use crate::{
	app, constants,
	data_conversion::{ConvertedCpuData, ConvertedProcessData},
	utils::{error, gen_util::*},
};
use tui::{
	backend,
	layout::{Alignment, Constraint, Direction, Layout, Rect},
	style::{Color, Modifier, Style},
	terminal::Frame,
	widgets::{Axis, Block, Borders, Chart, Dataset, Marker, Paragraph, Row, Table, Text, Widget},
	Terminal,
};

const TEXT_COLOUR: Color = Color::Gray;
const GRAPH_COLOUR: Color = Color::Gray;
const BORDER_STYLE_COLOUR: Color = Color::Gray;
const HIGHLIGHTED_BORDER_STYLE_COLOUR: Color = Color::LightBlue;
const GOLDEN_RATIO: f32 = 0.618_034; // Approx, good enough for use (also Clippy gets mad if it's too long)

lazy_static! {
	static ref HELP_TEXT: [Text<'static>; 14] = [
		Text::raw("\nGeneral Keybindings\n"),
		Text::raw("q, Ctrl-c to quit.\n"),
		Text::raw("Ctrl-r to reset all data.\n"),
		Text::raw("f to toggle freezing and unfreezing the display.\n"),
		Text::raw("Ctrl+Up/k, Ctrl+Down/j, Ctrl+Left/h, Ctrl+Right/l to navigate between panels.\n"),
		Text::raw("Up and Down scrolls through a list.\n"),
		Text::raw("Esc to close a dialog window (help or dd confirmation).\n"),
		Text::raw("? to get this help screen.\n"),
		Text::raw("\n Process Panel Keybindings\n"),
		Text::raw("dd to kill the selected process.\n"),
		Text::raw("c to sort by CPU usage.\n"),
		Text::raw("m to sort by memory usage.\n"),
		Text::raw("p to sort by PID.\n"),
		Text::raw("n to sort by process name.\n"),
	];
	static ref COLOUR_LIST: Vec<Color> = gen_n_colours(constants::NUM_COLOURS);
	static ref CANVAS_BORDER_STYLE: Style = Style::default().fg(BORDER_STYLE_COLOUR);
	static ref CANVAS_HIGHLIGHTED_BORDER_STYLE: Style = Style::default().fg(HIGHLIGHTED_BORDER_STYLE_COLOUR);
}

#[derive(Default)]
pub struct CanvasData {
	pub rx_display: String,
	pub tx_display: String,
	pub total_rx_display: String,
	pub total_tx_display: String,
	pub network_data_rx: Vec<(f64, f64)>,
	pub network_data_tx: Vec<(f64, f64)>,
	pub disk_data: Vec<Vec<String>>,
	pub temp_sensor_data: Vec<Vec<String>>,
	pub process_data: Vec<ConvertedProcessData>,
	pub memory_labels: Vec<(u64, u64)>,
	pub mem_data: Vec<(f64, f64)>,
	pub swap_data: Vec<(f64, f64)>,
	pub cpu_data: Vec<ConvertedCpuData>,
}

/// Generates random colours.
/// Strategy found from https://martin.ankerl.com/2009/12/09/how-to-create-random-colors-programmatically/
fn gen_n_colours(num_to_gen: i32) -> Vec<Color> {
	fn gen_hsv(h: f32) -> f32 {
		let new_val = h + GOLDEN_RATIO;
		if new_val > 1.0 {
			new_val.fract()
		} else {
			new_val
		}
	}
	/// This takes in an h, s, and v value of range [0, 1]
	/// For explanation of what this does, see
	/// https://en.wikipedia.org/wiki/HSL_and_HSV#HSV_to_RGB_alternative
	fn hsv_to_rgb(hue: f32, saturation: f32, value: f32) -> (u8, u8, u8) {
		fn hsv_helper(num: u32, hu: f32, sat: f32, val: f32) -> f32 {
			let k = (num as f32 + hu * 6.0) % 6.0;
			val - val * sat * float_max(float_min(k, float_min(4.1 - k, 1.1)), 0.0)
		}

		(
			(hsv_helper(5, hue, saturation, value) * 255.0) as u8,
			(hsv_helper(3, hue, saturation, value) * 255.0) as u8,
			(hsv_helper(1, hue, saturation, value) * 255.0) as u8,
		)
	}

