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[profile.default]
src = 'src'
out = 'out'
libs = ["node_modules", "lib"]
# See more config options https://github.com/foundry-rs/foundry/tree/master/config

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name: Tests
on: [push, pull_request]
jobs:
check:
name: Foundry project
runs-on: ubuntu-latest
steps:
- uses: actions/checkout@v2
with:
submodules: recursive
- name: Install Foundry
uses: onbjerg/foundry-toolchain@v1
with:
version: nightly
- name: Install dependencies
run: forge install
- name: Run tests
run: forge test -vvv
- name: Build Test with older solc versions
run: |
forge build --contracts src/Test.sol --use solc:0.8.0
forge build --contracts src/Test.sol --use solc:0.7.6
forge build --contracts src/Test.sol --use solc:0.7.0
forge build --contracts src/Test.sol --use solc:0.6.0

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cache/
out/
.vscode
.idea

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[submodule "lib/ds-test"]
path = lib/ds-test
url = https://github.com/dapphub/ds-test

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# Forge Standard Library • [![tests](https://github.com/brockelmore/forge-std/actions/workflows/tests.yml/badge.svg)](https://github.com/brockelmore/forge-std/actions/workflows/tests.yml)
Forge Standard Library is a collection of helpful contracts for use with [`forge` and `foundry`](https://github.com/foundry-rs/foundry). It leverages `forge`'s cheatcodes to make writing tests easier and faster, while improving the UX of cheatcodes.
**Learn how to use Forge Std with the [📖 Foundry Book (Forge Std Guide)](https://book.getfoundry.sh/forge/forge-std.html).**
## Install
```bash
forge install foundry-rs/forge-std
```
## Contracts
### stdError
This is a helper contract for errors and reverts. In `forge`, this contract is particularly helpful for the `expectRevert` cheatcode, as it provides all compiler builtin errors.
See the contract itself for all error codes.
#### Example usage
```solidity
import "forge-std/Test.sol";
contract TestContract is Test {
ErrorsTest test;
function setUp() public {
test = new ErrorsTest();
}
function testExpectArithmetic() public {
vm.expectRevert(stdError.arithmeticError);
test.arithmeticError(10);
}
}
contract ErrorsTest {
function arithmeticError(uint256 a) public {
uint256 a = a - 100;
}
}
```
### stdStorage
This is a rather large contract due to all of the overloading to make the UX decent. Primarily, it is a wrapper around the `record` and `accesses` cheatcodes. It can *always* find and write the storage slot(s) associated with a particular variable without knowing the storage layout. The one _major_ caveat to this is while a slot can be found for packed storage variables, we can't write to that variable safely. If a user tries to write to a packed slot, the execution throws an error, unless it is uninitialized (`bytes32(0)`).
This works by recording all `SLOAD`s and `SSTORE`s during a function call. If there is a single slot read or written to, it immediately returns the slot. Otherwise, behind the scenes, we iterate through and check each one (assuming the user passed in a `depth` parameter). If the variable is a struct, you can pass in a `depth` parameter which is basically the field depth.
I.e.:
```solidity
struct T {
// depth 0
uint256 a;
// depth 1
uint256 b;
}
```
#### Example usage
```solidity
import "forge-std/Test.sol";
contract TestContract is Test {
using stdStorage for StdStorage;
Storage test;
function setUp() public {
test = new Storage();
}
function testFindExists() public {
// Lets say we want to find the slot for the public
// variable `exists`. We just pass in the function selector
// to the `find` command
uint256 slot = stdstore.target(address(test)).sig("exists()").find();
assertEq(slot, 0);
}
function testWriteExists() public {
// Lets say we want to write to the slot for the public
// variable `exists`. We just pass in the function selector
// to the `checked_write` command
stdstore.target(address(test)).sig("exists()").checked_write(100);
assertEq(test.exists(), 100);
}
// It supports arbitrary storage layouts, like assembly based storage locations
function testFindHidden() public {
// `hidden` is a random hash of a bytes, iteration through slots would
// not find it. Our mechanism does
// Also, you can use the selector instead of a string
uint256 slot = stdstore.target(address(test)).sig(test.hidden.selector).find();
assertEq(slot, uint256(keccak256("my.random.var")));
}
// If targeting a mapping, you have to pass in the keys necessary to perform the find
// i.e.:
function testFindMapping() public {
uint256 slot = stdstore
.target(address(test))
.sig(test.map_addr.selector)
.with_key(address(this))
.find();
// in the `Storage` constructor, we wrote that this address' value was 1 in the map
// so when we load the slot, we expect it to be 1
assertEq(uint(vm.load(address(test), bytes32(slot))), 1);
}
// If the target is a struct, you can specify the field depth:
function testFindStruct() public {
// NOTE: see the depth parameter - 0 means 0th field, 1 means 1st field, etc.
uint256 slot_for_a_field = stdstore
.target(address(test))
.sig(test.basicStruct.selector)
.depth(0)
.find();
uint256 slot_for_b_field = stdstore
.target(address(test))
.sig(test.basicStruct.selector)
.depth(1)
.find();
assertEq(uint(vm.load(address(test), bytes32(slot_for_a_field))), 1);
assertEq(uint(vm.load(address(test), bytes32(slot_for_b_field))), 2);
}
}
// A complex storage contract
contract Storage {
struct UnpackedStruct {
uint256 a;
uint256 b;
}
constructor() {
map_addr[msg.sender] = 1;
}
uint256 public exists = 1;
mapping(address => uint256) public map_addr;
// mapping(address => Packed) public map_packed;
mapping(address => UnpackedStruct) public map_struct;
mapping(address => mapping(address => uint256)) public deep_map;
mapping(address => mapping(address => UnpackedStruct)) public deep_map_struct;
UnpackedStruct public basicStruct = UnpackedStruct({
a: 1,
b: 2
});
function hidden() public view returns (bytes32 t) {
// an extremely hidden storage slot
bytes32 slot = keccak256("my.random.var");
assembly {
t := sload(slot)
}
}
}
```
### stdCheats
This is a wrapper over miscellaneous cheatcodes that need wrappers to be more dev friendly. Currently there are only functions related to `prank`. In general, users may expect ETH to be put into an address on `prank`, but this is not the case for safety reasons. Explicitly this `hoax` function should only be used for address that have expected balances as it will get overwritten. If an address already has ETH, you should just use `prank`. If you want to change that balance explicitly, just use `deal`. If you want to do both, `hoax` is also right for you.
#### Example usage:
```solidity
// SPDX-License-Identifier: MIT
pragma solidity ^0.8.0;
import "forge-std/Test.sol";
// Inherit the stdCheats
contract StdCheatsTest is Test {
Bar test;
function setUp() public {
test = new Bar();
}
function testHoax() public {
// we call `hoax`, which gives the target address
// eth and then calls `prank`
hoax(address(1337));
test.bar{value: 100}(address(1337));
// overloaded to allow you to specify how much eth to
// initialize the address with
hoax(address(1337), 1);
test.bar{value: 1}(address(1337));
}
function testStartHoax() public {
// we call `startHoax`, which gives the target address
// eth and then calls `startPrank`
//
// it is also overloaded so that you can specify an eth amount
startHoax(address(1337));
test.bar{value: 100}(address(1337));
test.bar{value: 100}(address(1337));
vm.stopPrank();
test.bar(address(this));
}
}
contract Bar {
function bar(address expectedSender) public payable {
require(msg.sender == expectedSender, "!prank");
}
}
```
### Std Assertions
Expand upon the assertion functions from the `DSTest` library.
### `console.log`
Usage follows the same format as [Hardhat](https://hardhat.org/hardhat-network/reference/#console-log).
It's recommended to use `console2.sol` as shown below, as this will show the decoded logs in Forge traces.
```solidity
// import it indirectly via Test.sol
import "forge-std/Test.sol";
// or directly import it
import "forge-std/console2.sol";
...
console2.log(someValue);
```
If you need compatibility with Hardhat, you must use the standard `console.sol` instead.
Due to a bug in `console.sol`, logs that use `uint256` or `int256` types will not be properly decoded in Forge traces.
```solidity
// import it indirectly via Test.sol
import "forge-std/Test.sol";
// or directly import it
import "forge-std/console.sol";
...
console.log(someValue);
```

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[profile.default]
fs_permissions = [{ access = "read-write", path = "./"}]

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How to Apply These Terms to Your New Programs
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Also add information on how to contact you by electronic and paper mail.
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The hypothetical commands `show w' and `show c' should show the appropriate
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You should also get your employer (if you work as a programmer) or school,
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For more information on this, and how to apply and follow the GNU GPL, see
<http://www.gnu.org/licenses/>.
The GNU General Public License does not permit incorporating your program
into proprietary programs. If your program is a subroutine library, you
may consider it more useful to permit linking proprietary applications with
the library. If this is what you want to do, use the GNU Lesser General
Public License instead of this License. But first, please read
<http://www.gnu.org/philosophy/why-not-lgpl.html>.

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@ -0,0 +1,14 @@
all:; dapp build
test:
-dapp --use solc:0.4.23 build
-dapp --use solc:0.4.26 build
-dapp --use solc:0.5.17 build
-dapp --use solc:0.6.12 build
-dapp --use solc:0.7.5 build
demo:
DAPP_SRC=demo dapp --use solc:0.7.5 build
-hevm dapp-test --verbose 3
.PHONY: test demo

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@ -0,0 +1,4 @@
{ solidityPackage, dappsys }: solidityPackage {
name = "ds-test";
src = ./src;
}

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@ -0,0 +1,222 @@
// SPDX-License-Identifier: GPL-3.0-or-later
pragma solidity >=0.5.0;
import "../src/test.sol";
contract DemoTest is DSTest {
function test_this() public pure {
require(true);
}
function test_logs() public {
emit log("-- log(string)");
emit log("a string");
emit log("-- log_named_uint(string, uint)");
emit log_named_uint("uint", 512);
emit log("-- log_named_int(string, int)");
emit log_named_int("int", -512);
emit log("-- log_named_address(string, address)");
emit log_named_address("address", address(this));
emit log("-- log_named_bytes32(string, bytes32)");
emit log_named_bytes32("bytes32", "a string");
emit log("-- log_named_bytes(string, bytes)");
emit log_named_bytes("bytes", hex"cafefe");
emit log("-- log_named_string(string, string)");
emit log_named_string("string", "a string");
emit log("-- log_named_decimal_uint(string, uint, uint)");
emit log_named_decimal_uint("decimal uint", 1.0e18, 18);
emit log("-- log_named_decimal_int(string, int, uint)");
emit log_named_decimal_int("decimal int", -1.0e18, 18);
}
event log_old_named_uint(bytes32,uint);
function test_old_logs() public {
emit log_old_named_uint("key", 500);
emit log_named_bytes32("bkey", "val");
}
function test_trace() public view {
this.echo("string 1", "string 2");
}
function test_multiline() public {
emit log("a multiline\\nstring");
emit log("a multiline string");
emit log_bytes("a string");
emit log_bytes("a multiline\nstring");
emit log_bytes("a multiline\\nstring");
emit logs(hex"0000");
emit log_named_bytes("0x0000", hex"0000");
emit logs(hex"ff");
}
function echo(string memory s1, string memory s2) public pure
returns (string memory, string memory)
{
return (s1, s2);
}
function prove_this(uint x) public {
emit log_named_uint("sym x", x);
assertGt(x + 1, 0);
}
function test_logn() public {
assembly {
log0(0x01, 0x02)
log1(0x01, 0x02, 0x03)
log2(0x01, 0x02, 0x03, 0x04)
log3(0x01, 0x02, 0x03, 0x04, 0x05)
}
}
event MyEvent(uint, uint indexed, uint, uint indexed);
function test_events() public {
emit MyEvent(1, 2, 3, 4);
}
function test_asserts() public {
string memory err = "this test has failed!";
emit log("## assertTrue(bool)\n");
assertTrue(false);
emit log("\n");
assertTrue(false, err);
emit log("\n## assertEq(address,address)\n");
assertEq(address(this), msg.sender);
emit log("\n");
assertEq(address(this), msg.sender, err);
emit log("\n## assertEq32(bytes32,bytes32)\n");
assertEq32("bytes 1", "bytes 2");
emit log("\n");
assertEq32("bytes 1", "bytes 2", err);
emit log("\n## assertEq(bytes32,bytes32)\n");
assertEq32("bytes 1", "bytes 2");
emit log("\n");
assertEq32("bytes 1", "bytes 2", err);
emit log("\n## assertEq(uint,uint)\n");
assertEq(uint(0), 1);
emit log("\n");
assertEq(uint(0), 1, err);
emit log("\n## assertEq(int,int)\n");
assertEq(-1, -2);
emit log("\n");
assertEq(-1, -2, err);
emit log("\n## assertEqDecimal(int,int,uint)\n");
assertEqDecimal(-1.0e18, -1.1e18, 18);
emit log("\n");
assertEqDecimal(-1.0e18, -1.1e18, 18, err);
emit log("\n## assertEqDecimal(uint,uint,uint)\n");
assertEqDecimal(uint(1.0e18), 1.1e18, 18);
emit log("\n");
assertEqDecimal(uint(1.0e18), 1.1e18, 18, err);
emit log("\n## assertGt(uint,uint)\n");
assertGt(uint(0), 0);
emit log("\n");
assertGt(uint(0), 0, err);
emit log("\n## assertGt(int,int)\n");
assertGt(-1, -1);
emit log("\n");
assertGt(-1, -1, err);
emit log("\n## assertGtDecimal(int,int,uint)\n");
assertGtDecimal(-2.0e18, -1.1e18, 18);
emit log("\n");
assertGtDecimal(-2.0e18, -1.1e18, 18, err);
emit log("\n## assertGtDecimal(uint,uint,uint)\n");
assertGtDecimal(uint(1.0e18), 1.1e18, 18);
emit log("\n");
assertGtDecimal(uint(1.0e18), 1.1e18, 18, err);
emit log("\n## assertGe(uint,uint)\n");
assertGe(uint(0), 1);
emit log("\n");
assertGe(uint(0), 1, err);
emit log("\n## assertGe(int,int)\n");
assertGe(-1, 0);
emit log("\n");
assertGe(-1, 0, err);
emit log("\n## assertGeDecimal(int,int,uint)\n");
assertGeDecimal(-2.0e18, -1.1e18, 18);
emit log("\n");
assertGeDecimal(-2.0e18, -1.1e18, 18, err);
emit log("\n## assertGeDecimal(uint,uint,uint)\n");
assertGeDecimal(uint(1.0e18), 1.1e18, 18);
emit log("\n");
assertGeDecimal(uint(1.0e18), 1.1e18, 18, err);
emit log("\n## assertLt(uint,uint)\n");
assertLt(uint(0), 0);
emit log("\n");
assertLt(uint(0), 0, err);
emit log("\n## assertLt(int,int)\n");
assertLt(-1, -1);
emit log("\n");
assertLt(-1, -1, err);
emit log("\n## assertLtDecimal(int,int,uint)\n");
assertLtDecimal(-1.0e18, -1.1e18, 18);
emit log("\n");
assertLtDecimal(-1.0e18, -1.1e18, 18, err);
emit log("\n## assertLtDecimal(uint,uint,uint)\n");
assertLtDecimal(uint(2.0e18), 1.1e18, 18);
emit log("\n");
assertLtDecimal(uint(2.0e18), 1.1e18, 18, err);
emit log("\n## assertLe(uint,uint)\n");
assertLe(uint(1), 0);
emit log("\n");
assertLe(uint(1), 0, err);
emit log("\n## assertLe(int,int)\n");
assertLe(0, -1);
emit log("\n");
assertLe(0, -1, err);
emit log("\n## assertLeDecimal(int,int,uint)\n");
assertLeDecimal(-1.0e18, -1.1e18, 18);
emit log("\n");
assertLeDecimal(-1.0e18, -1.1e18, 18, err);
emit log("\n## assertLeDecimal(uint,uint,uint)\n");
assertLeDecimal(uint(2.0e18), 1.1e18, 18);
emit log("\n");
assertLeDecimal(uint(2.0e18), 1.1e18, 18, err);
emit log("\n## assertEq(string,string)\n");
string memory s1 = "string 1";
string memory s2 = "string 2";
assertEq(s1, s2);
emit log("\n");
assertEq(s1, s2, err);
emit log("\n## assertEq0(bytes,bytes)\n");
assertEq0(hex"abcdef01", hex"abcdef02");
emit log("\n");
assertEq0(hex"abcdef01", hex"abcdef02", err);
}
}
contract DemoTestWithSetUp {
function setUp() public {
}
function test_pass() public pure {
}
}

