refactor: convert indentation to tabs

addons/easy_charts/LineChart2D/LineChart2D.gd

@@ -116,547 +116,547 @@ var templates: Dictionary = {}
 
 
 func _point_plotted():
-    pass
+	pass
 
 
 func _ready():
-    _get_children()
+	_get_children()
 
 
 func _get_children():
-    OutlinesTween = $OutlinesTween
-    FunctionsTween = $FunctionsTween
-    Functions = $Functions
-    GridTween = $GridTween
-    PointData = $PointData/PointData
-    Outlines = $Outlines
-    Grid = $Grid
+	OutlinesTween = $OutlinesTween
+	FunctionsTween = $FunctionsTween
+	Functions = $Functions
+	GridTween = $GridTween
+	PointData = $PointData/PointData
+	Outlines = $Outlines
+	Grid = $Grid
 
 
 func _set_size(size: Vector2):
-    SIZE = size
-    build_chart()
-    if Engine.editor_hint:
-        _get_children()
-        Outlines.set_point_position(0, Vector2(origin.x, 0))
-        Outlines.set_point_position(1, Vector2(SIZE.x, 0))
-        Outlines.set_point_position(2, Vector2(SIZE.x, origin.y))
-        Outlines.set_point_position(3, origin)
-        Outlines.set_point_position(4, Vector2(origin.x, 0))
+	SIZE = size
+	build_chart()
+	if Engine.editor_hint:
+		_get_children()
+		Outlines.set_point_position(0, Vector2(origin.x, 0))
+		Outlines.set_point_position(1, Vector2(SIZE.x, 0))
+		Outlines.set_point_position(2, Vector2(SIZE.x, origin.y))
+		Outlines.set_point_position(3, origin)
+		Outlines.set_point_position(4, Vector2(origin.x, 0))
 
-        Grid.get_node("VLine").set_point_position(0, Vector2((OFFSET.x + SIZE.x) / 2,0))
-        Grid.get_node("VLine").set_point_position(1, Vector2((OFFSET.x + SIZE.x) / 2, origin.y))
-        Grid.get_node("HLine").set_point_position(0, Vector2(origin.x, origin.y / 2))
-        Grid.get_node("HLine").set_point_position(1, Vector2(SIZE.x, origin.y / 2))
+		Grid.get_node("VLine").set_point_position(0, Vector2((OFFSET.x + SIZE.x) / 2,0))
+		Grid.get_node("VLine").set_point_position(1, Vector2((OFFSET.x + SIZE.x) / 2, origin.y))
+		Grid.get_node("HLine").set_point_position(0, Vector2(origin.x, origin.y / 2))
+		Grid.get_node("HLine").set_point_position(1, Vector2(SIZE.x, origin.y / 2))
 
 
 func clear():
-    Outlines.points = []
-    Grid.get_node("HLine").queue_free()
-    Grid.get_node("VLine").queue_free()
+	Outlines.points = []
+	Grid.get_node("HLine").queue_free()
+	Grid.get_node("VLine").queue_free()
 
 
 func load_font():
-    if font != null:
-        font_size = font.get_height()
-        var theme: Theme = Theme.new()
-        theme.set_default_font(font)
-        PointData.set_theme(theme)
-    else:
-        var lbl = Label.new()
-        font = lbl.get_font("")
-        lbl.free()
-    if bold_font != null:
-        PointData.Data.set("custom_fonts/font",bold_font)
+	if font != null:
+		font_size = font.get_height()
+		var theme: Theme = Theme.new()
+		theme.set_default_font(font)
+		PointData.set_theme(theme)
+	else:
+		var lbl = Label.new()
+		font = lbl.get_font("")
+		lbl.free()
+	if bold_font != null:
+		PointData.Data.set("custom_fonts/font",bold_font)
 
 
 func _plot(source: String, delimiter: String, are_values_columns: bool, x_values_index: int):
-    randomize()
+	randomize()
 
-    clear()
+	clear()
 
-    load_font()
-    PointData.hide()
+	load_font()
+	PointData.hide()
 
-    datas = read_datas(source, delimiter)
-    count_functions()
-    structure_datas(datas, are_values_columns, x_values_index)
-    build_chart()
-    calculate_pass()
-    calculate_coordinates()
-    calculate_colors()
-    draw_chart()
+	datas = read_datas(source, delimiter)
+	count_functions()
+	structure_datas(datas, are_values_columns, x_values_index)
+	build_chart()
+	calculate_pass()
+	calculate_coordinates()
+	calculate_colors()
+	draw_chart()
 