	// Generate colours
	let mut colour_vec: Vec<Color> = vec![Color::LightCyan, Color::LightYellow, Color::Red, Color::Green, Color::LightMagenta];

	let mut h: f32 = 0.4; // We don't need random colours... right?
	for _i in 0..num_to_gen {
		h = gen_hsv(h);
		let result = hsv_to_rgb(h, 0.5, 0.95);
		colour_vec.push(Color::Rgb(result.0, result.1, result.2));
	}

	colour_vec
}

pub fn draw_data<B: backend::Backend>(terminal: &mut Terminal<B>, app_state: &mut app::App) -> error::Result<()> {
	terminal.autoresize()?;
	terminal.draw(|mut f| {
		if app_state.show_help {
			// Only for the help
			let vertical_dialog_chunk = Layout::default()
				.direction(Direction::Vertical)
				.margin(1)
				.constraints([Constraint::Percentage(32), Constraint::Percentage(40), Constraint::Percentage(28)].as_ref())
				.split(f.size());

			let middle_dialog_chunk = Layout::default()
				.direction(Direction::Horizontal)
				.margin(0)
				.constraints([Constraint::Percentage(30), Constraint::Percentage(40), Constraint::Percentage(30)].as_ref())
				.split(vertical_dialog_chunk[1]);

			Paragraph::new(HELP_TEXT.iter())
				.block(Block::default().title("Help (Press Esc to close)").borders(Borders::ALL))
				.style(Style::default().fg(Color::Gray))
				.alignment(Alignment::Left)
				.wrap(true)
				.render(&mut f, middle_dialog_chunk[1]);
		} else if app_state.show_dd {
			let vertical_dialog_chunk = Layout::default()
				.direction(Direction::Vertical)
				.margin(1)
				.constraints([Constraint::Percentage(40), Constraint::Percentage(20), Constraint::Percentage(40)].as_ref())
				.split(f.size());

			let middle_dialog_chunk = Layout::default()
				.direction(Direction::Horizontal)
				.margin(0)
				.constraints([Constraint::Percentage(30), Constraint::Percentage(40), Constraint::Percentage(30)].as_ref())
				.split(vertical_dialog_chunk[1]);

			if let Some(dd_err) = app_state.dd_err.clone() {
				let dd_text = [Text::raw(format!("\nFailure to properly kill the process - {}", dd_err))];

				Paragraph::new(dd_text.iter())
					.block(Block::default().title("Kill Process Error (Press Esc to close)").borders(Borders::ALL))
					.style(Style::default().fg(Color::Gray))
					.alignment(Alignment::Center)
					.wrap(true)
					.render(&mut f, middle_dialog_chunk[1]);
			} else if let Some(process) = app_state.get_current_highlighted_process() {
				let dd_text = [
					Text::raw(format!(
						"\nAre you sure you want to kill process {} with PID {}?",
						process.name, process.pid
					)),
					Text::raw("\n\nPress ENTER to proceed, ESC to exit."),
					Text::raw("\nNote that if bottom is frozen, it must be unfrozen for changes to be shown."),
				];

				Paragraph::new(dd_text.iter())
					.block(
						Block::default()
							.title("Kill Process Confirmation (Press Esc to close)")
							.borders(Borders::ALL),
					)
					.style(Style::default().fg(Color::Gray))
					.alignment(Alignment::Center)
					.wrap(true)
					.render(&mut f, middle_dialog_chunk[1]);
			} else {
				// This is a bit nasty, but it works well... I guess.
				app_state.show_dd = false;
			}
		} else {
			let vertical_chunks = Layout::default()
				.direction(Direction::Vertical)
				.margin(1)
				.constraints([Constraint::Percentage(33), Constraint::Percentage(34), Constraint::Percentage(34)].as_ref())
				.split(f.size());

			let middle_chunks = Layout::default()
				.direction(Direction::Horizontal)
				.margin(0)
				.constraints([Constraint::Percentage(60), Constraint::Percentage(40)].as_ref())
				.split(vertical_chunks[1]);

			let middle_divided_chunk_2 = Layout::default()
				.direction(Direction::Vertical)
				.margin(0)
				.constraints([Constraint::Percentage(50), Constraint::Percentage(50)].as_ref())
				.split(middle_chunks[1]);

			let bottom_chunks = Layout::default()
				.direction(Direction::Horizontal)
				.margin(0)
				.constraints([Constraint::Percentage(50), Constraint::Percentage(50)].as_ref())
				.split(vertical_chunks[2]);

