tanner/bangle
1
0
Fork 0
Code Issues Pull Requests Packages Projects Releases Wiki Activity
Files
d2c4be15d07a07c8417990e6464d51c8fb3fd5c3
bangle/calculator/test.js
T
tanner d2c4be15d0 test: Expand Pi button test coverage 
Co-authored-by: aider (gemini/gemini-2.5-pro) <aider@aider.chat>
2026-06-13 16:13:48 -06:00

590 lines
15 KiB
JavaScript
Raw Blame History

const fs = require('fs');
const path = require('path');
const assert = require('assert');
// --- Mock Bangle.js environment ---
let mock_display_str = "";
let mock_ui_callbacks = {};
let drawn_since_clear = false;
global.last_display_num = null;
// Mock 'g' (graphics)
global.g = {
_col: 0,
_bg: 0,
_font: "6x8",
_font_size: 1,
clear: () => { drawn_since_clear = false; },
clearRect: () => { drawn_since_clear = false; },
setColor: (c) => { global.g._col = c; return global.g; },
setBgColor: (c) => { global.g._bg = c; return global.g; },
fillRect: () => {},
setFont: function(font, size) {
if (font && font.includes(":")) {
const parts = font.split(":");
this._font = parts[0];
this._font_size = parseInt(parts[1], 10);
} else {
this._font = font;
if (size) this._font_size = size;
}
return this;
},
setFontAlign: () => {},
stringWidth: (s) => s.length * 4.7 * (global.g._font_size || 1), // approximation to match watch
getWidth: () => 176,
getHeight: () => 176,
drawString: (s) => {
if (!drawn_since_clear) {
mock_display_str = String(s);
drawn_since_clear = true;
}
},
getFontHeight: () => 8 * (global.g._font_size || 1)
};
global.Graphics = {};
// Mock Bangle.js-specific process.env properties
process.env.HWVERSION = 2; // Simulate Bangle.js 2
// Mock 'Bangle'
global.Bangle = {
setUI: (callbacks) => { mock_ui_callbacks = callbacks; },
http: () => new Promise(resolve => resolve({resp: "{}"})),
buzz: () => {},
};
// Mock 'load' (to exit app)
global.load = () => {};
// --- End Mock ---
// --- Load calculator app ---
// We inject a "spy" to capture the raw value passed to displayOutput,
// making our tests independent of UI formatting.
let calculatorCode = fs.readFileSync(path.join(__dirname, 'calculator.app.js'), 'utf8');
// 1. Rename the original function so we can call it.
calculatorCode = calculatorCode.replace(
'function displayOutput(num)',
'function _original_displayOutput(num)'
);
// 2. Prepend our spy that captures the value and then calls the original.
const spyCode = `
var displayOutput = function(num) {
global.last_display_num = num;
_original_displayOutput(num);
};
`;
const processedCode = spyCode + calculatorCode;
const wrappedCode = `(function(require) { ${processedCode}; return { buttonPress, scientificOperators }; })`;
const getAppFns = eval(wrappedCode);
const { buttonPress, scientificOperators } = getAppFns((name) => {
if (name === "FontDylex7x13") {
return { add: () => {} };
}
return require(name);
});
// --- End Load ---
// --- Test Framework ---
const test_suite = [];
let tests_passed = 0;
let tests_failed = 0;
function test(name, fn) {
test_suite.push({ name, fn });
}
function runTests() {
test_suite.forEach(t => {
// Reset state before each test
buttonPress('R'); // C
buttonPress('R'); // AC
if (global.last_display_num !== 0) {
console.error(`[FAIL] ${t.name} - Failed to reset state. Last number is: "${global.last_display_num}"`);
tests_failed++;
return;
}
try {
t.fn();
console.log(`[PASS] ${t.name}`);
tests_passed++;
} catch (e) {
console.error(`[FAIL] ${t.name}`);
console.error(e);
tests_failed++;
}
});
console.log(`\nTests finished. Passed: ${tests_passed}, Failed: ${tests_failed}.`);
if (tests_failed > 0) {
process.exit(1);
}
}
function press(buttons) {
for (const button of buttons) {
buttonPress(button);
}
}
function checkDisplay(expected, message) {
const actual = global.last_display_num;
if (typeof expected === 'number' && isNaN(expected)) {
assert.ok(typeof actual === 'number' && isNaN(actual), message || `Expected NaN, got ${actual}`);
return;
}
// Coerce to numbers for comparison to handle string vs number differences ('5' vs 5)
// and use a tolerance for floating point values.
const actualNum = parseFloat(actual);
const expectedNum = parseFloat(expected);
if (!isNaN(actualNum) && !isNaN(expectedNum)) {
const tolerance = 1e-9;
if (Math.abs(expectedNum - actualNum) < tolerance || actualNum === expectedNum) { // second part handles Infinity
return; // The numbers are close enough.
