import { createResource, Resource } from "features/resources/resource"; import Formula, { calculateCost, calculateMaxAffordable, unrefFormulaSource } from "game/formulas/formulas"; import type { GenericFormula, InvertibleFormula } from "game/formulas/types"; import Decimal, { DecimalSource } from "util/bignum"; import { beforeAll, describe, expect, test } from "vitest"; import { ref } from "vue"; import "../utils"; type FormulaFunctions = keyof GenericFormula & keyof typeof Formula & keyof typeof Decimal; const testValues = [-1, "0", Decimal.dOne] as const; const invertibleZeroParamFunctionNames = [ "neg", "recip", "log10", "log2", "ln", "pow10", "exp", "sqr", "sqrt", "cube", "cbrt", "lambertw", "ssqrt", "sin", "cos", "tan", "asin", "acos", "atan", "sinh", "cosh", "tanh", "asinh", "acosh", "atanh", "slog", "tetrate", "iteratedexp" ] as const; const nonInvertibleZeroParamFunctionNames = [ "abs", "sign", "round", "floor", "ceil", "trunc", "pLog10", "absLog10", "factorial", "gamma", "lngamma" ] as const; const integrableZeroParamFunctionNames = [ "neg", "recip", "log10", "log2", "ln", "pow10", "exp", "sqr", "sqrt", "cube", "cbrt", "sin", "cos", "tan", "asin", "acos", "atan", "sinh", "cosh", "tanh", "asinh", "acosh", "atanh" ] as const; const nonIntegrableZeroParamFunctionNames = [ ...nonInvertibleZeroParamFunctionNames, "lambertw", "ssqrt" ] as const; const invertibleIntegralZeroPramFunctionNames = [ "recip", "log10", "log2", "ln", "pow10", "sqr", "sqrt", "cube", "cbrt" ] as const; const nonInvertibleIntegralZeroPramFunctionNames = [ ...nonIntegrableZeroParamFunctionNames, "neg", "exp", "sin", "cos", "tan", "asin", "acos", "atan", "sinh", "cosh", "tanh", "asinh", "acosh", "atanh" ] as const; const invertibleOneParamFunctionNames = [ "add", "sub", "mul", "div", "log", "pow", "root", "layeradd" ] as const; const nonInvertibleOneParamFunctionNames = ["layeradd10"] as const; const integrableOneParamFunctionNames = ["add", "sub", "mul", "div", "log", "pow", "root"] as const; const nonIntegrableOneParamFunctionNames = [...nonInvertibleOneParamFunctionNames, "slog"] as const; const invertibleIntegralOneParamFunctionNames = integrableOneParamFunctionNames; const nonInvertibleIntegralOneParamFunctionNames = nonIntegrableOneParamFunctionNames; const nonInvertibleTwoParamFunctionNames = ["iteratedlog", "pentate"] as const; const nonIntegrableTwoParamFunctionNames = nonInvertibleTwoParamFunctionNames; const nonInvertibleIntegralTwoParamFunctionNames = nonIntegrableTwoParamFunctionNames; describe("Formula Equality Checking", () => { describe("Equality Checks", () => { test("Equals", () => expect(Formula.add(1, 1).equals(Formula.add(1, 1))).toBe(true)); test("Not Equals due to inputs", () => expect(Formula.add(1, 1).equals(Formula.add(1, 0))).toBe(false)); test("Not Equals due to functions", () => expect(Formula.add(1, 1).equals(Formula.sub(1, 1))).toBe(false)); test("Not Equals due to hasVariable", () => expect(Formula.constant(1).equals(Formula.variable(1))).toBe(false)); }); describe("Formula aliases", () => { function testAliases( aliases: T[], args: Parameters ) { describe(aliases[0], () => { let formula: GenericFormula; beforeAll(() => { // eslint-disable-next-line @typescript-eslint/ban-ts-comment // @ts-ignore formula = Formula[aliases[0]](...args); }); aliases.slice(1).forEach(alias => { // eslint-disable-next-line @typescript-eslint/ban-ts-comment // @ts-ignore test(alias, () => expect(Formula[alias](...args).equals(formula)).toBe(true)); }); }); } testAliases(["neg", "negate", "negated"], [1]); testAliases(["recip", "reciprocal", "reciprocate"], [1]); testAliases(["sign", "sgn"], [1]); testAliases(["add", "plus"], [1, 1]); testAliases(["sub", "subtract", "minus"], [1, 1]); testAliases(["mul", "multiply", "times"], [1, 1]); testAliases(["div", "divide"], [1, 1]); testAliases(["log", "logarithm"], [1, 1]); }); describe("Instance vs Static methods", () => { let formula: GenericFormula; beforeAll(() => { formula = Formula.constant(10); }); [...invertibleZeroParamFunctionNames, ...nonInvertibleZeroParamFunctionNames].forEach( name => { test(name, () => { const instanceFormula = formula[name](); const staticFormula = Formula[name](formula); expect(instanceFormula.equals(staticFormula)).toBe(true); }); } ); [...invertibleOneParamFunctionNames, ...nonInvertibleOneParamFunctionNames].forEach( name => { test(name, () => { const instanceFormula = formula[name](10); const staticFormula = Formula[name](formula, 10); expect(instanceFormula.equals(staticFormula)).toBe(true); }); } ); }); }); describe("Creating Formulas", () => { describe("Constants", () => { function testConstant( desc: string, formulaFunc: () => InvertibleFormula, expectedValue: DecimalSource = 10 ) { describe(desc, () => { let formula: GenericFormula; beforeAll(() => { formula = formulaFunc(); }); test("Is not invertible", () => expect(formula.isInvertible()).toBe(false)); test("Is not integrable", () => expect(formula.isIntegrable()).toBe(false)); test("Integral is not invertible", () => expect(formula.isIntegralInvertible()).toBe(false)); test("Is not marked as having a variable", () => expect(formula.hasVariable()).toBe(false)); test("Evaluates correctly", () => expect(formula.evaluate()).compare_tolerance(expectedValue)); test("Invert throws", () => expect(() => formula.invert(25)).toThrow()); test("Integrate throws", () => expect(() => formula.evaluateIntegral()).toThrow()); test("Invert integral throws", () => expect(() => formula.invertIntegral(25)).toThrow()); }); } testConstant("number", () => Formula.constant(10)); testConstant("string", () => Formula.constant("10")); testConstant("decimal", () => Formula.constant(new Decimal("1e400")), "1e400"); testConstant("ref", () => Formula.constant(ref(10))); }); function checkFormula( functionName: T, args: Readonly> ) { let formula: GenericFormula; beforeAll(() => { // eslint-disable-next-line @typescript-eslint/ban-ts-comment // @ts-ignore formula = Formula[functionName](...args); }); // None of these formulas have variables, so they should all behave the same test("Is not marked as having a variable", () => expect(formula.hasVariable()).toBe(false)); test("Is not invertible", () => expect(formula.isInvertible()).toBe(false)); test(`Formula throws if trying to invert`, () => expect(() => formula.invert(10)).toThrow()); test("Is not integrable", () => expect(formula.isIntegrable()).toBe(false)); test("Has a non-invertible integral", () => expect(formula.isIntegralInvertible()).toBe(false)); } // Utility function that will test all the different // It's a lot of tests, but I'd rather be exhaustive function testFormulaCall( functionName: T, args: Readonly> ) { let testName = functionName + "("; for (let i = 0; i < args.length; i++) { if (i !== 0) { testName += ", "; } testName += args[i]; } testName += ") evaluates correctly"; test(testName, () => { // eslint-disable-next-line @typescript-eslint/ban-ts-comment // @ts-ignore const formula = Formula[functionName](...args); try { const expectedEvaluation = Decimal[functionName]( // eslint-disable-next-line @typescript-eslint/ban-ts-comment // @ts-ignore ...args.map(i => unrefFormulaSource(i)) ); if (expectedEvaluation != null) { expect(formula.evaluate()).compare_tolerance(expectedEvaluation); } } catch { // If this is an invalid Decimal operation, then ignore this test case } }); } describe("0-param", () => { [...invertibleZeroParamFunctionNames, ...nonInvertibleZeroParamFunctionNames].forEach( names => describe(names, () => { checkFormula(names, [0] as const); testValues.forEach(i => testFormulaCall(names, [i] as const)); }) ); }); describe("1-param", () => { ( [ ...invertibleOneParamFunctionNames, ...nonInvertibleOneParamFunctionNames, "max", "min", "maxabs", "minabs", "clampMin", "clampMax" ] as const ).forEach(names => describe(names, () => { checkFormula(names, [0, 0] as const); testValues.forEach(i => testValues.forEach(j => testFormulaCall(names, [i, j] as const)) ); }) ); }); describe("2-param", () => { ([...nonInvertibleTwoParamFunctionNames, "clamp"] as const).forEach(names => describe(names, () => { checkFormula(names, [0, 0, 0] as const); testValues.forEach(i => testValues.forEach(j => testValues.forEach(k => testFormulaCall(names, [i, j, k] as const)) ) ); }) ); }); }); describe("Variables", () => { let variable: GenericFormula; let constant: GenericFormula; beforeAll(() => { variable = Formula.variable(10); constant = Formula.constant(10); }); test("Created variable is marked as a variable", () => expect(variable.hasVariable()).toBe(true)); test("evaluate() returns variable's value", () => expect(variable.evaluate()).compare_tolerance(10)); test("evaluate(variable) overrides variable value", () => expect(variable.add(10).evaluate(20)).compare_tolerance(30)); test("Nested variable is marked as having a variable", () => expect(variable.add(10).div(3).pow(2).hasVariable()).toBe(true)); test("Nested non-variable is marked as not having a variable", () => expect(constant.add(10).div(3).pow(2).hasVariable()).toBe(false)); }); describe("Inverting", () => { let variable: GenericFormula; let constant: GenericFormula; beforeAll(() => { variable = Formula.variable(10); constant = Formula.constant(10); }); test("variable.invert() is pass-through", () => expect(variable.invert(100)).compare_tolerance(100)); describe("Invertible Formulas correctly calculate when they contain a variable", () => { function checkFormula(formula: GenericFormula, expectedBool = true) { expect(formula.isInvertible()).toBe(expectedBool); expect(formula.hasVariable()).toBe(expectedBool); } invertibleZeroParamFunctionNames.forEach(name => { describe(name, () => { test(`${name}(var) is marked as invertible and having a variable`, () => checkFormula(Formula[name](variable))); }); }); invertibleOneParamFunctionNames.forEach(name => { describe(name, () => { test(`${name}(var, const) is marked as invertible and having a variable`, () => checkFormula(Formula[name](variable, constant))); test(`${name}(const, var) is marked as invertible and having a variable`, () => checkFormula(Formula[name](constant, variable))); test(`${name}(var, var) is marked as not invertible and not having a variable`, () => checkFormula(Formula[name](variable, variable), false)); }); }); }); describe("Non-invertible formulas marked as such", () => { function checkFormula(formula: GenericFormula) { expect(formula.isInvertible()).toBe(false); expect(formula.isIntegrable()).toBe(false); expect(formula.isIntegralInvertible()).toBe(false); } nonInvertibleZeroParamFunctionNames.forEach(name => { describe(name, () => { test(`${name}(var) is marked as not invertible`, () => checkFormula(Formula[name](variable))); }); }); nonInvertibleOneParamFunctionNames.forEach(name => { describe(name, () => { test(`${name}(var, const) is marked as not invertible`, () => checkFormula(Formula[name](variable, constant))); test(`${name}(const, var) is marked as not invertible`, () => checkFormula(Formula[name](constant, variable))); test(`${name}(var, var) is marked as not invertible`, () => checkFormula(Formula[name](variable, variable))); }); }); nonInvertibleTwoParamFunctionNames.forEach(name => { describe(name, () => { test(`${name}(var, const, const) is marked as not invertible`, () => checkFormula(Formula[name](variable, constant, constant))); test(`${name}(const, var, const) is marked as not invertible`, () => checkFormula(Formula[name](constant, variable, constant))); test(`${name}(const, const, var) is marked as not invertible`, () => checkFormula(Formula[name](constant, constant, variable))); test(`${name}(var, var, const) is marked as not invertible`, () => checkFormula(Formula[name](variable, variable, constant))); test(`${name}(var, const, var) is marked as not invertible`, () => checkFormula(Formula[name](variable, constant, variable))); test(`${name}(const, var, var) is marked as not invertible`, () => checkFormula(Formula[name](constant, variable, variable))); test(`${name}(var, var, var) is marked as not invertible`, () => checkFormula(Formula[name](variable, variable, variable))); }); }); }); describe("Inverting calculates the value of the variable", () => { let variable: GenericFormula; let constant: GenericFormula; beforeAll(() => { variable = Formula.variable(2); constant = Formula.constant(3); }); invertibleOneParamFunctionNames.forEach(name => describe(name, () => { test(`${name}(var, const).invert()`, () => { const formula = Formula[name](variable, constant); const result = formula.evaluate(); expect(formula.invert(result)).compare_tolerance(2); }); if (name !