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solidity/test/libsolidity/SolidityEndToEndTest.cpp
chriseth 3282c72a21 Update tests.
2019-04-03 11:32:03 +02:00

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/*
This file is part of solidity.
solidity 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.
solidity 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 solidity. If not, see <http://www.gnu.org/licenses/>.
*/
/**
* @author Christian <c@ethdev.com>
* @author Gav Wood <g@ethdev.com>
* @date 2014
* Unit tests for the solidity expression compiler, testing the behaviour of the code.
*/
#include <test/libsolidity/SolidityExecutionFramework.h>
#include <test/Options.h>
#include <liblangutil/Exceptions.h>
#include <liblangutil/EVMVersion.h>
#include <libevmasm/Assembly.h>
#include <libdevcore/Keccak256.h>
#include <boost/range/adaptor/transformed.hpp>
#include <boost/test/unit_test.hpp>
#include <functional>
#include <string>
#include <tuple>
using namespace std;
using namespace std::placeholders;
using namespace dev::test;
namespace dev
{
namespace solidity
{
namespace test
{
BOOST_FIXTURE_TEST_SUITE(SolidityEndToEndTest, SolidityExecutionFramework)
int constexpr roundTo32(int _num)
{
return (_num + 31) / 32 * 32;
}
BOOST_AUTO_TEST_CASE(transaction_status)
{
char const* sourceCode = R"(
contract test {
function f() public { }
function g() public { revert(); }
function h() public { assert(false); }
}
)";
compileAndRun(sourceCode);
callContractFunction("f()");
BOOST_CHECK(m_transactionSuccessful);
callContractFunction("g()");
BOOST_CHECK(!m_transactionSuccessful);
callContractFunction("h()");
BOOST_CHECK(!m_transactionSuccessful);
}
BOOST_AUTO_TEST_CASE(smoke_test)
{
char const* sourceCode = R"(
contract test {
function f(uint a) public returns(uint d) { return a * 7; }
}
)";
compileAndRun(sourceCode);
testContractAgainstCppOnRange("f(uint256)", [](u256 const& a) -> u256 { return a * 7; }, 0, 100);
}
BOOST_AUTO_TEST_CASE(empty_contract)
{
char const* sourceCode = R"(
contract test { }
)";
compileAndRun(sourceCode);
BOOST_CHECK(callContractFunction("i_am_not_there()", bytes()).empty());
}
BOOST_AUTO_TEST_CASE(exp_operator)
{
char const* sourceCode = R"(
contract test {
function f(uint a) public returns(uint d) { return 2 ** a; }
}
)";
compileAndRun(sourceCode);
testContractAgainstCppOnRange("f(uint256)", [](u256 const& a) -> u256 { return u256(1 << a.convert_to<int>()); }, 0, 16);
}
BOOST_AUTO_TEST_CASE(exp_operator_const)
{
char const* sourceCode = R"(
contract test {
function f() public returns(uint d) { return 2 ** 3; }
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("f()", bytes()), toBigEndian(u256(8)));
}
BOOST_AUTO_TEST_CASE(exp_operator_const_signed)
{
char const* sourceCode = R"(
contract test {
function f() public returns(int d) { return (-2) ** 3; }
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("f()", bytes()), toBigEndian(u256(-8)));
}
BOOST_AUTO_TEST_CASE(exp_zero)
{
char const* sourceCode = R"(
contract test {
function f(uint a) public returns(uint d) { return a ** 0; }
}
)";
compileAndRun(sourceCode);
testContractAgainstCppOnRange("f(uint256)", [](u256 const&) -> u256 { return u256(1); }, 0, 16);
}
BOOST_AUTO_TEST_CASE(exp_zero_literal)
{
char const* sourceCode = R"(
contract test {
function f() public returns(uint d) { return 0 ** 0; }
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("f()", bytes()), toBigEndian(u256(1)));
}
BOOST_AUTO_TEST_CASE(conditional_expression_true_literal)
{
char const* sourceCode = R"(
contract test {
function f() public returns(uint d) {
return true ? 5 : 10;
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("f()", bytes()), toBigEndian(u256(5)));
}
BOOST_AUTO_TEST_CASE(conditional_expression_false_literal)
{
char const* sourceCode = R"(
contract test {
function f() public returns(uint d) {
return false ? 5 : 10;
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("f()", bytes()), toBigEndian(u256(10)));
}
BOOST_AUTO_TEST_CASE(conditional_expression_multiple)
{
char const* sourceCode = R"(
contract test {
function f(uint x) public returns(uint d) {
return x > 100 ?
x > 1000 ? 1000 : 100
:
x > 50 ? 50 : 10;
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("f(uint256)", u256(1001)), toBigEndian(u256(1000)));
ABI_CHECK(callContractFunction("f(uint256)", u256(500)), toBigEndian(u256(100)));
ABI_CHECK(callContractFunction("f(uint256)", u256(80)), toBigEndian(u256(50)));
ABI_CHECK(callContractFunction("f(uint256)", u256(40)), toBigEndian(u256(10)));
}
BOOST_AUTO_TEST_CASE(conditional_expression_with_return_values)
{
char const* sourceCode = R"(
contract test {
function f(bool cond, uint v) public returns (uint a, uint b) {
cond ? a = v : b = v;
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("f(bool,uint256)", true, u256(20)), encodeArgs(u256(20), u256(0)));
ABI_CHECK(callContractFunction("f(bool,uint256)", false, u256(20)), encodeArgs(u256(0), u256(20)));
}
BOOST_AUTO_TEST_CASE(conditional_expression_storage_memory_1)
{
char const* sourceCode = R"(
contract test {
bytes2[2] data1;
function f(bool cond) public returns (uint) {
bytes2[2] memory x;
x[0] = "aa";
bytes2[2] memory y;
y[0] = "bb";
data1 = cond ? x : y;
uint ret = 0;
if (data1[0] == "aa")
{
ret = 1;
}
if (data1[0] == "bb")
{
ret = 2;
}
return ret;
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("f(bool)", true), encodeArgs(u256(1)));
ABI_CHECK(callContractFunction("f(bool)", false), encodeArgs(u256(2)));
}
BOOST_AUTO_TEST_CASE(conditional_expression_storage_memory_2)
{
char const* sourceCode = R"(
contract test {
bytes2[2] data1;
function f(bool cond) public returns (uint) {
data1[0] = "cc";
bytes2[2] memory x;
bytes2[2] memory y;
y[0] = "bb";
x = cond ? y : data1;
uint ret = 0;
if (x[0] == "bb")
{
ret = 1;
}
if (x[0] == "cc")
{
ret = 2;
}
return ret;
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("f(bool)", true), encodeArgs(u256(1)));
ABI_CHECK(callContractFunction("f(bool)", false), encodeArgs(u256(2)));
}
BOOST_AUTO_TEST_CASE(conditional_expression_different_types)
{
char const* sourceCode = R"(
contract test {
function f(bool cond) public returns (uint) {
uint8 x = 0xcd;
uint16 y = 0xabab;
return cond ? x : y;
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("f(bool)", true), encodeArgs(u256(0xcd)));
ABI_CHECK(callContractFunction("f(bool)", false), encodeArgs(u256(0xabab)));
}
/* let's add this back when I figure out the correct type conversion.
BOOST_AUTO_TEST_CASE(conditional_expression_string_literal)
{
char const* sourceCode = R"(
contract test {
function f(bool cond) public returns (bytes32) {
return cond ? "true" : "false";
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("f(bool)", true), encodeArgs(string("true", 4)));
ABI_CHECK(callContractFunction("f(bool)", false), encodeArgs(string("false", 5)));
}
*/
BOOST_AUTO_TEST_CASE(conditional_expression_tuples)
{
char const* sourceCode = R"(
contract test {
function f(bool cond) public returns (uint, uint) {
return cond ? (1, 2) : (3, 4);
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("f(bool)", true), encodeArgs(u256(1), u256(2)));
ABI_CHECK(callContractFunction("f(bool)", false), encodeArgs(u256(3), u256(4)));
}
BOOST_AUTO_TEST_CASE(conditional_expression_functions)
{
char const* sourceCode = R"(
contract test {
function x() public returns (uint) { return 1; }
function y() public returns (uint) { return 2; }
function f(bool cond) public returns (uint) {
function () returns (uint) z = cond ? x : y;
return z();
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("f(bool)", true), encodeArgs(u256(1)));
ABI_CHECK(callContractFunction("f(bool)", false), encodeArgs(u256(2)));
}
BOOST_AUTO_TEST_CASE(c99_scoping_activation)
{
char const* sourceCode = R"(
contract test {
function f() pure public returns (uint) {
uint x = 7;
{
x = 3; // This should still assign to the outer variable
uint x;
x = 4; // This should assign to the new one
}
return x;
}
function g() pure public returns (uint x) {
x = 7;
{
x = 3;
uint x;
return x; // This returns the new variable, i.e. 0
}
}
function h() pure public returns (uint x, uint a, uint b) {
x = 7;
{
x = 3;
a = x; // This should read from the outer
uint x = 4;
b = x;
}
}
function i() pure public returns (uint x, uint a) {
x = 7;
{
x = 3;
uint x = x; // This should read from the outer and assign to the inner
a = x;
}
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("f()"), encodeArgs(3));
ABI_CHECK(callContractFunction("g()"), encodeArgs(0));
ABI_CHECK(callContractFunction("h()"), encodeArgs(3, 3, 4));
ABI_CHECK(callContractFunction("i()"), encodeArgs(3, 3));
}
BOOST_AUTO_TEST_CASE(recursive_calls)
{
char const* sourceCode = R"(
contract test {
function f(uint n) public returns(uint nfac) {
if (n <= 1) return 1;
else return n * f(n - 1);
}
}
)";
compileAndRun(sourceCode);
function<u256(u256)> recursive_calls_cpp = [&recursive_calls_cpp](u256 const& n) -> u256
{
if (n <= 1)
return 1;
else
return n * recursive_calls_cpp(n - 1);
};
testContractAgainstCppOnRange("f(uint256)", recursive_calls_cpp, 0, 5);
}
BOOST_AUTO_TEST_CASE(multiple_functions)
{
char const* sourceCode = R"(
contract test {
function a() public returns(uint n) { return 0; }
function b() public returns(uint n) { return 1; }
function c() public returns(uint n) { return 2; }
function f() public returns(uint n) { return 3; }
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("a()", bytes()), toBigEndian(u256(0)));
ABI_CHECK(callContractFunction("b()", bytes()), toBigEndian(u256(1)));
ABI_CHECK(callContractFunction("c()", bytes()), toBigEndian(u256(2)));
ABI_CHECK(callContractFunction("f()", bytes()), toBigEndian(u256(3)));
ABI_CHECK(callContractFunction("i_am_not_there()", bytes()), bytes());
}
BOOST_AUTO_TEST_CASE(named_args)
{
char const* sourceCode = R"(
contract test {
function a(uint a, uint b, uint c) public returns (uint r) { r = a * 100 + b * 10 + c * 1; }
function b() public returns (uint r) { r = a({a: 1, b: 2, c: 3}); }
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("b()", bytes()), toBigEndian(u256(123)));
}
BOOST_AUTO_TEST_CASE(disorder_named_args)
{
char const* sourceCode = R"(
contract test {
function a(uint a, uint b, uint c) public returns (uint r) { r = a * 100 + b * 10 + c * 1; }
function b() public returns (uint r) { r = a({c: 3, a: 1, b: 2}); }
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("b()", bytes()), toBigEndian(u256(123)));
}
BOOST_AUTO_TEST_CASE(while_loop)
{
char const* sourceCode = R"(
contract test {
function f(uint n) public returns(uint nfac) {
nfac = 1;
uint i = 2;
while (i <= n) nfac *= i++;
}
}
)";
compileAndRun(sourceCode);
auto while_loop_cpp = [](u256 const& n) -> u256
{
u256 nfac = 1;
u256 i = 2;
while (i <= n)
nfac *= i++;
return nfac;
};
testContractAgainstCppOnRange("f(uint256)", while_loop_cpp, 0, 5);
}
BOOST_AUTO_TEST_CASE(do_while_loop)
{
char const* sourceCode = R"(
contract test {
function f(uint n) public returns(uint nfac) {
nfac = 1;
uint i = 2;
do { nfac *= i++; } while (i <= n);
}
}
)";
compileAndRun(sourceCode);
auto do_while_loop_cpp = [](u256 const& n) -> u256
{
u256 nfac = 1;
u256 i = 2;
do
{
nfac *= i++;
}
while (i <= n);
return nfac;
};
testContractAgainstCppOnRange("f(uint256)", do_while_loop_cpp, 0, 5);
}
BOOST_AUTO_TEST_CASE(do_while_loop_continue)
{
char const* sourceCode = R"(
contract test {
function f() public pure returns(uint r) {
uint i = 0;
do
{
if (i > 0) return 0;
i++;
continue;
} while (false);
return 42;
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("f()"), encodeArgs(42));
}
BOOST_AUTO_TEST_CASE(array_multiple_local_vars)
{
char const* sourceCode = R"(
contract test {
function f(uint256[] calldata seq) external pure returns (uint256) {
uint i = 0;
uint sum = 0;
while (i < seq.length)
{
uint idx = i;
if (idx >= 10) break;
uint x = seq[idx];
if (x >= 1000) {
uint n = i + 1;
i = n;
continue;
}
else {
uint y = sum + x;
sum = y;
}
if (sum >= 500) return sum;
i++;
}
return sum;
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("f(uint256[])", 32, 3, u256(1000), u256(1), u256(2)), encodeArgs(3));
ABI_CHECK(callContractFunction("f(uint256[])", 32, 3, u256(100), u256(500), u256(300)), encodeArgs(600));
ABI_CHECK(callContractFunction(
"f(uint256[])", 32, 11,
u256(1), u256(2), u256(3), u256(4), u256(5), u256(6), u256(7), u256(8), u256(9), u256(10), u256(111)
), encodeArgs(55));
}
BOOST_AUTO_TEST_CASE(do_while_loop_multiple_local_vars)
{
char const* sourceCode = R"(
contract test {
function f(uint x) public pure returns(uint r) {
uint i = 0;
do
{
uint z = x * 2;
if (z < 4) break;
else {
uint k = z + 1;
if (k < 8) {
x++;
continue;
}
}
if (z > 12) return 0;
x++;
i++;
} while (true);
return 42;
}
}
)";
compileAndRun(sourceCode);
auto do_while = [](u256 n) -> u256
{
u256 i = 0;
do
{
u256 z = n * 2;
if (z < 4) break;
else {
u256 k = z + 1;
if (k < 8) {
n++;
continue;
}
}
if (z > 12) return 0;
n++;
i++;
} while (true);
return 42;
};
testContractAgainstCppOnRange("f(uint256)", do_while, 0, 12);
}
BOOST_AUTO_TEST_CASE(nested_loops)
{
// tests that break and continue statements in nested loops jump to the correct place
char const* sourceCode = R"(
contract test {
function f(uint x) public returns(uint y) {
while (x > 1) {
if (x == 10) break;
while (x > 5) {
if (x == 8) break;
x--;
if (x == 6) continue;
return x;
}
x--;
if (x == 3) continue;
break;
}
return x;
}
}
)";
compileAndRun(sourceCode);
auto nested_loops_cpp = [](u256 n) -> u256
{
while (n > 1)
{
if (n == 10)
break;
while (n > 5)
{
if (n == 8)
break;
n--;
if (n == 6)
continue;
return n;
}
n--;
if (n == 3)
continue;
break;
}
return n;
};
testContractAgainstCppOnRange("f(uint256)", nested_loops_cpp, 0, 12);
}
BOOST_AUTO_TEST_CASE(nested_loops_multiple_local_vars)
{
// tests that break and continue statements in nested loops jump to the correct place
// and free local variables properly
char const* sourceCode = R"(
contract test {
function f(uint x) public returns(uint y) {
while (x > 0) {
uint z = x + 10;
uint k = z + 1;
if (k > 20) {
break;
uint p = 100;
k += p;
}
if (k > 15) {
x--;
continue;
uint t = 1000;
x += t;
}
while (k > 10) {
uint m = k - 1;
if (m == 10) return x;
return k;
uint h = 10000;
z += h;
}
x--;
break;
}
return x;
}
}
)";
compileAndRun(sourceCode);
auto nested_loops_cpp = [](u256 n) -> u256
{
while (n > 0)
{
u256 z = n + 10;
u256 k = z + 1;
if (k > 20) break;
if (k > 15) {
n--;
continue;
}
while (k > 10)
{
u256 m = k - 1;
if (m == 10) return n;
return k;
}
n--;
break;
}
return n;
};
testContractAgainstCppOnRange("f(uint256)", nested_loops_cpp, 0, 12);
}
BOOST_AUTO_TEST_CASE(for_loop_multiple_local_vars)
{
char const* sourceCode = R"(
contract test {
function f(uint x) public pure returns(uint r) {
for (uint i = 0; i < 12; i++)
{
uint z = x + 1;
if (z < 4) break;
else {
uint k = z * 2;
if (i + k < 10) {
x++;
continue;
}
}
if (z > 8) return 0;
x++;
}
return 42;
}
}
)";
compileAndRun(sourceCode);
auto for_loop = [](u256 n) -> u256
{
for (u256 i = 0; i < 12; i++)
{
u256 z = n + 1;
if (z < 4) break;
else {
u256 k = z * 2;
if (i + k < 10) {
n++;
continue;
}
}
if (z > 8) return 0;
n++;
}
return 42;
};
testContractAgainstCppOnRange("f(uint256)", for_loop, 0, 12);
}
BOOST_AUTO_TEST_CASE(nested_for_loop_multiple_local_vars)
{
char const* sourceCode = R"(
contract test {
function f(uint x) public pure returns(uint r) {
for (uint i = 0; i < 5; i++)
{
uint z = x + 1;
if (z < 3) {
break;
uint p = z + 2;
}
for (uint j = 0; j < 5; j++)
{
uint k = z * 2;
if (j + k < 8) {
x++;
continue;
uint t = z * 3;
}
x++;
if (x > 20) {
return 84;
uint h = x + 42;
}
}
if (x > 30) {
return 42;
uint b = 0xcafe;
}
}
return 42;
}
}
)";
compileAndRun(sourceCode);
auto for_loop = [](u256 n) -> u256
{
for (u256 i = 0; i < 5; i++)
{
u256 z = n + 1;
if (z < 3) break;
for (u256 j = 0; j < 5; j++)
{
u256 k = z * 2;
if (j + k < 8) {
n++;
continue;
}
n++;
if (n > 20) return 84;
}
if (n > 30) return 42;
}
return 42;
};
testContractAgainstCppOnRange("f(uint256)", for_loop, 0, 12);
}
BOOST_AUTO_TEST_CASE(for_loop)
{
char const* sourceCode = R"(
contract test {
function f(uint n) public returns(uint nfac) {
nfac = 1;
uint i;
for (i = 2; i <= n; i++)
nfac *= i;
}
}
)";
compileAndRun(sourceCode);
auto for_loop_cpp = [](u256 const& n) -> u256
{
u256 nfac = 1;
for (auto i = 2; i <= n; i++)
nfac *= i;
return nfac;
};
testContractAgainstCppOnRange("f(uint256)", for_loop_cpp, 0, 5);
}
BOOST_AUTO_TEST_CASE(for_loop_empty)
{
char const* sourceCode = R"(
contract test {
function f() public returns(uint ret) {
ret = 1;
for (;;) {
ret += 1;
if (ret >= 10) break;
}
}
}
)";
compileAndRun(sourceCode);
auto for_loop_empty_cpp = []() -> u256
{
u256 ret = 1;
for (;;)
{
ret += 1;
if (ret >= 10) break;
}
return ret;
};
testContractAgainstCpp("f()", for_loop_empty_cpp);
}
BOOST_AUTO_TEST_CASE(for_loop_simple_init_expr)
{
char const* sourceCode = R"(
contract test {
function f(uint n) public returns(uint nfac) {
nfac = 1;
uint256 i;
for (i = 2; i <= n; i++)
nfac *= i;
}
}
)";
compileAndRun(sourceCode);
auto for_loop_simple_init_expr_cpp = [](u256 const& n) -> u256
{
u256 nfac = 1;
u256 i;
for (i = 2; i <= n; i++)
nfac *= i;
return nfac;
};
testContractAgainstCppOnRange("f(uint256)", for_loop_simple_init_expr_cpp, 0, 5);
}
BOOST_AUTO_TEST_CASE(for_loop_break_continue)
{
char const* sourceCode = R"(
contract test {
function f(uint n) public returns (uint r)
{
uint i = 1;
uint k = 0;
for (i *= 5; k < n; i *= 7)
{
k++;
i += 4;
if (n % 3 == 0)
break;
i += 9;
if (n % 2 == 0)
continue;
i += 19;
}
return i;
}
}
)";
compileAndRun(sourceCode);
auto breakContinue = [](u256 const& n) -> u256
{
u256 i = 1;
u256 k = 0;
for (i *= 5; k < n; i *= 7)
{
k++;
i += 4;
if (n % 3 == 0)
break;
i += 9;
if (n % 2 == 0)
continue;
i += 19;
}
return i;
};
testContractAgainstCppOnRange("f(uint256)", breakContinue, 0, 10);
}
BOOST_AUTO_TEST_CASE(calling_other_functions)
{
char const* sourceCode = R"(
contract collatz {
function run(uint x) public returns(uint y) {
while ((y = x) > 1) {
if (x % 2 == 0) x = evenStep(x);
else x = oddStep(x);
}
}
function evenStep(uint x) public returns(uint y) {
return x / 2;
}
function oddStep(uint x) public returns(uint y) {
return 3 * x + 1;
}
}
)";
compileAndRun(sourceCode);
auto evenStep_cpp = [](u256 const& n) -> u256
{
return n / 2;
};
auto oddStep_cpp = [](u256 const& n) -> u256
{
return 3 * n + 1;
};
auto collatz_cpp = [&evenStep_cpp, &oddStep_cpp](u256 n) -> u256
{
u256 y;
while ((y = n) > 1)
{
if (n % 2 == 0)
n = evenStep_cpp(n);
else
n = oddStep_cpp(n);
}
return y;
};
testContractAgainstCpp("run(uint256)", collatz_cpp, u256(0));
testContractAgainstCpp("run(uint256)", collatz_cpp, u256(1));
testContractAgainstCpp("run(uint256)", collatz_cpp, u256(2));
testContractAgainstCpp("run(uint256)", collatz_cpp, u256(8));
testContractAgainstCpp("run(uint256)", collatz_cpp, u256(127));
}
BOOST_AUTO_TEST_CASE(many_local_variables)
{
char const* sourceCode = R"(
contract test {
function run(uint x1, uint x2, uint x3) public returns(uint y) {
uint8 a = 0x1; uint8 b = 0x10; uint16 c = 0x100;
y = a + b + c + x1 + x2 + x3;
y += b + x2;
}
}
)";
compileAndRun(sourceCode);
auto f = [](u256 const& x1, u256 const& x2, u256 const& x3) -> u256
{
u256 a = 0x1;
u256 b = 0x10;
u256 c = 0x100;
u256 y = a + b + c + x1 + x2 + x3;
return y + b + x2;
};
testContractAgainstCpp("run(uint256,uint256,uint256)", f, u256(0x1000), u256(0x10000), u256(0x100000));
}
BOOST_AUTO_TEST_CASE(packing_unpacking_types)
{
char const* sourceCode = R"(
contract test {
function run(bool a, uint32 b, uint64 c) public returns(uint256 y) {
if (a) y = 1;
y = y * 0x100000000 | ~b;
y = y * 0x10000000000000000 | ~c;
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(
callContractFunction("run(bool,uint32,uint64)", true, fromHex("0f0f0f0f"), fromHex("f0f0f0f0f0f0f0f0")),
fromHex("00000000000000000000000000000000000000""01""f0f0f0f0""0f0f0f0f0f0f0f0f")
);
}
BOOST_AUTO_TEST_CASE(packing_signed_types)
{
char const* sourceCode = R"(
contract test {
function run() public returns(int8 y) {
uint8 x = 0xfa;
return int8(x);
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(
callContractFunction("run()"),
fromHex("fffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffa")
);
}
BOOST_AUTO_TEST_CASE(multiple_return_values)
{
char const* sourceCode = R"(
contract test {
function run(bool x1, uint x2) public returns(uint y1, bool y2, uint y3) {
y1 = x2; y2 = x1;
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("run(bool,uint256)", true, 0xcd), encodeArgs(0xcd, true, 0));
}
BOOST_AUTO_TEST_CASE(short_circuiting)
{
char const* sourceCode = R"(
contract test {
function run(uint x) public returns(uint y) {
x == 0 || ((x = 8) > 0);
return x;
}
}
)";
compileAndRun(sourceCode);
auto short_circuiting_cpp = [](u256 n) -> u256
{
(void)(n == 0 || (n = 8) > 0);
return n;
};
testContractAgainstCppOnRange("run(uint256)", short_circuiting_cpp, 0, 2);
}
BOOST_AUTO_TEST_CASE(high_bits_cleaning)
{
char const* sourceCode = R"(
contract test {
function run() public returns(uint256 y) {
uint32 t = uint32(0xffffffff);
uint32 x = t + 10;
if (x >= 0xffffffff) return 0;
return x;
}
}
)";
compileAndRun(sourceCode);
auto high_bits_cleaning_cpp = []() -> u256
{
uint32_t t = uint32_t(0xffffffff);
uint32_t x = t + 10;
if (x >= 0xffffffff)
return 0;
return x;
};
testContractAgainstCpp("run()", high_bits_cleaning_cpp);
}
BOOST_AUTO_TEST_CASE(sign_extension)
{
char const* sourceCode = R"(
contract test {
function run() public returns(uint256 y) {
int64 x = -int32(0xff);
if (x >= 0xff) return 0;
return -uint256(x);
}
}
)";
compileAndRun(sourceCode);
auto sign_extension_cpp = []() -> u256
{
int64_t x = -int32_t(0xff);
if (x >= 0xff)
return 0;
return u256(x) * -1;
};
testContractAgainstCpp("run()", sign_extension_cpp);
}
BOOST_AUTO_TEST_CASE(small_unsigned_types)
{
char const* sourceCode = R"(
contract test {
function run() public returns(uint256 y) {
uint32 t = uint32(0xffffff);
uint32 x = t * 0xffffff;
return x / 0x100;
}
}
)";
compileAndRun(sourceCode);
auto small_unsigned_types_cpp = []() -> u256
{
uint32_t t = uint32_t(0xffffff);
uint32_t x = t * 0xffffff;
return x / 0x100;
};
testContractAgainstCpp("run()", small_unsigned_types_cpp);
}
BOOST_AUTO_TEST_CASE(small_signed_types)
{
char const* sourceCode = R"(
contract test {
function run() public returns(int256 y) {
return -int32(10) * -int64(20);
}
}
)";
compileAndRun(sourceCode);
auto small_signed_types_cpp = []() -> u256
{
return -int32_t(10) * -int64_t(20);
};
testContractAgainstCpp("run()", small_signed_types_cpp);
}
BOOST_AUTO_TEST_CASE(strings)
{
char const* sourceCode = R"(
contract test {
function fixedBytes() public returns(bytes32 ret) {
return "abc\x00\xff__";
}
function pipeThrough(bytes2 small, bool one) public returns(bytes16 large, bool oneRet) {
oneRet = one;
large = small;
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("fixedBytes()"), encodeArgs(string("abc\0\xff__", 7)));
ABI_CHECK(callContractFunction("pipeThrough(bytes2,bool)", string("\0\x02", 2), true), encodeArgs(string("\0\x2", 2), true));
}
BOOST_AUTO_TEST_CASE(inc_dec_operators)
{
char const* sourceCode = R"(
contract test {
uint8 x;
uint v;
function f() public returns (uint r) {
uint a = 6;
r = a;
r += (a++) * 0x10;
r += (++a) * 0x100;
v = 3;
r += (v++) * 0x1000;
r += (++v) * 0x10000;
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("f()"), encodeArgs(0x53866));
}
BOOST_AUTO_TEST_CASE(bytes_comparison)
{
char const* sourceCode = R"(
contract test {
function f() public returns (bool) {
bytes2 a = "a";
bytes2 x = "aa";
bytes2 b = "b";
return a < x && x < b;
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("f()"), encodeArgs(true));
}
BOOST_AUTO_TEST_CASE(state_smoke_test)
{
char const* sourceCode = R"(
contract test {
uint256 value1;
uint256 value2;
function get(uint8 which) public returns (uint256 value) {
if (which == 0) return value1;
else return value2;
}
function set(uint8 which, uint256 value) public {
if (which == 0) value1 = value;
else value2 = value;
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("get(uint8)", uint8_t(0x00)), encodeArgs(0));
ABI_CHECK(callContractFunction("get(uint8)", uint8_t(0x01)), encodeArgs(0));
ABI_CHECK(callContractFunction("set(uint8,uint256)", uint8_t(0x00), 0x1234), encodeArgs());
ABI_CHECK(callContractFunction("set(uint8,uint256)", uint8_t(0x01), 0x8765), encodeArgs());
ABI_CHECK(callContractFunction("get(uint8)", uint8_t( 0x00)), encodeArgs(0x1234));
ABI_CHECK(callContractFunction("get(uint8)", uint8_t(0x01)), encodeArgs(0x8765));
ABI_CHECK(callContractFunction("set(uint8,uint256)", uint8_t(0x00), 0x3), encodeArgs());
ABI_CHECK(callContractFunction("get(uint8)", uint8_t(0x00)), encodeArgs(0x3));
}
BOOST_AUTO_TEST_CASE(compound_assign)
{
char const* sourceCode = R"(
contract test {
uint value1;
uint value2;
function f(uint x, uint y) public returns (uint w) {
uint value3 = y;
value1 += x;
value3 *= x;
value2 *= value3 + value1;
return value2 += 7;
}
}
)";
compileAndRun(sourceCode);
u256 value1;
u256 value2;
auto f = [&](u256 const& _x, u256 const& _y) -> u256
{
u256 value3 = _y;
value1 += _x;
value3 *= _x;
value2 *= value3 + value1;
return value2 += 7;
};
testContractAgainstCpp("f(uint256,uint256)", f, u256(0), u256(6));
testContractAgainstCpp("f(uint256,uint256)", f, u256(1), u256(3));
testContractAgainstCpp("f(uint256,uint256)", f, u256(2), u256(25));
testContractAgainstCpp("f(uint256,uint256)", f, u256(3), u256(69));
testContractAgainstCpp("f(uint256,uint256)", f, u256(4), u256(84));
testContractAgainstCpp("f(uint256,uint256)", f, u256(5), u256(2));
testContractAgainstCpp("f(uint256,uint256)", f, u256(6), u256(51));
testContractAgainstCpp("f(uint256,uint256)", f, u256(7), u256(48));
}
BOOST_AUTO_TEST_CASE(simple_mapping)
{
char const* sourceCode = R"(
contract test {
mapping(uint8 => uint8) table;
function get(uint8 k) public returns (uint8 v) {
return table[k];
}
function set(uint8 k, uint8 v) public {
table[k] = v;
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("get(uint8)", uint8_t(0)), encodeArgs(uint8_t(0x00)));
ABI_CHECK(callContractFunction("get(uint8)", uint8_t(0x01)), encodeArgs(uint8_t(0x00)));
ABI_CHECK(callContractFunction("get(uint8)", uint8_t(0xa7)), encodeArgs(uint8_t(0x00)));
callContractFunction("set(uint8,uint8)", uint8_t(0x01), uint8_t(0xa1));
ABI_CHECK(callContractFunction("get(uint8)", uint8_t(0x00)), encodeArgs(uint8_t(0x00)));
ABI_CHECK(callContractFunction("get(uint8)", uint8_t(0x01)), encodeArgs(uint8_t(0xa1)));
ABI_CHECK(callContractFunction("get(uint8)", uint8_t(0xa7)), encodeArgs(uint8_t(0x00)));
callContractFunction("set(uint8,uint8)", uint8_t(0x00), uint8_t(0xef));
ABI_CHECK(callContractFunction("get(uint8)", uint8_t(0x00)), encodeArgs(uint8_t(0xef)));
ABI_CHECK(callContractFunction("get(uint8)", uint8_t(0x01)), encodeArgs(uint8_t(0xa1)));
ABI_CHECK(callContractFunction("get(uint8)", uint8_t(0xa7)), encodeArgs(uint8_t(0x00)));
callContractFunction("set(uint8,uint8)", uint8_t(0x01), uint8_t(0x05));
ABI_CHECK(callContractFunction("get(uint8)", uint8_t(0x00)), encodeArgs(uint8_t(0xef)));
ABI_CHECK(callContractFunction("get(uint8)", uint8_t(0x01)), encodeArgs(uint8_t(0x05)));
ABI_CHECK(callContractFunction("get(uint8)", uint8_t(0xa7)), encodeArgs(uint8_t(0x00)));
}
BOOST_AUTO_TEST_CASE(mapping_state)
{
char const* sourceCode = R"(
contract Ballot {
mapping(address => bool) canVote;
mapping(address => uint) voteCount;
mapping(address => bool) voted;
function getVoteCount(address addr) public returns (uint retVoteCount) {
return voteCount[addr];
}
function grantVoteRight(address addr) public {
canVote[addr] = true;
}
function vote(address voter, address vote) public returns (bool success) {
if (!canVote[voter] || voted[voter]) return false;
voted[voter] = true;
voteCount[vote] = voteCount[vote] + 1;
return true;
}
}
)";
compileAndRun(sourceCode);
class Ballot
{
public:
u256 getVoteCount(u160 _address) { return m_voteCount[_address]; }
void grantVoteRight(u160 _address) { m_canVote[_address] = true; }
bool vote(u160 _voter, u160 _vote)
{
if (!m_canVote[_voter] || m_voted[_voter]) return false;
m_voted[_voter] = true;
m_voteCount[_vote]++;
return true;
}
private:
map<u160, bool> m_canVote;
map<u160, u256> m_voteCount;
map<u160, bool> m_voted;
} ballot;
auto getVoteCount = bind(&Ballot::getVoteCount, &ballot, _1);
auto grantVoteRight = bind(&Ballot::grantVoteRight, &ballot, _1);
auto vote = bind(&Ballot::vote, &ballot, _1, _2);
testContractAgainstCpp("getVoteCount(address)", getVoteCount, u160(0));
testContractAgainstCpp("getVoteCount(address)", getVoteCount, u160(1));
testContractAgainstCpp("getVoteCount(address)", getVoteCount, u160(2));
// voting without vote right should be rejected
testContractAgainstCpp("vote(address,address)", vote, u160(0), u160(2));
testContractAgainstCpp("getVoteCount(address)", getVoteCount, u160(0));
testContractAgainstCpp("getVoteCount(address)", getVoteCount, u160(1));
testContractAgainstCpp("getVoteCount(address)", getVoteCount, u160(2));
// grant vote rights
testContractAgainstCpp("grantVoteRight(address)", grantVoteRight, u160(0));
testContractAgainstCpp("grantVoteRight(address)", grantVoteRight, u160(1));
// vote, should increase 2's vote count
testContractAgainstCpp("vote(address,address)", vote, u160(0), u160(2));
testContractAgainstCpp("getVoteCount(address)", getVoteCount, u160(0));
testContractAgainstCpp("getVoteCount(address)", getVoteCount, u160(1));
testContractAgainstCpp("getVoteCount(address)", getVoteCount, u160(2));
// vote again, should be rejected
testContractAgainstCpp("vote(address,address)", vote, u160(0), u160(1));
testContractAgainstCpp("getVoteCount(address)", getVoteCount, u160(0));
testContractAgainstCpp("getVoteCount(address)", getVoteCount, u160(1));
testContractAgainstCpp("getVoteCount(address)", getVoteCount, u160(2));
// vote without right to vote
testContractAgainstCpp("vote(address,address)", vote, u160(2), u160(1));
testContractAgainstCpp("getVoteCount(address)", getVoteCount, u160(0));
testContractAgainstCpp("getVoteCount(address)", getVoteCount, u160(1));
testContractAgainstCpp("getVoteCount(address)", getVoteCount, u160(2));
// grant vote right and now vote again
testContractAgainstCpp("grantVoteRight(address)", grantVoteRight, u160(2));
testContractAgainstCpp("vote(address,address)", vote, u160(2), u160(1));
testContractAgainstCpp("getVoteCount(address)", getVoteCount, u160(0));
testContractAgainstCpp("getVoteCount(address)", getVoteCount, u160(1));
testContractAgainstCpp("getVoteCount(address)", getVoteCount, u160(2));
}
BOOST_AUTO_TEST_CASE(mapping_state_inc_dec)
{
char const* sourceCode = R"(
contract test {
uint value;
mapping(uint => uint) table;
function f(uint x) public returns (uint y) {
value = x;
if (x > 0) table[++value] = 8;
if (x > 1) value--;
if (x > 2) table[value]++;
return --table[value++];
}
}
)";
compileAndRun(sourceCode);
u256 value = 0;
map<u256, u256> table;
auto f = [&](u256 const& _x) -> u256
{
value = _x;
if (_x > 0)
table[++value] = 8;
if (_x > 1)
value --;
if (_x > 2)
table[value]++;
return --table[value++];
};
testContractAgainstCppOnRange("f(uint256)", f, 0, 5);
}
BOOST_AUTO_TEST_CASE(multi_level_mapping)
{
char const* sourceCode = R"(
contract test {
mapping(uint => mapping(uint => uint)) table;
function f(uint x, uint y, uint z) public returns (uint w) {
if (z == 0) return table[x][y];
else return table[x][y] = z;
}
}
)";
compileAndRun(sourceCode);
map<u256, map<u256, u256>> table;
auto f = [&](u256 const& _x, u256 const& _y, u256 const& _z) -> u256
{
if (_z == 0) return table[_x][_y];
else return table[_x][_y] = _z;
};
testContractAgainstCpp("f(uint256,uint256,uint256)", f, u256(4), u256(5), u256(0));
testContractAgainstCpp("f(uint256,uint256,uint256)", f, u256(5), u256(4), u256(0));
testContractAgainstCpp("f(uint256,uint256,uint256)", f, u256(4), u256(5), u256(9));
testContractAgainstCpp("f(uint256,uint256,uint256)", f, u256(4), u256(5), u256(0));
testContractAgainstCpp("f(uint256,uint256,uint256)", f, u256(5), u256(4), u256(0));
testContractAgainstCpp("f(uint256,uint256,uint256)", f, u256(5), u256(4), u256(7));
testContractAgainstCpp("f(uint256,uint256,uint256)", f, u256(4), u256(5), u256(0));
testContractAgainstCpp("f(uint256,uint256,uint256)", f, u256(5), u256(4), u256(0));
}
BOOST_AUTO_TEST_CASE(mapping_local_assignment)
{
char const* sourceCode = R"(
contract test {
mapping(uint8 => uint8) m1;
mapping(uint8 => uint8) m2;
function f() public returns (uint8, uint8, uint8, uint8) {
mapping(uint8 => uint8) storage m = m1;
m[1] = 42;
m = m2;
m[2] = 21;
return (m1[1], m1[2], m2[1], m2[2]);
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("f()"), encodeArgs(uint8_t(42), uint8_t(0), uint8_t(0), uint8_t(21)));
}
BOOST_AUTO_TEST_CASE(mapping_local_tuple_assignment)
{
char const* sourceCode = R"(
contract test {
mapping(uint8 => uint8) m1;
mapping(uint8 => uint8) m2;
function f() public returns (uint8, uint8, uint8, uint8) {
mapping(uint8 => uint8) storage m = m1;
m[1] = 42;
uint8 v;
(m, v) = (m2, 21);
m[2] = v;
return (m1[1], m1[2], m2[1], m2[2]);
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("f()"), encodeArgs(uint8_t(42), uint8_t(0), uint8_t(0), uint8_t(21)));
}
BOOST_AUTO_TEST_CASE(mapping_local_compound_assignment)
{
char const* sourceCode = R"(
contract test {
mapping(uint8 => uint8) m1;
mapping(uint8 => uint8) m2;
function f() public returns (uint8, uint8, uint8, uint8) {
mapping(uint8 => uint8) storage m = m1;
m[1] = 42;
(m = m2)[2] = 21;
return (m1[1], m1[2], m2[1], m2[2]);
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("f()"), encodeArgs(uint8_t(42), uint8_t(0), uint8_t(0), uint8_t(21)));
}
BOOST_AUTO_TEST_CASE(mapping_internal_argument)
{
char const* sourceCode = R"(
contract test {
mapping(uint8 => uint8) a;
mapping(uint8 => uint8) b;
function set_internal(mapping(uint8 => uint8) storage m, uint8 key, uint8 value) internal returns (uint8) {
uint8 oldValue = m[key];
m[key] = value;
return oldValue;
}
function set(uint8 key, uint8 value_a, uint8 value_b) public returns (uint8 old_a, uint8 old_b) {
old_a = set_internal(a, key, value_a);
old_b = set_internal(b, key, value_b);
}
function get(uint8 key) public returns (uint8, uint8) {
return (a[key], b[key]);
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("set(uint8,uint8,uint8)", uint8_t(1), uint8_t(21), uint8_t(42)), encodeArgs(uint8_t(0), uint8_t(0)));
ABI_CHECK(callContractFunction("get(uint8)", uint8_t(1)), encodeArgs(uint8_t(21), uint8_t(42)));
ABI_CHECK(callContractFunction("set(uint8,uint8,uint8)", uint8_t(1), uint8_t(10), uint8_t(11)), encodeArgs(uint8_t(21), uint8_t(42)));
ABI_CHECK(callContractFunction("get(uint8)", uint8_t(1)), encodeArgs(uint8_t(10), uint8_t(11)));
}
BOOST_AUTO_TEST_CASE(mapping_array_internal_argument)
{
char const* sourceCode = R"(
contract test {
mapping(uint8 => uint8)[2] a;
mapping(uint8 => uint8)[2] b;
function set_internal(mapping(uint8 => uint8)[2] storage m, uint8 key, uint8 value1, uint8 value2) internal returns (uint8, uint8) {
uint8 oldValue1 = m[0][key];
uint8 oldValue2 = m[1][key];
m[0][key] = value1;
m[1][key] = value2;
return (oldValue1, oldValue2);
}
function set(uint8 key, uint8 value_a1, uint8 value_a2, uint8 value_b1, uint8 value_b2) public returns (uint8 old_a1, uint8 old_a2, uint8 old_b1, uint8 old_b2) {
(old_a1, old_a2) = set_internal(a, key, value_a1, value_a2);
(old_b1, old_b2) = set_internal(b, key, value_b1, value_b2);
}
function get(uint8 key) public returns (uint8, uint8, uint8, uint8) {
return (a[0][key], a[1][key], b[0][key], b[1][key]);
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("set(uint8,uint8,uint8,uint8,uint8)", uint8_t(1), uint8_t(21), uint8_t(22), uint8_t(42), uint8_t(43)), encodeArgs(uint8_t(0), uint8_t(0), uint8_t(0), uint8_t(0)));
ABI_CHECK(callContractFunction("get(uint8)", uint8_t(1)), encodeArgs(uint8_t(21), uint8_t(22), uint8_t(42), uint8_t(43)));
ABI_CHECK(callContractFunction("set(uint8,uint8,uint8,uint8,uint8)", uint8_t(1), uint8_t(10), uint8_t(30), uint8_t(11), uint8_t(31)), encodeArgs(uint8_t(21), uint8_t(22), uint8_t(42), uint8_t(43)));
ABI_CHECK(callContractFunction("get(uint8)", uint8_t(1)), encodeArgs(uint8_t(10), uint8_t(30), uint8_t(11), uint8_t(31)));
}
BOOST_AUTO_TEST_CASE(mapping_internal_return)
{
char const* sourceCode = R"(
contract test {
mapping(uint8 => uint8) a;
mapping(uint8 => uint8) b;
function f() internal returns (mapping(uint8 => uint8) storage r) {
r = a;
r[1] = 42;
r = b;
r[1] = 84;
}
function g() public returns (uint8, uint8, uint8, uint8, uint8, uint8) {
f()[2] = 21;
return (a[0], a[1], a[2], b[0], b[1], b[2]);
}
function h() public returns (uint8, uint8, uint8, uint8, uint8, uint8) {
mapping(uint8 => uint8) storage m = f();
m[2] = 17;
return (a[0], a[1], a[2], b[0], b[1], b[2]);
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("g()"), encodeArgs(uint8_t(0), uint8_t(42), uint8_t(0), uint8_t(0), uint8_t(84), uint8_t (21)));
ABI_CHECK(callContractFunction("h()"), encodeArgs(uint8_t(0), uint8_t(42), uint8_t(0), uint8_t(0), uint8_t(84), uint8_t (17)));
}
BOOST_AUTO_TEST_CASE(structs)
{
char const* sourceCode = R"(
contract test {
struct s1 {
uint8 x;
bool y;
}
struct s2 {
uint32 z;
s1 s1data;
mapping(uint8 => s2) recursive;
}
s2 data;
function check() public returns (bool ok) {
return data.z == 1 && data.s1data.x == 2 &&
data.s1data.y == true &&
data.recursive[3].recursive[4].z == 5 &&
data.recursive[4].recursive[3].z == 6 &&
data.recursive[0].s1data.y == false &&
data.recursive[4].z == 9;
}
function set() public {
data.z = 1;
data.s1data.x = 2;
data.s1data.y = true;
data.recursive[3].recursive[4].z = 5;
data.recursive[4].recursive[3].z = 6;
data.recursive[0].s1data.y = false;
data.recursive[4].z = 9;
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("check()"), encodeArgs(false));
ABI_CHECK(callContractFunction("set()"), bytes());
ABI_CHECK(callContractFunction("check()"), encodeArgs(true));
}
BOOST_AUTO_TEST_CASE(struct_reference)
{
char const* sourceCode = R"(
contract test {
struct s2 {
uint32 z;
mapping(uint8 => s2) recursive;
}
s2 data;
function check() public returns (bool ok) {
return data.z == 2 &&
data.recursive[0].z == 3 &&
data.recursive[0].recursive[1].z == 0 &&
data.recursive[0].recursive[0].z == 1;
}
function set() public {
data.z = 2;
mapping(uint8 => s2) storage map = data.recursive;
s2 storage inner = map[0];
inner.z = 3;
inner.recursive[0].z = inner.recursive[1].z + 1;
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("check()"), encodeArgs(false));
ABI_CHECK(callContractFunction("set()"), bytes());
ABI_CHECK(callContractFunction("check()"), encodeArgs(true));
}
BOOST_AUTO_TEST_CASE(deleteStruct)
{
char const* sourceCode = R"(
contract test {
struct topStruct {
nestedStruct nstr;
uint topValue;
mapping (uint => uint) topMapping;
}
uint toDelete;
topStruct str;
struct nestedStruct {
uint nestedValue;
mapping (uint => bool) nestedMapping;
}
constructor() public {
toDelete = 5;
str.topValue = 1;
str.topMapping[0] = 1;
str.topMapping[1] = 2;
str.nstr.nestedValue = 2;
str.nstr.nestedMapping[0] = true;
str.nstr.nestedMapping[1] = false;
delete str;
delete toDelete;
}
function getToDelete() public returns (uint res){
res = toDelete;
}
function getTopValue() public returns(uint topValue){
topValue = str.topValue;
}
function getNestedValue() public returns(uint nestedValue){
nestedValue = str.nstr.nestedValue;
}
function getTopMapping(uint index) public returns(uint ret) {
ret = str.topMapping[index];
}
function getNestedMapping(uint index) public returns(bool ret) {
return str.nstr.nestedMapping[index];
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("getToDelete()"), encodeArgs(0));
ABI_CHECK(callContractFunction("getTopValue()"), encodeArgs(0));
ABI_CHECK(callContractFunction("getNestedValue()"), encodeArgs(0));
// mapping values should be the same
ABI_CHECK(callContractFunction("getTopMapping(uint256)", 0), encodeArgs(1));
ABI_CHECK(callContractFunction("getTopMapping(uint256)", 1), encodeArgs(2));
ABI_CHECK(callContractFunction("getNestedMapping(uint256)", 0), encodeArgs(true));
ABI_CHECK(callContractFunction("getNestedMapping(uint256)", 1), encodeArgs(false));
}
BOOST_AUTO_TEST_CASE(deleteLocal)
{
char const* sourceCode = R"(
contract test {
function delLocal() public returns (uint res){
uint v = 5;
delete v;
res = v;
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("delLocal()"), encodeArgs(0));
}
BOOST_AUTO_TEST_CASE(deleteLocals)
{
char const* sourceCode = R"(
contract test {
function delLocal() public returns (uint res1, uint res2){
uint v = 5;
uint w = 6;
uint x = 7;
delete v;
res1 = w;
res2 = x;
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("delLocal()"), encodeArgs(6, 7));
}
BOOST_AUTO_TEST_CASE(deleteLength)
{
char const* sourceCode = R"(
contract test {
uint[] x;
function f() public returns (uint){
x.length = 1;
x[0] = 1;
delete x.length;
return x.length;
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("f()"), encodeArgs(0));
BOOST_CHECK(storageEmpty(m_contractAddress));
}
BOOST_AUTO_TEST_CASE(constructor)
{
char const* sourceCode = R"(
contract test {
mapping(uint => uint) data;
constructor() public {
data[7] = 8;
}
function get(uint key) public returns (uint value) {
return data[key];
}
}
)";
compileAndRun(sourceCode);
map<u256, uint8_t> data;
data[7] = 8;
auto get = [&](u256 const& _x) -> u256
{
return data[_x];
};
testContractAgainstCpp("get(uint256)", get, u256(6));
testContractAgainstCpp("get(uint256)", get, u256(7));
}
BOOST_AUTO_TEST_CASE(simple_accessor)
{
char const* sourceCode = R"(
contract test {
uint256 public data;
constructor() public {
data = 8;
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("data()"), encodeArgs(8));
}
BOOST_AUTO_TEST_CASE(array_accessor)
{
char const* sourceCode = R"(
contract test {
uint[8] public data;
uint[] public dynamicData;
uint24[] public smallTypeData;
struct st { uint a; uint[] finalArray; }
mapping(uint256 => mapping(uint256 => st[5])) public multiple_map;
constructor() public {
data[0] = 8;
dynamicData.length = 3;
dynamicData[2] = 8;
smallTypeData.length = 128;
smallTypeData[1] = 22;
smallTypeData[127] = 2;
multiple_map[2][1][2].a = 3;
multiple_map[2][1][2].finalArray.length = 4;
multiple_map[2][1][2].finalArray[3] = 5;
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("data(uint256)", 0), encodeArgs(8));
ABI_CHECK(callContractFunction("data(uint256)", 8), encodeArgs());