			// Component specific chunks
			let cpu_chunk = Layout::default()
				.direction(Direction::Horizontal)
				.margin(0)
				.constraints(
					if app_state.left_legend {
						[Constraint::Percentage(15), Constraint::Percentage(85)]
					} else {
						[Constraint::Percentage(85), Constraint::Percentage(15)]
					}
					.as_ref(),
				)
				.split(vertical_chunks[0]);

			let network_chunk = Layout::default()
				.direction(Direction::Vertical)
				.margin(0)
				.constraints(
					if app_state.left_legend {
						[Constraint::Percentage(10), Constraint::Percentage(90)]
					} else {
						[Constraint::Percentage(75), Constraint::Percentage(10)]
					}
					.as_ref(),
				)
				.split(bottom_chunks[0]);

			// Default chunk index based on left or right legend setting
			let legend_index = if app_state.left_legend { 0 } else { 1 };
			let graph_index = if app_state.left_legend { 1 } else { 0 };

			// Set up blocks and their components
			// CPU graph
			draw_cpu_graph(&mut f, &app_state, cpu_chunk[graph_index]);

			// CPU legend
			draw_cpu_legend(&mut f, app_state, cpu_chunk[legend_index]);

			//Memory usage graph
			draw_memory_graph(&mut f, &app_state, middle_chunks[0]);

			// Network graph
			draw_network_graph(&mut f, &app_state, network_chunk[0]);

			draw_network_labels(&mut f, app_state, network_chunk[1]);

			// Temperature table
			draw_temp_table(&mut f, app_state, middle_divided_chunk_2[0]);

			// Disk usage table
			draw_disk_table(&mut f, app_state, middle_divided_chunk_2[1]);

			// Processes table
			draw_processes_table(&mut f, app_state, bottom_chunks[1]);
		}
	})?;

	Ok(())
}

fn draw_cpu_graph<B: backend::Backend>(f: &mut Frame<B>, app_state: &app::App, draw_loc: Rect) {
	let cpu_data: &[ConvertedCpuData] = &app_state.canvas_data.cpu_data;

	// CPU usage graph
	let x_axis: Axis<String> = Axis::default()
		.style(Style::default().fg(GRAPH_COLOUR))
		.bounds([0.0, constants::TIME_STARTS_FROM as f64 * 10.0]);
	let y_axis = Axis::default()
		.style(Style::default().fg(GRAPH_COLOUR))
		.bounds([-0.5, 100.5])
		.labels(&["0%", "100%"]);

	let mut dataset_vector: Vec<Dataset> = Vec::new();
	let mut cpu_entries_vec: Vec<(Style, Vec<(f64, f64)>)> = Vec::new();

	for (i, cpu) in cpu_data.iter().enumerate() {
		let mut avg_cpu_exist_offset = 0;
		if app_state.show_average_cpu {
			if i == 0 {
				// Skip, we want to render the average cpu last!
				continue;
			} else {
				avg_cpu_exist_offset = 1;
			}
		}

		cpu_entries_vec.push((
			Style::default().fg(COLOUR_LIST[(i - avg_cpu_exist_offset) % COLOUR_LIST.len()]),
			cpu.cpu_data.iter().map(<(f64, f64)>::from).collect::<Vec<_>>(),
		));
	}

	if app_state.show_average_cpu {
		if let Some(avg_cpu_entry) = cpu_data.first() {
			cpu_entries_vec.push((
				Style::default().fg(COLOUR_LIST[(cpu_data.len() - 1) % COLOUR_LIST.len()]),
				avg_cpu_entry.cpu_data.iter().map(<(f64, f64)>::from).collect::<Vec<_>>(),
			));
		}
	}

	for cpu_entry in &cpu_entries_vec {
		dataset_vector.push(
			Dataset::default()
				.marker(if app_state.use_dot { Marker::Dot } else { Marker::Braille })
				.style(cpu_entry.0)
				.data(&(cpu_entry.1)),
		);
	}

