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import { BlockchainLifecycle, devConstants, web3Factory } from '@0xproject/dev-utils';
import { LogWithDecodedArgs, TransactionReceiptWithDecodedLogs } from '@0xproject/types';
import { BigNumber } from '@0xproject/utils';
import { Web3Wrapper } from '@0xproject/web3-wrapper';
import BN = require('bn.js');
import * as chai from 'chai';
import ethUtil = require('ethereumjs-util');
import * as Web3 from 'web3';
import { TestLibBytesContract } from '../../src/contract_wrappers/generated/test_lib_bytes';
import { artifacts } from '../../src/utils/artifacts';
import { chaiSetup } from '../../src/utils/chai_setup';
import { constants } from '../../src/utils/constants';
import { AssetProxyId } from '../../src/utils/types';
import { provider, txDefaults, web3Wrapper } from '../../src/utils/web3_wrapper';
chaiSetup.configure();
const expect = chai.expect;
const blockchainLifecycle = new BlockchainLifecycle(web3Wrapper);
describe('LibBytes', () => {
let owner: string;
let libBytes: TestLibBytesContract;
const byteArrayShorterThan32Bytes = '0x012345';
const byteArrayShorterThan20Bytes = byteArrayShorterThan32Bytes;
const byteArrayLongerThan32Bytes =
'0x0123456789abcdef0123456789abcdef0123456789abcdef0123456789abcdef0123456789abcdef';
const byteArrayLongerThan32BytesFirstBytesSwapped =
'0x2301456789abcdef0123456789abcdef0123456789abcdef0123456789abcdef0123456789abcdef';
const byteArrayLongerThan32BytesLastBytesSwapped =
'0x0123456789abcdef0123456789abcdef0123456789abcdef0123456789abcdef0123456789abefcd';
let testAddress: string;
const testBytes32 = '0x102030405060708090a0b0c0d0e0f0102030405060708090a0b0c0d0e0f01020';
const testUint256 = new BigNumber(testBytes32, 16);
before(async () => {
await blockchainLifecycle.startAsync();
});
after(async () => {
await blockchainLifecycle.revertAsync();
});
before(async () => {
// Setup accounts & addresses
const accounts = await web3Wrapper.getAvailableAddressesAsync();
owner = accounts[0];
testAddress = accounts[1];
// Deploy LibBytes
libBytes = await TestLibBytesContract.deployFrom0xArtifactAsync(artifacts.TestLibBytes, provider, txDefaults);
// Verify lengths of test data
const byteArrayShorterThan32BytesLength = ethUtil.toBuffer(byteArrayShorterThan32Bytes).byteLength;
expect(byteArrayShorterThan32BytesLength).to.be.lessThan(32);
const byteArrayLongerThan32BytesLength = ethUtil.toBuffer(byteArrayLongerThan32Bytes).byteLength;
expect(byteArrayLongerThan32BytesLength).to.be.greaterThan(32);
const testBytes32Length = ethUtil.toBuffer(testBytes32).byteLength;
expect(testBytes32Length).to.be.equal(32);
});
beforeEach(async () => {
await blockchainLifecycle.startAsync();
});
afterEach(async () => {
await blockchainLifecycle.revertAsync();
});
describe('popByte', () => {
it('should revert if length is 0', async () => {
return expect(libBytes.publicPopByte.callAsync(constants.NULL_BYTES)).to.be.rejectedWith(constants.REVERT);
});
it('should pop the last byte from the input and return it', async () => {
const [newBytes, poppedByte] = await libBytes.publicPopByte.callAsync(byteArrayLongerThan32Bytes);
const expectedNewBytes = byteArrayLongerThan32Bytes.slice(0, -2);
const expectedPoppedByte = `0x${byteArrayLongerThan32Bytes.slice(-2)}`;
expect(newBytes).to.equal(expectedNewBytes);
expect(poppedByte).to.equal(expectedPoppedByte);
});
});
describe('popAddress', () => {
it('should revert if length is less than 20', async () => {
return expect(libBytes.publicPopAddress.callAsync(byteArrayShorterThan20Bytes)).to.be.rejectedWith(
constants.REVERT,
);
});
it('should pop the last 20 bytes from the input and return it', async () => {
const [newBytes, poppedAddress] = await libBytes.publicPopAddress.callAsync(byteArrayLongerThan32Bytes);
const expectedNewBytes = byteArrayLongerThan32Bytes.slice(0, -40);
const expectedPoppedAddress = `0x${byteArrayLongerThan32Bytes.slice(-40)}`;
expect(newBytes).to.equal(expectedNewBytes);
expect(poppedAddress).to.equal(expectedPoppedAddress);
});
});
describe('areBytesEqual', () => {
it('should return true if byte arrays are equal (both arrays < 32 bytes)', async () => {
const areBytesEqual = await libBytes.publicAreBytesEqual.callAsync(
byteArrayShorterThan32Bytes,
byteArrayShorterThan32Bytes,
);
return expect(areBytesEqual).to.be.true();
});
it('should return true if byte arrays are equal (both arrays > 32 bytes)', async () => {
const areBytesEqual = await libBytes.publicAreBytesEqual.callAsync(
byteArrayLongerThan32Bytes,
byteArrayLongerThan32Bytes,
);
return expect(areBytesEqual).to.be.true();
});
it('should return false if byte arrays are not equal (first array < 32 bytes, second array > 32 bytes)', async () => {
const areBytesEqual = await libBytes.publicAreBytesEqual.callAsync(
byteArrayShorterThan32Bytes,