ABI_CHECK(callContractFunction("dynamicData(uint256)", 2), encodeArgs(8));
ABI_CHECK(callContractFunction("dynamicData(uint256)", 8), encodeArgs());
ABI_CHECK(callContractFunction("smallTypeData(uint256)", 1), encodeArgs(22));
ABI_CHECK(callContractFunction("smallTypeData(uint256)", 127), encodeArgs(2));
ABI_CHECK(callContractFunction("smallTypeData(uint256)", 128), encodeArgs());
ABI_CHECK(callContractFunction("multiple_map(uint256,uint256,uint256)", 2, 1, 2), encodeArgs(3));
}
BOOST_AUTO_TEST_CASE(accessors_mapping_for_array)
{
char const* sourceCode = R"(
contract test {
mapping(uint => uint[8]) public data;
mapping(uint => uint[]) public dynamicData;
constructor() public {
data[2][2] = 8;
dynamicData[2].length = 3;
dynamicData[2][2] = 8;
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("data(uint256,uint256)", 2, 2), encodeArgs(8));
ABI_CHECK(callContractFunction("data(uint256, 256)", 2, 8), encodeArgs());
ABI_CHECK(callContractFunction("dynamicData(uint256,uint256)", 2, 2), encodeArgs(8));
ABI_CHECK(callContractFunction("dynamicData(uint256,uint256)", 2, 8), encodeArgs());
}
BOOST_AUTO_TEST_CASE(multiple_elementary_accessors)
{
char const* sourceCode = R"(
contract test {
uint256 public data;
bytes6 public name;
bytes32 public a_hash;
address public an_address;
constructor() public {
data = 8;
name = "Celina";
a_hash = keccak256("\x7b");
an_address = address(0x1337);
super_secret_data = 42;
}
uint256 super_secret_data;
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("data()"), encodeArgs(8));
ABI_CHECK(callContractFunction("name()"), encodeArgs("Celina"));
ABI_CHECK(callContractFunction("a_hash()"), encodeArgs(dev::keccak256(bytes(1, 0x7b))));
ABI_CHECK(callContractFunction("an_address()"), encodeArgs(toBigEndian(u160(0x1337))));
ABI_CHECK(callContractFunction("super_secret_data()"), bytes());
}
BOOST_AUTO_TEST_CASE(complex_accessors)
{
char const* sourceCode = R"(
contract test {
mapping(uint256 => bytes4) public to_string_map;
mapping(uint256 => bool) public to_bool_map;
mapping(uint256 => uint256) public to_uint_map;
mapping(uint256 => mapping(uint256 => uint256)) public to_multiple_map;
constructor() public {
to_string_map[42] = "24";
to_bool_map[42] = false;
to_uint_map[42] = 12;
to_multiple_map[42][23] = 31;
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("to_string_map(uint256)", 42), encodeArgs("24"));
ABI_CHECK(callContractFunction("to_bool_map(uint256)", 42), encodeArgs(false));
ABI_CHECK(callContractFunction("to_uint_map(uint256)", 42), encodeArgs(12));
ABI_CHECK(callContractFunction("to_multiple_map(uint256,uint256)", 42, 23), encodeArgs(31));
}
BOOST_AUTO_TEST_CASE(struct_accessor)
{
char const* sourceCode = R"(
contract test {
struct Data { uint a; uint8 b; mapping(uint => uint) c; bool d; }
mapping(uint => Data) public data;
constructor() public {
data[7].a = 1;
data[7].b = 2;
data[7].c[0] = 3;
data[7].d = true;
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("data(uint256)", 7), encodeArgs(1, 2, true));
}
BOOST_AUTO_TEST_CASE(balance)
{
char const* sourceCode = R"(
contract test {
constructor() public payable {}
function getBalance() public returns (uint256 balance) {
return address(this).balance;
}
}
)";
compileAndRun(sourceCode, 23);
ABI_CHECK(callContractFunction("getBalance()"), encodeArgs(23));
}
BOOST_AUTO_TEST_CASE(blockchain)
{
char const* sourceCode = R"(
contract test {
constructor() public payable {}
function someInfo() public payable returns (uint256 value, address coinbase, uint256 blockNumber) {
value = msg.value;
coinbase = block.coinbase;
blockNumber = block.number;
}
}
)";
BOOST_CHECK(m_rpc.rpcCall("miner_setEtherbase", {"\"0x1212121212121212121212121212121212121212\""}).asBool() == true);
m_rpc.test_mineBlocks(5);
compileAndRun(sourceCode, 27);
ABI_CHECK(callContractFunctionWithValue("someInfo()", 28), encodeArgs(28, u256("0x1212121212121212121212121212121212121212"), 7));
}
BOOST_AUTO_TEST_CASE(msg_sig)
{
char const* sourceCode = R"(
contract test {
function foo(uint256 a) public returns (bytes4 value) {
return msg.sig;
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("foo(uint256)", 0), encodeArgs(asString(FixedHash<4>(dev::keccak256("foo(uint256)")).asBytes())));
}
BOOST_AUTO_TEST_CASE(msg_sig_after_internal_call_is_same)
{
char const* sourceCode = R"(
contract test {
function boo() public returns (bytes4 value) {
return msg.sig;
}
function foo(uint256 a) public returns (bytes4 value) {
return boo();
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("foo(uint256)", 0), encodeArgs(asString(FixedHash<4>(dev::keccak256("foo(uint256)")).asBytes())));
}
BOOST_AUTO_TEST_CASE(now)
{
char const* sourceCode = R"(
contract test {
function someInfo() public returns (bool equal, uint val) {
equal = block.timestamp == now;
val = now;
}
}
)";
compileAndRun(sourceCode);
u256 startBlock = m_blockNumber;
size_t startTime = blockTimestamp(startBlock);
auto ret = callContractFunction("someInfo()");
u256 endBlock = m_blockNumber;
size_t endTime = blockTimestamp(endBlock);
BOOST_CHECK(startBlock != endBlock);
BOOST_CHECK(startTime != endTime);
ABI_CHECK(ret, encodeArgs(true, endTime));
}
BOOST_AUTO_TEST_CASE(type_conversions_cleanup)
{
// 22-byte integer converted to a contract (i.e. address, 20 bytes), converted to a 32 byte
// integer should drop the first two bytes
char const* sourceCode = R"(
contract Test {
function test() public returns (uint ret) { return uint(address(Test(address(0x11223344556677889900112233445566778899001122)))); }
}
)";
compileAndRun(sourceCode);
BOOST_REQUIRE(callContractFunction("test()") == bytes({0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00,
0x33, 0x44, 0x55, 0x66, 0x77, 0x88, 0x99, 0x00, 0x11, 0x22,
0x33, 0x44, 0x55, 0x66, 0x77, 0x88, 0x99, 0x00, 0x11, 0x22}));
}
// fixed bytes to fixed bytes conversion tests
BOOST_AUTO_TEST_CASE(convert_fixed_bytes_to_fixed_bytes_smaller_size)
{
char const* sourceCode = R"(
contract Test {
function bytesToBytes(bytes4 input) public returns (bytes2 ret) {
return bytes2(input);
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("bytesToBytes(bytes4)", "abcd"), encodeArgs("ab"));
}
BOOST_AUTO_TEST_CASE(convert_fixed_bytes_to_fixed_bytes_greater_size)
{
char const* sourceCode = R"(
contract Test {
function bytesToBytes(bytes2 input) public returns (bytes4 ret) {
return bytes4(input);
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("bytesToBytes(bytes2)", "ab"), encodeArgs("ab"));
}
BOOST_AUTO_TEST_CASE(convert_fixed_bytes_to_fixed_bytes_same_size)
{
char const* sourceCode = R"(
contract Test {
function bytesToBytes(bytes4 input) public returns (bytes4 ret) {
return bytes4(input);
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("bytesToBytes(bytes4)", "abcd"), encodeArgs("abcd"));
}
// fixed bytes to uint conversion tests
BOOST_AUTO_TEST_CASE(convert_fixed_bytes_to_uint_same_size)
{
char const* sourceCode = R"(
contract Test {
function bytesToUint(bytes32 s) public returns (uint256 h) {
return uint(s);
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(
callContractFunction("bytesToUint(bytes32)", string("abc2")),
encodeArgs(u256("0x6162633200000000000000000000000000000000000000000000000000000000"))
);
}
BOOST_AUTO_TEST_CASE(convert_fixed_bytes_to_uint_same_min_size)
{
char const* sourceCode = R"(
contract Test {
function bytesToUint(bytes1 s) public returns (uint8 h) {
return uint8(s);
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(
callContractFunction("bytesToUint(bytes1)", string("a")),
encodeArgs(u256("0x61"))
);
}
BOOST_AUTO_TEST_CASE(convert_fixed_bytes_to_uint_smaller_size)
{
char const* sourceCode = R"(
contract Test {
function bytesToUint(bytes4 s) public returns (uint16 h) {
return uint16(uint32(s));
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(
callContractFunction("bytesToUint(bytes4)", string("abcd")),
encodeArgs(u256("0x6364"))
);
}
BOOST_AUTO_TEST_CASE(convert_fixed_bytes_to_uint_greater_size)
{
char const* sourceCode = R"(
contract Test {
function bytesToUint(bytes4 s) public returns (uint64 h) {
return uint64(uint32(s));
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(
callContractFunction("bytesToUint(bytes4)", string("abcd")),
encodeArgs(u256("0x61626364"))
);
}
// uint fixed bytes conversion tests
BOOST_AUTO_TEST_CASE(convert_uint_to_fixed_bytes_same_size)
{
char const* sourceCode = R"(
contract Test {
function uintToBytes(uint256 h) public returns (bytes32 s) {
return bytes32(h);
}
}
)";
compileAndRun(sourceCode);
u256 a("0x6162630000000000000000000000000000000000000000000000000000000000");
ABI_CHECK(callContractFunction("uintToBytes(uint256)", a), encodeArgs(a));
}
BOOST_AUTO_TEST_CASE(convert_uint_to_fixed_bytes_same_min_size)
{
char const* sourceCode = R"(
contract Test {
function UintToBytes(uint8 h) public returns (bytes1 s) {
return bytes1(h);
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(
callContractFunction("UintToBytes(uint8)", u256("0x61")),
encodeArgs(string("a"))
);
}
BOOST_AUTO_TEST_CASE(convert_uint_to_fixed_bytes_smaller_size)
{
char const* sourceCode = R"(
contract Test {
function uintToBytes(uint32 h) public returns (bytes2 s) {
return bytes2(uint16(h));
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(
callContractFunction("uintToBytes(uint32)", u160("0x61626364")),
encodeArgs(string("cd"))
);
}
BOOST_AUTO_TEST_CASE(convert_uint_to_fixed_bytes_greater_size)
{
char const* sourceCode = R"(
contract Test {
function UintToBytes(uint16 h) public returns (bytes8 s) {
return bytes8(uint64(h));
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(
callContractFunction("UintToBytes(uint16)", u256("0x6162")),
encodeArgs(string("\0\0\0\0\0\0ab", 8))
);
}
BOOST_AUTO_TEST_CASE(send_ether)
{
char const* sourceCode = R"(
contract test {
constructor() payable public {}
function a(address payable addr, uint amount) public returns (uint ret) {
addr.send(amount);
return address(this).balance;
}
}
)";
u256 amount(130);
compileAndRun(sourceCode, amount + 1);
u160 address(23);
ABI_CHECK(callContractFunction("a(address,uint256)", address, amount), encodeArgs(1));
BOOST_CHECK_EQUAL(balanceAt(address), amount);
}
BOOST_AUTO_TEST_CASE(transfer_ether)
{
char const* sourceCode = R"(
contract A {
constructor() public payable {}
function a(address payable addr, uint amount) public returns (uint) {
addr.transfer(amount);
return address(this).balance;
}
function b(address payable addr, uint amount) public {
addr.transfer(amount);
}
}
contract B {
}
contract C {
function () external payable {
revert();
}
}
)";
compileAndRun(sourceCode, 0, "B");
u160 const nonPayableRecipient = m_contractAddress;
compileAndRun(sourceCode, 0, "C");
u160 const oogRecipient = m_contractAddress;
compileAndRun(sourceCode, 20, "A");
u160 payableRecipient(23);
ABI_CHECK(callContractFunction("a(address,uint256)", payableRecipient, 10), encodeArgs(10));
BOOST_CHECK_EQUAL(balanceAt(payableRecipient), 10);
BOOST_CHECK_EQUAL(balanceAt(m_contractAddress), 10);
ABI_CHECK(callContractFunction("b(address,uint256)", nonPayableRecipient, 10), encodeArgs());
ABI_CHECK(callContractFunction("b(address,uint256)", oogRecipient, 10), encodeArgs());
}
BOOST_AUTO_TEST_CASE(uncalled_blockhash)
{
char const* code = R"(
contract C {
function f() public view returns (bytes32)
{
return (blockhash)(block.number - 1);
}
}
)";
compileAndRun(code, 0, "C");
bytes result = callContractFunction("f()");
BOOST_REQUIRE_EQUAL(result.size(), 32);
BOOST_CHECK(result[0] != 0 || result[1] != 0 || result[2] != 0);
}
BOOST_AUTO_TEST_CASE(blockhash_shadow_resolution)
{
char const* code = R"(
contract C {
function blockhash(uint256 blockNumber) public returns(bytes32) { bytes32 x; return x; }
function f() public returns(bytes32) { return blockhash(3); }
}
)";
compileAndRun(code, 0, "C");
ABI_CHECK(callContractFunction("f()"), encodeArgs(0));
}
BOOST_AUTO_TEST_CASE(log0)
{
char const* sourceCode = R"(
contract test {
function a() public {
log0(bytes32(uint256(1)));
}
}
)";
compileAndRun(sourceCode);
callContractFunction("a()");
BOOST_REQUIRE_EQUAL(m_logs.size(), 1);
BOOST_CHECK_EQUAL(m_logs[0].address, m_contractAddress);
BOOST_CHECK_EQUAL(h256(m_logs[0].data), h256(u256(1)));
BOOST_CHECK_EQUAL(m_logs[0].topics.size(), 0);
}
BOOST_AUTO_TEST_CASE(log1)
{
char const* sourceCode = R"(
contract test {
function a() public {
log1(bytes32(uint256(1)), bytes32(uint256(2)));
}
}
)";
compileAndRun(sourceCode);
callContractFunction("a()");
BOOST_REQUIRE_EQUAL(m_logs.size(), 1);
BOOST_CHECK_EQUAL(m_logs[0].address, m_contractAddress);
BOOST_CHECK_EQUAL(h256(m_logs[0].data), h256(u256(1)));
BOOST_REQUIRE_EQUAL(m_logs[0].topics.size(), 1);
BOOST_CHECK_EQUAL(m_logs[0].topics[0], h256(u256(2)));
}
BOOST_AUTO_TEST_CASE(log2)
{
char const* sourceCode = R"(
contract test {
function a() public {
log2(bytes32(uint256(1)), bytes32(uint256(2)), bytes32(uint256(3)));
}
}
)";
compileAndRun(sourceCode);
callContractFunction("a()");
BOOST_REQUIRE_EQUAL(m_logs.size(), 1);
BOOST_CHECK_EQUAL(m_logs[0].address, m_contractAddress);
BOOST_CHECK_EQUAL(h256(m_logs[0].data), h256(u256(1)));
BOOST_REQUIRE_EQUAL(m_logs[0].topics.size(), 2);
for (unsigned i = 0; i < 2; ++i)
BOOST_CHECK_EQUAL(m_logs[0].topics[i], h256(u256(i + 2)));
}
BOOST_AUTO_TEST_CASE(log3)
{
char const* sourceCode = R"(
contract test {
function a() public {
log3(bytes32(uint256(1)), bytes32(uint256(2)), bytes32(uint256(3)), bytes32(uint256(4)));
}
}
)";
compileAndRun(sourceCode);
callContractFunction("a()");
BOOST_REQUIRE_EQUAL(m_logs.size(), 1);
BOOST_CHECK_EQUAL(m_logs[0].address, m_contractAddress);
BOOST_CHECK_EQUAL(h256(m_logs[0].data), h256(u256(1)));
BOOST_REQUIRE_EQUAL(m_logs[0].topics.size(), 3);
for (unsigned i = 0; i < 3; ++i)
BOOST_CHECK_EQUAL(m_logs[0].topics[i], h256(u256(i + 2)));
}
BOOST_AUTO_TEST_CASE(log4)
{
char const* sourceCode = R"(
contract test {
function a() public {
log4(bytes32(uint256(1)), bytes32(uint256(2)), bytes32(uint256(3)), bytes32(uint256(4)), bytes32(uint256(5)));
}
}
)";
compileAndRun(sourceCode);
callContractFunction("a()");
BOOST_REQUIRE_EQUAL(m_logs.size(), 1);
BOOST_CHECK_EQUAL(m_logs[0].address, m_contractAddress);
BOOST_CHECK_EQUAL(h256(m_logs[0].data), h256(u256(1)));
BOOST_REQUIRE_EQUAL(m_logs[0].topics.size(), 4);
for (unsigned i = 0; i < 4; ++i)
BOOST_CHECK_EQUAL(m_logs[0].topics[i], h256(u256(i + 2)));
}
BOOST_AUTO_TEST_CASE(log_in_constructor)
{
char const* sourceCode = R"(
contract test {
constructor() public {
log1(bytes32(uint256(1)), bytes32(uint256(2)));
}
}
)";
compileAndRun(sourceCode);
BOOST_REQUIRE_EQUAL(m_logs.size(), 1);
BOOST_CHECK_EQUAL(m_logs[0].address, m_contractAddress);
BOOST_CHECK_EQUAL(h256(m_logs[0].data), h256(u256(1)));
BOOST_REQUIRE_EQUAL(m_logs[0].topics.size(), 1);
BOOST_CHECK_EQUAL(m_logs[0].topics[0], h256(u256(2)));
}
BOOST_AUTO_TEST_CASE(selfdestruct)
{
char const* sourceCode = R"(
contract test {
constructor() public payable {}
function a(address payable receiver) public returns (uint ret) {
selfdestruct(receiver);
return 10;
}
}
)";
u256 amount(130);
compileAndRun(sourceCode, amount);
u160 address(23);
ABI_CHECK(callContractFunction("a(address)", address), bytes());
BOOST_CHECK(!addressHasCode(m_contractAddress));
BOOST_CHECK_EQUAL(balanceAt(address), amount);
}
BOOST_AUTO_TEST_CASE(keccak256)
{
char const* sourceCode = R"(
contract test {
function a(bytes32 input) public returns (bytes32 hash) {
return keccak256(abi.encodePacked(input));
}
}
)";
compileAndRun(sourceCode);
auto f = [&](u256 const& _x) -> u256
{
return dev::keccak256(toBigEndian(_x));
};
testContractAgainstCpp("a(bytes32)", f, u256(4));
testContractAgainstCpp("a(bytes32)", f, u256(5));
testContractAgainstCpp("a(bytes32)", f, u256(-1));
}
BOOST_AUTO_TEST_CASE(sha256)
{
char const* sourceCode = R"(
contract test {
function a(bytes32 input) public returns (bytes32 sha256hash) {
return sha256(abi.encodePacked(input));
}
}
)";
compileAndRun(sourceCode);
auto f = [&](u256 const& _x) -> bytes
{
if (_x == u256(4))
return fromHex("e38990d0c7fc009880a9c07c23842e886c6bbdc964ce6bdd5817ad357335ee6f");
if (_x == u256(5))
return fromHex("96de8fc8c256fa1e1556d41af431cace7dca68707c78dd88c3acab8b17164c47");
if (_x == u256(-1))
return fromHex("af9613760f72635fbdb44a5a0a63c39f12af30f950a6ee5c971be188e89c4051");
return fromHex("");
};
testContractAgainstCpp("a(bytes32)", f, u256(4));
testContractAgainstCpp("a(bytes32)", f, u256(5));
testContractAgainstCpp("a(bytes32)", f, u256(-1));
}
BOOST_AUTO_TEST_CASE(ripemd)
{
char const* sourceCode = R"(
contract test {
function a(bytes32 input) public returns (bytes32 sha256hash) {
return ripemd160(abi.encodePacked(input));
}
}
)";
compileAndRun(sourceCode);
auto f = [&](u256 const& _x) -> bytes
{
if (_x == u256(4))
return fromHex("1b0f3c404d12075c68c938f9f60ebea4f74941a0000000000000000000000000");
if (_x == u256(5))
return fromHex("ee54aa84fc32d8fed5a5fe160442ae84626829d9000000000000000000000000");
if (_x == u256(-1))
return fromHex("1cf4e77f5966e13e109703cd8a0df7ceda7f3dc3000000000000000000000000");
return fromHex("");
};
testContractAgainstCpp("a(bytes32)", f, u256(4));
testContractAgainstCpp("a(bytes32)", f, u256(5));
testContractAgainstCpp("a(bytes32)", f, u256(-1));
}
BOOST_AUTO_TEST_CASE(packed_keccak256)
{
char const* sourceCode = R"(
contract test {
function a(bytes32 input) public returns (bytes32 hash) {
uint24 b = 65536;
uint c = 256;
return keccak256(abi.encodePacked(uint8(8), input, b, input, c));
}
}
)";
compileAndRun(sourceCode);
auto f = [&](u256 const& _x) -> u256
{
return dev::keccak256(
toCompactBigEndian(unsigned(8)) +
toBigEndian(_x) +
toCompactBigEndian(unsigned(65536)) +
toBigEndian(_x) +
toBigEndian(u256(256))
);
};
testContractAgainstCpp("a(bytes32)", f, u256(4));
testContractAgainstCpp("a(bytes32)", f, u256(5));
testContractAgainstCpp("a(bytes32)", f, u256(-1));
}
BOOST_AUTO_TEST_CASE(packed_keccak256_complex_types)
{
char const* sourceCode = R"(
contract test {
uint120[3] x;
function f() public returns (bytes32 hash1, bytes32 hash2, bytes32 hash3) {
uint120[] memory y = new uint120[](3);
x[0] = y[0] = uint120(-2);
x[1] = y[1] = uint120(-3);
x[2] = y[2] = uint120(-4);
hash1 = keccak256(abi.encodePacked(x));
hash2 = keccak256(abi.encodePacked(y));
hash3 = keccak256(abi.encodePacked(this.f));
}
}
)";
compileAndRun(sourceCode);
// Strangely, arrays are encoded with intra-element padding.
ABI_CHECK(callContractFunction("f()"), encodeArgs(
dev::keccak256(encodeArgs(u256("0xfffffffffffffffffffffffffffffe"), u256("0xfffffffffffffffffffffffffffffd"), u256("0xfffffffffffffffffffffffffffffc"))),
dev::keccak256(encodeArgs(u256("0xfffffffffffffffffffffffffffffe"), u256("0xfffffffffffffffffffffffffffffd"), u256("0xfffffffffffffffffffffffffffffc"))),
dev::keccak256(fromHex(m_contractAddress.hex() + "26121ff0"))
));
}
BOOST_AUTO_TEST_CASE(packed_sha256)
{
char const* sourceCode = R"(
contract test {
function a(bytes32 input) public returns (bytes32 hash) {
uint24 b = 65536;
uint c = 256;
return sha256(abi.encodePacked(uint8(8), input, b, input, c));
}
}
)";
compileAndRun(sourceCode);
auto f = [&](u256 const& _x) -> bytes
{
if (_x == u256(4))
return fromHex("804e0d7003cfd70fc925dc103174d9f898ebb142ecc2a286da1abd22ac2ce3ac");
if (_x == u256(5))
return fromHex("e94921945f9068726c529a290a954f412bcac53184bb41224208a31edbf63cf0");
if (_x == u256(-1))
return fromHex("f14def4d07cd185ddd8b10a81b2238326196a38867e6e6adbcc956dc913488c7");
return fromHex("");
};
testContractAgainstCpp("a(bytes32)", f, u256(4));
testContractAgainstCpp("a(bytes32)", f, u256(5));
testContractAgainstCpp("a(bytes32)", f, u256(-1));
}
BOOST_AUTO_TEST_CASE(packed_ripemd160)
{
char const* sourceCode = R"(
contract test {
function a(bytes32 input) public returns (bytes32 hash) {
uint24 b = 65536;
uint c = 256;
return ripemd160(abi.encodePacked(uint8(8), input, b, input, c));
}
}
)";
compileAndRun(sourceCode);
auto f = [&](u256 const& _x) -> bytes
{
if (_x == u256(4))
return fromHex("f93175303eba2a7b372174fc9330237f5ad202fc000000000000000000000000");
if (_x == u256(5))
return fromHex("04f4fc112e2bfbe0d38f896a46629e08e2fcfad5000000000000000000000000");
if (_x == u256(-1))
return fromHex("c0a2e4b1f3ff766a9a0089e7a410391730872495000000000000000000000000");
return fromHex("");
};
testContractAgainstCpp("a(bytes32)", f, u256(4));
testContractAgainstCpp("a(bytes32)", f, u256(5));
testContractAgainstCpp("a(bytes32)", f, u256(-1));
}
BOOST_AUTO_TEST_CASE(inter_contract_calls)
{
char const* sourceCode = R"(
contract Helper {
function multiply(uint a, uint b) public returns (uint c) {
return a * b;
}
}
contract Main {
Helper h;
function callHelper(uint a, uint b) public returns (uint c) {
return h.multiply(a, b);
}
function getHelper() public returns (address haddress) {
return address(h);
}
function setHelper(address haddress) public {
h = Helper(haddress);
}
}
)";
compileAndRun(sourceCode, 0, "Helper");
u160 const c_helperAddress = m_contractAddress;
compileAndRun(sourceCode, 0, "Main");
BOOST_REQUIRE(callContractFunction("setHelper(address)", c_helperAddress) == bytes());
BOOST_REQUIRE(callContractFunction("getHelper()", c_helperAddress) == encodeArgs(c_helperAddress));
u256 a(3456789);
u256 b("0x282837623374623234aa74");
BOOST_REQUIRE(callContractFunction("callHelper(uint256,uint256)", a, b) == encodeArgs(a * b));
}
BOOST_AUTO_TEST_CASE(inter_contract_calls_with_complex_parameters)
{
char const* sourceCode = R"(
contract Helper {
function sel(uint a, bool select, uint b) public returns (uint c) {
if (select) return a; else return b;
}
}
contract Main {
Helper h;
function callHelper(uint a, bool select, uint b) public returns (uint c) {
return h.sel(a, select, b) * 3;
}
function getHelper() public returns (address haddress) {
return address(h);
}
function setHelper(address haddress) public {
h = Helper(haddress);
}
}
)";
compileAndRun(sourceCode, 0, "Helper");
u160 const c_helperAddress = m_contractAddress;
compileAndRun(sourceCode, 0, "Main");
BOOST_REQUIRE(callContractFunction("setHelper(address)", c_helperAddress) == bytes());
BOOST_REQUIRE(callContractFunction("getHelper()", c_helperAddress) == encodeArgs(c_helperAddress));
u256 a(3456789);
u256 b("0x282837623374623234aa74");
BOOST_REQUIRE(callContractFunction("callHelper(uint256,bool,uint256)", a, true, b) == encodeArgs(a * 3));
BOOST_REQUIRE(callContractFunction("callHelper(uint256,bool,uint256)", a, false, b) == encodeArgs(b * 3));
}
BOOST_AUTO_TEST_CASE(inter_contract_calls_accessing_this)
{
char const* sourceCode = R"(
contract Helper {
function getAddress() public returns (address addr) {
return address(this);
}
}
contract Main {
Helper h;
function callHelper() public returns (address addr) {
return h.getAddress();
}
function getHelper() public returns (address addr) {
return address(h);
}
function setHelper(address addr) public {
h = Helper(addr);
}
}
)";
compileAndRun(sourceCode, 0, "Helper");
u160 const c_helperAddress = m_contractAddress;
compileAndRun(sourceCode, 0, "Main");
BOOST_REQUIRE(callContractFunction("setHelper(address)", c_helperAddress) == bytes());
BOOST_REQUIRE(callContractFunction("getHelper()", c_helperAddress) == encodeArgs(c_helperAddress));
BOOST_REQUIRE(callContractFunction("callHelper()") == encodeArgs(c_helperAddress));
}
BOOST_AUTO_TEST_CASE(calls_to_this)
{
char const* sourceCode = R"(
contract Helper {
function invoke(uint a, uint b) public returns (uint c) {
return this.multiply(a, b, 10);
}
function multiply(uint a, uint b, uint8 c) public returns (uint ret) {
return a * b + c;
}
}
contract Main {
Helper h;
function callHelper(uint a, uint b) public returns (uint ret) {
return h.invoke(a, b);
}
function getHelper() public returns (address addr) {
return address(h);
}
function setHelper(address addr) public {
h = Helper(addr);
}
}
)";
compileAndRun(sourceCode, 0, "Helper");
u160 const c_helperAddress = m_contractAddress;
compileAndRun(sourceCode, 0, "Main");
BOOST_REQUIRE(callContractFunction("setHelper(address)", c_helperAddress) == bytes());
BOOST_REQUIRE(callContractFunction("getHelper()", c_helperAddress) == encodeArgs(c_helperAddress));
u256 a(3456789);
u256 b("0x282837623374623234aa74");
BOOST_REQUIRE(callContractFunction("callHelper(uint256,uint256)", a, b) == encodeArgs(a * b + 10));
}
BOOST_AUTO_TEST_CASE(inter_contract_calls_with_local_vars)
{
// note that a reference to another contract's function occupies two stack slots,
// so this tests correct stack slot allocation
char const* sourceCode = R"(
contract Helper {
function multiply(uint a, uint b) public returns (uint c) {
return a * b;
}
}
contract Main {
Helper h;
function callHelper(uint a, uint b) public returns (uint c) {
uint8 y = 9;
uint256 ret = h.multiply(a, b);
return ret + y;
}
function getHelper() public returns (address haddress) {
return address(h);
}
function setHelper(address haddress) public {
h = Helper(haddress);
}
}
)";
compileAndRun(sourceCode, 0, "Helper");
u160 const c_helperAddress = m_contractAddress;
compileAndRun(sourceCode, 0, "Main");
BOOST_REQUIRE(callContractFunction("setHelper(address)", c_helperAddress) == bytes());
BOOST_REQUIRE(callContractFunction("getHelper()", c_helperAddress) == encodeArgs(c_helperAddress));
u256 a(3456789);
u256 b("0x282837623374623234aa74");
BOOST_REQUIRE(callContractFunction("callHelper(uint256,uint256)", a, b) == encodeArgs(a * b + 9));
}
BOOST_AUTO_TEST_CASE(fixed_bytes_in_calls)
{
char const* sourceCode = R"(
contract Helper {
function invoke(bytes3 x, bool stop) public returns (bytes4 ret) {
return x;
}
}
contract Main {
Helper h;
function callHelper(bytes2 x, bool stop) public returns (bytes5 ret) {
return h.invoke(x, stop);
}
function getHelper() public returns (address addr) {
return address(h);
}
function setHelper(address addr) public {
h = Helper(addr);
}
}
)";
compileAndRun(sourceCode, 0, "Helper");
u160 const c_helperAddress = m_contractAddress;
compileAndRun(sourceCode, 0, "Main");
BOOST_REQUIRE(callContractFunction("setHelper(address)", c_helperAddress) == bytes());
BOOST_REQUIRE(callContractFunction("getHelper()", c_helperAddress) == encodeArgs(c_helperAddress));
ABI_CHECK(callContractFunction("callHelper(bytes2,bool)", string("\0a", 2), true), encodeArgs(string("\0a\0\0\0", 5)));
}
BOOST_AUTO_TEST_CASE(constructor_arguments_internal)
{
char const* sourceCode = R"(
contract Helper {
bytes3 name;
bool flag;
constructor(bytes3 x, bool f) public {
name = x;
flag = f;
}
function getName() public returns (bytes3 ret) { return name; }
function getFlag() public returns (bool ret) { return flag; }
}
contract Main {
Helper h;
constructor() public {
h = new Helper("abc", true);
}
function getFlag() public returns (bool ret) { return h.getFlag(); }
function getName() public returns (bytes3 ret) { return h.getName(); }
}
)";
compileAndRun(sourceCode, 0, "Main");
ABI_CHECK(callContractFunction("getFlag()"), encodeArgs(true));
ABI_CHECK(callContractFunction("getName()"), encodeArgs("abc"));
}
BOOST_AUTO_TEST_CASE(constructor_arguments_external)
{
char const* sourceCode = R"(
contract Main {
bytes3 name;
bool flag;
constructor(bytes3 x, bool f) public {
name = x;
flag = f;
}
function getName() public returns (bytes3 ret) { return name; }
function getFlag() public returns (bool ret) { return flag; }
}
)";
compileAndRun(sourceCode, 0, "Main", encodeArgs("abc", true));
ABI_CHECK(callContractFunction("getFlag()"), encodeArgs(true));
ABI_CHECK(callContractFunction("getName()"), encodeArgs("abc"));
}
BOOST_AUTO_TEST_CASE(constructor_with_long_arguments)
{
char const* sourceCode = R"(
contract Main {
string public a;
string public b;
constructor(string memory _a, string memory _b) public {
a = _a;
b = _b;
}
}
)";
string a = "01234567890123gabddunaouhdaoneudapcgadi4567890789012oneudapcgadi4567890789012oneudapcgadi4567890789012oneudapcgadi4567890789012oneudapcgadi4567890789012oneudapcgadi4567890789012oneudapcgadi4567890789012oneudapcgadi45678907890123456789abcd123456787890123456789abcd90123456789012345678901234567890123456789aboneudapcgadi4567890789012oneudapcgadi4567890789012oneudapcgadi45678907890123456789abcd123456787890123456789abcd90123456789012345678901234567890123456789aboneudapcgadi4567890789012oneudapcgadi4567890789012oneudapcgadi45678907890123456789abcd123456787890123456789abcd90123456789012345678901234567890123456789aboneudapcgadi4567890789012cdef";
string b = "AUTAHIACIANOTUHAOCUHAOEUNAOEHUNTHDYDHPYDRCPYDRSTITOEUBXHUDGO>PYAUTAHIACIANOTUHAOCUHAOEUNAOEHUNTHDYDHPYDRCPYDRSTITOEUBXHUDGO>PYAUTAHIACIANOTUHAOCUHAOEUNAOEHUNTHDYDHPYDRCPYDRSTITOEUBXHUDGO>PYAUTAHIACIANOTUHAOCUHAOEUNAOEHUNTHDYDHPYDRCPYDRSTITOEUBXHUDGO>PYAUTAHIACIANOTUHAOCUHAOEUNAOEHUNTHDYDHPYDRCPYDRSTITOEUBXHUDGO>PYAUTAHIACIANOTUHAOCUHAOEUNAOEHUNTHDYDHPYDRCPYDRSTITOEUBXHUDGO>PYAUTAHIACIANOTUHAOCUHAOEUNAOEHUNTHDYDHPYDRCPYDRSTITOEUBXHUDGO>PYAUTAHIACIANOTUHAOCUHAOEUNAOEHUNTHDYDHPYDRCPYDRSTITOEUBXHUDGO>PYAUTAHIACIANOTUHAOCUHAOEUNAOEHUNTHDYDHPYDRCPYDRSTITOEUBXHUDGO>PYAUTAHIACIANOTUHAOCUHAOEUNAOEHUNTHDYDHPYDRCPYDRSTITOEUBXHUDGO>PYAUTAHIACIANOTUHAOCUHAOEUNAOEHUNTHDYDHPYDRCPYDRSTITOEUBXHUDGO>PYAUTAHIACIANOTUHAOCUHAOEUNAOEHUNTHDYDHPYDRCPYDRSTITOEUBXHUDGO>PYAUTAHIACIANOTUHAOCUHAOEUNAOEHUNTHDYDHPYDRCPYDRSTITOEUBXHUDGO>PYAUTAHIACIANOTUHAOCUHAOEUNAOEHUNTHDYDHPYDRCPYDRSTITOEUBXHUDGO>PYAUTAHIACIANOTUHAOCUHAOEUNAOEHUNTHDYDHPYDRCPYDRSTITOEUBXHUDGO>PYAUTAHIACIANOTUHAOCUHAOEUNAOEHUNTHDYDHPYDRCPYDRSTITOEUBXHUDGO>PYAUTAHIACIANOTUHAOCUHAOEUNAOEHUNTHDYDHPYDRCPYDRSTITOEUBXHUDGO>PYAUTAHIACIANOTUHAOCUHAOEUNAOEHUNTHDYDHPYDRCPYDRSTITOEUBXHUDGO>PY";
compileAndRun(sourceCode, 0, "Main", encodeArgs(
u256(0x40),
u256(0x40 + 0x20 + ((a.length() + 31) / 32) * 32),
u256(a.length()),
a,
u256(b.length()),
b
));
ABI_CHECK(callContractFunction("a()"), encodeDyn(a));
ABI_CHECK(callContractFunction("b()"), encodeDyn(b));
}
BOOST_AUTO_TEST_CASE(constructor_static_array_argument)
{
char const* sourceCode = R"(
contract C {
uint public a;
uint[3] public b;
constructor(uint _a, uint[3] memory _b) public {
a = _a;
b = _b;
}
}
)";
compileAndRun(sourceCode, 0, "C", encodeArgs(u256(1), u256(2), u256(3), u256(4)));
ABI_CHECK(callContractFunction("a()"), encodeArgs(u256(1)));
ABI_CHECK(callContractFunction("b(uint256)", u256(0)), encodeArgs(u256(2)));
ABI_CHECK(callContractFunction("b(uint256)", u256(1)), encodeArgs(u256(3)));
ABI_CHECK(callContractFunction("b(uint256)", u256(2)), encodeArgs(u256(4)));
}
BOOST_AUTO_TEST_CASE(constant_var_as_array_length)
{
char const* sourceCode = R"(
contract C {
uint constant LEN = 3;
uint[LEN] public a;
constructor(uint[LEN] memory _a) public {
a = _a;
}
}
)";
compileAndRun(sourceCode, 0, "C", encodeArgs(u256(1), u256(2), u256(3)));
ABI_CHECK(callContractFunction("a(uint256)", u256(0)), encodeArgs(u256(1)));
ABI_CHECK(callContractFunction("a(uint256)", u256(1)), encodeArgs(u256(2)));
ABI_CHECK(callContractFunction("a(uint256)", u256(2)), encodeArgs(u256(3)));
}
BOOST_AUTO_TEST_CASE(functions_called_by_constructor)
{
char const* sourceCode = R"(
contract Test {
bytes3 name;
bool flag;
constructor() public {
setName("abc");
}
function getName() public returns (bytes3 ret) { return name; }
function setName(bytes3 _name) private { name = _name; }
}
)";
compileAndRun(sourceCode);
BOOST_REQUIRE(callContractFunction("getName()") == encodeArgs("abc"));
}
BOOST_AUTO_TEST_CASE(contracts_as_addresses)
{
char const* sourceCode = R"(
contract helper {
function() external payable { } // can receive ether
}
contract test {
helper h;
constructor() public payable { h = new helper(); address(h).send(5); }
function getBalance() public returns (uint256 myBalance, uint256 helperBalance) {
myBalance = address(this).balance;
helperBalance = address(h).balance;
}
}
)";
compileAndRun(sourceCode, 20);
BOOST_CHECK_EQUAL(balanceAt(m_contractAddress), 20 - 5);
BOOST_REQUIRE(callContractFunction("getBalance()") == encodeArgs(u256(20 - 5), u256(5)));
}
BOOST_AUTO_TEST_CASE(gas_and_value_basic)
{
char const* sourceCode = R"(
contract helper {
bool flag;
function getBalance() payable public returns (uint256 myBalance) {
return address(this).balance;
}
function setFlag() public { flag = true; }
function getFlag() public returns (bool fl) { return flag; }
}
contract test {
helper h;
constructor() public payable { h = new helper(); }
function sendAmount(uint amount) public payable returns (uint256 bal) {
return h.getBalance.value(amount)();
}
function outOfGas() public returns (bool ret) {
h.setFlag.gas(2)(); // should fail due to OOG
return true;
}
function checkState() public returns (bool flagAfter, uint myBal) {
flagAfter = h.getFlag();
myBal = address(this).balance;
}
}
)";
compileAndRun(sourceCode, 20);
BOOST_REQUIRE(callContractFunction("sendAmount(uint256)", 5) == encodeArgs(5));
// call to helper should not succeed but amount should be transferred anyway
BOOST_REQUIRE(callContractFunction("outOfGas()") == bytes());
BOOST_REQUIRE(callContractFunction("checkState()") == encodeArgs(false, 20 - 5));
}
BOOST_AUTO_TEST_CASE(gasleft_decrease)
{
char const* sourceCode = R"(
contract C {
uint v;
function f() public returns (bool) {
uint startGas = gasleft();
v++;
assert(startGas > gasleft());
return true;
}
function g() public returns (bool) {
uint startGas = gasleft();
assert(startGas > gasleft());
return true;
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("f()"), encodeArgs(true));
ABI_CHECK(callContractFunction("g()"), encodeArgs(true));
}
BOOST_AUTO_TEST_CASE(gaslimit)
{
char const* sourceCode = R"(
contract C {
function f() public returns (uint) {
return block.gaslimit;
}
}
)";
compileAndRun(sourceCode);
auto result = callContractFunction("f()");
ABI_CHECK(result, encodeArgs(gasLimit()));
}
BOOST_AUTO_TEST_CASE(gasprice)
{
char const* sourceCode = R"(
contract C {
function f() public returns (uint) {
return tx.gasprice;
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("f()"), encodeArgs(gasPrice()));
}
BOOST_AUTO_TEST_CASE(blockhash)
{
char const* sourceCode = R"(
contract C {
uint256 counter;
function g() public returns (bool) { counter++; return true; }
function f() public returns (bytes32[] memory r) {
r = new bytes32[](259);
for (uint i = 0; i < 259; i++)
r[i] = blockhash(block.number - 257 + i);
}
}
)";
compileAndRun(sourceCode);
// generate a sufficient amount of blocks
while (blockNumber() < u256(255))
ABI_CHECK(callContractFunction("g()"), encodeArgs(true));
vector<u256> hashes;
// ``blockhash()`` is only valid for the last 256 blocks, otherwise zero
hashes.emplace_back(0);
for (u256 i = blockNumber() - u256(255); i <= blockNumber(); i++)
hashes.emplace_back(blockHash(i));
// the current block hash is not yet known at execution time and therefore zero
hashes.emplace_back(0);
// future block hashes are zero
hashes.emplace_back(0);
ABI_CHECK(callContractFunction("f()"), encodeDyn(hashes));
}
BOOST_AUTO_TEST_CASE(value_complex)
{
char const* sourceCode = R"(
contract helper {
function getBalance() payable public returns (uint256 myBalance) {
return address(this).balance;
}
}
contract test {
helper h;
constructor() public payable { h = new helper(); }
function sendAmount(uint amount) public payable returns (uint256 bal) {
uint someStackElement = 20;
return h.getBalance.value(amount).gas(1000).value(amount + 3)();
}
}
)";
compileAndRun(sourceCode, 20);
BOOST_REQUIRE(callContractFunction("sendAmount(uint256)", 5) == encodeArgs(8));
}
BOOST_AUTO_TEST_CASE(value_insane)
{
char const* sourceCode = R"(
contract helper {
function getBalance() payable public returns (uint256 myBalance) {
return address(this).balance;
}
}
contract test {
helper h;
constructor() public payable { h = new helper(); }
function sendAmount(uint amount) public returns (uint256 bal) {
return h.getBalance.value(amount).gas(1000).value(amount + 3)();// overwrite value
}
}
)";
compileAndRun(sourceCode, 20);
BOOST_REQUIRE(callContractFunction("sendAmount(uint256)", 5) == encodeArgs(8));
}
BOOST_AUTO_TEST_CASE(value_for_constructor)
{
char const* sourceCode = R"(
contract Helper {
bytes3 name;
bool flag;
constructor(bytes3 x, bool f) public payable {
name = x;
flag = f;
}
function getName() public returns (bytes3 ret) { return name; }
function getFlag() public returns (bool ret) { return flag; }
}
contract Main {
Helper h;
constructor() public payable {
h = (new Helper).value(10)("abc", true);
}
function getFlag() public returns (bool ret) { return h.getFlag(); }
function getName() public returns (bytes3 ret) { return h.getName(); }
function getBalances() public returns (uint me, uint them) { me = address(this).balance; them = address(h).balance;}
}
)";
compileAndRun(sourceCode, 22, "Main");
BOOST_REQUIRE(callContractFunction("getFlag()") == encodeArgs(true));
BOOST_REQUIRE(callContractFunction("getName()") == encodeArgs("abc"));
BOOST_REQUIRE(callContractFunction("getBalances()") == encodeArgs(12, 10));
}
BOOST_AUTO_TEST_CASE(virtual_function_calls)
{
char const* sourceCode = R"(
contract Base {
function f() public returns (uint i) { return g(); }
function g() public returns (uint i) { return 1; }
}
contract Derived is Base {
function g() public returns (uint i) { return 2; }
}
)";
compileAndRun(sourceCode, 0, "Derived");
ABI_CHECK(callContractFunction("g()"), encodeArgs(2));
ABI_CHECK(callContractFunction("f()"), encodeArgs(2));
}
BOOST_AUTO_TEST_CASE(access_base_storage)
{
char const* sourceCode = R"(
contract Base {
uint dataBase;
function getViaBase() public returns (uint i) { return dataBase; }
}
contract Derived is Base {
uint dataDerived;
function setData(uint base, uint derived) public returns (bool r) {
dataBase = base;
dataDerived = derived;
return true;
}
function getViaDerived() public returns (uint base, uint derived) {
base = dataBase;
derived = dataDerived;
}
}
)";
compileAndRun(sourceCode, 0, "Derived");
ABI_CHECK(callContractFunction("setData(uint256,uint256)", 1, 2), encodeArgs(true));
ABI_CHECK(callContractFunction("getViaBase()"), encodeArgs(1));
ABI_CHECK(callContractFunction("getViaDerived()"), encodeArgs(1, 2));
}
BOOST_AUTO_TEST_CASE(single_copy_with_multiple_inheritance)
{
char const* sourceCode = R"(
contract Base {
uint data;
function setData(uint i) public { data = i; }
function getViaBase() public returns (uint i) { return data; }
}
contract A is Base { function setViaA(uint i) public { setData(i); } }
contract B is Base { function getViaB() public returns (uint i) { return getViaBase(); } }
contract Derived is Base, B, A { }
)";
compileAndRun(sourceCode, 0, "Derived");
ABI_CHECK(callContractFunction("getViaB()"), encodeArgs(0));
ABI_CHECK(callContractFunction("setViaA(uint256)", 23), encodeArgs());
ABI_CHECK(callContractFunction("getViaB()"), encodeArgs(23));
}
BOOST_AUTO_TEST_CASE(explicit_base_class)
{
char const* sourceCode = R"(
contract BaseBase { function g() public returns (uint r) { return 1; } }
contract Base is BaseBase { function g() public returns (uint r) { return 2; } }
contract Derived is Base {
function f() public returns (uint r) { return BaseBase.g(); }
function g() public returns (uint r) { return 3; }
}
)";
compileAndRun(sourceCode, 0, "Derived");
ABI_CHECK(callContractFunction("g()"), encodeArgs(3));
ABI_CHECK(callContractFunction("f()"), encodeArgs(1));
}
BOOST_AUTO_TEST_CASE(base_constructor_arguments)
{
char const* sourceCode = R"(
contract BaseBase {
uint m_a;
constructor(uint a) public {
m_a = a;
}
}
contract Base is BaseBase(7) {
constructor() public {
m_a *= m_a;
}
}
contract Derived is Base() {
function getA() public returns (uint r) { return m_a; }
}
)";
compileAndRun(sourceCode, 0, "Derived");
ABI_CHECK(callContractFunction("getA()"), encodeArgs(7 * 7));
}
BOOST_AUTO_TEST_CASE(function_usage_in_constructor_arguments)
{
char const* sourceCode = R"(
contract BaseBase {
uint m_a;
constructor(uint a) public {
m_a = a;
}
function g() public returns (uint r) { return 2; }
}
contract Base is BaseBase(BaseBase.g()) {
}
contract Derived is Base() {
function getA() public returns (uint r) { return m_a; }
}
)";
compileAndRun(sourceCode, 0, "Derived");
ABI_CHECK(callContractFunction("getA()"), encodeArgs(2));
}
BOOST_AUTO_TEST_CASE(virtual_function_usage_in_constructor_arguments)
{
char const* sourceCode = R"(
contract BaseBase {
uint m_a;
constructor(uint a) public {
m_a = a;
}
function overridden() public returns (uint r) { return 1; }
function g() public returns (uint r) { return overridden(); }
}
contract Base is BaseBase(BaseBase.g()) {
}
contract Derived is Base() {
function getA() public returns (uint r) { return m_a; }
function overridden() public returns (uint r) { return 2; }
}
)";
compileAndRun(sourceCode, 0, "Derived");
ABI_CHECK(callContractFunction("getA()"), encodeArgs(2));
}
BOOST_AUTO_TEST_CASE(internal_constructor)
{
char const* sourceCode = R"(
contract C {
constructor() internal {}
}
)";
BOOST_CHECK(compileAndRunWithoutCheck(sourceCode, 0, "C").empty());
}
BOOST_AUTO_TEST_CASE(function_modifier)
{
char const* sourceCode = R"(
contract C {
function getOne() payable nonFree public returns (uint r) { return 1; }
modifier nonFree { if (msg.value > 0) _; }
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("getOne()"), encodeArgs(0));
ABI_CHECK(callContractFunctionWithValue("getOne()", 1), encodeArgs(1));
}
BOOST_AUTO_TEST_CASE(function_modifier_local_variables)
{
char const* sourceCode = R"(
contract C {
modifier mod1 { uint8 a = 1; uint8 b = 2; _; }
modifier mod2(bool a) { if (a) return; else _; }
function f(bool a) mod1 mod2(a) public returns (uint r) { return 3; }
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("f(bool)", true), encodeArgs(0));
ABI_CHECK(callContractFunction("f(bool)", false), encodeArgs(3));
}
BOOST_AUTO_TEST_CASE(function_modifier_loop)
{
char const* sourceCode = R"(
contract C {
modifier repeat(uint count) { uint i; for (i = 0; i < count; ++i) _; }
function f() repeat(10) public returns (uint r) { r += 1; }
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("f()"), encodeArgs(10));
}
BOOST_AUTO_TEST_CASE(function_modifier_multi_invocation)
{
char const* sourceCode = R"(
contract C {
modifier repeat(bool twice) { if (twice) _; _; }
function f(bool twice) repeat(twice) public returns (uint r) { r += 1; }
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("f(bool)", false), encodeArgs(1));
ABI_CHECK(callContractFunction("f(bool)", true), encodeArgs(2));
}
BOOST_AUTO_TEST_CASE(function_modifier_multi_with_return)
{
// Note that return sets the return variable and jumps to the end of the current function or
// modifier code block.
