lm-evaluation-harness
is a framework that strives to support a wide range of zero- and few-shot evaluation tasks on autoregressive language models (LMs).
This documentation page provides a walkthrough to get started creating your own task, in lm-eval
versions v0.4.0 and later.
A more interactive tutorial is available as a Jupyter notebook here.
If you haven't already, go ahead and fork the main repo, clone it, create a branch with the name of your task, and install the project requirements in your environment:
# After forking...
git clone https://github.com/<YOUR-USERNAME>/lm-evaluation-harness.git
cd lm-evaluation-harness
git checkout -b <task-name>
pip install -e ".[dev]"
In this document, we'll walk through the basics of implementing a static benchmark evaluation in two formats: a generative task which requires sampling text from a model, such as gsm8k
, and a discriminative, or multiple choice, task where the model picks the most likely of several fixed answer choices, such as sciq
.
To implement a new standard task, we'll need to write a YAML file which configures our task logic. We start by making a new empty YAML file. This file can have any name, but we recommend placing it in a subfolder of lm_eval/tasks
titled by the dataset or task's shorthand name: for example,
touch lm_eval/tasks/<dataset_name>/<my_new_task_name>.yaml
Or, copy the template subfolder we provide from templates/new_yaml_task
:
cp -r templates/new_yaml_task lm_eval/tasks/
and rename the folders and YAML file(s) as desired.
All data downloading and management is handled through the HuggingFace (HF) datasets
API. So, the first thing you should do is check to see if your task's dataset is already provided in their catalog here. If it's not in there, please consider adding it to their Hub to make it accessible to a wider user base by following their new dataset guide
.
Once you have a HuggingFace dataset prepared for your task, we want to assign our new YAML to use this dataset:
dataset_path: ... # the name of the dataset on the HF Hub.
dataset_name: ... # the dataset configuration to use. Leave `null` if your dataset does not require a config to be passed. See https://huggingface.co/docs/datasets/load_hub#configurations for more info.
dataset_kwargs: null # any extra keyword arguments that should be passed to the dataset constructor, e.g. `data_dir`.
Next, we'd like to tell our task what the dataset's train, validation, and test splits are named, if they exist:
training_split: <split name of training set, or `null`>
validation_split: <split name of val. set, or `null`>
test_split: <split name of test set, or `null`>
Tests will run on the test_split
if it is available, and otherwise evaluate on the validation_split
.
We can also specify from which split the task should retrieve few-shot examples via:
fewshot_split: <split name to draw fewshot examples from, or `null`>
or by hardcoding them, either using the following in the yaml file:
fewshot_config:
sampler: first_n
samples: [
{<sample 1>},
{<sample 2>},
]
or by adding the function list_fewshot_samples
in the associated utils.py file:
def list_fewshot_samples() -> list[dict]:
return [{<sample 1>}, {<sample 2>}]
See lm_eval/tasks/minerva_math/minerva_math_algebra.yaml
for an example of the latter, and lm_eval/tasks/gsm8k/gsm8k-cot.yaml
for an example of the former.
In this case, each sample must contain the same fields as the samples in the above sets--for example, if doc_to_text
expects an input
field when rendering input prompts, these provided samples must include an input
key.
If neither above options are not set, we will default to train/validation/test sets, in that order.
Finally, our dataset may not be already in the exact format we want. Maybe we have to strip whitespace and special characters via a regex from our dataset's "question" field! Or maybe we just want to rename its columns to match a convention we'll be using for our prompts.
Let's create a python file in the directory where we're writing our YAML file:
touch lm_eval/tasks/<dataset_name>/utils.py
Now, in utils.py
we'll write a function to process each split of our dataset (the following example is drawn from the hellaswag
task):
def process_docs(dataset: datasets.Dataset) -> datasets.Dataset:
def _process_doc(doc):
ctx = doc["ctx_a"] + " " + doc["ctx_b"].capitalize()
out_doc = {
"query": preprocess(doc["activity_label"] + ": " + ctx),
"choices": [preprocess(ending) for ending in doc["endings"]],
"gold": int(doc["label"]),
}
return out_doc
return dataset.map(_process_doc)
Now, in our YAML config file we'll use the !function
constructor, and tell the config where our imported Python function will come from. At runtime, before doing anything else we will preprocess our dataset according to this function!
process_docs: !function utils.process_docs
To load a local dataset for evaluation, you can specify data files in the dataset_kwargs
field, such as the following for JSON files:
dataset_path: json
dataset_name: null
dataset_kwargs:
data_files: /path/to/my/json
Or with files already split into separate directories:
dataset_path: arrow
dataset_kwargs:
data_files:
train: /path/to/arrow/train/data-00000-of-00001.arrow
validation: /path/to/arrow/validation/data-00000-of-00001.arrow
Alternatively, if you have previously downloaded a dataset from huggingface hub (using save_to_disk()
) and wish to use the local files, you will need to use data_dir
under dataset_kwargs
to point to where the directory is.
dataset_path: hellaswag
dataset_kwargs:
data_dir: hellaswag_local/
You can also set dataset_path
as a directory path in your local system. This will assume that there is a loading script with the same name as the directory. See datasets docs.