-    create_legend()
-    emit_signal("chart_plotted", self)
+	create_legend()
+	emit_signal("chart_plotted", self)
 
 
 func plot():
-    randomize()
+	randomize()
 
-    clear()
+	clear()
 
-    load_font()
-    PointData.hide()
+	load_font()
+	PointData.hide()
 
-    if source == "" or source == null:
-        Utilities._print_message("Can't plot a chart without a Source file. Please, choose it in editor, or use the custom function _plot().", 1)
-        return
-    datas = read_datas(source,delimiter)
-    count_functions()
-    structure_datas(datas, are_values_columns, x_values_index)
-    build_chart()
-    calculate_pass()
-    calculate_coordinates()
-    calculate_colors()
-    draw_chart()
+	if source == "" or source == null:
+		Utilities._print_message("Can't plot a chart without a Source file. Please, choose it in editor, or use the custom function _plot().", 1)
+		return
+	datas = read_datas(source,delimiter)
+	count_functions()
+	structure_datas(datas, are_values_columns, x_values_index)
+	build_chart()
+	calculate_pass()
+	calculate_coordinates()
+	calculate_colors()
+	draw_chart()
 
-    create_legend()
-    emit_signal("chart_plotted", self)
+	create_legend()
+	emit_signal("chart_plotted", self)
 
 
 func calculate_colors():
-    if function_colors.empty() or function_colors.size() < functions:
-        for function in functions:
-            function_colors.append(Color("#1e1e1e"))
+	if function_colors.empty() or function_colors.size() < functions:
+		for function in functions:
+			function_colors.append(Color("#1e1e1e"))
 
 
 func draw_chart():
-    draw_outlines()
-    draw_v_grid()
-    draw_h_grid()
-    draw_functions()
+	draw_outlines()
+	draw_v_grid()
+	draw_h_grid()
+	draw_functions()
 
 
 func draw_outlines():
-    if boxed:
-        Outlines.set_default_color(box_color)
-        OutlinesTween.interpolate_method(
-                Outlines,
-                "add_point",
-                Vector2(origin.x, 0),
-                Vector2(SIZE.x, 0),
-                drawing_duration * 0.5,
-                Tween.TRANS_QUINT,
-                Tween.EASE_OUT)
-        OutlinesTween.start()
-        yield(OutlinesTween, "tween_all_completed")
-        OutlinesTween.interpolate_method(
-                Outlines,
-                "add_point",
-                Vector2(SIZE.x, 0),
-                Vector2(SIZE.x, origin.y),
-                drawing_duration * 0.5,
-                Tween.TRANS_QUINT,
-                Tween.EASE_OUT)
-        OutlinesTween.start()
-        yield(OutlinesTween, "tween_all_completed")
+	if boxed:
+		Outlines.set_default_color(box_color)
+		OutlinesTween.interpolate_method(
+				Outlines,
+				"add_point",
+				Vector2(origin.x, 0),
+				Vector2(SIZE.x, 0),
+				drawing_duration * 0.5,
+				Tween.TRANS_QUINT,
+				Tween.EASE_OUT)
+		OutlinesTween.start()
+		yield(OutlinesTween, "tween_all_completed")
+		OutlinesTween.interpolate_method(
+				Outlines,
+				"add_point",
+				Vector2(SIZE.x, 0),
+				Vector2(SIZE.x, origin.y),
+				drawing_duration * 0.5,
+				Tween.TRANS_QUINT,
+				Tween.EASE_OUT)
+		OutlinesTween.start()
+		yield(OutlinesTween, "tween_all_completed")
 