char const* sourceCode = R"(
contract C {
modifier repeat(bool twice) { if (twice) _; _; }
function f(bool twice) repeat(twice) public returns (uint r) { r += 1; return r; }
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("f(bool)", false), encodeArgs(1));
ABI_CHECK(callContractFunction("f(bool)", true), encodeArgs(2));
}
BOOST_AUTO_TEST_CASE(function_modifier_overriding)
{
char const* sourceCode = R"(
contract A {
function f() mod public returns (bool r) { return true; }
modifier mod { _; }
}
contract C is A {
modifier mod { if (false) _; }
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("f()"), encodeArgs(false));
}
BOOST_AUTO_TEST_CASE(function_modifier_calling_functions_in_creation_context)
{
char const* sourceCode = R"(
contract A {
uint data;
constructor() mod1 public { f1(); }
function f1() mod2 public { data |= 0x1; }
function f2() public { data |= 0x20; }
function f3() public { }
modifier mod1 { f2(); _; }
modifier mod2 { f3(); if (false) _; }
function getData() public returns (uint r) { return data; }
}
contract C is A {
modifier mod1 { f4(); _; }
function f3() public { data |= 0x300; }
function f4() public { data |= 0x4000; }
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("getData()"), encodeArgs(0x4300));
}
BOOST_AUTO_TEST_CASE(function_modifier_for_constructor)
{
char const* sourceCode = R"(
contract A {
uint data;
constructor() mod1 public { data |= 2; }
modifier mod1 { data |= 1; _; }
function getData() public returns (uint r) { return data; }
}
contract C is A {
modifier mod1 { data |= 4; _; }
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("getData()"), encodeArgs(4 | 2));
}
BOOST_AUTO_TEST_CASE(function_modifier_multiple_times)
{
char const* sourceCode = R"(
contract C {
uint public a;
modifier mod(uint x) { a += x; _; }
function f(uint x) mod(2) mod(5) mod(x) public returns(uint) { return a; }
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("f(uint256)", u256(3)), encodeArgs(2 + 5 + 3));
ABI_CHECK(callContractFunction("a()"), encodeArgs(2 + 5 + 3));
}
BOOST_AUTO_TEST_CASE(function_modifier_multiple_times_local_vars)
{
char const* sourceCode = R"(
contract C {
uint public a;
modifier mod(uint x) { uint b = x; a += b; _; a -= b; assert(b == x); }
function f(uint x) mod(2) mod(5) mod(x) public returns(uint) { return a; }
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("f(uint256)", u256(3)), encodeArgs(2 + 5 + 3));
ABI_CHECK(callContractFunction("a()"), encodeArgs(0));
}
BOOST_AUTO_TEST_CASE(function_modifier_library)
{
char const* sourceCode = R"(
library L {
struct S { uint v; }
modifier mod(S storage s) { s.v++; _; }
function libFun(S storage s) mod(s) internal { s.v += 0x100; }
}
contract Test {
using L for *;
L.S s;
function f() public returns (uint) {
s.libFun();
L.libFun(s);
return s.v;
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("f()"), encodeArgs(0x202));
}
BOOST_AUTO_TEST_CASE(function_modifier_library_inheritance)
{
// Tests that virtual lookup for modifiers in libraries does not consider
// the current inheritance hierarchy.
char const* sourceCode = R"(
library L {
struct S { uint v; }
modifier mod(S storage s) { s.v++; _; }
function libFun(S storage s) mod(s) internal { s.v += 0x100; }
}
contract Test {
using L for *;
L.S s;
modifier mod(L.S storage) { revert(); _; }
function f() public returns (uint) {
s.libFun();
L.libFun(s);
return s.v;
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("f()"), encodeArgs(0x202));
}
BOOST_AUTO_TEST_CASE(crazy_elementary_typenames_on_stack)
{
char const* sourceCode = R"(
contract C {
function f() public returns (uint r) {
uint; uint; uint; uint;
int x = -7;
return uint(x);
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("f()"), encodeArgs(u256(-7)));
}
BOOST_AUTO_TEST_CASE(super)
{
char const* sourceCode = R"(
contract A { function f() public returns (uint r) { return 1; } }
contract B is A { function f() public returns (uint r) { return super.f() | 2; } }
contract C is A { function f() public returns (uint r) { return super.f() | 4; } }
contract D is B, C { function f() public returns (uint r) { return super.f() | 8; } }
)";
compileAndRun(sourceCode, 0, "D");
ABI_CHECK(callContractFunction("f()"), encodeArgs(1 | 2 | 4 | 8));
}
BOOST_AUTO_TEST_CASE(super_in_constructor)
{
char const* sourceCode = R"(
contract A { function f() public returns (uint r) { return 1; } }
contract B is A { function f() public returns (uint r) { return super.f() | 2; } }
contract C is A { function f() public returns (uint r) { return super.f() | 4; } }
contract D is B, C { uint data; constructor() public { data = super.f() | 8; } function f() public returns (uint r) { return data; } }
)";
compileAndRun(sourceCode, 0, "D");
ABI_CHECK(callContractFunction("f()"), encodeArgs(1 | 2 | 4 | 8));
}
BOOST_AUTO_TEST_CASE(super_alone)
{
char const* sourceCode = R"(
contract A { function f() public { super; } }
)";
compileAndRun(sourceCode, 0, "A");
ABI_CHECK(callContractFunction("f()"), encodeArgs());
}
BOOST_AUTO_TEST_CASE(fallback_function)
{
char const* sourceCode = R"(
contract A {
uint data;
function() external { data = 1; }
function getData() public returns (uint r) { return data; }
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("getData()"), encodeArgs(0));
ABI_CHECK(callContractFunction(""), encodeArgs());
ABI_CHECK(callContractFunction("getData()"), encodeArgs(1));
}
BOOST_AUTO_TEST_CASE(inherited_fallback_function)
{
char const* sourceCode = R"(
contract A {
uint data;
function() external { data = 1; }
function getData() public returns (uint r) { return data; }
}
contract B is A {}
)";
compileAndRun(sourceCode, 0, "B");
ABI_CHECK(callContractFunction("getData()"), encodeArgs(0));
ABI_CHECK(callContractFunction(""), encodeArgs());
ABI_CHECK(callContractFunction("getData()"), encodeArgs(1));
}
BOOST_AUTO_TEST_CASE(default_fallback_throws)
{
char const* sourceCode = R"YY(
contract A {
function f() public returns (bool) {
(bool success,) = address(this).call("");
return success;
}
}
)YY";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("f()"), encodeArgs(0));
if (dev::test::Options::get().evmVersion().hasStaticCall())
{
char const* sourceCode = R"YY(
contract A {
function f() public returns (bool) {
(bool success, bytes memory data) = address(this).staticcall("");
assert(data.length == 0);
return success;
}
}
)YY";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("f()"), encodeArgs(0));
}
}
BOOST_AUTO_TEST_CASE(short_data_calls_fallback)
{
char const* sourceCode = R"(
contract A {
uint public x;
// Signature is d88e0b00
function fow() public { x = 3; }
function () external { x = 2; }
}
)";
compileAndRun(sourceCode);
// should call fallback
sendMessage(asBytes("\xd8\x8e\x0b"), false, 0);
BOOST_CHECK(m_transactionSuccessful);
ABI_CHECK(callContractFunction("x()"), encodeArgs(2));
// should call function
sendMessage(asBytes(string("\xd8\x8e\x0b") + string(1, 0)), false, 0);
BOOST_CHECK(m_transactionSuccessful);
ABI_CHECK(callContractFunction("x()"), encodeArgs(3));
}
BOOST_AUTO_TEST_CASE(event)
{
char const* sourceCode = R"(
contract ClientReceipt {
event Deposit(address indexed _from, bytes32 indexed _id, uint _value);
function deposit(bytes32 _id, bool _manually) public payable {
if (_manually) {
bytes32 s = 0x19dacbf83c5de6658e14cbf7bcae5c15eca2eedecf1c66fbca928e4d351bea0f;
log3(bytes32(msg.value), s, bytes32(uint256(msg.sender)), _id);
} else {
emit Deposit(msg.sender, _id, msg.value);
}
}
}
)";
compileAndRun(sourceCode);
u256 value(18);
u256 id(0x1234);
for (bool manually: {true, false})
{
callContractFunctionWithValue("deposit(bytes32,bool)", value, id, manually);
BOOST_REQUIRE_EQUAL(m_logs.size(), 1);
BOOST_CHECK_EQUAL(m_logs[0].address, m_contractAddress);
BOOST_CHECK_EQUAL(h256(m_logs[0].data), h256(u256(value)));
BOOST_REQUIRE_EQUAL(m_logs[0].topics.size(), 3);
BOOST_CHECK_EQUAL(m_logs[0].topics[0], dev::keccak256(string("Deposit(address,bytes32,uint256)")));
BOOST_CHECK_EQUAL(m_logs[0].topics[1], h256(m_sender, h256::AlignRight));
BOOST_CHECK_EQUAL(m_logs[0].topics[2], h256(id));
}
}
BOOST_AUTO_TEST_CASE(event_emit)
{
char const* sourceCode = R"(
contract ClientReceipt {
event Deposit(address indexed _from, bytes32 indexed _id, uint _value);
function deposit(bytes32 _id) public payable {
emit Deposit(msg.sender, _id, msg.value);
}
}
)";
compileAndRun(sourceCode);
u256 value(18);
u256 id(0x1234);
callContractFunctionWithValue("deposit(bytes32)", value, id);
BOOST_REQUIRE_EQUAL(m_logs.size(), 1);
BOOST_CHECK_EQUAL(m_logs[0].address, m_contractAddress);
BOOST_CHECK_EQUAL(h256(m_logs[0].data), h256(u256(value)));
BOOST_REQUIRE_EQUAL(m_logs[0].topics.size(), 3);
BOOST_CHECK_EQUAL(m_logs[0].topics[0], dev::keccak256(string("Deposit(address,bytes32,uint256)")));
BOOST_CHECK_EQUAL(m_logs[0].topics[1], h256(m_sender, h256::AlignRight));
BOOST_CHECK_EQUAL(m_logs[0].topics[2], h256(id));
}
BOOST_AUTO_TEST_CASE(event_no_arguments)
{
char const* sourceCode = R"(
contract ClientReceipt {
event Deposit();
function deposit() public {
emit Deposit();
}
}
)";
compileAndRun(sourceCode);
callContractFunction("deposit()");
BOOST_REQUIRE_EQUAL(m_logs.size(), 1);
BOOST_CHECK_EQUAL(m_logs[0].address, m_contractAddress);
BOOST_CHECK(m_logs[0].data.empty());
BOOST_REQUIRE_EQUAL(m_logs[0].topics.size(), 1);
BOOST_CHECK_EQUAL(m_logs[0].topics[0], dev::keccak256(string("Deposit()")));
}
BOOST_AUTO_TEST_CASE(event_access_through_base_name_emit)
{
char const* sourceCode = R"(
contract A {
event x();
}
contract B is A {
function f() public returns (uint) {
emit A.x();
return 1;
}
}
)";
compileAndRun(sourceCode);
callContractFunction("f()");
BOOST_REQUIRE_EQUAL(m_logs.size(), 1);
BOOST_CHECK_EQUAL(m_logs[0].address, m_contractAddress);
BOOST_CHECK(m_logs[0].data.empty());
BOOST_REQUIRE_EQUAL(m_logs[0].topics.size(), 1);
BOOST_CHECK_EQUAL(m_logs[0].topics[0], dev::keccak256(string("x()")));
}
BOOST_AUTO_TEST_CASE(events_with_same_name)
{
char const* sourceCode = R"(
contract ClientReceipt {
event Deposit();
event Deposit(address _addr);
event Deposit(address _addr, uint _amount);
event Deposit(address _addr, bool _flag);
function deposit() public returns (uint) {
emit Deposit();
return 1;
}
function deposit(address _addr) public returns (uint) {
emit Deposit(_addr);
return 2;
}
function deposit(address _addr, uint _amount) public returns (uint) {
emit Deposit(_addr, _amount);
return 3;
}
function deposit(address _addr, bool _flag) public returns (uint) {
emit Deposit(_addr, _flag);
return 4;
}
}
)";
u160 const c_loggedAddress = m_contractAddress;
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("deposit()"), encodeArgs(u256(1)));
BOOST_REQUIRE_EQUAL(m_logs.size(), 1);
BOOST_CHECK_EQUAL(m_logs[0].address, m_contractAddress);
BOOST_CHECK(m_logs[0].data.empty());
BOOST_REQUIRE_EQUAL(m_logs[0].topics.size(), 1);
BOOST_CHECK_EQUAL(m_logs[0].topics[0], dev::keccak256(string("Deposit()")));
ABI_CHECK(callContractFunction("deposit(address)", c_loggedAddress), encodeArgs(u256(2)));
BOOST_REQUIRE_EQUAL(m_logs.size(), 1);
BOOST_CHECK_EQUAL(m_logs[0].address, m_contractAddress);
BOOST_CHECK(m_logs[0].data == encodeArgs(c_loggedAddress));
BOOST_REQUIRE_EQUAL(m_logs[0].topics.size(), 1);
BOOST_CHECK_EQUAL(m_logs[0].topics[0], dev::keccak256(string("Deposit(address)")));
ABI_CHECK(callContractFunction("deposit(address,uint256)", c_loggedAddress, u256(100)), encodeArgs(u256(3)));
BOOST_REQUIRE_EQUAL(m_logs.size(), 1);
BOOST_CHECK_EQUAL(m_logs[0].address, m_contractAddress);
BOOST_CHECK(m_logs[0].data == encodeArgs(c_loggedAddress, 100));
BOOST_REQUIRE_EQUAL(m_logs[0].topics.size(), 1);
BOOST_CHECK_EQUAL(m_logs[0].topics[0], dev::keccak256(string("Deposit(address,uint256)")));
ABI_CHECK(callContractFunction("deposit(address,bool)", c_loggedAddress, false), encodeArgs(u256(4)));
BOOST_REQUIRE_EQUAL(m_logs.size(), 1);
BOOST_CHECK_EQUAL(m_logs[0].address, m_contractAddress);
BOOST_CHECK(m_logs[0].data == encodeArgs(c_loggedAddress, false));
BOOST_REQUIRE_EQUAL(m_logs[0].topics.size(), 1);
BOOST_CHECK_EQUAL(m_logs[0].topics[0], dev::keccak256(string("Deposit(address,bool)")));
}
BOOST_AUTO_TEST_CASE(events_with_same_name_inherited_emit)
{
char const* sourceCode = R"(
contract A {
event Deposit();
}
contract B {
event Deposit(address _addr);
}
contract ClientReceipt is A, B {
event Deposit(address _addr, uint _amount);
function deposit() public returns (uint) {
emit Deposit();
return 1;
}
function deposit(address _addr) public returns (uint) {
emit Deposit(_addr);
return 1;
}
function deposit(address _addr, uint _amount) public returns (uint) {
emit Deposit(_addr, _amount);
return 1;
}
}
)";
u160 const c_loggedAddress = m_contractAddress;
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("deposit()"), encodeArgs(u256(1)));
BOOST_REQUIRE_EQUAL(m_logs.size(), 1);
BOOST_CHECK_EQUAL(m_logs[0].address, m_contractAddress);
BOOST_CHECK(m_logs[0].data.empty());
BOOST_REQUIRE_EQUAL(m_logs[0].topics.size(), 1);
BOOST_CHECK_EQUAL(m_logs[0].topics[0], dev::keccak256(string("Deposit()")));
ABI_CHECK(callContractFunction("deposit(address)", c_loggedAddress), encodeArgs(u256(1)));
BOOST_REQUIRE_EQUAL(m_logs.size(), 1);
BOOST_CHECK_EQUAL(m_logs[0].address, m_contractAddress);
BOOST_CHECK(m_logs[0].data == encodeArgs(c_loggedAddress));
BOOST_REQUIRE_EQUAL(m_logs[0].topics.size(), 1);
BOOST_CHECK_EQUAL(m_logs[0].topics[0], dev::keccak256(string("Deposit(address)")));
ABI_CHECK(callContractFunction("deposit(address,uint256)", c_loggedAddress, u256(100)), encodeArgs(u256(1)));
BOOST_REQUIRE_EQUAL(m_logs.size(), 1);
BOOST_CHECK_EQUAL(m_logs[0].address, m_contractAddress);
BOOST_CHECK(m_logs[0].data == encodeArgs(c_loggedAddress, 100));
BOOST_REQUIRE_EQUAL(m_logs[0].topics.size(), 1);
BOOST_CHECK_EQUAL(m_logs[0].topics[0], dev::keccak256(string("Deposit(address,uint256)")));
}
BOOST_AUTO_TEST_CASE(event_anonymous)
{
char const* sourceCode = R"(
contract ClientReceipt {
event Deposit() anonymous;
function deposit() public {
emit Deposit();
}
}
)";
compileAndRun(sourceCode);
callContractFunction("deposit()");
BOOST_REQUIRE_EQUAL(m_logs[0].topics.size(), 0);
}
BOOST_AUTO_TEST_CASE(event_anonymous_with_topics)
{
char const* sourceCode = R"(
contract ClientReceipt {
event Deposit(address indexed _from, bytes32 indexed _id, uint indexed _value, uint indexed _value2, bytes32 data) anonymous;
function deposit(bytes32 _id) public payable {
emit Deposit(msg.sender, _id, msg.value, 2, "abc");
}
}
)";
compileAndRun(sourceCode);
u256 value(18);
u256 id(0x1234);
callContractFunctionWithValue("deposit(bytes32)", value, id);
BOOST_REQUIRE_EQUAL(m_logs.size(), 1);
BOOST_CHECK_EQUAL(m_logs[0].address, m_contractAddress);
BOOST_CHECK(m_logs[0].data == encodeArgs("abc"));
BOOST_REQUIRE_EQUAL(m_logs[0].topics.size(), 4);
BOOST_CHECK_EQUAL(m_logs[0].topics[0], h256(m_sender, h256::AlignRight));
BOOST_CHECK_EQUAL(m_logs[0].topics[1], h256(id));
BOOST_CHECK_EQUAL(m_logs[0].topics[2], h256(value));
BOOST_CHECK_EQUAL(m_logs[0].topics[3], h256(2));
}
BOOST_AUTO_TEST_CASE(event_lots_of_data)
{
char const* sourceCode = R"(
contract ClientReceipt {
event Deposit(address _from, bytes32 _id, uint _value, bool _flag);
function deposit(bytes32 _id) public payable {
emit Deposit(msg.sender, _id, msg.value, true);
}
}
)";
compileAndRun(sourceCode);
u256 value(18);
u256 id(0x1234);
callContractFunctionWithValue("deposit(bytes32)", value, id);
BOOST_REQUIRE_EQUAL(m_logs.size(), 1);
BOOST_CHECK_EQUAL(m_logs[0].address, m_contractAddress);
BOOST_CHECK(m_logs[0].data == encodeArgs((u160)m_sender, id, value, true));
BOOST_REQUIRE_EQUAL(m_logs[0].topics.size(), 1);
BOOST_CHECK_EQUAL(m_logs[0].topics[0], dev::keccak256(string("Deposit(address,bytes32,uint256,bool)")));
}
BOOST_AUTO_TEST_CASE(event_really_lots_of_data)
{
char const* sourceCode = R"(
contract ClientReceipt {
event Deposit(uint fixeda, bytes dynx, uint fixedb);
function deposit() public {
emit Deposit(10, msg.data, 15);
}
}
)";
compileAndRun(sourceCode);
callContractFunction("deposit()");
BOOST_REQUIRE_EQUAL(m_logs.size(), 1);
BOOST_CHECK_EQUAL(m_logs[0].address, m_contractAddress);
BOOST_CHECK_EQUAL(toHex(m_logs[0].data), toHex(encodeArgs(10, 0x60, 15, 4, asString(FixedHash<4>(dev::keccak256("deposit()")).asBytes()))));
BOOST_REQUIRE_EQUAL(m_logs[0].topics.size(), 1);
BOOST_CHECK_EQUAL(m_logs[0].topics[0], dev::keccak256(string("Deposit(uint256,bytes,uint256)")));
}
BOOST_AUTO_TEST_CASE(event_really_lots_of_data_from_storage)
{
char const* sourceCode = R"(
contract ClientReceipt {
bytes x;
event Deposit(uint fixeda, bytes dynx, uint fixedb);
function deposit() public {
x.length = 3;
x[0] = "A";
x[1] = "B";
x[2] = "C";
emit Deposit(10, x, 15);
}
}
)";
compileAndRun(sourceCode);
callContractFunction("deposit()");
BOOST_REQUIRE_EQUAL(m_logs.size(), 1);
BOOST_CHECK_EQUAL(m_logs[0].address, m_contractAddress);
BOOST_CHECK_EQUAL(toHex(m_logs[0].data), toHex(encodeArgs(10, 0x60, 15, 3, string("ABC"))));
BOOST_REQUIRE_EQUAL(m_logs[0].topics.size(), 1);
BOOST_CHECK_EQUAL(m_logs[0].topics[0], dev::keccak256(string("Deposit(uint256,bytes,uint256)")));
}
BOOST_AUTO_TEST_CASE(event_really_really_lots_of_data_from_storage)
{
char const* sourceCode = R"(
contract ClientReceipt {
bytes x;
event Deposit(uint fixeda, bytes dynx, uint fixedb);
function deposit() public {
x.length = 31;
x[0] = "A";
x[1] = "B";
x[2] = "C";
x[30] = "Z";
emit Deposit(10, x, 15);
}
}
)";
compileAndRun(sourceCode);
callContractFunction("deposit()");
BOOST_REQUIRE_EQUAL(m_logs.size(), 1);
BOOST_CHECK_EQUAL(m_logs[0].address, m_contractAddress);
BOOST_CHECK(m_logs[0].data == encodeArgs(10, 0x60, 15, 31, string("ABC") + string(27, 0) + "Z"));
BOOST_REQUIRE_EQUAL(m_logs[0].topics.size(), 1);
BOOST_CHECK_EQUAL(m_logs[0].topics[0], dev::keccak256(string("Deposit(uint256,bytes,uint256)")));
}
BOOST_AUTO_TEST_CASE(event_struct_memory_v2)
{
char const* sourceCode = R"(
pragma experimental ABIEncoderV2;
contract C {
struct S { uint a; }
event E(S);
function createEvent(uint x) public {
emit E(S(x));
}
}
)";
compileAndRun(sourceCode);
u256 x(42);
callContractFunction("createEvent(uint256)", x);
BOOST_REQUIRE_EQUAL(m_logs.size(), 1);
BOOST_CHECK_EQUAL(m_logs[0].address, m_contractAddress);
BOOST_CHECK(m_logs[0].data == encodeArgs(x));
BOOST_REQUIRE_EQUAL(m_logs[0].topics.size(), 1);
BOOST_CHECK_EQUAL(m_logs[0].topics[0], dev::keccak256(string("E((uint256))")));
}
BOOST_AUTO_TEST_CASE(event_struct_storage_v2)
{
char const* sourceCode = R"(
pragma experimental ABIEncoderV2;
contract C {
struct S { uint a; }
event E(S);
S s;
function createEvent(uint x) public {
s.a = x;
emit E(s);
}
}
)";
compileAndRun(sourceCode);
u256 x(42);
callContractFunction("createEvent(uint256)", x);
BOOST_REQUIRE_EQUAL(m_logs.size(), 1);
BOOST_CHECK_EQUAL(m_logs[0].address, m_contractAddress);
BOOST_CHECK(m_logs[0].data == encodeArgs(x));
BOOST_REQUIRE_EQUAL(m_logs[0].topics.size(), 1);
BOOST_CHECK_EQUAL(m_logs[0].topics[0], dev::keccak256(string("E((uint256))")));
}
BOOST_AUTO_TEST_CASE(event_dynamic_array_memory)
{
char const* sourceCode = R"(
contract C {
event E(uint[]);
function createEvent(uint x) public {
uint[] memory arr = new uint[](3);
arr[0] = x;
arr[1] = x + 1;
arr[2] = x + 2;
emit E(arr);
}
}
)";
compileAndRun(sourceCode);
u256 x(42);
callContractFunction("createEvent(uint256)", x);
BOOST_REQUIRE_EQUAL(m_logs.size(), 1);
BOOST_CHECK_EQUAL(m_logs[0].address, m_contractAddress);
BOOST_CHECK(m_logs[0].data == encodeArgs(0x20, 3, x, x + 1, x + 2));
BOOST_REQUIRE_EQUAL(m_logs[0].topics.size(), 1);
BOOST_CHECK_EQUAL(m_logs[0].topics[0], dev::keccak256(string("E(uint256[])")));
}
BOOST_AUTO_TEST_CASE(event_dynamic_array_memory_v2)
{
char const* sourceCode = R"(
pragma experimental ABIEncoderV2;
contract C {
event E(uint[]);
function createEvent(uint x) public {
uint[] memory arr = new uint[](3);
arr[0] = x;
arr[1] = x + 1;
arr[2] = x + 2;
emit E(arr);
}
}
)";
compileAndRun(sourceCode);
u256 x(42);
callContractFunction("createEvent(uint256)", x);
BOOST_REQUIRE_EQUAL(m_logs.size(), 1);
BOOST_CHECK_EQUAL(m_logs[0].address, m_contractAddress);
BOOST_CHECK(m_logs[0].data == encodeArgs(0x20, 3, x, x + 1, x + 2));
BOOST_REQUIRE_EQUAL(m_logs[0].topics.size(), 1);
BOOST_CHECK_EQUAL(m_logs[0].topics[0], dev::keccak256(string("E(uint256[])")));
}
BOOST_AUTO_TEST_CASE(event_dynamic_nested_array_memory_v2)
{
char const* sourceCode = R"(
pragma experimental ABIEncoderV2;
contract C {
event E(uint[][]);
function createEvent(uint x) public {
uint[][] memory arr = new uint[][](2);
arr[0] = new uint[](2);
arr[1] = new uint[](2);
arr[0][0] = x;
arr[0][1] = x + 1;
arr[1][0] = x + 2;
arr[1][1] = x + 3;
emit E(arr);
}
}
)";
compileAndRun(sourceCode);
u256 x(42);
callContractFunction("createEvent(uint256)", x);
BOOST_REQUIRE_EQUAL(m_logs.size(), 1);
BOOST_CHECK_EQUAL(m_logs[0].address, m_contractAddress);
BOOST_CHECK(m_logs[0].data == encodeArgs(0x20, 2, 0x40, 0xa0, 2, x, x + 1, 2, x + 2, x + 3));
BOOST_REQUIRE_EQUAL(m_logs[0].topics.size(), 1);
BOOST_CHECK_EQUAL(m_logs[0].topics[0], dev::keccak256(string("E(uint256[][])")));
}
BOOST_AUTO_TEST_CASE(event_dynamic_array_storage)
{
char const* sourceCode = R"(
contract C {
event E(uint[]);
uint[] arr;
function createEvent(uint x) public {
arr.length = 3;
arr[0] = x;
arr[1] = x + 1;
arr[2] = x + 2;
emit E(arr);
}
}
)";
compileAndRun(sourceCode);
u256 x(42);
callContractFunction("createEvent(uint256)", x);
BOOST_REQUIRE_EQUAL(m_logs.size(), 1);
BOOST_CHECK_EQUAL(m_logs[0].address, m_contractAddress);
BOOST_CHECK(m_logs[0].data == encodeArgs(0x20, 3, x, x + 1, x + 2));
BOOST_REQUIRE_EQUAL(m_logs[0].topics.size(), 1);
BOOST_CHECK_EQUAL(m_logs[0].topics[0], dev::keccak256(string("E(uint256[])")));
}
BOOST_AUTO_TEST_CASE(event_dynamic_array_storage_v2)
{
char const* sourceCode = R"(
pragma experimental ABIEncoderV2;
contract C {
event E(uint[]);
uint[] arr;
function createEvent(uint x) public {
arr.length = 3;
arr[0] = x;
arr[1] = x + 1;
arr[2] = x + 2;
emit E(arr);
}
}
)";
compileAndRun(sourceCode);
u256 x(42);
callContractFunction("createEvent(uint256)", x);
BOOST_REQUIRE_EQUAL(m_logs.size(), 1);
BOOST_CHECK_EQUAL(m_logs[0].address, m_contractAddress);
BOOST_CHECK(m_logs[0].data == encodeArgs(0x20, 3, x, x + 1, x + 2));
BOOST_REQUIRE_EQUAL(m_logs[0].topics.size(), 1);
BOOST_CHECK_EQUAL(m_logs[0].topics[0], dev::keccak256(string("E(uint256[])")));
}
BOOST_AUTO_TEST_CASE(event_dynamic_nested_array_storage_v2)
{
char const* sourceCode = R"(
pragma experimental ABIEncoderV2;
contract C {
event E(uint[][]);
uint[][] arr;
function createEvent(uint x) public {
arr.length = 2;
arr[0].length = 2;
arr[1].length = 2;
arr[0][0] = x;
arr[0][1] = x + 1;
arr[1][0] = x + 2;
arr[1][1] = x + 3;
emit E(arr);
}
}
)";
compileAndRun(sourceCode);
u256 x(42);
callContractFunction("createEvent(uint256)", x);
BOOST_REQUIRE_EQUAL(m_logs.size(), 1);
BOOST_CHECK_EQUAL(m_logs[0].address, m_contractAddress);
BOOST_CHECK(m_logs[0].data == encodeArgs(0x20, 2, 0x40, 0xa0, 2, x, x + 1, 2, x + 2, x + 3));
BOOST_REQUIRE_EQUAL(m_logs[0].topics.size(), 1);
BOOST_CHECK_EQUAL(m_logs[0].topics[0], dev::keccak256(string("E(uint256[][])")));
}
BOOST_AUTO_TEST_CASE(event_indexed_string)
{
char const* sourceCode = R"(
contract C {
string x;
uint[4] y;
event E(string indexed r, uint[4] indexed t);
function deposit() public {
bytes(x).length = 90;
for (uint8 i = 0; i < 90; i++)
bytes(x)[i] = byte(i);
y[0] = 4;
y[1] = 5;
y[2] = 6;
y[3] = 7;
emit E(x, y);
}
}
)";
compileAndRun(sourceCode);
callContractFunction("deposit()");
BOOST_REQUIRE_EQUAL(m_logs.size(), 1);
BOOST_CHECK_EQUAL(m_logs[0].address, m_contractAddress);
string dynx(90, 0);
for (size_t i = 0; i < dynx.size(); ++i)
dynx[i] = i;
BOOST_CHECK(m_logs[0].data == bytes());
BOOST_REQUIRE_EQUAL(m_logs[0].topics.size(), 3);
BOOST_CHECK_EQUAL(m_logs[0].topics[1], dev::keccak256(dynx));
BOOST_CHECK_EQUAL(m_logs[0].topics[2], dev::keccak256(
encodeArgs(u256(4), u256(5), u256(6), u256(7))
));
BOOST_CHECK_EQUAL(m_logs[0].topics[0], dev::keccak256(string("E(string,uint256[4])")));
}
BOOST_AUTO_TEST_CASE(empty_name_input_parameter_with_named_one)
{
char const* sourceCode = R"(
contract test {
function f(uint, uint k) public returns(uint ret_k, uint ret_g){
uint g = 8;
ret_k = k;
ret_g = g;
}
}
)";
compileAndRun(sourceCode);
BOOST_CHECK(callContractFunction("f(uint256,uint256)", 5, 9) != encodeArgs(5, 8));
ABI_CHECK(callContractFunction("f(uint256,uint256)", 5, 9), encodeArgs(9, 8));
}
BOOST_AUTO_TEST_CASE(empty_name_return_parameter)
{
char const* sourceCode = R"(
contract test {
function f(uint k) public returns(uint){
return k;
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("f(uint256)", 9), encodeArgs(9));
}
BOOST_AUTO_TEST_CASE(sha256_empty)
{
char const* sourceCode = R"(
contract C {
function f() public returns (bytes32) {
return sha256("");
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("f()"), fromHex("0xe3b0c44298fc1c149afbf4c8996fb92427ae41e4649b934ca495991b7852b855"));
}
BOOST_AUTO_TEST_CASE(ripemd160_empty)
{
char const* sourceCode = R"(
contract C {
function f() public returns (bytes20) {
return ripemd160("");
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("f()"), fromHex("0x9c1185a5c5e9fc54612808977ee8f548b2258d31000000000000000000000000"));
}
BOOST_AUTO_TEST_CASE(keccak256_empty)
{
char const* sourceCode = R"(
contract C {
function f() public returns (bytes32) {
return keccak256("");
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("f()"), fromHex("0xc5d2460186f7233c927e7db2dcc703c0e500b653ca82273b7bfad8045d85a470"));
}
BOOST_AUTO_TEST_CASE(keccak256_multiple_arguments)
{
char const* sourceCode = R"(
contract c {
function foo(uint a, uint b, uint c) public returns (bytes32 d)
{
d = keccak256(abi.encodePacked(a, b, c));
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("foo(uint256,uint256,uint256)", 10, 12, 13), encodeArgs(
dev::keccak256(
toBigEndian(u256(10)) +
toBigEndian(u256(12)) +
toBigEndian(u256(13))
)
));
}
BOOST_AUTO_TEST_CASE(keccak256_multiple_arguments_with_numeric_literals)
{
char const* sourceCode = R"(
contract c {
function foo(uint a, uint16 b) public returns (bytes32 d)
{
d = keccak256(abi.encodePacked(a, b, uint8(145)));
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("foo(uint256,uint16)", 10, 12), encodeArgs(
dev::keccak256(
toBigEndian(u256(10)) +
bytes{0x0, 0xc} +
bytes(1, 0x91)
)
));
}
BOOST_AUTO_TEST_CASE(keccak256_multiple_arguments_with_string_literals)
{
char const* sourceCode = R"(
contract c {
function foo() public returns (bytes32 d)
{
d = keccak256("foo");
}
function bar(uint a, uint16 b) public returns (bytes32 d)
{
d = keccak256(abi.encodePacked(a, b, uint8(145), "foo"));
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("foo()"), encodeArgs(dev::keccak256("foo")));
ABI_CHECK(callContractFunction("bar(uint256,uint16)", 10, 12), encodeArgs(
dev::keccak256(
toBigEndian(u256(10)) +
bytes{0x0, 0xc} +
bytes(1, 0x91) +
bytes{0x66, 0x6f, 0x6f}
)
));
}
BOOST_AUTO_TEST_CASE(keccak256_with_bytes)
{
char const* sourceCode = R"(
contract c {
bytes data;
function foo() public returns (bool)
{
data.length = 3;
data[0] = "f";
data[1] = "o";
data[2] = "o";
return keccak256(data) == keccak256("foo");
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("foo()"), encodeArgs(true));
}
BOOST_AUTO_TEST_CASE(iterated_keccak256_with_bytes)
{
char const* sourceCode = R"ABC(
contract c {
bytes data;
function foo() public returns (bytes32)
{
data.length = 3;
data[0] = "x";
data[1] = "y";
data[2] = "z";
return keccak256(abi.encodePacked("b", keccak256(data), "a"));
}
}
)ABC";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("foo()"), encodeArgs(
u256(dev::keccak256(bytes{'b'} + dev::keccak256("xyz").asBytes() + bytes{'a'}))
));
}
BOOST_AUTO_TEST_CASE(generic_call)
{
char const* sourceCode = R"**(
contract receiver {
uint public received;
function receive(uint256 x) public payable { received = x; }
}
contract sender {
constructor() public payable {}
function doSend(address rec) public returns (uint d)
{
bytes4 signature = bytes4(bytes32(keccak256("receive(uint256)")));
rec.call.value(2)(abi.encodeWithSelector(signature, 23));
return receiver(rec).received();
}
}
)**";
compileAndRun(sourceCode, 0, "receiver");
u160 const c_receiverAddress = m_contractAddress;
compileAndRun(sourceCode, 50, "sender");
BOOST_REQUIRE(callContractFunction("doSend(address)", c_receiverAddress) == encodeArgs(23));
BOOST_CHECK_EQUAL(balanceAt(m_contractAddress), 50 - 2);
}
BOOST_AUTO_TEST_CASE(generic_delegatecall)
{
char const* sourceCode = R"**(
contract Receiver {
uint public received;
address public sender;
uint public value;
constructor() public payable {}
function receive(uint256 x) public payable { received = x; sender = msg.sender; value = msg.value; }
}
contract Sender {
uint public received;
address public sender;
uint public value;
constructor() public payable {}
function doSend(address rec) public payable
{
bytes4 signature = bytes4(bytes32(keccak256("receive(uint256)")));
(bool success,) = rec.delegatecall(abi.encodeWithSelector(signature, 23));
success;
}
}
)**";
for (auto v2: {false, true})
{
string source = (v2 ? "pragma experimental ABIEncoderV2;\n" : "") + string(sourceCode);
compileAndRun(source, 0, "Receiver");
u160 const c_receiverAddress = m_contractAddress;
compileAndRun(source, 50, "Sender");
u160 const c_senderAddress = m_contractAddress;
BOOST_CHECK(m_sender != c_senderAddress); // just for sanity
ABI_CHECK(callContractFunctionWithValue("doSend(address)", 11, c_receiverAddress), encodeArgs());
ABI_CHECK(callContractFunction("received()"), encodeArgs(u256(23)));
ABI_CHECK(callContractFunction("sender()"), encodeArgs(u160(m_sender)));
ABI_CHECK(callContractFunction("value()"), encodeArgs(u256(11)));
m_contractAddress = c_receiverAddress;
ABI_CHECK(callContractFunction("received()"), encodeArgs(u256(0)));
ABI_CHECK(callContractFunction("sender()"), encodeArgs(u256(0)));
ABI_CHECK(callContractFunction("value()"), encodeArgs(u256(0)));
BOOST_CHECK(storageEmpty(c_receiverAddress));
BOOST_CHECK(!storageEmpty(c_senderAddress));
BOOST_CHECK_EQUAL(balanceAt(c_receiverAddress), 0);
BOOST_CHECK_EQUAL(balanceAt(c_senderAddress), 50 + 11);
}
}
BOOST_AUTO_TEST_CASE(generic_staticcall)
{
if (dev::test::Options::get().evmVersion().hasStaticCall())
{
char const* sourceCode = R"**(
contract A {
uint public x;
constructor() public { x = 42; }
function pureFunction(uint256 p) public pure returns (uint256) { return p; }
function viewFunction(uint256 p) public view returns (uint256) { return p + x; }
function nonpayableFunction(uint256 p) public returns (uint256) { x = p; return x; }
function assertFunction(uint256 p) public view returns (uint256) { assert(x == p); return x; }
}
contract C {
function f(address a) public view returns (bool, bytes memory)
{
return a.staticcall(abi.encodeWithSignature("pureFunction(uint256)", 23));
}
function g(address a) public view returns (bool, bytes memory)
{
return a.staticcall(abi.encodeWithSignature("viewFunction(uint256)", 23));
}
function h(address a) public view returns (bool, bytes memory)
{
return a.staticcall(abi.encodeWithSignature("nonpayableFunction(uint256)", 23));
}
function i(address a, uint256 v) public view returns (bool, bytes memory)
{
return a.staticcall(abi.encodeWithSignature("assertFunction(uint256)", v));
}
}
)**";
compileAndRun(sourceCode, 0, "A");
u160 const c_addressA = m_contractAddress;
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("f(address)", c_addressA), encodeArgs(true, 0x40, 0x20, 23));
ABI_CHECK(callContractFunction("g(address)", c_addressA), encodeArgs(true, 0x40, 0x20, 23 + 42));
ABI_CHECK(callContractFunction("h(address)", c_addressA), encodeArgs(false, 0x40, 0x00));
ABI_CHECK(callContractFunction("i(address,uint256)", c_addressA, 42), encodeArgs(true, 0x40, 0x20, 42));
ABI_CHECK(callContractFunction("i(address,uint256)", c_addressA, 23), encodeArgs(false, 0x40, 0x00));
}
}
BOOST_AUTO_TEST_CASE(library_call_in_homestead)
{
char const* sourceCode = R"(
library Lib { function m() public returns (address) { return msg.sender; } }
contract Test {
address public sender;
function f() public {
sender = Lib.m();
}
}
)";
compileAndRun(sourceCode, 0, "Lib");
compileAndRun(sourceCode, 0, "Test", bytes(), map<string, Address>{{"Lib", m_contractAddress}});
ABI_CHECK(callContractFunction("f()"), encodeArgs());
ABI_CHECK(callContractFunction("sender()"), encodeArgs(u160(m_sender)));
}
BOOST_AUTO_TEST_CASE(library_call_protection)
{
// This tests code that reverts a call if it is a direct call to a library
// as opposed to a delegatecall.