== "layeradd") { test(`${name}(const, var).invert()`, () => { const formula = Formula[name](constant, variable); const result = formula.evaluate(); expect(formula.invert(result)).compare_tolerance(2); }); } }) ); }); describe("Inverting pass-throughs", () => { test("max", () => expect(Formula.max(variable, constant).invert(10)).compare_tolerance(10)); test("min", () => expect(Formula.min(variable, constant).invert(10)).compare_tolerance(10)); test("minabs", () => expect(Formula.minabs(variable, constant).invert(10)).compare_tolerance(10)); test("maxabs", () => expect(Formula.maxabs(variable, constant).invert(10)).compare_tolerance(10)); test("clampMax", () => expect(Formula.clampMax(variable, constant).invert(10)).compare_tolerance(10)); test("clampMin", () => expect(Formula.clampMin(variable, constant).invert(10)).compare_tolerance(10)); test("clamp", () => expect(Formula.clamp(variable, constant, constant).invert(10)).compare_tolerance(10)); }); test("Inverting nested formulas", () => { const formula = Formula.add(variable, constant).times(constant); expect(formula.invert(100)).compare_tolerance(0); }); test("Inverting with non-invertible sections", () => { const formula = Formula.add(variable, constant.ceil()); expect(formula.isInvertible()).toBe(true); expect(formula.invert(10)).compare_tolerance(0); }); }); describe("Integrating", () => { let variable: GenericFormula; let constant: GenericFormula; beforeAll(() => { variable = Formula.variable(ref(10)); constant = Formula.constant(10); }); test("variable.evaluateIntegral() calculates correctly", () => expect(variable.evaluateIntegral()).compare_tolerance(Decimal.pow(10, 2).div(2))); test("evaluateIntegral(variable) overrides variable value", () => expect(variable.add(10).evaluateIntegral(20)).compare_tolerance(400)); describe("Integrable functions marked as such", () => { function checkFormula(formula: GenericFormula) { expect(formula.isIntegrable()).toBe(true); expect(() => formula.evaluateIntegral()).to.not.throw(); } integrableZeroParamFunctionNames.forEach(name => { describe(name, () => { test(`${name}(var) is marked as integrable`, () => checkFormula(Formula[name](variable))); }); }); integrableOneParamFunctionNames.forEach(name => { describe(name, () => { test(`${name}(var, const) is marked as integrable`, () => checkFormula(Formula[name](variable, constant))); if (name !== "log" && name !== "root") { test(`${name}(const, var) is marked as integrable`, () => checkFormula(Formula[name](constant, variable))); } test(`${name}(var, var) is marked as not integrable`, () => expect(Formula[name](variable, variable).isIntegrable()).toBe(false)); }); }); }); describe("Non-Integrable functions marked as such", () => { function checkFormula(formula: GenericFormula) { expect(formula.isIntegrable()).toBe(false); } nonIntegrableZeroParamFunctionNames.forEach(name => { describe(name, () => { test(`${name}(var) is marked as not integrable`, () => checkFormula(Formula[name](variable))); }); }); nonIntegrableOneParamFunctionNames.forEach(name => { describe(name, () => { test(`${name}(var, const) is marked as not integrable`, () => checkFormula(Formula[name](variable, constant))); test(`${name}(const, var) is marked as not integrable`, () => checkFormula(Formula[name](constant, variable))); test(`${name}(var, var) is marked as not integrable`, () => checkFormula(Formula[name](variable, variable))); }); }); nonIntegrableTwoParamFunctionNames.forEach(name => { describe(name, () => { test(`${name}(var, const, const) is marked as not integrable`, () => checkFormula(Formula[name](variable, constant, constant))); test(`${name}(const, var, const) is marked as not integrable`, () => checkFormula(Formula[name](constant, variable, constant))); test(`${name}(const, const, var) is marked as not integrable`, () => checkFormula(Formula[name](constant, constant, variable))); test(`${name}(var, var, const) is