LycacraftMaps/src/editor.py

import os
from enum import Enum, auto
from math import floor
from typing import Optional

import platformdirs
import pygame

from src.image_handler import ImageHandler
from src.graph.graph import Graph


class Editor:
    WIDTH: int = 800
    HEIGHT: int = 600
    MAP_SIZE: int = 1024
    MAPS_DIR: str = os.path.join(platformdirs.user_cache_dir(appname="lycacraft-paths", appauthor="Lycacraft"), "maps")
    ZOOMS: tuple[float] = (0.25, 0.5, 1, 2, 4)
    CROSSHAIR_SIZE: int = 10

    def __init__(self):
        pygame.init()
        self.width: int = self.WIDTH
        self.height: int = self.HEIGHT
        self.win: pygame.Surface = pygame.display.set_mode([self.width, self.height], pygame.RESIZABLE)
        pygame.display.set_caption("Lycacraft Map Editor")
        self.center: list[int] = [0, 0]
        self.zoom_i: int = 2
        self.zoom: float = self.ZOOMS[self.zoom_i]
        self.running: bool = False
        self.image_handler: ImageHandler = ImageHandler(self.MAPS_DIR, self.MAP_SIZE)
        self.clock: pygame.time.Clock = pygame.time.Clock()
        self.left_drag_pos: Optional[tuple[int, int]] = None
        self.mid_drag_pos: Optional[tuple[int, int]] = None
        self.font: pygame.font.Font = pygame.font.SysFont("Ubuntu", 20)
        self.loading_font: pygame.font.Font = pygame.font.SysFont("Ubuntu", 30)
        self.zooms_texts: list[pygame.Surface] = list(map(
            lambda z: self.font.render(str(z), True, (255, 255, 255)),
            self.ZOOMS
        ))
        self.is_creating_node: bool = False
        self.typing: bool = False
        self.state: State = State.STOPPING
        self.graph = Graph()
        self.typing_text: str = ""
        self.node_candidate_pos: tuple[int, int] = None
        self.node_radius: int = 10
        self.line_size: int = (int) (self.node_radius / 5)
        self.edge_detect_radius: int = 3 * self.line_size
        self.selected_nodes: list[int] = []
        self.selected_edges: list[int] = []
        self.previously_created_nodes: list[int] = []

    def mainloop(self) -> None:
        self.state = State.LOADING
        while self.state != State.STOPPING:
            pygame.display.set_caption(f"Lycacraft Map Editor - {self.clock.get_fps():.2f}fps")
            self.process_events()
            if self.state == State.LOADING:
                self.render_loading()
                if not self.image_handler.loading:
                    self.state = State.RUNNING
            elif self.state == State.RUNNING:
                self.render()
            self.clock.tick(30)

    def process_events(self) -> None:
        events = pygame.event.get()

        keys = pygame.key.get_pressed()
        for event in events:
            if event.type == pygame.QUIT:
                self.state = State.STOPPING
            elif event.type == pygame.WINDOWRESIZED:
                self.width = event.x
                self.height = event.y
            elif event.type == pygame.KEYDOWN:
                if self.typing:
                    if event.key == pygame.K_ESCAPE:
                        self.typing = False
                        self.is_creating_node = False
                        self.node_candidate_pos = None
                        self.typing_text = ""
                    elif event.key == pygame.K_RETURN:
                        self.create_node()
                    elif event.key == pygame.K_BACKSPACE:
                        self.typing_text = self.typing_text[:-1]
                    else:
                        self.typing_text += event.unicode
                else:
                    if event.key == pygame.K_ESCAPE:
                        if self.selected_nodes != [] or self.selected_edges != []:
                            self.clear_selection()
                            self.previously_created_nodes = []
                        else:
                            self.state = State.STOPPING
                    elif event.key == pygame.K_PAGEUP:
                        self.zoom_in()
                    elif event.key == pygame.K_PAGEDOWN:
                        self.zoom_out()
                    elif event.key == pygame.K_BACKSPACE:
                        self.deleted_selected_objects()
            elif event.type == pygame.MOUSEBUTTONDOWN:
                if event.button == 2:
                    self.mid_drag_pos = event.pos
                elif event.button == 1:
                    if keys[pygame.K_LCTRL]:
                        self.left_drag_pos = event.pos
                    else:
                        self.select_object(keys[pygame.K_LSHIFT] or keys[pygame.K_RSHIFT])
                elif event.button == 3:
                    self.node_candidate_pos = self.screen_to_world(event.pos[0], event.pos[1])
                    self.is_creating_node = True
                    self.typing = True
                elif event.button == 4:
                    self.zoom_in()
                elif event.button == 5:
                    self.zoom_out()
            elif event.type == pygame.MOUSEBUTTONUP:
                if event.button == 2:
                    self.mid_drag_pos = None
                elif event.button == 1:
                    self.left_drag_pos = None