char const* sourceCode = R"(
library Lib {
struct S { uint x; }
// a direct call to this should revert
function np(S storage s) public returns (address) { s.x = 3; return msg.sender; }
// a direct call to this is fine
function v(S storage) public view returns (address) { return msg.sender; }
// a direct call to this is fine
function pu() public pure returns (uint) { return 2; }
}
contract Test {
Lib.S public s;
function np() public returns (address) { return Lib.np(s); }
function v() public view returns (address) { return Lib.v(s); }
function pu() public pure returns (uint) { return Lib.pu(); }
}
)";
compileAndRun(sourceCode, 0, "Lib");
ABI_CHECK(callContractFunction("np(Lib.S storage)", 0), encodeArgs());
ABI_CHECK(callContractFunction("v(Lib.S storage)", 0), encodeArgs(u160(m_sender)));
ABI_CHECK(callContractFunction("pu()"), encodeArgs(2));
compileAndRun(sourceCode, 0, "Test", bytes(), map<string, Address>{{"Lib", m_contractAddress}});
ABI_CHECK(callContractFunction("s()"), encodeArgs(0));
ABI_CHECK(callContractFunction("np()"), encodeArgs(u160(m_sender)));
ABI_CHECK(callContractFunction("s()"), encodeArgs(3));
ABI_CHECK(callContractFunction("v()"), encodeArgs(u160(m_sender)));
ABI_CHECK(callContractFunction("pu()"), encodeArgs(2));
}
BOOST_AUTO_TEST_CASE(library_staticcall_delegatecall)
{
char const* sourceCode = R"(
library Lib {
function x() public view returns (uint) {
return 1;
}
}
contract Test {
uint t;
function f() public returns (uint) {
t = 2;
return this.g();
}
function g() public view returns (uint) {
return Lib.x();
}
}
)";
compileAndRun(sourceCode, 0, "Lib");
compileAndRun(sourceCode, 0, "Test", bytes(), map<string, Address>{{"Lib", m_contractAddress}});
ABI_CHECK(callContractFunction("f()"), encodeArgs(1));
}
BOOST_AUTO_TEST_CASE(store_bytes)
{
// this test just checks that the copy loop does not mess up the stack
char const* sourceCode = R"(
contract C {
function save() public returns (uint r) {
r = 23;
savedData = msg.data;
r = 24;
}
bytes savedData;
}
)";
compileAndRun(sourceCode);
// empty copy loop
ABI_CHECK(callContractFunction("save()"), encodeArgs(24));
ABI_CHECK(callContractFunction("save()", "abcdefg"), encodeArgs(24));
}
BOOST_AUTO_TEST_CASE(bytes_from_calldata_to_memory)
{
char const* sourceCode = R"(
contract C {
function f() public returns (bytes32) {
return keccak256(abi.encodePacked("abc", msg.data));
}
}
)";
compileAndRun(sourceCode);
bytes calldata1 = FixedHash<4>(dev::keccak256("f()")).asBytes() + bytes(61, 0x22) + bytes(12, 0x12);
sendMessage(calldata1, false);
BOOST_CHECK(m_transactionSuccessful);
BOOST_CHECK(m_output == encodeArgs(dev::keccak256(bytes{'a', 'b', 'c'} + calldata1)));
}
BOOST_AUTO_TEST_CASE(call_forward_bytes)
{
char const* sourceCode = R"(
contract receiver {
uint public received;
function receive(uint x) public { received += x + 1; }
function() external { received = 0x80; }
}
contract sender {
constructor() public { rec = new receiver(); }
function() external { savedData = msg.data; }
function forward() public returns (bool) { address(rec).call(savedData); return true; }
function clear() public returns (bool) { delete savedData; return true; }
function val() public returns (uint) { return rec.received(); }
receiver rec;
bytes savedData;
}
)";
compileAndRun(sourceCode, 0, "sender");
ABI_CHECK(callContractFunction("receive(uint256)", 7), bytes());
ABI_CHECK(callContractFunction("val()"), encodeArgs(0));
ABI_CHECK(callContractFunction("forward()"), encodeArgs(true));
ABI_CHECK(callContractFunction("val()"), encodeArgs(8));
ABI_CHECK(callContractFunction("clear()"), encodeArgs(true));
ABI_CHECK(callContractFunction("val()"), encodeArgs(8));
ABI_CHECK(callContractFunction("forward()"), encodeArgs(true));
ABI_CHECK(callContractFunction("val()"), encodeArgs(0x80));
}
BOOST_AUTO_TEST_CASE(call_forward_bytes_length)
{
char const* sourceCode = R"(
contract receiver {
uint public calledLength;
function() external { calledLength = msg.data.length; }
}
contract sender {
receiver rec;
constructor() public { rec = new receiver(); }
function viaCalldata() public returns (uint) {
(bool success,) = address(rec).call(msg.data);
require(success);
return rec.calledLength();
}
function viaMemory() public returns (uint) {
bytes memory x = msg.data;
(bool success,) = address(rec).call(x);
require(success);
return rec.calledLength();
}
bytes s;
function viaStorage() public returns (uint) {
s = msg.data;
(bool success,) = address(rec).call(s);
require(success);
return rec.calledLength();
}
}
)";
compileAndRun(sourceCode, 0, "sender");
// No additional data, just function selector
ABI_CHECK(callContractFunction("viaCalldata()"), encodeArgs(4));
ABI_CHECK(callContractFunction("viaMemory()"), encodeArgs(4));
ABI_CHECK(callContractFunction("viaStorage()"), encodeArgs(4));
// Some additional unpadded data
bytes unpadded = asBytes(string("abc"));
ABI_CHECK(callContractFunctionNoEncoding("viaCalldata()", unpadded), encodeArgs(7));
ABI_CHECK(callContractFunctionNoEncoding("viaMemory()", unpadded), encodeArgs(7));
ABI_CHECK(callContractFunctionNoEncoding("viaStorage()", unpadded), encodeArgs(7));
}
BOOST_AUTO_TEST_CASE(copying_bytes_multiassign)
{
char const* sourceCode = R"(
contract receiver {
uint public received;
function receive(uint x) public { received += x + 1; }
function() external { received = 0x80; }
}
contract sender {
constructor() public { rec = new receiver(); }
function() external { savedData1 = savedData2 = msg.data; }
function forward(bool selector) public returns (bool) {
if (selector) { address(rec).call(savedData1); delete savedData1; }
else { address(rec).call(savedData2); delete savedData2; }
return true;
}
function val() public returns (uint) { return rec.received(); }
receiver rec;
bytes savedData1;
bytes savedData2;
}
)";
compileAndRun(sourceCode, 0, "sender");
ABI_CHECK(callContractFunction("receive(uint256)", 7), bytes());
ABI_CHECK(callContractFunction("val()"), encodeArgs(0));
ABI_CHECK(callContractFunction("forward(bool)", true), encodeArgs(true));
ABI_CHECK(callContractFunction("val()"), encodeArgs(8));
ABI_CHECK(callContractFunction("forward(bool)", false), encodeArgs(true));
ABI_CHECK(callContractFunction("val()"), encodeArgs(16));
ABI_CHECK(callContractFunction("forward(bool)", true), encodeArgs(true));
ABI_CHECK(callContractFunction("val()"), encodeArgs(0x80));
}
BOOST_AUTO_TEST_CASE(delete_removes_bytes_data)
{
char const* sourceCode = R"(
contract c {
function() external { data = msg.data; }
function del() public returns (bool) { delete data; return true; }
bytes data;
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("---", 7), bytes());
BOOST_CHECK(!storageEmpty(m_contractAddress));
ABI_CHECK(callContractFunction("del()", 7), encodeArgs(true));
BOOST_CHECK(storageEmpty(m_contractAddress));
}
BOOST_AUTO_TEST_CASE(copy_from_calldata_removes_bytes_data)
{
char const* sourceCode = R"(
contract c {
function set() public returns (bool) { data = msg.data; return true; }
function() external { data = msg.data; }
bytes data;
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("set()", 1, 2, 3, 4, 5), encodeArgs(true));
BOOST_CHECK(!storageEmpty(m_contractAddress));
sendMessage(bytes(), false);
BOOST_CHECK(m_transactionSuccessful);
BOOST_CHECK(m_output.empty());
BOOST_CHECK(storageEmpty(m_contractAddress));
}
BOOST_AUTO_TEST_CASE(copy_removes_bytes_data)
{
char const* sourceCode = R"(
contract c {
function set() public returns (bool) { data1 = msg.data; return true; }
function reset() public returns (bool) { data1 = data2; return true; }
bytes data1;
bytes data2;
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("set()", 1, 2, 3, 4, 5), encodeArgs(true));
BOOST_CHECK(!storageEmpty(m_contractAddress));
ABI_CHECK(callContractFunction("reset()"), encodeArgs(true));
BOOST_CHECK(storageEmpty(m_contractAddress));
}
BOOST_AUTO_TEST_CASE(bytes_inside_mappings)
{
char const* sourceCode = R"(
contract c {
function set(uint key) public returns (bool) { data[key] = msg.data; return true; }
function copy(uint from, uint to) public returns (bool) { data[to] = data[from]; return true; }
mapping(uint => bytes) data;
}
)";
compileAndRun(sourceCode);
// store a short byte array at 1 and a longer one at 2
ABI_CHECK(callContractFunction("set(uint256)", 1, 2), encodeArgs(true));
ABI_CHECK(callContractFunction("set(uint256)", 2, 2, 3, 4, 5), encodeArgs(true));
BOOST_CHECK(!storageEmpty(m_contractAddress));
// copy shorter to longer
ABI_CHECK(callContractFunction("copy(uint256,uint256)", 1, 2), encodeArgs(true));
BOOST_CHECK(!storageEmpty(m_contractAddress));
// copy empty to both
ABI_CHECK(callContractFunction("copy(uint256,uint256)", 99, 1), encodeArgs(true));
BOOST_CHECK(!storageEmpty(m_contractAddress));
ABI_CHECK(callContractFunction("copy(uint256,uint256)", 99, 2), encodeArgs(true));
BOOST_CHECK(storageEmpty(m_contractAddress));
}
BOOST_AUTO_TEST_CASE(bytes_length_member)
{
char const* sourceCode = R"(
contract c {
function set() public returns (bool) { data = msg.data; return true; }
function getLength() public returns (uint) { return data.length; }
bytes data;
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("getLength()"), encodeArgs(0));
ABI_CHECK(callContractFunction("set()", 1, 2), encodeArgs(true));
ABI_CHECK(callContractFunction("getLength()"), encodeArgs(4+32+32));
}
BOOST_AUTO_TEST_CASE(struct_copy)
{
char const* sourceCode = R"(
contract c {
struct Nested { uint x; uint y; }
struct Struct { uint a; mapping(uint => Struct) b; Nested nested; uint c; }
mapping(uint => Struct) data;
function set(uint k) public returns (bool) {
data[k].a = 1;
data[k].nested.x = 3;
data[k].nested.y = 4;
data[k].c = 2;
return true;
}
function copy(uint from, uint to) public returns (bool) {
data[to] = data[from];
return true;
}
function retrieve(uint k) public returns (uint a, uint x, uint y, uint c)
{
a = data[k].a;
x = data[k].nested.x;
y = data[k].nested.y;
c = data[k].c;
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("set(uint256)", 7), encodeArgs(true));
ABI_CHECK(callContractFunction("retrieve(uint256)", 7), encodeArgs(1, 3, 4, 2));
ABI_CHECK(callContractFunction("copy(uint256,uint256)", 7, 8), encodeArgs(true));
ABI_CHECK(callContractFunction("retrieve(uint256)", 7), encodeArgs(1, 3, 4, 2));
ABI_CHECK(callContractFunction("retrieve(uint256)", 8), encodeArgs(1, 3, 4, 2));
ABI_CHECK(callContractFunction("copy(uint256,uint256)", 0, 7), encodeArgs(true));
ABI_CHECK(callContractFunction("retrieve(uint256)", 7), encodeArgs(0, 0, 0, 0));
ABI_CHECK(callContractFunction("retrieve(uint256)", 8), encodeArgs(1, 3, 4, 2));
ABI_CHECK(callContractFunction("copy(uint256,uint256)", 7, 8), encodeArgs(true));
ABI_CHECK(callContractFunction("retrieve(uint256)", 8), encodeArgs(0, 0, 0, 0));
}
BOOST_AUTO_TEST_CASE(struct_containing_bytes_copy_and_delete)
{
char const* sourceCode = R"(
contract c {
struct Struct { uint a; bytes data; uint b; }
Struct data1;
Struct data2;
function set(uint _a, bytes calldata _data, uint _b) external returns (bool) {
data1.a = _a;
data1.b = _b;
data1.data = _data;
return true;
}
function copy() public returns (bool) {
data1 = data2;
return true;
}
function del() public returns (bool) {
delete data1;
return true;
}
}
)";
compileAndRun(sourceCode);
string data = "123456789012345678901234567890123";
BOOST_CHECK(storageEmpty(m_contractAddress));
ABI_CHECK(callContractFunction("set(uint256,bytes,uint256)", 12, 0x60, 13, u256(data.length()), data), encodeArgs(true));
BOOST_CHECK(!storageEmpty(m_contractAddress));
ABI_CHECK(callContractFunction("copy()"), encodeArgs(true));
BOOST_CHECK(storageEmpty(m_contractAddress));
ABI_CHECK(callContractFunction("set(uint256,bytes,uint256)", 12, 0x60, 13, u256(data.length()), data), encodeArgs(true));
BOOST_CHECK(!storageEmpty(m_contractAddress));
ABI_CHECK(callContractFunction("del()"), encodeArgs(true));
BOOST_CHECK(storageEmpty(m_contractAddress));
}
BOOST_AUTO_TEST_CASE(struct_copy_via_local)
{
char const* sourceCode = R"(
contract c {
struct Struct { uint a; uint b; }
Struct data1;
Struct data2;
function test() public returns (bool) {
data1.a = 1;
data1.b = 2;
Struct memory x = data1;
data2 = x;
return data2.a == data1.a && data2.b == data1.b;
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("test()"), encodeArgs(true));
}
BOOST_AUTO_TEST_CASE(using_enums)
{
char const* sourceCode = R"(
contract test {
enum ActionChoices { GoLeft, GoRight, GoStraight, Sit }
constructor() public
{
choices = ActionChoices.GoStraight;
}
function getChoice() public returns (uint d)
{
d = uint256(choices);
}
ActionChoices choices;
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("getChoice()"), encodeArgs(2));
}
BOOST_AUTO_TEST_CASE(enum_explicit_overflow)
{
char const* sourceCode = R"(
contract test {
enum ActionChoices { GoLeft, GoRight, GoStraight }
constructor() public
{
}
function getChoiceExp(uint x) public returns (uint d)
{
choice = ActionChoices(x);
d = uint256(choice);
}
function getChoiceFromSigned(int x) public returns (uint d)
{
choice = ActionChoices(x);
d = uint256(choice);
}
function getChoiceFromNegativeLiteral() public returns (uint d)
{
choice = ActionChoices(-1);
d = uint256(choice);
}
ActionChoices choice;
}
)";
compileAndRun(sourceCode);
// These should throw
ABI_CHECK(callContractFunction("getChoiceExp(uint256)", 3), encodeArgs());
ABI_CHECK(callContractFunction("getChoiceFromSigned(int256)", -1), encodeArgs());
ABI_CHECK(callContractFunction("getChoiceFromNegativeLiteral()"), encodeArgs());
// These should work
ABI_CHECK(callContractFunction("getChoiceExp(uint256)", 2), encodeArgs(2));
ABI_CHECK(callContractFunction("getChoiceExp(uint256)", 0), encodeArgs(0));
}
BOOST_AUTO_TEST_CASE(storing_invalid_boolean)
{
char const* sourceCode = R"(
contract C {
event Ev(bool);
bool public perm;
function set() public returns(uint) {
bool tmp;
assembly {
tmp := 5
}
perm = tmp;
return 1;
}
function ret() public returns(bool) {
bool tmp;
assembly {
tmp := 5
}
return tmp;
}
function ev() public returns(uint) {
bool tmp;
assembly {
tmp := 5
}
emit Ev(tmp);
return 1;
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("set()"), encodeArgs(1));
ABI_CHECK(callContractFunction("perm()"), encodeArgs(1));
ABI_CHECK(callContractFunction("ret()"), encodeArgs(1));
ABI_CHECK(callContractFunction("ev()"), encodeArgs(1));
BOOST_REQUIRE_EQUAL(m_logs.size(), 1);
BOOST_CHECK_EQUAL(m_logs[0].address, m_contractAddress);
BOOST_CHECK(m_logs[0].data == encodeArgs(1));
BOOST_REQUIRE_EQUAL(m_logs[0].topics.size(), 1);
BOOST_CHECK_EQUAL(m_logs[0].topics[0], dev::keccak256(string("Ev(bool)")));
}
BOOST_AUTO_TEST_CASE(using_contract_enums_with_explicit_contract_name)
{
char const* sourceCode = R"(
contract test {
enum Choice { A, B, C }
function answer () public returns (test.Choice _ret)
{
_ret = test.Choice.B;
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("answer()"), encodeArgs(1));
}
BOOST_AUTO_TEST_CASE(using_inherited_enum)
{
char const* sourceCode = R"(
contract base {
enum Choice { A, B, C }
}
contract test is base {
function answer () public returns (Choice _ret)
{
_ret = Choice.B;
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("answer()"), encodeArgs(1));
}
BOOST_AUTO_TEST_CASE(using_inherited_enum_excplicitly)
{
char const* sourceCode = R"(
contract base {
enum Choice { A, B, C }
}
contract test is base {
function answer () public returns (base.Choice _ret)
{
_ret = base.Choice.B;
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("answer()"), encodeArgs(1));
}
BOOST_AUTO_TEST_CASE(constructing_enums_from_ints)
{
char const* sourceCode = R"(
contract c {
enum Truth { False, True }
function test() public returns (uint)
{
return uint(Truth(uint8(0x701)));
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("test()"), encodeArgs(1));
}
BOOST_AUTO_TEST_CASE(struct_referencing)
{
static char const* sourceCode = R"(
pragma experimental ABIEncoderV2;
interface I {
struct S { uint a; }
}
library L {
struct S { uint b; uint a; }
function f() public pure returns (S memory) {
S memory s;
s.a = 3;
return s;
}
function g() public pure returns (I.S memory) {
I.S memory s;
s.a = 4;
return s;
}
// argument-dependant lookup tests
function a(I.S memory) public pure returns (uint) { return 1; }
function a(S memory) public pure returns (uint) { return 2; }
}
contract C is I {
function f() public pure returns (S memory) {
S memory s;
s.a = 1;
return s;
}
function g() public pure returns (I.S memory) {
I.S memory s;
s.a = 2;
return s;
}
function h() public pure returns (L.S memory) {
L.S memory s;
s.a = 5;
return s;
}
function x() public pure returns (L.S memory) {
return L.f();
}
function y() public pure returns (I.S memory) {
return L.g();
}
function a1() public pure returns (uint) { S memory s; return L.a(s); }
function a2() public pure returns (uint) { L.S memory s; return L.a(s); }
}
)";
compileAndRun(sourceCode, 0, "L");
ABI_CHECK(callContractFunction("f()"), encodeArgs(0, 3));
ABI_CHECK(callContractFunction("g()"), encodeArgs(4));
compileAndRun(sourceCode, 0, "C", bytes(), map<string, Address>{ {"L", m_contractAddress}});
ABI_CHECK(callContractFunction("f()"), encodeArgs(1));
ABI_CHECK(callContractFunction("g()"), encodeArgs(2));
ABI_CHECK(callContractFunction("h()"), encodeArgs(0, 5));
ABI_CHECK(callContractFunction("x()"), encodeArgs(0, 3));
ABI_CHECK(callContractFunction("y()"), encodeArgs(4));
ABI_CHECK(callContractFunction("a1()"), encodeArgs(1));
ABI_CHECK(callContractFunction("a2()"), encodeArgs(2));
}
BOOST_AUTO_TEST_CASE(enum_referencing)
{
char const* sourceCode = R"(
interface I {
enum Direction { A, B, Left, Right }
}
library L {
enum Direction { Left, Right }
function f() public pure returns (Direction) {
return Direction.Right;
}
function g() public pure returns (I.Direction) {
return I.Direction.Right;
}
}
contract C is I {
function f() public pure returns (Direction) {
return Direction.Right;
}
function g() public pure returns (I.Direction) {
return I.Direction.Right;
}
function h() public pure returns (L.Direction) {
return L.Direction.Right;
}
function x() public pure returns (L.Direction) {
return L.f();
}
function y() public pure returns (I.Direction) {
return L.g();
}
}
)";
compileAndRun(sourceCode, 0, "L");
ABI_CHECK(callContractFunction("f()"), encodeArgs(1));
ABI_CHECK(callContractFunction("g()"), encodeArgs(3));
compileAndRun(sourceCode, 0, "C", bytes(), map<string, Address>{{"L", m_contractAddress}});
ABI_CHECK(callContractFunction("f()"), encodeArgs(3));
ABI_CHECK(callContractFunction("g()"), encodeArgs(3));
ABI_CHECK(callContractFunction("h()"), encodeArgs(1));
ABI_CHECK(callContractFunction("x()"), encodeArgs(1));
ABI_CHECK(callContractFunction("y()"), encodeArgs(3));
}
BOOST_AUTO_TEST_CASE(inline_member_init)
{
char const* sourceCode = R"(
contract test {
constructor() public {
m_b = 6;
m_c = 8;
}
uint m_a = 5;
uint m_b;
uint m_c = 7;
function get() public returns (uint a, uint b, uint c){
a = m_a;
b = m_b;
c = m_c;
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("get()"), encodeArgs(5, 6, 8));
}
BOOST_AUTO_TEST_CASE(inline_member_init_inheritence)
{
char const* sourceCode = R"(
contract Base {
constructor() public {}
uint m_base = 5;
function getBMember() public returns (uint i) { return m_base; }
}
contract Derived is Base {
constructor() public {}
uint m_derived = 6;
function getDMember() public returns (uint i) { return m_derived; }
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("getBMember()"), encodeArgs(5));
ABI_CHECK(callContractFunction("getDMember()"), encodeArgs(6));
}
BOOST_AUTO_TEST_CASE(inline_member_init_inheritence_without_constructor)
{
char const* sourceCode = R"(
contract Base {
uint m_base = 5;
function getBMember() public returns (uint i) { return m_base; }
}
contract Derived is Base {
uint m_derived = 6;
function getDMember() public returns (uint i) { return m_derived; }
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("getBMember()"), encodeArgs(5));
ABI_CHECK(callContractFunction("getDMember()"), encodeArgs(6));
}
BOOST_AUTO_TEST_CASE(external_function)
{
char const* sourceCode = R"(
contract c {
function f(uint a) public returns (uint) { return a; }
function test(uint a, uint b) external returns (uint r_a, uint r_b) {
r_a = f(a + 7);
r_b = b;
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("test(uint256,uint256)", 2, 3), encodeArgs(2+7, 3));
}
BOOST_AUTO_TEST_CASE(bytes_in_arguments)
{
char const* sourceCode = R"(
contract c {
uint result;
function f(uint a, uint b) public { result += a + b; }
function g(uint a) public { result *= a; }
function test(uint a, bytes calldata data1, bytes calldata data2, uint b) external returns (uint r_a, uint r, uint r_b, uint l) {
r_a = a;
address(this).call(data1);
address(this).call(data2);
r = result;
r_b = b;
l = data1.length;
}
}
)";
compileAndRun(sourceCode);
string innercalldata1 = asString(FixedHash<4>(dev::keccak256("f(uint256,uint256)")).asBytes() + encodeArgs(8, 9));
string innercalldata2 = asString(FixedHash<4>(dev::keccak256("g(uint256)")).asBytes() + encodeArgs(3));
bytes calldata = encodeArgs(
12, 32 * 4, u256(32 * 4 + 32 + (innercalldata1.length() + 31) / 32 * 32), 13,
u256(innercalldata1.length()), innercalldata1,
u256(innercalldata2.length()), innercalldata2);
ABI_CHECK(
callContractFunction("test(uint256,bytes,bytes,uint256)", calldata),
encodeArgs(12, (8 + 9) * 3, 13, u256(innercalldata1.length()))
);
}
BOOST_AUTO_TEST_CASE(fixed_arrays_in_storage)
{
char const* sourceCode = R"(
contract c {
struct Data { uint x; uint y; }
Data[2**10] data;
uint[2**10 + 3] ids;
function setIDStatic(uint id) public { ids[2] = id; }
function setID(uint index, uint id) public { ids[index] = id; }
function setData(uint index, uint x, uint y) public { data[index].x = x; data[index].y = y; }
function getID(uint index) public returns (uint) { return ids[index]; }
function getData(uint index) public returns (uint x, uint y) { x = data[index].x; y = data[index].y; }
function getLengths() public returns (uint l1, uint l2) { l1 = data.length; l2 = ids.length; }
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("setIDStatic(uint256)", 11), bytes());
ABI_CHECK(callContractFunction("getID(uint256)", 2), encodeArgs(11));
ABI_CHECK(callContractFunction("setID(uint256,uint256)", 7, 8), bytes());
ABI_CHECK(callContractFunction("getID(uint256)", 7), encodeArgs(8));
ABI_CHECK(callContractFunction("setData(uint256,uint256,uint256)", 7, 8, 9), bytes());
ABI_CHECK(callContractFunction("setData(uint256,uint256,uint256)", 8, 10, 11), bytes());
ABI_CHECK(callContractFunction("getData(uint256)", 7), encodeArgs(8, 9));
ABI_CHECK(callContractFunction("getData(uint256)", 8), encodeArgs(10, 11));
ABI_CHECK(callContractFunction("getLengths()"), encodeArgs(u256(1) << 10, (u256(1) << 10) + 3));
}
BOOST_AUTO_TEST_CASE(dynamic_arrays_in_storage)
{
char const* sourceCode = R"(
contract c {
struct Data { uint x; uint y; }
Data[] data;
uint[] ids;
function setIDStatic(uint id) public { ids[2] = id; }
function setID(uint index, uint id) public { ids[index] = id; }
function setData(uint index, uint x, uint y) public { data[index].x = x; data[index].y = y; }
function getID(uint index) public returns (uint) { return ids[index]; }
function getData(uint index) public returns (uint x, uint y) { x = data[index].x; y = data[index].y; }
function getLengths() public returns (uint l1, uint l2) { l1 = data.length; l2 = ids.length; }
function setLengths(uint l1, uint l2) public { data.length = l1; ids.length = l2; }
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("getLengths()"), encodeArgs(0, 0));
ABI_CHECK(callContractFunction("setLengths(uint256,uint256)", 48, 49), bytes());
ABI_CHECK(callContractFunction("getLengths()"), encodeArgs(48, 49));
ABI_CHECK(callContractFunction("setIDStatic(uint256)", 11), bytes());
ABI_CHECK(callContractFunction("getID(uint256)", 2), encodeArgs(11));
ABI_CHECK(callContractFunction("setID(uint256,uint256)", 7, 8), bytes());
ABI_CHECK(callContractFunction("getID(uint256)", 7), encodeArgs(8));
ABI_CHECK(callContractFunction("setData(uint256,uint256,uint256)", 7, 8, 9), bytes());
ABI_CHECK(callContractFunction("setData(uint256,uint256,uint256)", 8, 10, 11), bytes());
ABI_CHECK(callContractFunction("getData(uint256)", 7), encodeArgs(8, 9));
ABI_CHECK(callContractFunction("getData(uint256)", 8), encodeArgs(10, 11));
}
BOOST_AUTO_TEST_CASE(fixed_out_of_bounds_array_access)
{
char const* sourceCode = R"(
contract c {
uint[4] data;
function set(uint index, uint value) public returns (bool) { data[index] = value; return true; }
function get(uint index) public returns (uint) { return data[index]; }
function length() public returns (uint) { return data.length; }
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("length()"), encodeArgs(4));
ABI_CHECK(callContractFunction("set(uint256,uint256)", 3, 4), encodeArgs(true));
ABI_CHECK(callContractFunction("set(uint256,uint256)", 4, 5), bytes());
ABI_CHECK(callContractFunction("set(uint256,uint256)", 400, 5), bytes());
ABI_CHECK(callContractFunction("get(uint256)", 3), encodeArgs(4));
ABI_CHECK(callContractFunction("get(uint256)", 4), bytes());
ABI_CHECK(callContractFunction("get(uint256)", 400), bytes());
ABI_CHECK(callContractFunction("length()"), encodeArgs(4));
}
BOOST_AUTO_TEST_CASE(dynamic_out_of_bounds_array_access)
{
char const* sourceCode = R"(
contract c {
uint[] data;
function enlarge(uint amount) public returns (uint) { return data.length += amount; }
function set(uint index, uint value) public returns (bool) { data[index] = value; return true; }
function get(uint index) public returns (uint) { return data[index]; }
function length() public returns (uint) { return data.length; }
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("length()"), encodeArgs(0));
ABI_CHECK(callContractFunction("get(uint256)", 3), bytes());
ABI_CHECK(callContractFunction("enlarge(uint256)", 4), encodeArgs(4));
ABI_CHECK(callContractFunction("length()"), encodeArgs(4));
ABI_CHECK(callContractFunction("set(uint256,uint256)", 3, 4), encodeArgs(true));
ABI_CHECK(callContractFunction("get(uint256)", 3), encodeArgs(4));
ABI_CHECK(callContractFunction("length()"), encodeArgs(4));
ABI_CHECK(callContractFunction("set(uint256,uint256)", 4, 8), bytes());
ABI_CHECK(callContractFunction("length()"), encodeArgs(4));
}
BOOST_AUTO_TEST_CASE(fixed_array_cleanup)
{
char const* sourceCode = R"(
contract c {
uint spacer1;
uint spacer2;
uint[20] data;
function fill() public {
for (uint i = 0; i < data.length; ++i) data[i] = i+1;
}
function clear() public { delete data; }
}
)";
compileAndRun(sourceCode);
BOOST_CHECK(storageEmpty(m_contractAddress));
ABI_CHECK(callContractFunction("fill()"), bytes());
BOOST_CHECK(!storageEmpty(m_contractAddress));
ABI_CHECK(callContractFunction("clear()"), bytes());
BOOST_CHECK(storageEmpty(m_contractAddress));
}
BOOST_AUTO_TEST_CASE(short_fixed_array_cleanup)
{
char const* sourceCode = R"(
contract c {
uint spacer1;
uint spacer2;
uint[3] data;
function fill() public {
for (uint i = 0; i < data.length; ++i) data[i] = i+1;
}
function clear() public { delete data; }
}
)";
compileAndRun(sourceCode);
BOOST_CHECK(storageEmpty(m_contractAddress));
ABI_CHECK(callContractFunction("fill()"), bytes());
BOOST_CHECK(!storageEmpty(m_contractAddress));
ABI_CHECK(callContractFunction("clear()"), bytes());
BOOST_CHECK(storageEmpty(m_contractAddress));
}
BOOST_AUTO_TEST_CASE(dynamic_array_cleanup)
{
char const* sourceCode = R"(
contract c {
uint[20] spacer;
uint[] dynamic;
function fill() public {
dynamic.length = 21;
for (uint i = 0; i < dynamic.length; ++i) dynamic[i] = i+1;
}
function halfClear() public { dynamic.length = 5; }
function fullClear() public { delete dynamic; }
}
)";
compileAndRun(sourceCode);
BOOST_CHECK(storageEmpty(m_contractAddress));
ABI_CHECK(callContractFunction("fill()"), bytes());
BOOST_CHECK(!storageEmpty(m_contractAddress));
ABI_CHECK(callContractFunction("halfClear()"), bytes());
BOOST_CHECK(!storageEmpty(m_contractAddress));
ABI_CHECK(callContractFunction("fullClear()"), bytes());
BOOST_CHECK(storageEmpty(m_contractAddress));
}
BOOST_AUTO_TEST_CASE(dynamic_multi_array_cleanup)
{
char const* sourceCode = R"(
contract c {
struct s { uint[][] d; }
s[] data;
function fill() public returns (uint) {
data.length = 3;
data[2].d.length = 4;
data[2].d[3].length = 5;
data[2].d[3][4] = 8;
return data[2].d[3][4];
}
function clear() public { delete data; }
}
)";
compileAndRun(sourceCode);
BOOST_CHECK(storageEmpty(m_contractAddress));
ABI_CHECK(callContractFunction("fill()"), encodeArgs(8));
BOOST_CHECK(!storageEmpty(m_contractAddress));
ABI_CHECK(callContractFunction("clear()"), bytes());
BOOST_CHECK(storageEmpty(m_contractAddress));
}
BOOST_AUTO_TEST_CASE(array_copy_storage_storage_dyn_dyn)
{
char const* sourceCode = R"(
contract c {
uint[] data1;
uint[] data2;
function setData1(uint length, uint index, uint value) public {
data1.length = length; if (index < length) data1[index] = value;
}
function copyStorageStorage() public { data2 = data1; }
function getData2(uint index) public returns (uint len, uint val) {
len = data2.length; if (index < len) val = data2[index];
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("setData1(uint256,uint256,uint256)", 10, 5, 4), bytes());
ABI_CHECK(callContractFunction("copyStorageStorage()"), bytes());
ABI_CHECK(callContractFunction("getData2(uint256)", 5), encodeArgs(10, 4));
ABI_CHECK(callContractFunction("setData1(uint256,uint256,uint256)", 0, 0, 0), bytes());
ABI_CHECK(callContractFunction("copyStorageStorage()"), bytes());
ABI_CHECK(callContractFunction("getData2(uint256)", 0), encodeArgs(0, 0));
BOOST_CHECK(storageEmpty(m_contractAddress));
}
BOOST_AUTO_TEST_CASE(array_copy_storage_storage_static_static)
{
char const* sourceCode = R"(
contract c {
uint[40] data1;
uint[20] data2;
function test() public returns (uint x, uint y){
data1[30] = 4;
data1[2] = 7;
data1[3] = 9;
data2[3] = 8;
data1 = data2;
x = data1[3];
y = data1[30]; // should be cleared
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("test()"), encodeArgs(8, 0));
}
BOOST_AUTO_TEST_CASE(array_copy_storage_storage_static_dynamic)
{
char const* sourceCode = R"(
contract c {
uint[9] data1;
uint[] data2;
function test() public returns (uint x, uint y){
data1[8] = 4;
data2 = data1;
x = data2.length;
y = data2[8];
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("test()"), encodeArgs(9, 4));
}
BOOST_AUTO_TEST_CASE(array_copy_different_packing)
{
char const* sourceCode = R"(
contract c {
bytes8[] data1; // 4 per slot
bytes10[] data2; // 3 per slot
function test() public returns (bytes10 a, bytes10 b, bytes10 c, bytes10 d, bytes10 e) {
data1.length = 9;
for (uint i = 0; i < data1.length; ++i)
data1[i] = bytes8(uint64(i));
data2 = data1;
a = data2[1];
b = data2[2];
c = data2[3];
d = data2[4];
e = data2[5];
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("test()"), encodeArgs(
asString(fromHex("0000000000000001")),
asString(fromHex("0000000000000002")),
asString(fromHex("0000000000000003")),
asString(fromHex("0000000000000004")),
asString(fromHex("0000000000000005"))
));
}
BOOST_AUTO_TEST_CASE(array_copy_target_simple)
{
char const* sourceCode = R"(
contract c {
bytes8[9] data1; // 4 per slot
bytes17[10] data2; // 1 per slot, no offset counter
function test() public returns (bytes17 a, bytes17 b, bytes17 c, bytes17 d, bytes17 e) {
for (uint i = 0; i < data1.length; ++i)
data1[i] = bytes8(uint64(i));
data2[8] = data2[9] = bytes8(uint64(2));
data2 = data1;
a = data2[1];
b = data2[2];
c = data2[3];
d = data2[4];
e = data2[9];
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("test()"), encodeArgs(
asString(fromHex("0000000000000001")),
asString(fromHex("0000000000000002")),
asString(fromHex("0000000000000003")),
asString(fromHex("0000000000000004")),
asString(fromHex("0000000000000000"))
));
}
BOOST_AUTO_TEST_CASE(array_copy_target_leftover)
{
// test that leftover elements in the last slot of target are correctly cleared during assignment
char const* sourceCode = R"(
contract c {
byte[10] data1;
bytes2[32] data2;
function test() public returns (uint check, uint res1, uint res2) {
uint i;
for (i = 0; i < data2.length; ++i)
data2[i] = 0xffff;
check = uint(uint16(data2[31])) * 0x10000 | uint(uint16(data2[14]));
for (i = 0; i < data1.length; ++i)
data1[i] = byte(uint8(1 + i));
data2 = data1;
for (i = 0; i < 16; ++i)
res1 |= uint(uint16(data2[i])) * 0x10000**i;
for (i = 0; i < 16; ++i)
res2 |= uint(uint16(data2[16 + i])) * 0x10000**i;
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("test()"), encodeArgs(
u256("0xffffffff"),
asString(fromHex("0000000000000000""000000000a000900""0800070006000500""0400030002000100")),
asString(fromHex("0000000000000000""0000000000000000""0000000000000000""0000000000000000"))
));
}
BOOST_AUTO_TEST_CASE(array_copy_target_leftover2)
{
// since the copy always copies whole slots, we have to make sure that the source size maxes
// out a whole slot and at the same time there are still elements left in the target at that point
char const* sourceCode = R"(
contract c {
bytes8[4] data1; // fits into one slot
bytes10[6] data2; // 4 elements need two slots
function test() public returns (bytes10 r1, bytes10 r2, bytes10 r3) {
data1[0] = bytes8(uint64(1));
data1[1] = bytes8(uint64(2));
data1[2] = bytes8(uint64(3));
data1[3] = bytes8(uint64(4));
for (uint i = 0; i < data2.length; ++i)
data2[i] = bytes10(uint80(0xffff00 | (1 + i)));
data2 = data1;
r1 = data2[3];
r2 = data2[4];
r3 = data2[5];
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("test()"), encodeArgs(
asString(fromHex("0000000000000004")),
asString(fromHex("0000000000000000")),
asString(fromHex("0000000000000000"))
));
}
BOOST_AUTO_TEST_CASE(array_copy_storage_storage_struct)
{
char const* sourceCode = R"(
contract c {
struct Data { uint x; uint y; }
Data[] data1;
Data[] data2;
function test() public returns (uint x, uint y) {
data1.length = 9;
data1[8].x = 4;
data1[8].y = 5;
data2 = data1;
x = data2[8].x;
y = data2[8].y;
data1.length = 0;
data2 = data1;
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("test()"), encodeArgs(4, 5));
BOOST_CHECK(storageEmpty(m_contractAddress));
}
BOOST_AUTO_TEST_CASE(array_copy_storage_abi)
{
// NOTE: This does not really test copying from storage to ABI directly,
// because it will always copy to memory first.
char const* sourceCode = R"(
pragma experimental ABIEncoderV2;
contract c {
uint8[] x;
uint16[] y;
uint24[] z;
uint24[][] w;
function test1() public returns (uint8[] memory) {
for (uint i = 0; i < 101; ++i)
x.push(uint8(i));
return x;
}
function test2() public returns (uint16[] memory) {
for (uint i = 0; i < 101; ++i)
y.push(uint16(i));
return y;
}
function test3() public returns (uint24[] memory) {
for (uint i = 0; i < 101; ++i)
z.push(uint24(i));
return z;
}
function test4() public returns (uint24[][] memory) {
w.length = 5;
for (uint i = 0; i < 5; ++i)
for (uint j = 0; j < 101; ++j)
w[i].push(uint24(j));
return w;
}
}
)";
compileAndRun(sourceCode);
bytes valueSequence;
for (size_t i = 0; i < 101; ++i)
valueSequence += toBigEndian(u256(i));
ABI_CHECK(callContractFunction("test1()"), encodeArgs(0x20, 101) + valueSequence);
ABI_CHECK(callContractFunction("test2()"), encodeArgs(0x20, 101) + valueSequence);
ABI_CHECK(callContractFunction("test3()"), encodeArgs(0x20, 101) + valueSequence);
ABI_CHECK(callContractFunction("test4()"),
encodeArgs(0x20, 5, 0xa0, 0xa0 + 102 * 32 * 1, 0xa0 + 102 * 32 * 2, 0xa0 + 102 * 32 * 3, 0xa0 + 102 * 32 * 4) +
encodeArgs(101) + valueSequence +
encodeArgs(101) + valueSequence +
encodeArgs(101) + valueSequence +
encodeArgs(101) + valueSequence +
encodeArgs(101) + valueSequence
);
}
BOOST_AUTO_TEST_CASE(array_copy_storage_abi_signed)
{
// NOTE: This does not really test copying from storage to ABI directly,
// because it will always copy to memory first.
char const* sourceCode = R"(
contract c {
int16[] x;
function test() public returns (int16[] memory) {
x.push(int16(-1));
x.push(int16(-1));
x.push(int16(8));
x.push(int16(-16));
x.push(int16(-2));
x.push(int16(6));
x.push(int16(8));
x.push(int16(-1));
return x;
}
}
)";
compileAndRun(sourceCode);
bytes valueSequence;
ABI_CHECK(callContractFunction("test()"), encodeArgs(0x20, 8,
u256(-1),
u256(-1),
u256(8),
u256(-16),
u256(-2),
u256(6),
u256(8),
u256(-1)
));
}
BOOST_AUTO_TEST_CASE(array_push)
{
char const* sourceCode = R"(
contract c {
uint[] data;
function test() public returns (uint x, uint y, uint z, uint l) {
data.push(5);
x = data[0];
data.push(4);
y = data[1];
l = data.push(3);
z = data[2];
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("test()"), encodeArgs(5, 4, 3, 3));
}
BOOST_AUTO_TEST_CASE(array_push_struct)
{
char const* sourceCode = R"(
contract c {
struct S { uint16 a; uint16 b; uint16[3] c; uint16[] d; }
S[] data;
function test() public returns (uint16, uint16, uint16, uint16) {
S memory s;
s.a = 2;
s.b = 3;
s.c[2] = 4;
s.d = new uint16[](4);
s.d[2] = 5;
data.push(s);
return (data[0].a, data[0].b, data[0].c[2], data[0].d[2]);
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("test()"), encodeArgs(2, 3, 4, 5));
}
BOOST_AUTO_TEST_CASE(array_push_packed_array)
{
char const* sourceCode = R"(
contract c {
uint80[] x;
function test() public returns (uint80, uint80, uint80, uint80) {
x.push(1);
x.push(2);
x.push(3);
x.push(4);
x.push(5);
x.length = 4;
return (x[0], x[1], x[2], x[3]);
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("test()"), encodeArgs(1, 2, 3, 4));
}
BOOST_AUTO_TEST_CASE(byte_array_push)
{
char const* sourceCode = R"(
contract c {
bytes data;
function test() public returns (bool x) {
if (data.push(0x05) != 1) return true;
if (data[0] != 0x05) return true;
data.push(0x04);
if (data[1] != 0x04) return true;
uint l = data.push(0x03);
if (data[2] != 0x03) return true;
if (l != 0x03) return true;
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("test()"), encodeArgs(false));
}
BOOST_AUTO_TEST_CASE(byte_array_push_transition)
{
// Tests transition between short and long encoding
char const* sourceCode = R"(
contract c {
bytes data;
function test() public returns (uint) {
for (uint8 i = 1; i < 40; i++)
{
data.push(byte(i));
if (data.length != i) return 0x1000 + i;
if (data[data.length - 1] != byte(i)) return i;
}
for (uint8 i = 1; i < 40; i++)
if (data[i - 1] != byte(i)) return 0x1000000 + i;
return 0;
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("test()"), encodeArgs(0));
}
BOOST_AUTO_TEST_CASE(array_pop)
{
char const* sourceCode = R"(
contract c {
uint[] data;
function test() public returns (uint x, uint l) {
data.push(7);
x = data.push(3);
data.pop();
x = data.length;
data.pop();
l = data.length;
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("test()"), encodeArgs(1, 0));
}
BOOST_AUTO_TEST_CASE(array_pop_uint16_transition)
{
char const* sourceCode = R"(
contract c {
uint16[] data;
function test() public returns (uint16 x, uint16 y, uint16 z) {
for (uint i = 1; i <= 48; i++)
data.push(uint16(i));
for (uint j = 1; j <= 10; j++)
data.pop();
x = data[data.length - 1];
for (uint k = 1; k <= 10; k++)
data.pop();
y = data[data.length - 1];
for (uint l = 1; l <= 10; l++)
data.pop();
z = data[data.length - 1];
for (uint m = 1; m <= 18; m++)
data.pop();
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("test()"), encodeArgs(38, 28, 18));
BOOST_CHECK(storageEmpty(m_contractAddress));
}
BOOST_AUTO_TEST_CASE(array_pop_uint24_transition)
{
char const* sourceCode = R"(
contract c {
uint256 a;
uint256 b;
uint256 c;
uint24[] data;
function test() public returns (uint24 x, uint24 y) {
for (uint i = 1; i <= 30; i++)
data.push(uint24(i));
for (uint j = 1; j <= 10; j++)
data.pop();
x = data[data.length - 1];
for (uint k = 1; k <= 10; k++)
data.pop();
y = data[data.length - 1];
for (uint l = 1; l <= 10; l++)
data.pop();
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("test()"), encodeArgs(20, 10));
BOOST_CHECK(storageEmpty(m_contractAddress));
}
BOOST_AUTO_TEST_CASE(array_pop_array_transition)
{
char const* sourceCode = R"(
contract c {
uint256 a;
uint256 b;
uint256 c;
uint16[] inner = [1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16];
uint16[][] data;
function test() public returns (uint x, uint y, uint z) {
for (uint i = 1; i <= 48; i++)
data.push(inner);
for (uint j = 1; j <= 10; j++)
data.pop();
x = data[data.length - 1][0];
for (uint k = 1; k <= 10; k++)
data.pop();
y = data[data.length - 1][1];
for (uint l = 1; l <= 10; l++)
data.pop();
z = data[data.length - 1][2];
for (uint m = 1; m <= 18; m++)
data.pop();
delete inner;
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("test()"), encodeArgs(1, 2, 3));
BOOST_CHECK(storageEmpty(m_contractAddress));
}
BOOST_AUTO_TEST_CASE(array_pop_empty_exception)
{
char const* sourceCode = R"(
contract c {
uint[] data;
function test() public returns (bool) {
data.pop();
return true;
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("test()"), encodeArgs());
}
BOOST_AUTO_TEST_CASE(array_pop_storage_empty)
{
char const* sourceCode = R"(
contract c {
uint[] data;
function test() public {
data.push(7);
data.pop();
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("test()"), encodeArgs());
BOOST_CHECK(storageEmpty(m_contractAddress));
}
BOOST_AUTO_TEST_CASE(byte_array_pop)
{
char const* sourceCode = R"(
contract c {
bytes data;
function test() public returns (uint x, uint y, uint l) {
data.push(0x07);
x = data.push(0x03);
data.pop();
data.pop();
y = data.push(0x02);
l = data.length;
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("test()"), encodeArgs(2, 1, 1));
}
BOOST_AUTO_TEST_CASE(byte_array_pop_empty_exception)
{
char const* sourceCode = R"(
contract c {
uint256 a;
uint256 b;
uint256 c;
bytes data;
function test() public returns (bool) {
data.pop();
return true;
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("test()"), encodeArgs());
}
BOOST_AUTO_TEST_CASE(byte_array_pop_storage_empty)
{
char const* sourceCode = R"(
contract c {
bytes data;
function test() public {
data.push(0x07);
data.push(0x05);
data.push(0x03);
data.pop();
data.pop();
data.pop();
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("test()"), encodeArgs());
BOOST_CHECK(storageEmpty(m_contractAddress));
}
BOOST_AUTO_TEST_CASE(byte_array_pop_long_storage_empty)
{
char const* sourceCode = R"(
contract c {
uint256 a;
uint256 b;
uint256 c;
bytes data;
function test() public returns (bool) {
for (uint8 i = 0; i <= 40; i++)
data.push(byte(i+1));
for (int8 j = 40; j >= 0; j--) {
require(data[uint8(j)] == byte(j+1));
require(data.length == uint8(j+1));
data.pop();
}
return true;
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("test()"), encodeArgs(true));
BOOST_CHECK(storageEmpty(m_contractAddress));
}
BOOST_AUTO_TEST_CASE(byte_array_pop_long_storage_empty_garbage_ref)
{
char const* sourceCode = R"(
contract c {
uint256 a;
uint256 b;
bytes data;
function test() public {
for (uint8 i = 0; i <= 40; i++)
data.push(0x03);
for (uint8 j = 0; j <= 40; j++) {
assembly {
mstore(0, "garbage")
}
data.pop();
}
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("test()"), encodeArgs());
BOOST_CHECK(storageEmpty(m_contractAddress));
}
BOOST_AUTO_TEST_CASE(byte_array_pop_masking_long)
{
char const* sourceCode = R"(
contract c {
bytes data;
function test() public returns (bytes memory) {
for (uint i = 0; i < 34; i++)
data.push(0x03);
data.pop();
return data;
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("test()"), encodeArgs(
u256(0x20),
u256(33),
asString(fromHex("0303030303030303030303030303030303030303030303030303030303030303")),
asString(fromHex("03"))
));
}
BOOST_AUTO_TEST_CASE(byte_array_pop_copy_long)
{
char const* sourceCode = R"(
contract c {
bytes data;
function test() public returns (bytes memory) {
for (uint i = 0; i < 33; i++)
data.push(0x03);
for (uint j = 0; j < 4; j++)
data.pop();
return data;
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("test()"), encodeArgs(
u256(0x20),
u256(29),
asString(fromHex("0303030303030303030303030303030303030303030303030303030303"))
));
}
BOOST_AUTO_TEST_CASE(array_pop_isolated)
{
char const* sourceCode = R"(
// This tests that the compiler knows the correct size of the function on the stack.
