Status: True
Assertion
The Earth’s diameter at the equator is roughly 12,742 kilometres.
Results
The statement accurately describes important aspects of scaling down Earth’s equatorial diameter using paper as a representation tool. It emphasizes the importance of accurate measurements, proper use of rulers and protractors, understanding of scale factor calculations, and maintaining proportionality for effective simplification on a smaller scale.
Assumptions
Here are the assumptions supporting the statement that constructing an approximation of Earth’s equatorial diameter on paper using a ruler and protractor can demonstrate the concept of scaling down:
1. The scale factor used (1:1,000,000) is chosen appropriately to fit the Earth’s equatorial diameter into the A3 size paper while maintaining proportionality.
2. Precision in measuring and drawing on a ruler and protractor can ensure an accurate representation of scaled-down dimensions.
3. The use of these tools (ruler and protractor) is appropriate for creating straight lines, angles, and curves required to represent the Earth’s equatorial diameter accurately.
4. Users understand how to read a ruler in centimeters and degrees on a protractor correctly.
5. Proper scaling calculations are performed before drawing to maintain proportionality of dimensions when representing real-world objects on paper.
6. The representation is simplified, focusing only on the equatorial diameter while ignoring other relevant Earth features for simplicity’s sake in demonstrating the concept of scaling down.
7. Users have a basic understanding of scale and can interpret the results correctly.
Fact Checker Output
<|assistant|> 1. True – The chosen scale factor (1:1,000,000) allows for fitting Earth’s equatorial diameter onto an A3 size paper while maintaining proportionality; this demonstrates the concept of scaling down effectively.
2. True – Precision in using a ruler and protractor can ensure accurate measurements and drawings, which are crucial when representing scaled-down dimensions on paper.
3. True – Rulers are ideal for measuring straight lines and angles while protractors are perfect for drawing precise angles; these tools together allow for an accurate representation of Earth’s equatorial diameter in a simplified form.
4. True – Users should understand how to read both the centimeter markings on rulers and degree measurements on protractors, as it is fundamental for accurately applying scaled-down dimensions on paper.
5. True – Performing proper scaling calculations before drawing ensures that all proportional relationships are maintained when representing real-world objects like Earth’s equatorial diameter on a smaller scale, demonstrating the concept of scaling down effectively.
6. True – By simplifying the representation to focus solely on the equatorial
Model Used
microsoft/Phi-3-mini-4k-instruct-gguf
Script Name
fact_checker_mongodb.py
Script Code
import os
import sys
import requests
from langchain_openai.llms import OpenAI
from langchain.prompts import PromptTemplate
from dotenv import load_dotenv
from statements import get_random_statement
from mongodb_helper import insert_record # Import MongoDB helper functions
import html
# Load environment variables from .env file
load_dotenv()
# Define category IDs
CATEGORY_IDS = {
"True": 2,
"False": 3,
"Debatable": 4,
"Unknown": 6
}
def create_wordpress_post(title, content, category):
data = {
"title": title,
"content": content,
"status": "publish",
"categories": [CATEGORY_IDS[category]]
}
response = requests.post(
os.getenv("WORDPRESS_POSTS_URL"),
json=data,
auth=(os.getenv("WORDPRESS_USERNAME"), os.getenv("WORDPRESS_PASSWORD"))
)
if response.status_code == 201:
print("Blog post created successfully.")
else:
print(f"Failed to create blog post: {response.status_code} - {response.text}")
def fact_check(assertion):
llm = OpenAI(temperature=0.7, model=os.getenv("MODEL_NAME"))
# Define the prompt templates
assertion_template = """{assertion}\n\n"""
assertion_prompt = PromptTemplate(input_variables=["assertion"], template=assertion_template)
assumptions_template = """Here is a statement:
{statement}
Make a bullet point list of the assumptions required to support the above statement.\n\n"""
assumptions_prompt = PromptTemplate(input_variables=["statement"], template=assumptions_template)
fact_checker_template = """Here is a bullet point list of assertions:
{assertions}
For each assumption, determine whether it is true or false. Explain your reasoning.\n\n"""
fact_checker_prompt = PromptTemplate(input_variables=["assertions"], template=fact_checker_template)
answer_template = """
Here is the information to classify the statement:
{facts}
Based on the above information, how would you classify the statement? Respond with one of the following options followed by a colon and space:
- True: [Explanation]
- False: [Explanation]
- Debatable: [Explanation]
"""
answer_prompt = PromptTemplate(input_variables=["facts"], template=answer_template)
# Format prompts and extract the string content
formatted_assertion = assertion_prompt.format_prompt(assertion=assertion).text
assertion_output = llm.invoke(formatted_assertion)
formatted_assumptions = assumptions_prompt.format_prompt(statement=assertion_output).text
assumptions_output = llm.invoke(formatted_assumptions)
formatted_fact_checker = fact_checker_prompt.format_prompt(assertions=assumptions_output).text
fact_checker_output = llm.invoke(formatted_fact_checker)
formatted_answer = answer_prompt.format_prompt(facts=fact_checker_output).text
final_output = llm.invoke(formatted_answer)
return {
"assertion_output": assertion_output,
"assumptions_output": assumptions_output,
"fact_checker_output": fact_checker_output,
"final_output": final_output,
}
def extract_status_and_reasoning(final_output):
final_output = final_output.strip()
if "True:" in final_output:
status_start = final_output.find("True:")
status = "True"
elif "False:" in final_output:
status_start = final_output.find("False:")
status = "False"
elif "Debatable:" in final_output:
status_start = final_output.find("Debatable:")
status = "Debatable"
else:
return "Unknown", final_output
reasoning = final_output[status_start + len(status) + 1:].strip()
return status, reasoning
if __name__ == "__main__":
if len(sys.argv) > 1:
assertion = sys.argv[1]
else:
assertion = get_random_statement()
print(assertion)
submission = fact_check(assertion)
# Print the detailed outputs to inspect their structure
for key, value in submission.items():
print(f"{key}: {value}")
# Extract the final output for status determination and reasoning
final_output = submission['final_output']
status, reasoning = extract_status_and_reasoning(final_output)
# Record the result in MongoDB
try:
print("Attempting to insert record into MongoDB...")
insert_record(
script_name="fact_checker_mongodb.py",
script_code=html.escape(open(__file__).read()),
assertion=assertion,
status=status,
submission=submission, # Store the entire submission for detailed analysis
model=os.getenv("MODEL_NAME")
)
print("Record inserted into MongoDB successfully.")
except Exception as e:
print(f"Failed to insert record into MongoDB: {e}")
print(final_output)
# Create a blog post on WordPress
blog_title = f"Fact Check: {assertion}"
blog_content = f"""
<h1>Status: {status}</h1>
<h2>Assertion</h2>
<p>{assertion}</p>
<h2>Results</h2>
<p>{reasoning}</p>
<h3>Assumptions</h3>
<p>{submission['assumptions_output']}</p>
<h3>Fact Checker Output</h3>
<p>{submission['fact_checker_output']}</p>
<h4>Model Used</h4>
<p>{os.getenv("MODEL_NAME")}</p>
<h4>Script Name</h4>
<p>fact_checker_mongodb.py</p>
<h4>Script Code</h4>
<pre>{html.escape(open(__file__).read())}</pre>
"""
create_wordpress_post(blog_title, blog_content, status)
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