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@ -0,0 +1,469 @@
// SPDX-License-Identifier: GPL-3.0-or-later
// This program is free software: you can redistribute it and/or modify
// it under the terms of the GNU General Public License as published by
// the Free Software Foundation, either version 3 of the License, or
// (at your option) any later version.
// This program is distributed in the hope that it will be useful,
// but WITHOUT ANY WARRANTY; without even the implied warranty of
// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
// GNU General Public License for more details.
// You should have received a copy of the GNU General Public License
// along with this program. If not, see <http://www.gnu.org/licenses/>.
pragma solidity >=0.5.0;
contract DSTest {
event log (string);
event logs (bytes);
event log_address (address);
event log_bytes32 (bytes32);
event log_int (int);
event log_uint (uint);
event log_bytes (bytes);
event log_string (string);
event log_named_address (string key, address val);
event log_named_bytes32 (string key, bytes32 val);
event log_named_decimal_int (string key, int val, uint decimals);
event log_named_decimal_uint (string key, uint val, uint decimals);
event log_named_int (string key, int val);
event log_named_uint (string key, uint val);
event log_named_bytes (string key, bytes val);
event log_named_string (string key, string val);
bool public IS_TEST = true;
bool private _failed;
address constant HEVM_ADDRESS =
address(bytes20(uint160(uint256(keccak256('hevm cheat code')))));
modifier mayRevert() { _; }
modifier testopts(string memory) { _; }
function failed() public returns (bool) {
if (_failed) {
return _failed;
} else {
bool globalFailed = false;
if (hasHEVMContext()) {
(, bytes memory retdata) = HEVM_ADDRESS.call(
abi.encodePacked(
bytes4(keccak256("load(address,bytes32)")),
abi.encode(HEVM_ADDRESS, bytes32("failed"))
)
);
globalFailed = abi.decode(retdata, (bool));
}
return globalFailed;
}
}
function fail() internal {
if (hasHEVMContext()) {
(bool status, ) = HEVM_ADDRESS.call(
abi.encodePacked(
bytes4(keccak256("store(address,bytes32,bytes32)")),
abi.encode(HEVM_ADDRESS, bytes32("failed"), bytes32(uint256(0x01)))
)
);
status; // Silence compiler warnings
}
_failed = true;
}
function hasHEVMContext() internal view returns (bool) {
uint256 hevmCodeSize = 0;
assembly {
hevmCodeSize := extcodesize(0x7109709ECfa91a80626fF3989D68f67F5b1DD12D)
}
return hevmCodeSize > 0;
}
modifier logs_gas() {
uint startGas = gasleft();
_;
uint endGas = gasleft();
emit log_named_uint("gas", startGas - endGas);
}
function assertTrue(bool condition) internal {
if (!condition) {
emit log("Error: Assertion Failed");
fail();
}
}
function assertTrue(bool condition, string memory err) internal {
if (!condition) {
emit log_named_string("Error", err);
assertTrue(condition);
}
}
function assertEq(address a, address b) internal {
if (a != b) {
emit log("Error: a == b not satisfied [address]");
emit log_named_address(" Expected", b);
emit log_named_address(" Actual", a);
fail();
}
}
function assertEq(address a, address b, string memory err) internal {
if (a != b) {
emit log_named_string ("Error", err);
assertEq(a, b);
}
}
function assertEq(bytes32 a, bytes32 b) internal {
if (a != b) {
emit log("Error: a == b not satisfied [bytes32]");
emit log_named_bytes32(" Expected", b);
emit log_named_bytes32(" Actual", a);
fail();
}
}
function assertEq(bytes32 a, bytes32 b, string memory err) internal {
if (a != b) {
emit log_named_string ("Error", err);
assertEq(a, b);
}
}
function assertEq32(bytes32 a, bytes32 b) internal {
assertEq(a, b);
}
function assertEq32(bytes32 a, bytes32 b, string memory err) internal {
assertEq(a, b, err);
}
function assertEq(int a, int b) internal {
if (a != b) {
emit log("Error: a == b not satisfied [int]");
emit log_named_int(" Expected", b);
emit log_named_int(" Actual", a);
fail();
}
}
function assertEq(int a, int b, string memory err) internal {
if (a != b) {
emit log_named_string("Error", err);
assertEq(a, b);
}
}
function assertEq(uint a, uint b) internal {
if (a != b) {
emit log("Error: a == b not satisfied [uint]");
emit log_named_uint(" Expected", b);
emit log_named_uint(" Actual", a);
fail();
}
}
function assertEq(uint a, uint b, string memory err) internal {
if (a != b) {
emit log_named_string("Error", err);
assertEq(a, b);
}
}
function assertEqDecimal(int a, int b, uint decimals) internal {
if (a != b) {
emit log("Error: a == b not satisfied [decimal int]");
emit log_named_decimal_int(" Expected", b, decimals);
emit log_named_decimal_int(" Actual", a, decimals);
fail();
}
}
function assertEqDecimal(int a, int b, uint decimals, string memory err) internal {
if (a != b) {
emit log_named_string("Error", err);
assertEqDecimal(a, b, decimals);
}
}
function assertEqDecimal(uint a, uint b, uint decimals) internal {
if (a != b) {
emit log("Error: a == b not satisfied [decimal uint]");
emit log_named_decimal_uint(" Expected", b, decimals);
emit log_named_decimal_uint(" Actual", a, decimals);
fail();
}
}
function assertEqDecimal(uint a, uint b, uint decimals, string memory err) internal {
if (a != b) {
emit log_named_string("Error", err);
assertEqDecimal(a, b, decimals);
}
}
function assertGt(uint a, uint b) internal {
if (a <= b) {
emit log("Error: a > b not satisfied [uint]");
emit log_named_uint(" Value a", a);
emit log_named_uint(" Value b", b);
fail();
}
}
function assertGt(uint a, uint b, string memory err) internal {
if (a <= b) {
emit log_named_string("Error", err);
assertGt(a, b);
}
}
function assertGt(int a, int b) internal {
if (a <= b) {
emit log("Error: a > b not satisfied [int]");
emit log_named_int(" Value a", a);
emit log_named_int(" Value b", b);
fail();
}
}
function assertGt(int a, int b, string memory err) internal {
if (a <= b) {
emit log_named_string("Error", err);
assertGt(a, b);
}
}
function assertGtDecimal(int a, int b, uint decimals) internal {
if (a <= b) {
emit log("Error: a > b not satisfied [decimal int]");
emit log_named_decimal_int(" Value a", a, decimals);
emit log_named_decimal_int(" Value b", b, decimals);
fail();
}
}
function assertGtDecimal(int a, int b, uint decimals, string memory err) internal {
if (a <= b) {
emit log_named_string("Error", err);
assertGtDecimal(a, b, decimals);
}
}
function assertGtDecimal(uint a, uint b, uint decimals) internal {
if (a <= b) {
emit log("Error: a > b not satisfied [decimal uint]");
emit log_named_decimal_uint(" Value a", a, decimals);
emit log_named_decimal_uint(" Value b", b, decimals);
fail();
}
}
function assertGtDecimal(uint a, uint b, uint decimals, string memory err) internal {
if (a <= b) {
emit log_named_string("Error", err);
assertGtDecimal(a, b, decimals);
}
}
function assertGe(uint a, uint b) internal {
if (a < b) {
emit log("Error: a >= b not satisfied [uint]");
emit log_named_uint(" Value a", a);
emit log_named_uint(" Value b", b);
fail();
}
}
function assertGe(uint a, uint b, string memory err) internal {
if (a < b) {
emit log_named_string("Error", err);
assertGe(a, b);
}
}
function assertGe(int a, int b) internal {
if (a < b) {
emit log("Error: a >= b not satisfied [int]");
emit log_named_int(" Value a", a);
emit log_named_int(" Value b", b);
fail();
}
}
function assertGe(int a, int b, string memory err) internal {
if (a < b) {
emit log_named_string("Error", err);
assertGe(a, b);
}
}
function assertGeDecimal(int a, int b, uint decimals) internal {
if (a < b) {
emit log("Error: a >= b not satisfied [decimal int]");
emit log_named_decimal_int(" Value a", a, decimals);
emit log_named_decimal_int(" Value b", b, decimals);
fail();
}
}
function assertGeDecimal(int a, int b, uint decimals, string memory err) internal {
if (a < b) {
emit log_named_string("Error", err);
assertGeDecimal(a, b, decimals);
}
}
function assertGeDecimal(uint a, uint b, uint decimals) internal {
if (a < b) {
emit log("Error: a >= b not satisfied [decimal uint]");
emit log_named_decimal_uint(" Value a", a, decimals);
emit log_named_decimal_uint(" Value b", b, decimals);
fail();
}
}
function assertGeDecimal(uint a, uint b, uint decimals, string memory err) internal {
if (a < b) {
emit log_named_string("Error", err);
assertGeDecimal(a, b, decimals);
}
}
function assertLt(uint a, uint b) internal {
if (a >= b) {
emit log("Error: a < b not satisfied [uint]");
emit log_named_uint(" Value a", a);
emit log_named_uint(" Value b", b);
fail();
}
}
function assertLt(uint a, uint b, string memory err) internal {
if (a >= b) {
emit log_named_string("Error", err);
assertLt(a, b);
}
}
function assertLt(int a, int b) internal {
if (a >= b) {
emit log("Error: a < b not satisfied [int]");
emit log_named_int(" Value a", a);
emit log_named_int(" Value b", b);
fail();
}
}
function assertLt(int a, int b, string memory err) internal {
if (a >= b) {
emit log_named_string("Error", err);
assertLt(a, b);
}
}
function assertLtDecimal(int a, int b, uint decimals) internal {
if (a >= b) {
emit log("Error: a < b not satisfied [decimal int]");
emit log_named_decimal_int(" Value a", a, decimals);
emit log_named_decimal_int(" Value b", b, decimals);
fail();
}
}
function assertLtDecimal(int a, int b, uint decimals, string memory err) internal {
if (a >= b) {
emit log_named_string("Error", err);
assertLtDecimal(a, b, decimals);
}
}
function assertLtDecimal(uint a, uint b, uint decimals) internal {
if (a >= b) {
emit log("Error: a < b not satisfied [decimal uint]");
emit log_named_decimal_uint(" Value a", a, decimals);
emit log_named_decimal_uint(" Value b", b, decimals);
fail();
}
}
function assertLtDecimal(uint a, uint b, uint decimals, string memory err) internal {
if (a >= b) {
emit log_named_string("Error", err);
assertLtDecimal(a, b, decimals);
}
}
function assertLe(uint a, uint b) internal {
if (a > b) {
emit log("Error: a <= b not satisfied [uint]");
emit log_named_uint(" Value a", a);
emit log_named_uint(" Value b", b);
fail();
}
}
function assertLe(uint a, uint b, string memory err) internal {
if (a > b) {
emit log_named_string("Error", err);
assertLe(a, b);
}
}
function assertLe(int a, int b) internal {
if (a > b) {
emit log("Error: a <= b not satisfied [int]");
emit log_named_int(" Value a", a);
emit log_named_int(" Value b", b);
fail();
}
}
function assertLe(int a, int b, string memory err) internal {
if (a > b) {
emit log_named_string("Error", err);
assertLe(a, b);
}
}
function assertLeDecimal(int a, int b, uint decimals) internal {
if (a > b) {
emit log("Error: a <= b not satisfied [decimal int]");
emit log_named_decimal_int(" Value a", a, decimals);
emit log_named_decimal_int(" Value b", b, decimals);
fail();
}
}
function assertLeDecimal(int a, int b, uint decimals, string memory err) internal {
if (a > b) {
emit log_named_string("Error", err);
assertLeDecimal(a, b, decimals);
}
}
function assertLeDecimal(uint a, uint b, uint decimals) internal {
if (a > b) {
emit log("Error: a <= b not satisfied [decimal uint]");
emit log_named_decimal_uint(" Value a", a, decimals);
emit log_named_decimal_uint(" Value b", b, decimals);
fail();
}
}
function assertLeDecimal(uint a, uint b, uint decimals, string memory err) internal {
if (a > b) {
emit log_named_string("Error", err);
assertGeDecimal(a, b, decimals);
}
}
function assertEq(string memory a, string memory b) internal {
if (keccak256(abi.encodePacked(a)) != keccak256(abi.encodePacked(b))) {
emit log("Error: a == b not satisfied [string]");
emit log_named_string(" Expected", b);
emit log_named_string(" Actual", a);
fail();
}
}
function assertEq(string memory a, string memory b, string memory err) internal {
if (keccak256(abi.encodePacked(a)) != keccak256(abi.encodePacked(b))) {
emit log_named_string("Error", err);
assertEq(a, b);
}
}
function checkEq0(bytes memory a, bytes memory b) internal pure returns (bool ok) {
ok = true;
if (a.length == b.length) {
for (uint i = 0; i < a.length; i++) {
if (a[i] != b[i]) {
ok = false;
}
}
} else {
ok = false;
}
}
function assertEq0(bytes memory a, bytes memory b) internal {
if (!checkEq0(a, b)) {
emit log("Error: a == b not satisfied [bytes]");
emit log_named_bytes(" Expected", b);
emit log_named_bytes(" Actual", a);
fail();
}
}
function assertEq0(bytes memory a, bytes memory b, string memory err) internal {
if (!checkEq0(a, b)) {
emit log_named_string("Error", err);
assertEq0(a, b);
}
}
}

