggingface.co/spaces/HuggingFaceH4/open_llm_leaderboard.
  • point_of_contact - Point of contact for the results dataset, e.g., yourname@example.com.

External Library Usage

We also support using the library's external API for use within model training loops or other scripts.

lm_eval supplies two functions for external import and use: lm_eval.evaluate() and lm_eval.simple_evaluate().

simple_evaluate() can be used by simply creating an lm_eval.api.model.LM subclass that implements the methods described in the Model Guide, and wrapping your custom model in that class as follows:

import lm_eval
...

my_model = initialize_my_model() # create your model (could be running finetuning with some custom modeling code)
...
# instantiate an LM subclass that takes your initialized model and can run
# - `Your_LM.loglikelihood()`
# - `Your_LM.loglikelihood_rolling()`
# - `Your_LM.generate_until()`
lm_obj = Your_LM(model=my_model, batch_size=16)

# indexes all tasks from the `lm_eval/tasks` subdirectory.
# Alternatively, you can set `TaskManager(include_path="path/to/my/custom/task/configs")`
# to include a set of tasks in a separate directory.
task_manager = lm_eval.tasks.TaskManager()

# Setting `task_manager` to the one above is optional and should generally be done
# if you want to include tasks from paths other than ones in `lm_eval/tasks`.
# `simple_evaluate` will instantiate its own task_manager if it is set to None here.
results = lm_eval.simple_evaluate( # call simple_evaluate
    model=lm_obj,
    tasks=["taskname1", "taskname2"],
    num_fewshot=0,
    task_manager=task_manager,
    ...
)

See https://github.com/EleutherAI/lm-evaluation-harness/blob/365fcda9b85bbb6e0572d91976b8daf409164500/lm_eval/evaluator.py#L35 for a full description of all arguments available. All keyword arguments to simple_evaluate share the same role as the command-line flags described previously.

Additionally, the evaluate() function offers the core evaluation functionality provided by the library, but without some of the special handling and simplification + abstraction provided by simple_evaluate().

See https://github.com/EleutherAI/lm-evaluation-harness/blob/365fcda9b85bbb6e0572d91976b8daf409164500/lm_eval/evaluator.py#L173 for more details.

As a brief example usage of evaluate():

import lm_eval

# suppose you've defined a custom lm_eval.api.Task subclass in your own external codebase
from my_tasks import MyTask1
...

# create your model (could be running finetuning with some custom modeling code)
my_model = initialize_my_model()
...

# instantiate an LM subclass that takes your initialized model and can run
# - `Your_LM.loglikelihood()`
# - `Your_LM.loglikelihood_rolling()`
# - `Your_LM.generate_until()`
lm_obj = Your_LM(model=my_model, batch_size=16)

# optional: the task_manager indexes tasks including ones
# specified by the user through `include_path`.
task_manager = lm_eval.tasks.TaskManager(
    include_path="/path/to/custom/yaml"
    )

# To get a task dict for `evaluate`
task_dict = lm_eval.tasks.get_task_dict(
    [
        "mmlu", # A stock task
        "my_custom_task", # A custom task
        {
            "task": ..., # A dict that configures a task
            "doc_to_text": ...,
            },
        MyTask1 # A task object from `lm_eval.task.Task`
        ],
    task_manager # A task manager that allows lm_eval to
                 # load the task during evaluation.
                 # If none is provided, `get_task_dict`
                 # will instantiate one itself, but this
                 # only includes the stock tasks so users
                 # will need to set this if including
                 # custom paths is required.
    )

results = evaluate(
    lm=lm_obj,
    task_dict=task_dict,
    ...
)