Upit | Learn about creating the game Memerge with gen AI

/**** * Plugins ****/ var tween = LK.import("@upit/tween.v1"); var storage = LK.import("@upit/storage.v1"); /**** * Classes ****/ var Fruit = Container.expand(function (type) { var self = Container.call(this); // FruitTypes is being used before it's defined, so we need to handle this case self.type = type; self.vx = 0; self.vy = 0; self.rotation = 0; self.angularVelocity = 0; self.angularFriction = 0.92; // Increased friction for faster angular velocity reduction self.groundAngularFriction = 0.75; // Stronger ground friction to stop spinning faster self.gravity = 1.8; // Doubled gravity to make fruits drop faster self.friction = 0.98; // Calculate elasticity based on fruit level // The biggest fruit (DURIAN) has elasticity of 0.7 // Smaller fruits are more bouncy with elasticity closer to 1.0 var fruitLevels = { 'CHERRY': 1, 'GRAPE': 2, 'APPLE': 3, 'ORANGE': 4, 'WATERMELON': 5, 'PINEAPPLE': 6, 'MELON': 7, 'PEACH': 8, 'COCONUT': 9, 'DURIAN': 10 }; var currentLevel = self.type ? fruitLevels[self.type.id.toUpperCase()] || 10 : 10; // Scale elasticity from 0.9 (most bouncy) for level 1 to 0.7 (least bouncy) for level 10 self.elasticity = 0.9 - (currentLevel - 1) * (0.2 / 9); self.merging = false; self.isStatic = false; self.maxAngularVelocity = 0.15; // Add maximum angular velocity cap // Only attempt to attach the asset if self.type exists and has necessary properties if (self.type && self.type.id && self.type.points && self.type.size) { var fruitGraphics = self.attachAsset(self.type.id, { anchorX: 0.5, anchorY: 0.5 }); // Set width and height directly from the actual asset for accurate hitbox self.width = fruitGraphics.width; self.height = fruitGraphics.height; // No point value shown on fruit } else { // This will be initialized properly when the game is fully loaded console.log("Warning: Fruit type not available yet or missing required properties"); } self.update = function () { // Skip updates for static or merging fruits if (self.isStatic || self.merging) { return; } // Initialize necessary tracking properties if undefined if (self.safetyPeriod === undefined) { self.safetyPeriod = false; } if (self.wallContactFrames === undefined) { self.wallContactFrames = 0; } // Track safety period state changes if (self.safetyPeriod === false && self.vy <= 0) { // When a fruit that was in safety period starts moving upward or stops, // it means it has hit something, so it's no longer in safety period self.safetyPeriod = true; } // Add damping when velocity is low if (Math.abs(self.vx) < 0.5 && Math.abs(self.vy) < 0.5) { self.angularVelocity *= 0.9; // Apply damping when fruit is almost at rest } // Check for contact with walls to apply wall friction // Use width instead of assuming a radius - better for non-circular fruits var fruitHalfWidth = self.width / 2; var isContactingLeftWall = self.x <= wallLeft.x + wallLeft.width / 2 + fruitHalfWidth + 2; var isContactingRightWall = self.x >= wallRight.x - wallRight.width / 2 - fruitHalfWidth - 2; if (isContactingLeftWall || isContactingRightWall) { // Apply progressive wall friction based on how long the fruit has been in contact self.wallContactFrames++; // Increase wall friction the longer the fruit stays in contact var progressiveFriction = Math.min(0.85, 0.65 + self.wallContactFrames * 0.01); self.angularVelocity *= progressiveFriction; } else { // Reset wall contact frames when not touching walls self.wallContactFrames = 0; } // Check for contact with other fruits to apply additional friction var isContactingOtherFruit = false; for (var i = 0; i < fruits.length; i++) { var otherFruit = fruits[i]; if (otherFruit !== self && !otherFruit.merging && !otherFruit.isStatic) { var dx = otherFruit.x - self.x; var dy = otherFruit.y - self.y; var distance = Math.sqrt(dx * dx + dy * dy); var combinedHalfWidths = (self.width + otherFruit.width) / 2; if (distance < combinedHalfWidths + 2) { // Small buffer for contact detection isContactingOtherFruit = true; break; } } } // Apply stronger friction when in contact with other fruits if (isContactingOtherFruit) { self.angularVelocity *= 0.8; // Stronger friction when touching other fruits } // Apply extreme damping when almost stopped rotating if (Math.abs(self.angularVelocity) < 0.01) { self.angularVelocity = 0; } }; self.merge = function (otherFruit) { // Prevent already merging fruits from merging again if (self.merging) { return; } // Mark both fruits as merging to prevent further interactions self.merging = true; otherFruit.merging = true; // Calculate midpoint between fruits for new fruit position var midX = (self.x + otherFruit.x) / 2; var midY = (self.y + otherFruit.y) / 2; // Create merge animation for both fruits tween(self, { alpha: 0, scaleX: 0.5, scaleY: 0.5 }, { duration: 200, easing: tween.easeOut }); tween(otherFruit, { alpha: 0, scaleX: 0.5, scaleY: 0.5 }, { duration: 200, easing: tween.easeOut, onFinish: function onFinish() { // Play merge sound once for all fruit types LK.getSound('merge').play(); // Track if this is a merge involving the player's most recently dropped fruit var fromReleasedFruits = self.fromChargedRelease || otherFruit.fromChargedRelease; var isPlayerDroppedFruitMerge = !fromReleasedFruits && (self === lastDroppedFruit || otherFruit === lastDroppedFruit) && !lastDroppedHasMerged; // Allow for a 2-second grace period after dropping the fruit var fruitHasMergeGracePeriod = self.mergeGracePeriodActive || otherFruit.mergeGracePeriodActive; // Only mark as merged if it's the player's dropped fruit or in grace period if (isPlayerDroppedFruitMerge || fruitHasMergeGracePeriod) { lastDroppedHasMerged = true; // Mark that this fruit has had its first merge } // Reset fromChargedRelease flag after this merge completes // so these fruits can participate in future chain reactions with next player drop // Special case for DURIAN - they simply disappear instead of merging if (self.type.id.toUpperCase() === 'DURIAN') { // Add points based on the durian's value LK.setScore(LK.getScore() + self.type.points); updateScoreDisplay(); // Remove both fruits removeFruitFromGame(self); removeFruitFromGame(otherFruit); // Only charge if this is the player's active merge or in grace period if (isPlayerDroppedFruitMerge || fruitHasMergeGracePeriod) { chargeCounter++; updateChargedBallDisplay(); // Check if we've reached 3 charged balls (changed from 5) if (chargeCounter >= 3 && !readyToReleaseCharged) { releaseChargedBalls(); } } } else { // Only charge if this is the player's active merge or in grace period if (isPlayerDroppedFruitMerge || fruitHasMergeGracePeriod) { chargeCounter++; updateChargedBallDisplay(); // Check if we've reached 3 charged balls (changed from 5) if (chargeCounter >= 3 && !readyToReleaseCharged) { releaseChargedBalls(); } } // Normal merge behavior for all other fruits var nextType = FruitTypes[self.type.next.toUpperCase()]; var newFruit = new Fruit(nextType); // Position at midpoint with initial small scale newFruit.x = midX; newFruit.y = midY; newFruit.scaleX = 0.5; newFruit.scaleY = 0.5; // Add to game and array game.addChild(newFruit); fruits.push(newFruit); // Add merge points based on the new fruit's level LK.setScore(LK.getScore() + nextType.points); updateScoreDisplay(); // Animate new fruit growing tween(newFruit, { scaleX: 1, scaleY: 1 }, { duration: 300, easing: tween.bounceOut }); // Remove both original fruits removeFruitFromGame(self); removeFruitFromGame(otherFruit); // Removed charged balls check here since it's now handled at the beginning of merge function } } }); // Helper function to remove a fruit from the game function removeFruitFromGame(fruit) { var index = fruits.indexOf(fruit); if (index !== -1) { fruits.splice(index, 1); } fruit.destroy(); } }; return self; }); var Line = Container.expand(function () { var self = Container.call(this); var lineGraphics = self.attachAsset('floor', { anchorX: 0.5, anchorY: 0.5 }); // Make it visually distinct from the floor lineGraphics.tint = 0xff0000; // Ensure full width is used for collision but visual is thin lineGraphics.height = 20; // Make the visual thinner return self; }); var TrajectoryLine = Container.expand(function () { var self = Container.call(this); self.dots = []; self.dotSpacing = 10; // Space between dots in the trajectory (closer dots) self.dotSize = 15; // Size of trajectory dots (larger dots) self.maxDots = 100; // Maximum number of dots to prevent excessive calculations (increased for longer line) // Create dots self.createDots = function () { // Clear existing dots first self.clearDots(); // Create new dots for (var i = 0; i < self.maxDots; i++) { var dot = new Container(); // Create a small white circle using the trajectory dot asset var dotGraphic = dot.attachAsset('trajectoryDot', { anchorX: 0.5, anchorY: 0.5 }); // Make sure the dot is white and appropriately sized dotGraphic.tint = 0xFFFFFF; dot.scaleX = 0.8; // Make dots more visible dot.scaleY = 0.8; // Initially hide the dot dot.visible = false; // Add to container and array self.addChild(dot); self.dots.push(dot); } }; // Clear all dots self.clearDots = function () { for (var i = 0; i < self.dots.length; i++) { if (self.dots[i]) { self.dots[i].destroy(); } } self.dots = []; }; // Update trajectory based on current active fruit position self.updateTrajectory = function (startX, startY) { if (!activeFruit) { return; } // Hide all dots first for (var i = 0; i < self.dots.length; i++) { self.dots[i].visible = false; } // Physics simulation variables var simX = startX; var simY = startY; var simVX = 0; // Starting with no horizontal velocity var simVY = 0; // Starting with no vertical velocity var gravity = 1.8; // Same gravity as in the game // Show dots along predicted path var dotCount = 0; var hitFruit = false; // Create dots in a straight line directly