-    OutlinesTween.interpolate_method(
-            Outlines,
-            "add_point",
-            Vector2(SIZE.x, origin.y),
-            origin,
-            drawing_duration * 0.5,
-            Tween.TRANS_QUINT,
-            Tween.EASE_OUT)
-    OutlinesTween.start()
-    yield(OutlinesTween, "tween_all_completed")
-    OutlinesTween.interpolate_method(
-            Outlines,
-            "add_point",
-            origin,
-            Vector2(origin.x, 0),
-            drawing_duration * 0.5,
-            Tween.TRANS_QUINT,
-            Tween.EASE_OUT)
-    OutlinesTween.start()
-    yield(OutlinesTween, "tween_all_completed")
+	OutlinesTween.interpolate_method(
+			Outlines,
+			"add_point",
+			Vector2(SIZE.x, origin.y),
+			origin,
+			drawing_duration * 0.5,
+			Tween.TRANS_QUINT,
+			Tween.EASE_OUT)
+	OutlinesTween.start()
+	yield(OutlinesTween, "tween_all_completed")
+	OutlinesTween.interpolate_method(
+			Outlines,
+			"add_point",
+			origin,
+			Vector2(origin.x, 0),
+			drawing_duration * 0.5,
+			Tween.TRANS_QUINT,
+			Tween.EASE_OUT)
+	OutlinesTween.start()
+	yield(OutlinesTween, "tween_all_completed")
 
 
 func draw_v_grid():
-    for p in x_chors.size():
-        var point: Vector2 = origin + Vector2((p) * x_pass, 0)
-        var v_grid: Line2D = Line2D.new()
-        Grid.add_child(v_grid)
-        v_grid.set_width(1)
-        v_grid.set_default_color(v_lines_color)
-        add_label(point + Vector2(-const_width / 2 * x_chors[p].length(), font_size / 2), x_chors[p])
-        GridTween.interpolate_method(
-                v_grid,
-                "add_point",
-                point,
-                point - Vector2(0, SIZE.y - OFFSET.y),
-                drawing_duration / (x_chors.size()),
-                Tween.TRANS_EXPO,
-                Tween.EASE_OUT)
-        GridTween.start()
-        yield(GridTween,"tween_all_completed")
+	for p in x_chors.size():
+		var point: Vector2 = origin + Vector2((p) * x_pass, 0)
+		var v_grid: Line2D = Line2D.new()
+		Grid.add_child(v_grid)
+		v_grid.set_width(1)
+		v_grid.set_default_color(v_lines_color)
+		add_label(point + Vector2(-const_width / 2 * x_chors[p].length(), font_size / 2), x_chors[p])
+		GridTween.interpolate_method(
+				v_grid,
+				"add_point",
+				point,
+				point - Vector2(0, SIZE.y - OFFSET.y),
+				drawing_duration / (x_chors.size()),
+				Tween.TRANS_EXPO,
+				Tween.EASE_OUT)
+		GridTween.start()
+		yield(GridTween, "tween_all_completed")
 
 
 func draw_h_grid():
-    for p in y_chors.size():
-        var point: Vector2 = origin - Vector2(0, p * y_pass)
-        var h_grid: Line2D = Line2D.new()
-        Grid.add_child(h_grid)
-        h_grid.set_width(1)
-        h_grid.set_default_color(h_lines_color)
-        add_label(point - Vector2(y_chors[p].length() * const_width + font_size, font_size / 2), y_chors[p])
-        GridTween.interpolate_method(
-                h_grid,
-                "add_point",
-                point,
-                Vector2(SIZE.x, point.y),
-                drawing_duration / (y_chors.size()),
-                Tween.TRANS_EXPO,
-                Tween.EASE_OUT)
-        GridTween.start()
-        yield(GridTween,"tween_all_completed")
+	for p in y_chors.size():
+		var point: Vector2 = origin - Vector2(0, p * y_pass)
+		var h_grid: Line2D = Line2D.new()
+		Grid.add_child(h_grid)
+		h_grid.set_width(1)
+		h_grid.set_default_color(h_lines_color)
+		add_label(point - Vector2(y_chors[p].length() * const_width + font_size, font_size / 2), y_chors[p])
+		GridTween.interpolate_method(
+				h_grid,
+				"add_point",
+				point,
+				Vector2(SIZE.x, point.y),
+				drawing_duration / (y_chors.size()),
+				Tween.TRANS_EXPO,
+				Tween.EASE_OUT)
+		GridTween.start()
+		yield(GridTween, "tween_all_completed")
 
