package power; import io.anuke.arc.util.Time; import io.anuke.mindustry.content.Items; import io.anuke.mindustry.content.Liquids; import io.anuke.mindustry.type.Item; import io.anuke.mindustry.type.Liquid; import io.anuke.mindustry.world.Tile; import io.anuke.mindustry.world.blocks.power.ItemLiquidGenerator; import org.junit.jupiter.api.*; import java.util.ArrayList; import static org.junit.jupiter.api.Assertions.assertEquals; import static org.junit.jupiter.api.Assertions.assertTrue; import static org.junit.jupiter.api.DynamicTest.dynamicTest; /** * This class tests generators which can process items, liquids or both. * All tests are run with a fixed delta of 0.5 so delta considerations can be tested as well. * Additionally, each PowerGraph::update() call will have its own thread frame, i.e. the method will never be called twice within the same frame. * Both of these constraints are handled by FakeThreadHandler within PowerTestFixture. * Any expected power amount (produced, consumed, buffered) should be affected by FakeThreadHandler.fakeDelta but satisfaction should not! */ public class ItemLiquidGeneratorTests extends PowerTestFixture{ private ItemLiquidGenerator generator; private Tile tile; private ItemLiquidGenerator.ItemLiquidGeneratorEntity entity; private final float fakeItemDuration = 60f; //ticks private final float maximumLiquidUsage = 0.5f; public void createGenerator(InputType inputType){ generator = new ItemLiquidGenerator(inputType != InputType.liquids, inputType != InputType.items, "fakegen"){ { powerProduction = 0.1f; itemDuration = fakeItemDuration; maxLiquidGenerate = maximumLiquidUsage; } @Override public float getItemEfficiency(Item item){ return item.flammability; } @Override public float getLiquidEfficiency(Liquid liquid){ return liquid.flammability; } }; tile = createFakeTile(0, 0, generator); entity = tile.entity(); } /** Tests the consumption and efficiency when being supplied with liquids. */ @TestFactory DynamicTest[] generatorWorksProperlyWithLiquidInput(){ // Execute all tests for the case where only liquids are accepted and for the case where liquids and items are accepted (but supply only liquids) InputType[] inputTypesToBeTested = new InputType[]{ InputType.liquids, InputType.any }; ArrayList tests = new ArrayList<>(); for(InputType inputType : inputTypesToBeTested){ tests.add(dynamicTest("01", () -> simulateLiquidConsumption(inputType, Liquids.oil, 0.0f, "No liquids provided"))); tests.add(dynamicTest("02", () -> simulateLiquidConsumption(inputType, Liquids.oil, maximumLiquidUsage / 4.0f, "Low oil provided"))); tests.add(dynamicTest("03", () -> simulateLiquidConsumption(inputType, Liquids.oil, maximumLiquidUsage * 1.0f, "Sufficient oil provided"))); tests.add(dynamicTest("04", () -> simulateLiquidConsumption(inputType, Liquids.oil, maximumLiquidUsage * 2.0f, "Excess oil provided"))); // Note: The generator will decline any other liquid since it's not flammable } DynamicTest[] testArray = new DynamicTest[tests.size()]; testArray = tests.toArray(testArray); return testArray; } void simulateLiquidConsumption(InputType inputType, Liquid liquid, float availableLiquidAmount, String parameterDescription){ final float baseEfficiency = liquid.flammability; final float expectedEfficiency = Math.min(1.0f, availableLiquidAmount / maximumLiquidUsage) * baseEfficiency; final float expectedConsumptionPerTick = Math.min(maximumLiquidUsage, availableLiquidAmount); final float expectedRemainingLiquidAmount = Math.max(0.0f, availableLiquidAmount - expectedConsumptionPerTick * Time.delta()); createGenerator(inputType); assertTrue(generator.acceptLiquid(tile, null, liquid, availableLiquidAmount), inputType + " | " + parameterDescription + ": Liquids which will be declined by the generator don't need to be tested - The code won't be called for those