byteArrayLongerThan32Bytes,
);
return expect(areBytesEqual).to.be.false();
});
it('should return false if byte arrays are not equal (first array > 32 bytes, second array < 32 bytes)', async () => {
const areBytesEqual = await libBytes.publicAreBytesEqual.callAsync(
byteArrayLongerThan32Bytes,
byteArrayShorterThan32Bytes,
);
return expect(areBytesEqual).to.be.false();
});
it('should return false if byte arrays are not equal (same length, but a byte in first word differs)', async () => {
const areBytesEqual = await libBytes.publicAreBytesEqual.callAsync(
byteArrayLongerThan32BytesFirstBytesSwapped,
byteArrayLongerThan32Bytes,
);
return expect(areBytesEqual).to.be.false();
});
it('should return false if byte arrays are not equal (same length, but a byte in last word differs)', async () => {
const areBytesEqual = await libBytes.publicAreBytesEqual.callAsync(
byteArrayLongerThan32BytesLastBytesSwapped,
byteArrayLongerThan32Bytes,
);
return expect(areBytesEqual).to.be.false();
});
});
describe('readAddress', () => {
it('should successfully read address when the address takes up the whole array)', async () => {
const byteArray = ethUtil.addHexPrefix(testAddress);
const testAddressOffset = new BigNumber(0);
const address = await libBytes.publicReadAddress.callAsync(byteArray, testAddressOffset);
return expect(address).to.be.equal(testAddress);
});
it('should successfully read address when it is offset in the array)', async () => {
const addressByteArrayBuffer = ethUtil.toBuffer(testAddress);
const prefixByteArrayBuffer = ethUtil.toBuffer('0xabcdef');
const combinedByteArrayBuffer = Buffer.concat([prefixByteArrayBuffer, addressByteArrayBuffer]);
const combinedByteArray = ethUtil.bufferToHex(combinedByteArrayBuffer);
const testAddressOffset = new BigNumber(prefixByteArrayBuffer.byteLength);
const address = await libBytes.publicReadAddress.callAsync(combinedByteArray, testAddressOffset);
return expect(address).to.be.equal(testAddress);
});
it('should fail if the byte array is too short to hold an address)', async () => {
const shortByteArray = '0xabcdef';
const offset = new BigNumber(0);
return expect(libBytes.publicReadAddress.callAsync(shortByteArray, offset)).to.be.rejectedWith(
constants.REVERT,
);
});
it('should fail if the length between the offset and end of the byte array is too short to hold an address)', async () => {
const byteArray = ethUtil.addHexPrefix(testAddress);
const badOffset = new BigNumber(ethUtil.toBuffer(byteArray).byteLength);
return expect(libBytes.publicReadAddress.callAsync(byteArray, badOffset)).to.be.rejectedWith(
constants.REVERT,
);
});
});
/// @TODO Implement test cases for writeAddress. Test template below.
/// Currently, the generated contract wrappers do not support this library's write methods.
/*
describe('writeAddress', () => {
it('should successfully write address when the address takes up the whole array)', async () => {});
it('should successfully write address when it is offset in the array)', async () => {});
it('should fail if the byte array is too short to hold an address)', async () => {});
it('should fail if the length between the offset and end of the byte array is too short to hold an address)', async () => {});
});
*/
describe('readBytes32', () => {
it('should successfully read bytes32 when the bytes32 takes up the whole array)', async () => {
const testBytes32Offset = new BigNumber(0);
const bytes32 = await libBytes.publicReadBytes32.callAsync(testBytes32, testBytes32Offset);
return expect(bytes32).to.be.equal(testBytes32);
});
it('should successfully read bytes32 when it is offset in the array)', async () => {
const bytes32ByteArrayBuffer = ethUtil.toBuffer(testBytes32);
const prefixByteArrayBuffer = ethUtil.toBuffer('0xabcdef');
const combinedByteArrayBuffer = Buffer.concat([prefixByteArrayBuffer, bytes32ByteArrayBuffer]);
const combinedByteArray = ethUtil.bufferToHex(combinedByteArrayBuffer);
const testAddressOffset = new BigNumber(prefixByteArrayBuffer.byteLength);
const bytes32 = await libBytes.publicReadBytes32.callAsync(combinedByteArray, testAddressOffset);
return expect(bytes32).to.be.equal(testBytes32);
});
it('should fail if the byte array is too short to hold a bytes32)', async () => {
const offset = new BigNumber(0);
return expect(libBytes.publicReadBytes32.callAsync(byteArrayShorterThan32Bytes, offset)).to.be.rejectedWith(
constants.REVERT,
);
});
it('should fail if the length between the offset and end of the byte array is too short to hold a bytes32)', async () => {
const badOffset = new BigNumber(ethUtil.toBuffer(testBytes32).byteLength);
return expect(libBytes.publicReadBytes32.callAsync(testBytes32, badOffset)).to.be.rejectedWith(
constants.REVERT,
);
});
});
/// @TODO Implement test cases for writeBytes32. Test template below.