        if keys[pygame.K_LEFT]:
            self.center[0] -= 4 / self.zoom
        if keys[pygame.K_RIGHT]:
            self.center[0] += 4 / self.zoom
        if keys[pygame.K_UP]:
            self.center[1] -= 4 / self.zoom
        if keys[pygame.K_DOWN]:
            self.center[1] += 4 / self.zoom

        mbtns = pygame.mouse.get_pressed()
        mpos = pygame.mouse.get_pos()
        if mbtns[1] or (mbtns[0] and keys[pygame.K_LCTRL]):
            drag_pos = self.mid_drag_pos if mbtns[1] else self.left_drag_pos
            dx = mpos[0] - drag_pos[0]
            dy = mpos[1] - drag_pos[1]
            self.center[0] -= dx / self.zoom
            self.center[1] -= dy / self.zoom
            if mbtns[0] and keys[pygame.K_LCTRL]:
                self.left_drag_pos = mpos
            if mbtns[1]:
                self.mid_drag_pos = mpos

    def render(self) -> None:
        self.win.fill((0, 0, 0))
        off_x = (self.center[0] * self.zoom) % self.MAP_SIZE
        off_y = (self.center[1] * self.zoom) % self.MAP_SIZE

        w2 = self.width / 2
        h2 = self.height / 2

        # In game top-left / bottom-right corners
        x0 = floor(self.center[0] - w2 / self.zoom)
        y0 = floor(self.center[1] - h2 / self.zoom)
        x1 = floor(self.center[0] + w2 / self.zoom)
        y1 = floor(self.center[1] + h2 / self.zoom)

        # Top-left / bottom-right maps
        mx0 = floor(x0 * self.zoom / self.MAP_SIZE)
        my0 = floor(y0 * self.zoom / self.MAP_SIZE)
        mx1 = floor(x1 * self.zoom / self.MAP_SIZE)
        my1 = floor(y1 * self.zoom / self.MAP_SIZE)

        h_maps = mx1 - mx0 + 1
        v_maps = my1 - my0 + 1
        cx = floor(self.center[0] * self.zoom / self.MAP_SIZE)
        cy = floor(self.center[1] * self.zoom / self.MAP_SIZE)
        ox = w2 + (mx0 - cx) * self.MAP_SIZE - off_x
        oy = h2 + (my0 - cy) * self.MAP_SIZE - off_y

        for y in range(v_maps):
            for x in range(h_maps):
                map_image = self.image_handler.get_for_pos(mx0 + x, my0 + y, self.zoom)
                if map_image is None:
                    continue
                self.win.blit(map_image, [
                    ox + x * self.MAP_SIZE,
                    oy + y * self.MAP_SIZE
                ])

        self.render_graph()

        pygame.draw.line(self.win, (150, 150, 150), [w2 - self.CROSSHAIR_SIZE, h2], [w2 + self.CROSSHAIR_SIZE, h2])
        pygame.draw.line(self.win, (150, 150, 150), [w2, h2 - self.CROSSHAIR_SIZE], [w2, h2 + self.CROSSHAIR_SIZE])
        self.render_zoom_slider()

        mpos = pygame.mouse.get_pos()
        world_x, world_z = self.screen_to_world(*mpos)
        mouse_txt = self.font.render(f"x: {world_x} / z: {world_z}", True, (255, 255, 255))
        pygame.draw.rect(self.win, (80, 80, 80), [0, 0, mouse_txt.get_width() + 10, mouse_txt.get_height() + 10])
        self.win.blit(mouse_txt, [5, 5])