contract c {
uint[] data;
function test() public returns (uint x) {
x = 2;
data.pop;
x = 3;
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("test()"), encodeArgs(3));
}
BOOST_AUTO_TEST_CASE(byte_array_pop_isolated)
{
char const* sourceCode = R"(
// This tests that the compiler knows the correct size of the function on the stack.
contract c {
bytes data;
function test() public returns (uint x) {
x = 2;
data.pop;
x = 3;
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("test()"), encodeArgs(3));
}
BOOST_AUTO_TEST_CASE(external_array_args)
{
char const* sourceCode = R"(
contract c {
function test(uint[8] calldata a, uint[] calldata b, uint[5] calldata c, uint a_index, uint b_index, uint c_index)
external returns (uint av, uint bv, uint cv) {
av = a[a_index];
bv = b[b_index];
cv = c[c_index];
}
}
)";
compileAndRun(sourceCode);
bytes params = encodeArgs(
1, 2, 3, 4, 5, 6, 7, 8, // a
32 * (8 + 1 + 5 + 1 + 1 + 1), // offset to b
21, 22, 23, 24, 25, // c
0, 1, 2, // (a,b,c)_index
3, // b.length
11, 12, 13 // b
);
ABI_CHECK(callContractFunction("test(uint256[8],uint256[],uint256[5],uint256,uint256,uint256)", params), encodeArgs(1, 12, 23));
}
BOOST_AUTO_TEST_CASE(bytes_index_access)
{
char const* sourceCode = R"(
contract c {
bytes data;
function direct(bytes calldata arg, uint index) external returns (uint) {
return uint(uint8(arg[index]));
}
function storageCopyRead(bytes calldata arg, uint index) external returns (uint) {
data = arg;
return uint(uint8(data[index]));
}
function storageWrite() external returns (uint) {
data.length = 35;
data[31] = 0x77;
data[32] = 0x14;
data[31] = 0x01;
data[31] |= 0x08;
data[30] = 0x01;
data[32] = 0x03;
return uint(uint8(data[30])) * 0x100 | uint(uint8(data[31])) * 0x10 | uint(uint8(data[32]));
}
}
)";
compileAndRun(sourceCode);
string array{
0, 1, 2, 3, 4, 5, 6, 7, 8, 9,
10, 11, 12, 13, 14, 15, 16, 17, 18, 19,
20, 21, 22, 23, 24, 25, 26, 27, 28, 29,
30, 31, 32, 33};
ABI_CHECK(callContractFunction("direct(bytes,uint256)", 64, 33, u256(array.length()), array), encodeArgs(33));
ABI_CHECK(callContractFunction("storageCopyRead(bytes,uint256)", 64, 33, u256(array.length()), array), encodeArgs(33));
ABI_CHECK(callContractFunction("storageWrite()"), encodeArgs(0x193));
}
BOOST_AUTO_TEST_CASE(bytes_delete_element)
{
char const* sourceCode = R"(
contract c {
bytes data;
function test1() external returns (bool) {
data.length = 100;
for (uint i = 0; i < data.length; i++)
data[i] = byte(uint8(i));
delete data[94];
delete data[96];
delete data[98];
return data[94] == 0 && uint8(data[95]) == 95 && data[96] == 0 && uint8(data[97]) == 97;
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("test1()"), encodeArgs(true));
}
BOOST_AUTO_TEST_CASE(array_copy_calldata_storage)
{
char const* sourceCode = R"(
contract c {
uint[9] m_data;
uint[] m_data_dyn;
uint8[][] m_byte_data;
function store(uint[9] calldata a, uint8[3][] calldata b) external returns (uint8) {
m_data = a;
m_data_dyn = a;
m_byte_data = b;
return b[3][1]; // note that access and declaration are reversed to each other
}
function retrieve() public returns (uint a, uint b, uint c, uint d, uint e, uint f, uint g) {
a = m_data.length;
b = m_data[7];
c = m_data_dyn.length;
d = m_data_dyn[7];
e = m_byte_data.length;
f = m_byte_data[3].length;
g = m_byte_data[3][1];
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("store(uint256[9],uint8[3][])", encodeArgs(
21, 22, 23, 24, 25, 26, 27, 28, 29, // a
u256(32 * (9 + 1)),
4, // size of b
1, 2, 3, // b[0]
11, 12, 13, // b[1]
21, 22, 23, // b[2]
31, 32, 33 // b[3]
)), encodeArgs(32));
ABI_CHECK(callContractFunction("retrieve()"), encodeArgs(
9, 28, 9, 28,
4, 3, 32));
}
BOOST_AUTO_TEST_CASE(array_copy_nested_array)
{
char const* sourceCode = R"(
contract c {
uint[4][] a;
uint[10][] b;
uint[][] c;
function test(uint[2][] calldata d) external returns (uint) {
a = d;
b = a;
c = b;
return c[1][1] | c[1][2] | c[1][3] | c[1][4];
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("test(uint256[2][])", encodeArgs(
32, 3,
7, 8,
9, 10,
11, 12
)), encodeArgs(10));
}
BOOST_AUTO_TEST_CASE(array_copy_including_mapping)
{
char const* sourceCode = R"(
contract c {
mapping(uint=>uint)[90][] large;
mapping(uint=>uint)[3][] small;
function test() public returns (uint r) {
large.length = small.length = 7;
large[3][2][0] = 2;
large[1] = large[3];
small[3][2][0] = 2;
small[1] = small[2];
r = ((
small[3][2][0] * 0x100 |
small[1][2][0]) * 0x100 |
large[3][2][0]) * 0x100 |
large[1][2][0];
delete small;
delete large;
}
function clear() public returns (uint r) {
large.length = small.length = 7;
small[3][2][0] = 0;
large[3][2][0] = 0;
small.length = large.length = 0;
return 7;
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("test()"), encodeArgs(0x02000200));
// storage is not empty because we cannot delete the mappings
BOOST_CHECK(!storageEmpty(m_contractAddress));
ABI_CHECK(callContractFunction("clear()"), encodeArgs(7));
BOOST_CHECK(storageEmpty(m_contractAddress));
}
BOOST_AUTO_TEST_CASE(swap_in_storage_overwrite)
{
// This tests a swap in storage which does not work as one
// might expect because we do not have temporary storage.
// (x, y) = (y, x) is the same as
// y = x;
// x = y;
char const* sourceCode = R"(
contract c {
struct S { uint a; uint b; }
S public x;
S public y;
function set() public {
x.a = 1; x.b = 2;
y.a = 3; y.b = 4;
}
function swap() public {
(x, y) = (y, x);
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("x()"), encodeArgs(u256(0), u256(0)));
ABI_CHECK(callContractFunction("y()"), encodeArgs(u256(0), u256(0)));
ABI_CHECK(callContractFunction("set()"), encodeArgs());
ABI_CHECK(callContractFunction("x()"), encodeArgs(u256(1), u256(2)));
ABI_CHECK(callContractFunction("y()"), encodeArgs(u256(3), u256(4)));
ABI_CHECK(callContractFunction("swap()"), encodeArgs());
ABI_CHECK(callContractFunction("x()"), encodeArgs(u256(1), u256(2)));
ABI_CHECK(callContractFunction("y()"), encodeArgs(u256(1), u256(2)));
}
BOOST_AUTO_TEST_CASE(pass_dynamic_arguments_to_the_base)
{
char const* sourceCode = R"(
contract Base {
constructor(uint i) public
{
m_i = i;
}
uint public m_i;
}
contract Derived is Base {
constructor(uint i) Base(i) public
{}
}
contract Final is Derived(4) {
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("m_i()"), encodeArgs(4));
}
BOOST_AUTO_TEST_CASE(pass_dynamic_arguments_to_the_base_base)
{
char const* sourceCode = R"(
contract Base {
constructor(uint j) public
{
m_i = j;
}
uint public m_i;
}
contract Base1 is Base {
constructor(uint k) Base(k) public {}
}
contract Derived is Base, Base1 {
constructor(uint i) Base1(i) public
{}
}
contract Final is Derived(4) {
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("m_i()"), encodeArgs(4));
}
BOOST_AUTO_TEST_CASE(pass_dynamic_arguments_to_the_base_base_with_gap)
{
char const* sourceCode = R"(
contract Base {
constructor(uint i) public
{
m_i = i;
}
uint public m_i;
}
contract Base1 is Base {
constructor(uint k) public {}
}
contract Derived is Base, Base1 {
constructor(uint i) Base(i) Base1(7) public {}
}
contract Final is Derived(4) {
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("m_i()"), encodeArgs(4));
}
BOOST_AUTO_TEST_CASE(simple_constant_variables_test)
{
char const* sourceCode = R"(
contract Foo {
function getX() public returns (uint r) { return x; }
uint constant x = 56;
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("getX()"), encodeArgs(56));
}
BOOST_AUTO_TEST_CASE(constant_variables)
{
char const* sourceCode = R"(
contract Foo {
uint constant x = 56;
enum ActionChoices { GoLeft, GoRight, GoStraight, Sit }
ActionChoices constant choices = ActionChoices.GoLeft;
bytes32 constant st = "abc\x00\xff__";
}
)";
compileAndRun(sourceCode);
}
BOOST_AUTO_TEST_CASE(assignment_to_const_var_involving_expression)
{
char const* sourceCode = R"(
contract C {
uint constant x = 0x123 + 0x456;
function f() public returns (uint) { return x + 1; }
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("f()"), encodeArgs(0x123 + 0x456 + 1));
}
BOOST_AUTO_TEST_CASE(assignment_to_const_var_involving_keccak)
{
char const* sourceCode = R"(
contract C {
bytes32 constant x = keccak256("abc");
function f() public returns (bytes32) { return x; }
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("f()"), encodeArgs(dev::keccak256("abc")));
}
// Disabled until https://github.com/ethereum/solidity/issues/715 is implemented
//BOOST_AUTO_TEST_CASE(assignment_to_const_array_vars)
//{
// char const* sourceCode = R"(
// contract C {
// uint[3] constant x = [uint(1), 2, 3];
// uint constant y = x[0] + x[1] + x[2];
// function f() public returns (uint) { return y; }
// }
// )";
// compileAndRun(sourceCode);
// ABI_CHECK(callContractFunction("f()"), encodeArgs(1 + 2 + 3));
//}
// Disabled until https://github.com/ethereum/solidity/issues/715 is implemented
//BOOST_AUTO_TEST_CASE(constant_struct)
//{
// char const* sourceCode = R"(
// contract C {
// struct S { uint x; uint[] y; }
// S constant x = S(5, new uint[](4));
// function f() public returns (uint) { return x.x; }
// }
// )";
// compileAndRun(sourceCode);
// ABI_CHECK(callContractFunction("f()"), encodeArgs(5));
//}
BOOST_AUTO_TEST_CASE(packed_storage_structs_uint)
{
char const* sourceCode = R"(
contract C {
struct str { uint8 a; uint16 b; uint248 c; }
str data;
function test() public returns (uint) {
data.a = 2;
if (data.a != 2) return 2;
data.b = 0xabcd;
if (data.b != 0xabcd) return 3;
data.c = 0x1234567890;
if (data.c != 0x1234567890) return 4;
if (data.a != 2) return 5;
data.a = 8;
if (data.a != 8) return 6;
if (data.b != 0xabcd) return 7;
data.b = 0xdcab;
if (data.b != 0xdcab) return 8;
if (data.c != 0x1234567890) return 9;
data.c = 0x9876543210;
if (data.c != 0x9876543210) return 10;
return 1;
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("test()"), encodeArgs(1));
}
BOOST_AUTO_TEST_CASE(packed_storage_structs_enum)
{
char const* sourceCode = R"(
contract C {
enum small { A, B, C, D }
enum larger { A, B, C, D, E}
struct str { small a; small b; larger c; larger d; }
str data;
function test() public returns (uint) {
data.a = small.B;
if (data.a != small.B) return 2;
data.b = small.C;
if (data.b != small.C) return 3;
data.c = larger.D;
if (data.c != larger.D) return 4;
if (data.a != small.B) return 5;
data.a = small.C;
if (data.a != small.C) return 6;
if (data.b != small.C) return 7;
data.b = small.D;
if (data.b != small.D) return 8;
if (data.c != larger.D) return 9;
data.c = larger.B;
if (data.c != larger.B) return 10;
return 1;
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("test()"), encodeArgs(1));
}
BOOST_AUTO_TEST_CASE(packed_storage_structs_bytes)
{
char const* sourceCode = R"(
contract C {
struct s1 { byte a; byte b; bytes10 c; bytes9 d; bytes10 e; }
struct s2 { byte a; s1 inner; byte b; byte c; }
byte x;
s2 data;
byte y;
function test() public returns (bool) {
x = 0x01;
data.a = 0x02;
data.inner.a = 0x03;
data.inner.b = 0x04;
data.inner.c = "1234567890";
data.inner.d = "123456789";
data.inner.e = "abcdefghij";
data.b = 0x05;
data.c = byte(0x06);
y = 0x07;
return x == 0x01 && data.a == 0x02 && data.inner.a == 0x03 && data.inner.b == 0x04 &&
data.inner.c == "1234567890" && data.inner.d == "123456789" &&
data.inner.e == "abcdefghij" && data.b == 0x05 && data.c == byte(0x06) && y == 0x07;
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("test()"), encodeArgs(true));
}
BOOST_AUTO_TEST_CASE(packed_storage_structs_delete)
{
char const* sourceCode = R"(
contract C {
struct str { uint8 a; uint16 b; uint8 c; }
uint8 x;
uint16 y;
str data;
function test() public returns (uint) {
x = 1;
y = 2;
data.a = 2;
data.b = 0xabcd;
data.c = 0xfa;
if (x != 1 || y != 2 || data.a != 2 || data.b != 0xabcd || data.c != 0xfa)
return 2;
delete y;
delete data.b;
if (x != 1 || y != 0 || data.a != 2 || data.b != 0 || data.c != 0xfa)
return 3;
delete x;
delete data;
return 1;
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("test()"), encodeArgs(1));
BOOST_CHECK(storageEmpty(m_contractAddress));
}
BOOST_AUTO_TEST_CASE(overloaded_function_call_resolve_to_first)
{
char const* sourceCode = R"(
contract test {
function f(uint k) public returns(uint d) { return k; }
function f(uint a, uint b) public returns(uint d) { return a + b; }
function g() public returns(uint d) { return f(3); }
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("g()"), encodeArgs(3));
}
BOOST_AUTO_TEST_CASE(overloaded_function_call_resolve_to_second)
{
char const* sourceCode = R"(
contract test {
function f(uint a, uint b) public returns(uint d) { return a + b; }
function f(uint k) public returns(uint d) { return k; }
function g() public returns(uint d) { return f(3, 7); }
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("g()"), encodeArgs(10));
}
BOOST_AUTO_TEST_CASE(overloaded_function_call_with_if_else)
{
char const* sourceCode = R"(
contract test {
function f(uint a, uint b) public returns(uint d) { return a + b; }
function f(uint k) public returns(uint d) { return k; }
function g(bool flag) public returns(uint d) {
if (flag)
return f(3);
else
return f(3, 7);
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("g(bool)", true), encodeArgs(3));
ABI_CHECK(callContractFunction("g(bool)", false), encodeArgs(10));
}
BOOST_AUTO_TEST_CASE(derived_overload_base_function_direct)
{
char const* sourceCode = R"(
contract B { function f() public returns(uint) { return 10; } }
contract C is B {
function f(uint i) public returns(uint) { return 2 * i; }
function g() public returns(uint) { return f(1); }
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("g()"), encodeArgs(2));
}
BOOST_AUTO_TEST_CASE(derived_overload_base_function_indirect)
{
char const* sourceCode = R"(
contract A { function f(uint a) public returns(uint) { return 2 * a; } }
contract B { function f() public returns(uint) { return 10; } }
contract C is A, B {
function g() public returns(uint) { return f(); }
function h() public returns(uint) { return f(1); }
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("g()"), encodeArgs(10));
ABI_CHECK(callContractFunction("h()"), encodeArgs(2));
}
BOOST_AUTO_TEST_CASE(super_overload)
{
char const* sourceCode = R"(
contract A { function f(uint a) public returns(uint) { return 2 * a; } }
contract B { function f(bool b) public returns(uint) { return 10; } }
contract C is A, B {
function g() public returns(uint) { return super.f(true); }
function h() public returns(uint) { return super.f(1); }
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("g()"), encodeArgs(10));
ABI_CHECK(callContractFunction("h()"), encodeArgs(2));
}
BOOST_AUTO_TEST_CASE(gasleft_shadow_resolution)
{
char const* sourceCode = R"(
contract C {
function gasleft() public returns(uint256) { return 0; }
function f() public returns(uint256) { return gasleft(); }
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("f()"), encodeArgs(0));
}
BOOST_AUTO_TEST_CASE(bool_conversion)
{
char const* sourceCode = R"(
contract C {
function f(bool _b) public returns(uint) {
if (_b)
return 1;
else
return 0;
}
function g(bool _in) public returns (bool _out) {
_out = _in;
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("f(bool)", 0), encodeArgs(0));
ABI_CHECK(callContractFunction("f(bool)", 1), encodeArgs(1));
ABI_CHECK(callContractFunction("f(bool)", 2), encodeArgs(1));
ABI_CHECK(callContractFunction("f(bool)", 3), encodeArgs(1));
ABI_CHECK(callContractFunction("f(bool)", 255), encodeArgs(1));
ABI_CHECK(callContractFunction("g(bool)", 0), encodeArgs(0));
ABI_CHECK(callContractFunction("g(bool)", 1), encodeArgs(1));
ABI_CHECK(callContractFunction("g(bool)", 2), encodeArgs(1));
ABI_CHECK(callContractFunction("g(bool)", 3), encodeArgs(1));
ABI_CHECK(callContractFunction("g(bool)", 255), encodeArgs(1));
}
BOOST_AUTO_TEST_CASE(packed_storage_signed)
{
char const* sourceCode = R"(
contract C {
int8 a;
uint8 b;
int8 c;
uint8 d;
function test() public returns (uint x1, uint x2, uint x3, uint x4) {
a = -2;
b = -uint8(a) * 2;
c = a * int8(120) * int8(121);
x1 = uint(a);
x2 = b;
x3 = uint(c);
x4 = d;
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("test()"), encodeArgs(u256(-2), u256(4), u256(-112), u256(0)));
}
BOOST_AUTO_TEST_CASE(external_types_in_calls)
{
char const* sourceCode = R"(
contract C1 { C1 public bla; constructor(C1 x) public { bla = x; } }
contract C {
function test() public returns (C1 x, C1 y) {
C1 c = new C1(C1(9));
x = c.bla();
y = this.t1(C1(7));
}
function t1(C1 a) public returns (C1) { return a; }
function t2() public returns (C1) { return C1(9); }
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("test()"), encodeArgs(u256(9), u256(7)));
ABI_CHECK(callContractFunction("t2()"), encodeArgs(u256(9)));
}
BOOST_AUTO_TEST_CASE(invalid_enum_compared)
{
char const* sourceCode = R"(
contract C {
enum X { A, B }
function test_eq() public returns (bool) {
X garbled;
assembly {
garbled := 5
}
return garbled == garbled;
}
function test_eq_ok() public returns (bool) {
X garbled = X.A;
return garbled == garbled;
}
function test_neq() public returns (bool) {
X garbled;
assembly {
garbled := 5
}
return garbled != garbled;
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("test_eq_ok()"), encodeArgs(u256(1)));
// both should throw
ABI_CHECK(callContractFunction("test_eq()"), encodeArgs());
ABI_CHECK(callContractFunction("test_neq()"), encodeArgs());
}
BOOST_AUTO_TEST_CASE(invalid_enum_logged)
{
char const* sourceCode = R"(
contract C {
enum X { A, B }
event Log(X);
function test_log() public returns (uint) {
X garbled = X.A;
assembly {
garbled := 5
}
emit Log(garbled);
return 1;
}
function test_log_ok() public returns (uint) {
X x = X.A;
emit Log(x);
return 1;
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("test_log_ok()"), encodeArgs(u256(1)));
BOOST_REQUIRE_EQUAL(m_logs.size(), 1);
BOOST_CHECK_EQUAL(m_logs[0].address, m_contractAddress);
BOOST_REQUIRE_EQUAL(m_logs[0].topics.size(), 1);
BOOST_REQUIRE_EQUAL(m_logs[0].topics[0], dev::keccak256(string("Log(uint8)")));
BOOST_CHECK_EQUAL(h256(m_logs[0].data), h256(u256(0)));
// should throw
ABI_CHECK(callContractFunction("test_log()"), encodeArgs());
}
BOOST_AUTO_TEST_CASE(invalid_enum_stored)
{
char const* sourceCode = R"(
contract C {
enum X { A, B }
X public x;
function test_store() public returns (uint) {
X garbled = X.A;
assembly {
garbled := 5
}
x = garbled;
return 1;
}
function test_store_ok() public returns (uint) {
x = X.A;
return 1;
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("test_store_ok()"), encodeArgs(u256(1)));
ABI_CHECK(callContractFunction("x()"), encodeArgs(u256(0)));
// should throw
ABI_CHECK(callContractFunction("test_store()"), encodeArgs());
}
BOOST_AUTO_TEST_CASE(invalid_enum_as_external_ret)
{
char const* sourceCode = R"(
contract C {
enum X { A, B }
function test_return() public returns (X) {
X garbled;
assembly {
garbled := 5
}
return garbled;
}
function test_inline_assignment() public returns (X _ret) {
assembly {
_ret := 5
}
}
function test_assignment() public returns (X _ret) {
X tmp;
assembly {
tmp := 5
}
_ret = tmp;
}
}
)";
compileAndRun(sourceCode, 0, "C");
// both should throw
ABI_CHECK(callContractFunction("test_return()"), encodeArgs());
ABI_CHECK(callContractFunction("test_inline_assignment()"), encodeArgs());
ABI_CHECK(callContractFunction("test_assignment()"), encodeArgs());
}
BOOST_AUTO_TEST_CASE(invalid_enum_as_external_arg)
{
char const* sourceCode = R"(
contract C {
enum X { A, B }
function tested (X x) public returns (uint) {
return 1;
}
function test() public returns (uint) {
X garbled;
assembly {
garbled := 5
}
return this.tested(garbled);
}
}
)";
compileAndRun(sourceCode, 0, "C");
// should throw
ABI_CHECK(callContractFunction("test()"), encodeArgs());
}
BOOST_AUTO_TEST_CASE(proper_order_of_overwriting_of_attributes)
{
// bug #1798
char const* sourceCode = R"(
contract init {
function isOk() public returns (bool) { return false; }
bool public ok = false;
}
contract fix {
function isOk() public returns (bool) { return true; }
bool public ok = true;
}
contract init_fix is init, fix {
function checkOk() public returns (bool) { return ok; }
}
contract fix_init is fix, init {
function checkOk() public returns (bool) { return ok; }
}
)";
compileAndRun(sourceCode, 0, "init_fix");
ABI_CHECK(callContractFunction("isOk()"), encodeArgs(true));
ABI_CHECK(callContractFunction("ok()"), encodeArgs(true));
compileAndRun(sourceCode, 0, "fix_init");
ABI_CHECK(callContractFunction("isOk()"), encodeArgs(false));
ABI_CHECK(callContractFunction("ok()"), encodeArgs(false));
}
BOOST_AUTO_TEST_CASE(struct_assign_reference_to_struct)
{
char const* sourceCode = R"(
contract test {
struct testStruct
{
uint m_value;
}
testStruct data1;
testStruct data2;
testStruct data3;
constructor() public
{
data1.m_value = 2;
}
function assign() public returns (uint ret_local, uint ret_global, uint ret_global3, uint ret_global1)
{
testStruct storage x = data1; //x is a reference data1.m_value == 2 as well as x.m_value = 2
data2 = data1; // should copy data. data2.m_value == 2
ret_local = x.m_value; // = 2
ret_global = data2.m_value; // = 2
x.m_value = 3;
data3 = x; //should copy the data. data3.m_value == 3
ret_global3 = data3.m_value; // = 3
ret_global1 = data1.m_value; // = 3. Changed due to the assignment to x.m_value
}
}
)";
compileAndRun(sourceCode, 0, "test");
ABI_CHECK(callContractFunction("assign()"), encodeArgs(2, 2, 3, 3));
}
BOOST_AUTO_TEST_CASE(struct_delete_member)
{
char const* sourceCode = R"(
contract test {
struct testStruct
{
uint m_value;
}
testStruct data1;
constructor() public
{
data1.m_value = 2;
}
function deleteMember() public returns (uint ret_value)
{
testStruct storage x = data1; //should not copy the data. data1.m_value == 2 but x.m_value = 0
x.m_value = 4;
delete x.m_value;
ret_value = data1.m_value;
}
}
)";
compileAndRun(sourceCode, 0, "test");
ABI_CHECK(callContractFunction("deleteMember()"), encodeArgs(0));
}
BOOST_AUTO_TEST_CASE(struct_delete_struct_in_mapping)
{
char const* sourceCode = R"(
contract test {
struct testStruct
{
uint m_value;
}
mapping (uint => testStruct) campaigns;
constructor() public
{
campaigns[0].m_value = 2;
}
function deleteIt() public returns (uint)
{
delete campaigns[0];
return campaigns[0].m_value;
}
}
)";
compileAndRun(sourceCode, 0, "test");
ABI_CHECK(callContractFunction("deleteIt()"), encodeArgs(0));
}
BOOST_AUTO_TEST_CASE(evm_exceptions_out_of_band_access)
{
char const* sourceCode = R"(
contract A {
uint[3] arr;
bool public test = false;
function getElement(uint i) public returns (uint)
{
return arr[i];
}
function testIt() public returns (bool)
{
uint i = this.getElement(5);
test = true;
return true;
}
}
)";
compileAndRun(sourceCode, 0, "A");
ABI_CHECK(callContractFunction("test()"), encodeArgs(false));
ABI_CHECK(callContractFunction("testIt()"), encodeArgs());
ABI_CHECK(callContractFunction("test()"), encodeArgs(false));
}
BOOST_AUTO_TEST_CASE(evm_exceptions_in_constructor_call_fail)
{
char const* sourceCode = R"(
contract A {
constructor() public
{
address(this).call("123");
}
}
contract B {
uint public test = 1;
function testIt() public
{
A a = new A();
++test;
}
}
)";
compileAndRun(sourceCode, 0, "B");
ABI_CHECK(callContractFunction("testIt()"), encodeArgs());
ABI_CHECK(callContractFunction("test()"), encodeArgs(2));
}
BOOST_AUTO_TEST_CASE(evm_exceptions_in_constructor_out_of_baund)
{
char const* sourceCode = R"(
contract A {
uint public test = 1;
uint[3] arr;
constructor() public
{
uint index = 5;
test = arr[index];
++test;
}
}
)";
ABI_CHECK(compileAndRunWithoutCheck(sourceCode, 0, "A"), encodeArgs());
BOOST_CHECK(!m_transactionSuccessful);
}
BOOST_AUTO_TEST_CASE(positive_integers_to_signed)
{
char const* sourceCode = R"(
contract test {
int8 public x = 2;
int8 public y = 127;
int16 public q = 250;
}
)";
compileAndRun(sourceCode, 0, "test");
ABI_CHECK(callContractFunction("x()"), encodeArgs(2));
ABI_CHECK(callContractFunction("y()"), encodeArgs(127));
ABI_CHECK(callContractFunction("q()"), encodeArgs(250));
}
BOOST_AUTO_TEST_CASE(failing_send)
{
char const* sourceCode = R"(
contract Helper {
uint[] data;
function () external {
data[9]; // trigger exception
}
}
contract Main {
constructor() public payable {}
function callHelper(address payable _a) public returns (bool r, uint bal) {
r = !_a.send(5);
bal = address(this).balance;
}
}
)";
compileAndRun(sourceCode, 0, "Helper");
u160 const c_helperAddress = m_contractAddress;
compileAndRun(sourceCode, 20, "Main");
BOOST_REQUIRE(callContractFunction("callHelper(address)", c_helperAddress) == encodeArgs(true, 20));
}
BOOST_AUTO_TEST_CASE(send_zero_ether)
{
// Sending zero ether to a contract should still invoke the fallback function
// (it previously did not because the gas stipend was not provided by the EVM)
char const* sourceCode = R"(
contract Receiver {
function () external payable {
}
}
contract Main {
constructor() public payable {}
function s() public returns (bool) {
Receiver r = new Receiver();
return address(r).send(0);
}
}
)";
compileAndRun(sourceCode, 20, "Main");
BOOST_REQUIRE(callContractFunction("s()") == encodeArgs(true));
}
BOOST_AUTO_TEST_CASE(reusing_memory)
{
// Invoke some features that use memory and test that they do not interfere with each other.
char const* sourceCode = R"(
contract Helper {
uint public flag;
constructor(uint x) public {
flag = x;
}
}
contract Main {
mapping(uint => uint) map;
function f(uint x) public returns (uint) {
map[x] = x;
return (new Helper(uint(keccak256(abi.encodePacked(this.g(map[x])))))).flag();
}
function g(uint a) public returns (uint)
{
return map[a];
}
}
)";
compileAndRun(sourceCode, 0, "Main");
BOOST_REQUIRE(callContractFunction("f(uint256)", 0x34) == encodeArgs(dev::keccak256(dev::toBigEndian(u256(0x34)))));
}
BOOST_AUTO_TEST_CASE(return_string)
{
char const* sourceCode = R"(
contract Main {
string public s;
function set(string calldata _s) external {
s = _s;
}
function get1() public returns (string memory r) {
return s;
}
function get2() public returns (string memory r) {
r = s;
}
}
)";
compileAndRun(sourceCode, 0, "Main");
string s("Julia");
bytes args = encodeArgs(u256(0x20), u256(s.length()), s);
BOOST_REQUIRE(callContractFunction("set(string)", asString(args)) == encodeArgs());
ABI_CHECK(callContractFunction("get1()"), args);
ABI_CHECK(callContractFunction("get2()"), args);
ABI_CHECK(callContractFunction("s()"), args);
}
BOOST_AUTO_TEST_CASE(return_multiple_strings_of_various_sizes)
{
char const* sourceCode = R"(
contract Main {
string public s1;
string public s2;
function set(string calldata _s1, uint x, string calldata _s2) external returns (uint) {
s1 = _s1;
s2 = _s2;
return x;
}
function get() public returns (string memory r1, string memory r2) {
r1 = s1;
r2 = s2;
}
}
)";
compileAndRun(sourceCode, 0, "Main");
string s1(
"abcdefghijklmnopqrstuvwxyzabcdefghijklmnopqrstuvwxyzabcdefghijklmnopqrstuvwxyz"
"abcdefghijklmnopqrstuvwxyzabcdefghijklmnopqrstuvwxyzabcdefghijklmnopqrstuvwxyz"
"abcdefghijklmnopqrstuvwxyzabcdefghijklmnopqrstuvwxyzabcdefghijklmnopqrstuvwxyz"
"abcdefghijklmnopqrstuvwxyzabcdefghijklmnopqrstuvwxyzabcdefghijklmnopqrstuvwxyz"
);
string s2(
"ABCDEFGHIJKLMNOPQRSTUVXYZABCDEFGHIJKLMNOPQRSTUVXYZABCDEFGHIJKLMNOPQRSTUVXYZ"
"ABCDEFGHIJKLMNOPQRSTUVXYZABCDEFGHIJKLMNOPQRSTUVXYZABCDEFGHIJKLMNOPQRSTUVXYZ"
"ABCDEFGHIJKLMNOPQRSTUVXYZABCDEFGHIJKLMNOPQRSTUVXYZABCDEFGHIJKLMNOPQRSTUVXYZ"
"ABCDEFGHIJKLMNOPQRSTUVXYZABCDEFGHIJKLMNOPQRSTUVXYZABCDEFGHIJKLMNOPQRSTUVXYZ"
"ABCDEFGHIJKLMNOPQRSTUVXYZABCDEFGHIJKLMNOPQRSTUVXYZABCDEFGHIJKLMNOPQRSTUVXYZ"
);
vector<size_t> lengths{0, 30, 32, 63, 64, 65, 210, 300};
for (auto l1: lengths)
for (auto l2: lengths)
{
bytes dyn1 = encodeArgs(u256(l1), s1.substr(0, l1));
bytes dyn2 = encodeArgs(u256(l2), s2.substr(0, l2));
bytes args = encodeArgs(u256(0x60), u256(l1), u256(0x60 + dyn1.size())) + dyn1 + dyn2;
BOOST_REQUIRE(
callContractFunction("set(string,uint256,string)", asString(args)) ==
encodeArgs(u256(l1))
);
bytes result = encodeArgs(u256(0x40), u256(0x40 + dyn1.size())) + dyn1 + dyn2;
ABI_CHECK(callContractFunction("get()"), result);
ABI_CHECK(callContractFunction("s1()"), encodeArgs(0x20) + dyn1);
ABI_CHECK(callContractFunction("s2()"), encodeArgs(0x20) + dyn2);
}
}
BOOST_AUTO_TEST_CASE(accessor_involving_strings)
{
char const* sourceCode = R"(
contract Main {
struct stringData { string a; uint b; string c; }
mapping(uint => stringData[]) public data;
function set(uint x, uint y, string calldata a, uint b, string calldata c) external returns (bool) {
data[x].length = y + 1;
data[x][y].a = a;
data[x][y].b = b;
data[x][y].c = c;
return true;
}
}
)";
compileAndRun(sourceCode, 0, "Main");
string s1("abcdefghijklmnopqrstuvwxyzabcdefghijklmnopqrstuvwxyzabcdefghijklmnopqrstuvwxyz");
string s2("ABCDEFGHIJKLMNOPQRSTUVXYZABCDEFGHIJKLMNOPQRSTUVXYZABCDEFGHIJKLMNOPQRSTUVXYZ");
bytes s1Data = encodeArgs(u256(s1.length()), s1);
bytes s2Data = encodeArgs(u256(s2.length()), s2);
u256 b = 765;
u256 x = 7;
u256 y = 123;
bytes args = encodeArgs(x, y, u256(0xa0), b, u256(0xa0 + s1Data.size()), s1Data, s2Data);
bytes result = encodeArgs(u256(0x60), b, u256(0x60 + s1Data.size()), s1Data, s2Data);
BOOST_REQUIRE(callContractFunction("set(uint256,uint256,string,uint256,string)", asString(args)) == encodeArgs(true));
BOOST_REQUIRE(callContractFunction("data(uint256,uint256)", x, y) == result);
}
BOOST_AUTO_TEST_CASE(bytes_in_function_calls)
{
char const* sourceCode = R"(
contract Main {
string public s1;
string public s2;
function set(string memory _s1, uint x, string memory _s2) public returns (uint) {
s1 = _s1;
s2 = _s2;
return x;
}
function setIndirectFromMemory(string memory _s1, uint x, string memory _s2) public returns (uint) {
return this.set(_s1, x, _s2);
}
function setIndirectFromCalldata(string calldata _s1, uint x, string calldata _s2) external returns (uint) {
return this.set(_s1, x, _s2);
}
}
)";
compileAndRun(sourceCode, 0, "Main");
string s1("abcdefghijklmnopqrstuvwxyzabcdefghijklmnopqrstuvwxyzabcdefghijklmnopqrstuvwxyz");
string s2("ABCDEFGHIJKLMNOPQRSTUVXYZABCDEFGHIJKLMNOPQRSTUVXYZABCDEFGHIJKLMNOPQRSTUVXYZ");
vector<size_t> lengths{0, 31, 64, 65};
for (auto l1: lengths)
for (auto l2: lengths)
{
bytes dyn1 = encodeArgs(u256(l1), s1.substr(0, l1));
bytes dyn2 = encodeArgs(u256(l2), s2.substr(0, l2));
bytes args1 = encodeArgs(u256(0x60), u256(l1), u256(0x60 + dyn1.size())) + dyn1 + dyn2;
BOOST_REQUIRE(
callContractFunction("setIndirectFromMemory(string,uint256,string)", asString(args1)) ==
encodeArgs(u256(l1))
);
ABI_CHECK(callContractFunction("s1()"), encodeArgs(0x20) + dyn1);
ABI_CHECK(callContractFunction("s2()"), encodeArgs(0x20) + dyn2);
// swapped
bytes args2 = encodeArgs(u256(0x60), u256(l1), u256(0x60 + dyn2.size())) + dyn2 + dyn1;
BOOST_REQUIRE(
callContractFunction("setIndirectFromCalldata(string,uint256,string)", asString(args2)) ==
encodeArgs(u256(l1))
);
ABI_CHECK(callContractFunction("s1()"), encodeArgs(0x20) + dyn2);
ABI_CHECK(callContractFunction("s2()"), encodeArgs(0x20) + dyn1);
}
}
BOOST_AUTO_TEST_CASE(return_bytes_internal)
{
char const* sourceCode = R"(
contract Main {
bytes s1;
function doSet(bytes memory _s1) public returns (bytes memory _r1) {
s1 = _s1;
_r1 = s1;
}
function set(bytes calldata _s1) external returns (uint _r, bytes memory _r1) {
_r1 = doSet(_s1);
_r = _r1.length;
}
}
)";
compileAndRun(sourceCode, 0, "Main");
string s1("abcdefghijklmnopqrstuvwxyzabcdefghijklmnopqrstuvwxyzabcdefghijklmnopqrstuvwxyz");
vector<size_t> lengths{0, 31, 64, 65};
for (auto l1: lengths)
{
bytes dyn1 = encodeArgs(u256(l1), s1.substr(0, l1));
bytes args1 = encodeArgs(u256(0x20)) + dyn1;
BOOST_REQUIRE(
callContractFunction("set(bytes)", asString(args1)) ==
encodeArgs(u256(l1), u256(0x40)) + dyn1
);
}
}
BOOST_AUTO_TEST_CASE(bytes_index_access_memory)
{
char const* sourceCode = R"(
contract Main {
function f(bytes memory _s1, uint i1, uint i2, uint i3) public returns (byte c1, byte c2, byte c3) {
c1 = _s1[i1];
c2 = intern(_s1, i2);
c3 = internIndirect(_s1)[i3];
}
function intern(bytes memory _s1, uint i) public returns (byte c) {
return _s1[i];
}
function internIndirect(bytes memory _s1) public returns (bytes memory) {
return _s1;
}
}
)";
compileAndRun(sourceCode, 0, "Main");
string s1("abcdefghijklmnopqrstuvwxyzabcdefghijklmnopqrstuvwxyzabcdefghijklmnopqrstuvwxyz");
bytes dyn1 = encodeArgs(u256(s1.length()), s1);
bytes args1 = encodeArgs(u256(0x80), u256(3), u256(4), u256(5)) + dyn1;
BOOST_REQUIRE(
callContractFunction("f(bytes,uint256,uint256,uint256)", asString(args1)) ==
encodeArgs(string{s1[3]}, string{s1[4]}, string{s1[5]})
);
}
BOOST_AUTO_TEST_CASE(bytes_in_constructors_unpacker)
{
char const* sourceCode = R"(
contract Test {
uint public m_x;
bytes public m_s;
constructor(uint x, bytes memory s) public {
m_x = x;
m_s = s;
}
}
)";
string s1("abcdefghijklmnopqrstuvwxyzabcdefghijklmnopqrstuvwxyzabcdefghijklmnopqrstuvwxyz");
bytes dyn1 = encodeArgs(u256(s1.length()), s1);
u256 x = 7;
bytes args1 = encodeArgs(x, u256(0x40)) + dyn1;
compileAndRun(sourceCode, 0, "Test", args1);
BOOST_REQUIRE(callContractFunction("m_x()") == encodeArgs(x));
BOOST_REQUIRE(callContractFunction("m_s()") == encodeArgs(u256(0x20)) + dyn1);
}
BOOST_AUTO_TEST_CASE(bytes_in_constructors_packer)
{
char const* sourceCode = R"(
contract Base {
uint public m_x;
bytes m_s;
constructor(uint x, bytes memory s) public {
m_x = x;
m_s = s;
}
function part(uint i) public returns (byte) {
return m_s[i];
}
}
contract Main is Base {
constructor(bytes memory s, uint x) Base(x, f(s)) public {}
function f(bytes memory s) public returns (bytes memory) {
return s;
}
}
contract Creator {
function f(uint x, bytes memory s) public returns (uint r, byte ch) {
Main c = new Main(s, x);
r = c.m_x();
ch = c.part(x);
}
}
)";
compileAndRun(sourceCode, 0, "Creator");
string s1("abcdefghijklmnopqrstuvwxyzabcdefghijklmnopqrstuvwxyzabcdefghijklmnopqrstuvwxyz");
bytes dyn1 = encodeArgs(u256(s1.length()), s1);
u256 x = 7;
bytes args1 = encodeArgs(x, u256(0x40)) + dyn1;
BOOST_REQUIRE(
callContractFunction("f(uint256,bytes)", asString(args1)) ==
encodeArgs(x, string{s1[unsigned(x)]})
);
}
BOOST_AUTO_TEST_CASE(arrays_in_constructors)
{
char const* sourceCode = R"(
contract Base {
uint public m_x;
address[] m_s;
constructor(uint x, address[] memory s) public {
m_x = x;
m_s = s;
}
function part(uint i) public returns (address) {
return m_s[i];
}
}
contract Main is Base {
constructor(address[] memory s, uint x) Base(x, f(s)) public {}
function f(address[] memory s) public returns (address[] memory) {
return s;
}
}
contract Creator {
function f(uint x, address[] memory s) public returns (uint r, address ch) {
Main c = new Main(s, x);
r = c.m_x();
ch = c.part(x);
}
}
)";
compileAndRun(sourceCode, 0, "Creator");
vector<u256> s1{1, 2, 3, 4, 5, 6, 7, 8, 9, 10};
bytes dyn1 = encodeArgs(u256(s1.size()), s1);
u256 x = 7;
bytes args1 = encodeArgs(x, u256(0x40)) + dyn1;
BOOST_REQUIRE(
callContractFunction("f(uint256,address[])", asString(args1)) ==
encodeArgs(x, s1[unsigned(x)])
);
}
BOOST_AUTO_TEST_CASE(fixed_arrays_in_constructors)
{
char const* sourceCode = R"(
contract Creator {
uint public r;
address public ch;
constructor(address[3] memory s, uint x) public {
r = x;
ch = s[2];
}
}
)";
compileAndRun(sourceCode, 0, "Creator", encodeArgs(u256(1), u256(2), u256(3), u256(4)));
BOOST_REQUIRE(callContractFunction("r()") == encodeArgs(u256(4)));
BOOST_REQUIRE(callContractFunction("ch()") == encodeArgs(u256(3)));
}
BOOST_AUTO_TEST_CASE(arrays_from_and_to_storage)
{
char const* sourceCode = R"(
contract Test {
uint24[] public data;
function set(uint24[] memory _data) public returns (uint) {
data = _data;
return data.length;
}
function get() public returns (uint24[] memory) {
return data;
}
}
)";
compileAndRun(sourceCode, 0, "Test");
vector<u256> data{1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18};
BOOST_REQUIRE(
callContractFunction("set(uint24[])", u256(0x20), u256(data.size()), data) ==
encodeArgs(u256(data.size()))
);
ABI_CHECK(callContractFunction("data(uint256)", u256(7)), encodeArgs(u256(8)));
ABI_CHECK(callContractFunction("data(uint256)", u256(15)), encodeArgs(u256(16)));
ABI_CHECK(callContractFunction("data(uint256)", u256(18)), encodeArgs());
ABI_CHECK(callContractFunction("get()"), encodeArgs(u256(0x20), u256(data.size()), data));
}
BOOST_AUTO_TEST_CASE(arrays_complex_from_and_to_storage)
{
char const* sourceCode = R"(
contract Test {
uint24[3][] public data;
function set(uint24[3][] memory _data) public returns (uint) {
data = _data;
return data.length;
}
function get() public returns (uint24[3][] memory) {
return data;
}
}
)";
compileAndRun(sourceCode, 0, "Test");
vector<u256> data{1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18};
BOOST_REQUIRE(
callContractFunction("set(uint24[3][])", u256(0x20), u256(data.size() / 3), data) ==
encodeArgs(u256(data.size() / 3))
);
ABI_CHECK(callContractFunction("data(uint256,uint256)", u256(2), u256(2)), encodeArgs(u256(9)));
ABI_CHECK(callContractFunction("data(uint256,uint256)", u256(5), u256(1)), encodeArgs(u256(17)));
ABI_CHECK(callContractFunction("data(uint256,uint256)", u256(6), u256(0)), encodeArgs());
ABI_CHECK(callContractFunction("get()"), encodeArgs(u256(0x20), u256(data.size() / 3), data));
}
BOOST_AUTO_TEST_CASE(arrays_complex_memory_index_access)
{
char const* sourceCode = R"(
contract Test {
function set(uint24[3][] memory _data, uint a, uint b) public returns (uint l, uint e) {
l = _data.length;
e = _data[a][b];
}
}
)";
compileAndRun(sourceCode, 0, "Test");
vector<u256> data{1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18};
BOOST_REQUIRE(callContractFunction(
"set(uint24[3][],uint256,uint256)",
u256(0x60),
u256(3),
u256(2),
u256(data.size() / 3),
data
) == encodeArgs(u256(data.size() / 3), u256(data[3 * 3 + 2])));
}
BOOST_AUTO_TEST_CASE(bytes_memory_index_access)
{
char const* sourceCode = R"(
contract Test {
function set(bytes memory _data, uint i) public returns (uint l, byte c) {
l = _data.length;
c = _data[i];
}
}
)";
compileAndRun(sourceCode, 0, "Test");
string data("abcdefgh");
BOOST_REQUIRE(callContractFunction(
"set(bytes,uint256)",
u256(0x40),
u256(3),
u256(data.size()),
data
) == encodeArgs(u256(data.size()), string("d")));
}
BOOST_AUTO_TEST_CASE(storage_array_ref)
{
char const* sourceCode = R"(
contract BinarySearch {
/// Finds the position of _value in the sorted list _data.