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{
"name": "forge-std",
"version": "0.1.0",
"description": "Forge Standard Library is a collection of helpful contracts for use with forge and foundry",
"homepage": "https://book.getfoundry.sh/forge/forge-std",
"bugs": "https://github.com/foundry-rs/forge-std/issues",
"license": "(Apache-2.0 OR MIT)",
"author": "Contributors to forge-std",
"files": [
"src/*"
],
"repository": {
"type": "git",
"url": "https://github.com/foundry-rs/forge-std.git"
}
}

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// SPDX-License-Identifier: MIT
pragma solidity >=0.6.0 <0.9.0;
import "./console.sol";
import "./console2.sol";
import "./StdJson.sol";
abstract contract Script {
bool public IS_SCRIPT = true;
address constant private VM_ADDRESS =
address(bytes20(uint160(uint256(keccak256('hevm cheat code')))));
Vm public constant vm = Vm(VM_ADDRESS);
/// @dev Compute the address a contract will be deployed at for a given deployer address and nonce
/// @notice adapated from Solmate implementation (https://github.com/transmissions11/solmate/blob/main/src/utils/LibRLP.sol)
function computeCreateAddress(address deployer, uint256 nonce) internal pure returns (address) {
// The integer zero is treated as an empty byte string, and as a result it only has a length prefix, 0x80, computed via 0x80 + 0.
// A one byte integer uses its own value as its length prefix, there is no additional "0x80 + length" prefix that comes before it.
if (nonce == 0x00) return addressFromLast20Bytes(keccak256(abi.encodePacked(bytes1(0xd6), bytes1(0x94), deployer, bytes1(0x80))));
if (nonce <= 0x7f) return addressFromLast20Bytes(keccak256(abi.encodePacked(bytes1(0xd6), bytes1(0x94), deployer, uint8(nonce))));
// Nonces greater than 1 byte all follow a consistent encoding scheme, where each value is preceded by a prefix of 0x80 + length.
if (nonce <= 2**8 - 1) return addressFromLast20Bytes(keccak256(abi.encodePacked(bytes1(0xd7), bytes1(0x94), deployer, bytes1(0x81), uint8(nonce))));
if (nonce <= 2**16 - 1) return addressFromLast20Bytes(keccak256(abi.encodePacked(bytes1(0xd8), bytes1(0x94), deployer, bytes1(0x82), uint16(nonce))));
if (nonce <= 2**24 - 1) return addressFromLast20Bytes(keccak256(abi.encodePacked(bytes1(0xd9), bytes1(0x94), deployer, bytes1(0x83), uint24(nonce))));
// More details about RLP encoding can be found here: https://eth.wiki/fundamentals/rlp
// 0xda = 0xc0 (short RLP prefix) + 0x16 (length of: 0x94 ++ proxy ++ 0x84 ++ nonce)
// 0x94 = 0x80 + 0x14 (0x14 = the length of an address, 20 bytes, in hex)
// 0x84 = 0x80 + 0x04 (0x04 = the bytes length of the nonce, 4 bytes, in hex)
// We assume nobody can have a nonce large enough to require more than 32 bytes.
return addressFromLast20Bytes(keccak256(abi.encodePacked(bytes1(0xda), bytes1(0x94), deployer, bytes1(0x84), uint32(nonce))));
}
function addressFromLast20Bytes(bytes32 bytesValue) internal pure returns (address) {
return address(uint160(uint256(bytesValue)));
}
function deriveRememberKey(string memory mnemonic, uint32 index) internal returns (address who, uint256 privateKey) {
privateKey = vm.deriveKey(mnemonic, index);
who = vm.rememberKey(privateKey);
}
}

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// SPDX-License-Identifier: MIT
pragma solidity >=0.6.0 <0.9.0;
pragma experimental ABIEncoderV2;
import "./Vm.sol";
// Helpers for parsing keys into types.
library stdJson {
Vm private constant vm = Vm(address(uint160(uint256(keccak256("hevm cheat code")))));
function parseRaw(string memory json, string memory key)
internal
returns (bytes memory)
{
return vm.parseJson(json, key);
}
function readUint(string memory json, string memory key)
internal
returns (uint256)
{
return abi.decode(vm.parseJson(json, key), (uint256));
}
function readUintArray(string memory json, string memory key)
internal
returns (uint256[] memory)
{
return abi.decode(vm.parseJson(json, key), (uint256[]));
}
function readInt(string memory json, string memory key)
internal
returns (int256)
{
return abi.decode(vm.parseJson(json, key), (int256));
}
function readIntArray(string memory json, string memory key)
internal
returns (int256[] memory)
{
return abi.decode(vm.parseJson(json, key), (int256[]));
}
function readBytes32(string memory json, string memory key)
internal
returns (bytes32)
{
return abi.decode(vm.parseJson(json, key), (bytes32));
}
function readBytes32Array(string memory json, string memory key)
internal
returns (bytes32[] memory)
{
return abi.decode(vm.parseJson(json, key), (bytes32[]));
}
function readString(string memory json, string memory key)
internal
returns (string memory)
{
return abi.decode(vm.parseJson(json, key), (string));
}
function readStringArray(string memory json, string memory key)
internal
returns (string[] memory)
{
return abi.decode(vm.parseJson(json, key), (string[]));
}
function readAddress(string memory json, string memory key)
internal
returns (address)
{
return abi.decode(vm.parseJson(json, key), (address));
}
function readAddressArray(string memory json, string memory key)
internal
returns (address[] memory)
{
return abi.decode(vm.parseJson(json, key), (address[]));
}
function readBool(string memory json, string memory key)
internal
returns (bool)
{
return abi.decode(vm.parseJson(json, key), (bool));
}
function readBoolArray(string memory json, string memory key)
internal
returns (bool[] memory)
{
return abi.decode(vm.parseJson(json, key), (bool[]));
}
function readBytes(string memory json, string memory key)
internal
returns (bytes memory)
{
return abi.decode(vm.parseJson(json, key), (bytes));
}
function readBytesArray(string memory json, string memory key)
internal
returns (bytes[] memory)
{
return abi.decode(vm.parseJson(json, key), (bytes[]));
}
}

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lib/forge-std/src/Test.sol Normal file