        if self.is_creating_node:
            self.render_node_creator()

        pygame.display.flip()

    def render_zoom_slider(self) -> None:
        zoom_height = self.height * 0.2
        zoom_h_margin = self.width * 0.02
        zoom_v_margin = self.height * 0.05
        zoom_x = self.width - zoom_h_margin
        zoom_y = self.height - zoom_v_margin - zoom_height
        zoom_space = zoom_height / 4
        zoom_r = zoom_space / 4
        zoom_width = max(s.get_width() for s in self.zooms_texts) + 2 * zoom_r + 5
        pygame.draw.rect(self.win, (80, 80, 80), [
            zoom_x + zoom_r - zoom_width - 5,
            zoom_y - zoom_r - 5,
            zoom_width + 10,
            zoom_height + 2 * zoom_r + 10
        ])
        pygame.draw.line(self.win, (255, 255, 255), [zoom_x, zoom_y], [zoom_x, zoom_y + zoom_height])
        for i, txt in enumerate(self.zooms_texts):
            y = zoom_y + zoom_height - i * zoom_space
            col = (255, 0, 0) if i == self.zoom_i else (255, 255, 255)
            pygame.draw.circle(self.win, col, [zoom_x, y], zoom_r)
            self.win.blit(txt, [zoom_x - txt.get_width() - zoom_r - 5, y - txt.get_height() / 2])

    def render_loading(self) -> None:
        self.win.fill((0, 0, 0))
        count = self.image_handler.count
        total = self.image_handler.total
        txt = self.loading_font.render(f"Loading maps - {count}/{total}", True, (255, 255, 255))

        width = self.width * 0.6
        height = self.height * 0.05
        w2 = self.width / 2
        h2 = self.height / 2
        x0 = w2 - width / 2
        y0 = h2 - height / 2
        loaded_width = 0 if total == 0 else width * count / total
        pygame.draw.rect(self.win, (160, 160, 160), [x0, y0, width, height])
        pygame.draw.rect(self.win, (90, 250, 90), [x0, y0, loaded_width, height])
        self.win.blit(txt, [w2 - txt.get_width() / 2, y0 - txt.get_height() - 5])

        pygame.display.flip()

    def render_node_creator(self) -> None:
        width = self.width / 2
        height = self.height / 2
        x0 = (self.width - width) / 2
        y0 = (self.height - height) / 2

        line_height = height / 6

        nc_txt = self.loading_font.render("NODE CREATOR", True, (255, 255, 255))
        name_txt = self.loading_font.render("Name:", True, (255, 255, 255))
        txt = self.loading_font.render(self.typing_text, True, (255, 255, 255))

        pygame.draw.rect(self.win, (0, 0, 0), [x0, y0, width, height])
        self.win.blit(nc_txt, [self.width / 2 - nc_txt.get_width() / 2, y0 + line_height])
        self.win.blit(name_txt, [self.width / 2 - name_txt.get_width() / 2, y0 + 3 * line_height])
        self.win.blit(txt, [self.width / 2 - txt.get_width() / 2, y0 + 4 * line_height])
    
    def render_graph(self) -> None:
        self.render_edges()

        hover_index, is_node = self.get_hover_object()
        if is_node:
            self.render_nodes()
            self.render_hover_node(hover_index)
        else:
            self.render_hover_edge(hover_index)
            self.render_nodes()

    def render_edges(self) -> None:
        for edge in self.graph.edges:
            node_1, node_2 = self.graph.get_edge_nodes(edge)
            color = (0, 255, 255) if edge.index in self.selected_edges else (255, 0, 0)
            pygame.draw.line(self.win, color, self.world_to_screen(node_1.x, node_1.z), self.world_to_screen(node_2.x, node_2.z), self.line_size)
    
    def render_nodes(self) -> None:
        for node in self.graph.nodes:
            blitpos = self.world_to_screen(node.x, node.z)
            pygame.draw.circle(self.win, (255, 0, 0), (blitpos[0], blitpos[1]), self.node_radius)
        for node_index in self.selected_nodes:
            node = self.graph.nodes[node_index]
            blitpos = self.world_to_screen(node.x, node.z)
            pygame.draw.circle(self.win, (0, 255, 255), (blitpos[0], blitpos[1]), self.node_radius)
    