 
 func add_label(point: Vector2, text: String):
-        var lbl: Label = Label.new()
-        if font != null:
-            lbl.set("custom_fonts/font", font)
-        lbl.set("custom_colors/font_color", font_color)
-        Grid.add_child(lbl)
-        lbl.rect_position = point
-        lbl.set_text(text)
+		var lbl: Label = Label.new()
+		if font != null:
+			lbl.set("custom_fonts/font", font)
+		lbl.set("custom_colors/font_color", font_color)
+		Grid.add_child(lbl)
+		lbl.rect_position = point
+		lbl.set_text(text)
 
 
 func draw_functions():
-    for function in point_positions.size():
-        draw_function(function, point_positions[function])
+	for function in point_positions.size():
+		draw_function(function, point_positions[function])
 
 
 func draw_function(f_index: int, function: Array):
-    var line: Line2D = Line2D.new()
-    var backline: Line2D = Line2D.new()
-    construct_line(line, backline, f_index, function)
-    var pointv: Point
-    for point in function.size():
-        pointv = point_node.instance()
-        Functions.add_child(pointv)
-        pointv.connect("_mouse_entered", self, "show_data")
-        pointv.connect("_mouse_exited", self, "hide_data")
-        pointv.connect("_point_pressed", self, "point_pressed")
-        pointv.create_point(
-                point_shape,
-                function_colors[f_index],
-                Color.white, function[point],
-                pointv.format_value(point_values[f_index][point], false, false),
-                y_labels[point if invert_chart else f_index] as String)
-        if point < function.size() - 1:
-            FunctionsTween.interpolate_method(
-                    line,
-                    "add_point",
-                    function[point],
-                    function[point + 1],
-                    drawing_duration / function.size(),
-                    Tween.TRANS_QUINT,
-                    Tween.EASE_OUT)
-            FunctionsTween.start()
-            yield(FunctionsTween, "tween_all_completed")
+	var line: Line2D = Line2D.new()
+	var backline: Line2D = Line2D.new()
+	construct_line(line, backline, f_index, function)
+	var pointv: Point
+	for point in function.size():
+		pointv = point_node.instance()
+		Functions.add_child(pointv)
+		pointv.connect("_mouse_entered", self, "show_data")
+		pointv.connect("_mouse_exited", self, "hide_data")
+		pointv.connect("_point_pressed", self, "point_pressed")
+		pointv.create_point(
+				point_shape,
+				function_colors[f_index],
+				Color.white, function[point],
+				pointv.format_value(point_values[f_index][point], false, false),
+				y_labels[point if invert_chart else f_index] as String)
+		if point < function.size() - 1:
+			FunctionsTween.interpolate_method(
+					line,
+					"add_point",
+					function[point],
+					function[point + 1],
+					drawing_duration / function.size(),
+					Tween.TRANS_QUINT,
+					Tween.EASE_OUT)
+			FunctionsTween.start()
+			yield(FunctionsTween, "tween_all_completed")
 
 
 func construct_line(line: Line2D, backline: Line2D, f_index: int, function: Array):
-    var midtone = Color(
-            Color(function_colors[f_index]).r,
-            Color(function_colors[f_index]).g,
-            Color(function_colors[f_index]).b,
-            Color(function_colors[f_index]).a / 2)
-    backline.set_width(3)
-    backline.set_default_color(midtone)
-    backline.antialiased = true
-    Functions.add_child(backline)
-    line.set_width(2)
-    line.set_default_color(function_colors[f_index])
-    line.antialiased = true
-    Functions.add_child(line)
+	var midtone = Color(
+			Color(function_colors[f_index]).r,
+			Color(function_colors[f_index]).g,
+			Color(function_colors[f_index]).b,
+			Color(function_colors[f_index]).a / 2)
+	backline.set_width(3)
+	backline.set_default_color(midtone)
+	backline.antialiased = true
+	Functions.add_child(backline)
+	line.set_width(2)
+	line.set_default_color(function_colors[f_index])
+	line.antialiased = true
+	Functions.add_child(line)
 
 
 func read_datas(source: String, delimiter: String):
-    var file: File = File.new()
-    file.open(source, File.READ)
-    var content: Array
-    while not file.eof_reached():
-        var line: PoolStringArray = file.get_csv_line(delimiter)
-        content.append(line)
-    file.close()
-    for data in content:
-        if data.size() < 2:
-            content.erase(data)
-    return content
+	var file: File = File.new()
+	file.open(source, File.READ)
+	var content: Array
+	while not file.eof_reached():
+		var line: PoolStringArray = file.get_csv_line(delimiter)
+		content.append(line)
+	file.close()
+	for data in content:
+		if data.size() < 2:
+			content.erase(data)
+	return content
 