	Chart::default()
		.block(
			Block::default()
				.title("CPU")
				.borders(Borders::ALL)
				.border_style(match app_state.current_application_position {
					app::ApplicationPosition::Cpu => *CANVAS_HIGHLIGHTED_BORDER_STYLE,
					_ => *CANVAS_BORDER_STYLE,
				}),
		)
		.x_axis(x_axis)
		.y_axis(y_axis)
		.datasets(&dataset_vector)
		.render(f, draw_loc);
}

fn draw_cpu_legend<B: backend::Backend>(f: &mut Frame<B>, app_state: &mut app::App, draw_loc: Rect) {
	let cpu_data: &[ConvertedCpuData] = &(app_state.canvas_data.cpu_data);

	let num_rows = i64::from(draw_loc.height) - 4;
	let start_position = get_start_position(
		num_rows,
		&(app_state.scroll_direction),
		&mut app_state.previous_cpu_table_position,
		&mut app_state.currently_selected_cpu_table_position,
	);

	let sliced_cpu_data = (&cpu_data[start_position as usize..]).to_vec();
	let mut stringified_cpu_data: Vec<Vec<String>> = Vec::new();

	for cpu in sliced_cpu_data {
		if let Some(cpu_data) = cpu.cpu_data.last() {
			stringified_cpu_data.push(vec![cpu.cpu_name.clone(), format!("{:.0}%", cpu_data.usage.round())]);
		}
	}

	let mut cpu_row_counter = 0;

	let cpu_rows = stringified_cpu_data.iter().enumerate().map(|(itx, cpu_string_row)| {
		Row::StyledData(
			cpu_string_row.iter(),
			match app_state.current_application_position {
				app::ApplicationPosition::Cpu => {
					if cpu_row_counter == app_state.currently_selected_cpu_table_position - start_position {
						cpu_row_counter = -1;
						Style::default().fg(Color::Black).bg(Color::Cyan)
					} else {
						if cpu_row_counter >= 0 {
							cpu_row_counter += 1;
						}
						Style::default().fg(COLOUR_LIST[itx % COLOUR_LIST.len()])
					}
				}
				_ => Style::default().fg(COLOUR_LIST[itx % COLOUR_LIST.len()]),
			},
		)
	});

	Table::new(["CPU", "Use%"].iter(), cpu_rows)
		.block(
			Block::default()
				.borders(Borders::ALL)
				.border_style(match app_state.current_application_position {
					app::ApplicationPosition::Cpu => *CANVAS_HIGHLIGHTED_BORDER_STYLE,
					_ => *CANVAS_BORDER_STYLE,
				}),
		)
		.header_style(Style::default().fg(Color::LightBlue))
		.widths(&[Constraint::Percentage(50), Constraint::Percentage(50)])
		.render(f, draw_loc);
}

fn _draw_memory_table<B: backend::Backend>(_f: &mut Frame<B>, _app_state: &app::App, _draw_loc: Rect) {
	todo!("Not implemented yet..."); // TODO: For basic mode
}

fn draw_memory_graph<B: backend::Backend>(f: &mut Frame<B>, app_state: &app::App, draw_loc: Rect) {
	let mem_data: &[(f64, f64)] = &(app_state.canvas_data.mem_data);
	let swap_data: &[(f64, f64)] = &(app_state.canvas_data.swap_data);
	let memory_labels: &[(u64, u64)] = &(app_state.canvas_data.memory_labels);

	let x_axis: Axis<String> = Axis::default()
		.style(Style::default().fg(GRAPH_COLOUR))
		.bounds([0.0, constants::TIME_STARTS_FROM as f64 * 10.0]);
	let y_axis = Axis::default()
		.style(Style::default().fg(GRAPH_COLOUR))
		.bounds([-0.5, 100.5]) // Offset as the zero value isn't drawn otherwise...
		.labels(&["0%", "100%"]);

	let mem_name = "RAM:".to_string()
		+ &format!("{:3}%", (mem_data.last().unwrap_or(&(0_f64, 0_f64)).1.round() as u64))
		+ &format!(
			"   {:.1}GB/{:.1}GB",
			memory_labels.first().unwrap_or(&(0, 0)).0 as f64 / 1024.0,
			memory_labels.first().unwrap_or(&(0, 0)).1 as f64 / 1024.0
		);
	let swap_name: String;

