Status: True
Assertion
Sunflowers track the sun across the sky.
Reasoning
Sunflowers exhibit heliotropism, particularly during their early growth stages. The `sunFollowSunflower` function simplifies reality by assuming only one light source affects the movement of a sunflower, which aligns with the general understanding that while multiple light sources can influence plant orientation, the primary focus when discussing heliotropism in sunflowers is their tracking behavior toward the sun’s path across the sky to maximize photosynthesis. This simplification is appropriate for illustrating this specific biological phenomenon.
Assumptions
<|assistant|> – Sunflowers have a natural growth habit that exhibits heliotropism, which is the ability to move their flowers or leaves in response to sunlight.
– The function `sunFollowSunflower` assumes there’s only one source of light (the sun) affecting the movement of the sunflower.
– The statement presumes that during certain stages of growth, specifically before maturity (usually until about 30 days old), sunflowers will actively track the sun across the sky.
– It implies a static environment where only light from the sun affects the movement and no other environmental factors like shadows or moonlight play a significant role in influencing the sunflower’s orientation.
– The function assumes that the input `sun` is relevant to the context, meaning it represents the sun as an object with properties that can be described in relation to its position and behavior relative to the sunflower (although not explicitly defined within this scope).
– It does not take into account any artificial light sources or changes in natural light patterns due to geographical location, time of day, or season.
– The statement does not consider variability among different species of sunflowers
Fact Checker Output
explanation: – True: Sunflowers exhibit heliotropism, especially during their early growth stages before they reach maturity. This behavior allows them to optimize photosynthesis by facing the sun throughout the day.
– False: The function `sunFollowSunflower` oversimplifies reality by assuming only one light source affects movement. In a realistic scenario, multiple sources of light (such as other stars at night or artificial lights during the day) might influence plant orientation. However, in terms of solar tracking behavior during the daytime, this assumption is generally true for sunflowers.
– True: Sunflowers are known to track the sun across the sky when they’re young and growing rapidly, a phenomenon called heliotropism or solar tracking. This behavior typically diminishes as they mature and enter their reproductive phase.
– False: While it is true that the function focuses on the light from the sun affecting the sunflower’s movement, saying no other environmental factors play a role might be too narrow. For instance, while moonlight or artificial lights are not directly responsible for heliotropism in this context, they can impact plant growth
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
from wordpress_helper import create_wordpress_post # Import WordPress helper functions
import html
# Load environment variables from .env file
load_dotenv()
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):
llm = OpenAI(temperature=0.7, model=os.getenv("MODEL_NAME"))
extraction_template = """
Here is a final output of a fact-checking process:
{final_output}
Based on the above text, what is the classification of the statement? Respond with one of the following options followed by a colon and space:
- True: [Explanation]
- False: [Explanation]
- Debatable: [Explanation]
"""
extraction_prompt = PromptTemplate(input_variables=["final_output"], template=extraction_template)
formatted_prompt = extraction_prompt.format_prompt(final_output=final_output).text
extraction_output = llm.invoke(formatted_prompt).strip()
if "True:" in extraction_output:
status = "True"
reasoning = extraction_output.split("True:", 1)[1].strip()
elif "False:" in extraction_output:
status = "False"
reasoning = extraction_output.split("False:", 1)[1].strip()
elif "Debatable:" in extraction_output:
status = "Debatable"
reasoning = extraction_output.split("Debatable:", 1)[1].strip()
else:
status = "Unknown"
reasoning = extraction_output
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)
# Print the final status and reasoning
print(final_output)
print(f"Status: {status}")
print(f"Reasoning: {reasoning}")
# Record the result in MongoDB
try:
print("Attempting to insert record into MongoDB...")
insert_record(
script_name=__file__,
script_code=html.escape(open(__file__).read()),
assertion=assertion,
status=status,
submission=submission, # Store the entire submission for detailed analysis
reasoning=reasoning,
model=os.getenv("MODEL_NAME")
)
print("Record inserted into MongoDB successfully.")
except Exception as e:
print(f"Failed to insert record into MongoDB: {e}")
# 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>Reasoning</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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