// SPDX-License-Identifier: MIT // This file was procedurally generated from scripts/generate/templates/Checkpoints.t.js. pragma solidity ^0.8.0; import "forge-std/Test.sol"; import "../../contracts/utils/Checkpoints.sol"; import "../../contracts/utils/math/SafeCast.sol"; contract CheckpointsHistoryTest is Test { using Checkpoints for Checkpoints.History; // Maximum gap between keys used during the fuzzing tests: the `_prepareKeys` function with make sure that // key#n+1 is in the [key#n, key#n + _KEY_MAX_GAP] range. uint8 internal constant _KEY_MAX_GAP = 64; Checkpoints.History internal _ckpts; // helpers function _boundUint32(uint32 x, uint32 min, uint32 max) internal view returns (uint32) { return SafeCast.toUint32(bound(uint256(x), uint256(min), uint256(max))); } function _prepareKeys(uint32[] memory keys, uint32 maxSpread) internal view { uint32 lastKey = 0; for (uint256 i = 0; i < keys.length; ++i) { uint32 key = _boundUint32(keys[i], lastKey, lastKey + maxSpread); keys[i] = key; lastKey = key; } } function _assertLatestCheckpoint(bool exist, uint32 key, uint224 value) internal { (bool _exist, uint32 _key, uint224 _value) = _ckpts.latestCheckpoint(); assertEq(_exist, exist); assertEq(_key, key); assertEq(_value, value); } // tests function testPush(uint32[] memory keys, uint224[] memory values, uint32 pastKey) public { vm.assume(values.length > 0 && values.length <= keys.length); _prepareKeys(keys, _KEY_MAX_GAP); // initial state assertEq(_ckpts.length(), 0); assertEq(_ckpts.latest(), 0); _assertLatestCheckpoint(false, 0, 0); uint256 duplicates = 0; for (uint256 i = 0; i < keys.length; ++i) { uint32 key = keys[i]; uint224 value = values[i % values.length]; if (i > 0 && key == keys[i - 1]) ++duplicates; // push vm.roll(key); _ckpts.push(value); // check length & latest assertEq(_ckpts.length(), i + 1 - duplicates); assertEq(_ckpts.latest(), value); _assertLatestCheckpoint(true, key, value); } // Can't push any key in the past if (keys.length > 0) { uint32 lastKey = keys[keys.length - 1]; pastKey = _boundUint32(pastKey, 0, lastKey - 1); vm.roll(pastKey); vm.expectRevert(); this.push(values[keys.length % values.length]); } } // used to test reverts function push(uint224 value) external { _ckpts.push(value); } function testLookup(uint32[] memory keys, uint224[] memory values, uint32 lookup) public { vm.assume(keys.length > 0); vm.assume(values.length > 0 && values.length <= keys.length); _prepareKeys(keys, _KEY_MAX_GAP); uint32 lastKey = keys[keys.length - 1]; vm.assume(lastKey > 0); lookup = _boundUint32(lookup, 0, lastKey - 1); uint224 upper = 0; for (uint256 i = 0; i < keys.length; ++i) { uint32 key = keys[i]; uint224 value = values[i % values.length]; // push vm.roll(key); _ckpts.push(value); // track expected result of lookups if (key <= lookup) { upper = value; } } // check lookup assertEq(_ckpts.getAtBlock(lookup), upper); assertEq(_ckpts.getAtProbablyRecentBlock(lookup), upper); vm.expectRevert(); this.getAtBlock(lastKey); vm.expectRevert(); this.getAtBlock(lastKey + 1); vm.expectRevert(); this.getAtProbablyRecentBlock(lastKey); vm.expectRevert(); this.getAtProbablyRecentBlock(lastKey + 1); } // used to test reverts function getAtBlock(uint32 key) external view { _ckpts.getAtBlock(key); } // used to test reverts function getAtProbablyRecentBlock(uint32 key) external view { _ckpts.getAtProbablyRecentBlock(key); } } contract CheckpointsTrace224Test is Test { using Checkpoints for Checkpoints.Trace224; // Maximum gap between keys used during the fuzzing tests: the `_prepareKeys` function with make sure that // key#n+1 is in the [key#n, key#n + _KEY_MAX_GAP] range. uint8 internal constant _KEY_MAX_GAP = 64; Checkpoints.Trace224 internal _ckpts; // helpers function _boundUint32(uint32 x, uint32 min, uint32 max) internal view returns (uint32) { return SafeCast.toUint32(bound(uint256(x), uint256(min), uint256(max))); } function _prepareKeys(uint32[] memory keys, uint32 maxSpread) internal view { uint32 lastKey = 0; for (uint256 i = 0; i < keys.length; ++i) { uint32 key = _boundUint32(keys[i], lastKey, lastKey + maxSpread); keys[i] = key; lastKey = key; } } function _assertLatestCheckpoint(bool exist, uint32 key, uint224 value) internal { (bool _exist, uint32 _key, uint224 _value) = _ckpts.latestCheckpoint(); assertEq(_exist, exist); assertEq(_key, key); assertEq(_value, value); } // tests function testPush(uint32[] memory keys, uint224[] memory values, uint32 pastKey) public { vm.assume(values.length > 0 && values.length <= keys.length); _prepareKeys(keys, _KEY_MAX_GAP); // initial state