The next thing we need to do is decide what format to use when presenting the data to the LM. This is our prompt, where we'll define both an input and output format.
To write a prompt, users will use doc_to_text
, doc_to_target
, and doc_to_choice
(Optional when certain conditions are met).
doc_to_text
defines the input string a model will be given while doc_to_target
and doc_to_choice
will be used to generate the target text. doc_to_target
can be either a text string that refers to the target string or an integer that refers to the index of the correct label. When it is set as an index, doc_to_choice
must be also be set with the appropriate list of possible choice strings.
If a dataset is straightforward enough, users can enter the feature name directly. This assumes that no preprocessing is required. For example in Swag, doc_to_text
and doc_to_target
given the name of one of the feature each.
doc_to_text: startphrase
doc_to_target: label
Hard-coding is also possible as is the case in SciQ.
doc_to_target: 3
doc_to_choice
can be directly given a list of text as option (See Toxigen)
doc_to_choice: ['No', 'Yes']
if a dataset feature is already a list, you can set the name of the feature as doc_to_choice
(See Hellaswag)
doc_to_choice: choices
We support the Jinja 2 templating language for writing prompts. In practice, this means you can take your dataset's columns and do many basic string manipulations to place each document into prompted format.
Take for example the dataset super_glue/boolq
. As input, we'd like to use the features passage
and question
and string them together so that for a a sample line doc
, the model sees something the format of:
doc["passage"]
Question: doc["question"]?
Answer:
We do this by writing
doc_to_text: "{{passage}}\nQuestion: {{question}}?\nAnswer:"
Such that {{passage}}
will be replaced by doc["passage"]
and {{question}}
with doc["question"]
when rendering the prompt template.
Our intended output is for the model to predict a single whitespace, and then the answer to the question. We do this via:
doc_to_target: "{{answer}}"
Important: we now add target_delimiter
between input and target which defaults to " ", such that the full input-output string is doc_to_target(doc) + target_delimiter + doc_to_text(doc)
. doc_to_text
and doc_to_target
should not contain trailing right or left whitespace, respectively.
For tasks which are multiple choice (a fixed, finite set of label words per each document) and evaluated via comparing loglikelihoods of all label words (the multiple_choice
task output type) we enforce a particular convention on prompt format.
An annotated example in the case of SciQ is as follows:
doc_to_text: "{{support.lstrip()}}\nQuestion: {{question}}\nAnswer:" # This is the input portion of the prompt for this doc. It will have " {{choice}}" appended to it as target for each choice in answer_choices.
doc_to_target: 3 # this contains the index into the answer choice list of the correct answer.
doc_to_choice: "{{[distractor1, distractor2, distractor3, correct_answer]}}"
Task implementers are thus able to decide what the answer choices should be for a document, and what prompt format to use.
The label index can also be sourced from a feature directly. For example in superglue/boolq
, the label index if defined in the feature label
. We can set doc_to_target
as simply label
. The options or verbalizers can be written in a the form of a list ["no", "yes"]
that will correspond to the label index.
doc_to_text: "{{passage}}\nQuestion: {{question}}?\nAnswer:"
doc_to_target: label
doc_to_choice: ["no", "yes"]
There may be cases where the prompt we want to implement is easier expressed in Python instead of Jinja 2. For this, we can use Python helper functions that are defined in the YAML config. It should be noted that the function script must be in the same directory as the yaml.
A good example is WikiText that requires a lot of regex rules to clean the samples.
def wikitext_detokenizer(doc):
string = doc["page"]
# contractions
string = string.replace("s '", "s'")
string = re.sub(r"/' [0-9]/", r"/'[0-9]/", string)
...
string = string.replace(" 's", "'s")
return string
We can load this function in doc_to_target
by using a !function
operator after doc_to_target
and followed by <file name>.<function name>
. In the file wikitext.yaml we write:
doc_to_target: !function preprocess_wikitext.wikitext_detokenizer
Promptsource is a great repository for crowdsourced prompts for many datasets. We can load these prompts easily by using the use_prompt
argument and filling it with the format "promptsource:<name of prompt template>"
. To use this, doc_to_text
and doc_to_target
should be left undefined. This will fetch the template of the dataset defined in the YAML file.