marked as not integrable`, () => checkFormula(Formula[name](variable, variable, constant))); test(`${name}(var, const, var) is marked as not integrable`, () => checkFormula(Formula[name](variable, constant, variable))); test(`${name}(const, var, var) is marked as not integrable`, () => checkFormula(Formula[name](constant, variable, variable))); test(`${name}(var, var, var) is marked as not integrable`, () => checkFormula(Formula[name](variable, variable, variable))); }); }); }); // TODO I think these tests will require writing at least one known example for every function describe.todo("Integrable formulas integrate correctly"); test("Integrating nested formulas", () => { const formula = Formula.add(variable, constant).times(constant).pow(2).times(30); const actualCost = new Array(10) .fill(null) .reduce((acc, _, i) => acc.add(formula.evaluate(i)), new Decimal(0)); // Check if the calculated cost is within 10% of the actual cost, // because this is an approximation expect( Decimal.sub(actualCost, formula.evaluateIntegral()).abs().div(actualCost).toNumber() ).toBeLessThan(0.1); }); test("Integrating nested complex formulas", () => { const formula = Formula.pow(1.05, variable).times(100).pow(0.5); expect(() => formula.evaluateIntegral()).toThrow(); }); }); describe("Inverting integrals", () => { let variable: GenericFormula; let constant: GenericFormula; beforeAll(() => { variable = Formula.variable(10); constant = Formula.constant(10); }); test("variable.invertIntegral() calculates correctly", () => expect(variable.invertIntegral(20)).compare_tolerance( Decimal.sqrt(20).times(Decimal.sqrt(2)) )); describe("Invertible Integral functions marked as such", () => { function checkFormula(formula: GenericFormula) { expect(formula.isIntegralInvertible()).toBe(true); expect(() => formula.invertIntegral(10)).to.not.throw(); } invertibleIntegralZeroPramFunctionNames.forEach(name => { describe(name, () => { test(`${name}(var) is marked as having an invertible integral`, () => checkFormula(Formula[name](variable))); }); }); invertibleIntegralOneParamFunctionNames.forEach(name => { describe(name, () => { test(`${name}(var, const) is marked as having an invertible integral`, () => checkFormula(Formula[name](variable, constant))); if (name !== "log" && name !== "root") { test(`${name}(const, var) is marked as having an invertible integral`, () => checkFormula(Formula[name](constant, variable))); } test(`${name}(var, var) is marked as not having an invertible integral`, () => { const formula = Formula[name](variable, variable); expect(formula.isIntegralInvertible()).toBe(false); expect(() => formula.invertIntegral(10)).to.throw(); }); }); }); }); describe("Non-Invertible integral functions marked as such", () => { function checkFormula(formula: GenericFormula) { expect(formula.isIntegralInvertible()).toBe(false); } nonInvertibleIntegralZeroPramFunctionNames.forEach(name => { describe(name, () => { test(`${name}(var) is marked as not having an invertible integral`, () => checkFormula(Formula[name](variable))); }); }); nonInvertibleIntegralOneParamFunctionNames.forEach(name => { describe(name, () => { test(`${name}(var, const) is marked as not having an invertible integral`, () => checkFormula(Formula[name](variable, constant))); test(`${name}(const, var) is marked as not having an invertible integral`, () => checkFormula(Formula[name](constant, variable))); test(`${name}(var, var) is marked as not having an invertible integral`, () => checkFormula(Formula[name](variable, variable))); }); }); nonInvertibleIntegralTwoParamFunctionNames.forEach(name => { describe(name, () => { test(`${name}(var, const, const) is marked as not having an invertible integral`, () => checkFormula(Formula[name](variable, constant, constant))); test(`${name}(const, var, const) is marked as not having an invertible integral`, () => checkFormula(Formula[name](constant, variable, constant))); test(`${name}(const, const, var) is marked as not having an invertible integral`, () => checkFormula(Formula[name](constant, constant, variable))); test(`${name}(var, var, const) is