}
}
// Fallback to strict equality for non-numeric strings or when numeric check fails
assert.strictEqual(actual, expected, message);
}
// --- End Test Framework ---
// --- Test Cases ---
const basicNumbers = [
0, 1, -1, 2, -2, 5, -5, 10, -10, 0.1, -0.1, 0.2, -0.2, 0.5, -0.5,
123, -123, 1.23, -1.23,
1234567, -1234567, 99999999, -99999999,
];
const edgeCaseNumbers = [
-0,
Number.MAX_SAFE_INTEGER,
Number.MIN_SAFE_INTEGER,
Math.PI, Math.E,
0.000001, -0.000001, 0.00000001, -0.00000001,
1000000, -1000000, 100000000, -100000000,
0.1+0.2, // floating point fun
1/3, 2/3, 0.9999999, 1.0000001
];
// Generate some more numbers to reach the target count
const generatedNumbers = [];
for (let i = 1; i <= 20; i++) {
// integers
generatedNumbers.push(i * 123);
generatedNumbers.push(i * -123);
// floats
generatedNumbers.push(i / 10);
generatedNumbers.push(i / -10);
// small floats
generatedNumbers.push(i / 1000);
generatedNumbers.push(i / -1000);
}
const testNumbers = [...new Set([...basicNumbers, ...edgeCaseNumbers, ...generatedNumbers])];
// We need to filter out Infinity/-Infinity for pressNumber helper as they can't be typed.
// They can only appear as results, which we test for separately.
const finiteTestNumbers = testNumbers.filter(n => isFinite(n));
// Helper to press a number, handling negatives
function pressNumber(n) {
let s = String(n);
// If string representation is in scientific notation, convert to decimal string
if (s.includes('e')) {
s = n.toFixed(20).replace(/0+$/, '').replace(/\.$/, '');
}
if (s.startsWith('-')) {
press(s.substring(1));
buttonPress('N');
} else {
press(s);
}
}
// --- Generated Tests: Binary Operations ---
const binaryOps = {
'+': (a, b) => a + b,
'-': (a, b) => a - b,
'*': (a, b) => a * b,
'/': (a, b) => a / b,
};
for (const op in binaryOps) {
for (const a of finiteTestNumbers) {
for (const b of finiteTestNumbers) {
if (op === '/' && b === 0) {
test(`Binary Edge Case: ${a} / 0`, () => {
pressNumber(a);
buttonPress('/');
pressNumber(0);
buttonPress('=');
checkDisplay(a === 0 ? NaN : (a > 0 ? Infinity : -Infinity));
});
continue;
}
test(`Binary: ${a} ${op} ${b}`, () => {
pressNumber(a);
buttonPress(op);
pressNumber(b);
buttonPress('=');
const expected = binaryOps[op](a, b);
checkDisplay(expected);
});
}
}
}
// --- Generated Tests: Operations with non-finite results ---
const smallFiniteTestNumbers = [1, -1, 5, -5, 0, 100, -100]; // for speed
// Test operations that result in Infinity, -Infinity, or NaN, and then continue with another operation
for (const a of smallFiniteTestNumbers) {
// a / 0 -> Infinity/-Infinity/NaN
test(`Non-finite chaining: (${a} / 0) + 5`, () => {
pressNumber(a);
press('/0=');
const intermediate = a/0;
checkDisplay(intermediate);
press('+5=');
checkDisplay(intermediate + 5);
});
test(`Non-finite chaining: (${a} / 0) * 5`, () => {
pressNumber(a);
press('/0=');
const intermediate = a/0;
checkDisplay(intermediate);
press('*5=');
checkDisplay(intermediate * 5);
});
test(`Non-finite chaining: (${a} / 0) * 0`, () => {
pressNumber(a);
press('/0=');
const intermediate = a/0;
checkDisplay(intermediate);
press('*0=');
checkDisplay(intermediate * 0); // Should be NaN
});
test(`Non-finite chaining: (${a} / 0) / 5`, () => {
pressNumber(a);
press('/0=');
