import { DIRECTIONS } from './defs.js'; import { mk } from './util.js'; import TILE_TYPES from './tiletypes.js'; export class CanvasRenderer { constructor(tileset, fixed_size = null) { this.tileset = tileset; // Default, unfortunately and arbitrarily, to the CC1 size of 9×9. We // don't know for sure what size to use until the Game loads a level, // and it doesn't do that until creating a renderer! It could be fixed // to do so, but then we wouldn't make a canvas so it couldn't be // hooked, yadda yadda if (fixed_size) { this.viewport_is_fixed = true; this.viewport_size_x = fixed_size; this.viewport_size_y = fixed_size; } else { this.viewport_size_x = 9; this.viewport_size_y = 9; } this.canvas = mk('canvas', {width: tileset.size_x * this.viewport_size_x, height: tileset.size_y * this.viewport_size_y}); this.canvas.style.setProperty('--viewport-width', this.viewport_size_x); this.canvas.style.setProperty('--viewport-height', this.viewport_size_y); this.ctx = this.canvas.getContext('2d'); this.viewport_x = 0; this.viewport_y = 0; this.use_rewind_effect = false; } set_level(level) { this.level = level; // TODO update viewport size... or maybe Game should do that since you might be cheating } cell_coords_from_event(ev) { let rect = this.canvas.getBoundingClientRect(); let scale_x = rect.width / this.canvas.width; let scale_y = rect.height / this.canvas.height; let x = Math.floor((ev.clientX - rect.x) / scale_x / this.tileset.size_x + this.viewport_x); let y = Math.floor((ev.clientY - rect.y) / scale_y / this.tileset.size_y + this.viewport_y); return [x, y]; } // Draw to a canvas using tile coordinates blit(ctx, sx, sy, dx, dy, w = 1, h = w) { let tw = this.tileset.size_x; let th = this.tileset.size_y; ctx.drawImage( this.tileset.image, sx * tw, sy * th, w * tw, h * th, dx * tw, dy * th, w * tw, h * th); } draw(tic_offset = 0) { if (! this.level) { console.warn("CanvasRenderer.draw: No level to render"); return; } // TODO StoredLevel may not have a tic_counter let tic = (this.level.tic_counter ?? 0) + tic_offset; let tw = this.tileset.size_x; let th = this.tileset.size_y; this.ctx.clearRect(0, 0, this.canvas.width, this.canvas.height); // TODO only recompute if the player moved? // TODO what about levels smaller than the viewport...? shrink the canvas in set_level? let xmargin = (this.viewport_size_x - 1) / 2; let ymargin = (this.viewport_size_y - 1) / 2; let px, py; // FIXME editor vs player if (this.level.player) { [px, py] = this.level.player.visual_position(tic_offset); } else { [px, py] = [0, 0]; } // Figure out where to start drawing let x0 = Math.max(0, Math.min(this.level.size_x - this.viewport_size_x, px - xmargin)); let y0 = Math.max(0, Math.min(this.level.size_y - this.viewport_size_y, py - ymargin)); // Round to the pixel grid x0 = Math.floor(x0 * tw + 0.5) / tw; y0 = Math.floor(y0 * th + 0.5) / th; this.viewport_x = x0; this.viewport_y = y0; // The viewport might not be aligned to the grid, so split off any fractional part. let xf0 = Math.floor(x0); let yf0 = Math.floor(y0); // Note that when the viewport is exactly aligned to the grid, we need to draw the cells // just outside of it, or we'll miss objects partway through crossing the border if (xf0 === x0 && xf0 > 0) { xf0 -= 1; } if (yf0 === y0 && yf0 > 0) { yf0 -= 1; } // Find where to stop drawing. As with above, if we're aligned to the grid, we need to // include the tiles just outside it, so we allow this fencepost problem to fly let x1 = Math.min(this.level.size_x - 1, Math.ceil(x0 + this.viewport_size_x)); let y1 = Math.min(this.level.size_y - 1, Math.ceil(y0 + this.viewport_size_y)); // Draw one layer at a time, so animated objects aren't overdrawn by // neighboring terrain // XXX layer count hardcoded here for (let layer = 0; layer < 4; layer++) { for (let x = xf0; x <= x1; x++) { for (let y = yf0; y <= y1; y++) { for (let tile of this.level.cells[y][x]) { if (tile.type.draw_layer !== layer) continue; if (tile.type.is_actor && // FIXME kind of a hack for the editor, which uses bare tile objects tile.visual_position) { // Handle smooth scrolling let [vx, vy] = tile.visual_position(tic_offset); // Round this to the pixel grid too! vx = Math.floor(vx * tw + 0.5) / tw; vy = Math.floor(vy * th + 0.5) / th; this.tileset.draw(tile, tic, (sx, sy, dx = 0, dy = 0, w = 1, h = w) => this.blit(this.ctx, sx, sy, vx - x0 + dx, vy - y0 + dy, w, h)); } else { // Non-actors can't move this.tileset.draw(tile, tic, (sx, sy, dx = 0, dy = 0, w = 1, h = w) => this.blit(this.ctx, sx, sy, x - x0 + dx, y - y0 + dy, w, h)); } } } } } if (this.use_rewind_effect) { this.draw_rewind_effect(tic); } } draw_rewind_effect(tic) { // Shift several rows over in a recurring pattern, like a VHS, whatever that is let rewind_start = tic / 20 % 1; for (let chunk = 0; chunk < 4; chunk++) { let y = Math.floor(this.canvas.height * (chunk + rewind_start) / 4); for (let dy = 1; dy < 5; dy++) { this.ctx.drawImage( this.canvas, 0, y + dy, this.canvas.width, 1, -dy * dy, y + dy, this.canvas.width, 1); } } } create_tile_type_canvas(name) { let canvas = mk('canvas', {width: this.tileset.size_x, height: this.tileset.size_y}); let ctx = canvas.getContext('2d'); this.tileset.draw_type(name, null, 0, (sx, sy, dx = 0, dy = 0, w = 1, h = w) => this.blit(ctx, sx, sy, dx, dy, w, h)); return canvas; } } export default CanvasRenderer;