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lib/forge-std/src/Vm.sol Normal file
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// SPDX-License-Identifier: MIT
pragma solidity >=0.6.0 <0.9.0;
pragma experimental ABIEncoderV2;
interface Vm {
struct Log {
bytes32[] topics;
bytes data;
}
// Sets block.timestamp (newTimestamp)
function warp(uint256) external;
// Sets block.height (newHeight)
function roll(uint256) external;
// Sets block.basefee (newBasefee)
function fee(uint256) external;
// Sets block.difficulty (newDifficulty)
function difficulty(uint256) external;
// Sets block.chainid
function chainId(uint256) external;
// Loads a storage slot from an address (who, slot)
function load(address,bytes32) external returns (bytes32);
// Stores a value to an address' storage slot, (who, slot, value)
function store(address,bytes32,bytes32) external;
// Signs data, (privateKey, digest) => (v, r, s)
function sign(uint256,bytes32) external returns (uint8,bytes32,bytes32);
// Gets the address for a given private key, (privateKey) => (address)
function addr(uint256) external returns (address);
// Gets the nonce of an account
function getNonce(address) external returns (uint64);
// Sets the nonce of an account; must be higher than the current nonce of the account
function setNonce(address, uint64) external;
// Performs a foreign function call via the terminal, (stringInputs) => (result)
function ffi(string[] calldata) external returns (bytes memory);
// Sets environment variables, (name, value)
function setEnv(string calldata, string calldata) external;
// Reads environment variables, (name) => (value)
function envBool(string calldata) external returns (bool);
function envUint(string calldata) external returns (uint256);
function envInt(string calldata) external returns (int256);
function envAddress(string calldata) external returns (address);
function envBytes32(string calldata) external returns (bytes32);
function envString(string calldata) external returns (string memory);
function envBytes(string calldata) external returns (bytes memory);
// Reads environment variables as arrays, (name, delim) => (value[])
function envBool(string calldata, string calldata) external returns (bool[] memory);
function envUint(string calldata, string calldata) external returns (uint256[] memory);
function envInt(string calldata, string calldata) external returns (int256[] memory);
function envAddress(string calldata, string calldata) external returns (address[] memory);
function envBytes32(string calldata, string calldata) external returns (bytes32[] memory);
function envString(string calldata, string calldata) external returns (string[] memory);
function envBytes(string calldata, string calldata) external returns (bytes[] memory);
// Sets the *next* call's msg.sender to be the input address
function prank(address) external;
// Sets all subsequent calls' msg.sender to be the input address until `stopPrank` is called
function startPrank(address) external;
// Sets the *next* call's msg.sender to be the input address, and the tx.origin to be the second input
function prank(address,address) external;
// Sets all subsequent calls' msg.sender to be the input address until `stopPrank` is called, and the tx.origin to be the second input
function startPrank(address,address) external;
// Resets subsequent calls' msg.sender to be `address(this)`
function stopPrank() external;
// Sets an address' balance, (who, newBalance)
function deal(address, uint256) external;
// Sets an address' code, (who, newCode)
function etch(address, bytes calldata) external;
// Expects an error on next call
function expectRevert(bytes calldata) external;
function expectRevert(bytes4) external;
function expectRevert() external;
// Records all storage reads and writes
function record() external;
// Gets all accessed reads and write slot from a recording session, for a given address
function accesses(address) external returns (bytes32[] memory reads, bytes32[] memory writes);
// Prepare an expected log with (bool checkTopic1, bool checkTopic2, bool checkTopic3, bool checkData).
// Call this function, then emit an event, then call a function. Internally after the call, we check if
// logs were emitted in the expected order with the expected topics and data (as specified by the booleans)
function expectEmit(bool,bool,bool,bool) external;
function expectEmit(bool,bool,bool,bool,address) external;
// Mocks a call to an address, returning specified data.
// Calldata can either be strict or a partial match, e.g. if you only
// pass a Solidity selector to the expected calldata, then the entire Solidity
// function will be mocked.
function mockCall(address,bytes calldata,bytes calldata) external;
// Mocks a call to an address with a specific msg.value, returning specified data.
// Calldata match takes precedence over msg.value in case of ambiguity.
function mockCall(address,uint256,bytes calldata,bytes calldata) external;
// Clears all mocked calls
function clearMockedCalls() external;
// Expects a call to an address with the specified calldata.
// Calldata can either be a strict or a partial match
function expectCall(address,bytes calldata) external;
// Expects a call to an address with the specified msg.value and calldata
function expectCall(address,uint256,bytes calldata) external;
// Gets the _creation_ bytecode from an artifact file. Takes in the relative path to the json file
function getCode(string calldata) external returns (bytes memory);
// Gets the _deployed_ bytecode from an artifact file. Takes in the relative path to the json file
function getDeployedCode(string calldata) external returns (bytes memory);
// Labels an address in call traces
function label(address, string calldata) external;
// If the condition is false, discard this run's fuzz inputs and generate new ones
function assume(bool) external;
// Sets block.coinbase (who)
function coinbase(address) external;
// Using the address that calls the test contract, has the next call (at this call depth only) create a transaction that can later be signed and sent onchain
function broadcast() external;
// Has the next call (at this call depth only) create a transaction with the address provided as the sender that can later be signed and sent onchain
function broadcast(address) external;
// Has the next call (at this call depth only) create a transaction with the private key provided as the sender that can later be signed and sent onchain
function broadcast(uint256) external;
// Using the address that calls the test contract, has all subsequent calls (at this call depth only) create transactions that can later be signed and sent onchain
function startBroadcast() external;
// Has all subsequent calls (at this call depth only) create transactions with the address provided that can later be signed and sent onchain
function startBroadcast(address) external;
// Has all subsequent calls (at this call depth only) create transactions with the private key provided that can later be signed and sent onchain
function startBroadcast(uint256) external;
// Stops collecting onchain transactions
function stopBroadcast() external;
// Reads the entire content of file to string, (path) => (data)
function readFile(string calldata) external returns (string memory);
// Reads the entire content of file as binary. Path is relative to the project root. (path) => (data)
function readFileBinary(string calldata) external returns (bytes memory);
// Get the path of the current project root
function projectRoot() external returns (string memory);
// Reads next line of file to string, (path) => (line)
function readLine(string calldata) external returns (string memory);
// Writes data to file, creating a file if it does not exist, and entirely replacing its contents if it does.
// (path, data) => ()
function writeFile(string calldata, string calldata) external;
// Writes binary data to a file, creating a file if it does not exist, and entirely replacing its contents if it does.
// Path is relative to the project root. (path, data) => ()
function writeFileBinary(string calldata, bytes calldata) external;
// Writes line to file, creating a file if it does not exist.
// (path, data) => ()
function writeLine(string calldata, string calldata) external;
// Closes file for reading, resetting the offset and allowing to read it from beginning with readLine.
// (path) => ()
function closeFile(string calldata) external;
// Removes file. This cheatcode will revert in the following situations, but is not limited to just these cases:
// - Path points to a directory.
// - The file doesn't exist.
// - The user lacks permissions to remove the file.
// (path) => ()
function removeFile(string calldata) external;
// Convert values to a string, (value) => (stringified value)
function toString(address) external returns(string memory);
function toString(bytes calldata) external returns(string memory);
function toString(bytes32) external returns(string memory);
function toString(bool) external returns(string memory);
function toString(uint256) external returns(string memory);
function toString(int256) external returns(string memory);
// Convert values from a string, (string) => (parsed value)
function parseBytes(string calldata) external returns (bytes memory);
function parseAddress(string calldata) external returns (address);
function parseUint(string calldata) external returns (uint256);
function parseInt(string calldata) external returns (int256);
function parseBytes32(string calldata) external returns (bytes32);
function parseBool(string calldata) external returns (bool);
// Record all the transaction logs
function recordLogs() external;
// Gets all the recorded logs, () => (logs)
function getRecordedLogs() external returns (Log[] memory);
// Snapshot the current state of the evm.
// Returns the id of the snapshot that was created.
// To revert a snapshot use `revertTo`
function snapshot() external returns(uint256);
// Revert the state of the evm to a previous snapshot
// Takes the snapshot id to revert to.
// This deletes the snapshot and all snapshots taken after the given snapshot id.
function revertTo(uint256) external returns(bool);
// Creates a new fork with the given endpoint and block and returns the identifier of the fork
function createFork(string calldata,uint256) external returns(uint256);
// Creates a new fork with the given endpoint and the _latest_ block and returns the identifier of the fork
function createFork(string calldata) external returns(uint256);
// Creates a new fork with the given endpoint and at the block the given transaction was mined in, and replays all transaction mined in the block before the transaction
function createFork(string calldata, bytes32) external returns (uint256);
// Creates _and_ also selects a new fork with the given endpoint and block and returns the identifier of the fork
function createSelectFork(string calldata,uint256) external returns(uint256);
// Creates _and_ also selects new fork with the given endpoint and at the block the given transaction was mined in, and replays all transaction mined in the block before the transaction
function createSelectFork(string calldata, bytes32) external returns (uint256);
// Creates _and_ also selects a new fork with the given endpoint and the latest block and returns the identifier of the fork
function createSelectFork(string calldata) external returns(uint256);
// Takes a fork identifier created by `createFork` and sets the corresponding forked state as active.
function selectFork(uint256) external;
/// Returns the currently active fork
/// Reverts if no fork is currently active
function activeFork() external returns(uint256);
// Updates the currently active fork to given block number
// This is similar to `roll` but for the currently active fork
function rollFork(uint256) external;
// Updates the currently active fork to given transaction
// this will `rollFork` with the number of the block the transaction was mined in and replays all transaction mined before it in the block
function rollFork(bytes32) external;
// Updates the given fork to given block number
function rollFork(uint256 forkId, uint256 blockNumber) external;
// Updates the given fork to block number of the given transaction and replays all transaction mined before it in the block
function rollFork(uint256 forkId, bytes32 transaction) external;
// Marks that the account(s) should use persistent storage across fork swaps in a multifork setup
// Meaning, changes made to the state of this account will be kept when switching forks
function makePersistent(address) external;
function makePersistent(address, address) external;
function makePersistent(address, address, address) external;
function makePersistent(address[] calldata) external;
// Revokes persistent status from the address, previously added via `makePersistent`
function revokePersistent(address) external;
function revokePersistent(address[] calldata) external;
// Returns true if the account is marked as persistent
function isPersistent(address) external returns (bool);
// In forking mode, explicitly grant the given address cheatcode access
function allowCheatcodes(address) external;
// Fetches the given transaction from the active fork and executes it on the current state
function transact(bytes32 txHash) external;
// Fetches the given transaction from the given fork and executes it on the current state
function transact(uint256 forkId, bytes32 txHash) external;
// Returns the RPC url for the given alias
function rpcUrl(string calldata) external returns(string memory);
// Returns all rpc urls and their aliases `[alias, url][]`
function rpcUrls() external returns(string[2][] memory);
// Derive a private key from a provided mnenomic string (or mnenomic file path) at the derivation path m/44'/60'/0'/0/{index}
function deriveKey(string calldata, uint32) external returns (uint256);
// Derive a private key from a provided mnenomic string (or mnenomic file path) at the derivation path {path}{index}
function deriveKey(string calldata, string calldata, uint32) external returns (uint256);
// Adds a private key to the local forge wallet and returns the address
function rememberKey(uint256) external returns (address);
// parseJson
// Given a string of JSON, return the ABI-encoded value of provided key
// (stringified json, key) => (ABI-encoded data)
// Read the note below!
function parseJson(string calldata, string calldata) external returns(bytes memory);
// Given a string of JSON, return it as ABI-encoded, (stringified json, key) => (ABI-encoded data)
// Read the note below!
function parseJson(string calldata) external returns(bytes memory);
// Note:
// ----
// In case the returned value is a JSON object, it's encoded as a ABI-encoded tuple. As JSON objects
// don't have the notion of ordered, but tuples do, they JSON object is encoded with it's fields ordered in
// ALPHABETICAL ordser. That means that in order to succesfully decode the tuple, we need to define a tuple that
// encodes the fields in the same order, which is alphabetical. In the case of Solidity structs, they are encoded
// as tuples, with the attributes in the order in which they are defined.
// For example: json = { 'a': 1, 'b': 0xa4tb......3xs}
// a: uint256
// b: address
// To decode that json, we need to define a struct or a tuple as follows:
// struct json = { uint256 a; address b; }
// If we defined a json struct with the opposite order, meaning placing the address b first, it would try to
// decode the tuple in that order, and thus fail.
}

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// SPDX-License-Identifier: MIT
pragma solidity >=0.7.0 <0.9.0;
import "../Test.sol";
contract ScriptTest is Test
{
function testGenerateCorrectAddress() external {
address creation = computeCreateAddress(0x6C9FC64A53c1b71FB3f9Af64d1ae3A4931A5f4E9, 14);
assertEq(creation, 0x68b3465833fb72A70ecDF485E0e4C7bD8665Fc45);
}
function testDeriveRememberKey() external {
string memory mnemonic = "test test test test test test test test test test test junk";
(address deployer, uint256 privateKey) = deriveRememberKey(mnemonic, 0);
assertEq(deployer, 0xf39Fd6e51aad88F6F4ce6aB8827279cffFb92266);
assertEq(privateKey, 0xac0974bec39a17e36ba4a6b4d238ff944bacb478cbed5efcae784d7bf4f2ff80);
}
}