downward var dotY = startY; var dotSpacing = 25; // Smaller spacing between dots for a more continuous line while (dotCount < self.maxDots && !hitFruit) { // Place dot at current position if (dotCount < self.dots.length) { // Place dot directly below the fruit in a straight line self.dots[dotCount].x = startX; self.dots[dotCount].y = dotY; self.dots[dotCount].visible = true; self.dots[dotCount].alpha = 1.0; dotCount++; } // Move to next dot position dotY += dotSpacing; // Check if we've hit the floor var floorCollisionY = gameFloor.y - gameFloor.height / 2 - activeFruit.width / 2; if (dotY > floorCollisionY) { // Stop at the floor break; } // Check if we've hit any fruits var hitFruit = false; for (var j = 0; j < fruits.length; j++) { var fruit = fruits[j]; if (fruit !== activeFruit && !fruit.merging) { var dx = fruit.x - startX; var dy = fruit.y - dotY; var distance = Math.sqrt(dx * dx + dy * dy); var combinedRadius = (activeFruit.width + fruit.width) / 2; if (distance < combinedRadius) { hitFruit = true; break; } } } if (hitFruit) { break; } } }; return self; }); /**** * Initialize Game ****/ var game = new LK.Game({ backgroundColor: 0xf6e58d }); /**** * Game Code ****/ // Game variables var gameOverLine; // Game over line var pineapple; // The pineapple that pushes in from left var pineappleActive = false; // Track if pineapple is active in gameplay var pineapplePushCount = 0; // Count how many times pineapple has been pushed var readyToReleaseCharged = false; // Flag to indicate if charged fruits are ready to be released var trajectoryLine; // Line showing trajectory of active fruit var chargedFruitIconScale = 0.6; // Global scale for charged fruit icons var FruitTypes = { CHERRY: { id: 'cherry', size: 150, points: 1, next: 'grape' }, GRAPE: { id: 'grape', size: 200, points: 2, next: 'apple' }, APPLE: { id: 'apple', size: 250, points: 3, next: 'orange' }, ORANGE: { id: 'orange', size: 300, points: 5, next: 'watermelon' }, WATERMELON: { id: 'watermelon', size: 350, points: 8, next: 'pineapple' }, PINEAPPLE: { id: 'pineapple', size: 400, points: 13, next: 'melon' }, MELON: { id: 'melon', size: 450, points: 21, next: 'peach' }, PEACH: { id: 'peach', size: 500, points: 34, next: 'coconut' }, COCONUT: { id: 'coconut', size: 550, points: 55, next: 'durian' }, DURIAN: { id: 'durian', size: 600, points: 89, next: null } }; var gameWidth = 2048; var gameHeight = 2732; var fruits = []; var nextFruitType = null; var activeFruit = null; // The fruit currently controlled by the player var wallLeft, wallRight, gameFloor; var dropPointY = 200; // Y coordinate where new fruits appear var gameOver = false; var scoreText; var isDragging = false; // Flag to check if the player is currently dragging var chargedBalls = []; // Array to hold charged ball icons var chargedBallContainer = null; // Container for charged ball icons var chargeCounter = 0; // Counter to track dropped balls for charging var lastDroppedFruit = null; // Track last fruit dropped by player var lastDroppedHasMerged = false; // Track if last dropped fruit has already had its first merge // Setup game boundaries function setupBoundaries() { // Left wall wallLeft = game.addChild(LK.getAsset('wall', { anchorX: 0.5, anchorY: 0.5 })); wallLeft.x = 0; wallLeft.y = gameHeight / 2; // Right wall wallRight = game.addChild(LK.getAsset('wall', { anchorX: 0.5, anchorY: 0.5 })); wallRight.x = gameWidth; wallRight.y = gameHeight / 2; // Floor gameFloor = game.addChild(LK.getAsset('floor', { anchorX: 0.5, anchorY: 0.5 })); gameFloor.x = gameWidth / 2; gameFloor.y = gameHeight; // Game over line gameOverLine = game.addChild(new Line()); gameOverLine.x = gameWidth / 2; gameOverLine.y = 50; // Position 200 pixels higher than before gameOverLine.scaleX = 1; // Make it stretch across the entire width of the screen gameOverLine.scaleY = 0.2; // Make it thinner gameOverLine.alpha = 0; // Make the line completely invisible } // Create new next fruit function createNextFruit() { // Determine which fruit to spawn - only level 1 (CHERRY) or level 2 (GRAPE), never level 3+ var fruitProbability = Math.random(); var fruitType; if (fruitProbability < 0.6) { fruitType = FruitTypes.CHERRY; } else { fruitType = FruitTypes.GRAPE; } nextFruitType = fruitType; // Update display // No explicit preview display needed, the next fruit will be the one the player controls // Create the active fruit activeFruit = new Fruit(nextFruitType); // Position at the location of the last dropped fruit if available, otherwise at the top center if (lastDroppedFruit) { activeFruit.x = lastDroppedFruit.x; activeFruit.y = dropPointY + 200; } else { activeFruit.x = gameWidth / 2; activeFruit.y = dropPointY + 200; } // Make it static while the player controls it activeFruit.isStatic = true; game.addChild(activeFruit); // Update trajectory line for the new fruit if (trajectoryLine) { trajectoryLine.updateTrajectory(activeFruit.x, activeFruit.y); } } // Drop