marked as not having an invertible integral`, () => checkFormula(Formula[name](variable, variable, constant))); test(`${name}(var, const, var) is marked as not having an invertible integral`, () => checkFormula(Formula[name](variable, constant, variable))); test(`${name}(const, var, var) is marked as not having an invertible integral`, () => checkFormula(Formula[name](constant, variable, variable))); test(`${name}(var, var, var) is marked as not having an invertible integral`, () => checkFormula(Formula[name](variable, variable, variable))); }); }); }); // TODO I think these tests will require writing at least one known example for every function describe.todo("Invertible Integral formulas invert correctly"); test("Inverting integral of nested formulas", () => { const formula = Formula.add(variable, constant).times(constant).pow(2).times(30); expect(formula.invertIntegral(formula.evaluateIntegral())).compare_tolerance(10); }); test("Inverting integral of nested complex formulas", () => { const formula = Formula.pow(1.05, variable).times(100).pow(0.5); expect(() => formula.invertIntegral(100)).toThrow(); }); describe("Inverting integral pass-throughs", () => { test("max", () => expect(Formula.max(variable, constant).invertIntegral(10)).compare_tolerance(10)); test("min", () => expect(Formula.min(variable, constant).invertIntegral(10)).compare_tolerance(10)); test("minabs", () => expect(Formula.minabs(variable, constant).invertIntegral(10)).compare_tolerance(10)); test("maxabs", () => expect(Formula.maxabs(variable, constant).invertIntegral(10)).compare_tolerance(10)); test("clampMax", () => expect(Formula.clampMax(variable, constant).invertIntegral(10)).compare_tolerance(10)); test("clampMin", () => expect(Formula.clampMin(variable, constant).invertIntegral(10)).compare_tolerance(10)); test("clamp", () => expect( Formula.clamp(variable, constant, constant).invertIntegral(10) ).compare_tolerance(10)); }); }); describe("Step-wise", () => { let variable: GenericFormula; let constant: GenericFormula; beforeAll(() => { variable = Formula.variable(10); constant = Formula.constant(10); }); test("Formula without variable is marked as such", () => { expect(Formula.step(constant, 10, value => Formula.sqrt(value)).isInvertible()).toBe(false); expect(Formula.step(constant, 10, value => Formula.sqrt(value)).hasVariable()).toBe(false); }); test("Formula with variable is marked as such", () => { expect(Formula.step(variable, 10, value => Formula.sqrt(value)).isInvertible()).toBe(true); expect(Formula.step(variable, 10, value => Formula.sqrt(value)).hasVariable()).toBe(true); }); test("Non-invertible formula modifier marks formula as such", () => { expect(Formula.step(constant, 10, value => Formula.abs(value)).isInvertible()).toBe(false); expect(Formula.step(constant, 10, value => Formula.abs(value)).hasVariable()).toBe(false); }); test("Formula never marked integrable", () => { expect(Formula.step(constant, 10, value => Formula.add(value, 10)).isIntegrable()).toBe( false ); expect(() => Formula.step(constant, 10, value => Formula.add(value, 10)).evaluateIntegral() ).toThrow(); }); test("Formula never marked as having an invertible integral", () => { expect( Formula.step(constant, 10, value => Formula.add(value, 10)).isIntegralInvertible() ).toBe(false); expect(() => Formula.step(constant, 10, value => Formula.add(value, 10)).invertIntegral(10) ).toThrow(); }); test("Formula modifiers with variables mark formula as non-invertible", () => { expect( Formula.step(constant, 10, value => Formula.add(value, variable)).isInvertible() ).toBe(false); expect( Formula.step(constant, 10, value => Formula.add(value, variable)).hasVariable() ).toBe(false); }); describe("Pass-through underneath start", () => { test("Evaluates correctly", () => expect( Formula.step(constant, 20, value => Formula.sqrt(value)).evaluate() ).compare_tolerance(10)); test("Inverts correctly with variable in input", () => expect( Formula.step(variable, 20, value => Formula.sqrt(value)).invert(10) ).compare_tolerance(10)); }); describe("Pass-through