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// SPDX-License-Identifier: MIT
pragma solidity >=0.7.0 <0.9.0;
import "../Test.sol";
contract StdAssertionsTest is Test
{
string constant CUSTOM_ERROR = "guh!";
bool constant EXPECT_PASS = false;
bool constant EXPECT_FAIL = true;
TestTest t = new TestTest();
/*//////////////////////////////////////////////////////////////////////////
ASSERT_EQ(UINT)
//////////////////////////////////////////////////////////////////////////*/
function testAssertions() public {
assertEqUint(uint32(1), uint32(1));
assertEqUint(uint64(1), uint64(1));
assertEqUint(uint96(1), uint96(1));
assertEqUint(uint128(1), uint128(1));
}
/*//////////////////////////////////////////////////////////////////////////
FAIL(STRING)
//////////////////////////////////////////////////////////////////////////*/
function testShouldFail() external {
vm.expectEmit(false, false, false, true);
emit log_named_string("Error", CUSTOM_ERROR);
t._fail(CUSTOM_ERROR);
}
/*//////////////////////////////////////////////////////////////////////////
ASSERT_FALSE
//////////////////////////////////////////////////////////////////////////*/
function testAssertFalse_Pass() external {
t._assertFalse(false, EXPECT_PASS);
}
function testAssertFalse_Fail() external {
vm.expectEmit(false, false, false, true);
emit log("Error: Assertion Failed");
t._assertFalse(true, EXPECT_FAIL);
}
function testAssertFalse_Err_Pass() external {
t._assertFalse(false, CUSTOM_ERROR, EXPECT_PASS);
}
function testAssertFalse_Err_Fail() external {
vm.expectEmit(false, false, false, true);
emit log_named_string("Error", CUSTOM_ERROR);
t._assertFalse(true, CUSTOM_ERROR, EXPECT_FAIL);
}
/*//////////////////////////////////////////////////////////////////////////
ASSERT_EQ(BOOL)
//////////////////////////////////////////////////////////////////////////*/
function testAssertEq_Bool_Pass(bool a) external {
t._assertEq(a, a, EXPECT_PASS);
}
function testAssertEq_Bool_Fail(bool a, bool b) external {
vm.assume(a != b);
vm.expectEmit(false, false, false, true);
emit log("Error: a == b not satisfied [bool]");
t._assertEq(a, b, EXPECT_FAIL);
}
function testAssertEq_BoolErr_Pass(bool a) external {
t._assertEq(a, a, CUSTOM_ERROR, EXPECT_PASS);
}
function testAssertEq_BoolErr_Fail(bool a, bool b) external {
vm.assume(a != b);
vm.expectEmit(false, false, false, true);
emit log_named_string("Error", CUSTOM_ERROR);
t._assertEq(a, b, CUSTOM_ERROR, EXPECT_FAIL);
}
/*//////////////////////////////////////////////////////////////////////////
ASSERT_EQ(BYTES)
//////////////////////////////////////////////////////////////////////////*/
function testAssertEq_Bytes_Pass(bytes calldata a) external {
t._assertEq(a, a, EXPECT_PASS);
}
function testAssertEq_Bytes_Fail(bytes calldata a, bytes calldata b) external {
vm.assume(keccak256(a) != keccak256(b));
vm.expectEmit(false, false, false, true);
emit log("Error: a == b not satisfied [bytes]");
t._assertEq(a, b, EXPECT_FAIL);
}
function testAssertEq_BytesErr_Pass(bytes calldata a) external {
t._assertEq(a, a, CUSTOM_ERROR, EXPECT_PASS);
}
function testAssertEq_BytesErr_Fail(bytes calldata a, bytes calldata b) external {
vm.assume(keccak256(a) != keccak256(b));
vm.expectEmit(false, false, false, true);
emit log_named_string("Error", CUSTOM_ERROR);
t._assertEq(a, b, CUSTOM_ERROR, EXPECT_FAIL);
}
/*//////////////////////////////////////////////////////////////////////////
ASSERT_EQ(ARRAY)
//////////////////////////////////////////////////////////////////////////*/
function testAssertEq_UintArr_Pass(uint256 e0, uint256 e1, uint256 e2) public {
uint256[] memory a = new uint256[](3);
a[0] = e0;
a[1] = e1;
a[2] = e2;
uint256[] memory b = new uint256[](3);
b[0] = e0;
b[1] = e1;
b[2] = e2;
t._assertEq(a, b, EXPECT_PASS);
}
function testAssertEq_IntArr_Pass(int256 e0, int256 e1, int256 e2) public {
int256[] memory a = new int256[](3);
a[0] = e0;
a[1] = e1;
a[2] = e2;
int256[] memory b = new int256[](3);
b[0] = e0;
b[1] = e1;
b[2] = e2;
t._assertEq(a, b, EXPECT_PASS);
}
function testAssertEq_AddressArr_Pass(address e0, address e1, address e2) public {
address[] memory a = new address[](3);
a[0] = e0;
a[1] = e1;
a[2] = e2;
address[] memory b = new address[](3);
b[0] = e0;
b[1] = e1;
b[2] = e2;
t._assertEq(a, b, EXPECT_PASS);
}
function testAssertEq_UintArr_FailEl(uint256 e1) public {
vm.assume(e1 != 0);
uint256[] memory a = new uint256[](3);
uint256[] memory b = new uint256[](3);
b[1] = e1;
vm.expectEmit(false, false, false, true);
emit log("Error: a == b not satisfied [uint[]]");
t._assertEq(a, b, EXPECT_FAIL);
}
function testAssertEq_IntArr_FailEl(int256 e1) public {
vm.assume(e1 != 0);
int256[] memory a = new int256[](3);
int256[] memory b = new int256[](3);
b[1] = e1;
vm.expectEmit(false, false, false, true);
emit log("Error: a == b not satisfied [int[]]");
t._assertEq(a, b, EXPECT_FAIL);
}
function testAssertEq_AddressArr_FailEl(address e1) public {
vm.assume(e1 != address(0));
address[] memory a = new address[](3);
address[] memory b = new address[](3);
b[1] = e1;
vm.expectEmit(false, false, false, true);
emit log("Error: a == b not satisfied [address[]]");
t._assertEq(a, b, EXPECT_FAIL);
}
function testAssertEq_UintArrErr_FailEl(uint256 e1) public {
vm.assume(e1 != 0);
uint256[] memory a = new uint256[](3);
uint256[] memory b = new uint256[](3);
b[1] = e1;
vm.expectEmit(false, false, false, true);
emit log_named_string("Error", CUSTOM_ERROR);
vm.expectEmit(false, false, false, true);
emit log("Error: a == b not satisfied [uint[]]");
t._assertEq(a, b, CUSTOM_ERROR, EXPECT_FAIL);
}
function testAssertEq_IntArrErr_FailEl(int256 e1) public {
vm.assume(e1 != 0);
int256[] memory a = new int256[](3);
int256[] memory b = new int256[](3);
b[1] = e1;
vm.expectEmit(false, false, false, true);
emit log_named_string("Error", CUSTOM_ERROR);
vm.expectEmit(false, false, false, true);
emit log("Error: a == b not satisfied [int[]]");
t._assertEq(a, b, CUSTOM_ERROR, EXPECT_FAIL);
}
function testAssertEq_AddressArrErr_FailEl(address e1) public {
vm.assume(e1 != address(0));
address[] memory a = new address[](3);
address[] memory b = new address[](3);
b[1] = e1;
vm.expectEmit(false, false, false, true);
emit log_named_string("Error", CUSTOM_ERROR);
vm.expectEmit(false, false, false, true);
emit log("Error: a == b not satisfied [address[]]");
t._assertEq(a, b, CUSTOM_ERROR, EXPECT_FAIL);
}
function testAssertEq_UintArr_FailLen(uint256 lenA, uint256 lenB) public {
vm.assume(lenA != lenB);
vm.assume(lenA <= 10000);
vm.assume(lenB <= 10000);
uint256[] memory a = new uint256[](lenA);
uint256[] memory b = new uint256[](lenB);
vm.expectEmit(false, false, false, true);
emit log("Error: a == b not satisfied [uint[]]");
t._assertEq(a, b, EXPECT_FAIL);
}
function testAssertEq_IntArr_FailLen(uint256 lenA, uint256 lenB) public {
vm.assume(lenA != lenB);
vm.assume(lenA <= 10000);
vm.assume(lenB <= 10000);
int256[] memory a = new int256[](lenA);
int256[] memory b = new int256[](lenB);
vm.expectEmit(false, false, false, true);
emit log("Error: a == b not satisfied [int[]]");
t._assertEq(a, b, EXPECT_FAIL);
}
function testAssertEq_AddressArr_FailLen(uint256 lenA, uint256 lenB) public {
vm.assume(lenA != lenB);
vm.assume(lenA <= 10000);
vm.assume(lenB <= 10000);
address[] memory a = new address[](lenA);
address[] memory b = new address[](lenB);
vm.expectEmit(false, false, false, true);
emit log("Error: a == b not satisfied [address[]]");
t._assertEq(a, b, EXPECT_FAIL);
}
function testAssertEq_UintArrErr_FailLen(uint256 lenA, uint256 lenB) public {
vm.assume(lenA != lenB);
vm.assume(lenA <= 10000);
vm.assume(lenB <= 10000);
uint256[] memory a = new uint256[](lenA);
uint256[] memory b = new uint256[](lenB);
vm.expectEmit(false, false, false, true);
emit log_named_string("Error", CUSTOM_ERROR);
vm.expectEmit(false, false, false, true);
emit log("Error: a == b not satisfied [uint[]]");
t._assertEq(a, b, CUSTOM_ERROR, EXPECT_FAIL);
}
function testAssertEq_IntArrErr_FailLen(uint256 lenA, uint256 lenB) public {
vm.assume(lenA != lenB);
vm.assume(lenA <= 10000);
vm.assume(lenB <= 10000);
int256[] memory a = new int256[](lenA);
int256[] memory b = new int256[](lenB);
vm.expectEmit(false, false, false, true);
emit log_named_string("Error", CUSTOM_ERROR);
vm.expectEmit(false, false, false, true);
emit log("Error: a == b not satisfied [int[]]");
t._assertEq(a, b, CUSTOM_ERROR, EXPECT_FAIL);
}
function testAssertEq_AddressArrErr_FailLen(uint256 lenA, uint256 lenB) public {
vm.assume(lenA != lenB);
vm.assume(lenA <= 10000);
vm.assume(lenB <= 10000);
address[] memory a = new address[](lenA);
address[] memory b = new address[](lenB);
vm.expectEmit(false, false, false, true);
emit log_named_string("Error", CUSTOM_ERROR);
vm.expectEmit(false, false, false, true);
emit log("Error: a == b not satisfied [address[]]");
t._assertEq(a, b, CUSTOM_ERROR, EXPECT_FAIL);
}
/*//////////////////////////////////////////////////////////////////////////
APPROX_EQ_ABS(UINT)
//////////////////////////////////////////////////////////////////////////*/
function testAssertApproxEqAbs_Uint_Pass(uint256 a, uint256 b, uint256 maxDelta) external {
vm.assume(stdMath.delta(a, b) <= maxDelta);
t._assertApproxEqAbs(a, b, maxDelta, EXPECT_PASS);
}
function testAssertApproxEqAbs_Uint_Fail(uint256 a, uint256 b, uint256 maxDelta) external {
vm.assume(stdMath.delta(a, b) > maxDelta);
vm.expectEmit(false, false, false, true);
emit log("Error: a ~= b not satisfied [uint]");
t._assertApproxEqAbs(a, b, maxDelta, EXPECT_FAIL);
}
function testAssertApproxEqAbs_UintErr_Pass(uint256 a, uint256 b, uint256 maxDelta) external {
vm.assume(stdMath.delta(a, b) <= maxDelta);
t._assertApproxEqAbs(a, b, maxDelta, CUSTOM_ERROR, EXPECT_PASS);
}
function testAssertApproxEqAbs_UintErr_Fail(uint256 a, uint256 b, uint256 maxDelta) external {
vm.assume(stdMath.delta(a, b) > maxDelta);
vm.expectEmit(false, false, false, true);
emit log_named_string("Error", CUSTOM_ERROR);
t._assertApproxEqAbs(a, b, maxDelta, CUSTOM_ERROR, EXPECT_FAIL);
}
/*//////////////////////////////////////////////////////////////////////////
APPROX_EQ_ABS(INT)
//////////////////////////////////////////////////////////////////////////*/
function testAssertApproxEqAbs_Int_Pass(int256 a, int256 b, uint256 maxDelta) external {
vm.assume(stdMath.delta(a, b) <= maxDelta);
t._assertApproxEqAbs(a, b, maxDelta, EXPECT_PASS);
}
function testAssertApproxEqAbs_Int_Fail(int256 a, int256 b, uint256 maxDelta) external {
vm.assume(stdMath.delta(a, b) > maxDelta);
vm.expectEmit(false, false, false, true);
emit log("Error: a ~= b not satisfied [int]");
t._assertApproxEqAbs(a, b, maxDelta, EXPECT_FAIL);
}
function testAssertApproxEqAbs_IntErr_Pass(int256 a, int256 b, uint256 maxDelta) external {
vm.assume(stdMath.delta(a, b) <= maxDelta);
t._assertApproxEqAbs(a, b, maxDelta, CUSTOM_ERROR, EXPECT_PASS);
}
function testAssertApproxEqAbs_IntErr_Fail(int256 a, int256 b, uint256 maxDelta) external {
vm.assume(stdMath.delta(a, b) > maxDelta);
vm.expectEmit(false, false, false, true);
emit log_named_string("Error", CUSTOM_ERROR);
t._assertApproxEqAbs(a, b, maxDelta, CUSTOM_ERROR, EXPECT_FAIL);
}
/*//////////////////////////////////////////////////////////////////////////
APPROX_EQ_REL(UINT)
//////////////////////////////////////////////////////////////////////////*/
function testAssertApproxEqRel_Uint_Pass(uint256 a, uint256 b, uint256 maxPercentDelta) external {
vm.assume(a < type(uint128).max && b < type(uint128).max && b != 0);
vm.assume(stdMath.percentDelta(a, b) <= maxPercentDelta);
t._assertApproxEqRel(a, b, maxPercentDelta, EXPECT_PASS);
}
function testAssertApproxEqRel_Uint_Fail(uint256 a, uint256 b, uint256 maxPercentDelta) external {
vm.assume(a < type(uint128).max && b < type(uint128).max && b != 0);
vm.assume(stdMath.percentDelta(a, b) > maxPercentDelta);
vm.expectEmit(false, false, false, true);
emit log("Error: a ~= b not satisfied [uint]");
t._assertApproxEqRel(a, b, maxPercentDelta, EXPECT_FAIL);
}
function testAssertApproxEqRel_UintErr_Pass(uint256 a, uint256 b, uint256 maxPercentDelta) external {
vm.assume(a < type(uint128).max && b < type(uint128).max && b != 0);
vm.assume(stdMath.percentDelta(a, b) <= maxPercentDelta);
t._assertApproxEqRel(a, b, maxPercentDelta, CUSTOM_ERROR, EXPECT_PASS);
}
function testAssertApproxEqRel_UintErr_Fail(uint256 a, uint256 b, uint256 maxPercentDelta) external {
vm.assume(a < type(uint128).max && b < type(uint128).max && b != 0);
vm.assume(stdMath.percentDelta(a, b) > maxPercentDelta);
vm.expectEmit(false, false, false, true);
emit log_named_string("Error", CUSTOM_ERROR);
t._assertApproxEqRel(a, b, maxPercentDelta, CUSTOM_ERROR, EXPECT_FAIL);
}
/*//////////////////////////////////////////////////////////////////////////
APPROX_EQ_REL(INT)
//////////////////////////////////////////////////////////////////////////*/
function testAssertApproxEqRel_Int_Pass(int128 a, int128 b, uint128 maxPercentDelta) external {
vm.assume(b != 0);
vm.assume(stdMath.percentDelta(a, b) <= maxPercentDelta);
t._assertApproxEqRel(a, b, maxPercentDelta, EXPECT_PASS);
}
function testAssertApproxEqRel_Int_Fail(int128 a, int128 b, uint128 maxPercentDelta) external {
vm.assume(b != 0);
vm.assume(stdMath.percentDelta(a, b) > maxPercentDelta);
vm.expectEmit(false, false, false, true);
emit log("Error: a ~= b not satisfied [int]");
t._assertApproxEqRel(a, b, maxPercentDelta, EXPECT_FAIL);
}
function testAssertApproxEqRel_IntErr_Pass(int128 a, int128 b, uint128 maxPercentDelta) external {
vm.assume(b != 0);
vm.assume(stdMath.percentDelta(a, b) <= maxPercentDelta);
t._assertApproxEqRel(a, b, maxPercentDelta, CUSTOM_ERROR, EXPECT_PASS);
}
function testAssertApproxEqRel_IntErr_Fail(int128 a, int128 b, uint128 maxPercentDelta) external {
vm.assume(b != 0);
vm.assume(stdMath.percentDelta(a, b) > maxPercentDelta);
vm.expectEmit(false, false, false, true);
emit log_named_string("Error", CUSTOM_ERROR);
t._assertApproxEqRel(a, b, maxPercentDelta, CUSTOM_ERROR, EXPECT_FAIL);
}
}
contract TestTest is Test
{
modifier expectFailure(bool expectFail) {
bool preState = vm.load(HEVM_ADDRESS, bytes32("failed")) != bytes32(0x00);
_;
bool postState = vm.load(HEVM_ADDRESS, bytes32("failed")) != bytes32(0x00);
if (preState == true) {
return;
}
if (expectFail) {
require(postState == true, "expected failure not triggered");
// unwind the expected failure
vm.store(HEVM_ADDRESS, bytes32("failed"), bytes32(uint256(0x00)));
} else {
require(postState == false, "unexpected failure was triggered");
}
}
function _fail(string memory err) external expectFailure(true) {
fail(err);
}
function _assertFalse(bool data, bool expectFail) external expectFailure(expectFail) {
assertFalse(data);
}
function _assertFalse(bool data, string memory err, bool expectFail) external expectFailure(expectFail) {
assertFalse(data, err);
}
function _assertEq(bool a, bool b, bool expectFail) external expectFailure(expectFail) {
assertEq(a, b);
}
function _assertEq(bool a, bool b, string memory err, bool expectFail) external expectFailure(expectFail) {
assertEq(a, b, err);
}
function _assertEq(bytes memory a, bytes memory b, bool expectFail) external expectFailure(expectFail) {
assertEq(a, b);
}
function _assertEq(bytes memory a,
bytes memory b,
string memory err,
bool expectFail
) external expectFailure(expectFail) {
assertEq(a, b, err);
}
function _assertEq(uint256[] memory a, uint256[] memory b, bool expectFail) external expectFailure(expectFail) {
assertEq(a, b);
}
function _assertEq(int256[] memory a, int256[] memory b, bool expectFail) external expectFailure(expectFail) {
assertEq(a, b);
}
function _assertEq(address[] memory a, address[] memory b, bool expectFail) external expectFailure(expectFail) {
assertEq(a, b);
}
function _assertEq(uint256[] memory a, uint256[] memory b, string memory err, bool expectFail) external expectFailure(expectFail) {
assertEq(a, b, err);
}
function _assertEq(int256[] memory a, int256[] memory b, string memory err, bool expectFail) external expectFailure(expectFail) {
assertEq(a, b, err);
}
function _assertEq(address[] memory a, address[] memory b, string memory err, bool expectFail) external expectFailure(expectFail) {
assertEq(a, b, err);
}
function _assertApproxEqAbs(
uint256 a,
uint256 b,
uint256 maxDelta,
bool expectFail
) external expectFailure(expectFail) {
assertApproxEqAbs(a, b, maxDelta);
}
function _assertApproxEqAbs(
uint256 a,
uint256 b,
uint256 maxDelta,
string memory err,
bool expectFail
) external expectFailure(expectFail) {
assertApproxEqAbs(a, b, maxDelta, err);
}
function _assertApproxEqAbs(
int256 a,
int256 b,
uint256 maxDelta,
bool expectFail
) external expectFailure(expectFail) {
assertApproxEqAbs(a, b, maxDelta);
}
function _assertApproxEqAbs(
int256 a,
int256 b,
uint256 maxDelta,
string memory err,
bool expectFail
) external expectFailure(expectFail) {
assertApproxEqAbs(a, b, maxDelta, err);
}
function _assertApproxEqRel(
uint256 a,
uint256 b,
uint256 maxPercentDelta,
bool expectFail
) external expectFailure(expectFail) {
assertApproxEqRel(a, b, maxPercentDelta);
}
function _assertApproxEqRel(
uint256 a,
uint256 b,
uint256 maxPercentDelta,
string memory err,
bool expectFail
) external expectFailure(expectFail) {
assertApproxEqRel(a, b, maxPercentDelta, err);
}
function _assertApproxEqRel(
int256 a,
int256 b,
uint256 maxPercentDelta,
bool expectFail
) external expectFailure(expectFail) {
assertApproxEqRel(a, b, maxPercentDelta);
}
function _assertApproxEqRel(
int256 a,
int256 b,
uint256 maxPercentDelta,
string memory err,
bool expectFail
) external expectFailure(expectFail) {
assertApproxEqRel(a, b, maxPercentDelta, err);
}
}