/// Note that "internal" is important here, because storage references only work for internal or private functions
function find(uint[] storage _data, uint _value) internal returns (uint o_position) {
return find(_data, 0, _data.length, _value);
}
function find(uint[] storage _data, uint _begin, uint _len, uint _value) private returns (uint o_position) {
if (_len == 0 || (_len == 1 && _data[_begin] != _value))
return uint(-1); // failure
uint halfLen = _len / 2;
uint v = _data[_begin + halfLen];
if (_value < v)
return find(_data, _begin, halfLen, _value);
else if (_value > v)
return find(_data, _begin + halfLen + 1, halfLen - 1, _value);
else
return _begin + halfLen;
}
}
contract Store is BinarySearch {
uint[] data;
function add(uint v) public {
data.length++;
data[data.length - 1] = v;
}
function find(uint v) public returns (uint) {
return find(data, v);
}
}
)";
compileAndRun(sourceCode, 0, "Store");
BOOST_REQUIRE(callContractFunction("find(uint256)", u256(7)) == encodeArgs(u256(-1)));
BOOST_REQUIRE(callContractFunction("add(uint256)", u256(7)) == encodeArgs());
BOOST_REQUIRE(callContractFunction("find(uint256)", u256(7)) == encodeArgs(u256(0)));
ABI_CHECK(callContractFunction("add(uint256)", u256(11)), encodeArgs());
ABI_CHECK(callContractFunction("add(uint256)", u256(17)), encodeArgs());
ABI_CHECK(callContractFunction("add(uint256)", u256(27)), encodeArgs());
ABI_CHECK(callContractFunction("add(uint256)", u256(31)), encodeArgs());
ABI_CHECK(callContractFunction("add(uint256)", u256(32)), encodeArgs());
ABI_CHECK(callContractFunction("add(uint256)", u256(66)), encodeArgs());
ABI_CHECK(callContractFunction("add(uint256)", u256(177)), encodeArgs());
ABI_CHECK(callContractFunction("find(uint256)", u256(7)), encodeArgs(u256(0)));
ABI_CHECK(callContractFunction("find(uint256)", u256(27)), encodeArgs(u256(3)));
ABI_CHECK(callContractFunction("find(uint256)", u256(32)), encodeArgs(u256(5)));
ABI_CHECK(callContractFunction("find(uint256)", u256(176)), encodeArgs(u256(-1)));
ABI_CHECK(callContractFunction("find(uint256)", u256(0)), encodeArgs(u256(-1)));
ABI_CHECK(callContractFunction("find(uint256)", u256(400)), encodeArgs(u256(-1)));
}
BOOST_AUTO_TEST_CASE(memory_types_initialisation)
{
char const* sourceCode = R"(
contract Test {
mapping(uint=>uint) data;
function stat() public returns (uint[5] memory)
{
data[2] = 3; // make sure to use some memory
}
function dyn() public returns (uint[] memory) { stat(); }
function nested() public returns (uint[3][] memory) { stat(); }
function nestedStat() public returns (uint[3][7] memory) { stat(); }
}
)";
compileAndRun(sourceCode, 0, "Test");
ABI_CHECK(callContractFunction("stat()"), encodeArgs(vector<u256>(5)));
ABI_CHECK(callContractFunction("dyn()"), encodeArgs(u256(0x20), u256(0)));
ABI_CHECK(callContractFunction("nested()"), encodeArgs(u256(0x20), u256(0)));
ABI_CHECK(callContractFunction("nestedStat()"), encodeArgs(vector<u256>(3 * 7)));
}
BOOST_AUTO_TEST_CASE(memory_arrays_delete)
{
char const* sourceCode = R"(
contract Test {
function del() public returns (uint24[3][4] memory) {
uint24[3][4] memory x;
for (uint24 i = 0; i < x.length; i ++)
for (uint24 j = 0; j < x[i].length; j ++)
x[i][j] = i * 0x10 + j;
delete x[1];
delete x[3][2];
return x;
}
}
)";
compileAndRun(sourceCode, 0, "Test");
vector<u256> data(3 * 4);
for (unsigned i = 0; i < 4; i++)
for (unsigned j = 0; j < 3; j++)
{
u256 v = 0;
if (!(i == 1 || (i == 3 && j == 2)))
v = i * 0x10 + j;
data[i * 3 + j] = v;
}
ABI_CHECK(callContractFunction("del()"), encodeArgs(data));
}
BOOST_AUTO_TEST_CASE(memory_arrays_index_access_write)
{
char const* sourceCode = R"(
contract Test {
function set(uint24[3][4] memory x) public {
x[2][2] = 1;
x[3][2] = 7;
}
function f() public returns (uint24[3][4] memory){
uint24[3][4] memory data;
set(data);
return data;
}
}
)";
compileAndRun(sourceCode, 0, "Test");
vector<u256> data(3 * 4);
data[3 * 2 + 2] = 1;
data[3 * 3 + 2] = 7;
ABI_CHECK(callContractFunction("f()"), encodeArgs(data));
}
BOOST_AUTO_TEST_CASE(memory_arrays_dynamic_index_access_write)
{
char const* sourceCode = R"(
contract Test {
uint24[3][][4] data;
function set(uint24[3][][4] memory x) internal returns (uint24[3][][4] memory) {
x[1][2][2] = 1;
x[1][3][2] = 7;
return x;
}
function f() public returns (uint24[3][] memory) {
data[1].length = 4;
return set(data)[1];
}
}
)";
compileAndRun(sourceCode, 0, "Test");
vector<u256> data(3 * 4);
data[3 * 2 + 2] = 1;
data[3 * 3 + 2] = 7;
ABI_CHECK(callContractFunction("f()"), encodeArgs(u256(0x20), u256(4), data));
}
BOOST_AUTO_TEST_CASE(memory_structs_read_write)
{
char const* sourceCode = R"(
contract Test {
struct S { uint8 x; uint16 y; uint z; uint8[2] a; }
S[5] data;
function testInit() public returns (uint8 x, uint16 y, uint z, uint8 a, bool flag) {
S[2] memory d;
x = d[0].x;
y = d[0].y;
z = d[0].z;
a = d[0].a[1];
flag = true;
}
function testCopyRead() public returns (uint8 x, uint16 y, uint z, uint8 a) {
data[2].x = 1;
data[2].y = 2;
data[2].z = 3;
data[2].a[1] = 4;
S memory s = data[2];
x = s.x;
y = s.y;
z = s.z;
a = s.a[1];
}
function testAssign() public returns (uint8 x, uint16 y, uint z, uint8 a) {
S memory s;
s.x = 1;
s.y = 2;
s.z = 3;
s.a[1] = 4;
x = s.x;
y = s.y;
z = s.z;
a = s.a[1];
}
}
)";
compileAndRun(sourceCode, 0, "Test");
ABI_CHECK(callContractFunction("testInit()"), encodeArgs(u256(0), u256(0), u256(0), u256(0), true));
ABI_CHECK(callContractFunction("testCopyRead()"), encodeArgs(u256(1), u256(2), u256(3), u256(4)));
ABI_CHECK(callContractFunction("testAssign()"), encodeArgs(u256(1), u256(2), u256(3), u256(4)));
}
BOOST_AUTO_TEST_CASE(memory_structs_as_function_args)
{
char const* sourceCode = R"(
contract Test {
struct S { uint8 x; uint16 y; uint z; }
function test() public returns (uint x, uint y, uint z) {
S memory data = combine(1, 2, 3);
x = extract(data, 0);
y = extract(data, 1);
z = extract(data, 2);
}
function extract(S memory s, uint which) internal returns (uint x) {
if (which == 0) return s.x;
else if (which == 1) return s.y;
else return s.z;
}
function combine(uint8 x, uint16 y, uint z) internal returns (S memory s) {
s.x = x;
s.y = y;
s.z = z;
}
}
)";
compileAndRun(sourceCode, 0, "Test");
ABI_CHECK(callContractFunction("test()"), encodeArgs(u256(1), u256(2), u256(3)));
}
BOOST_AUTO_TEST_CASE(memory_structs_nested)
{
char const* sourceCode = R"(
contract Test {
struct S { uint8 x; uint16 y; uint z; }
struct X { uint8 x; S s; }
function test() public returns (uint a, uint x, uint y, uint z) {
X memory d = combine(1, 2, 3, 4);
a = extract(d, 0);
x = extract(d, 1);
y = extract(d, 2);
z = extract(d, 3);
}
function extract(X memory s, uint which) internal returns (uint x) {
if (which == 0) return s.x;
else if (which == 1) return s.s.x;
else if (which == 2) return s.s.y;
else return s.s.z;
}
function combine(uint8 a, uint8 x, uint16 y, uint z) internal returns (X memory s) {
s.x = a;
s.s.x = x;
s.s.y = y;
s.s.z = z;
}
}
)";
compileAndRun(sourceCode, 0, "Test");
ABI_CHECK(callContractFunction("test()"), encodeArgs(u256(1), u256(2), u256(3), u256(4)));
}
BOOST_AUTO_TEST_CASE(memory_structs_nested_load)
{
char const* sourceCode = R"(
contract Test {
struct S { uint8 x; uint16 y; uint z; }
struct X { uint8 x; S s; uint8[2] a; }
X m_x;
function load() public returns (uint a, uint x, uint y, uint z, uint a1, uint a2) {
m_x.x = 1;
m_x.s.x = 2;
m_x.s.y = 3;
m_x.s.z = 4;
m_x.a[0] = 5;
m_x.a[1] = 6;
X memory d = m_x;
a = d.x;
x = d.s.x;
y = d.s.y;
z = d.s.z;
a1 = d.a[0];
a2 = d.a[1];
}
function store() public returns (uint a, uint x, uint y, uint z, uint a1, uint a2) {
X memory d;
d.x = 1;
d.s.x = 2;
d.s.y = 3;
d.s.z = 4;
d.a[0] = 5;
d.a[1] = 6;
m_x = d;
a = m_x.x;
x = m_x.s.x;
y = m_x.s.y;
z = m_x.s.z;
a1 = m_x.a[0];
a2 = m_x.a[1];
}
}
)";
compileAndRun(sourceCode, 0, "Test");
auto out = encodeArgs(u256(1), u256(2), u256(3), u256(4), u256(5), u256(6));
ABI_CHECK(callContractFunction("load()"), out);
ABI_CHECK(callContractFunction("store()"), out);
}
BOOST_AUTO_TEST_CASE(struct_constructor_nested)
{
char const* sourceCode = R"(
contract C {
struct X { uint x1; uint x2; }
struct S { uint s1; uint[3] s2; X s3; }
S s;
constructor() public {
uint[3] memory s2;
s2[1] = 9;
s = S(1, s2, X(4, 5));
}
function get() public returns (uint s1, uint[3] memory s2, uint x1, uint x2)
{
s1 = s.s1;
s2 = s.s2;
x1 = s.s3.x1;
x2 = s.s3.x2;
}
}
)";
compileAndRun(sourceCode, 0, "C");
auto out = encodeArgs(u256(1), u256(0), u256(9), u256(0), u256(4), u256(5));
ABI_CHECK(callContractFunction("get()"), out);
}
BOOST_AUTO_TEST_CASE(struct_named_constructor)
{
char const* sourceCode = R"(
contract C {
struct S { uint a; bool x; }
S public s;
constructor() public {
s = S({a: 1, x: true});
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("s()"), encodeArgs(u256(1), true));
}
BOOST_AUTO_TEST_CASE(calldata_array)
{
char const* sourceCode = R"(
pragma experimental ABIEncoderV2;
contract C {
function f(uint[2] calldata s) external pure returns (uint256 a, uint256 b) {
a = s[0];
b = s[1];
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("f(uint256[2])", encodeArgs(u256(42), u256(23))), encodeArgs(u256(42), u256(23)));
}
BOOST_AUTO_TEST_CASE(calldata_struct)
{
char const* sourceCode = R"(
pragma experimental ABIEncoderV2;
contract C {
struct S { uint256 a; uint256 b; }
function f(S calldata s) external pure returns (uint256 a, uint256 b) {
a = s.a;
b = s.b;
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("f((uint256,uint256))", encodeArgs(u256(42), u256(23))), encodeArgs(u256(42), u256(23)));
}
BOOST_AUTO_TEST_CASE(calldata_struct_and_ints)
{
char const* sourceCode = R"(
pragma experimental ABIEncoderV2;
contract C {
struct S { uint256 a; uint256 b; }
function f(uint256 a, S calldata s, uint256 b) external pure returns (uint256, uint256, uint256, uint256) {
return (a, s.a, s.b, b);
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("f(uint256,(uint256,uint256),uint256)", encodeArgs(u256(1), u256(2), u256(3), u256(4))), encodeArgs(u256(1), u256(2), u256(3), u256(4)));
}
BOOST_AUTO_TEST_CASE(calldata_structs)
{
char const* sourceCode = R"(
pragma experimental ABIEncoderV2;
contract C {
struct S1 { uint256 a; uint256 b; }
struct S2 { uint256 a; }
function f(S1 calldata s1, S2 calldata s2, S1 calldata s3)
external pure returns (uint256 a, uint256 b, uint256 c, uint256 d, uint256 e) {
a = s1.a;
b = s1.b;
c = s2.a;
d = s3.a;
e = s3.b;
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("f((uint256,uint256),(uint256),(uint256,uint256))", encodeArgs(u256(1), u256(2), u256(3), u256(4), u256(5))), encodeArgs(u256(1), u256(2), u256(3), u256(4), u256(5)));
}
BOOST_AUTO_TEST_CASE(calldata_struct_array_member)
{
char const* sourceCode = R"(
pragma experimental ABIEncoderV2;
contract C {
struct S { uint256 a; uint256[2] b; uint256 c; }
function f(S calldata s) external pure returns (uint256 a, uint256 b0, uint256 b1, uint256 c) {
a = s.a;
b0 = s.b[0];
b1 = s.b[1];
c = s.c;
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("f((uint256,uint256[2],uint256))", encodeArgs(u256(42), u256(1), u256(2), u256(23))), encodeArgs(u256(42), u256(1), u256(2), u256(23)));
}
BOOST_AUTO_TEST_CASE(calldata_array_of_struct)
{
char const* sourceCode = R"(
pragma experimental ABIEncoderV2;
contract C {
struct S { uint256 a; uint256 b; }
function f(S[] calldata s) external pure returns (uint256 l, uint256 a, uint256 b, uint256 c, uint256 d) {
l = s.length;
a = s[0].a;
b = s[0].b;
c = s[1].a;
d = s[1].b;
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("f((uint256,uint256)[])", encodeArgs(u256(0x20), u256(2), u256(1), u256(2), u256(3), u256(4))), encodeArgs(u256(2), u256(1), u256(2), u256(3), u256(4)));
}
BOOST_AUTO_TEST_CASE(calldata_array_of_struct_to_memory)
{
char const* sourceCode = R"(
pragma experimental ABIEncoderV2;
contract C {
struct S { uint256 a; uint256 b; }
function f(S[] calldata s) external pure returns (uint256 l, uint256 a, uint256 b, uint256 c, uint256 d) {
S[] memory m = s;
l = m.length;
a = m[0].a;
b = m[0].b;
c = m[1].a;
d = m[1].b;
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("f((uint256,uint256)[])", encodeArgs(u256(0x20), u256(2), u256(1), u256(2), u256(3), u256(4))), encodeArgs(u256(2), u256(1), u256(2), u256(3), u256(4)));
}
BOOST_AUTO_TEST_CASE(calldata_struct_to_memory)
{
char const* sourceCode = R"(
pragma experimental ABIEncoderV2;
contract C {
struct S { uint256 a; uint256 b; }
function f(S calldata s) external pure returns (uint256, uint256) {
S memory m = s;
return (m.a, m.b);
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("f((uint256,uint256))", encodeArgs(u256(42), u256(23))), encodeArgs(u256(42), u256(23)));
}
BOOST_AUTO_TEST_CASE(nested_calldata_struct)
{
char const* sourceCode = R"(
pragma experimental ABIEncoderV2;
contract C {
struct S1 { uint256 a; uint256 b; }
struct S2 { uint256 a; uint256 b; S1 s; uint256 c; }
function f(S2 calldata s) external pure returns (uint256 a, uint256 b, uint256 sa, uint256 sb, uint256 c) {
return (s.a, s.b, s.s.a, s.s.b, s.c);
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("f((uint256,uint256,(uint256,uint256),uint256))", encodeArgs(u256(1), u256(2), u256(3), u256(4), u256(5))), encodeArgs(u256(1), u256(2), u256(3), u256(4), u256(5)));
}
BOOST_AUTO_TEST_CASE(nested_calldata_struct_to_memory)
{
char const* sourceCode = R"(
pragma experimental ABIEncoderV2;
contract C {
struct S1 { uint256 a; uint256 b; }
struct S2 { uint256 a; uint256 b; S1 s; uint256 c; }
function f(S2 calldata s) external pure returns (uint256 a, uint256 b, uint256 sa, uint256 sb, uint256 c) {
S2 memory m = s;
return (m.a, m.b, m.s.a, m.s.b, m.c);
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("f((uint256,uint256,(uint256,uint256),uint256))", encodeArgs(u256(1), u256(2), u256(3), u256(4), u256(5))), encodeArgs(u256(1), u256(2), u256(3), u256(4), u256(5)));
}
BOOST_AUTO_TEST_CASE(calldata_struct_short)
{
char const* sourceCode = R"(
pragma experimental ABIEncoderV2;
contract C {
struct S { uint256 a; uint256 b; }
function f(S calldata) external pure returns (uint256) {
return msg.data.length;
}
}
)";
compileAndRun(sourceCode, 0, "C");
// double check that the valid case goes through
ABI_CHECK(callContractFunction("f((uint256,uint256))", u256(1), u256(2)), encodeArgs(0x44));
ABI_CHECK(callContractFunctionNoEncoding("f((uint256,uint256))", bytes(63,0)), encodeArgs());
ABI_CHECK(callContractFunctionNoEncoding("f((uint256,uint256))", bytes(33,0)), encodeArgs());
ABI_CHECK(callContractFunctionNoEncoding("f((uint256,uint256))", bytes(32,0)), encodeArgs());
ABI_CHECK(callContractFunctionNoEncoding("f((uint256,uint256))", bytes(31,0)), encodeArgs());
ABI_CHECK(callContractFunctionNoEncoding("f((uint256,uint256))", bytes()), encodeArgs());
}
BOOST_AUTO_TEST_CASE(calldata_struct_cleaning)
{
char const* sourceCode = R"(
pragma experimental ABIEncoderV2;
contract C {
struct S { uint8 a; bytes1 b; }
function f(S calldata s) external pure returns (uint256 a, bytes32 b) {
uint8 tmp1 = s.a;
bytes1 tmp2 = s.b;
assembly {
a := tmp1
b := tmp2
}
}
}
)";
compileAndRun(sourceCode, 0, "C");
// double check that the valid case goes through
ABI_CHECK(callContractFunction("f((uint8,bytes1))", u256(0x12), bytes{0x34} + bytes(31,0)), encodeArgs(0x12, bytes{0x34} + bytes(31,0)));
ABI_CHECK(callContractFunction("f((uint8,bytes1))", u256(0x1234), bytes{0x56, 0x78} + bytes(30,0)), encodeArgs());
ABI_CHECK(callContractFunction("f((uint8,bytes1))", u256(-1), u256(-1)), encodeArgs());
}
BOOST_AUTO_TEST_CASE(calldata_struct_function_type)
{
char const* sourceCode = R"(
pragma experimental ABIEncoderV2;
contract C {
struct S { function (uint) external returns (uint) fn; }
function f(S calldata s) external returns (uint256) {
return s.fn(42);
}
function g(uint256 a) external returns (uint256) {
return a * 3;
}
function h(uint256 a) external returns (uint256) {
return 23;
}
}
)";
compileAndRun(sourceCode, 0, "C");
bytes fn_C_g = m_contractAddress.asBytes() + FixedHash<4>(dev::keccak256("g(uint256)")).asBytes() + bytes(8,0);
bytes fn_C_h = m_contractAddress.asBytes() + FixedHash<4>(dev::keccak256("h(uint256)")).asBytes() + bytes(8,0);
ABI_CHECK(callContractFunctionNoEncoding("f((function))", fn_C_g), encodeArgs(42 * 3));
ABI_CHECK(callContractFunctionNoEncoding("f((function))", fn_C_h), encodeArgs(23));
}
BOOST_AUTO_TEST_CASE(calldata_array_dynamic_bytes)
{
char const* sourceCode = R"(
pragma experimental ABIEncoderV2;
contract C {
function f1(bytes[1] calldata a) external returns (uint256, uint256, uint256, uint256) {
return (a[0].length, uint8(a[0][0]), uint8(a[0][1]), uint8(a[0][2]));
}
function f2(bytes[1] calldata a, bytes[1] calldata b) external returns (uint256, uint256, uint256, uint256, uint256, uint256, uint256) {
return (a[0].length, uint8(a[0][0]), uint8(a[0][1]), uint8(a[0][2]), b[0].length, uint8(b[0][0]), uint8(b[0][1]));
}
function g1(bytes[2] calldata a) external returns (uint256, uint256, uint256, uint256, uint256, uint256, uint256, uint256) {
return (a[0].length, uint8(a[0][0]), uint8(a[0][1]), uint8(a[0][2]), a[1].length, uint8(a[1][0]), uint8(a[1][1]), uint8(a[1][2]));
}
function g2(bytes[] calldata a) external returns (uint256[8] memory) {
return [a.length, a[0].length, uint8(a[0][0]), uint8(a[0][1]), a[1].length, uint8(a[1][0]), uint8(a[1][1]), uint8(a[1][2])];
}
}
)";
compileAndRun(sourceCode, 0, "C");
bytes bytes010203 = bytes{1,2,3}+bytes(29,0);
bytes bytes040506 = bytes{4,5,6}+bytes(29,0);
bytes bytes0102 = bytes{1,2}+bytes(30,0);
ABI_CHECK(
callContractFunction("f1(bytes[1])", 0x20, 0x20, 3, bytes010203),
encodeArgs(3, 1, 2, 3)
);
ABI_CHECK(
callContractFunction("f2(bytes[1],bytes[1])", 0x40, 0xA0, 0x20, 3, bytes010203, 0x20, 2, bytes0102),
encodeArgs(3, 1, 2, 3, 2, 1, 2)
);
ABI_CHECK(
callContractFunction("g1(bytes[2])", 0x20, 0x40, 0x80, 3, bytes010203, 3, bytes040506),
encodeArgs(3, 1, 2, 3, 3, 4, 5, 6)
);
// same offset for both arrays
ABI_CHECK(
callContractFunction("g1(bytes[2])", 0x20, 0x40, 0x40, 3, bytes010203),
encodeArgs(3, 1, 2, 3, 3, 1, 2, 3)
);
ABI_CHECK(
callContractFunction("g2(bytes[])", 0x20, 2, 0x40, 0x80, 2, bytes0102, 3, bytes040506),
encodeArgs(2, 2, 1, 2, 3, 4, 5, 6)
);
}
BOOST_AUTO_TEST_CASE(calldata_dynamic_array_to_memory)
{
char const* sourceCode = R"(
pragma experimental ABIEncoderV2;
contract C {
function f(uint256[][] calldata a) external returns (uint, uint256[] memory) {
uint256[] memory m = a[0];
return (a.length, m);
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(
callContractFunction("f(uint256[][])", 0x20, 1, 0x20, 2, 23, 42),
encodeArgs(1, 0x40, 2, 23, 42)
);
}
BOOST_AUTO_TEST_CASE(calldata_bytes_array_to_memory)
{
char const* sourceCode = R"(
pragma experimental ABIEncoderV2;
contract C {
function f(bytes[] calldata a) external returns (uint, uint, bytes memory) {
bytes memory m = a[0];
return (a.length, m.length, m);
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(
callContractFunction("f(bytes[])", 0x20, 1, 0x20, 2, bytes{'a', 'b'} + bytes(30, 0)),
encodeArgs(1, 2, 0x60, 2, bytes{'a','b'} + bytes(30, 0))
);
ABI_CHECK(
callContractFunction("f(bytes[])", 0x20, 1, 0x20, 32, bytes(32, 'x')),
encodeArgs(1, 32, 0x60, 32, bytes(32, 'x'))
);
bytes x_zero_a = bytes{'x'} + bytes(30, 0) + bytes{'a'};
bytes a_zero_x = bytes{'a'} + bytes(30, 0) + bytes{'x'};
bytes a_m_x = bytes{'a'} + bytes(30, 'm') + bytes{'x'};
ABI_CHECK(
callContractFunction("f(bytes[])", 0x20, 1, 0x20, 32, x_zero_a),
encodeArgs(1, 32, 0x60, 32, x_zero_a)
);
ABI_CHECK(
callContractFunction("f(bytes[])", 0x20, 1, 0x20, 32, a_zero_x),
encodeArgs(1, 32, 0x60, 32, a_zero_x)
);
ABI_CHECK(
callContractFunction("f(bytes[])", 0x20, 1, 0x20, 32, a_m_x),
encodeArgs(1, 32, 0x60, 32, a_m_x)
);
}
BOOST_AUTO_TEST_CASE(calldata_bytes_array_bounds)
{
char const* sourceCode = R"(
pragma experimental ABIEncoderV2;
contract C {
function f(bytes[] calldata a, uint256 i) external returns (uint) {
return uint8(a[0][i]);
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(
callContractFunction("f(bytes[],uint256)", 0x40, 0, 1, 0x20, 2, bytes{'a', 'b'} + bytes(30, 0)),
encodeArgs('a')
);
ABI_CHECK(
callContractFunction("f(bytes[],uint256)", 0x40, 1, 1, 0x20, 2, bytes{'a', 'b'} + bytes(30, 0)),
encodeArgs('b')
);
ABI_CHECK(
callContractFunction("f(bytes[],uint256)", 0x40, 2, 1, 0x20, 2, bytes{'a', 'b'} + bytes(30, 0)),
encodeArgs()
);
}
BOOST_AUTO_TEST_CASE(calldata_string_array)
{
char const* sourceCode = R"(
pragma experimental ABIEncoderV2;
contract C {
function f(string[] calldata a) external returns (uint, uint, uint, string memory) {
string memory s1 = a[0];
bytes memory m1 = bytes(s1);
return (a.length, m1.length, uint8(m1[0]), s1);
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(
callContractFunction("f(string[])", 0x20, 1, 0x20, 2, bytes{'a', 'b'} + bytes(30, 0)),
encodeArgs(1, 2, 'a', 0x80, 2, bytes{'a', 'b'} + bytes(30, 0))
);
}
BOOST_AUTO_TEST_CASE(calldata_array_two_dimensional)
{
vector<vector<u256>> data {
{ 0x0A01, 0x0A02, 0x0A03 },
{ 0x0B01, 0x0B02, 0x0B03, 0x0B04 }
};
for (bool outerDynamicallySized: { true, false })
{
string arrayType = outerDynamicallySized ? "uint256[][]" : "uint256[][2]";
string sourceCode = R"(
pragma experimental ABIEncoderV2;
contract C {
function test()" + arrayType + R"( calldata a) external returns (uint256) {
return a.length;
}
function test()" + arrayType + R"( calldata a, uint256 i) external returns (uint256) {
return a[i].length;
}
function test()" + arrayType + R"( calldata a, uint256 i, uint256 j) external returns (uint256) {
return a[i][j];
}
}
)";
compileAndRun(sourceCode, 0, "C");
bytes encoding = encodeArray(
outerDynamicallySized,
true,
data | boost::adaptors::transformed([&](vector<u256> const& _values) {
return encodeArray(true, false, _values);
})
);
ABI_CHECK(callContractFunction("test(" + arrayType + ")", 0x20, encoding), encodeArgs(data.size()));
for (size_t i = 0; i < data.size(); i++)
{
ABI_CHECK(callContractFunction("test(" + arrayType + ",uint256)", 0x40, i, encoding), encodeArgs(data[i].size()));
for (size_t j = 0; j < data[i].size(); j++)
ABI_CHECK(callContractFunction("test(" + arrayType + ",uint256,uint256)", 0x60, i, j, encoding), encodeArgs(data[i][j]));
// out of bounds access
ABI_CHECK(callContractFunction("test(" + arrayType + ",uint256,uint256)", 0x60, i, data[i].size(), encoding), encodeArgs());
}
// out of bounds access
ABI_CHECK(callContractFunction("test(" + arrayType + ",uint256)", 0x40, data.size(), encoding), encodeArgs());
}
}
BOOST_AUTO_TEST_CASE(calldata_array_dynamic_three_dimensional)
{
vector<vector<vector<u256>>> data {
{
{ 0x010A01, 0x010A02, 0x010A03 },
{ 0x010B01, 0x010B02, 0x010B03 }
},
{
{ 0x020A01, 0x020A02, 0x020A03 },
{ 0x020B01, 0x020B02, 0x020B03 }
}
};
for (bool outerDynamicallySized: { true, false })
for (bool middleDynamicallySized: { true, false })
for (bool innerDynamicallySized: { true, false })
{
// only test dynamically encoded arrays
if (!outerDynamicallySized && !middleDynamicallySized && !innerDynamicallySized)
continue;
string arrayType = "uint256";
arrayType += innerDynamicallySized ? "[]" : "[3]";
arrayType += middleDynamicallySized ? "[]" : "[2]";
arrayType += outerDynamicallySized ? "[]" : "[2]";
string sourceCode = R"(
pragma experimental ABIEncoderV2;
contract C {
function test()" + arrayType + R"( calldata a) external returns (uint256) {
return a.length;
}
function test()" + arrayType + R"( calldata a, uint256 i) external returns (uint256) {
return a[i].length;
}
function test()" + arrayType + R"( calldata a, uint256 i, uint256 j) external returns (uint256) {
return a[i][j].length;
}
function test()" + arrayType + R"( calldata a, uint256 i, uint256 j, uint256 k) external returns (uint256) {
return a[i][j][k];
}
}
)";
compileAndRun(sourceCode, 0, "C");
bytes encoding = encodeArray(
outerDynamicallySized,
middleDynamicallySized || innerDynamicallySized,
data | boost::adaptors::transformed([&](auto const& _middleData) {
return encodeArray(
middleDynamicallySized,
innerDynamicallySized,
_middleData | boost::adaptors::transformed([&](auto const& _values) {
return encodeArray(innerDynamicallySized, false, _values);
})
);
})
);
ABI_CHECK(callContractFunction("test(" + arrayType + ")", 0x20, encoding), encodeArgs(data.size()));
for (size_t i = 0; i < data.size(); i++)
{
ABI_CHECK(callContractFunction("test(" + arrayType + ",uint256)", 0x40, i, encoding), encodeArgs(data[i].size()));
for (size_t j = 0; j < data[i].size(); j++)
{
ABI_CHECK(callContractFunction("test(" + arrayType + ",uint256,uint256)", 0x60, i, j, encoding), encodeArgs(data[i][j].size()));
for (size_t k = 0; k < data[i][j].size(); k++)
ABI_CHECK(callContractFunction("test(" + arrayType + ",uint256,uint256,uint256)", 0x80, i, j, k, encoding), encodeArgs(data[i][j][k]));
// out of bounds access
ABI_CHECK(callContractFunction("test(" + arrayType + ",uint256,uint256,uint256)", 0x80, i, j, data[i][j].size(), encoding), encodeArgs());
}
// out of bounds access
ABI_CHECK(callContractFunction("test(" + arrayType + ",uint256,uint256)", 0x60, i, data[i].size(), encoding), encodeArgs());
}
// out of bounds access
ABI_CHECK(callContractFunction("test(" + arrayType + ",uint256)", 0x40, data.size(), encoding), encodeArgs());
}
}
BOOST_AUTO_TEST_CASE(calldata_array_dynamic_invalid)
{
char const* sourceCode = R"(
pragma experimental ABIEncoderV2;
contract C {
function f(uint256[][] calldata a) external returns (uint) {
return 42;
}
function g(uint256[][] calldata a) external returns (uint) {
a[0];
return 42;
}
}
)";
compileAndRun(sourceCode, 0, "C");
// valid access stub
ABI_CHECK(callContractFunction("f(uint256[][])", 0x20, 0), encodeArgs(42));
// invalid on argument decoding
ABI_CHECK(callContractFunction("f(uint256[][])", 0x20, 1), encodeArgs());
// invalid on outer access
ABI_CHECK(callContractFunction("f(uint256[][])", 0x20, 1, 0x20), encodeArgs(42));
ABI_CHECK(callContractFunction("g(uint256[][])", 0x20, 1, 0x20), encodeArgs());
// invalid on inner access
ABI_CHECK(callContractFunction("f(uint256[][])", 0x20, 1, 0x20, 2, 0x42), encodeArgs(42));
ABI_CHECK(callContractFunction("g(uint256[][])", 0x20, 1, 0x20, 2, 0x42), encodeArgs());
}
BOOST_AUTO_TEST_CASE(calldata_array_dynamic_invalid_static_middle)
{
char const* sourceCode = R"(
pragma experimental ABIEncoderV2;
contract C {
function f(uint256[][1][] calldata a) external returns (uint) {
return 42;
}
function g(uint256[][1][] calldata a) external returns (uint) {
a[0];
return 42;
}
function h(uint256[][1][] calldata a) external returns (uint) {
a[0][0];
return 42;
}
}
)";
compileAndRun(sourceCode, 0, "C");
// valid access stub
ABI_CHECK(callContractFunction("f(uint256[][1][])", 0x20, 0), encodeArgs(42));
// invalid on argument decoding
ABI_CHECK(callContractFunction("f(uint256[][1][])", 0x20, 1), encodeArgs());
// invalid on outer access
ABI_CHECK(callContractFunction("f(uint256[][1][])", 0x20, 1, 0x20), encodeArgs(42));
ABI_CHECK(callContractFunction("g(uint256[][1][])", 0x20, 1, 0x20), encodeArgs());
// invalid on inner access
ABI_CHECK(callContractFunction("f(uint256[][1][])", 0x20, 1, 0x20, 0x20), encodeArgs(42));
ABI_CHECK(callContractFunction("g(uint256[][1][])", 0x20, 1, 0x20, 0x20), encodeArgs(42));
ABI_CHECK(callContractFunction("h(uint256[][1][])", 0x20, 1, 0x20, 0x20), encodeArgs());
ABI_CHECK(callContractFunction("f(uint256[][1][])", 0x20, 1, 0x20, 0x20, 1), encodeArgs(42));
ABI_CHECK(callContractFunction("g(uint256[][1][])", 0x20, 1, 0x20, 0x20, 1), encodeArgs(42));
ABI_CHECK(callContractFunction("h(uint256[][1][])", 0x20, 1, 0x20, 0x20, 1), encodeArgs());
}
BOOST_AUTO_TEST_CASE(literal_strings)
{
char const* sourceCode = R"(
contract Test {
string public long;
string public medium;
string public short;
string public empty;
function f() public returns (string memory) {
long = "0123456789012345678901234567890123456789012345678901234567890123456789012345678901234567890123456789001234567890123456789012345678901234567890123456789012345678901234567890123456789012345678901234567890012345678901234567890123456789012345678901234567890123456789012345678901234567890123456789012345678900123456789012345678901234567890123456789012345678901234567890123456789012345678901234567890123456789001234567890123456789012345678901234567890123456789012345678901234567890123456789012345678901234567890";
medium = "01234567890123456789012345678901234567890123456789012345678901234567890123456789";
short = "123";
empty = "";
return "Hello, World!";
}
}
)";
compileAndRun(sourceCode, 0, "Test");
string longStr = "0123456789012345678901234567890123456789012345678901234567890123456789012345678901234567890123456789001234567890123456789012345678901234567890123456789012345678901234567890123456789012345678901234567890012345678901234567890123456789012345678901234567890123456789012345678901234567890123456789012345678900123456789012345678901234567890123456789012345678901234567890123456789012345678901234567890123456789001234567890123456789012345678901234567890123456789012345678901234567890123456789012345678901234567890";
string medium = "01234567890123456789012345678901234567890123456789012345678901234567890123456789";
string shortStr = "123";
string hello = "Hello, World!";
ABI_CHECK(callContractFunction("f()"), encodeDyn(hello));
ABI_CHECK(callContractFunction("long()"), encodeDyn(longStr));
ABI_CHECK(callContractFunction("medium()"), encodeDyn(medium));
ABI_CHECK(callContractFunction("short()"), encodeDyn(shortStr));
ABI_CHECK(callContractFunction("empty()"), encodeDyn(string()));
}
BOOST_AUTO_TEST_CASE(initialise_string_constant)
{
char const* sourceCode = R"(
contract Test {
string public short = "abcdef";
string public long = "0123456789012345678901234567890123456789012345678901234567890123456789012345678901234567890123456789001234567890123456789012345678901234567890123456789012345678901234567890123456789012345678901234567890012345678901234567890123456789012345678901234567890123456789012345678901234567890123456789012345678900123456789012345678901234567890123456789012345678901234567890123456789012345678901234567890123456789001234567890123456789012345678901234567890123456789012345678901234567890123456789012345678901234567890";
}
)";
compileAndRun(sourceCode, 0, "Test");
string longStr = "0123456789012345678901234567890123456789012345678901234567890123456789012345678901234567890123456789001234567890123456789012345678901234567890123456789012345678901234567890123456789012345678901234567890012345678901234567890123456789012345678901234567890123456789012345678901234567890123456789012345678900123456789012345678901234567890123456789012345678901234567890123456789012345678901234567890123456789001234567890123456789012345678901234567890123456789012345678901234567890123456789012345678901234567890";
string shortStr = "abcdef";
ABI_CHECK(callContractFunction("long()"), encodeDyn(longStr));
ABI_CHECK(callContractFunction("short()"), encodeDyn(shortStr));
}
BOOST_AUTO_TEST_CASE(memory_structs_with_mappings)
{
char const* sourceCode = R"(
contract Test {
struct S { uint8 a; mapping(uint => uint) b; uint8 c; }
S s;
function f() public returns (uint) {
S memory x;
if (x.a != 0 || x.c != 0) return 1;
x.a = 4; x.c = 5;
s = x;
if (s.a != 4 || s.c != 5) return 2;
x = S(2, 3);
if (x.a != 2 || x.c != 3) return 3;
x = s;
if (s.a != 4 || s.c != 5) return 4;
}
}
)";
compileAndRun(sourceCode, 0, "Test");
ABI_CHECK(callContractFunction("f()"), encodeArgs(u256(0)));
}
BOOST_AUTO_TEST_CASE(string_bytes_conversion)
{
char const* sourceCode = R"(
contract Test {
string s;
bytes b;
function f(string memory _s, uint n) public returns (byte) {
b = bytes(_s);
s = string(b);
return bytes(s)[n];
}
function l() public returns (uint) { return bytes(s).length; }
}
)";
compileAndRun(sourceCode, 0, "Test");
ABI_CHECK(callContractFunction(
"f(string,uint256)",
u256(0x40),
u256(2),
u256(6),
string("abcdef")
), encodeArgs("c"));
ABI_CHECK(callContractFunction("l()"), encodeArgs(u256(6)));
}
BOOST_AUTO_TEST_CASE(string_as_mapping_key)
{
char const* sourceCode = R"(
contract Test {
mapping(string => uint) data;
function set(string memory _s, uint _v) public { data[_s] = _v; }
function get(string memory _s) public returns (uint) { return data[_s]; }
}
)";
compileAndRun(sourceCode, 0, "Test");
vector<string> strings{
"Hello, World!",
"Hello, World!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!1111",
"",
"1"
};
for (unsigned i = 0; i < strings.size(); i++)
ABI_CHECK(callContractFunction(
"set(string,uint256)",
u256(0x40),
u256(7 + i),
u256(strings[i].size()),
strings[i]
), encodeArgs());
for (unsigned i = 0; i < strings.size(); i++)
ABI_CHECK(callContractFunction(
"get(string)",
u256(0x20),
u256(strings[i].size()),
strings[i]
), encodeArgs(u256(7 + i)));
}
BOOST_AUTO_TEST_CASE(string_as_public_mapping_key)
{
char const* sourceCode = R"(
contract Test {
mapping(string => uint) public data;
function set(string memory _s, uint _v) public { data[_s] = _v; }
}
)";
compileAndRun(sourceCode, 0, "Test");
vector<string> strings{
"Hello, World!",
"Hello, World!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!1111",
"",
"1"
};
for (unsigned i = 0; i < strings.size(); i++)
ABI_CHECK(callContractFunction(
"set(string,uint256)",
u256(0x40),
u256(7 + i),
u256(strings[i].size()),
strings[i]
), encodeArgs());
for (unsigned i = 0; i < strings.size(); i++)
ABI_CHECK(callContractFunction(
"data(string)",
u256(0x20),
u256(strings[i].size()),
strings[i]
), encodeArgs(u256(7 + i)));
}
BOOST_AUTO_TEST_CASE(nested_string_as_public_mapping_key)
{
char const* sourceCode = R"(
contract Test {
mapping(string => mapping(string => uint)) public data;
function set(string memory _s, string memory _s2, uint _v) public {
data[_s][_s2] = _v; }
}
)";
compileAndRun(sourceCode, 0, "Test");
vector<string> strings{
"Hello, World!",
"Hello, World!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!1111",
"",
"1",
"last one"
};
for (unsigned i = 0; i + 1 < strings.size(); i++)
ABI_CHECK(callContractFunction(
"set(string,string,uint256)",
u256(0x60),
u256(roundTo32(0x80 + strings[i].size())),
u256(7 + i),
u256(strings[i].size()),
strings[i],
u256(strings[i+1].size()),
strings[i+1]
), encodeArgs());
for (unsigned i = 0; i + 1 < strings.size(); i++)
ABI_CHECK(callContractFunction(
"data(string,string)",
u256(0x40),
u256(roundTo32(0x60 + strings[i].size())),
u256(strings[i].size()),
strings[i],
u256(strings[i+1].size()),
strings[i+1]
), encodeArgs(u256(7 + i)));
}
BOOST_AUTO_TEST_CASE(nested_mixed_string_as_public_mapping_key)
{
char const* sourceCode = R"(
contract Test {
mapping(string =>
mapping(int =>
mapping(address =>
mapping(bytes => int)))) public data;
function set(
string memory _s1,
int _s2,
address _s3,
bytes memory _s4,
int _value
) public
{
data[_s1][_s2][_s3][_s4] = _value;
}
}
)";
compileAndRun(sourceCode, 0, "Test");
struct Index
{
string s1;
int s2;
int s3;
string s4;
};
vector<Index> data{
{ "aabcabcabcabcabcabcabcabcabcabcabcabcabcabcabcabcabcabcabcabcabcabcabcabcabcabcabcabcabcabcabcabcbc", 4, 23, "efg" },
{ "tiaron", 456, 63245, "908apzapzapzapzapzapzapzapzapzapzapzapzapzapzapzapzapzapzapzapzapzapzapzapzapzapzapzapzapzapzapzapzapzapzapzapzapzapzapzapzapzapzapzapz" },
{ "", 2345, 12934, "665i65i65i65i65i65i65i65i65i65i65i65i65i65i65i65i65i65i5iart" },
{ "¡¿…", 9781, 8148, "" },
{ "ρν♀♀ω₂₃♀", 929608, 303030, "" }
};
for (size_t i = 0; i + 1 < data.size(); i++)
ABI_CHECK(callContractFunction(
"set(string,int256,address,bytes,int256)",
u256(0xA0),
u256(data[i].s2),
u256(data[i].s3),
u256(roundTo32(0xC0 + data[i].s1.size())),
u256(i - 3),
u256(data[i].s1.size()),
data[i].s1,
u256(data[i].s4.size()),
data[i].s4
), encodeArgs());
for (size_t i = 0; i + 1 < data.size(); i++)
ABI_CHECK(callContractFunction(
"data(string,int256,address,bytes)",
u256(0x80),
u256(data[i].s2),
u256(data[i].s3),
u256(roundTo32(0xA0 + data[i].s1.size())),
u256(data[i].s1.size()),
data[i].s1,
u256(data[i].s4.size()),
data[i].s4
), encodeArgs(u256(i - 3)));
}
BOOST_AUTO_TEST_CASE(accessor_for_state_variable)
{
char const* sourceCode = R"(
contract Lotto {
uint public ticketPrice = 500;
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("ticketPrice()"), encodeArgs(u256(500)));
}
BOOST_AUTO_TEST_CASE(accessor_for_const_state_variable)
{
char const* sourceCode = R"(
contract Lotto{
uint constant public ticketPrice = 555;
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("ticketPrice()"), encodeArgs(u256(555)));
}
BOOST_AUTO_TEST_CASE(state_variable_under_contract_name)
{
char const* text = R"(
contract Scope {
uint stateVar = 42;
function getStateVar() public view returns (uint stateVar) {
stateVar = Scope.stateVar;
}
}
)";
compileAndRun(text);
ABI_CHECK(callContractFunction("getStateVar()"), encodeArgs(u256(42)));
}
BOOST_AUTO_TEST_CASE(state_variable_local_variable_mixture)
{
char const* sourceCode = R"(
contract A {
uint x = 1;
uint y = 2;
function a() public returns (uint x) {
x = A.y;
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("a()"), encodeArgs(u256(2)));
}
BOOST_AUTO_TEST_CASE(inherited_function) {
char const* sourceCode = R"(
contract A { function f() internal returns (uint) { return 1; } }
contract B is A {
function f() internal returns (uint) { return 2; }
function g() public returns (uint) {
return A.f();
}
}
)";
compileAndRun(sourceCode, 0, "B");
ABI_CHECK(callContractFunction("g()"), encodeArgs(u256(1)));
}
BOOST_AUTO_TEST_CASE(inherited_function_calldata_memory) {
char const* sourceCode = R"(
contract A { function f(uint[] calldata a) external returns (uint) { return a[0]; } }
contract B is A {
function f(uint[] memory a) public returns (uint) { return a[1]; }
function g() public returns (uint) {
uint[] memory m = new uint[](2);
m[0] = 42;
m[1] = 23;
return A(this).f(m);
}
}
)";
compileAndRun(sourceCode, 0, "B");
ABI_CHECK(callContractFunction("g()"), encodeArgs(u256(23)));
}
BOOST_AUTO_TEST_CASE(inherited_function_calldata_memory_interface) {
char const* sourceCode = R"(
interface I { function f(uint[] calldata a) external returns (uint); }
contract A is I { function f(uint[] memory a) public returns (uint) { return 42; } }
contract B {
function f(uint[] memory a) public returns (uint) { return a[1]; }
function g() public returns (uint) {
I i = I(new A());
return i.f(new uint[](2));
}
}
)";
compileAndRun(sourceCode, 0, "B");
ABI_CHECK(callContractFunction("g()"), encodeArgs(u256(42)));
}
BOOST_AUTO_TEST_CASE(inherited_function_calldata_calldata_interface) {
char const* sourceCode = R"(
interface I { function f(uint[] calldata a) external returns (uint); }
contract A is I { function f(uint[] calldata a) external returns (uint) { return 42; } }
contract B {
function f(uint[] memory a) public returns (uint) { return a[1]; }
function g() public returns (uint) {
I i = I(new A());
return i.f(new uint[](2));
}
}
)";
compileAndRun(sourceCode, 0, "B");
ABI_CHECK(callContractFunction("g()"), encodeArgs(u256(42)));
}
BOOST_AUTO_TEST_CASE(inherited_function_from_a_library) {
char const* sourceCode = R"(
library A { function f() internal returns (uint) { return 1; } }
contract B {
function f() internal returns (uint) { return 2; }
function g() public returns (uint) {
return A.f();
}
}
)";
compileAndRun(sourceCode, 0, "B");
ABI_CHECK(callContractFunction("g()"), encodeArgs(u256(1)));
}
BOOST_AUTO_TEST_CASE(inherited_constant_state_var)
{
char const* sourceCode = R"(
contract A {
uint constant x = 7;
}
contract B is A {
function f() public returns (uint) {
return A.x;
}
}
)";
compileAndRun(sourceCode, 0, "B");