	let mut mem_canvas_vec: Vec<Dataset> = vec![Dataset::default()
		.name(&mem_name)
		.marker(if app_state.use_dot { Marker::Dot } else { Marker::Braille })
		.style(Style::default().fg(COLOUR_LIST[0]))
		.data(&mem_data)];

	if !(&swap_data).is_empty() {
		if let Some(last_canvas_result) = (&swap_data).last() {
			if last_canvas_result.1 >= 0.0 {
				swap_name = "SWP:".to_string()
					+ &format!("{:3}%", (swap_data.last().unwrap_or(&(0_f64, 0_f64)).1.round() as u64))
					+ &format!(
						"   {:.1}GB/{:.1}GB",
						memory_labels[1].0 as f64 / 1024.0,
						memory_labels[1].1 as f64 / 1024.0
					);
				mem_canvas_vec.push(
					Dataset::default()
						.name(&swap_name)
						.marker(if app_state.use_dot { Marker::Dot } else { Marker::Braille })
						.style(Style::default().fg(COLOUR_LIST[1]))
						.data(&swap_data),
				);
			}
		}
	}

	Chart::default()
		.block(
			Block::default()
				.title("Memory")
				.borders(Borders::ALL)
				.border_style(match app_state.current_application_position {
					app::ApplicationPosition::Mem => *CANVAS_HIGHLIGHTED_BORDER_STYLE,
					_ => *CANVAS_BORDER_STYLE,
				}),
		)
		.x_axis(x_axis)
		.y_axis(y_axis)
		.datasets(&mem_canvas_vec)
		.render(f, draw_loc);
}

fn draw_network_graph<B: backend::Backend>(f: &mut Frame<B>, app_state: &app::App, draw_loc: Rect) {
	let network_data_rx: &[(f64, f64)] = &(app_state.canvas_data.network_data_rx);
	let network_data_tx: &[(f64, f64)] = &(app_state.canvas_data.network_data_tx);

	let x_axis: Axis<String> = Axis::default().style(Style::default().fg(GRAPH_COLOUR)).bounds([0.0, 600_000.0]);
	let y_axis = Axis::default()
		.style(Style::default().fg(GRAPH_COLOUR))
		.bounds([-0.5, 30_f64])
		.labels(&["0B", "1KiB", "1MiB", "1GiB"]);
	Chart::default()
		.block(
			Block::default()
				.title("Network")
				.borders(Borders::ALL)
				.border_style(match app_state.current_application_position {
					app::ApplicationPosition::Network => *CANVAS_HIGHLIGHTED_BORDER_STYLE,
					_ => *CANVAS_BORDER_STYLE,
				}),
		)
		.x_axis(x_axis)
		.y_axis(y_axis)
		.datasets(&[
			Dataset::default()
				.marker(if app_state.use_dot { Marker::Dot } else { Marker::Braille })
				.style(Style::default().fg(COLOUR_LIST[0]))
				.data(&network_data_rx),
			Dataset::default()
				.marker(if app_state.use_dot { Marker::Dot } else { Marker::Braille })
				.style(Style::default().fg(COLOUR_LIST[1]))
				.data(&network_data_tx),
		])
		.render(f, draw_loc);
}

fn draw_network_labels<B: backend::Backend>(f: &mut Frame<B>, app_state: &mut app::App, draw_loc: Rect) {
	let rx_display: String = app_state.canvas_data.rx_display.clone();
	let tx_display: String = app_state.canvas_data.tx_display.clone();
	let total_rx_display: String = app_state.canvas_data.total_rx_display.clone();
	let total_tx_display: String = app_state.canvas_data.total_tx_display.clone();

	// Gross but I need it to work...
	let total_network = if cfg!(not(target_os = "windows")) {
		vec![vec![rx_display, tx_display, total_rx_display, total_tx_display]]
	} else {
		vec![vec![rx_display, tx_display]]
	};
	let mapped_network = total_network.iter().map(|val| Row::Data(val.iter()));