For example, For Super Glue BoolQ, if we want to use the prompt template GPT-3 Style
we can add this to the YAML file.
use_prompt: "promptsource:GPT-3 Style"
If you would like to run evaluation on all prompt templates, you can simply call it this way.
use_prompt: "promptsource:*"
You're almost done! Now we need to choose how to score our task.
- If this is a multiple choice task: do you just want to check your model's accuracy in choosing the correct answer choice?
- If this is a generation task: do you just want to check how often your model outputs exactly the ground-truth output string provided?
If the answer to the above is no: you'll need to record what scoring metrics to use! Metrics can be listed in the following format:
metric_list:
- metric: <name of the metric here>
aggregation: <name of the aggregation fn here>
higher_is_better: <true or false>
- metric: !function script.function
aggregation: ...
higher_is_better: ...
aggregation
and higher_is_better
can optionally be left out to default to the manually-set defaults if using a natively supported metric, otherwise it must be defined explicitly (for example, when using a custom metric implemented as a function).
For a full list of natively supported metrics and aggregation functions see docs/task_guide.md
. All metrics supported in HuggingFace Evaluate can also be used, and will be loaded if a given metric name is not one natively supported in lm-eval
or hf_evaluate
is set to true
.
Some tasks may require more advanced processing logic than is described in this guide.
As a heuristic check:
- Does your task require generating multiple free-form outputs per input document?
- Does your task require complex, multi-step post-processing of generated model outputs?
- Does your task require subsetting documents on the fly based on their content?
- Do you expect to compute metrics after applying multiple such processing steps on your model outputs?
- Does your task rely on metrics that need a custom implementation?
For more detail on the task system and advanced features, see docs/task_guide.md
. If none of the above sound like they apply to your task, it's time to continue onto checking your task performance!
To test a task conveniently, it helps to register the task--that is, to give it a name and make the lm-eval
library aware it exists!
If you're writing your YAML file inside the lm_eval/tasks
folder, you just need to give your task a name! You can do this inside your YAML file:
task: <name of the task>
Including a task name is mandatory.
It is often also convenient to label your task with several tag
values, though this field is optional:
tag:
- tag1
- tag2
This will add your task to the tag1
and tag2
tags, enabling people to know how to categorize your task, and if desired run all tasks in one of these groups at once, your task along with them.
If your task is not in the lm_eval/tasks
folder, you'll need to tell the Eval Harness where to look for YAML files.
You can do this via the --include_path
argument in __main__.py
. This command will be used to initialize the TaskManager
object which you can also use for your custom scripts.
task_manager = TaskManager(args.verbosity, include_path=args.include_path)
Passing --tasks /path/to/yaml/file
is also accepted.
While tag
values are helpful when you want to be able to quickly and conveniently run a set of related tasks via --tasks my_tag_name
, often, we wish to implement more complex logic. For example, the MMLU benchmark contains 57 subtasks that must all be averaged together in order to report a final 'MMLU score'.
Groupings of tasks might also use particular variants of a task--for example, we might want to default to evaluating a task as 5-shot when called as part of a given grouping, but not have a preference for number of shots when evaluating it as a standalone.
We implement this via groups, which are distinct from tags. Groups can be implemented via group config YAML files, which are laid out similarly but slightly differently to tasks' YAML configs.
The most basic form of group can be defined via a YAML config similar to the following:
group: nli_tasks
task:
- cb
- anli_r1
- rte
metadata:
version: 1.0
This will behave almost identically to a tag
that includes these 3 tasks, but with one key distinction: we'll print the nli_tasks
group as a row (with no associated metrics) in our table of outputs, and visually show that these 3 tasks appear under its subheader.
Now, let's assume we actually want to report an aggregate score for nli_tasks
. We would instead use a YAML config like the following:
group: nli_tasks
task:
- cb
- anli_r1
- rte
aggregate_metric_list:
- metric: acc
aggregation: mean
weight_by_size: true # defaults to `true`. Set this to `false` to do a "macro" average (taking each subtask's average accuracy, and summing those accuracies and dividing by 3)--by default we do a "micro" average (retain all subtasks' per-document accuracies, and take the mean over all documents' accuracies to get our aggregate mean).
metadata:
version: 1.0
Similar to our metric_list
for listing out the metrics we want to calculate for a given task, we use an aggregate_metric_list
field to specify which metric name to aggregate across subtasks, what aggregation function to use, and whether we should micro- or macro- average these metrics. See ./task_guide.md for a full list of related sub-keys.
[!Tip]: currently, we predominantly only support the aggregation of group metrics that use mean
(either micro- or macro- averaged) over their subtasks. If you require even more complex aggregation rules, you may want to perform aggregation offline.