ABI_CHECK(callContractFunction("f()"), encodeArgs(u256(7)));
}
BOOST_AUTO_TEST_CASE(multiple_inherited_state_vars)
{
char const* sourceCode = R"(
contract A {
uint x = 7;
}
contract B {
uint x = 9;
}
contract C is A, B {
function a() public returns (uint) {
return A.x;
}
function b() public returns (uint) {
return B.x;
}
function a_set(uint _x) public returns (uint) {
A.x = _x;
return 1;
}
function b_set(uint _x) public returns (uint) {
B.x = _x;
return 1;
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("a()"), encodeArgs(u256(7)));
ABI_CHECK(callContractFunction("b()"), encodeArgs(u256(9)));
ABI_CHECK(callContractFunction("a_set(uint256)", u256(1)), encodeArgs(u256(1)));
ABI_CHECK(callContractFunction("b_set(uint256)", u256(3)), encodeArgs(u256(1)));
ABI_CHECK(callContractFunction("a()"), encodeArgs(u256(1)));
ABI_CHECK(callContractFunction("b()"), encodeArgs(u256(3)));
}
BOOST_AUTO_TEST_CASE(constant_string_literal)
{
char const* sourceCode = R"(
contract Test {
bytes32 constant public b = "abcdefghijklmnopq";
string constant public x = "abefghijklmnopqabcdefghijklmnopqabcdefghijklmnopqabca";
constructor() public {
string memory xx = x;
bytes32 bb = b;
}
function getB() public returns (bytes32) { return b; }
function getX() public returns (string memory) { return x; }
function getX2() public returns (string memory r) { r = x; }
function unused() public returns (uint) {
"unusedunusedunusedunusedunusedunusedunusedunusedunusedunusedunusedunused";
return 2;
}
}
)";
compileAndRun(sourceCode);
string longStr = "abefghijklmnopqabcdefghijklmnopqabcdefghijklmnopqabca";
string shortStr = "abcdefghijklmnopq";
ABI_CHECK(callContractFunction("b()"), encodeArgs(shortStr));
ABI_CHECK(callContractFunction("x()"), encodeDyn(longStr));
ABI_CHECK(callContractFunction("getB()"), encodeArgs(shortStr));
ABI_CHECK(callContractFunction("getX()"), encodeDyn(longStr));
ABI_CHECK(callContractFunction("getX2()"), encodeDyn(longStr));
ABI_CHECK(callContractFunction("unused()"), encodeArgs(2));
}
BOOST_AUTO_TEST_CASE(storage_string_as_mapping_key_without_variable)
{
char const* sourceCode = R"(
contract Test {
mapping(string => uint) data;
function f() public returns (uint) {
data["abc"] = 2;
return data["abc"];
}
}
)";
compileAndRun(sourceCode, 0, "Test");
ABI_CHECK(callContractFunction("f()"), encodeArgs(u256(2)));
}
BOOST_AUTO_TEST_CASE(library_call)
{
char const* sourceCode = R"(
library Lib { function m(uint x, uint y) public returns (uint) { return x * y; } }
contract Test {
function f(uint x) public returns (uint) {
return Lib.m(x, 9);
}
}
)";
compileAndRun(sourceCode, 0, "Lib");
compileAndRun(sourceCode, 0, "Test", bytes(), map<string, Address>{{"Lib", m_contractAddress}});
ABI_CHECK(callContractFunction("f(uint256)", u256(33)), encodeArgs(u256(33) * 9));
}
BOOST_AUTO_TEST_CASE(library_function_external)
{
char const* sourceCode = R"(
library Lib { function m(bytes calldata b) external pure returns (byte) { return b[2]; } }
contract Test {
function f(bytes memory b) public pure returns (byte) {
return Lib.m(b);
}
}
)";
compileAndRun(sourceCode, 0, "Lib");
compileAndRun(sourceCode, 0, "Test", bytes(), map<string, Address>{{"Lib", m_contractAddress}});
ABI_CHECK(callContractFunction("f(bytes)", u256(0x20), u256(5), "abcde"), encodeArgs("c"));
}
BOOST_AUTO_TEST_CASE(library_stray_values)
{
char const* sourceCode = R"(
library Lib { function m(uint x, uint y) public returns (uint) { return x * y; } }
contract Test {
function f(uint x) public returns (uint) {
Lib;
Lib.m;
return x + 9;
}
}
)";
compileAndRun(sourceCode, 0, "Lib");
compileAndRun(sourceCode, 0, "Test", bytes(), map<string, Address>{{"Lib", m_contractAddress}});
ABI_CHECK(callContractFunction("f(uint256)", u256(33)), encodeArgs(u256(42)));
}
BOOST_AUTO_TEST_CASE(cross_contract_types)
{
char const* sourceCode = R"(
contract Lib { struct S {uint a; uint b; } }
contract Test {
function f() public returns (uint r) {
Lib.S memory x = Lib.S({a: 2, b: 3});
r = x.b;
}
}
)";
compileAndRun(sourceCode, 0, "Test");
ABI_CHECK(callContractFunction("f()"), encodeArgs(u256(3)));
}
BOOST_AUTO_TEST_CASE(simple_throw)
{
char const* sourceCode = R"(
contract Test {
function f(uint x) public returns (uint) {
if (x > 10)
return x + 10;
else
revert();
return 2;
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("f(uint256)", u256(11)), encodeArgs(u256(21)));
ABI_CHECK(callContractFunction("f(uint256)", u256(1)), encodeArgs());
}
BOOST_AUTO_TEST_CASE(strings_in_struct)
{
char const* sourceCode = R"(
contract buggystruct {
Buggy public bug;
struct Buggy {
uint first;
uint second;
uint third;
string last;
}
constructor() public {
bug = Buggy(10, 20, 30, "asdfghjkl");
}
function getFirst() public returns (uint)
{
return bug.first;
}
function getSecond() public returns (uint)
{
return bug.second;
}
function getThird() public returns (uint)
{
return bug.third;
}
function getLast() public returns (string memory)
{
return bug.last;
}
}
)";
compileAndRun(sourceCode);
string s = "asdfghjkl";
ABI_CHECK(callContractFunction("getFirst()"), encodeArgs(u256(10)));
ABI_CHECK(callContractFunction("getSecond()"), encodeArgs(u256(20)));
ABI_CHECK(callContractFunction("getThird()"), encodeArgs(u256(30)));
ABI_CHECK(callContractFunction("getLast()"), encodeDyn(s));
}
BOOST_AUTO_TEST_CASE(fixed_arrays_as_return_type)
{
char const* sourceCode = R"(
contract A {
function f(uint16 input) public pure returns (uint16[5] memory arr)
{
arr[0] = input;
arr[1] = ++input;
arr[2] = ++input;
arr[3] = ++input;
arr[4] = ++input;
}
}
contract B {
function f() public returns (uint16[5] memory res, uint16[5] memory res2)
{
A a = new A();
res = a.f(2);
res2 = a.f(1000);
}
}
)";
compileAndRun(sourceCode, 0, "B");
ABI_CHECK(callContractFunction("f()"), encodeArgs(
u256(2), u256(3), u256(4), u256(5), u256(6), // first return argument
u256(1000), u256(1001), u256(1002), u256(1003), u256(1004)) // second return argument
);
}
BOOST_AUTO_TEST_CASE(internal_types_in_library)
{
char const* sourceCode = R"(
library Lib {
function find(uint16[] storage _haystack, uint16 _needle) public view returns (uint)
{
for (uint i = 0; i < _haystack.length; ++i)
if (_haystack[i] == _needle)
return i;
return uint(-1);
}
}
contract Test {
mapping(string => uint16[]) data;
function f() public returns (uint a, uint b)
{
data["abc"].length = 20;
data["abc"][4] = 9;
data["abc"][17] = 3;
a = Lib.find(data["abc"], 9);
b = Lib.find(data["abc"], 3);
}
}
)";
compileAndRun(sourceCode, 0, "Lib");
compileAndRun(sourceCode, 0, "Test", bytes(), map<string, Address>{{"Lib", m_contractAddress}});
ABI_CHECK(callContractFunction("f()"), encodeArgs(u256(4), u256(17)));
}
BOOST_AUTO_TEST_CASE(mapping_arguments_in_library)
{
char const* sourceCode = R"(
library Lib {
function set(mapping(uint => uint) storage m, uint key, uint value) internal
{
m[key] = value;
}
function get(mapping(uint => uint) storage m, uint key) internal view returns (uint)
{
return m[key];
}
}
contract Test {
mapping(uint => uint) m;
function set(uint256 key, uint256 value) public returns (uint)
{
uint oldValue = Lib.get(m, key);
Lib.set(m, key, value);
return oldValue;
}
function get(uint256 key) public view returns (uint) {
return Lib.get(m, key);
}
}
)";
compileAndRun(sourceCode, 0, "Lib");
compileAndRun(sourceCode, 0, "Test", bytes(), map<string, Address>{{"Lib", m_contractAddress}});
ABI_CHECK(callContractFunction("set(uint256,uint256)", u256(1), u256(42)), encodeArgs(u256(0)));
ABI_CHECK(callContractFunction("set(uint256,uint256)", u256(2), u256(84)), encodeArgs(u256(0)));
ABI_CHECK(callContractFunction("set(uint256,uint256)", u256(21), u256(7)), encodeArgs(u256(0)));
ABI_CHECK(callContractFunction("get(uint256)", u256(0)), encodeArgs(u256(0)));
ABI_CHECK(callContractFunction("get(uint256)", u256(1)), encodeArgs(u256(42)));
ABI_CHECK(callContractFunction("get(uint256)", u256(2)), encodeArgs(u256(84)));
ABI_CHECK(callContractFunction("get(uint256)", u256(21)), encodeArgs(u256(7)));
ABI_CHECK(callContractFunction("set(uint256,uint256)", u256(1), u256(21)), encodeArgs(u256(42)));
ABI_CHECK(callContractFunction("set(uint256,uint256)", u256(2), u256(42)), encodeArgs(u256(84)));
ABI_CHECK(callContractFunction("set(uint256,uint256)", u256(21), u256(14)), encodeArgs(u256(7)));
ABI_CHECK(callContractFunction("get(uint256)", u256(0)), encodeArgs(u256(0)));
ABI_CHECK(callContractFunction("get(uint256)", u256(1)), encodeArgs(u256(21)));
ABI_CHECK(callContractFunction("get(uint256)", u256(2)), encodeArgs(u256(42)));
ABI_CHECK(callContractFunction("get(uint256)", u256(21)), encodeArgs(u256(14)));
}
BOOST_AUTO_TEST_CASE(mapping_returns_in_library)
{
char const* sourceCode = R"(
library Lib {
function choose_mapping(mapping(uint => uint) storage a, mapping(uint => uint) storage b, bool c) internal pure returns(mapping(uint=>uint) storage)
{
return c ? a : b;
}
}
contract Test {
mapping(uint => uint) a;
mapping(uint => uint) b;
function set(bool choice, uint256 key, uint256 value) public returns (uint)
{
mapping(uint => uint) storage m = Lib.choose_mapping(a, b, choice);
uint oldValue = m[key];
m[key] = value;
return oldValue;
}
function get(bool choice, uint256 key) public view returns (uint) {
return Lib.choose_mapping(a, b, choice)[key];
}
function get_a(uint256 key) public view returns (uint) {
return a[key];
}
function get_b(uint256 key) public view returns (uint) {
return b[key];
}
}
)";
compileAndRun(sourceCode, 0, "Lib");
compileAndRun(sourceCode, 0, "Test", bytes(), map<string, Address>{{"Lib", m_contractAddress}});
ABI_CHECK(callContractFunction("set(bool,uint256,uint256)", true, u256(1), u256(42)), encodeArgs(u256(0)));
ABI_CHECK(callContractFunction("set(bool,uint256,uint256)", true, u256(2), u256(84)), encodeArgs(u256(0)));
ABI_CHECK(callContractFunction("set(bool,uint256,uint256)", true, u256(21), u256(7)), encodeArgs(u256(0)));
ABI_CHECK(callContractFunction("set(bool,uint256,uint256)", false, u256(1), u256(10)), encodeArgs(u256(0)));
ABI_CHECK(callContractFunction("set(bool,uint256,uint256)", false, u256(2), u256(11)), encodeArgs(u256(0)));
ABI_CHECK(callContractFunction("set(bool,uint256,uint256)", false, u256(21), u256(12)), encodeArgs(u256(0)));
ABI_CHECK(callContractFunction("get(bool,uint256)", true, u256(0)), encodeArgs(u256(0)));
ABI_CHECK(callContractFunction("get(bool,uint256)", true, u256(1)), encodeArgs(u256(42)));
ABI_CHECK(callContractFunction("get(bool,uint256)", true, u256(2)), encodeArgs(u256(84)));
ABI_CHECK(callContractFunction("get(bool,uint256)", true, u256(21)), encodeArgs(u256(7)));
ABI_CHECK(callContractFunction("get_a(uint256)", u256(0)), encodeArgs(u256(0)));
ABI_CHECK(callContractFunction("get_a(uint256)", u256(1)), encodeArgs(u256(42)));
ABI_CHECK(callContractFunction("get_a(uint256)", u256(2)), encodeArgs(u256(84)));
ABI_CHECK(callContractFunction("get_a(uint256)", u256(21)), encodeArgs(u256(7)));
ABI_CHECK(callContractFunction("get(bool,uint256)", false, u256(0)), encodeArgs(u256(0)));
ABI_CHECK(callContractFunction("get(bool,uint256)", false, u256(1)), encodeArgs(u256(10)));
ABI_CHECK(callContractFunction("get(bool,uint256)", false, u256(2)), encodeArgs(u256(11)));
ABI_CHECK(callContractFunction("get(bool,uint256)", false, u256(21)), encodeArgs(u256(12)));
ABI_CHECK(callContractFunction("get_b(uint256)", u256(0)), encodeArgs(u256(0)));
ABI_CHECK(callContractFunction("get_b(uint256)", u256(1)), encodeArgs(u256(10)));
ABI_CHECK(callContractFunction("get_b(uint256)", u256(2)), encodeArgs(u256(11)));
ABI_CHECK(callContractFunction("get_b(uint256)", u256(21)), encodeArgs(u256(12)));
ABI_CHECK(callContractFunction("set(bool,uint256,uint256)", true, u256(1), u256(21)), encodeArgs(u256(42)));
ABI_CHECK(callContractFunction("set(bool,uint256,uint256)", true, u256(2), u256(42)), encodeArgs(u256(84)));
ABI_CHECK(callContractFunction("set(bool,uint256,uint256)", true, u256(21), u256(14)), encodeArgs(u256(7)));
ABI_CHECK(callContractFunction("set(bool,uint256,uint256)", false, u256(1), u256(30)), encodeArgs(u256(10)));
ABI_CHECK(callContractFunction("set(bool,uint256,uint256)", false, u256(2), u256(31)), encodeArgs(u256(11)));
ABI_CHECK(callContractFunction("set(bool,uint256,uint256)", false, u256(21), u256(32)), encodeArgs(u256(12)));
ABI_CHECK(callContractFunction("get_a(uint256)", u256(0)), encodeArgs(u256(0)));
ABI_CHECK(callContractFunction("get_a(uint256)", u256(1)), encodeArgs(u256(21)));
ABI_CHECK(callContractFunction("get_a(uint256)", u256(2)), encodeArgs(u256(42)));
ABI_CHECK(callContractFunction("get_a(uint256)", u256(21)), encodeArgs(u256(14)));
ABI_CHECK(callContractFunction("get(bool,uint256)", true, u256(0)), encodeArgs(u256(0)));
ABI_CHECK(callContractFunction("get(bool,uint256)", true, u256(1)), encodeArgs(u256(21)));
ABI_CHECK(callContractFunction("get(bool,uint256)", true, u256(2)), encodeArgs(u256(42)));
ABI_CHECK(callContractFunction("get(bool,uint256)", true, u256(21)), encodeArgs(u256(14)));
ABI_CHECK(callContractFunction("get_b(uint256)", u256(0)), encodeArgs(u256(0)));
ABI_CHECK(callContractFunction("get_b(uint256)", u256(1)), encodeArgs(u256(30)));
ABI_CHECK(callContractFunction("get_b(uint256)", u256(2)), encodeArgs(u256(31)));
ABI_CHECK(callContractFunction("get_b(uint256)", u256(21)), encodeArgs(u256(32)));
ABI_CHECK(callContractFunction("get(bool,uint256)", false, u256(0)), encodeArgs(u256(0)));
ABI_CHECK(callContractFunction("get(bool,uint256)", false, u256(1)), encodeArgs(u256(30)));
ABI_CHECK(callContractFunction("get(bool,uint256)", false, u256(2)), encodeArgs(u256(31)));
ABI_CHECK(callContractFunction("get(bool,uint256)", false, u256(21)), encodeArgs(u256(32)));
}
BOOST_AUTO_TEST_CASE(mapping_returns_in_library_named)
{
char const* sourceCode = R"(
library Lib {
function f(mapping(uint => uint) storage a, mapping(uint => uint) storage b) internal returns(mapping(uint=>uint) storage r)
{
r = a;
r[1] = 42;
r = b;
r[1] = 21;
}
}
contract Test {
mapping(uint => uint) a;
mapping(uint => uint) b;
function f() public returns (uint, uint, uint, uint, uint, uint)
{
Lib.f(a, b)[2] = 84;
return (a[0], a[1], a[2], b[0], b[1], b[2]);
}
function g() public returns (uint, uint, uint, uint, uint, uint)
{
mapping(uint => uint) storage m = Lib.f(a, b);
m[2] = 17;
return (a[0], a[1], a[2], b[0], b[1], b[2]);
}
}
)";
compileAndRun(sourceCode, 0, "Lib");
compileAndRun(sourceCode, 0, "Test", bytes(), map<string, Address>{{"Lib", m_contractAddress}});
ABI_CHECK(callContractFunction("f()"), encodeArgs(u256(0), u256(42), u256(0), u256(0), u256(21), u256(84)));
ABI_CHECK(callContractFunction("g()"), encodeArgs(u256(0), u256(42), u256(0), u256(0), u256(21), u256(17)));
}
BOOST_AUTO_TEST_CASE(using_library_mappings_public)
{
char const* sourceCode = R"(
library Lib {
function set(mapping(uint => uint) storage m, uint key, uint value) public
{
m[key] = value;
}
}
contract Test {
mapping(uint => uint) m1;
mapping(uint => uint) m2;
function f() public returns (uint, uint, uint, uint, uint, uint)
{
Lib.set(m1, 0, 1);
Lib.set(m1, 2, 42);
Lib.set(m2, 0, 23);
Lib.set(m2, 2, 99);
return (m1[0], m1[1], m1[2], m2[0], m2[1], m2[2]);
}
}
)";
compileAndRun(sourceCode, 0, "Lib");
compileAndRun(sourceCode, 0, "Test", bytes(), map<string, Address>{{"Lib", m_contractAddress}});
ABI_CHECK(callContractFunction("f()"), encodeArgs(u256(1), u256(0), u256(42), u256(23), u256(0), u256(99)));
}
BOOST_AUTO_TEST_CASE(using_library_mappings_external)
{
char const* libSourceCode = R"(
library Lib {
function set(mapping(uint => uint) storage m, uint key, uint value) external
{
m[key] = value * 2;
}
}
)";
char const* sourceCode = R"(
library Lib {
function set(mapping(uint => uint) storage m, uint key, uint value) external;
}
contract Test {
mapping(uint => uint) m1;
mapping(uint => uint) m2;
function f() public returns (uint, uint, uint, uint, uint, uint)
{
Lib.set(m1, 0, 1);
Lib.set(m1, 2, 42);
Lib.set(m2, 0, 23);
Lib.set(m2, 2, 99);
return (m1[0], m1[1], m1[2], m2[0], m2[1], m2[2]);
}
}
)";
for (auto v2: {false, true})
{
string prefix = v2 ? "pragma experimental ABIEncoderV2;\n" : "";
compileAndRun(prefix + libSourceCode, 0, "Lib");
compileAndRun(prefix + sourceCode, 0, "Test", bytes(), map<string, Address>{{"Lib", m_contractAddress}});
ABI_CHECK(callContractFunction("f()"), encodeArgs(u256(2), u256(0), u256(84), u256(46), u256(0), u256(198)));
}
}
BOOST_AUTO_TEST_CASE(using_library_mappings_return)
{
char const* sourceCode = R"(
library Lib {
function choose(mapping(uint => mapping(uint => uint)) storage m, uint key) external returns (mapping(uint => uint) storage) {
return m[key];
}
}
contract Test {
mapping(uint => mapping(uint => uint)) m;
function f() public returns (uint, uint, uint, uint, uint, uint)
{
Lib.choose(m, 0)[0] = 1;
Lib.choose(m, 0)[2] = 42;
Lib.choose(m, 1)[0] = 23;
Lib.choose(m, 1)[2] = 99;
return (m[0][0], m[0][1], m[0][2], m[1][0], m[1][1], m[1][2]);
}
}
)";
compileAndRun(sourceCode, 0, "Lib");
compileAndRun(sourceCode, 0, "Test", bytes(), map<string, Address>{{"Lib", m_contractAddress}});
ABI_CHECK(callContractFunction("f()"), encodeArgs(u256(1), u256(0), u256(42), u256(23), u256(0), u256(99)));
}
BOOST_AUTO_TEST_CASE(using_library_structs)
{
char const* sourceCode = R"(
library Lib {
struct Data { uint a; uint[] b; }
function set(Data storage _s) public
{
_s.a = 7;
_s.b.length = 20;
_s.b[19] = 8;
}
}
contract Test {
mapping(string => Lib.Data) data;
function f() public returns (uint a, uint b)
{
Lib.set(data["abc"]);
a = data["abc"].a;
b = data["abc"].b[19];
}
}
)";
compileAndRun(sourceCode, 0, "Lib");
compileAndRun(sourceCode, 0, "Test", bytes(), map<string, Address>{{"Lib", m_contractAddress}});
ABI_CHECK(callContractFunction("f()"), encodeArgs(u256(7), u256(8)));
}
BOOST_AUTO_TEST_CASE(library_struct_as_an_expression)
{
char const* sourceCode = R"(
library Arst {
struct Foo {
int Things;
int Stuff;
}
}
contract Tsra {
function f() public returns(uint) {
Arst.Foo;
return 1;
}
}
)";
compileAndRun(sourceCode, 0, "Tsra");
ABI_CHECK(callContractFunction("f()"), encodeArgs(u256(1)));
}
BOOST_AUTO_TEST_CASE(library_enum_as_an_expression)
{
char const* sourceCode = R"(
library Arst {
enum Foo {
Things,
Stuff
}
}
contract Tsra {
function f() public returns(uint) {
Arst.Foo;
return 1;
}
}
)";
compileAndRun(sourceCode, 0, "Tsra");
ABI_CHECK(callContractFunction("f()"), encodeArgs(u256(1)));
}
BOOST_AUTO_TEST_CASE(short_strings)
{
// This test verifies that the byte array encoding that combines length and data works
// correctly.
char const* sourceCode = R"(
contract A {
bytes public data1 = "123";
bytes data2;
function lengthChange() public returns (uint)
{
// store constant in short and long string
data1 = "123";
if (!equal(data1, "123")) return 1;
data2 = "12345678901234567890123456789012345678901234567890a";
if (data2[17] != "8") return 3;
if (data2.length != 51) return 4;
if (data2[data2.length - 1] != "a") return 5;
// change length: short -> short
data1.length = 5;
if (data1.length != 5) return 6;
data1[4] = "4";
if (data1[0] != "1") return 7;
if (data1[4] != "4") return 8;
// change length: short -> long
data1.length = 80;
if (data1.length != 80) return 9;
data1.length = 70;
if (data1.length != 70) return 9;
if (data1[0] != "1") return 10;
if (data1[4] != "4") return 11;
for (uint i = 0; i < data1.length; i ++)
data1[i] = byte(uint8(i * 3));
if (uint8(data1[4]) != 4 * 3) return 12;
if (uint8(data1[67]) != 67 * 3) return 13;
// change length: long -> short
data1.length = 22;
if (data1.length != 22) return 14;
if (uint8(data1[21]) != 21 * 3) return 15;
if (uint8(data1[2]) != 2 * 3) return 16;
// change length: short -> shorter
data1.length = 19;
if (data1.length != 19) return 17;
if (uint8(data1[7]) != 7 * 3) return 18;
// and now again to original size
data1.length = 22;
if (data1.length != 22) return 19;
if (data1[21] != 0) return 20;
data1.length = 0;
data2.length = 0;
}
function copy() public returns (uint) {
bytes memory x = "123";
bytes memory y = "012345678901234567890123456789012345678901234567890123456789";
bytes memory z = "1234567";
data1 = x;
data2 = y;
if (!equal(data1, x)) return 1;
if (!equal(data2, y)) return 2;
// lengthen
data1 = y;
if (!equal(data1, y)) return 3;
// shorten
data1 = x;
if (!equal(data1, x)) return 4;
// change while keeping short
data1 = z;
if (!equal(data1, z)) return 5;
// copy storage -> storage
data1 = x;
data2 = y;
// lengthen
data1 = data2;
if (!equal(data1, y)) return 6;
// shorten
data1 = x;
data2 = data1;
if (!equal(data2, x)) return 7;
bytes memory c = data2;
data1 = c;
if (!equal(data1, x)) return 8;
data1 = "";
data2 = "";
}
function deleteElements() public returns (uint) {
data1 = "01234";
delete data1[2];
if (data1[2] != 0) return 1;
if (data1[0] != "0") return 2;
if (data1[3] != "3") return 3;
delete data1;
if (data1.length != 0) return 4;
}
function equal(bytes storage a, bytes memory b) internal returns (bool) {
if (a.length != b.length) return false;
for (uint i = 0; i < a.length; ++i) if (a[i] != b[i]) return false;
return true;
}
}
)";
compileAndRun(sourceCode, 0, "A");
ABI_CHECK(callContractFunction("data1()"), encodeDyn(string("123")));
ABI_CHECK(callContractFunction("lengthChange()"), encodeArgs(u256(0)));
BOOST_CHECK(storageEmpty(m_contractAddress));
ABI_CHECK(callContractFunction("deleteElements()"), encodeArgs(u256(0)));
BOOST_CHECK(storageEmpty(m_contractAddress));
ABI_CHECK(callContractFunction("copy()"), encodeArgs(u256(0)));
BOOST_CHECK(storageEmpty(m_contractAddress));
}
BOOST_AUTO_TEST_CASE(calldata_offset)
{
// This tests a specific bug that was caused by not using the correct memory offset in the
// calldata unpacker.
char const* sourceCode = R"(
contract CB
{
address[] _arr;
string public last = "nd";
constructor(address[] memory guardians) public
{
_arr = guardians;
}
}
)";
compileAndRun(sourceCode, 0, "CB", encodeArgs(u256(0x20)));
ABI_CHECK(callContractFunction("last()", encodeArgs()), encodeDyn(string("nd")));
}
BOOST_AUTO_TEST_CASE(contract_binary_dependencies)
{
char const* sourceCode = R"(
contract A { function f() public { new B(); } }
contract B { function f() public { } }
contract C { function f() public { new B(); } }
)";
compileAndRun(sourceCode);
}
BOOST_AUTO_TEST_CASE(reject_ether_sent_to_library)
{
char const* sourceCode = R"(
library lib {}
contract c {
constructor() public payable {}
function f(address payable x) public returns (bool) {
return x.send(1);
}
function () external payable {}
}
)";
compileAndRun(sourceCode, 0, "lib");
Address libraryAddress = m_contractAddress;
compileAndRun(sourceCode, 10, "c");
BOOST_CHECK_EQUAL(balanceAt(m_contractAddress), 10);
BOOST_CHECK_EQUAL(balanceAt(libraryAddress), 0);
ABI_CHECK(callContractFunction("f(address)", encodeArgs(u160(libraryAddress))), encodeArgs(false));
BOOST_CHECK_EQUAL(balanceAt(m_contractAddress), 10);
BOOST_CHECK_EQUAL(balanceAt(libraryAddress), 0);
ABI_CHECK(callContractFunction("f(address)", encodeArgs(u160(m_contractAddress))), encodeArgs(true));
BOOST_CHECK_EQUAL(balanceAt(m_contractAddress), 10);
BOOST_CHECK_EQUAL(balanceAt(libraryAddress), 0);
}
BOOST_AUTO_TEST_CASE(multi_variable_declaration)
{
char const* sourceCode = R"(
contract C {
function g() public returns (uint a, uint b, uint c) {
a = 1; b = 2; c = 3;
}
function h() public returns (uint a, uint b, uint c, uint d) {
a = 1; b = 2; c = 3; d = 4;
}
function f1() public returns (bool) {
(uint x, uint y, uint z) = g();
if (x != 1 || y != 2 || z != 3) return false;
(, uint a,) = g();
if (a != 2) return false;
(uint b, , ) = g();
if (b != 1) return false;
(, , uint c) = g();
if (c != 3) return false;
return true;
}
function f2() public returns (bool) {
(uint a1, , uint a3, ) = h();
if (a1 != 1 || a3 != 3) return false;
(uint b1, uint b2, , ) = h();
if (b1 != 1 || b2 != 2) return false;
(, uint c2, uint c3, ) = h();
if (c2 != 2 || c3 != 3) return false;
(, , uint d3, uint d4) = h();
if (d3 != 3 || d4 != 4) return false;
(uint e1, , uint e3, uint e4) = h();
if (e1 != 1 || e3 != 3 || e4 != 4) return false;
return true;
}
function f() public returns (bool) {
return f1() && f2();
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("f()", encodeArgs()), encodeArgs(true));
}
BOOST_AUTO_TEST_CASE(typed_multi_variable_declaration)
{
char const* sourceCode = R"(
contract C {
struct S { uint x; }
S s;
function g() internal returns (uint, S storage, uint) {
s.x = 7;
return (1, s, 2);
}
function f() public returns (bool) {
(uint x1, S storage y1, uint z1) = g();
if (x1 != 1 || y1.x != 7 || z1 != 2) return false;
(, S storage y2,) = g();
if (y2.x != 7) return false;
(uint x2,,) = g();
if (x2 != 1) return false;
(,,uint z2) = g();
if (z2 != 2) return false;
return true;
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("f()", encodeArgs()), encodeArgs(true));
}
BOOST_AUTO_TEST_CASE(tuples)
{
char const* sourceCode = R"(
contract C {
uint[] data;
uint[] m_c;
function g() internal returns (uint a, uint b, uint[] storage c) {
return (1, 2, data);
}
function h() external returns (uint a, uint b) {
return (5, 6);
}
function f() public returns (uint) {
data.length = 1;
data[0] = 3;
uint a; uint b;
(a, b) = this.h();
if (a != 5 || b != 6) return 1;
uint[] storage c = m_c;
(a, b, c) = g();
if (a != 1 || b != 2 || c[0] != 3) return 2;
(a, b) = (b, a);
if (a != 2 || b != 1) return 3;
(a, , b, , ) = (8, 9, 10, 11, 12);
if (a != 8 || b != 10) return 4;
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("f()"), encodeArgs(u256(0)));
}
BOOST_AUTO_TEST_CASE(string_tuples)
{
char const* sourceCode = R"(
contract C {
function f() public returns (string memory, uint) {
return ("abc", 8);
}
function g() public returns (string memory, string memory) {
return (h(), "def");
}
function h() public returns (string memory) {
return ("abc");
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("f()"), encodeArgs(u256(0x40), u256(8), u256(3), string("abc")));
ABI_CHECK(callContractFunction("g()"), encodeArgs(u256(0x40), u256(0x80), u256(3), string("abc"), u256(3), string("def")));
}
BOOST_AUTO_TEST_CASE(decayed_tuple)
{
char const* sourceCode = R"(
contract C {
function f() public returns (uint) {
uint x = 1;
(x) = 2;
return x;
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("f()"), encodeArgs(u256(2)));
}
BOOST_AUTO_TEST_CASE(inline_tuple_with_rational_numbers)
{
char const* sourceCode = R"(
contract c {
function f() public returns (int8) {
int8[5] memory foo3 = [int8(1), -1, 0, 0, 0];
return foo3[0];
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("f()"), encodeArgs(u256(1)));
}
BOOST_AUTO_TEST_CASE(destructuring_assignment)
{
char const* sourceCode = R"(
contract C {
uint x = 7;
bytes data;
uint[] y;
uint[] arrayData;
function returnsArray() public returns (uint[] memory) {
arrayData.length = 9;
arrayData[2] = 5;
arrayData[7] = 4;
return arrayData;
}
function f(bytes memory s) public returns (uint) {
uint loc;
uint[] memory memArray;
(loc, x, y, data, arrayData[3]) = (8, 4, returnsArray(), s, 2);
if (loc != 8) return 1;
if (x != 4) return 2;
if (y.length != 9) return 3;
if (y[2] != 5) return 4;
if (y[7] != 4) return 5;
if (data.length != s.length) return 6;
if (data[3] != s[3]) return 7;
if (arrayData[3] != 2) return 8;
(memArray, loc) = (arrayData, 3);
if (loc != 3) return 9;
if (memArray.length != arrayData.length) return 10;
bytes memory memBytes;
(x, memBytes, y[2], , ) = (456, s, 789, 101112, 131415);
if (x != 456 || memBytes.length != s.length || y[2] != 789) return 11;
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("f(bytes)", u256(0x20), u256(5), string("abcde")), encodeArgs(u256(0)));
}
BOOST_AUTO_TEST_CASE(lone_struct_array_type)
{
char const* sourceCode = R"(
contract C {
struct s { uint a; uint b;}
function f() public returns (uint) {
s[7][]; // This is only the type, should not have any effect
return 3;
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("f()"), encodeArgs(u256(3)));
}
BOOST_AUTO_TEST_CASE(create_memory_array)
{
char const* sourceCode = R"(
contract C {
struct S { uint[2] a; bytes b; }
function f() public returns (byte, uint, uint, byte) {
bytes memory x = new bytes(200);
x[199] = 'A';
uint[2][] memory y = new uint[2][](300);
y[203][1] = 8;
S[] memory z = new S[](180);
z[170].a[1] = 4;
z[170].b = new bytes(102);
z[170].b[99] = 'B';
return (x[199], y[203][1], z[170].a[1], z[170].b[99]);
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("f()"), encodeArgs(string("A"), u256(8), u256(4), string("B")));
}
BOOST_AUTO_TEST_CASE(create_memory_array_allocation_size)
{
// Check allocation size of byte array. Should be 32 plus length rounded up to next
// multiple of 32
char const* sourceCode = R"(
contract C {
function f() public pure returns (uint d1, uint d2, uint d3, uint memsize) {
bytes memory b1 = new bytes(31);
bytes memory b2 = new bytes(32);
bytes memory b3 = new bytes(256);
bytes memory b4 = new bytes(31);
assembly {
d1 := sub(b2, b1)
d2 := sub(b3, b2)
d3 := sub(b4, b3)
memsize := msize()
}
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("f()"), encodeArgs(0x40, 0x40, 0x20 + 256, 0x260));
}
BOOST_AUTO_TEST_CASE(memory_arrays_of_various_sizes)
{
// Computes binomial coefficients the chinese way
char const* sourceCode = R"(
contract C {
function f(uint n, uint k) public returns (uint) {
uint[][] memory rows = new uint[][](n + 1);
for (uint i = 1; i <= n; i++) {
rows[i] = new uint[](i);
rows[i][0] = rows[i][rows[i].length - 1] = 1;
for (uint j = 1; j < i - 1; j++)
rows[i][j] = rows[i - 1][j - 1] + rows[i - 1][j];
}
return rows[n][k - 1];
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("f(uint256,uint256)", encodeArgs(u256(3), u256(1))), encodeArgs(u256(1)));
ABI_CHECK(callContractFunction("f(uint256,uint256)", encodeArgs(u256(9), u256(5))), encodeArgs(u256(70)));
}
BOOST_AUTO_TEST_CASE(create_multiple_dynamic_arrays)
{
char const* sourceCode = R"(
contract C {
function f() public returns (uint) {
uint[][] memory x = new uint[][](42);
assert(x[0].length == 0);
x[0] = new uint[](1);
x[0][0] = 1;
assert(x[4].length == 0);
x[4] = new uint[](1);
x[4][0] = 2;
assert(x[10].length == 0);
x[10] = new uint[](1);
x[10][0] = 44;
uint[][] memory y = new uint[][](24);
assert(y[0].length == 0);
y[0] = new uint[](1);
y[0][0] = 1;
assert(y[4].length == 0);
y[4] = new uint[](1);
y[4][0] = 2;
assert(y[10].length == 0);
y[10] = new uint[](1);
y[10][0] = 88;
if ((x[0][0] == y[0][0]) && (x[4][0] == y[4][0]) && (x[10][0] == 44) && (y[10][0] == 88))
return 7;
return 0;
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("f()"), encodeArgs(u256(7)));
}
BOOST_AUTO_TEST_CASE(memory_overwrite)
{
char const* sourceCode = R"(
contract C {
function f() public returns (bytes memory x) {
x = "12345";
x[3] = 0x61;
x[0] = 0x62;
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("f()"), encodeDyn(string("b23a5")));
}
BOOST_AUTO_TEST_CASE(addmod_mulmod)
{
char const* sourceCode = R"(
contract C {
function test() public returns (uint) {
// Note that this only works because computation on literals is done using
// unbounded integers.
if ((2**255 + 2**255) % 7 != addmod(2**255, 2**255, 7))
return 1;
if ((2**255 + 2**255) % 7 != addmod(2**255, 2**255, 7))
return 2;
return 0;
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("test()"), encodeArgs(u256(0)));
}
BOOST_AUTO_TEST_CASE(addmod_mulmod_zero)
{
char const* sourceCode = R"(
contract C {
function f(uint d) public pure returns (uint) {
addmod(1, 2, d);
return 2;
}
function g(uint d) public pure returns (uint) {
mulmod(1, 2, d);
return 2;
}
function h() public pure returns (uint) {
mulmod(0, 1, 2);
mulmod(1, 0, 2);
addmod(0, 1, 2);
addmod(1, 0, 2);
return 2;
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("f(uint)", 0), encodeArgs());
ABI_CHECK(callContractFunction("g(uint)", 0), encodeArgs());
ABI_CHECK(callContractFunction("h()"), encodeArgs(2));
}
BOOST_AUTO_TEST_CASE(divisiod_by_zero)
{
char const* sourceCode = R"(
contract C {
function div(uint a, uint b) public returns (uint) {
return a / b;
}
function mod(uint a, uint b) public returns (uint) {
return a % b;
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("div(uint256,uint256)", 7, 2), encodeArgs(u256(3)));
// throws
ABI_CHECK(callContractFunction("div(uint256,uint256)", 7, 0), encodeArgs());
ABI_CHECK(callContractFunction("mod(uint256,uint256)", 7, 2), encodeArgs(u256(1)));
// throws
ABI_CHECK(callContractFunction("mod(uint256,uint256)", 7, 0), encodeArgs());
}
BOOST_AUTO_TEST_CASE(string_allocation_bug)
{
char const* sourceCode = R"(
contract Sample
{
struct s { uint16 x; uint16 y; string a; string b;}
s[2] public p;
constructor() public {
s memory m;
m.x = 0xbbbb;
m.y = 0xcccc;
m.a = "hello";
m.b = "world";
p[0] = m;
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("p(uint256)", 0), encodeArgs(
u256(0xbbbb),
u256(0xcccc),
u256(0x80),
u256(0xc0),
u256(5),
string("hello"),
u256(5),
string("world")
));
}
BOOST_AUTO_TEST_CASE(using_for_function_on_int)
{
char const* sourceCode = R"(
library D { function double(uint self) public returns (uint) { return 2*self; } }
contract C {
using D for uint;
function f(uint a) public returns (uint) {
return a.double();
}
}
)";
compileAndRun(sourceCode, 0, "D");
compileAndRun(sourceCode, 0, "C", bytes(), map<string, Address>{{"D", m_contractAddress}});
ABI_CHECK(callContractFunction("f(uint256)", u256(9)), encodeArgs(u256(2 * 9)));
}
BOOST_AUTO_TEST_CASE(using_for_function_on_struct)
{
char const* sourceCode = R"(
library D { struct s { uint a; } function mul(s storage self, uint x) public returns (uint) { return self.a *= x; } }
contract C {
using D for D.s;
D.s public x;
function f(uint a) public returns (uint) {
x.a = 3;
return x.mul(a);
}
}
)";
compileAndRun(sourceCode, 0, "D");
compileAndRun(sourceCode, 0, "C", bytes(), map<string, Address>{{"D", m_contractAddress}});
ABI_CHECK(callContractFunction("f(uint256)", u256(7)), encodeArgs(u256(3 * 7)));
ABI_CHECK(callContractFunction("x()"), encodeArgs(u256(3 * 7)));
}
BOOST_AUTO_TEST_CASE(using_for_overload)
{
char const* sourceCode = R"(
library D {
struct s { uint a; }
function mul(s storage self, uint x) public returns (uint) { return self.a *= x; }
function mul(s storage self, bytes32 x) public returns (bytes32) { }
}
contract C {
using D for D.s;
D.s public x;
function f(uint a) public returns (uint) {
x.a = 6;
return x.mul(a);
}
}
)";
compileAndRun(sourceCode, 0, "D");
compileAndRun(sourceCode, 0, "C", bytes(), map<string, Address>{{"D", m_contractAddress}});
ABI_CHECK(callContractFunction("f(uint256)", u256(7)), encodeArgs(u256(6 * 7)));
ABI_CHECK(callContractFunction("x()"), encodeArgs(u256(6 * 7)));
}
BOOST_AUTO_TEST_CASE(using_for_by_name)
{
char const* sourceCode = R"(
library D { struct s { uint a; } function mul(s storage self, uint x) public returns (uint) { return self.a *= x; } }
contract C {
using D for D.s;
D.s public x;
function f(uint a) public returns (uint) {
x.a = 6;
return x.mul({x: a});
}
}
)";
compileAndRun(sourceCode, 0, "D");
compileAndRun(sourceCode, 0, "C", bytes(), map<string, Address>{{"D", m_contractAddress}});
ABI_CHECK(callContractFunction("f(uint256)", u256(7)), encodeArgs(u256(6 * 7)));
ABI_CHECK(callContractFunction("x()"), encodeArgs(u256(6 * 7)));
}
BOOST_AUTO_TEST_CASE(bound_function_in_function)
{
char const* sourceCode = R"(
library L {
function g(function() internal returns (uint) _t) internal returns (uint) { return _t(); }
}
contract C {
using L for *;
function f() public returns (uint) {
return t.g();
}
function t() public pure returns (uint) { return 7; }
}
)";
compileAndRun(sourceCode, 0, "L");
compileAndRun(sourceCode, 0, "C", bytes(), map<string, Address>{{"L", m_contractAddress}});
ABI_CHECK(callContractFunction("f()"), encodeArgs(u256(7)));
}
BOOST_AUTO_TEST_CASE(bound_function_in_var)
{
char const* sourceCode = R"(
library D { struct s { uint a; } function mul(s storage self, uint x) public returns (uint) { return self.a *= x; } }
contract C {
using D for D.s;
D.s public x;
function f(uint a) public returns (uint) {
x.a = 6;
return (x.mul)({x: a});
}
}
)";
compileAndRun(sourceCode, 0, "D");
compileAndRun(sourceCode, 0, "C", bytes(), map<string, Address>{{"D", m_contractAddress}});
ABI_CHECK(callContractFunction("f(uint256)", u256(7)), encodeArgs(u256(6 * 7)));
ABI_CHECK(callContractFunction("x()"), encodeArgs(u256(6 * 7)));
}
BOOST_AUTO_TEST_CASE(bound_function_to_string)
{
char const* sourceCode = R"(
library D { function length(string memory self) public returns (uint) { return bytes(self).length; } }
contract C {
using D for string;
string x;
function f() public returns (uint) {
x = "abc";
return x.length();
}
function g() public returns (uint) {
string memory s = "abc";
return s.length();
}
}
)";
compileAndRun(sourceCode, 0, "D");
compileAndRun(sourceCode, 0, "C", bytes(), map<string, Address>{{"D", m_contractAddress}});
ABI_CHECK(callContractFunction("f()"), encodeArgs(u256(3)));
ABI_CHECK(callContractFunction("g()"), encodeArgs(u256(3)));
}
BOOST_AUTO_TEST_CASE(inline_array_storage_to_memory_conversion_strings)
{
char const* sourceCode = R"(
contract C {
string s = "doh";
function f() public returns (string memory, string memory) {
string memory t = "ray";
string[3] memory x = [s, t, "mi"];
return (x[1], x[2]);
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("f()"), encodeArgs(u256(0x40), u256(0x80), u256(3), string("ray"), u256(2), string("mi")));
}
BOOST_AUTO_TEST_CASE(inline_array_strings_from_document)
{
char const* sourceCode = R"(
contract C {
function f(uint i) public returns (string memory) {
string[4] memory x = ["This", "is", "an", "array"];
return (x[i]);
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("f(uint256)", u256(0)), encodeArgs(u256(0x20), u256(4), string("This")));
ABI_CHECK(callContractFunction("f(uint256)", u256(1)), encodeArgs(u256(0x20), u256(2), string("is")));
ABI_CHECK(callContractFunction("f(uint256)", u256(2)), encodeArgs(u256(0x20), u256(2), string("an")));
ABI_CHECK(callContractFunction("f(uint256)", u256(3)), encodeArgs(u256(0x20), u256(5), string("array")));
}
BOOST_AUTO_TEST_CASE(inline_array_storage_to_memory_conversion_ints)
{
char const* sourceCode = R"(
contract C {
function f() public returns (uint x, uint y) {
x = 3;
y = 6;
uint[2] memory z = [x, y];
return (z[0], z[1]);
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("f()"), encodeArgs(3, 6));
}
BOOST_AUTO_TEST_CASE(inline_array_index_access_ints)
{
char const* sourceCode = R"(
contract C {
function f() public returns (uint) {
return ([1, 2, 3, 4][2]);
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("f()"), encodeArgs(3));
}
BOOST_AUTO_TEST_CASE(inline_array_index_access_strings)
{
char const* sourceCode = R"(
contract C {
string public tester;
function f() public returns (string memory) {
return (["abc", "def", "g"][0]);
}
function test() public {
tester = f();
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("test()"), encodeArgs());
ABI_CHECK(callContractFunction("tester()"), encodeArgs(u256(0x20), u256(3), string("abc")));
}
BOOST_AUTO_TEST_CASE(inline_array_return)
{
char const* sourceCode = R"(
contract C {
uint8[] tester;
function f() public returns (uint8[5] memory) {
return ([1,2,3,4,5]);
}
function test() public returns (uint8, uint8, uint8, uint8, uint8) {
tester = f();
return (tester[0], tester[1], tester[2], tester[3], tester[4]);
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("f()"), encodeArgs(1, 2, 3, 4, 5));
}
BOOST_AUTO_TEST_CASE(inline_array_singleton)
{
// This caused a failure since the type was not converted to its mobile type.