fruit at specified position function dropFruit() { if (gameOver || !activeFruit) { return; } // Make the active fruit dynamic so it drops activeFruit.isStatic = false; // Use standardized drop mechanics applyDropPhysics(activeFruit, 3.5); // Standard force for normal fruits // Add the fruit to the main fruits array fruits.push(activeFruit); // Mark this as the player's dropped fruit to track its first merge lastDroppedFruit = activeFruit; lastDroppedHasMerged = false; // Set merge grace period flag on the dropped fruit activeFruit.mergeGracePeriodActive = true; // Start 2-second timer after which the grace period expires LK.setTimeout(function () { if (activeFruit && fruits.includes(activeFruit)) { activeFruit.mergeGracePeriodActive = false; } }, 2000); // Hide all trajectory dots when fruit is dropped if (trajectoryLine) { for (var i = 0; i < trajectoryLine.dots.length; i++) { trajectoryLine.dots[i].visible = false; } } // Reset fromChargedRelease flags on all fruits when a new player fruit is dropped // This allows previously released charged fruits to participate in new chain reactions for (var i = 0; i < fruits.length; i++) { if (fruits[i] && fruits[i].fromChargedRelease) { fruits[i].fromChargedRelease = false; } } // Play drop sound LK.getSound('drop').play(); // Check if we have charged balls ready to be released if (readyToReleaseCharged && chargeCounter >= 3) { // Play the PickleRick sound when releasing the charged fruits LK.getSound('pickleRick').play(); // Create and drop 3 level 3 (apple) balls from above the screen (changed from 5) for (var i = 0; i < 3; i++) { // Create the actual fruit var apple = new Fruit(FruitTypes.APPLE); // Position each fruit evenly across the screen width, above the visible area var spacing = gameWidth / 4; // Divide by 4 to get 3 spaces between var xPos = spacing * (i + 1); // Position at 1/4, 2/4, 3/4 of screen width // Place fruits above the screen, with increased vertical spacing between them apple.x = xPos; apple.y = -apple.height - i * 200; // Add 400px gap between each fruit // Make it dynamic so it drops apple.isStatic = false; // Apply standard drop physics - slightly randomize forces for natural effect var forceMultiplier = 3.5 + (Math.random() * 1 - 0.5); applyDropPhysics(apple, forceMultiplier); // Mark this fruit as coming from charged release apple.fromChargedRelease = true; // Add to game and fruits array game.addChild(apple); fruits.push(apple); } // Reset charge counter chargeCounter = 0; // Reset charged balls UI resetChargedBalls(); // Reset the release flag readyToReleaseCharged = false; } // Charge counter is now only incremented on merges // Handle pineapple logic if (pineappleActive) { // Pineapple is ready to drop after pushes pineapple.isStatic = false; // Use standardized drop mechanics with less force for bigger fruit applyDropPhysics(pineapple, 2.5); // Add to fruits array fruits.push(pineapple); // Start 2-second timer to enable game over contact LK.setTimeout(function () { pineapple.immuneToGameOver = false; }, 2000); // Setup a new pineapple for next cycle setupPineapple(); } else { // Push the pineapple further in pushPineapple(); } // Clear active fruit activeFruit = null; // Create the next fruit immediately createNextFruit(); } // Helper function to standardize drop physics for all fruits function applyDropPhysics(fruit, forceMultiplier) { // Add angle variation - random angle between -10 and +10 degrees var angle = (Math.random() * 20 - 10) * (Math.PI / 180); // Convert to radians // Apply velocity based on angle fruit.vx = Math.sin(angle) * forceMultiplier; fruit.vy = Math.abs(Math.cos(angle) * forceMultiplier); // Make sure initial Y velocity is downward // Mark this fruit as in safety period since it's newly dropped fruit.safetyPeriod = false; // Make it immune to game over for a second fruit.immuneToGameOver = true; // Start 1-second timer to enable game over contact LK.setTimeout(function () { if (fruit && fruits.includes(fruit)) { fruit.immuneToGameOver = false; } }, 1000); } // Update score display function updateScoreDisplay() { scoreText.setText(LK.getScore()); } // Setup UI function setupUI() { // Score display scoreText = new Text2("0", { size: 80, fill: 0xFFFFFF }); scoreText.anchor.set(0.5, 0); LK.gui.top.addChild(scoreText); scoreText.y = 30; // Create charged ball grid setupChargedBallDisplay(); } // Create charged ball grid function setupChargedBallDisplay() { // Create container for charged balls chargedBallContainer = new Container(); game.addChild(chargedBallContainer); // Position the container at the top of the screen - move down slightly chargedBallContainer.y = 150; // Use consistent values for UI balls matching the actual game fruit var ballType = FruitTypes.APPLE; // Level 3 ball type // Make icons smaller and decrease gaps between them // Use the global charged fruit icon scale // Position first element