assertEq(_ckpts.length(), 0); assertEq(_ckpts.latest(), 0); _assertLatestCheckpoint(false, 0, 0); uint256 duplicates = 0; for (uint256 i = 0; i < keys.length; ++i) { uint32 key = keys[i]; uint224 value = values[i % values.length]; if (i > 0 && key == keys[i - 1]) ++duplicates; // push _ckpts.push(key, value); // check length & latest assertEq(_ckpts.length(), i + 1 - duplicates); assertEq(_ckpts.latest(), value); _assertLatestCheckpoint(true, key, value); } if (keys.length > 0) { uint32 lastKey = keys[keys.length - 1]; pastKey = _boundUint32(pastKey, 0, lastKey - 1); vm.expectRevert(); this.push(pastKey, values[keys.length % values.length]); } } // used to test reverts function push(uint32 key, uint224 value) external { _ckpts.push(key, value); } function testLookup(uint32[] memory keys, uint224[] memory values, uint32 lookup) public { vm.assume(values.length > 0 && values.length <= keys.length); _prepareKeys(keys, _KEY_MAX_GAP); uint32 lastKey = keys.length == 0 ? 0 : keys[keys.length - 1]; lookup = _boundUint32(lookup, 0, lastKey + _KEY_MAX_GAP); uint224 upper = 0; uint224 lower = 0; uint32 lowerKey = type(uint32).max; for (uint256 i = 0; i < keys.length; ++i) { uint32 key = keys[i]; uint224 value = values[i % values.length]; // push _ckpts.push(key, value); // track expected result of lookups if (key <= lookup) { upper = value; } // find the first key that is not smaller than the lookup key if (key >= lookup && (i == 0 || keys[i - 1] < lookup)) { lowerKey = key; } if (key == lowerKey) { lower = value; } } // check lookup assertEq(_ckpts.lowerLookup(lookup), lower); assertEq(_ckpts.upperLookup(lookup), upper); assertEq(_ckpts.upperLookupRecent(lookup), upper); } } contract CheckpointsTrace160Test is Test { using Checkpoints for Checkpoints.Trace160; // Maximum gap between keys used during the fuzzing tests: the `_prepareKeys` function with make sure that // key#n+1 is in the [key#n, key#n + _KEY_MAX_GAP] range. uint8 internal constant _KEY_MAX_GAP = 64; Checkpoints.Trace160 internal _ckpts; // helpers function _boundUint96(uint96 x, uint96 min, uint96 max) internal view returns (uint96) { return SafeCast.toUint96(bound(uint256(x), uint256(min), uint256(max))); } function _prepareKeys(uint96[] memory keys, uint96 maxSpread) internal view { uint96 lastKey = 0; for (uint256 i = 0; i < keys.length; ++i) { uint96 key = _boundUint96(keys[i], lastKey, lastKey + maxSpread); keys[i] = key; lastKey = key; } } function _assertLatestCheckpoint(bool exist, uint96 key, uint160 value) internal { (bool _exist, uint96 _key, uint160 _value) = _ckpts.latestCheckpoint(); assertEq(_exist, exist); assertEq(_key, key); assertEq(_value, value); } // tests function testPush(uint96[] memory keys, uint160[] memory values, uint96 pastKey) public { vm.assume(values.length > 0 && values.length <= keys.length); _prepareKeys(keys, _KEY_MAX_GAP); // initial state assertEq(_ckpts.length(), 0); assertEq(_ckpts.latest(), 0); _assertLatestCheckpoint(false, 0, 0); uint256 duplicates = 0; for (uint256 i = 0; i < keys.length; ++i) { uint96 key = keys[i]; uint160 value = values[i % values.length]; if (i > 0 && key == keys[i - 1]) ++duplicates; // push _ckpts.push(key, value); // check length & latest assertEq(_ckpts.length(), i + 1 - duplicates); assertEq(_ckpts.latest(), value); _assertLatestCheckpoint(true, key, value); } if (keys.length > 0) { uint96 lastKey = keys[keys.length - 1]; pastKey = _boundUint96(pastKey, 0, lastKey - 1); vm.expectRevert(); this.push(pastKey, values[keys.length % values.length]); } } // used to test reverts function push(uint96 key, uint160 value) external { _ckpts.push(key, value); } function testLookup(uint96[] memory keys, uint160[] memory values, uint96 lookup) public { vm.assume(values.length > 0 && values.length <= keys.length); _prepareKeys(keys, _KEY_MAX_GAP); uint96 lastKey = keys.length == 0 ? 0 : keys[keys.length - 1]; lookup = _boundUint96(lookup, 0, lastKey + _KEY_MAX_GAP); uint160 upper = 0; uint160 lower = 0; uint96 lowerKey = type(uint96).max; for (uint256 i = 0; i < keys.length; ++i) { uint96 key = keys[i]; uint160 value = values[i % values.length]; // push _ckpts.push(key, value); // track expected result of lookups if (key <= lookup) { upper = value; } // find the first key that is not smaller than the lookup key if (key >= lookup && (i == 0 || keys[i - 1] < lookup)) { lowerKey = key; } if (key == lowerKey) { lower = value; } } // check lookup assertEq(_ckpts.lowerLookup(lookup), lower); assertEq(_ckpts.upperLookup(lookup), upper); assertEq(_ckpts.upperLookupRecent(lookup), upper); } }