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We can load HumanEval dataset and pass@k metric from 🤗 [`datasets`](https://huggingface.co/docs/datasets/index) and 🤗 [`evaluate`](https://huggingface.co/docs/evaluate/index) |
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```python |
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from datasets import load_dataset |
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from evaluate import load |
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human_eval = load_dataset("openai_humaneval") |
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code_eval_metric = load("code_eval") |
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``` |
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We can easily compute the pass@k for a problem that asks for the implementation of a function that sums two integers: |
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```python |
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test_cases = ["assert add(2,3)==5"] |
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candidates = [["def add(a,b): return a*b", "def add(a, b): return a+b"]] |
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pass_at_k, results = code_eval_metric.compute(references=test_cases, predictions=candidates, k=[1, 2]) |
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print(pass_at_k) |
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{'pass@1': 0.5, 'pass@2': 1.0} |
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``` |
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To better understand how pass@k metric works, we will illustrate it with a concrete example from HumanEval dataset. We select the problem below and see how CodeParrot 🦜 (110M) performs and which code completions pass the unit tests: |
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**Problem:** |
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```python |
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def truncate_number(number: float) -> float: |
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""" Given a positive floating point number, it can be decomposed into |
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and integer part (largest integer smaller than given number) and decimals |
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(leftover part always smaller than 1). |
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Return the decimal part of the number. |
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>>> truncate_number(3.5) |
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0.5 |
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""" |
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```` |
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Instead of 200 candidate solutions, we will only generate 20 samples for illustration purposes. We use nucleus sampling with top-p where `p=0.95`, `temperature=0.2`, and sample tokens from the model until we encounter a stop sequence indicating the end of a method: ‘\nclass’, ‘\ndef’, ‘\n#’, ‘\nif’, or ‘\nprint’. For more details about decoding strategies for language generation, we recommend this [blog](https://huggingface.co/blog/how-to-generate). |
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**Remark**: |
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Regarding the temperature parameter, in [CodeGen](https://github.com/salesforce/CodeGen) paper, the authors observed that the best performing temperature increases as the number of samples permitted k increases. When a model is only allowed a few samples to pass unit tests, it is beneficial to use the learned distribution, through a low temperature, to select candidates that are likely to pass. But when a model is allowed for more chances with a high k, using a higher sampling temperature to tilt the learned model distribution lets it explore diverse samples and thus have a greater chance of synthesizing a correct program. |
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For our experiment, we compute pass@1, pass@10 and pass@20, each corresponding to unit test pass rate when selecting respectively 1, 10 and 20 samples from the candidate solutions. |
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``` |
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Results: {'pass@1': 0.1, 'pass@10': 0.7631, 'pass@20': 1.0} |
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```` |
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If we take a closer look at the unit test results for each candidate solution, we find that 2 passed the unit test. This means that we have 2 correct solutions among 20, which corresponds to our pass@1 value `2/20 = 0.1`. The scores pass@10 and pass@20 are higher, because the more samples we select from the candidate completions, the more likely we are to include the correct implementation. As |
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for pass@20, it is `1`, since if we select all 20 candidates the problem gets solved which gives 100% success rate. If you are curious about the candidate solutions that passed the tests, they both implemented this function: |
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```python |
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def truncate_number(number: float) -> float: |
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""" Given a positive floating point number, it can be decomposed into |
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and integer part (largest integer smaller than given number) and decimals |
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(leftover part always smaller than 1). |
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Return the decimal part of the number. |
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>>> truncate_number(3.5) |
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0.5 |
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""" |
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return number % 1 |
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``` |