at boundary", () => { test("Evaluates correctly", () => expect( Formula.step(constant, 10, value => Formula.sqrt(value)).evaluate() ).compare_tolerance(10)); test("Inverts correctly with variable in input", () => expect( Formula.step(variable, 10, value => Formula.sqrt(value)).invert(10) ).compare_tolerance(10)); }); describe("Evaluates correctly beyond start", () => { test("Evaluates correctly", () => expect( Formula.step(variable, 8, value => Formula.add(value, 2)).evaluate() ).compare_tolerance(12)); test("Inverts correctly", () => expect( Formula.step(variable, 8, value => Formula.add(value, 2)).invert(12) ).compare_tolerance(10)); }); describe("Evaluates correctly when nested", () => { test("Evaluates correctly", () => expect( Formula.add(variable, constant) .step(10, value => Formula.mul(value, 2)) .sub(10) .evaluate() ).compare_tolerance(20)); test("Inverts correctly", () => expect( Formula.add(variable, constant) .step(10, value => Formula.mul(value, 2)) .sub(10) .invert(30) ).compare_tolerance(15)); }); }); describe("Conditionals", () => { let variable: GenericFormula; let constant: GenericFormula; beforeAll(() => { variable = Formula.variable(10); constant = Formula.constant(10); }); test("Formula without variable is marked as such", () => { expect(Formula.if(constant, true, value => Formula.sqrt(value)).isInvertible()).toBe(false); expect(Formula.if(constant, true, value => Formula.sqrt(value)).hasVariable()).toBe(false); }); test("Formula with variable is marked as such", () => { expect(Formula.if(variable, true, value => Formula.sqrt(value)).isInvertible()).toBe(true); expect(Formula.if(variable, true, value => Formula.sqrt(value)).hasVariable()).toBe(true); }); test("Non-invertible formula modifier marks formula as such", () => { expect(Formula.if(constant, true, value => Formula.abs(value)).isInvertible()).toBe(false); expect(Formula.if(constant, true, value => Formula.abs(value)).hasVariable()).toBe(false); }); test("Formula never marked integrable", () => { expect(Formula.if(constant, true, value => Formula.add(value, 10)).isIntegrable()).toBe( false ); expect(() => Formula.if(constant, true, value => Formula.add(value, 10)).evaluateIntegral() ).toThrow(); }); test("Formula never marked as having an invertible integral", () => { expect( Formula.if(constant, true, value => Formula.add(value, 10)).isIntegralInvertible() ).toBe(false); expect(() => Formula.if(constant, true, value => Formula.add(value, 10)).invertIntegral(10) ).toThrow(); }); test("Formula modifiers with variables mark formula as non-invertible", () => { expect( Formula.if(constant, true, value => Formula.add(value, variable)).isInvertible() ).toBe(false); expect( Formula.if(constant, true, value => Formula.add(value, variable)).hasVariable() ).toBe(false); }); describe("Pass-through with condition false", () => { test("Evaluates correctly", () => expect( Formula.if(constant, false, value => Formula.sqrt(value)).evaluate() ).compare_tolerance(10)); test("Inverts correctly with variable in input", () => expect( Formula.if(variable, false, value => Formula.sqrt(value)).invert(10) ).compare_tolerance(10)); }); describe("Evaluates correctly with condition true", () => { test("Evaluates correctly", () => expect( Formula.if(variable, true, value => Formula.add(value, 2)).evaluate() ).compare_tolerance(12)); test("Inverts correctly", () => expect( Formula.if(variable, true, value => Formula.add(value, 2)).invert(12) ).compare_tolerance(10)); }); describe("Evaluates correctly when nested", () => { test("Evaluates correctly", () => expect( Formula.add(variable, constant) .if(true, value => Formula.add(value, 2)) .div(2) .evaluate() ).compare_tolerance(11)); test("Inverts correctly", () => expect( Formula.add(variable, constant) .if(true, value => Formula.add(value, 2)) .div(2) .invert(12) ).compare_tolerance(12)); }); }); describe("Custom Formulas", () => { let variable: GenericFormula; beforeAll(() => { variable = Formula.variable(1); }); describe("Formula with evaluate", () => { test("Zero input evaluates correctly", () => expect(new Formula({ inputs: [], evaluate: () => 10 }).evaluate()).compare_tolerance( 10 )); test("One input evaluates correctly", () => expect( new Formula({ inputs: [1], evaluate: value => value }).evaluate() ).compare_tolerance(1)); test("Two inputs evaluates correctly", () => expect( new Formula({ inputs: [1, 2], evaluate: (v1, v2) => v1 }).evaluate() ).compare_tolerance(1)); }); describe("Formula with invert", () => { test("Zero input does not invert", () => expect(() => new Formula({ inputs: [], evaluate: () => 6, invert: value => value, hasVariable: true }).invert(10) ).toThrow()); test("One input inverts correctly", () => expect( new Formula({ inputs: [variable], evaluate: () => 10, invert: (value, v1) => v1.evaluate(), hasVariable: true }).invert(10) ).compare_tolerance(1)); test("Two inputs inverts correctly", () => expect( new Formula({ inputs: [variable, 2], evaluate: () => 10, invert: (value, v1, v2) => v2, hasVariable: true }).invert(10) ).compare_tolerance(2)); }); describe("Formula with integrate", () => { test("Zero input integrates correctly", () => expect( new Formula({ inputs: [], evaluate: () => 10, integrate: variable => variable }).evaluateIntegral() ).compare_tolerance(20)); test("One input integrates correctly", () => expect( new Formula({ inputs: [variable], evaluate: () => 10, integrate: (variable, stack, v1) => Formula.add(variable, v1) }).evaluateIntegral() ).compare_tolerance(20)); test("Two inputs integrates correctly", () => expect( new Formula({ inputs: [variable, 2], evaluate: (v1, v2) => 10, integrate: (variable, v1, v2) => variable }).evaluateIntegral() ).compare_tolerance(3)); }); describe("Formula with invertIntegral", () => { test("Zero input does not invert integral", () => expect(() => new Formula({ inputs: [], evaluate: () => 10, integrate: variable => variable, hasVariable: true }).invertIntegral(8) ).toThrow()); test("One input inverts integral correctly", () => expect( new Formula({ inputs: [variable], evaluate: () => 10, integrate: (variable, stack, v1) => variable, hasVariable: true }).invertIntegral(8) ).compare_tolerance(1)); test("Two inputs inverts integral correctly", () => expect( new Formula({ inputs: [variable, 2], evaluate: (v1, v2) => 10, integrate: (variable, v1, v2) => variable, hasVariable: true }).invertIntegral(8) ).compare_tolerance(1)); }); describe.todo("Formula as input"); describe.todo("Determines invertibility etc. correctly"); }); describe("Buy Max", () => { let resource: Resource; beforeAll(() => { resource = createResource(ref(1000)); }); describe("Without spending", () => { test("Throws on formula with non-invertible integral", () => { const maxAffordable = calculateMaxAffordable(Formula.neg(10), resource, false); expect(() => maxAffordable.value).toThrow(); }); // https://www.desmos.com/calculator/7ffthe7wi8 test("Calculates max affordable and cost correctly", () => { const variable = Formula.variable(0); const formula = Formula.pow(1.05, variable).times(100); const maxAffordable = calculateMaxAffordable(formula, resource, false); expect(maxAffordable.value).compare_tolerance(47); expect(calculateCost(formula, maxAffordable.value, false)).compare_tolerance( Decimal.pow(1.05, 47).times(100) ); }); }); describe("With spending", () => { test("Throws on non-invertible formula", () => { const maxAffordable = calculateMaxAffordable(Formula.abs(10), resource); expect(() => maxAffordable.value).toThrow(); }); // https://www.desmos.com/calculator/7ffthe7wi8 test("Calculates max affordable and cost correctly", () => { const variable = Formula.variable(0); const formula = Formula.pow(1.05, variable).times(100); const maxAffordable = calculateMaxAffordable(formula, resource); expect(maxAffordable.value).compare_tolerance(7); const actualCost = new Array(7) .fill(null) .reduce((acc, _, i) => acc.add(formula.evaluate(i)), new Decimal(0)); const calculatedCost = calculateCost(formula, maxAffordable.value); // Check if the calculated cost is within 10% of the actual cost, // because this is an approximation expect( Decimal.sub(actualCost, calculatedCost).abs().div(actualCost).toNumber() ).toBeLessThan(0.1); }); }); });