aave-protocol-v2/specs/VariableDebtToken.spec

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RPMSpec
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using LendingPoolHarnessForVariableDebtToken as POOL
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/**
Checks that each possible opertaion changes the balance of at most one user.
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*/
rule balanceOfChange(address a, address b, method f)
{
env e;
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require a != b;
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uint256 balanceABefore = sinvoke balanceOf(e, a);
uint256 balanceBBefore = sinvoke balanceOf(e, b);
calldataarg arg;
sinvoke f(e, arg);
uint256 balanceAAfter = sinvoke balanceOf(e, a);
uint256 balanceBAfter = sinvoke balanceOf(e, b);
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assert (balanceABefore == balanceAAfter || balanceBBefore == balanceBAfter);
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}
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/**
Checks that the change to total supply is coherent with the change to the balance due to an operation
(which is neither a burn nor a mint).
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*/
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rule integirtyBalanceOfTotalSupply(address a, method f)
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{
env e;
uint256 balanceABefore = balanceOf(e, a);
uint256 totalSupplyBefore = totalSupply(e);
calldataarg arg;
sinvoke f(e, arg);
require (f.selector != burn(address, uint256, uint256).selector &&
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f.selector != mint(address, address, uint256, uint256).selector);
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uint256 balanceAAfter = balanceOf(e, a);
uint256 totalSupplyAfter = totalSupply(e);
assert (balanceAAfter != balanceABefore => ( balanceAAfter - balanceABefore == totalSupplyAfter - totalSupplyBefore));
}
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/**
Checks that the change to total supply is coherent with the change to the balance due to a burn operation.
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*/
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rule integirtyBalanceOfTotalSupplyOnBurn(address a)
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{
env e;
uint256 balanceABefore = balanceOf(e, a);
uint256 totalSupplyBefore = totalSupply(e);
uint256 x;
address asset;
uint256 index = POOL.getReserveNormalizedVariableDebt(e, asset);
sinvoke burn(e, a, x, index);
uint256 balanceAAfter = balanceOf(e, a);
uint256 totalSupplyAfter = totalSupply(e);
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assert (balanceAAfter != balanceABefore => (balanceAAfter - balanceABefore == totalSupplyAfter - totalSupplyBefore));
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}
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/**
Checks that the change to total supply is coherent with the change to the balance due to a mint operation.
*/
rule integirtyBalanceOfTotalSupplyOnMint(address u, address delegatedUser)
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{
env e;
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uint256 balanceUBefore = balanceOf(e, u);
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uint256 totalSupplyBefore = totalSupply(e);
uint256 x;
address asset;
uint256 index = POOL.getReserveNormalizedVariableDebt(e, asset);
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sinvoke mint(e, delegatedUser, u, x, index);
uint256 balanceUAfter = balanceOf(e, u);
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uint256 totalSupplyAfter = totalSupply(e);
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assert (balanceUAfter != balanceUBefore => (balanceUAfter - balanceUBefore == totalSupplyAfter - totalSupplyBefore));
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}
/**
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Minting an amount of x tokens for user u increases her balance by x, up to rounding errors.
{ b = balanceOf(u,t) }
mint(delegatedUser, u, x, index)
{ balanceOf(u,t) = b + x }.
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Also, if the minting is done by a user delegatedUser different than u, the balance of delegatedUser
remains unchanged.
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*/
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rule integrityMint(address u, address delegatedUser, uint256 x) {
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env e;
address asset;
uint256 index = POOL.getReserveNormalizedVariableDebt(e,asset);
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uint256 balanceUBefore = balanceOf(e, u);
uint256 balanceDelegatedUBefore = balanceOf(e, delegatedUser);
sinvoke mint(e, delegatedUser, u, x, index);
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uint256 balanceUAfter = balanceOf(e, u);
uint256 balanceDelegatedUAfter = balanceOf(e, delegatedUser);
assert balanceUAfter == balanceUBefore + x && (u != delegatedUser => (balanceDelegatedUAfter == balanceDelegatedUBefore));
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}
/**
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Mint is additive, namely it can performed either all at once or gradually:
mint(delegatedUser, u, x, index); mint(delegatedUser, u, y, index) ~ mint(delegatedUser, u, x+y, index) at the same timestamp.
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*/
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rule additiveMint(address a, address delegatedUser, uint256 x, uint256 y) {
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env e;
address asset;
uint256 index = POOL.getReserveNormalizedVariableDebt(e, asset);
storage initialStorage = lastStorage;
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sinvoke mint(e, delegatedUser, a, x, index);
sinvoke mint(e, delegatedUser, a, y, index);
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uint256 balanceScenario1 = balanceOf(e, a);
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uint256 t = x + y;
sinvoke mint(e, delegatedUser, a, t ,index) at initialStorage;
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uint256 balanceScenario2 = balanceOf(e, a);
assert balanceScenario1 == balanceScenario2, "mint is not additive";
}
/**
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Burning an amount of x tokens for user u decreases her balance by x, up to rounding errors.
{ bu = balanceOf(u) }
burn(u, x)
{ balanceOf(u) = bu - x }.
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*/
rule integrityBurn(address a, uint256 x) {
env e;
address asset;
uint256 index = POOL.getReserveNormalizedVariableDebt(e, asset);
uint256 balancebefore = balanceOf(e, a);
sinvoke burn(e, a, x, index);
uint256 balanceAfter = balanceOf(e, a);
assert balanceAfter == balancebefore - x;
}
/**
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Minting is additive, i.e., it can be performed either all at once or in steps:
burn(u, x); burn(u, y) ~ burn(u, x+y) at the same timestamp.
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*/
rule additiveBurn(address a, uint256 x, uint256 y) {
env e;
address asset;
uint256 index = POOL.getReserveNormalizedVariableDebt(e, asset);
storage initialStorage = lastStorage;
sinvoke burn(e, a, x, index);
sinvoke burn(e, a, y, index);
uint256 balanceScenario1 = balanceOf(e, a);
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uint256 t = x + y;
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sinvoke burn(e, a, t ,index) at initialStorage;
uint256 balanceScenario2 = balanceOf(e, a);
assert balanceScenario1 == balanceScenario2, "burn is not additive";
}
/**
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Minting and burning are inverse operations:
{ bu = balanceOf(u) }
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mint(u,x); burn(u, u, x)
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{ balanceOf(u) = bu }.
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*/
rule inverseMintBurn(address a, uint256 x) {
env e;
address asset;
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address delegatedUser;
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uint256 index = POOL.getReserveNormalizedVariableDebt(e, asset);
uint256 balancebefore = balanceOf(e, a);
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sinvoke mint(e, delegatedUser, a, x, index);
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sinvoke burn(e, a, x, index);
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uint256 balanceAfter = balanceOf(e, a);
assert balancebefore == balanceAfter, "burn is not the inverse of mint";
}