	Table::new(
		if cfg!(not(target_os = "windows")) {
			vec!["RX", "TX", "Total RX", "Total TX"]
		} else {
			vec!["RX", "TX"]
		}
		.iter(),
		mapped_network,
	)
	.block(
		Block::default()
			.borders(Borders::ALL)
			.border_style(match app_state.current_application_position {
				app::ApplicationPosition::Network => *CANVAS_HIGHLIGHTED_BORDER_STYLE,
				_ => *CANVAS_BORDER_STYLE,
			}),
	)
	.header_style(Style::default().fg(Color::LightBlue))
	.widths(&if cfg!(not(target_os = "windows")) {
		vec![
			Constraint::Percentage(25),
			Constraint::Percentage(25),
			Constraint::Percentage(25),
			Constraint::Percentage(25),
		]
	} else {
		vec![Constraint::Percentage(50), Constraint::Percentage(50)]
	})
	.render(f, draw_loc);
}

fn draw_temp_table<B: backend::Backend>(f: &mut Frame<B>, app_state: &mut app::App, draw_loc: Rect) {
	let temp_sensor_data: &[Vec<String>] = &(app_state.canvas_data.temp_sensor_data);

	let num_rows = i64::from(draw_loc.height) - 4;
	let start_position = get_start_position(
		num_rows,
		&(app_state.scroll_direction),
		&mut app_state.previous_temp_position,
		&mut app_state.currently_selected_temperature_position,
	);

	let sliced_vec: Vec<Vec<String>> = (&temp_sensor_data[start_position as usize..]).to_vec();
	let mut temp_row_counter = 0;

	let temperature_rows = sliced_vec.iter().map(|temp_row| {
		Row::StyledData(
			temp_row.iter(),
			match app_state.current_application_position {
				app::ApplicationPosition::Temp => {
					if temp_row_counter == app_state.currently_selected_temperature_position - start_position {
						temp_row_counter = -1;
						Style::default().fg(Color::Black).bg(Color::Cyan)
					} else {
						if temp_row_counter >= 0 {
							temp_row_counter += 1;
						}
						Style::default().fg(TEXT_COLOUR)
					}
				}
				_ => Style::default().fg(TEXT_COLOUR),
			},
		)
	});
	Table::new(["Sensor", "Temp"].iter(), temperature_rows)
		.block(
			Block::default()
				.title("Temperatures")
				.borders(Borders::ALL)
				.border_style(match app_state.current_application_position {
					app::ApplicationPosition::Temp => *CANVAS_HIGHLIGHTED_BORDER_STYLE,
					_ => *CANVAS_BORDER_STYLE,
				}),
		)
		.header_style(Style::default().fg(Color::LightBlue))
		.widths(&[Constraint::Percentage(50), Constraint::Percentage(50)])
		.render(f, draw_loc);
}

fn draw_disk_table<B: backend::Backend>(f: &mut Frame<B>, app_state: &mut app::App, draw_loc: Rect) {
	let disk_data: &[Vec<String>] = &(app_state.canvas_data.disk_data);
	let num_rows = i64::from(draw_loc.height) - 4;
	let start_position = get_start_position(
		num_rows,
		&(app_state.scroll_direction),
		&mut app_state.previous_disk_position,
		&mut app_state.currently_selected_disk_position,
	);

	let sliced_vec: Vec<Vec<String>> = (&disk_data[start_position as usize..]).to_vec();
	let mut disk_counter = 0;

	let disk_rows = sliced_vec.iter().map(|disk| {
		Row::StyledData(
			disk.iter(),
			match app_state.current_application_position {
				app::ApplicationPosition::Disk => {
					if disk_counter == app_state.currently_selected_disk_position - start_position {
						disk_counter = -1;
						Style::default().fg(Color::Black).bg(Color::Cyan)
					} else {
						if disk_counter >= 0 {
							disk_counter += 1;
						}
						Style::default().fg(TEXT_COLOUR)
					}
				}
				_ => Style::default().fg(TEXT_COLOUR),
			},
		)
	});