 
 func structure_datas(database: Array, are_values_columns: bool, x_values_index: int):
-    # @x_values_index can be either a column or a row relative to x values
-    # @y_values can be either a column or a row relative to y values
-    self.are_values_columns = are_values_columns
-    match are_values_columns:
-        true:
-            for row in database.size():
-                var t_vals: Array
-                for column in database[row].size():
-                    if column == x_values_index:
-                        var x_data = database[row][column]
-                        if x_data.is_valid_float() or x_data.is_valid_integer():
-                            x_datas.append(x_data as float)
-                        else:
-                            x_datas.append(x_data.replace(",", ".") as float)
-                    else:
-                        if row != 0:
-                            var y_data = database[row][column]
-                            if y_data.is_valid_float() or y_data.is_valid_integer():
-                                t_vals.append(y_data as float)
-                            else:
-                                t_vals.append(y_data.replace(",", ".") as float)
-                        else:
-                            y_labels.append(str(database[row][column]))
-                if not t_vals.empty():
-                    y_datas.append(t_vals)
-            x_label = str(x_datas.pop_front())
-        false:
-            for row in database.size():
-                if row == x_values_index:
-                    x_datas = (database[row])
-                    x_label = x_datas.pop_front() as String
-                else:
-                    var values = database[row] as Array
-                    y_labels.append(values.pop_front() as String)
-                    y_datas.append(values)
-            for data in y_datas:
-                for value in data.size():
-                    data[value] = data[value] as float
+	# @x_values_index can be either a column or a row relative to x values
+	# @y_values can be either a column or a row relative to y values
+	self.are_values_columns = are_values_columns
+	match are_values_columns:
+		true:
+			for row in database.size():
+				var t_vals: Array
+				for column in database[row].size():
+					if column == x_values_index:
+						var x_data = database[row][column]
+						if x_data.is_valid_float() or x_data.is_valid_integer():
+							x_datas.append(x_data as float)
+						else:
+							x_datas.append(x_data.replace(",", ".") as float)
+					else:
+						if row != 0:
+							var y_data = database[row][column]
+							if y_data.is_valid_float() or y_data.is_valid_integer():
+								t_vals.append(y_data as float)
+							else:
+								t_vals.append(y_data.replace(",", ".") as float)
+						else:
+							y_labels.append(str(database[row][column]))
+				if not t_vals.empty():
+					y_datas.append(t_vals)
+			x_label = str(x_datas.pop_front())
+		false:
+			for row in database.size():
+				if row == x_values_index:
+					x_datas = (database[row])
+					x_label = x_datas.pop_front() as String
+				else:
+					var values = database[row] as Array
+					y_labels.append(values.pop_front() as String)
+					y_datas.append(values)
+			for data in y_datas:
+				for value in data.size():
+					data[value] = data[value] as float
 
-    # draw y labels
-    var to_order: Array
-    var to_order_min: Array
-    for cluster in y_datas.size():
-        # define x_chors and y_chors
-        var ordered_cluster = y_datas[cluster] as Array
-        ordered_cluster.sort()
-        ordered_cluster = PoolIntArray(ordered_cluster)
-        var margin_max = ordered_cluster[ordered_cluster.size() - 1]
-        var margin_min = ordered_cluster[0]
-        to_order.append(margin_max)
-        to_order_min.append(margin_min)
+	# draw y labels
+	var to_order: Array
+	var to_order_min: Array
+	for cluster in y_datas.size():
+		# define x_chors and y_chors
+		var ordered_cluster = y_datas[cluster] as Array
+		ordered_cluster.sort()
+		ordered_cluster = PoolIntArray(ordered_cluster)
+		var margin_max = ordered_cluster[ordered_cluster.size() - 1]
+		var margin_min = ordered_cluster[0]
+		to_order.append(margin_max)
+		to_order_min.append(margin_min)
 