    def render_hover_node(self, node_index):
        if node_index != -1:
            node = self.graph.nodes[node_index]
            txt = self.loading_font.render(node.name, True, (0, 0, 0))
            node_pos = self.world_to_screen(node.x, node.z)
            self.win.blit(txt, [node_pos[0] - txt.get_width(), node_pos[1] - txt.get_height()])
            pygame.draw.circle(self.win, (0, 0, 0), (node_pos[0], node_pos[1]), self.node_radius, self.line_size)
    
    def render_hover_edge(self, edge_index):
        if edge_index != -1:
            node_1, node_2 = self.graph.get_edge_nodes(self.graph.edges[edge_index])
            pygame.draw.line(self.win, (0, 0, 0), self.world_to_screen(node_1.x, node_1.z), self.world_to_screen(node_2.x, node_2.z), self.edge_detect_radius)
            color = (0, 255, 255) if edge_index in self.selected_edges else (255, 0, 0)
            pygame.draw.line(self.win, color, self.world_to_screen(node_1.x, node_1.z), self.world_to_screen(node_2.x, node_2.z), self.line_size)

    def set_zoom(self, zoom_i: int) -> None:
        self.zoom_i = max(0, min(len(self.ZOOMS) - 1, zoom_i))
        self.zoom = self.ZOOMS[self.zoom_i]

    def zoom_in(self) -> None:
        self.set_zoom(self.zoom_i + 1)

    def zoom_out(self) -> None:
        self.set_zoom(self.zoom_i - 1)

    def screen_to_world(self, x: int, y: int) -> tuple[int, int]:
        w2 = self.width / 2
        h2 = self.height / 2
        world_x = floor((x - w2) / self.zoom + self.center[0])
        world_z = floor((y - h2) / self.zoom + self.center[1])

        return int(world_x), int(world_z)
    
    def world_to_screen(self, world_x: int, world_z: int) -> tuple[int, int]:
        w2 = self.width / 2
        h2 = self.height / 2
        screen_x = (world_x - self.center[0]) * self.zoom + w2
        screen_y = (world_z - self.center[1]) * self.zoom + h2

        return int(screen_x), int(screen_y)
    
    def select_object(self, shifting: bool = False) -> None:
        hover_index, is_node = self.get_hover_object()
        
        self.previously_created_nodes = []

        if is_node:
            self.select_node(hover_index, shifting)
        elif hover_index != -1:
            self.select_edge(hover_index, shifting)
        else:
            self.clear_selection()
    
    def select_node(self, node: int, shifting: bool = False) -> None:
        if shifting:
            if node in self.selected_nodes:
                self.selected_nodes.remove(node)
                return
            if node != -1:
                self.selected_nodes.append(node)
            return
        
        if node in self.selected_nodes:
            self.clear_selection()
            self.selected_nodes.append(node)
            return
        
        if node != -1:
            for sel_node in self.selected_nodes:
                self.link_nodes(sel_node, node)
        self.selected_nodes = [] if node == -1 else [node]
        self.selected_edges = []

    def select_edge(self, edge: int, shifting: bool = False) -> None:
        if shifting:
            if edge in self.selected_edges:
                self.selected_edges.remove(edge)
                return
            if edge != -1:
                self.selected_edges.append(edge)
            return
        
        if edge in self.selected_edges:
            self.clear_selection()
            self.selected_edges.append(edge)
            return
        self.selected_edges = [] if edge == -1 else [edge]
        self.selected_nodes = []
    
    def link_nodes(self, node_1: int, node_2: int) -> None:
        if not self.graph.edge_exists(node_1, node_2):
            self.create_edge(node_1, node_2)
    
    def clear_selection(self) -> None:
        self.selected_nodes = []
        self.selected_edges = []
    