and then space them evenly with exactly 200px gaps (increased from 100px) var startX = gameWidth / 2 + 350; // Center the group of 3 icons and adjust position // Create 3 balls in a single row (changed from 5) for (var i = 0; i < 3; i++) { // Changed loop to 3 var ball = new Container(); // Use apple as charged balls with consistent scale var ballGraphics = ball.attachAsset('apple', { anchorX: 0.5, anchorY: 0.5 }); // Scale down the apple UI elements for smaller icons ball.scaleX = chargedFruitIconScale; ball.scaleY = chargedFruitIconScale; // Position relative to the first icon with exactly 200px spacing (increased from 100px) ball.x = startX + i * 150; // Set to semi-transparent initially ball.alpha = 0.5; // Add to container and array chargedBallContainer.addChild(ball); chargedBalls.push(ball); } // Center the container horizontally chargedBallContainer.x = 0; } // Function to update charged ball display function updateChargedBallDisplay() { // Update the visibility of balls based on chargeCounter for (var i = 0; i < chargedBalls.length; i++) { if (i < chargeCounter) { // Balls that are charged are fully visible if (chargedBalls[i].alpha !== 1) { tween(chargedBalls[i], { alpha: 1 }, { duration: 300, easing: tween.easeOut }); } } else { // Balls that are not yet charged are semi-transparent if (chargedBalls[i].alpha !== 0.5) { chargedBalls[i].alpha = 0.5; } } } } // Function to prepare charged balls for release (just sets a flag, doesn't release them yet) function releaseChargedBalls() { // Don't play drop sound here anymore as we're not dropping yet // Just set a flag to indicate we have charged balls ready to be released readyToReleaseCharged = true; // Make all charged balls visible to indicate they're charged for (var i = 0; i < chargedBalls.length; i++) { tween(chargedBalls[i], { alpha: 1 }, { duration: 300, easing: tween.easeOut }); } // We don't reset the charge counter or UI here - we'll do that when the charged fruits are actually released } // Separate function to reset charged balls UI function resetChargedBalls() { // Reset the charged ball display immediately for (var j = 0; j < chargedBalls.length; j++) { // Explicitly reset all balls to inactive state with tween to ensure transition tween(chargedBalls[j], { alpha: 0.5 }, { duration: 200, easing: tween.easeOut }); chargedBalls[j].scaleX = chargedFruitIconScale; // Use global scale variable chargedBalls[j].scaleY = chargedFruitIconScale; // Use global scale variable } // No need to call updateChargedBallDisplay() as we set the state directly here } // Check for fruit collisions function checkFruitCollisions() { for (var i = 0; i < fruits.length; i++) { var fruit1 = fruits[i]; // Skip collision for the active fruit if (fruit1 === activeFruit || fruit1.merging) { continue; } for (var j = i + 1; j < fruits.length; j++) { var fruit2 = fruits[j]; // Skip collision for the active fruit if (fruit2 === activeFruit || fruit2.merging) { continue; } // Calculate distance between centers var dx = fruit2.x - fruit1.x; var dy = fruit2.y - fruit1.y; var distance = Math.sqrt(dx * dx + dy * dy); // Check if they are overlapping - use actual asset dimensions for more accurate hitboxes // Calculate half dimensions for both fruits var fruit1HalfWidth = fruit1.width / 2; var fruit1HalfHeight = fruit1.height / 2; var fruit2HalfWidth = fruit2.width / 2; var fruit2HalfHeight = fruit2.height / 2; // Check for collision using Rectangle Intersection algorithm // First, calculate the distance between centers on each axis var absDistanceX = Math.abs(dx); var absDistanceY = Math.abs(dy); // Then calculate the sum of half-widths and half-heights var combinedHalfWidths = fruit1HalfWidth + fruit2HalfWidth; var combinedHalfHeights = fruit1HalfHeight + fruit2HalfHeight; // If distance on either axis is less than combined halves, we have an overlap if (absDistanceX < combinedHalfWidths && absDistanceY < combinedHalfHeights) { // Resolve collision (simple separation and velocity adjustment) var combinedRadius = Math.min(combinedHalfWidths, combinedHalfHeights); var overlap = combinedRadius - distance; var normalizeX = dx / distance; var normalizeY = dy / distance; var moveX = overlap / 2 * normalizeX; var moveY = overlap / 2 * normalizeY; fruit1.x -= moveX; fruit1.y -= moveY; fruit2.x += moveX; fruit2.y += moveY; // Calculate relative velocity var rvX = fruit2.vx - fruit1.vx; var rvY = fruit2.vy - fruit1.vy; var contactVelocity = rvX * normalizeX + rvY * normalizeY; // Only resolve if velocities are separating if (contactVelocity < 0) { // Use the higher elasticity for the collision (smaller fruits bounce more) var collisionElasticity = Math.max(fruit1.elasticity, fruit2.elasticity); var impulse = -(1 + collisionElasticity) * contactVelocity; var totalMass = fruit1.type.size + fruit2.type.size; // Using size as a proxy for mass var impulse1 = impulse * (fruit2.type.size / totalMass); var impulse2 = impulse * (fruit1.type.size / totalMass); // Apply impact scaling for smaller fruits against bigger ones // Smaller fruits should bounce away more from larger fruits var sizeDifference = Math.abs(fruit1.type.size - fruit2.type.size) / Math.max(fruit1.type.size, fruit2.type.size); if (fruit1.type.size < fruit2.type.size) { impulse1 *= 1 + sizeDifference * 0.5; // Smaller fruit gets extra bounce } else if (fruit2.type.size < fruit1.type.size) { impulse2 *= 1 + sizeDifference * 0.5; // Smaller fruit gets extra bounce } fruit1.vx -= impulse1 * normalizeX; fruit1.vy -= impulse1 * normalizeY; fruit2.vx += impulse2 * normalizeX; fruit2.vy += impulse2 * normalizeY; // Apply friction between colliding fruits var tangentX = -normalizeY; var tangentY = normalizeX; var tangentVelocity = rvX * tangentX + rvY * tangentY; var frictionImpulse = -tangentVelocity * 0.2; // Increased friction factor fruit1.vx -= frictionImpulse * tangentX; fruit1.vy -= frictionImpulse * tangentY; fruit2.vx += frictionImpulse * tangentX; fruit2.vy += frictionImpulse * tangentY; // Apply angular velocity change based on collision with proportional damping var fruit1AngularImpulse = impulse1 * (tangentX * normalizeY - tangentY * normalizeX) * 0.0005; var fruit2AngularImpulse = impulse2 * (tangentX * normalizeY - tangentY * normalizeX) * 0.0005; fruit1.angularVelocity += fruit1AngularImpulse; fruit2.angularVelocity -= fruit2AngularImpulse; // Apply additional angular damping during collisions fruit1.angularVelocity *= 0.9; fruit2.angularVelocity *= 0.9; // Cap angular velocity fruit1.angularVelocity = Math.min(Math.max(fruit1.angularVelocity, -fruit1.maxAngularVelocity), fruit1.maxAngularVelocity); fruit2.angularVelocity = Math.min(Math.max(fruit2.angularVelocity, -fruit2.maxAngularVelocity), fruit2.maxAngularVelocity); if (Math.abs(contactVelocity) > 1) { // Bounce sound removed } } // Only proceed with merge if fruits are the same type if (fruit1.type === fruit2.type) { // Merge fruits if they are close enough and of the same type fruit1.merge(fruit2); break; } } } } } // Check if game is over (fruits touching the red line) function checkGameOver() { if (gameOver) { return; } // Remove "too many fruits" game over condition // Check if any fruits are touching the red line for (var i = 0; i < fruits.length; i++) { // Don't check game over for the active fruit if (fruits[i] === activeFruit) { continue; } // Check if fruit touches the game over line // For more accurate collision, calculate if any part of the fruit is above the line var fruit = fruits[i]; var fruitHalfHeight = fruit.height / 2; var fruitHalfWidth = fruit.width / 2; // Calculate the effective height based on fruit's rotation var cosAngle = Math.abs(Math.cos(fruit.rotation)); var sinAngle = Math.abs(Math.sin(fruit.rotation)); var effectiveHeight = fruitHalfHeight * cosAngle + fruitHalfWidth * sinAngle; // Check if the top of the fruit is above/at the game over line var fruitTopY = fruit.y - effectiveHeight; var lineBottomY = gameOverLine.y + gameOverLine.height / 2; if (!fruit.merging && fruitTopY <= lineBottomY) { // Skip game over if the fruit is immune (any fruit in grace period) if (fruit.immuneToGameOver) { continue; } // Initialize the safetyPeriod property if not already set if (fruits[i].safetyPeriod === undefined) { // If the fruit is still moving downward, it's probably just spawned if (fruits[i].vy > 0) { // Mark this fruit as in safety period - it has just been dropped fruits[i].safetyPeriod = false; continue; // Skip game over check for freshly dropped fruits } // If the fruit has hit something and bounced back or is stable, it's no longer in safety period if (fruits[i].vy <= 0) { fruits[i].safetyPeriod = true; // Mark that we've checked and it's now unsafe } } // Only trigger game over if the fruit is not in safety period if (fruits[i].safetyPeriod) { // Trigger game over when a fruit touches the line after having bounced/settled gameOver = true; LK.showGameOver(); return; } } } } // Create and setup the pineapple function setupPineapple() { pineapple = new Fruit(FruitTypes.PINEAPPLE); pineapple.x = -pineapple.width / 2; // Start completely off screen pineapple.y = 200; // Position 200 pixels higher than before pineapple.isStatic = true; // Make it static until it's dropped pineappleActive = false; // Not active in gameplay yet pineapplePushCount = 0; // Reset push count game.addChild(pineapple); } // Function to push the pineapple function pushPineapple() { // Only push if not already active in gameplay if (!pineappleActive) { pineapplePushCount++; // Calculate new x position (100px per push instead of 200px) var newX = -pineapple.width / 2 + pineapplePushCount * 70; // Animate the push tween(pineapple, { x: newX }, { duration: 300, easing: tween.bounceOut }); // Check if we've pushed the pineapple 7 times if (pineapplePushCount >= 7) { pineappleActive = true; // Mark as ready to drop on