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// SPDX-License-Identifier: MIT
pragma solidity >=0.7.0 <0.9.0;
import "../Test.sol";
import "../StdJson.sol";
contract StdCheatsTest is Test {
Bar test;
using stdJson for string;
function setUp() public {
test = new Bar();
}
function testSkip() public {
vm.warp(100);
skip(25);
assertEq(block.timestamp, 125);
}
function testRewind() public {
vm.warp(100);
rewind(25);
assertEq(block.timestamp, 75);
}
function testHoax() public {
hoax(address(1337));
test.bar{value: 100}(address(1337));
}
function testHoaxOrigin() public {
hoax(address(1337), address(1337));
test.origin{value: 100}(address(1337));
}
function testHoaxDifferentAddresses() public {
hoax(address(1337), address(7331));
test.origin{value: 100}(address(1337), address(7331));
}
function testStartHoax() public {
startHoax(address(1337));
test.bar{value: 100}(address(1337));
test.bar{value: 100}(address(1337));
vm.stopPrank();
test.bar(address(this));
}
function testStartHoaxOrigin() public {
startHoax(address(1337), address(1337));
test.origin{value: 100}(address(1337));
test.origin{value: 100}(address(1337));
vm.stopPrank();
test.bar(address(this));
}
function testChangePrank() public {
vm.startPrank(address(1337));
test.bar(address(1337));
changePrank(address(0xdead));
test.bar(address(0xdead));
changePrank(address(1337));
test.bar(address(1337));
vm.stopPrank();
}
function testMakeAddrEquivalence() public {
(address addr, ) = makeAddrAndKey("1337");
assertEq(makeAddr("1337"), addr);
}
function testMakeAddrSigning() public {
(address addr, uint256 key) = makeAddrAndKey("1337");
bytes32 hash = keccak256("some_message");
(uint8 v, bytes32 r, bytes32 s) = vm.sign(key, hash);
assertEq(ecrecover(hash, v, r, s), addr);
}
function testDeal() public {
deal(address(this), 1 ether);
assertEq(address(this).balance, 1 ether);
}
function testDealToken() public {
Bar barToken = new Bar();
address bar = address(barToken);
deal(bar, address(this), 10000e18);
assertEq(barToken.balanceOf(address(this)), 10000e18);
}
function testDealTokenAdjustTS() public {
Bar barToken = new Bar();
address bar = address(barToken);
deal(bar, address(this), 10000e18, true);
assertEq(barToken.balanceOf(address(this)), 10000e18);
assertEq(barToken.totalSupply(), 20000e18);
deal(bar, address(this), 0, true);
assertEq(barToken.balanceOf(address(this)), 0);
assertEq(barToken.totalSupply(), 10000e18);
}
function testBound() public {
assertEq(bound(5, 0, 4), 0);
assertEq(bound(0, 69, 69), 69);
assertEq(bound(0, 68, 69), 68);
assertEq(bound(10, 150, 190), 160);
assertEq(bound(300, 2800, 3200), 3100);
assertEq(bound(9999, 1337, 6666), 6006);
}
function testCannotBoundMaxLessThanMin() public {
vm.expectRevert(bytes("Test bound(uint256,uint256,uint256): Max is less than min."));
bound(5, 100, 10);
}
function testBound(
uint256 num,
uint256 min,
uint256 max
) public {
if (min > max) (min, max) = (max, min);
uint256 bounded = bound(num, min, max);
assertGe(bounded, min);
assertLe(bounded, max);
}
function testBoundUint256Max() public {
assertEq(bound(0, type(uint256).max - 1, type(uint256).max), type(uint256).max - 1);
assertEq(bound(1, type(uint256).max - 1, type(uint256).max), type(uint256).max);
}
function testCannotBoundMaxLessThanMin(
uint256 num,
uint256 min,
uint256 max
) public {
vm.assume(min > max);
vm.expectRevert(bytes("Test bound(uint256,uint256,uint256): Max is less than min."));
bound(num, min, max);
}
function testDeployCode() public {
address deployed = deployCode("StdCheats.t.sol:StdCheatsTest", bytes(""));
assertEq(string(getCode(deployed)), string(getCode(address(this))));
}
function testDeployCodeNoArgs() public {
address deployed = deployCode("StdCheats.t.sol:StdCheatsTest");
assertEq(string(getCode(deployed)), string(getCode(address(this))));
}
// We need that payable constructor in order to send ETH on construction
constructor() payable {}
function testDeployCodeVal() public {
address deployed = deployCode("StdCheats.t.sol:StdCheatsTest", bytes(""), 1 ether);
assertEq(string(getCode(deployed)), string(getCode(address(this))));
assertEq(deployed.balance, 1 ether);
}
function testDeployCodeValNoArgs() public {
address deployed = deployCode("StdCheats.t.sol:StdCheatsTest", 1 ether);
assertEq(string(getCode(deployed)), string(getCode(address(this))));
assertEq(deployed.balance, 1 ether);
}
// We need this so we can call "this.deployCode" rather than "deployCode" directly
function deployCodeHelper(string memory what) external {
deployCode(what);
}
function testDeployCodeFail() public {
vm.expectRevert(bytes("Test deployCode(string): Deployment failed."));
this.deployCodeHelper("StdCheats.t.sol:RevertingContract");
}
function getCode(address who) internal view returns (bytes memory o_code) {
/// @solidity memory-safe-assembly
assembly {
// retrieve the size of the code, this needs assembly
let size := extcodesize(who)
// allocate output byte array - this could also be done without assembly
// by using o_code = new bytes(size)
o_code := mload(0x40)
// new "memory end" including padding
mstore(0x40, add(o_code, and(add(add(size, 0x20), 0x1f), not(0x1f))))
// store length in memory
mstore(o_code, size)
// actually retrieve the code, this needs assembly
extcodecopy(who, add(o_code, 0x20), 0, size)
}
}
function testBytesToUint() public {
assertEq(3, bytesToUint(hex'03'));
assertEq(2, bytesToUint(hex'02'));
assertEq(255, bytesToUint(hex'ff'));
assertEq(29625, bytesToUint(hex'73b9'));
}
function testParseJsonTxDetail() public {
string memory root = vm.projectRoot();
string memory path = string.concat(root, "/src/test/fixtures/broadcast.log.json");
string memory json = vm.readFile(path);
bytes memory transactionDetails = json.parseRaw(".transactions[0].tx");
RawTx1559Detail memory rawTxDetail = abi.decode(transactionDetails, (RawTx1559Detail));
Tx1559Detail memory txDetail = rawToConvertedEIP1559Detail(rawTxDetail);
assertEq(txDetail.from, 0xf39Fd6e51aad88F6F4ce6aB8827279cffFb92266);
assertEq(txDetail.to, 0xe7f1725E7734CE288F8367e1Bb143E90bb3F0512);
assertEq(txDetail.data, hex'23e99187000000000000000000000000000000000000000000000000000000000000000100000000000000000000000000000000000000000000000000000000000013370000000000000000000000000000000000000000000000000000000000000060000000000000000000000000000000000000000000000000000000000000000200000000000000000000000000000000000000000000000000000000000000030000000000000000000000000000000000000000000000000000000000000004');
assertEq(txDetail.nonce, 3);
assertEq(txDetail.txType, 2);
assertEq(txDetail.gas, 29625);
assertEq(txDetail.value, 0);
}
function testReadEIP1559Transaction() public {
string memory root = vm.projectRoot();
string memory path = string.concat(root, "/src/test/fixtures/broadcast.log.json");
uint256 index = 0;
Tx1559 memory transaction = readTx1559(path, index);
}
function testReadEIP1559Transactions() public {
string memory root = vm.projectRoot();
string memory path = string.concat(root, "/src/test/fixtures/broadcast.log.json");
Tx1559[] memory transactions = readTx1559s(path);
}
function testReadReceipt() public {
string memory root = vm.projectRoot();
string memory path = string.concat(root, "/src/test/fixtures/broadcast.log.json");
uint index = 5;
Receipt memory receipt = readReceipt(path, index);
assertEq(receipt.logsBloom,
hex"00000000000800000000000000000010000000000000000000000000000180000000000000000000000000000000000000000000000008000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000100");
}
function testReadReceipts() public {
string memory root = vm.projectRoot();
string memory path = string.concat(root, "/src/test/fixtures/broadcast.log.json");
Receipt[] memory receipts = readReceipts(path);
}
}
contract Bar {
constructor() {
/// `DEAL` STDCHEAT
totalSupply = 10000e18;
balanceOf[address(this)] = totalSupply;
}
/// `HOAX` STDCHEATS
function bar(address expectedSender) public payable {
require(msg.sender == expectedSender, "!prank");
}
function origin(address expectedSender) public payable {
require(msg.sender == expectedSender, "!prank");
require(tx.origin == expectedSender, "!prank");
}
function origin(address expectedSender, address expectedOrigin) public payable {
require(msg.sender == expectedSender, "!prank");
require(tx.origin == expectedOrigin, "!prank");
}
/// `DEAL` STDCHEAT
mapping (address => uint256) public balanceOf;
uint256 public totalSupply;
}
contract RevertingContract {
constructor() {
revert();
}
}