    def create_node(self) -> None:
        self.graph.add_node(self.node_candidate_pos[0], self.node_candidate_pos[1], self.typing_text)
        self.typing_text = ""
        self.node_candidate_pos = None
        self.typing = False
        self.is_creating_node = False
        if len(self.selected_nodes) == 1:
            self.previously_created_nodes.append(self.selected_nodes[0])
        self.select_node(self.graph.number_of_nodes() - 1)
    
    def create_edge(self, node_1: int, node_2: int):
        n1 = self.graph.nodes[node_1]
        n2 = self.graph.nodes[node_2]
        self.graph.add_edge(node_1, node_2, ((n1.x - n2.x) ** 2 + (n1.z - n2.z) ** 2) ** 0.5)
    
    def get_hovering_nodes(self) -> tuple[list[int], list[float]]:
        hovering = []
        dists = []
        mouse_pos = pygame.mouse.get_pos()

        for node in self.graph.nodes:
            dist = self.get_node_distance(node.index, mouse_pos[0], mouse_pos[1])
            if dist < self.node_radius:
                hovering.append(node.index)
                dists.append(dist)
        
        return hovering, dists
    
    def get_hover_node(self) -> int:
        hover_nodes, distances = self.get_hovering_nodes()
        return -1 if len(hover_nodes) == 0 else hover_nodes[distances.index(min(distances))]
    
    def get_hovering_edges(self) -> tuple[list[int], list[float]]:
        hovering = []
        dists = []
        mouse_pos = pygame.mouse.get_pos()

        for edge in self.graph.edges:
            dist = self.get_edge_distance(edge.index, mouse_pos[0], mouse_pos[1])
            if dist < self.edge_detect_radius:
                hovering.append(edge.index)
                dists.append(dist)
        
        return hovering, dists
    
    def get_hover_edge(self) -> int:
        hover_edges, distances = self.get_hovering_edges()
        return -1 if len(hover_edges) == 0 else hover_edges[distances.index(min(distances))]
    
    def get_hover_object(self) -> tuple[int, bool]:
        node = self.get_hover_node()
        if node != -1:
            return node, True
        
        edge = self.get_hover_edge()
        if edge != -1:
            return edge, False
        
        return -1, False
    
    def get_edge_distance(self, edge_i: int, px: int, pz: int) -> float:
        start_n, end_n = self.graph.get_edge_nodes(self.graph.edges[edge_i])
        start_p = self.world_to_screen(start_n.x, start_n.z)
        end_p = self.world_to_screen(end_n.x, end_n.z)
        
        edge_vec = (end_p[0] - start_p[0], end_p[1] - start_p[1])
        start_vec = (px - start_p[0], pz - start_p[1])

        edge_vec_len = (edge_vec[0] ** 2 + edge_vec[1] ** 2) ** 0.5

        if edge_vec_len == 0:
            return self.get_node_distance(start_n.index, px, pz)

        scal_prod = start_vec[0] * edge_vec[0] + start_vec[1] * edge_vec[1]

        proj_len = scal_prod / edge_vec_len

        if proj_len < 0:
            return self.get_node_distance(start_n.index, px, pz)
        if proj_len > edge_vec_len:
            return self.get_node_distance(end_n.index, px, pz)
        return abs((edge_vec[0] * start_vec[1] - edge_vec[1] * start_vec[0]) / edge_vec_len)

    def get_node_distance(self, node_i: int, px: int, pz: int) -> float:
        node = self.graph.nodes[node_i]
        node_pos = self.world_to_screen(node.x, node.z)
        return ((px - node_pos[0]) ** 2 + (pz - node_pos[1]) ** 2) ** 0.5
    
    def deleted_selected_objects(self):
        edges_to_delete = [self.graph.edges[i] for i in self.selected_edges]
        nodes_to_delete = [self.graph.nodes[i] for i in self.selected_nodes]
        for edge in edges_to_delete:
            self.graph.delete_edge(edge)
        for node in nodes_to_delete:
            self.graph.delete_node(node)
        self.clear_selection()
        n = len(self.previously_created_nodes)
        if n != 0:
            self.selected_nodes.append(self.previously_created_nodes[n - 1])
            self.previously_created_nodes.pop()







class State(Enum):
    STOPPING = auto()
    LOADING = auto()
    RUNNING = auto()
    CREATING_NODE = auto()