Group configs can be fairly complex! We can do various operations, such as defining new subtask(s) inline in our group YAML, overriding an existing task's specific config value, or nesting existing groups within our
For example, let's build a config for evaluating MMLU and a few natural language inference tasks. For MMLU, we can write the name for the benchmark as a subtask written under task
. You can configure the parameters such as num_fewshot
. If the task being configured is a group such as mmlu
or super_glue
, the parameter set will be applied to all of the subtasks.
group: nli_and_mmlu
task:
- group: nli_tasks
task:
- cb
- anli_r1
- rte
aggregate_metric_list:
- metric: acc
aggregation: mean
higher_is_better: true
- task: mmlu
num_fewshot: 2
There can occasions when yaml-based tasks cannot accommodate how a task is handled. LM-Eval supports the manually implementing tasks as was previously done before 0.4.x
. To register the task, you can simply make a yaml with the name of the task in task
and the class object in class
using the !function
prefix.
task: squadv2
class: !function task.SQuAD2
This also applies to building group configurations with subtasks that are python classes.
group: scrolls
task:
- task: scrolls_qasper
class: !function task.Qasper
- task: scrolls_quality
class: !function task.QuALITY
- task: scrolls_narrativeqa
class: !function task.NarrativeQA
...
You can also pass a custom argument to your class by accepting config
in the custom class constructor.
Here's how to do it:
task: 20_newsgroups
class: !function task.Unitxt
recipe: card=cards.20_newsgroups,template=templates.classification.multi_class.title
In this example, recipe
is the custom argument for the Unitxt
class.
To avoid conflict, each task needs to be registered with a unique name. Because of this, slight variations of task are still counted as unique tasks and need to be named uniquely. This could be done by appending an additional naming that may refer to the variation such as in MMLU where the template used to evaluated for flan are differentiated from the default by the prefix mmlu_flan_*
. Printing the full task names can easily clutter the results table at the end of the evaluation especially when you have a long list of tasks or are using a benchmark that comprises of many tasks. To make it more legible, you can use task_alias
and group_alias
to provide an alternative task name and group name that will be printed. For example in mmlu_abstract_algebra.yaml
we set task_alias
to abstract_algebra
. In group configs, a group_alias
for a group can also be set.
"dataset_name": "abstract_algebra"
"description": "The following are multiple choice questions (with answers) about abstract\
\ algebra.\n\n"
"include": "_default_template_yaml"
"task": "mmlu_abstract_algebra"
"task_alias": "abstract_algebra"
After registering your task, you can now check on your data downloading and verify that the few-shot samples look as intended. Run the following command with your desired args:
python -m scripts.write_out \
--output_base_path <path> \
--tasks <your-task-name> \
--sets <train | val | test> \
--num_fewshot K \
--num_examples N \
Open the file specified at the --output_base_path <path>
and ensure it passes
a simple eye test.
One key feature in LM Evaluation Harness is the ability to version tasks and groups--that is, mark them with a specific version number that can be bumped whenever a breaking change is made.
This version info can be provided by adding the following to your new task or group config file:
metadata:
version: 0
Now, whenever a change needs to be made to your task in the future, please increase the version number by 1 so that users can differentiate the different task iterations and versions.
If you are incrementing a task's version, please also consider adding a changelog to the task's README.md noting the date, PR number, what version you have updated to, and a one-liner describing the change.
for example,
- [Dec 25, 2023] (PR #999) Version 0.0 -> 1.0: Fixed a bug with answer extraction that led to underestimated performance.
It's now time to check models' performance on your task! In the evaluation harness, we intend to support a wide range of evaluation tasks and setups, but prioritize the inclusion of already-proven benchmarks following the precise evaluation setups in the literature where possible.
To enable this, we provide a checklist that should be completed when contributing a new task, to enable accurate book-keeping and to ensure that tasks added to the library are well-tested and, where applicable, precedented.
The checklist is the following:
For adding novel benchmarks/datasets to the library:
- Is the task an existing benchmark in the literature?
- Have you referenced the original paper that introduced the task?
- If yes, does the original paper provide a reference implementation? If so, have you checked against the reference implementation and documented how to run such a test?
If other tasks on this dataset are already supported:
- Is the "Main" variant of this task clearly denoted?
- Have you provided a short sentence in a README on what each new variant adds / evaluates?
- Have you noted which, if any, published evaluation setups are matched by this variant?
It is recommended to include a filled-out copy of this checklist in the README.md for the subfolder you are creating, if you have created a new subfolder in lm_eval/tasks
.
Finally, please add a short description of your task(s), along with a link to its subfolder in lm_eval/tasks , to lm_eval/tasks/README.md
so that users can discover your task in the library, and follow the link to your README for more information about the variants supported, their task names, and the original source of the dataset and/or evaluation setup.
You're all set! Now push your work and make a pull request to the main
branch! Thanks for the contribution :). If there are any questions, please leave a message in the #lm-thunderdome
channel on the EAI discord!