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// SPDX-License-Identifier: MIT
pragma solidity >=0.8.10 <0.9.0;
import "../Test.sol";
contract StdErrorsTest is Test {
ErrorsTest test;
function setUp() public {
test = new ErrorsTest();
}
function testExpectAssertion() public {
vm.expectRevert(stdError.assertionError);
test.assertionError();
}
function testExpectArithmetic() public {
vm.expectRevert(stdError.arithmeticError);
test.arithmeticError(10);
}
function testExpectDiv() public {
vm.expectRevert(stdError.divisionError);
test.divError(0);
}
function testExpectMod() public {
vm.expectRevert(stdError.divisionError);
test.modError(0);
}
function testExpectEnum() public {
vm.expectRevert(stdError.enumConversionError);
test.enumConversion(1);
}
function testExpectEncodeStg() public {
vm.expectRevert(stdError.encodeStorageError);
test.encodeStgError();
}
function testExpectPop() public {
vm.expectRevert(stdError.popError);
test.pop();
}
function testExpectOOB() public {
vm.expectRevert(stdError.indexOOBError);
test.indexOOBError(1);
}
function testExpectMem() public {
vm.expectRevert(stdError.memOverflowError);
test.mem();
}
function testExpectIntern() public {
vm.expectRevert(stdError.zeroVarError);
test.intern();
}
function testExpectLowLvl() public {
vm.expectRevert(stdError.lowLevelError);
test.someArr(0);
}
}
contract ErrorsTest {
enum T {
T1
}
uint256[] public someArr;
bytes someBytes;
function assertionError() public pure {
assert(false);
}
function arithmeticError(uint256 a) public pure {
a -= 100;
}
function divError(uint256 a) public pure {
100 / a;
}
function modError(uint256 a) public pure {
100 % a;
}
function enumConversion(uint256 a) public pure {
T(a);
}
function encodeStgError() public {
/// @solidity memory-safe-assembly
assembly {
sstore(someBytes.slot, 1)
}
keccak256(someBytes);
}
function pop() public {
someArr.pop();
}
function indexOOBError(uint256 a) public pure {
uint256[] memory t = new uint256[](0);
t[a];
}
function mem() public pure {
uint256 l = 2**256 / 32;
new uint256[](l);
}
function intern() public returns (uint256) {
function(uint256) internal returns (uint256) x;
x(2);
return 7;
}
}

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// SPDX-License-Identifier: MIT
pragma solidity >=0.8.0 <0.9.0;
import "../Test.sol";
contract StdMathTest is Test
{
function testGetAbs() external {
assertEq(stdMath.abs(-50), 50);
assertEq(stdMath.abs(50), 50);
assertEq(stdMath.abs(-1337), 1337);
assertEq(stdMath.abs(0), 0);
assertEq(stdMath.abs(type(int256).min), (type(uint256).max >> 1) + 1);
assertEq(stdMath.abs(type(int256).max), (type(uint256).max >> 1));
}
function testGetAbs_Fuzz(int256 a) external {
uint256 manualAbs = getAbs(a);
uint256 abs = stdMath.abs(a);
assertEq(abs, manualAbs);
}
function testGetDelta_Uint() external {
assertEq(stdMath.delta(uint256(0), uint256(0)), 0);
assertEq(stdMath.delta(uint256(0), uint256(1337)), 1337);
assertEq(stdMath.delta(uint256(0), type(uint64).max), type(uint64).max);
assertEq(stdMath.delta(uint256(0), type(uint128).max), type(uint128).max);
assertEq(stdMath.delta(uint256(0), type(uint256).max), type(uint256).max);
assertEq(stdMath.delta(0, uint256(0)), 0);
assertEq(stdMath.delta(1337, uint256(0)), 1337);
assertEq(stdMath.delta(type(uint64).max, uint256(0)), type(uint64).max);
assertEq(stdMath.delta(type(uint128).max, uint256(0)), type(uint128).max);
assertEq(stdMath.delta(type(uint256).max, uint256(0)), type(uint256).max);
assertEq(stdMath.delta(1337, uint256(1337)), 0);
assertEq(stdMath.delta(type(uint256).max, type(uint256).max), 0);
assertEq(stdMath.delta(5000, uint256(1250)), 3750);
}
function testGetDelta_Uint_Fuzz(uint256 a, uint256 b) external {
uint256 manualDelta;
if (a > b) {
manualDelta = a - b;
} else {
manualDelta = b - a;
}
uint256 delta = stdMath.delta(a, b);
assertEq(delta, manualDelta);
}
function testGetDelta_Int() external {
assertEq(stdMath.delta(int256(0), int256(0)), 0);
assertEq(stdMath.delta(int256(0), int256(1337)), 1337);
assertEq(stdMath.delta(int256(0), type(int64).max), type(uint64).max >> 1);
assertEq(stdMath.delta(int256(0), type(int128).max), type(uint128).max >> 1);
assertEq(stdMath.delta(int256(0), type(int256).max), type(uint256).max >> 1);
assertEq(stdMath.delta(0, int256(0)), 0);
assertEq(stdMath.delta(1337, int256(0)), 1337);
assertEq(stdMath.delta(type(int64).max, int256(0)), type(uint64).max >> 1);
assertEq(stdMath.delta(type(int128).max, int256(0)), type(uint128).max >> 1);
assertEq(stdMath.delta(type(int256).max, int256(0)), type(uint256).max >> 1);
assertEq(stdMath.delta(-0, int256(0)), 0);
assertEq(stdMath.delta(-1337, int256(0)), 1337);
assertEq(stdMath.delta(type(int64).min, int256(0)), (type(uint64).max >> 1) + 1);
assertEq(stdMath.delta(type(int128).min, int256(0)), (type(uint128).max >> 1) + 1);
assertEq(stdMath.delta(type(int256).min, int256(0)), (type(uint256).max >> 1) + 1);
assertEq(stdMath.delta(int256(0), -0), 0);
assertEq(stdMath.delta(int256(0), -1337), 1337);
assertEq(stdMath.delta(int256(0), type(int64).min), (type(uint64).max >> 1) + 1);
assertEq(stdMath.delta(int256(0), type(int128).min), (type(uint128).max >> 1) + 1);
assertEq(stdMath.delta(int256(0), type(int256).min), (type(uint256).max >> 1) + 1);
assertEq(stdMath.delta(1337, int256(1337)), 0);
assertEq(stdMath.delta(type(int256).max, type(int256).max), 0);
assertEq(stdMath.delta(type(int256).min, type(int256).min), 0);
assertEq(stdMath.delta(type(int256).min, type(int256).max), type(uint256).max);
assertEq(stdMath.delta(5000, int256(1250)), 3750);
}
function testGetDelta_Int_Fuzz(int256 a, int256 b) external {
uint256 absA = getAbs(a);
uint256 absB = getAbs(b);
uint256 absDelta = absA > absB
? absA - absB
: absB - absA;
uint256 manualDelta;
if ((a >= 0 && b >= 0) || (a < 0 && b < 0)) {
manualDelta = absDelta;
}
// (a < 0 && b >= 0) || (a >= 0 && b < 0)
else {
manualDelta = absA + absB;
}
uint256 delta = stdMath.delta(a, b);
assertEq(delta, manualDelta);
}
function testGetPercentDelta_Uint() external {
assertEq(stdMath.percentDelta(uint256(0), uint256(1337)), 1e18);
assertEq(stdMath.percentDelta(uint256(0), type(uint64).max), 1e18);
assertEq(stdMath.percentDelta(uint256(0), type(uint128).max), 1e18);
assertEq(stdMath.percentDelta(uint256(0), type(uint192).max), 1e18);
assertEq(stdMath.percentDelta(1337, uint256(1337)), 0);
assertEq(stdMath.percentDelta(type(uint192).max, type(uint192).max), 0);
assertEq(stdMath.percentDelta(0, uint256(2500)), 1e18);
assertEq(stdMath.percentDelta(2500, uint256(2500)), 0);
assertEq(stdMath.percentDelta(5000, uint256(2500)), 1e18);
assertEq(stdMath.percentDelta(7500, uint256(2500)), 2e18);
vm.expectRevert(stdError.divisionError);
stdMath.percentDelta(uint256(1), 0);
}
function testGetPercentDelta_Uint_Fuzz(uint192 a, uint192 b) external {
vm.assume(b != 0);
uint256 manualDelta;
if (a > b) {
manualDelta = a - b;
} else {
manualDelta = b - a;
}
uint256 manualPercentDelta = manualDelta * 1e18 / b;
uint256 percentDelta = stdMath.percentDelta(a, b);
assertEq(percentDelta, manualPercentDelta);
}
function testGetPercentDelta_Int() external {
assertEq(stdMath.percentDelta(int256(0), int256(1337)), 1e18);
assertEq(stdMath.percentDelta(int256(0), -1337), 1e18);
assertEq(stdMath.percentDelta(int256(0), type(int64).min), 1e18);
assertEq(stdMath.percentDelta(int256(0), type(int128).min), 1e18);
assertEq(stdMath.percentDelta(int256(0), type(int192).min), 1e18);
assertEq(stdMath.percentDelta(int256(0), type(int64).max), 1e18);
assertEq(stdMath.percentDelta(int256(0), type(int128).max), 1e18);
assertEq(stdMath.percentDelta(int256(0), type(int192).max), 1e18);
assertEq(stdMath.percentDelta(1337, int256(1337)), 0);
assertEq(stdMath.percentDelta(type(int192).max, type(int192).max), 0);
assertEq(stdMath.percentDelta(type(int192).min, type(int192).min), 0);
assertEq(stdMath.percentDelta(type(int192).min, type(int192).max), 2e18); // rounds the 1 wei diff down
assertEq(stdMath.percentDelta(type(int192).max, type(int192).min), 2e18 - 1); // rounds the 1 wei diff down
assertEq(stdMath.percentDelta(0, int256(2500)), 1e18);
assertEq(stdMath.percentDelta(2500, int256(2500)), 0);
assertEq(stdMath.percentDelta(5000, int256(2500)), 1e18);
assertEq(stdMath.percentDelta(7500, int256(2500)), 2e18);
vm.expectRevert(stdError.divisionError);
stdMath.percentDelta(int256(1), 0);
}
function testGetPercentDelta_Int_Fuzz(int192 a, int192 b) external {
vm.assume(b != 0);
uint256 absA = getAbs(a);
uint256 absB = getAbs(b);
uint256 absDelta = absA > absB
? absA - absB
: absB - absA;
uint256 manualDelta;
if ((a >= 0 && b >= 0) || (a < 0 && b < 0)) {
manualDelta = absDelta;
}
// (a < 0 && b >= 0) || (a >= 0 && b < 0)
else {
manualDelta = absA + absB;
}
uint256 manualPercentDelta = manualDelta * 1e18 / absB;
uint256 percentDelta = stdMath.percentDelta(a, b);
assertEq(percentDelta, manualPercentDelta);
}
/*//////////////////////////////////////////////////////////////////////////
HELPERS
//////////////////////////////////////////////////////////////////////////*/
function getAbs(int256 a) private pure returns (uint256) {
if (a < 0)
return a == type(int256).min ? uint256(type(int256).max) + 1 : uint256(-a);
return uint256(a);
}
}