const intermediate = a/0;
checkDisplay(intermediate);
press('/5=');
checkDisplay(intermediate / 5);
});
test(`Non-finite chaining: (${a} / 0) / 0`, () => {
pressNumber(a);
press('/0=');
const intermediate = a/0;
checkDisplay(intermediate);
press('/0=');
checkDisplay(intermediate / 0);
});
}
// 0/0 = NaN. Test operations on NaN
test(`Non-finite chaining: (0 / 0) + 5`, () => {
press('0/0=');
checkDisplay(NaN);
press('+5=');
checkDisplay(NaN + 5); // anything + NaN is NaN
});
test(`Non-finite chaining: (0 / 0) * 5`, () => {
press('0/0=');
checkDisplay(NaN);
press('*5=');
checkDisplay(NaN * 5);
});
test(`Non-finite chaining: (0 / 0) / 5`, () => {
press('0/0=');
checkDisplay(NaN);
press('/5=');
checkDisplay(NaN / 5);
});
test(`Non-finite chaining: sqrt(negative) then op`, () => {
press('9N'); // -9
press('r'); // sqrt
checkDisplay(NaN);
press('+1=');
checkDisplay(NaN);
});
// --- Generated Tests: Unary Operations ---
const unaryOps = {
'r': { name: 'sqrt', fn: Math.sqrt },
's': { name: 'x^2', fn: (a) => a * a },
'i': { name: '1/x', fn: (a) => 1 / a },
};
for (const op in unaryOps) {
for (const a of finiteTestNumbers) {
if (op === 'r' && a < 0) {
test(`Unary Edge Case: sqrt(${a})`, () => {
pressNumber(a);
buttonPress('r');
checkDisplay(NaN);
});
continue;
}
test(`Unary: ${unaryOps[op].name}(${a})`, () => {
pressNumber(a);
buttonPress(op);
const expected = unaryOps[op].fn(a);
checkDisplay(expected);
});
}
}
// --- Generated Tests: Chaining Operations ---
// To keep runtime sane, we'll pick a smaller subset for chaining
const chainNumbers = [0, 1, -1, 5, -5, 0.5, -0.5, 10, -10, 123, -123, 1.23];
const chainOps = ['+', '-', '*', '/'];
for (const a of chainNumbers) {
for (const b of chainNumbers) {
for (const c of chainNumbers) {
for (const op1 of chainOps) {
for (const op2 of chainOps) {
test(`Chaining: ${a} ${op1} ${b} ${op2} ${c}`, () => {
pressNumber(a);
buttonPress(op1);
pressNumber(b);
buttonPress(op2); // This will execute the first operation
pressNumber(c);
buttonPress('='); // This will execute the second operation
// Calculator does sequential evaluation: (a op1 b) op2 c
const expected = binaryOps[op2](binaryOps[op1](a, b), c);
checkDisplay(expected);
});
}
}
}
}
}
// --- Generated Tests: Trigonometry ---
const trigOps = {
'sin': { fn: Math.sin, name: 'sin' },
'cos': { fn: Math.cos, name: 'cos' },
'tan': { fn: Math.tan, name: 'tan' },
};
const trigAngles = [0, 15, 30, 45, 60, 75, 90, 180, 270, 360, -30, -45, -90, -180, 450, 720, Math.PI/6, Math.PI/4, Math.PI/3, Math.PI/2, Math.PI, 3*Math.PI/2, 2*Math.PI, -Math.PI/2, -Math.PI];
// Test in DEG mode (default)
for (const op in trigOps) {
for (const angle of trigAngles) {
test(`Trig (deg): ${trigOps[op].name}(${angle})`, () => {
pressNumber(angle);
buttonPress(op);
const expected = trigOps[op].fn(angle * Math.PI / 180);
checkDisplay(expected);
});
}
}
// Test in RAD mode
test('Switch to RAD mode', () => {
buttonPress('angleMode');
assert.strictEqual(scientificOperators.angleMode.val, 'rad');
});
for (const op in trigOps) {
for (const angle of trigAngles) {
test(`Trig (rad): ${trigOps[op].name}(${angle})`, () => {
pressNumber(angle);
buttonPress(op);
const expected = trigOps[op].fn(angle);
checkDisplay(expected);
});
}
}
test('Switch back to DEG mode for subsequent tests', () => {
