mirror of
https://github.com/Instadapp/aave-protocol-v2.git
synced 2024-07-29 21:47:30 +00:00
184 lines
5.4 KiB
Ruby
184 lines
5.4 KiB
Ruby
methods {
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getUserLastUpdated(address) returns uint40 envfree
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}
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rule integrityTimeStamp(address user, method f) {
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env e;
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require sinvoke getIncentivesController(e) == 0;
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require getUserLastUpdated(user) <= e.block.timestamp;
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calldataarg arg;
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sinvoke f(e,arg);
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assert getUserLastUpdated(user) <= e.block.timestamp;
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}
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/**
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TotalSupply is the sum of all users’ balances
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totalSupply(t) = Σaddress u. balanceOf(u,t).
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Checks that each possible operation changes the balance of at most one user.
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*/
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rule balanceOfChange(address a, address b, method f)
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{
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env e;
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require a!=b;
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require sinvoke getIncentivesController(e) == 0;
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uint256 balanceABefore = sinvoke balanceOf(e, a);
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uint256 balanceBBefore = sinvoke balanceOf(e, b);
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calldataarg arg;
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sinvoke f(e, arg);
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uint256 balanceAAfter = sinvoke balanceOf(e, a);
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uint256 balanceBAfter = sinvoke balanceOf(e, b);
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assert (balanceABefore == balanceAAfter || balanceBBefore == balanceBAfter );
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}
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/**
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Checks that the change to total supply is coherent with the change to user balance due to an operation
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(which is not burn).
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*/
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rule integirtyBalanceOfTotalSupply(address a, method f )
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{
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env e;
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require sinvoke getIncentivesController(e) == 0;
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uint256 balanceABefore = sinvoke balanceOf(e, a);
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uint256 totalSupplyBefore = sinvoke totalSupply(e);
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calldataarg arg;
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sinvoke f(e, arg);
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require (f.selector != burn(address, uint256).selector);
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uint256 balanceAAfter = sinvoke balanceOf(e, a);
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uint256 totalSupplyAfter = sinvoke totalSupply(e);
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assert (balanceAAfter != balanceABefore => (balanceAAfter - balanceABefore == totalSupplyAfter - totalSupplyBefore));
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}
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/**
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Checks that the change to total supply is coherent with the change to user balance due to a burn operation.
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*/
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rule integirtyBalanceOfTotalSupplyOnBurn(address a, uint256 x)
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{
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env e;
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require sinvoke getIncentivesController(e) == 0;
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uint256 balanceABefore = sinvoke balanceOf(e, a);
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uint256 totalSupplyBefore = sinvoke totalSupply(e);
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uint256 averageStableRateBefore = sinvoke getAverageStableRate(e);
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uint256 debtSupplyBefore = sinvoke rayWadMul(e, averageStableRateBefore, totalSupplyBefore);
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uint256 stableRateA = sinvoke getUserStableRate(e, a);
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uint256 repaidDebtA = sinvoke rayWadMul(e, stableRateA, x);
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sinvoke burn(e, a, x);
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uint256 balanceAAfter = sinvoke balanceOf(e, a);
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uint256 totalSupplyAfter = sinvoke totalSupply(e);
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if(totalSupplyBefore > x) {
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/* The amount being burned (x) is smaller than the total supply */
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if(repaidDebtA >= debtSupplyBefore) {
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/*
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The user debt being repaid is at least the debt supply.
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The total supply becomes 0.
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*/
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assert(totalSupplyAfter == 0);
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}
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else {
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assert(balanceAAfter != balanceABefore =>
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(balanceAAfter - balanceABefore == totalSupplyAfter - totalSupplyBefore));
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}
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}
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else {
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/* The amount being burned (x) is at least the total supply.
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The total supply becomes 0.
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*/
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assert (totalSupplyAfter == 0);
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}
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}
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/**
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Mint increases the balanceOf user a as expected.
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*/
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rule integrityMint(address a, uint256 x) {
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env e;
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address delegatedUser;
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require sinvoke getIncentivesController(e) == 0;
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uint256 index;
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uint256 balancebefore = sinvoke balanceOf(e,a);
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sinvoke mint(e, delegatedUser, a, x, index);
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uint256 balanceAfter = sinvoke balanceOf(e,a);
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assert balanceAfter == balancebefore+x;
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}
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/**
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Mint is additive, namely it can performed either all at once or gradually:
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mint(u, x); mint(u, y) ~ mint(u, x+y) at the same timestamp.
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Note: We assume that the stable rate of the user is 0.
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The case where the rate is non-zero takes much more time to prove,
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and therefore it is currently excluded from the CI.
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*/
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rule additiveMint(address a, uint256 x, uint256 y) {
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env e;
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address delegatedUser;
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require sinvoke getIncentivesController(e) == 0;
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require getUserStableRate(e, a) == 0;
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uint256 index;
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storage initialStorage = lastStorage;
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sinvoke mint(e, delegatedUser, a, x, index);
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sinvoke mint(e, delegatedUser, a, y, index);
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uint256 balanceScenario1 = sinvoke balanceOf(e, a);
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uint256 t = x + y;
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sinvoke mint(e, delegatedUser, a, t ,index) at initialStorage;
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uint256 balanceScenario2 = sinvoke balanceOf(e, a);
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assert balanceScenario1 == balanceScenario2, "mint is not additive";
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}
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rule integrityBurn(address a, uint256 x) {
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env e;
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require sinvoke getIncentivesController(e) == 0;
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uint256 index;
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uint256 balancebefore = sinvoke balanceOf(e, a);
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sinvoke burn(e,a,x);
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uint256 balanceAfter = sinvoke balanceOf(e, a);
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assert balanceAfter == balancebefore - x;
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}
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rule additiveBurn(address a, uint256 x, uint256 y) {
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env e;
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require sinvoke getIncentivesController(e) == 0;
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storage initialStorage = lastStorage;
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sinvoke burn(e, a, x);
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sinvoke burn(e, a, y);
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uint256 balanceScenario1 = balanceOf(e, a);
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uint256 t = x + y;
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sinvoke burn(e, a, t) at initialStorage;
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uint256 balanceScenario2 = balanceOf(e, a);
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assert balanceScenario1 == balanceScenario2, "burn is not additive";
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}
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/**
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Mint and burn are inverse operations.
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Therefore, both totalSupply and BalanceOf user are back to the initial state.
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*/
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rule inverseMintBurn(address a, uint256 x) {
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env e;
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address delegatedUser;
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require sinvoke getIncentivesController(e) == 0;
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uint256 index;
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uint256 balancebefore = sinvoke balanceOf(e, a);
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sinvoke mint(e, delegatedUser, a, x, index);
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sinvoke burn(e, a, x);
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uint256 balanceAfter = sinvoke balanceOf(e, a);
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assert balancebefore == balanceAfter, "burn is not the inverse of mint";
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} |