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// SPDX-License-Identifier: MIT
pragma solidity >=0.7.0 <0.9.0;
import "../Test.sol";
contract StdStorageTest is Test {
using stdStorage for StdStorage;
StorageTest test;
function setUp() public {
test = new StorageTest();
}
function testStorageHidden() public {
assertEq(uint256(keccak256("my.random.var")), stdstore.target(address(test)).sig("hidden()").find());
}
function testStorageObvious() public {
assertEq(uint256(0), stdstore.target(address(test)).sig("exists()").find());
}
function testStorageCheckedWriteHidden() public {
stdstore.target(address(test)).sig(test.hidden.selector).checked_write(100);
assertEq(uint256(test.hidden()), 100);
}
function testStorageCheckedWriteObvious() public {
stdstore.target(address(test)).sig(test.exists.selector).checked_write(100);
assertEq(test.exists(), 100);
}
function testStorageMapStructA() public {
uint256 slot = stdstore
.target(address(test))
.sig(test.map_struct.selector)
.with_key(address(this))
.depth(0)
.find();
assertEq(uint256(keccak256(abi.encode(address(this), 4))), slot);
}
function testStorageMapStructB() public {
uint256 slot = stdstore
.target(address(test))
.sig(test.map_struct.selector)
.with_key(address(this))
.depth(1)
.find();
assertEq(uint256(keccak256(abi.encode(address(this), 4))) + 1, slot);
}
function testStorageDeepMap() public {
uint256 slot = stdstore
.target(address(test))
.sig(test.deep_map.selector)
.with_key(address(this))
.with_key(address(this))
.find();
assertEq(uint256(keccak256(abi.encode(address(this), keccak256(abi.encode(address(this), uint(5)))))), slot);
}
function testStorageCheckedWriteDeepMap() public {
stdstore
.target(address(test))
.sig(test.deep_map.selector)
.with_key(address(this))
.with_key(address(this))
.checked_write(100);
assertEq(100, test.deep_map(address(this), address(this)));
}
function testStorageDeepMapStructA() public {
uint256 slot = stdstore
.target(address(test))
.sig(test.deep_map_struct.selector)
.with_key(address(this))
.with_key(address(this))
.depth(0)
.find();
assertEq(bytes32(uint256(keccak256(abi.encode(address(this), keccak256(abi.encode(address(this), uint(6)))))) + 0), bytes32(slot));
}
function testStorageDeepMapStructB() public {
uint256 slot = stdstore
.target(address(test))
.sig(test.deep_map_struct.selector)
.with_key(address(this))
.with_key(address(this))
.depth(1)
.find();
assertEq(bytes32(uint256(keccak256(abi.encode(address(this), keccak256(abi.encode(address(this), uint(6)))))) + 1), bytes32(slot));
}
function testStorageCheckedWriteDeepMapStructA() public {
stdstore
.target(address(test))
.sig(test.deep_map_struct.selector)
.with_key(address(this))
.with_key(address(this))
.depth(0)
.checked_write(100);
(uint256 a, uint256 b) = test.deep_map_struct(address(this), address(this));
assertEq(100, a);
assertEq(0, b);
}
function testStorageCheckedWriteDeepMapStructB() public {
stdstore
.target(address(test))
.sig(test.deep_map_struct.selector)
.with_key(address(this))
.with_key(address(this))
.depth(1)
.checked_write(100);
(uint256 a, uint256 b) = test.deep_map_struct(address(this), address(this));
assertEq(0, a);
assertEq(100, b);
}
function testStorageCheckedWriteMapStructA() public {
stdstore
.target(address(test))
.sig(test.map_struct.selector)
.with_key(address(this))
.depth(0)
.checked_write(100);
(uint256 a, uint256 b) = test.map_struct(address(this));
assertEq(a, 100);
assertEq(b, 0);
}
function testStorageCheckedWriteMapStructB() public {
stdstore
.target(address(test))
.sig(test.map_struct.selector)
.with_key(address(this))
.depth(1)
.checked_write(100);
(uint256 a, uint256 b) = test.map_struct(address(this));
assertEq(a, 0);
assertEq(b, 100);
}
function testStorageStructA() public {
uint256 slot = stdstore.target(address(test)).sig(test.basic.selector).depth(0).find();
assertEq(uint256(7), slot);
}
function testStorageStructB() public {
uint256 slot = stdstore.target(address(test)).sig(test.basic.selector).depth(1).find();
assertEq(uint256(7) + 1, slot);
}
function testStorageCheckedWriteStructA() public {
stdstore.target(address(test)).sig(test.basic.selector).depth(0).checked_write(100);
(uint256 a, uint256 b) = test.basic();
assertEq(a, 100);
assertEq(b, 1337);
}
function testStorageCheckedWriteStructB() public {
stdstore.target(address(test)).sig(test.basic.selector).depth(1).checked_write(100);
(uint256 a, uint256 b) = test.basic();
assertEq(a, 1337);
assertEq(b, 100);
}
function testStorageMapAddrFound() public {
uint256 slot = stdstore.target(address(test)).sig(test.map_addr.selector).with_key(address(this)).find();
assertEq(uint256(keccak256(abi.encode(address(this), uint(1)))), slot);
}
function testStorageMapUintFound() public {
uint256 slot = stdstore.target(address(test)).sig(test.map_uint.selector).with_key(100).find();
assertEq(uint256(keccak256(abi.encode(100, uint(2)))), slot);
}
function testStorageCheckedWriteMapUint() public {
stdstore.target(address(test)).sig(test.map_uint.selector).with_key(100).checked_write(100);
assertEq(100, test.map_uint(100));
}
function testStorageCheckedWriteMapAddr() public {
stdstore.target(address(test)).sig(test.map_addr.selector).with_key(address(this)).checked_write(100);
assertEq(100, test.map_addr(address(this)));
}
function testStorageCheckedWriteMapBool() public {
stdstore.target(address(test)).sig(test.map_bool.selector).with_key(address(this)).checked_write(true);
assertTrue(test.map_bool(address(this)));
}
function testFailStorageCheckedWriteMapPacked() public {
// expect PackedSlot error but not external call so cant expectRevert
stdstore.target(address(test)).sig(test.read_struct_lower.selector).with_key(address(uint160(1337))).checked_write(100);
}
function testStorageCheckedWriteMapPackedSuccess() public {
uint256 full = test.map_packed(address(1337));
// keep upper 128, set lower 128 to 1337
full = (full & (uint256((1 << 128) - 1) << 128)) | 1337;
stdstore.target(address(test)).sig(test.map_packed.selector).with_key(address(uint160(1337))).checked_write(full);
assertEq(1337, test.read_struct_lower(address(1337)));
}
function testFailStorageConst() public {
// vm.expectRevert(abi.encodeWithSignature("NotStorage(bytes4)", bytes4(keccak256("const()"))));
stdstore.target(address(test)).sig("const()").find();
}
function testFailStorageNativePack() public {
stdstore.target(address(test)).sig(test.tA.selector).find();
stdstore.target(address(test)).sig(test.tB.selector).find();
// these both would fail
stdstore.target(address(test)).sig(test.tC.selector).find();
stdstore.target(address(test)).sig(test.tD.selector).find();
}
function testStorageReadBytes32() public {
bytes32 val = stdstore.target(address(test)).sig(test.tE.selector).read_bytes32();
assertEq(val, hex"1337");
}
function testStorageReadBool_False() public {
bool val = stdstore.target(address(test)).sig(test.tB.selector).read_bool();
assertEq(val, false);
}
function testStorageReadBool_True() public {
bool val = stdstore.target(address(test)).sig(test.tH.selector).read_bool();
assertEq(val, true);
}
function testStorageReadBool_Revert() public {
vm.expectRevert("stdStorage read_bool(StdStorage): Cannot decode. Make sure you are reading a bool.");
this.readNonBoolValue();
}
function readNonBoolValue() public {
stdstore.target(address(test)).sig(test.tE.selector).read_bool();
}
function testStorageReadAddress() public {
address val = stdstore.target(address(test)).sig(test.tF.selector).read_address();
assertEq(val, address(1337));
}
function testStorageReadUint() public {
uint256 val = stdstore.target(address(test)).sig(test.exists.selector).read_uint();
assertEq(val, 1);
}
function testStorageReadInt() public {
int256 val = stdstore.target(address(test)).sig(test.tG.selector).read_int();
assertEq(val, type(int256).min);
}
}
contract StorageTest {
uint256 public exists = 1;
mapping(address => uint256) public map_addr;
mapping(uint256 => uint256) public map_uint;
mapping(address => uint256) public map_packed;
mapping(address => UnpackedStruct) public map_struct;
mapping(address => mapping(address => uint256)) public deep_map;
mapping(address => mapping(address => UnpackedStruct)) public deep_map_struct;
UnpackedStruct public basic;
uint248 public tA;
bool public tB;
bool public tC = false;
uint248 public tD = 1;
struct UnpackedStruct {
uint256 a;
uint256 b;
}
mapping(address => bool) public map_bool;
bytes32 public tE = hex"1337";
address public tF = address(1337);
int256 public tG = type(int256).min;
bool public tH = true;
constructor() {
basic = UnpackedStruct({
a: 1337,
b: 1337
});
uint256 two = (1<<128) | 1;
map_packed[msg.sender] = two;
map_packed[address(bytes20(uint160(1337)))] = 1<<128;
}
function read_struct_upper(address who) public view returns (uint256) {
return map_packed[who] >> 128;
}
function read_struct_lower(address who) public view returns (uint256) {
return map_packed[who] & ((1 << 128) - 1);
}
function hidden() public view returns (bytes32 t) {
bytes32 slot = keccak256("my.random.var");
/// @solidity memory-safe-assembly
assembly {
t := sload(slot)
}
}
function const() public pure returns (bytes32 t) {
t = bytes32(hex"1337");
}
}

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@ -0,0 +1,187 @@
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"contractAddress": "0x7c6b4bbe207d642d98d5c537142d85209e585087",
"function": "t(uint256):(uint256)",
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],
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}

15
package.json Normal file
View File

@ -0,0 +1,15 @@
{
"name": "accounting-renumeration-proposal",
"version": "1.0.0",
"description": "",
"main": "index.js",
"directories": {
"lib": "lib",
"test": "test"
},
"scripts": {
"test": "forge test"
},
"author": "",
"license": "ISC",
}

21
src/Proposal.sol Normal file
View File

@ -0,0 +1,21 @@
pragma solidity 0.8.1;
import "./interfaces/IERC20.sol";
import "./interfaces/ISablier.sol"
import "./proprietary/Parameters.sol";
contract Proposal is Parameters {
function executeProposal() public {
IERC20(tokenAddress).approve(sablierAddress, RENUMERATION_AMOUNT);
ISablier(sablierAddress).createStream(
RENUMERATION_ADDRESS,
FISCAL_Q_RENUMERATION_AMOUNT,
tokenAddress,
RENUMERATION_START_TS,
RENUMERATION_START_TS + FISCAL_Q_DURATION
);
ISablier(sablierAddress).cancelStream(COMMUNITY_FUND_STREAM_ID);
}
}

13
src/interfaces/IERC20.sol Normal file
View File

@ -0,0 +1,13 @@
pragma solidity 0.8.1;
interface IERC20 {
function transfer(address to, uint256 amount) external returns (bool);
function transferFrom(address from, address to, uint256 amount) external returns (bool);
function balanceOf(address owner) external returns (uint256);
function approve(address spender, uint256 amount) external;
}

View File

@ -0,0 +1,15 @@
pragma solidity 0.8.1;
interface ISablier {
function cancelStream(uint256 streamId) external returns (bool);
function createStream(
address recipent,
uint256 deposit,
address tokenAddress,
uint256 startTime,
uint256 stopTime
) external returns (uint256);
}

View File

@ -0,0 +1,16 @@
pragma solidity 0.8.1;
contract Parameters {
uint256 public COMMUNITY_FUND_STREAM_ID = 103358;
uint256 public FISCAL_Q_RENUMERATION_AMOUNT = 10000 ether;
uint256 public FISCAL_Q_DURATION = 90 days;
uint256 public RENUMERATION_START_TS =;
address public RENUMERATION_ADDRESS =;
// beneficary addresses
address public governanceAddress = 0x5efda50f22d34F262c29268506C5Fa42cB56A1Ce;
address public tokenAddress = 0x77777FeDdddFfC19Ff86DB637967013e6C6A116C;
address public sablierAddress = 0xCD18eAa163733Da39c232722cBC4E8940b1D8888;
}

36
test/Proposal.t.sol Normal file
View File

@ -0,0 +1,36 @@
pragma solidity ^0.8.1;
import "../src/interfaces/IENSResolver.sol";
import "../src/Proposal.sol";
import "forge-std/Test.sol";
contract ProposalTest is Test, Proposal {
function compareBytes(bytes memory a, bytes memory b) public returns (bool e) {
e = keccak256(abi.encodePacked(a)) == keccak256(abi.encodePacked(b));
}
function testProposal() public {
vm.startPrank(address(governanceAddress));
executeProposal();
vm.stopPrank();
_testResults();
}
function _testResults() public {
IENSResolver resolver = IENSResolver(resolverAddress);
bytes memory classicContentHash = resolver.contenthash(CLASSIC_ENS_SUBNODE);
bytes memory novaContentHash = resolver.contenthash(NOVA_ENS_SUBNODE);
require(
compareBytes(classicContentHash, CLASSIC_IPFS_HASH),
"PRIMARY CONTENT NOT UPDATED"
);
require(
compareBytes(novaContentHash, NOVA_IPFS_HASH),
"SECONDARY CONTENT NOT UPDATED"
);
}
}