cases."); entity.liquids.add(liquid, availableLiquidAmount); entity.cons.update(); // Perform an update on the generator once - This should use up any resource up to the maximum liquid usage generator.update(tile); assertEquals(expectedRemainingLiquidAmount, entity.liquids.get(liquid), inputType + " | " + parameterDescription + ": Remaining liquid amount mismatch."); assertEquals(expectedEfficiency, entity.productionEfficiency, inputType + " | " + parameterDescription + ": Efficiency mismatch."); } /** Tests the consumption and efficiency when being supplied with items. */ @TestFactory DynamicTest[] generatorWorksProperlyWithItemInput(){ // Execute all tests for the case where only items are accepted and for the case where liquids and items are accepted (but supply only items) InputType[] inputTypesToBeTested = new InputType[]{ InputType.items, InputType.any }; ArrayList tests = new ArrayList<>(); for(InputType inputType : inputTypesToBeTested){ tests.add(dynamicTest("01", () -> simulateItemConsumption(inputType, Items.coal, 0, "No items provided"))); tests.add(dynamicTest("02", () -> simulateItemConsumption(inputType, Items.coal, 1, "Sufficient coal provided"))); tests.add(dynamicTest("03", () -> simulateItemConsumption(inputType, Items.coal, 10, "Excess coal provided"))); tests.add(dynamicTest("04", () -> simulateItemConsumption(inputType, Items.blastCompound, 1, "Blast compound provided"))); //dynamicTest("03", () -> simulateItemConsumption(inputType, Items.plastanium, 1, "Plastanium provided")), // Not accepted by generator due to low flammability tests.add(dynamicTest("05", () -> simulateItemConsumption(inputType, Items.sporePod, 1, "Biomatter provided"))); tests.add(dynamicTest("06", () -> simulateItemConsumption(inputType, Items.pyratite, 1, "Pyratite provided"))); } DynamicTest[] testArray = new DynamicTest[tests.size()]; testArray = tests.toArray(testArray); return testArray; } void simulateItemConsumption(InputType inputType, Item item, int amount, String parameterDescription){ final float expectedEfficiency = amount > 0 ? item.flammability : 0f; final float expectedRemainingItemAmount = Math.max(0, amount - 1); createGenerator(inputType); assertTrue(generator.acceptItem(item, tile, null), inputType + " | " + parameterDescription + ": Items which will be declined by the generator don't need to be tested - The code won't be called for those cases."); if(amount > 0){ entity.items.add(item, amount); } entity.cons.update(); // Perform an update on the generator once - This should use up one or zero items - dependent on if the item is accepted and available or not. generator.update(tile); assertEquals(expectedRemainingItemAmount, entity.items.get(item), inputType + " | " + parameterDescription + ": Remaining item amount mismatch."); assertEquals(expectedEfficiency, entity.productionEfficiency, inputType + " | " + parameterDescription + ": Efficiency mismatch."); } /** Makes sure the efficiency stays equal during the item duration. */ @Test void efficiencyRemainsConstantWithinItemDuration_ItemsOnly(){ testItemDuration(InputType.items); } /** Makes sure the efficiency stays equal during the item duration. */ @Test void efficiencyRemainsConstantWithinItemDuration_ItemsAndLiquids(){ testItemDuration(InputType.any); } void testItemDuration(InputType inputType){ createGenerator(inputType); // Burn a single coal and test for the duration entity.items.add(Items.coal, 1); entity.cons.update(); generator.update(tile); float expectedEfficiency = entity.productionEfficiency; float currentDuration = 0.0f; while((currentDuration += Time.delta()) <= fakeItemDuration){ generator.update(tile); assertEquals(expectedEfficiency, entity.productionEfficiency, "Duration: " + currentDuration); } generator.update(tile); assertEquals(0.0f, entity.productionEfficiency, "Duration: " + currentDuration); } enum InputType{ items, liquids, any } }