	Table::new(["Disk", "Mount", "Used", "Total", "Free", "R/s", "W/s"].iter(), disk_rows)
		.block(
			Block::default()
				.title("Disk")
				.borders(Borders::ALL)
				.border_style(match app_state.current_application_position {
					app::ApplicationPosition::Disk => *CANVAS_HIGHLIGHTED_BORDER_STYLE,
					_ => *CANVAS_BORDER_STYLE,
				}),
		)
		.header_style(Style::default().fg(Color::LightBlue).modifier(Modifier::BOLD))
		.widths(&[
			Constraint::Percentage(18),
			Constraint::Percentage(14),
			Constraint::Percentage(11),
			Constraint::Percentage(11),
			Constraint::Percentage(11),
			Constraint::Percentage(11),
			Constraint::Percentage(11),
			Constraint::Percentage(11),
		])
		.render(f, draw_loc);
}

fn draw_processes_table<B: backend::Backend>(f: &mut Frame<B>, app_state: &mut app::App, draw_loc: Rect) {
	let process_data: &[ConvertedProcessData] = &(app_state.canvas_data.process_data);

	// Admittedly this is kinda a hack... but we need to:
	// * Scroll
	// * Show/hide elements based on scroll position
	// As such, we use a process_counter to know when we've hit the process we've currently scrolled to.  We also need to move the list - we can
	// do so by hiding some elements!
	let num_rows = i64::from(draw_loc.height) - 4;

	let start_position = get_start_position(
		num_rows,
		&(app_state.scroll_direction),
		&mut app_state.previous_process_position,
		&mut app_state.currently_selected_process_position,
	);

	let sliced_vec: Vec<ConvertedProcessData> = (&process_data[start_position as usize..]).to_vec();
	let mut process_counter = 0;

	let process_rows = sliced_vec.iter().map(|process| {
		let stringified_process_vec: Vec<String> = vec![
			process.pid.to_string(),
			process.name.clone(),
			process.cpu_usage.clone(),
			process.mem_usage.clone(),
		];
		Row::StyledData(
			stringified_process_vec.into_iter(),
			match app_state.current_application_position {
				app::ApplicationPosition::Process => {
					if process_counter == app_state.currently_selected_process_position - start_position {
						process_counter = -1;
						Style::default().fg(Color::Black).bg(Color::Cyan)
					} else {
						if process_counter >= 0 {
							process_counter += 1;
						}
						Style::default().fg(TEXT_COLOUR)
					}
				}
				_ => Style::default().fg(TEXT_COLOUR),
			},
		)
	});

	{
		use app::data_collection::processes::ProcessSorting;
		let mut pid = "PID(p)".to_string();
		let mut name = "Name(n)".to_string();
		let mut cpu = "CPU%(c)".to_string();
		let mut mem = "Mem%(m)".to_string();

		let direction_val = if app_state.process_sorting_reverse {
			"⯆".to_string()
		} else {
			"⯅".to_string()
		};

		match app_state.process_sorting_type {
			ProcessSorting::CPU => cpu += &direction_val,
			ProcessSorting::MEM => mem += &direction_val,
			ProcessSorting::PID => pid += &direction_val,
			ProcessSorting::NAME => name += &direction_val,
		};

		Table::new([pid, name, cpu, mem].iter(), process_rows)
			.block(
				Block::default()
					.title("Processes")
					.borders(Borders::ALL)
					.border_style(match app_state.current_application_position {
						app::ApplicationPosition::Process => *CANVAS_HIGHLIGHTED_BORDER_STYLE,
						_ => *CANVAS_BORDER_STYLE,
					}),
			)
			.header_style(Style::default().fg(Color::LightBlue))
			.widths(&[
				Constraint::Percentage(20),
				Constraint::Percentage(35),
				Constraint::Percentage(20),
				Constraint::Percentage(20),
			])
			.render(f, draw_loc);
	}
}

fn get_start_position(
	num_rows: i64, scroll_direction: &app::ScrollDirection, previous_position: &mut i64, currently_selected_position: &mut i64,
) -> i64 {
	match scroll_direction {
		app::ScrollDirection::DOWN => {
			if *currently_selected_position < num_rows {
				0
			} else if *currently_selected_position - num_rows < *previous_position {
				*previous_position
			} else {
				*previous_position = *currently_selected_position - num_rows + 1;
				*previous_position
			}
		}
		app::ScrollDirection::UP => {
			if *currently_selected_position == 0 {
				*previous_position = 0;
				return *previous_position;
			}

			if *currently_selected_position == *previous_position - 1 {
				*previous_position = if *previous_position > 0 { *previous_position - 1 } else { 0 };
				*previous_position
			} else {
				*previous_position
			}
		}
	}
}