-    to_order.sort()
-    to_order_min.sort()
-    var margin = to_order.pop_back()
-    if not origin_at_zero:
-        y_margin_min = to_order_min.pop_front()
-    v_dist = y_decim * pow(10.0,str(margin).length() - 2)
-    var multi = 0
-    var p = (v_dist * multi) + (y_margin_min if not origin_at_zero else 0)
-    y_chors.append(p as String)
-    while p < margin:
-        multi+=1
-        p = (v_dist * multi) + (y_margin_min if not origin_at_zero else 0)
-        y_chors.append(p as String)
+	to_order.sort()
+	to_order_min.sort()
+	var margin = to_order.pop_back()
+	if not origin_at_zero:
+		y_margin_min = to_order_min.pop_front()
+	v_dist = y_decim * pow(10.0,str(margin).length() - 2)
+	var multi = 0
+	var p = (v_dist * multi) + (y_margin_min if not origin_at_zero else 0)
+	y_chors.append(p as String)
+	while p < margin:
+		multi+=1
+		p = (v_dist * multi) + (y_margin_min if not origin_at_zero else 0)
+		y_chors.append(p as String)
 
-    # draw x_labels
-    if not show_x_values_as_labels:
-        to_order.clear()
-        to_order = x_datas as PoolIntArray
+	# draw x_labels
+	if not show_x_values_as_labels:
+		to_order.clear()
+		to_order = x_datas as PoolIntArray
 
-        to_order.sort()
-        margin = to_order.pop_back()
-        if not origin_at_zero:
-            x_margin_min = to_order.pop_front()
-        h_dist = x_decim * pow(10.0, str(margin).length() - 2)
-        multi = 0
-        p = (h_dist * multi) + (x_margin_min if not origin_at_zero else 0)
-        x_labels.append(p as String)
-        while p < margin:
-            multi += 1
-            p = (h_dist * multi) + (x_margin_min if not origin_at_zero else 0)
-            x_labels.append(p as String)
+		to_order.sort()
+		margin = to_order.pop_back()
+		if not origin_at_zero:
+			x_margin_min = to_order.pop_front()
+		h_dist = x_decim * pow(10.0, str(margin).length() - 2)
+		multi = 0
+		p = (h_dist * multi) + (x_margin_min if not origin_at_zero else 0)
+		x_labels.append(p as String)
+		while p < margin:
+			multi += 1
+			p = (h_dist * multi) + (x_margin_min if not origin_at_zero else 0)
+			x_labels.append(p as String)
 
 
 func build_chart():
-    origin = Vector2(OFFSET.x, SIZE.y - OFFSET.y)
+	origin = Vector2(OFFSET.x, SIZE.y - OFFSET.y)
 
 
 func calculate_pass():
-    if invert_chart:
-        x_chors = y_labels as PoolStringArray
-    else:
-        if show_x_values_as_labels:
-            x_chors = x_datas as PoolStringArray
-        else:
-            x_chors = x_labels
+	if invert_chart:
+		x_chors = y_labels as PoolStringArray
+	else:
+		if show_x_values_as_labels:
+			x_chors = x_datas as PoolStringArray
+		else:
+			x_chors = x_labels
 
-    # calculate distance in pixel between 2 consecutive values/datas
-    x_pass = (SIZE.x - OFFSET.x) / (x_chors.size() - 1)
-    y_pass = origin.y / (y_chors.size() - 1)
+	# calculate distance in pixel between 2 consecutive values/datas
+	x_pass = (SIZE.x - OFFSET.x) / (x_chors.size() - 1)
+	y_pass = origin.y / (y_chors.size() - 1)
 
 
 func calculate_coordinates():
-    x_coordinates.clear()
-    y_coordinates.clear()
-    point_values.clear()
-    point_positions.clear()
+	x_coordinates.clear()
+	y_coordinates.clear()
+	point_values.clear()
+	point_positions.clear()
 