buttonPress('angleMode');
assert.strictEqual(scientificOperators.angleMode.val, 'deg');
});
// --- Specific Functionality Tests ---
test('Clear and All Clear', () => {
press('123+');
checkDisplay('123');
press('R'); // Clear
checkDisplay('0');
press('456');
checkDisplay('456');
press('=');
checkDisplay('579'); // 123 + 456
press('R'); // Clear
checkDisplay('0');
buttonPress('R'); // All Clear
press('+1=');
checkDisplay('1');
});
test('Backspace', () => {
press('123.45B');
checkDisplay('123.4');
press('B');
checkDisplay('123.');
press('B');
checkDisplay('123');
press('B');
checkDisplay('12');
press('B');
checkDisplay('1');
press('B');
checkDisplay('0');
press('B');
checkDisplay('0');
});
test('Repeated equals', () => {
press('2+3=');
checkDisplay('5');
press('=');
checkDisplay('8');
press('=');
checkDisplay('11');
press('R'); press('R');
press('10-2=');
checkDisplay('8');
press('=');
checkDisplay('6');
});
test('Operator change', () => {
press('10+-*/2=');
checkDisplay('5'); // 10/2=5
});
test('Long number input', () => {
press('1234567');
checkDisplay('1234567');
});
test('Input starting with decimal point', () => {
press('.5');
checkDisplay('0.5');
press('*2=');
checkDisplay('1');
});
test('Negative zero handling', () => {
press('0N'); // get -0
checkDisplay(-0);
press('*5');
checkDisplay('5'); // after typing 5, display should be 5
press('=');
checkDisplay(-0); // -0 * 5 = -0
buttonPress('R'); buttonPress('R');
press('5*0N='); // 5 * -0 = -0
checkDisplay(-0);
});
test('Pi button', () => {
press('p');
checkDisplay(Math.PI);
press('*2=');
checkDisplay(Math.PI * 2);
});
test('Pi replaces current number entry', () => {
press('123p');
checkDisplay(Math.PI);
});
test('Operation with Pi', () => {
press('5*p=');
checkDisplay(5 * Math.PI);
});
test('Pi as second operand', () => {
press('2+p=');
checkDisplay(2 + Math.PI);
});
test('Chaining operations with Pi', () => {
press('p*2+3=');
checkDisplay(Math.PI * 2 + 3);
});
test('Unary operations on Pi', () => {
press('p');
checkDisplay(Math.PI);
press('r'); // sqrt
checkDisplay(Math.sqrt(Math.PI));
press('R'); press('R'); // AC
press('p');
press('s'); // x^2
checkDisplay(Math.PI * Math.PI);
press('R'); press('R'); // AC
press('p');
press('i'); // 1/x
checkDisplay(1 / Math.PI);
});
test('Trig functions with Pi (rad)', () => {
buttonPress('angleMode'); // switch to RAD
assert.strictEqual(scientificOperators.angleMode.val, 'rad');
press('p');
press('sin');
checkDisplay(Math.sin(Math.PI)); // ~0
press('R'); press('R');
press('p');
press('cos');
checkDisplay(Math.cos(Math.PI)); // -1
press('R'); press('R');
press('p');
press('tan');
checkDisplay(Math.tan(Math.PI)); // ~0
buttonPress('angleMode'); // switch back to DEG
assert.strictEqual(scientificOperators.angleMode.val, 'deg');
});
test('Pi after equals', () => {
press('1+2=');
checkDisplay(3);
press('p');
checkDisplay(Math.PI);
press('+1=');
checkDisplay(Math.PI + 1);
});
test('Pi with negative operator', () => {
press('pN');
checkDisplay(-Math.PI);
press('*2=');
checkDisplay(-Math.PI * 2);
});
test('Negative number times Pi', () => {
press('2N*p=');
checkDisplay(-2 * Math.PI);
});
// Run all the defined tests
runTests();
Reference in New Issue View Git Blame Copy Permalink