next fruit release } } } // Initialize game function initGame() { LK.setScore(0); gameOver = false; fruits = []; chargeCounter = 0; chargedBalls = []; readyToReleaseCharged = false; lastScoreCheckForCoconut = 0; lastDroppedFruit = null; lastDroppedHasMerged = false; // We no longer reset fromChargedRelease flag here // as we want it to persist only for the current chain reaction // fromChargedRelease is now reset in the merge function when needed // Start background music LK.playMusic('bgmusic'); // Setup game elements setupBoundaries(); setupUI(); setupPineapple(); // Setup the pineapple // Create trajectory line if (trajectoryLine) { trajectoryLine.destroy(); } trajectoryLine = game.addChild(new TrajectoryLine()); trajectoryLine.createDots(); updateScoreDisplay(); createNextFruit(); // Ensure all UI balls are properly initialized to inactive state LK.setTimeout(function () { if (chargedBalls.length === 3) { resetChargedBalls(); } }, 100); } // Function to spawn coconut from bottom of screen function spawnCoconut() { var coconut = new Fruit(FruitTypes.COCONUT); // Randomly position coconut horizontally within game area var minX = wallLeft.x + wallLeft.width / 2 + coconut.width / 2 + 50; var maxX = wallRight.x - wallRight.width / 2 - coconut.width / 2 - 50; coconut.x = minX + Math.random() * (maxX - minX); // Position below the screen coconut.y = gameHeight + coconut.height / 2; // Make it static while animating into place coconut.isStatic = true; // Play the Stonks sound when coconut appears LK.getSound('stonks').play(); // Add to game and fruits array game.addChild(coconut); fruits.push(coconut); // Mark as in safety period coconut.safetyPeriod = false; // Make it immune to game over for a second coconut.immuneToGameOver = true; // Use tween to smoothly animate the coconut entering the screen from below // Calculate target Y position where the coconut is fully in the board var targetY = gameHeight - gameFloor.height / 2 - coconut.height / 2 - 10; // Animate entry with an easeOut effect and gradually increasing speed tween(coconut, { y: targetY }, { duration: 1200, // 1.2 seconds for a faster entry easing: tween.easeIn, // Start slow and speed up onFinish: function onFinish() { // Once fully entered, make it dynamic so it can interact with other fruits coconut.isStatic = false; // Give it a small upward push to make it bounce slightly when it enters coconut.vy = -2; // Add random horizontal velocity for natural movement coconut.vx = (Math.random() * 2 - 1) * 1.5; // Start 1-second timer to enable game over contact LK.setTimeout(function () { if (coconut && fruits.includes(coconut)) { coconut.immuneToGameOver = false; } }, 1000); } }); } // Track last score checked for coconut spawn var lastScoreCheckForCoconut = 0; // Event handlers game.down = function (x, y) { // We don't need to check specific boundaries to start dragging. // As long as there's an active fruit, we can start dragging. if (activeFruit) { isDragging = true; // Update active fruit position immediately game.move(x, y); } }; // Mouse or touch move on game object game.move = function (x, y) { if (isDragging && activeFruit) { // Only move the active fruit on the X axis - use actual fruit width var fruitRadius = activeFruit.width / 2; var minX = wallLeft.x + wallLeft.width / 2 + fruitRadius; var maxX = wallRight.x - wallRight.width / 2 - fruitRadius; activeFruit.x = Math.max(minX, Math.min(maxX, x)); // Update trajectory line if (trajectoryLine) { trajectoryLine.updateTrajectory(activeFruit.x, activeFruit.y); } } }; // Mouse or touch up on game object game.up = function () { if (isDragging && activeFruit) { dropFruit(); } isDragging = false; }; // Game update loop game.update = function () { // Check if we've reached a new 500-point threshold var currentScore = LK.getScore(); if (Math.floor(currentScore / 500) > Math.floor(lastScoreCheckForCoconut / 500)) { // Spawn a coconut for every 500 points spawnCoconut(); } lastScoreCheckForCoconut = currentScore; // We no longer need to check if pineapple is in the board // as we now use push count to determine when it's ready // Apply physics and check collisions for each fruit for (var i = fruits.length - 1; i >= 0; i--) { var fruit = fruits[i]; if (fruit.isStatic || fruit.merging) { continue; } // Store last position for boundary checks if (fruit.lastY === undefined) { fruit.lastY = fruit.y; } if (fruit.lastX === undefined) { fruit.lastX = fruit.x; } // Apply gravity fruit.vy += fruit.gravity; // Apply velocity fruit.x += fruit.vx; fruit.y += fruit.vy; // Apply rotation fruit.rotation += fruit.angularVelocity; // Apply friction fruit.vx *= fruit.friction; fruit.vy *= fruit.friction; // Apply angular friction fruit.angularVelocity *= fruit.angularFriction; // Force fruits to stop rotating when they're barely moving if (Math.abs(fruit.vx) < 0.1 && Math.abs(fruit.vy) < 0.1 && Math.abs(fruit.angularVelocity) < 0.03) { fruit.angularVelocity = 0; } // Apply stronger angular friction when moving slowly if (Math.abs(fruit.vx) < 0.8 && Math.abs(fruit.vy) < 0.8) { fruit.angularVelocity *= 0.9; } // Clamp angular velocity fruit.angularVelocity = Math.min(Math.max(fruit.angularVelocity, -fruit.maxAngularVelocity), fruit.maxAngularVelocity); // Wall collision - use actual fruit width for accurate collision var fruitHalfWidth = fruit.width / 2; // Use half width of the asset var fruitHalfHeight = fruit.height / 2; // Use half height of the asset // For non-circular fruits, adjust collision bounds based on asset orientation // Use the larger dimension to ensure no part of the fruit goes through walls var collisionRadius = Math.max(fruitHalfWidth, fruitHalfHeight); if (fruit.x < wallLeft.x + wallLeft.width / 2 + collisionRadius) { fruit.x = wallLeft.x + wallLeft.width / 2 + collisionRadius; fruit.vx = -fruit.vx * fruit.elasticity; // Smaller fruits get more angular velocity from impacts var angularImpactMultiplier = 0.005 * (1 + (0.9 - fruit.elasticity) * 5); fruit.angularVelocity += fruit.vy * angularImpactMultiplier * (fruit.vx / Math.abs(fruit.vx || 1)); // Apply angular velocity based on vertical velocity and direction of impact // Apply wall friction - stronger when in wall contact and proportional to fruit size var wallFriction = 0.65 + (fruit.elasticity - 0.7) * 0.5; // More elastic (smaller) fruits get less wall friction fruit.angularVelocity *= wallFriction; fruit.angularVelocity *= fruit.groundAngularFriction; if (Math.abs(fruit.vx) > 1) { // Bounce sound removed } } else if (fruit.x > wallRight.x - wallRight.width / 2 - collisionRadius) { fruit.x = wallRight.x - wallRight.width / 2 - collisionRadius; fruit.vx = -fruit.vx * fruit.elasticity; // Smaller fruits get more angular velocity from impacts var angularImpactMultiplier = 0.005 * (1 + (0.9 - fruit.elasticity) * 5); fruit.angularVelocity -= fruit.vy * angularImpactMultiplier * (fruit.vx / Math.abs(fruit.vx || 1)); // Apply angular velocity based on vertical velocity and direction of impact // Apply wall friction - stronger when in wall contact and proportional to fruit size var wallFriction = 0.65 + (fruit.elasticity - 0.7) * 0.5; // More elastic (smaller) fruits get less wall friction fruit.angularVelocity *= wallFriction; fruit.angularVelocity *= fruit.groundAngularFriction; if (Math.abs(fruit.vx) > 1) { // Bounce sound removed } } // Floor collision - use cached values for better performance // Calculate the effective height based on fruit's rotation var cosAngle = Math.abs(Math.cos(fruit.rotation)); var sinAngle = Math.abs(Math.sin(fruit.rotation)); var effectiveHeight = fruitHalfHeight * cosAngle + fruitHalfWidth * sinAngle; var floorCollisionY = gameFloor.y - gameFloor.height / 2 - effectiveHeight; // Use the values we already calculated above if (fruit.y > floorCollisionY) { fruit.y = gameFloor.y - gameFloor.height / 2 - effectiveHeight; fruit.vy = -fruit.vy * fruit.elasticity; if (Math.abs(fruit.vx) > 0.5) { // Smaller fruits get more angular velocity from impacts var angularImpactMultiplier = 0.01 * (1 + (0.9 - fruit.elasticity) * 5); fruit.angularVelocity += fruit.vx * angularImpactMultiplier * (fruit.vy / Math.abs(fruit.vy || 1)); // Apply angular velocity based on horizontal velocity and direction of impact } // Smaller fruits should spin longer after impact var angularDamping = fruit.elasticity > 0.85 ? 0.85 : fruit.groundAngularFriction; fruit.angularVelocity *= angularDamping; // Smaller fruits take more time to come to rest var restThreshold = 1 + (fruit.elasticity - 0.7) * 10; if (Math.abs(fruit.vy) < restThreshold) { fruit.vy = 0; } // Angular rest threshold should also scale with elasticity var angularRestThreshold = 0.03 * (1 - (fruit.elasticity - 0.7) * 2); if (Math.abs(fruit.angularVelocity) < angularRestThreshold) { fruit.angularVelocity = 0; } if (Math.abs(fruit.vy) > 1) { // Bounce sound removed } } // Update last positions fruit.lastX = fruit.x; fruit.lastY = fruit.y; } // Check for fruit collisions checkFruitCollisions(); // Check game over conditions checkGameOver(); }; // Initialize the game initGame();

===================================================================
--- original.js
+++ change.js
@@ -542,9 +542,9 @@
 			var spacing = gameWidth / 4; // Divide by 4 to get 3 spaces between
 			var xPos = spacing * (i + 1); // Position at 1/4, 2/4, 3/4 of screen width
 			// Place fruits above the screen, with increased vertical spacing between them
 			apple.x = xPos;
-			apple.y = -apple.height - i * 400; // Add 400px gap between each fruit
+			apple.y = -apple.height - i * 200; // Add 400px gap between each fruit
 			// Make it dynamic so it drops
 			apple.isStatic = false;
 			// Apply standard drop physics - slightly randomize forces for natural effect
 			var forceMultiplier = 3.5 + (Math.random() * 1 - 0.5);

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