-    if invert_chart:
-        for column in y_datas[0].size():
-            var single_coordinates: Array
-            for row in y_datas:
-                if origin_at_zero:
-                    single_coordinates.append((row[column] * y_pass) / v_dist)
-                else:
-                    single_coordinates.append((row[column] - y_margin_min) * y_pass / v_dist)
-            y_coordinates.append(single_coordinates)
-    else:
-        for cluster in y_datas:
-            var single_coordinates: Array
-            for value in cluster.size():
-                if origin_at_zero:
-                    single_coordinates.append((cluster[value] * y_pass) / v_dist)
-                else:
-                    single_coordinates.append((cluster[value] - y_margin_min) * y_pass / v_dist)
-            y_coordinates.append(single_coordinates)
+	if invert_chart:
+		for column in y_datas[0].size():
+			var single_coordinates: Array
+			for row in y_datas:
+				if origin_at_zero:
+					single_coordinates.append((row[column] * y_pass) / v_dist)
+				else:
+					single_coordinates.append((row[column] - y_margin_min) * y_pass / v_dist)
+			y_coordinates.append(single_coordinates)
+	else:
+		for cluster in y_datas:
+			var single_coordinates: Array
+			for value in cluster.size():
+				if origin_at_zero:
+					single_coordinates.append((cluster[value] * y_pass) / v_dist)
+				else:
+					single_coordinates.append((cluster[value] - y_margin_min) * y_pass / v_dist)
+			y_coordinates.append(single_coordinates)
 
-    if show_x_values_as_labels:
-        for x in x_datas.size():
-            x_coordinates.append(x_pass * x)
-    else:
-        for x in x_datas.size():
-            if origin_at_zero:
-                if invert_chart:
-                    x_coordinates.append(x_pass * x)
-                else:
-                    x_coordinates.append(x_datas[x] * x_pass / h_dist)
-            else:
-                x_coordinates.append((x_datas[x] - x_margin_min) * x_pass / h_dist)
+	if show_x_values_as_labels:
+		for x in x_datas.size():
+			x_coordinates.append(x_pass * x)
+	else:
+		for x in x_datas.size():
+			if origin_at_zero:
+				if invert_chart:
+					x_coordinates.append(x_pass * x)
+				else:
+					x_coordinates.append(x_datas[x] * x_pass / h_dist)
+			else:
+				x_coordinates.append((x_datas[x] - x_margin_min) * x_pass / h_dist)
 
-    for f in functions:
-        point_values.append([])
-        point_positions.append([])
+	for f in functions:
+		point_values.append([])
+		point_positions.append([])
 
-    if invert_chart:
-        for function in y_coordinates.size():
-            for function_value in y_coordinates[function].size():
-                if are_values_columns:
-                    point_positions[function_value].append(Vector2(
-                            x_coordinates[function] + origin.x,
-                            origin.y - y_coordinates[function][function_value]))
-                    point_values[function_value].append(
-                            [x_datas[function_value], y_datas[function_value][function]])
-                else:
-                    point_positions[function].append(Vector2(
-                            x_coordinates[function_value] + origin.x,
-                            origin.y - y_coordinates[function][function_value]))
-                    point_values[function].append(
-                        [x_datas[function_value], y_datas[function_value][function]])
-    else:
-        for cluster in y_coordinates.size():
-            for y in y_coordinates[cluster].size():
-                if are_values_columns:
-                    point_values[y].append([x_datas[cluster],y_datas[cluster][y]])
-                    point_positions[y].append(Vector2(
-                        x_coordinates[cluster] + origin.x,
-                        origin.y - y_coordinates[cluster][y]))
-                else:
-                    point_values[cluster].append([x_datas[y],y_datas[cluster][y]])
-                    point_positions[cluster].append(Vector2(
-                        x_coordinates[y] + origin.x,
-                        origin.y - y_coordinates[cluster][y]))
+	if invert_chart:
+		for function in y_coordinates.size():
+			for function_value in y_coordinates[function].size():
+				if are_values_columns:
+					point_positions[function_value].append(Vector2(
+							x_coordinates[function] + origin.x,
+							origin.y - y_coordinates[function][function_value]))
+					point_values[function_value].append(
+							[x_datas[function_value], y_datas[function_value][function]])
+				else:
+					point_positions[function].append(Vector2(
+							x_coordinates[function_value] + origin.x,
+							origin.y - y_coordinates[function][function_value]))
+					point_values[function].append(
+						[x_datas[function_value], y_datas[function_value][function]])
+	else:
+		for cluster in y_coordinates.size():
+			for y in y_coordinates[cluster].size():
+				if are_values_columns:
+					point_values[y].append([x_datas[cluster],y_datas[cluster][y]])
+					point_positions[y].append(Vector2(
+						x_coordinates[cluster] + origin.x,
+						origin.y - y_coordinates[cluster][y]))
+				else:
+					point_values[cluster].append([x_datas[y],y_datas[cluster][y]])
+					point_positions[cluster].append(Vector2(
+						x_coordinates[y] + origin.x,
+						origin.y - y_coordinates[cluster][y]))
 