/// Currently, the generated contract wrappers do not support this library's write methods.
/*
describe('writeBytes32', () => {
it('should successfully write bytes32 when the address takes up the whole array)', async () => {});
it('should successfully write bytes32 when it is offset in the array)', async () => {});
it('should fail if the byte array is too short to hold a bytes32)', async () => {});
it('should fail if the length between the offset and end of the byte array is too short to hold a bytes32)', async () => {});
});
*/
describe('readUint256', () => {
it('should successfully read uint256 when the uint256 takes up the whole array)', async () => {
const formattedTestUint256 = new BN(testUint256.toString(10));
const testUint256AsBuffer = ethUtil.toBuffer(formattedTestUint256);
const byteArray = ethUtil.bufferToHex(testUint256AsBuffer);
const testUint256Offset = new BigNumber(0);
const uint256 = await libBytes.publicReadUint256.callAsync(byteArray, testUint256Offset);
return expect(uint256).to.bignumber.equal(testUint256);
});
it('should successfully read uint256 when it is offset in the array)', async () => {
const prefixByteArrayBuffer = ethUtil.toBuffer('0xabcdef');
const formattedTestUint256 = new BN(testUint256.toString(10));
const testUint256AsBuffer = ethUtil.toBuffer(formattedTestUint256);
const combinedByteArrayBuffer = Buffer.concat([prefixByteArrayBuffer, testUint256AsBuffer]);
const combinedByteArray = ethUtil.bufferToHex(combinedByteArrayBuffer);
const testUint256Offset = new BigNumber(prefixByteArrayBuffer.byteLength);
const uint256 = await libBytes.publicReadUint256.callAsync(combinedByteArray, testUint256Offset);
return expect(uint256).to.bignumber.equal(testUint256);
});
it('should fail if the byte array is too short to hold a uint256)', async () => {
const offset = new BigNumber(0);
return expect(libBytes.publicReadUint256.callAsync(byteArrayShorterThan32Bytes, offset)).to.be.rejectedWith(
constants.REVERT,
);
});
it('should fail if the length between the offset and end of the byte array is too short to hold a uint256)', async () => {
const formattedTestUint256 = new BN(testUint256.toString(10));
const testUint256AsBuffer = ethUtil.toBuffer(formattedTestUint256);
const byteArray = ethUtil.bufferToHex(testUint256AsBuffer);
const badOffset = new BigNumber(testUint256AsBuffer.byteLength);
return expect(libBytes.publicReadUint256.callAsync(byteArray, badOffset)).to.be.rejectedWith(
constants.REVERT,
);
});
});
/// @TODO Implement test cases for writeUint256. Test template below.
/// Currently, the generated contract wrappers do not support this library's write methods.
/*
describe('writeUint256', () => {
it('should successfully write uint256 when the address takes up the whole array)', async () => {});
it('should successfully write uint256 when it is offset in the array)', async () => {});
it('should fail if the byte array is too short to hold a uint256)', async () => {});
it('should fail if the length between the offset and end of the byte array is too short to hold a uint256)', async () => {});
});
*/
describe('readFirst4', () => {
it('should revert if byte array has a length < 4', async () => {
const byteArrayLessThan4Bytes = '0x010101';
return expect(libBytes.publicReadFirst4.callAsync(byteArrayLessThan4Bytes)).to.be.rejectedWith(
constants.REVERT,
);
});
it('should return the first 4 bytes of a byte array of arbitrary length', async () => {
const first4Bytes = await libBytes.publicReadFirst4.callAsync(byteArrayLongerThan32Bytes);
const expectedFirst4Bytes = byteArrayLongerThan32Bytes.slice(0, 10);
expect(first4Bytes).to.equal(expectedFirst4Bytes);
});
});
});
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