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neon_arch

🔧 chore: fix link in the logs & add logs for engine error (#170)

653d08c over 1 year ago

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	//! This module provides the functionality to scrape and gathers all the results from the upstream
	//! search engines and then removes duplicate results.

	use std::{collections::HashMap, time::Duration};

	use error_stack::Report;
	use rand::Rng;
	use tokio::task::JoinHandle;

	use super::{
	aggregation_models::{EngineErrorInfo, RawSearchResult, SearchResult, SearchResults},
	user_agent::random_user_agent,
	};

	use crate::engines::{
	duckduckgo,
	engine_models::{EngineError, SearchEngine},
	searx,
	};

	/// Aliases for long type annotations
	type FutureVec = Vec<JoinHandle<Result<HashMap<String, RawSearchResult>, Report<EngineError>>>>;

	/// The function aggregates the scraped results from the user-selected upstream search engines.
	/// These engines can be chosen either from the user interface (UI) or from the configuration file.
	/// The code handles this process by matching the selected search engines and adding them to a vector.
	/// This vector is then used to create an asynchronous task vector using `tokio::spawn`, which returns
	/// a future. This future is awaited in another loop. Once the results are collected, they are filtered
	/// to remove any errors and ensure only proper results are included. If an error is encountered, it is
	/// sent to the UI along with the name of the engine and the type of error. This information is finally
	/// placed in the returned `SearchResults` struct.
	///
	/// Additionally, the function eliminates duplicate results. If two results are identified as coming from
	/// multiple engines, their names are combined to indicate that the results were fetched from these upstream
	/// engines. After this, all the data in the `HashMap` is removed and placed into a struct that contains all
	/// the aggregated results in a vector. Furthermore, the query used is also added to the struct. This step is
	/// necessary to ensure that the search bar in the search remains populated even when searched from the query URL.
	///
	/// Overall, this function serves to aggregate scraped results from user-selected search engines, handling errors,
	/// removing duplicates, and organizing the data for display in the UI.
	///
	/// # Example:
	///
	/// If you search from the url like `https://127.0.0.1/search?q=huston` then the search bar should
	/// contain the word huston and not remain empty.
	///
	/// # Arguments
	///
	/// * `query` - Accepts a string to query with the above upstream search engines.
	/// * `page` - Accepts an u32 page number.
	/// * `random_delay` - Accepts a boolean value to add a random delay before making the request.
	/// * `debug` - Accepts a boolean value to enable or disable debug mode option.
	/// * `upstream_search_engines` - Accepts a vector of search engine names which was selected by the
	/// * `request_timeout` - Accepts a time (secs) as a value which controls the server request timeout.
	/// user through the UI or the config file.
	///
	/// # Error
	///
	/// Returns an error a reqwest and scraping selector errors if any error occurs in the results
	/// function in either `searx` or `duckduckgo` or both otherwise returns a `SearchResults struct`
	/// containing appropriate values.
	pub async fn aggregate(
	query: String,
	page: u32,
	random_delay: bool,
	debug: bool,
	upstream_search_engines: Vec<String>,
	request_timeout: u8,
	) -> Result<SearchResults, Box<dyn std::error::Error>> {
	let user_agent: String = random_user_agent();
	let mut result_map: HashMap<String, RawSearchResult> = HashMap::new();

	// Add a random delay before making the request.
	if random_delay \|\| !debug {
	let mut rng = rand::thread_rng();
	let delay_secs = rng.gen_range(1..10);
	std::thread::sleep(Duration::from_secs(delay_secs));
	}

	// fetch results from upstream search engines simultaneously/concurrently.
	let search_engines: Vec<Box<dyn SearchEngine + Send + Sync>> = upstream_search_engines
	.iter()
	.map(\|engine\| match engine.to_lowercase().as_str() {
	"duckduckgo" => Box::new(duckduckgo::DuckDuckGo) as Box<dyn SearchEngine + Send + Sync>,
	"searx" => Box::new(searx::Searx) as Box<dyn SearchEngine + Send + Sync>,
	&_ => panic!("Config Error: Incorrect config file option provided"),
	})
	.collect();

	let task_capacity: usize = search_engines.len();

	let tasks: FutureVec = search_engines
	.into_iter()
	.map(\|search_engine\| {
	let query: String = query.clone();
	let user_agent: String = user_agent.clone();
	tokio::spawn(async move {
	search_engine
	.results(query, page, user_agent.clone(), request_timeout)
	.await
	})
	})
	.collect();

	let mut outputs = Vec::with_capacity(task_capacity);

	for task in tasks {
	if let Ok(result) = task.await {
	outputs.push(result)
	}
	}

	let mut engine_errors_info: Vec<EngineErrorInfo> = Vec::new();

	// The code block `outputs.iter()` determines whether it is the first time the code is being run.
	// It does this by checking the initial flag. If it is the first time, the code selects the first
	// engine from which results are fetched and adds or extends them into the `result_map`. If the
	// initially selected engine fails, the code automatically selects another engine to map or extend
	// into the `result_map`. On the other hand, if an engine selected for the first time successfully
	// fetches results and maps them into the `result_map`, the initial flag is set to false. Subsequently,
	// the code iterates through the remaining engines one by one. It compares the fetched results from each
	// engine with the results already present in the `result_map` to identify any duplicates. If duplicate
	// results are found, the code groups them together with the name of the engine from which they were
	// fetched, and automatically removes the duplicate results from the newly fetched data.
	//
	// Additionally, the code handles errors returned by the engines. It keeps track of which engines
	// encountered errors and stores this information in a vector of structures called `EngineErrorInfo`.
	// Each structure in this vector contains the name of the engine and the type of error it returned.
	// These structures will later be added to the final `SearchResults` structure. The `SearchResults`
	// structure is used to display an error box in the UI containing the relevant information from
	// the `EngineErrorInfo` structure.
	//
	// In summary, this code block manages the selection of engines, handling of duplicate results, and tracking
	// of errors in order to populate the `result_map` and provide informative feedback to the user through the
	// `SearchResults` structure.
	let mut initial: bool = true;
	let mut counter: usize = 0;
	outputs.iter().for_each(\|results\| {
	if initial {
	match results {
	Ok(result) => {
	result_map.extend(result.clone());
	counter += 1;
	initial = false
	}
	Err(error_type) => {
	log::error!("Engine Error: {:?}", error_type);
	engine_errors_info.push(EngineErrorInfo::new(
	error_type.downcast_ref::<EngineError>().unwrap(),
	upstream_search_engines[counter].clone(),
	));
	counter += 1
	}
	}
	} else {
	match results {
	Ok(result) => {
	result.clone().into_iter().for_each(\|(key, value)\| {
	result_map
	.entry(key)
	.and_modify(\|result\| {
	result.add_engines(value.clone().engine());
	})
	.or_insert_with(\|\| -> RawSearchResult {
	RawSearchResult::new(
	value.title.clone(),
	value.visiting_url.clone(),
	value.description.clone(),
	value.engine.clone(),
	)
	});
	});
	counter += 1
	}
	Err(error_type) => {
	log::error!("Engine Error: {:?}", error_type);
	engine_errors_info.push(EngineErrorInfo::new(
	error_type.downcast_ref::<EngineError>().unwrap(),
	upstream_search_engines[counter].clone(),
	));
	counter += 1
	}
	}
	}
	});

	Ok(SearchResults::new(
	result_map
	.into_iter()
	.map(\|(key, value)\| {
	SearchResult::new(
	value.title,
	value.visiting_url,
	key,
	value.description,
	value.engine,
	)
	})
	.collect(),
	query.to_string(),
	engine_errors_info,
	))
	}