 
 func redraw():
-    build_chart()
-    calculate_pass()
-    calculate_coordinates()
-    update()
+	build_chart()
+	calculate_pass()
+	calculate_coordinates()
+	update()
 
 
 func show_data(point):
-    PointData.update_datas(point)
-    PointData.show()
+	PointData.update_datas(point)
+	PointData.show()
 
 
 func hide_data():
-    PointData.hide()
+	PointData.hide()
 
 
 func clear_points():
-    function_colors.clear()
-    if Functions.get_children():
-        for function in Functions.get_children():
-            function.queue_free()
+	function_colors.clear()
+	if Functions.get_children():
+		for function in Functions.get_children():
+			function.queue_free()
 
 
 func set_legend(l: Array):
-    legend = l
+	legend = l
 
 
 func get_legend():
-    return legend
+	return legend
 
 
 func invert_chart():
-    invert_chart = !invert_chart
-    count_functions()
-    redraw()
-    create_legend()
+	invert_chart = !invert_chart
+	count_functions()
+	redraw()
+	create_legend()
 
 
 func count_functions():
-    if are_values_columns:
-        if not invert_chart:
-            functions = datas[0].size() - 1
-        else:
-            functions = datas.size() - 1
-    else:
-        if invert_chart:
-            functions = datas[0].size() - 1
-        else:
-            functions = datas.size() - 1
+	if are_values_columns:
+		if not invert_chart:
+			functions = datas[0].size() - 1
+		else:
+			functions = datas.size() - 1
+	else:
+		if invert_chart:
+			functions = datas[0].size() - 1
+		else:
+			functions = datas.size() - 1
 
 
 func create_legend():
-    legend.clear()
-    for function in functions:
-        var function_legend = FunctionLegend.instance()
-        var f_name: String
-        if invert_chart:
-            f_name = x_datas[function] as String
-        else:
-            f_name = y_labels[function]
-        var legend_font: Font
-        if font != null:
-            legend_font = font
-        if bold_font != null:
-            legend_font = bold_font
-        function_legend.create_legend(f_name, function_colors[function], bold_font, font_color)
-        legend.append(function_legend)
+	legend.clear()
+	for function in functions:
+		var function_legend = FunctionLegend.instance()
+		var f_name: String
+		if invert_chart:
+			f_name = x_datas[function] as String
+		else:
+			f_name = y_labels[function]
+		var legend_font: Font
+		if font != null:
+			legend_font = font
+		if bold_font != null:
+			legend_font = bold_font
+		function_legend.create_legend(f_name, function_colors[function], bold_font, font_color)
+		legend.append(function_legend)
 
 
 func apply_template(template_name: int):
-    template = template_name
-    templates = Utilities._load_templates()
-    if template_name != null:
-        var custom_template = templates.get(templates.keys()[template_name])
-        function_colors = custom_template.function_colors as PoolColorArray
-        v_lines_color = Color(custom_template.v_lines_color)
-        h_lines_color = Color(custom_template.h_lines_color)
-        box_color = Color(custom_template.outline_color)
-        font_color = Color(custom_template.font_color)
-    property_list_changed_notify()
+	template = template_name
+	templates = Utilities._load_templates()
+	if template_name != null:
+		var custom_template = templates.get(templates.keys()[template_name])
+		function_colors = custom_template.function_colors as PoolColorArray
+		v_lines_color = Color(custom_template.v_lines_color)
+		h_lines_color = Color(custom_template.h_lines_color)
+		box_color = Color(custom_template.outline_color)
+		font_color = Color(custom_template.font_color)
+	property_list_changed_notify()
 
-    if Engine.editor_hint:
-        _get_children()
-        Outlines.set_default_color(box_color)
-        Grid.get_node("VLine").set_default_color(v_lines_color)
-        Grid.get_node("HLine").set_default_color(h_lines_color)
+	if Engine.editor_hint:
+		_get_children()
+		Outlines.set_default_color(box_color)
+		Grid.get_node("VLine").set_default_color(v_lines_color)
+		Grid.get_node("HLine").set_default_color(h_lines_color)
 
 
 func _enter_tree():
-    _ready()
+	_ready()
 
 
 # Signal Repeaters
 func point_pressed(point: Point) -> Point:
-    return point
+	return point