char const* sourceCode = R"(
contract C {
function f() public returns (uint) {
return [4][0];
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("f()"), encodeArgs(u256(4)));
}
BOOST_AUTO_TEST_CASE(inline_long_string_return)
{
char const* sourceCode = R"(
contract C {
function f() public returns (string memory) {
return (["somethingShort", "0123456789012345678901234567890123456789012345678901234567890123456789012345678901234567890123456789001234567890123456789012345678901234567890123456789012345678901234567890123456789012345678901234567890012345678901234567890123456789012345678901234567890123456789012345678901234567890123456789012345678900123456789012345678901234567890123456789012345678901234567890123456789012345678901234567890123456789001234567890123456789012345678901234567890123456789012345678901234567890123456789012345678901234567890"][1]);
}
}
)";
string strLong = "0123456789012345678901234567890123456789012345678901234567890123456789012345678901234567890123456789001234567890123456789012345678901234567890123456789012345678901234567890123456789012345678901234567890012345678901234567890123456789012345678901234567890123456789012345678901234567890123456789012345678900123456789012345678901234567890123456789012345678901234567890123456789012345678901234567890123456789001234567890123456789012345678901234567890123456789012345678901234567890123456789012345678901234567890";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("f()"), encodeDyn(strLong));
}
BOOST_AUTO_TEST_CASE(fixed_bytes_index_access)
{
char const* sourceCode = R"(
contract C {
bytes16[] public data;
function f(bytes32 x) public returns (byte) {
return x[2];
}
function g(bytes32 x) public returns (uint) {
data = [x[0], x[1], x[2]];
data[0] = "12345";
return uint(uint8(data[0][4]));
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("f(bytes32)", "789"), encodeArgs("9"));
ABI_CHECK(callContractFunction("g(bytes32)", "789"), encodeArgs(u256(int('5'))));
ABI_CHECK(callContractFunction("data(uint256)", u256(1)), encodeArgs("8"));
}
BOOST_AUTO_TEST_CASE(fixed_bytes_length_access)
{
char const* sourceCode = R"(
contract C {
byte a;
function f(bytes32 x) public returns (uint, uint, uint) {
return (x.length, bytes16(uint128(2)).length, a.length + 7);
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("f(bytes32)", "789"), encodeArgs(u256(32), u256(16), u256(8)));
}
BOOST_AUTO_TEST_CASE(byte_optimization_bug)
{
char const* sourceCode = R"(
contract C {
function f(uint x) public returns (uint a) {
assembly {
a := byte(x, 31)
}
}
function g(uint x) public returns (uint a) {
assembly {
a := byte(31, x)
}
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("f(uint256)", u256(2)), encodeArgs(u256(0)));
ABI_CHECK(callContractFunction("g(uint256)", u256(2)), encodeArgs(u256(2)));
}
BOOST_AUTO_TEST_CASE(inline_assembly_write_to_stack)
{
char const* sourceCode = R"(
contract C {
function f() public returns (uint r, bytes32 r2) {
assembly { r := 7 r2 := "abcdef" }
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("f()"), encodeArgs(u256(7), string("abcdef")));
}
BOOST_AUTO_TEST_CASE(inline_assembly_read_and_write_stack)
{
char const* sourceCode = R"(
contract C {
function f() public returns (uint r) {
for (uint x = 0; x < 10; ++x)
assembly { r := add(r, x) }
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("f()"), encodeArgs(u256(45)));
}
BOOST_AUTO_TEST_CASE(inline_assembly_memory_access)
{
char const* sourceCode = R"(
contract C {
function test() public returns (bytes memory) {
bytes memory x = new bytes(5);
for (uint i = 0; i < x.length; ++i)
x[i] = byte(uint8(i + 1));
assembly { mstore(add(x, 32), "12345678901234567890123456789012") }
return x;
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("test()"), encodeArgs(u256(0x20), u256(5), string("12345")));
}
BOOST_AUTO_TEST_CASE(inline_assembly_storage_access)
{
char const* sourceCode = R"(
contract C {
uint16 x;
uint16 public y;
uint public z;
function f() public returns (bool) {
uint off1;
uint off2;
assembly {
sstore(z_slot, 7)
off1 := z_offset
off2 := y_offset
}
assert(off1 == 0);
assert(off2 == 2);
return true;
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("f()"), encodeArgs(true));
ABI_CHECK(callContractFunction("z()"), encodeArgs(u256(7)));
}
BOOST_AUTO_TEST_CASE(inline_assembly_storage_access_inside_function)
{
char const* sourceCode = R"(
contract C {
uint16 x;
uint16 public y;
uint public z;
function f() public returns (bool) {
uint off1;
uint off2;
assembly {
function f() -> o1 {
sstore(z_slot, 7)
o1 := y_offset
}
off2 := f()
}
assert(off2 == 2);
return true;
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("f()"), encodeArgs(true));
ABI_CHECK(callContractFunction("z()"), encodeArgs(u256(7)));
}
BOOST_AUTO_TEST_CASE(inline_assembly_storage_access_via_pointer)
{
char const* sourceCode = R"(
contract C {
struct Data { uint contents; }
uint public separator;
Data public a;
uint public separator2;
function f() public returns (bool) {
Data storage x = a;
uint off;
assembly {
sstore(x_slot, 7)
off := x_offset
}
assert(off == 0);
return true;
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("f()"), encodeArgs(true));
ABI_CHECK(callContractFunction("a()"), encodeArgs(u256(7)));
ABI_CHECK(callContractFunction("separator()"), encodeArgs(u256(0)));
ABI_CHECK(callContractFunction("separator2()"), encodeArgs(u256(0)));
}
BOOST_AUTO_TEST_CASE(inline_assembly_function_call)
{
char const* sourceCode = R"(
contract C {
function f() public {
assembly {
function asmfun(a, b, c) -> x, y, z {
x := a
y := b
z := 7
}
let a1, b1, c1 := asmfun(1, 2, 3)
mstore(0x00, a1)
mstore(0x20, b1)
mstore(0x40, c1)
return(0, 0x60)
}
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("f()"), encodeArgs(u256(1), u256(2), u256(7)));
}
BOOST_AUTO_TEST_CASE(inline_assembly_function_call_assignment)
{
char const* sourceCode = R"(
contract C {
function f() public {
assembly {
let a1, b1, c1
function asmfun(a, b, c) -> x, y, z {
x := a
y := b
z := 7
}
a1, b1, c1 := asmfun(1, 2, 3)
mstore(0x00, a1)
mstore(0x20, b1)
mstore(0x40, c1)
return(0, 0x60)
}
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("f()"), encodeArgs(u256(1), u256(2), u256(7)));
}
BOOST_AUTO_TEST_CASE(inline_assembly_function_call2)
{
char const* sourceCode = R"(
contract C {
function f() public {
assembly {
let d := 0x10
function asmfun(a, b, c) -> x, y, z {
x := a
y := b
z := 7
}
let a1, b1, c1 := asmfun(1, 2, 3)
mstore(0x00, a1)
mstore(0x20, b1)
mstore(0x40, c1)
mstore(0x60, d)
return(0, 0x80)
}
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("f()"), encodeArgs(u256(1), u256(2), u256(7), u256(0x10)));
}
BOOST_AUTO_TEST_CASE(inline_assembly_embedded_function_call)
{
char const* sourceCode = R"(
contract C {
function f() public {
assembly {
let d := 0x10
function asmfun(a, b, c) -> x, y, z {
x := g(a)
function g(r) -> s { s := mul(r, r) }
y := g(b)
z := 7
}
let a1, b1, c1 := asmfun(1, 2, 3)
mstore(0x00, a1)
mstore(0x20, b1)
mstore(0x40, c1)
mstore(0x60, d)
return(0, 0x80)
}
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("f()"), encodeArgs(u256(1), u256(4), u256(7), u256(0x10)));
}
BOOST_AUTO_TEST_CASE(inline_assembly_if)
{
char const* sourceCode = R"(
contract C {
function f(uint a) public returns (uint b) {
assembly {
if gt(a, 1) { b := 2 }
}
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("f(uint256)", u256(0)), encodeArgs(u256(0)));
ABI_CHECK(callContractFunction("f(uint256)", u256(1)), encodeArgs(u256(0)));
ABI_CHECK(callContractFunction("f(uint256)", u256(2)), encodeArgs(u256(2)));
ABI_CHECK(callContractFunction("f(uint256)", u256(3)), encodeArgs(u256(2)));
}
BOOST_AUTO_TEST_CASE(inline_assembly_switch)
{
char const* sourceCode = R"(
contract C {
function f(uint a) public returns (uint b) {
assembly {
switch a
case 1 { b := 8 }
case 2 { b := 9 }
default { b := 2 }
}
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("f(uint256)", u256(0)), encodeArgs(u256(2)));
ABI_CHECK(callContractFunction("f(uint256)", u256(1)), encodeArgs(u256(8)));
ABI_CHECK(callContractFunction("f(uint256)", u256(2)), encodeArgs(u256(9)));
ABI_CHECK(callContractFunction("f(uint256)", u256(3)), encodeArgs(u256(2)));
}
BOOST_AUTO_TEST_CASE(inline_assembly_recursion)
{
char const* sourceCode = R"(
contract C {
function f(uint a) public returns (uint b) {
assembly {
function fac(n) -> nf {
switch n
case 0 { nf := 1 }
case 1 { nf := 1 }
default { nf := mul(n, fac(sub(n, 1))) }
}
b := fac(a)
}
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("f(uint256)", u256(0)), encodeArgs(u256(1)));
ABI_CHECK(callContractFunction("f(uint256)", u256(1)), encodeArgs(u256(1)));
ABI_CHECK(callContractFunction("f(uint256)", u256(2)), encodeArgs(u256(2)));
ABI_CHECK(callContractFunction("f(uint256)", u256(3)), encodeArgs(u256(6)));
ABI_CHECK(callContractFunction("f(uint256)", u256(4)), encodeArgs(u256(24)));
}
BOOST_AUTO_TEST_CASE(inline_assembly_for)
{
char const* sourceCode = R"(
contract C {
function f(uint a) public returns (uint b) {
assembly {
function fac(n) -> nf {
nf := 1
for { let i := n } gt(i, 0) { i := sub(i, 1) } {
nf := mul(nf, i)
}
}
b := fac(a)
}
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("f(uint256)", u256(0)), encodeArgs(u256(1)));
ABI_CHECK(callContractFunction("f(uint256)", u256(1)), encodeArgs(u256(1)));
ABI_CHECK(callContractFunction("f(uint256)", u256(2)), encodeArgs(u256(2)));
ABI_CHECK(callContractFunction("f(uint256)", u256(3)), encodeArgs(u256(6)));
ABI_CHECK(callContractFunction("f(uint256)", u256(4)), encodeArgs(u256(24)));
}
BOOST_AUTO_TEST_CASE(inline_assembly_for2)
{
char const* sourceCode = R"(
contract C {
uint st;
function f(uint a) public returns (uint b, uint c, uint d) {
st = 0;
assembly {
function sideeffect(r) -> x { sstore(0, add(sload(0), r)) x := 1}
for { let i := a } eq(i, sideeffect(2)) { d := add(d, 3) } {
b := i
i := 0
}
}
c = st;
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("f(uint256)", u256(0)), encodeArgs(u256(0), u256(2), u256(0)));
ABI_CHECK(callContractFunction("f(uint256)", u256(1)), encodeArgs(u256(1), u256(4), u256(3)));
ABI_CHECK(callContractFunction("f(uint256)", u256(2)), encodeArgs(u256(0), u256(2), u256(0)));
}
BOOST_AUTO_TEST_CASE(index_access_with_type_conversion)
{
// Test for a bug where higher order bits cleanup was not done for array index access.
char const* sourceCode = R"(
contract C {
function f(uint x) public returns (uint[256] memory r){
r[uint8(x)] = 2;
}
}
)";
compileAndRun(sourceCode, 0, "C");
// neither of the two should throw due to out-of-bounds access
BOOST_CHECK(callContractFunction("f(uint256)", u256(0x01)).size() == 256 * 32);
BOOST_CHECK(callContractFunction("f(uint256)", u256(0x101)).size() == 256 * 32);
}
BOOST_AUTO_TEST_CASE(delete_on_array_of_structs)
{
// Test for a bug where we did not increment the counter properly while deleting a dynamic array.
char const* sourceCode = R"(
contract C {
struct S { uint x; uint[] y; }
S[] data;
function f() public returns (bool) {
data.length = 2;
data[0].x = 2**200;
data[1].x = 2**200;
delete data;
return true;
}
}
)";
compileAndRun(sourceCode, 0, "C");
// This code interprets x as an array length and thus will go out of gas.
// neither of the two should throw due to out-of-bounds access
ABI_CHECK(callContractFunction("f()"), encodeArgs(true));
}
BOOST_AUTO_TEST_CASE(internal_library_function)
{
// tests that internal library functions can be called from outside
// and retain the same memory context (i.e. are pulled into the caller's code)
char const* sourceCode = R"(
library L {
function f(uint[] memory _data) internal {
_data[3] = 2;
}
}
contract C {
function f() public returns (uint) {
uint[] memory x = new uint[](7);
x[3] = 8;
L.f(x);
return x[3];
}
}
)";
// This has to work without linking, because everything will be inlined.
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("f()"), encodeArgs(u256(2)));
}
BOOST_AUTO_TEST_CASE(internal_library_function_calling_private)
{
// tests that internal library functions that are called from outside and that
// themselves call private functions are still able to (i.e. the private function
// also has to be pulled into the caller's code)
char const* sourceCode = R"(
library L {
function g(uint[] memory _data) private {
_data[3] = 2;
}
function f(uint[] memory _data) internal {
g(_data);
}
}
contract C {
function f() public returns (uint) {
uint[] memory x = new uint[](7);
x[3] = 8;
L.f(x);
return x[3];
}
}
)";
// This has to work without linking, because everything will be inlined.
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("f()"), encodeArgs(u256(2)));
}
BOOST_AUTO_TEST_CASE(internal_library_function_bound)
{
char const* sourceCode = R"(
library L {
struct S { uint[] data; }
function f(S memory _s) internal {
_s.data[3] = 2;
}
}
contract C {
using L for L.S;
function f() public returns (uint) {
L.S memory x;
x.data = new uint[](7);
x.data[3] = 8;
x.f();
return x.data[3];
}
}
)";
// This has to work without linking, because everything will be inlined.
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("f()"), encodeArgs(u256(2)));
}
BOOST_AUTO_TEST_CASE(internal_library_function_return_var_size)
{
char const* sourceCode = R"(
library L {
struct S { uint[] data; }
function f(S memory _s) internal returns (uint[] memory) {
_s.data[3] = 2;
return _s.data;
}
}
contract C {
using L for L.S;
function f() public returns (uint) {
L.S memory x;
x.data = new uint[](7);
x.data[3] = 8;
return x.f()[3];
}
}
)";
// This has to work without linking, because everything will be inlined.
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("f()"), encodeArgs(u256(2)));
}
BOOST_AUTO_TEST_CASE(iszero_bnot_correct)
{
// A long time ago, some opcodes were renamed, which involved the opcodes
// "iszero" and "not".
char const* sourceCode = R"(
contract C {
function f() public returns (bool) {
bytes32 x = bytes32(uint256(1));
assembly { x := not(x) }
if (x != ~bytes32(uint256(1))) return false;
assembly { x := iszero(x) }
if (x != bytes32(0)) return false;
return true;
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("f()"), encodeArgs(true));
}
BOOST_AUTO_TEST_CASE(cleanup_bytes_types)
{
// Checks that bytesXX types are properly cleaned before they are compared.
char const* sourceCode = R"(
contract C {
function f(bytes2 a, uint16 x) public returns (uint) {
if (a != "ab") return 1;
if (x != 0x0102) return 2;
if (bytes3(uint24(x)) != 0x000102) return 3;
return 0;
}
}
)";
compileAndRun(sourceCode, 0, "C");
// We input longer data on purpose.
ABI_CHECK(callContractFunction("f(bytes2,uint16)", string("abc"), u256(0x040102)), encodeArgs(0));
}
BOOST_AUTO_TEST_CASE(cleanup_bytes_types_shortening)
{
char const* sourceCode = R"(
contract C {
function f() public pure returns (bytes32 r) {
bytes4 x = 0xffffffff;
bytes2 y = bytes2(x);
assembly { r := y }
// At this point, r and y both store four bytes, but
// y is properly cleaned before the equality check
require(y == bytes2(0xffff));
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("f()"), encodeArgs("\xff\xff\xff\xff"));
}
BOOST_AUTO_TEST_CASE(cleanup_address_types)
{
// Checks that address types are properly cleaned before they are compared.
char const* sourceCode = R"(
contract C {
function f(address a) public returns (uint) {
if (a != 0x1234567890123456789012345678901234567890) return 1;
return 0;
}
function g(address payable a) public returns (uint) {
if (a != 0x1234567890123456789012345678901234567890) return 1;
return 0;
}
}
)";
compileAndRun(sourceCode, 0, "C");
// We input longer data on purpose.
ABI_CHECK(callContractFunction("f(address)", u256("0xFFFF1234567890123456789012345678901234567890")), encodeArgs(0));
ABI_CHECK(callContractFunction("g(address)", u256("0xFFFF1234567890123456789012345678901234567890")), encodeArgs(0));
}
BOOST_AUTO_TEST_CASE(cleanup_address_types_shortening)
{
char const* sourceCode = R"(
contract C {
function f() public pure returns (address r) {
bytes21 x = 0x1122334455667788990011223344556677889900ff;
bytes20 y;
assembly { y := x }
address z = address(y);
assembly { r := z }
require(z == 0x1122334455667788990011223344556677889900);
}
function g() public pure returns (address payable r) {
bytes21 x = 0x1122334455667788990011223344556677889900ff;
bytes20 y;
assembly { y := x }
address payable z = address(y);
assembly { r := z }
require(z == 0x1122334455667788990011223344556677889900);
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("f()"), encodeArgs(u256("0x1122334455667788990011223344556677889900")));
ABI_CHECK(callContractFunction("g()"), encodeArgs(u256("0x1122334455667788990011223344556677889900")));
}
BOOST_AUTO_TEST_CASE(skip_dynamic_types)
{
// The EVM cannot provide access to dynamically-sized return values, so we have to skip them.
char const* sourceCode = R"(
contract C {
function f() public returns (uint, uint[] memory, uint) {
return (7, new uint[](2), 8);
}
function g() public returns (uint, uint) {
// Previous implementation "moved" b to the second place and did not skip.
(uint a,, uint b) = this.f();
return (a, b);
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("g()"), encodeArgs(u256(7), u256(8)));
}
BOOST_AUTO_TEST_CASE(skip_dynamic_types_for_structs)
{
// For accessors, the dynamic types are already removed in the external signature itself.
char const* sourceCode = R"(
contract C {
struct S {
uint x;
string a; // this is present in the accessor
uint[] b; // this is not present
uint y;
}
S public s;
function g() public returns (uint, uint) {
s.x = 2;
s.a = "abc";
s.b = [7, 8, 9];
s.y = 6;
(uint x,, uint y) = this.s();
return (x, y);
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("g()"), encodeArgs(u256(2), u256(6)));
}
BOOST_AUTO_TEST_CASE(failed_create)
{
char const* sourceCode = R"(
contract D { constructor() public payable {} }
contract C {
uint public x;
constructor() public payable {}
function f(uint amount) public returns (D) {
x++;
return (new D).value(amount)();
}
function stack(uint depth) public returns (address) {
if (depth < 1024)
return this.stack(depth - 1);
else
return address(f(0));
}
}
)";
compileAndRun(sourceCode, 20, "C");
BOOST_CHECK(callContractFunction("f(uint256)", 20) != encodeArgs(u256(0)));
ABI_CHECK(callContractFunction("x()"), encodeArgs(u256(1)));
ABI_CHECK(callContractFunction("f(uint256)", 20), encodeArgs());
ABI_CHECK(callContractFunction("x()"), encodeArgs(u256(1)));
ABI_CHECK(callContractFunction("stack(uint256)", 1023), encodeArgs());
ABI_CHECK(callContractFunction("x()"), encodeArgs(u256(1)));
}
BOOST_AUTO_TEST_CASE(create_dynamic_array_with_zero_length)
{
char const* sourceCode = R"(
contract C {
function f() public returns (uint) {
uint[][] memory a = new uint[][](0);
return 7;
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("f()"), encodeArgs(u256(7)));
}
BOOST_AUTO_TEST_CASE(correctly_initialize_memory_array_in_constructor)
{
// Memory arrays are initialized using codecopy past the size of the code.
// This test checks that it also works in the constructor context.
char const* sourceCode = R"(
contract C {
bool public success;
constructor() public {
// Make memory dirty.
assembly {
for { let i := 0 } lt(i, 64) { i := add(i, 1) } {
mstore(msize, not(0))
}
}
uint16[3] memory c;
require(c[0] == 0 && c[1] == 0 && c[2] == 0);
uint16[] memory x = new uint16[](3);
require(x[0] == 0 && x[1] == 0 && x[2] == 0);
success = true;
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("success()"), encodeArgs(u256(1)));
}
BOOST_AUTO_TEST_CASE(return_does_not_skip_modifier)
{
char const* sourceCode = R"(
contract C {
uint public x;
modifier setsx {
_;
x = 9;
}
function f() setsx public returns (uint) {
return 2;
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("x()"), encodeArgs(u256(0)));
ABI_CHECK(callContractFunction("f()"), encodeArgs(u256(2)));
ABI_CHECK(callContractFunction("x()"), encodeArgs(u256(9)));
}
BOOST_AUTO_TEST_CASE(break_in_modifier)
{
char const* sourceCode = R"(
contract C {
uint public x;
modifier run() {
for (uint i = 0; i < 10; i++) {
_;
break;
}
}
function f() run public {
uint k = x;
uint t = k + 1;
x = t;
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("x()"), encodeArgs(u256(0)));
ABI_CHECK(callContractFunction("f()"), encodeArgs());
ABI_CHECK(callContractFunction("x()"), encodeArgs(u256(1)));
}
BOOST_AUTO_TEST_CASE(continue_in_modifier)
{
char const* sourceCode = R"(
contract C {
uint public x;
modifier run() {
for (uint i = 0; i < 10; i++) {
if (i % 2 == 1) continue;
_;
}
}
function f() run public {
uint k = x;
uint t = k + 1;
x = t;
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("x()"), encodeArgs(u256(0)));
ABI_CHECK(callContractFunction("f()"), encodeArgs());
ABI_CHECK(callContractFunction("x()"), encodeArgs(u256(5)));
}
BOOST_AUTO_TEST_CASE(return_in_modifier)
{
char const* sourceCode = R"(
contract C {
uint public x;
modifier run() {
for (uint i = 1; i < 10; i++) {
if (i == 5) return;
_;
}
}
function f() run public {
uint k = x;
uint t = k + 1;
x = t;
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("x()"), encodeArgs(u256(0)));
ABI_CHECK(callContractFunction("f()"), encodeArgs());
ABI_CHECK(callContractFunction("x()"), encodeArgs(u256(4)));
}
BOOST_AUTO_TEST_CASE(stacked_return_with_modifiers)
{
char const* sourceCode = R"(
contract C {
uint public x;
modifier run() {
for (uint i = 0; i < 10; i++) {
_;
break;
}
}
function f() run public {
uint k = x;
uint t = k + 1;
x = t;
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("x()"), encodeArgs(u256(0)));
ABI_CHECK(callContractFunction("f()"), encodeArgs());
ABI_CHECK(callContractFunction("x()"), encodeArgs(u256(1)));
}
BOOST_AUTO_TEST_CASE(mutex)
{
char const* sourceCode = R"(
contract mutexed {
bool locked;
modifier protected {
if (locked) revert();
locked = true;
_;
locked = false;
}
}
contract Fund is mutexed {
uint shares;
constructor() public payable { shares = msg.value; }
function withdraw(uint amount) public protected returns (uint) {
// NOTE: It is very bad practice to write this function this way.
// Please refer to the documentation of how to do this properly.
if (amount > shares) revert();
(bool success,) = msg.sender.call.value(amount)("");
require(success);
shares -= amount;
return shares;
}
function withdrawUnprotected(uint amount) public returns (uint) {
// NOTE: It is very bad practice to write this function this way.
// Please refer to the documentation of how to do this properly.
if (amount > shares) revert();
(bool success,) = msg.sender.call.value(amount)("");
require(success);
shares -= amount;
return shares;
}
}
contract Attacker {
Fund public fund;
uint callDepth;
bool protected;
function setProtected(bool _protected) public { protected = _protected; }
constructor(Fund _fund) public { fund = _fund; }
function attack() public returns (uint) {
callDepth = 0;
return attackInternal();
}
function attackInternal() internal returns (uint) {
if (protected)
return fund.withdraw(10);
else
return fund.withdrawUnprotected(10);
}
function() external payable {
callDepth++;
if (callDepth < 4)
attackInternal();
}
}
)";
compileAndRun(sourceCode, 500, "Fund");
auto fund = m_contractAddress;
BOOST_CHECK_EQUAL(balanceAt(fund), 500);
compileAndRun(sourceCode, 0, "Attacker", encodeArgs(u160(fund)));
ABI_CHECK(callContractFunction("setProtected(bool)", true), encodeArgs());
ABI_CHECK(callContractFunction("attack()"), encodeArgs());
BOOST_CHECK_EQUAL(balanceAt(fund), 500);
ABI_CHECK(callContractFunction("setProtected(bool)", false), encodeArgs());
ABI_CHECK(callContractFunction("attack()"), encodeArgs(u256(460)));
BOOST_CHECK_EQUAL(balanceAt(fund), 460);
}
BOOST_AUTO_TEST_CASE(calling_nonexisting_contract_throws)
{
char const* sourceCode = R"YY(
contract D { function g() public; }
contract C {
D d = D(0x1212);
function f() public returns (uint) {
d.g();
return 7;
}
function g() public returns (uint) {
d.g.gas(200)();
return 7;
}
function h() public returns (uint) {
address(d).call(""); // this does not throw (low-level)
return 7;
}
}
)YY";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("f()"), encodeArgs());
ABI_CHECK(callContractFunction("g()"), encodeArgs());
ABI_CHECK(callContractFunction("h()"), encodeArgs(u256(7)));
}
BOOST_AUTO_TEST_CASE(payable_constructor)
{
char const* sourceCode = R"(
contract C {
constructor() public payable { }
}
)";
compileAndRun(sourceCode, 27, "C");
}
BOOST_AUTO_TEST_CASE(payable_function)
{
char const* sourceCode = R"(
contract C {
uint public a;
function f() payable public returns (uint) {
return msg.value;
}
function() external payable {
a = msg.value + 1;
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunctionWithValue("f()", 27), encodeArgs(u256(27)));
BOOST_CHECK_EQUAL(balanceAt(m_contractAddress), 27);
ABI_CHECK(callContractFunctionWithValue("", 27), encodeArgs());
BOOST_CHECK_EQUAL(balanceAt(m_contractAddress), 27 + 27);
ABI_CHECK(callContractFunction("a()"), encodeArgs(u256(28)));
BOOST_CHECK_EQUAL(balanceAt(m_contractAddress), 27 + 27);
}
BOOST_AUTO_TEST_CASE(payable_function_calls_library)
{
char const* sourceCode = R"(
library L {
function f() public returns (uint) { return 7; }
}
contract C {
function f() public payable returns (uint) {
return L.f();
}
}
)";
compileAndRun(sourceCode, 0, "L");
compileAndRun(sourceCode, 0, "C", bytes(), map<string, Address>{{"L", m_contractAddress}});
ABI_CHECK(callContractFunctionWithValue("f()", 27), encodeArgs(u256(7)));
}
BOOST_AUTO_TEST_CASE(non_payable_throw)
{
char const* sourceCode = R"(
contract C {
uint public a;
function f() public returns (uint) {
return msgvalue();
}
function msgvalue() internal returns (uint) {
return msg.value;
}
function() external {
update();
}
function update() internal {
a = msg.value + 1;
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunctionWithValue("f()", 27), encodeArgs());
BOOST_CHECK_EQUAL(balanceAt(m_contractAddress), 0);
ABI_CHECK(callContractFunction(""), encodeArgs());
ABI_CHECK(callContractFunction("a()"), encodeArgs(u256(1)));
ABI_CHECK(callContractFunctionWithValue("", 27), encodeArgs());
BOOST_CHECK_EQUAL(balanceAt(m_contractAddress), 0);
ABI_CHECK(callContractFunction("a()"), encodeArgs(u256(1)));
ABI_CHECK(callContractFunctionWithValue("a()", 27), encodeArgs());
BOOST_CHECK_EQUAL(balanceAt(m_contractAddress), 0);
}
BOOST_AUTO_TEST_CASE(no_nonpayable_circumvention_by_modifier)
{
char const* sourceCode = R"(
contract C {
modifier tryCircumvent {
if (false) _; // avoid the function, we should still not accept ether
}
function f() tryCircumvent public returns (uint) {
return msgvalue();
}
function msgvalue() internal returns (uint) {
return msg.value;
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunctionWithValue("f()", 27), encodeArgs());
BOOST_CHECK_EQUAL(balanceAt(m_contractAddress), 0);
}
BOOST_AUTO_TEST_CASE(mem_resize_is_not_paid_at_call)
{
// This tests that memory resize for return values is not paid during the call, which would
// make the gas calculation overly complex. We access the end of the output area before
// the call is made.
// Tests that this also survives the optimizer.
char const* sourceCode = R"(
contract C {
function f() public returns (uint[200] memory) {}
}
contract D {
function f(C c) public returns (uint) { c.f(); return 7; }
}
)";
compileAndRun(sourceCode, 0, "C");
u160 cAddr = m_contractAddress;
compileAndRun(sourceCode, 0, "D");
ABI_CHECK(callContractFunction("f(address)", cAddr), encodeArgs(u256(7)));
}
BOOST_AUTO_TEST_CASE(calling_uninitialized_function)
{
char const* sourceCode = R"(
contract C {
function intern() public returns (uint) {
function (uint) internal returns (uint) x;
x(2);
return 7;
}
function extern() public returns (uint) {
function (uint) external returns (uint) x;
x(2);
return 7;
}
}
)";
compileAndRun(sourceCode, 0, "C");
// This should throw exceptions
ABI_CHECK(callContractFunction("intern()"), encodeArgs());
ABI_CHECK(callContractFunction("extern()"), encodeArgs());
}
BOOST_AUTO_TEST_CASE(calling_uninitialized_function_in_detail)
{
char const* sourceCode = R"(
contract C {
function() internal returns (uint) x;
int mutex;
function t() public returns (uint) {
if (mutex > 0)
{ assembly { mstore(0, 7) return(0, 0x20) } }
mutex = 1;
// Avoid re-executing this function if we jump somewhere.
x();
return 2;
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("t()"), encodeArgs());
}
BOOST_AUTO_TEST_CASE(calling_uninitialized_function_through_array)
{
char const* sourceCode = R"(
contract C {
int mutex;
function t() public returns (uint) {
if (mutex > 0)
{ assembly { mstore(0, 7) return(0, 0x20) } }
mutex = 1;
// Avoid re-executing this function if we jump somewhere.
function() internal returns (uint)[200] memory x;
x[0]();
return 2;
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("t()"), encodeArgs());
}
BOOST_AUTO_TEST_CASE(pass_function_types_internally)
{
char const* sourceCode = R"(
contract C {
function f(uint x) public returns (uint) {
return eval(g, x);
}
function eval(function(uint) internal returns (uint) x, uint a) internal returns (uint) {
return x(a);
}
function g(uint x) public returns (uint) { return x + 1; }
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("f(uint256)", 7), encodeArgs(u256(8)));
}
BOOST_AUTO_TEST_CASE(pass_function_types_externally)
{
char const* sourceCode = R"(
contract C {
function f(uint x) public returns (uint) {
return this.eval(this.g, x);
}
function f2(uint x) public returns (uint) {
return eval(this.g, x);
}
function eval(function(uint) external returns (uint) x, uint a) public returns (uint) {
return x(a);
}
function g(uint x) public returns (uint) { return x + 1; }
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("f(uint256)", 7), encodeArgs(u256(8)));
ABI_CHECK(callContractFunction("f2(uint256)", 7), encodeArgs(u256(8)));
}
BOOST_AUTO_TEST_CASE(receive_external_function_type)
{
char const* sourceCode = R"(
contract C {
function g() public returns (uint) { return 7; }
function f(function() external returns (uint) g) public returns (uint) {
return g();
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction(
"f(function)",
m_contractAddress.asBytes() + FixedHash<4>(dev::keccak256("g()")).asBytes() + bytes(32 - 4 - 20, 0)
), encodeArgs(u256(7)));
}
BOOST_AUTO_TEST_CASE(return_external_function_type)
{
char const* sourceCode = R"(
contract C {
function g() public {}
function f() public returns (function() external) {
return this.g;
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(
callContractFunction("f()"),
m_contractAddress.asBytes() + FixedHash<4>(dev::keccak256("g()")).asBytes() + bytes(32 - 4 - 20, 0)
);
}
BOOST_AUTO_TEST_CASE(store_function)
{
char const* sourceCode = R"(
contract Other {
function addTwo(uint x) public returns (uint) { return x + 2; }
}
contract C {
function (function (uint) external returns (uint)) internal returns (uint) ev;
function (uint) external returns (uint) x;
function store(function(uint) external returns (uint) y) public {
x = y;
}
function eval(function(uint) external returns (uint) y) public returns (uint) {
return y(7);
}
function t() public returns (uint) {
ev = eval;
this.store((new Other()).addTwo);
return ev(x);
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("t()"), encodeArgs(u256(9)));
}
BOOST_AUTO_TEST_CASE(store_function_in_constructor)
{
char const* sourceCode = R"(
contract C {
uint public result_in_constructor;
function (uint) internal returns (uint) x;
constructor() public {
x = double;
result_in_constructor = use(2);
}
function double(uint _arg) public returns (uint _ret) {
_ret = _arg * 2;
}
function use(uint _arg) public returns (uint) {
return x(_arg);
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("use(uint256)", encodeArgs(u256(3))), encodeArgs(u256(6)));
ABI_CHECK(callContractFunction("result_in_constructor()"), encodeArgs(u256(4)));
}
// TODO: store bound internal library functions
BOOST_AUTO_TEST_CASE(store_internal_unused_function_in_constructor)
{
char const* sourceCode = R"(
contract C {
function () internal returns (uint) x;
constructor() public {
x = unused;
}
function unused() internal returns (uint) {
return 7;
}
function t() public returns (uint) {
return x();
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("t()"), encodeArgs(u256(7)));
}
BOOST_AUTO_TEST_CASE(store_internal_unused_library_function_in_constructor)
{
char const* sourceCode = R"(
library L { function x() internal returns (uint) { return 7; } }
contract C {
function () internal returns (uint) x;
constructor() public {
x = L.x;
}
function t() public returns (uint) {
return x();
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("t()"), encodeArgs(u256(7)));
}
BOOST_AUTO_TEST_CASE(same_function_in_construction_and_runtime)
{
char const* sourceCode = R"(
contract C {
uint public initial;
constructor() public {
initial = double(2);
}
function double(uint _arg) public returns (uint _ret) {
_ret = _arg * 2;
}
function runtime(uint _arg) public returns (uint) {
return double(_arg);
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("runtime(uint256)", encodeArgs(u256(3))), encodeArgs(u256(6)));
ABI_CHECK(callContractFunction("initial()"), encodeArgs(u256(4)));
}
BOOST_AUTO_TEST_CASE(same_function_in_construction_and_runtime_equality_check)
{
char const* sourceCode = R"(
contract C {
function (uint) internal returns (uint) x;
constructor() public {
x = double;
}
function test() public returns (bool) {
return x == double;
}
function double(uint _arg) public returns (uint _ret) {
_ret = _arg * 2;
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("test()"), encodeArgs(true));
}
BOOST_AUTO_TEST_CASE(function_type_library_internal)
{
char const* sourceCode = R"(
library Utils {
function reduce(uint[] memory array, function(uint, uint) internal returns (uint) f, uint init) internal returns (uint) {
for (uint i = 0; i < array.length; i++) {
init = f(array[i], init);
}
return init;
}
function sum(uint a, uint b) internal returns (uint) {
return a + b;
}
}
contract C {
function f(uint[] memory x) public returns (uint) {
return Utils.reduce(x, Utils.sum, 0);
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("f(uint256[])", 0x20, 3, u256(1), u256(7), u256(3)), encodeArgs(u256(11)));
}
BOOST_AUTO_TEST_CASE(call_function_returning_function)
{
char const* sourceCode = R"(
contract test {
function f0() public returns (uint) {
return 2;
}
function f1() internal returns (function() internal returns (uint)) {
return f0;
}
function f2() internal returns (function() internal returns (function () internal returns (uint))) {
return f1;
}
function f3() internal returns (function() internal returns (function () internal returns (function () internal returns (uint))))
{
return f2;
}
function f() public returns (uint) {
function() internal returns(function() internal returns(function() internal returns(function() internal returns(uint)))) x;
x = f3;
return x()()()();
}
}
)";
compileAndRun(sourceCode, 0, "test");
ABI_CHECK(callContractFunction("f()"), encodeArgs(u256(2)));
}
BOOST_AUTO_TEST_CASE(mapping_of_functions)
{
char const* sourceCode = R"(
contract Flow {
bool public success;
mapping (address => function () internal) stages;
function stage0() internal {
stages[msg.sender] = stage1;
}
function stage1() internal {
stages[msg.sender] = stage2;
}
function stage2() internal {
success = true;
}
constructor() public {
stages[msg.sender] = stage0;
}
function f() public returns (uint) {
stages[msg.sender]();
return 7;
}
}
)";
compileAndRun(sourceCode, 0, "Flow");
ABI_CHECK(callContractFunction("success()"), encodeArgs(false));
ABI_CHECK(callContractFunction("f()"), encodeArgs(u256(7)));
ABI_CHECK(callContractFunction("f()"), encodeArgs(u256(7)));
ABI_CHECK(callContractFunction("success()"), encodeArgs(false));
ABI_CHECK(callContractFunction("f()"), encodeArgs(u256(7)));
ABI_CHECK(callContractFunction("success()"), encodeArgs(true));
}
BOOST_AUTO_TEST_CASE(packed_functions)
{
char const* sourceCode = R"(
contract C {
// these should take the same slot
function() internal returns (uint) a;
function() external returns (uint) b;
function() external returns (uint) c;
function() internal returns (uint) d;
uint8 public x;
function set() public {
x = 2;
d = g;
c = this.h;
b = this.h;
a = g;
}
function t1() public returns (uint) {
return a();
}
function t2() public returns (uint) {
return b();
}
function t3() public returns (uint) {
return a();
}
function t4() public returns (uint) {
return b();
}
function g() public returns (uint) {
return 7;
}
function h() public returns (uint) {
return 8;
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("set()"), encodeArgs());
ABI_CHECK(callContractFunction("t1()"), encodeArgs(u256(7)));
ABI_CHECK(callContractFunction("t2()"), encodeArgs(u256(8)));
ABI_CHECK(callContractFunction("t3()"), encodeArgs(u256(7)));
ABI_CHECK(callContractFunction("t4()"), encodeArgs(u256(8)));
ABI_CHECK(callContractFunction("x()"), encodeArgs(u256(2)));
}
BOOST_AUTO_TEST_CASE(function_memory_array)
{
char const* sourceCode = R"(
contract C {
function a(uint x) public returns (uint) { return x + 1; }
function b(uint x) public returns (uint) { return x + 2; }
function c(uint x) public returns (uint) { return x + 3; }
function d(uint x) public returns (uint) { return x + 5; }
function e(uint x) public returns (uint) { return x + 8; }
function test(uint x, uint i) public returns (uint) {
function(uint) internal returns (uint)[] memory arr =
new function(uint) internal returns (uint)[](10);
arr[0] = a;
arr[1] = b;
arr[2] = c;
arr[3] = d;
arr[4] = e;
return arr[i](x);
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("test(uint256,uint256)", u256(10), u256(0)), encodeArgs(u256(11)));
ABI_CHECK(callContractFunction("test(uint256,uint256)", u256(10), u256(1)), encodeArgs(u256(12)));
ABI_CHECK(callContractFunction("test(uint256,uint256)", u256(10), u256(2)), encodeArgs(u256(13)));
ABI_CHECK(callContractFunction("test(uint256,uint256)", u256(10), u256(3)), encodeArgs(u256(15)));
ABI_CHECK(callContractFunction("test(uint256,uint256)", u256(10), u256(4)), encodeArgs(u256(18)));
ABI_CHECK(callContractFunction("test(uint256,uint256)", u256(10), u256(5)), encodeArgs());
}
BOOST_AUTO_TEST_CASE(function_delete_storage)
{
char const* sourceCode = R"(
contract C {
function a() public returns (uint) { return 7; }
function() internal returns (uint) y;
function set() public returns (uint) {
y = a;
return y();
}
function d() public returns (uint) {
delete y;
return 1;
}
function ca() public returns (uint) {
return y();
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("set()"), encodeArgs(u256(7)));
ABI_CHECK(callContractFunction("ca()"), encodeArgs(u256(7)));
ABI_CHECK(callContractFunction("d()"), encodeArgs(u256(1)));
ABI_CHECK(callContractFunction("ca()"), encodeArgs());
}
BOOST_AUTO_TEST_CASE(function_delete_stack)
{
char const* sourceCode = R"(
contract C {
function a() public returns (uint) { return 7; }
function test() public returns (uint) {
function () returns (uint) y = a;
delete y;
y();
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("test()"), encodeArgs());
}
BOOST_AUTO_TEST_CASE(copy_function_storage_array)
{
char const* sourceCode = R"(
contract C {
function() internal returns (uint)[] x;
function() internal returns (uint)[] y;
function test() public returns (uint) {
x.length = 10;
x[9] = a;
y = x;
return y[9]();
}
function a() public returns (uint) {
return 7;
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("test()"), encodeArgs(u256(7)));
}
BOOST_AUTO_TEST_CASE(function_array_cross_calls)
{
char const* sourceCode = R"(
contract D {
function f(function() external returns (function() external returns (uint))[] memory x)
public returns (function() external returns (uint)[3] memory r)
{
r[0] = x[0]();
r[1] = x[1]();
r[2] = x[2]();
}
}
contract C {
function test() public returns (uint, uint, uint) {
function() external returns (function() external returns (uint))[] memory x =
new function() external returns (function() external returns (uint))[](10);
for (uint i = 0; i < x.length; i ++)
x[i] = this.h;
x[0] = this.htwo;
function() external returns (uint)[3] memory y = (new D()).f(x);
return (y[0](), y[1](), y[2]());
}
function e() public returns (uint) { return 5; }
function f() public returns (uint) { return 6; }
function g() public returns (uint) { return 7; }
uint counter;
function h() public returns (function() external returns (uint)) {
return counter++ == 0 ? this.f : this.g;
}
function htwo() public returns (function() external returns (uint)) {
return this.e;
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("test()"), encodeArgs(u256(5), u256(6), u256(7)));
}
BOOST_AUTO_TEST_CASE(external_function_to_address)
{
char const* sourceCode = R"(
contract C {
function f() public returns (bool) {
return address(this.f) == address(this);
}
function g(function() external cb) public returns (address) {
return address(cb);
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("f()"), encodeArgs(true));
ABI_CHECK(callContractFunction("g(function)", fromHex("00000000000000000000000000000000000004226121ff00000000000000000")), encodeArgs(u160(0x42)));
}
BOOST_AUTO_TEST_CASE(copy_internal_function_array_to_storage)
{
char const* sourceCode = R"(
contract C {
function() internal returns (uint)[20] x;
int mutex;
function one() public returns (uint) {
function() internal returns (uint)[20] memory xmem;
x = xmem;
return 3;
}
function two() public returns (uint) {
if (mutex > 0)
return 7;
mutex = 1;
// If this test fails, it might re-execute this function.
x[0]();
return 2;
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("one()"), encodeArgs(u256(3)));
ABI_CHECK(callContractFunction("two()"), encodeArgs());
}
BOOST_AUTO_TEST_CASE(shift_constant_left)
{
char const* sourceCode = R"(
contract C {
uint public a = 0x42 << 8;
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("a()"), encodeArgs(u256(0x4200)));
}
BOOST_AUTO_TEST_CASE(shift_negative_constant_left)
{
char const* sourceCode = R"(
contract C {
int public a = -0x42 << 8;
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("a()"), encodeArgs(u256(-0x4200)));
}
BOOST_AUTO_TEST_CASE(shift_constant_right)
{
char const* sourceCode = R"(
contract C {
uint public a = 0x4200 >> 8;
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("a()"), encodeArgs(u256(0x42)));
}
BOOST_AUTO_TEST_CASE(shift_negative_constant_right)
{
char const* sourceCode = R"(
contract C {
int public a = -0x4200 >> 8;
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("a()"), encodeArgs(u256(-0x42)));
}
BOOST_AUTO_TEST_CASE(shift_left)
{
char const* sourceCode = R"(
contract C {
function f(uint a, uint b) public returns (uint) {
return a << b;
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("f(uint256,uint256)", u256(0x4266), u256(0)), encodeArgs(u256(0x4266)));
ABI_CHECK(callContractFunction("f(uint256,uint256)", u256(0x4266), u256(8)), encodeArgs(u256(0x426600)));
ABI_CHECK(callContractFunction("f(uint256,uint256)", u256(0x4266), u256(16)), encodeArgs(u256(0x42660000)));
ABI_CHECK(callContractFunction("f(uint256,uint256)", u256(0x4266), u256(17)), encodeArgs(u256(0x84cc0000)));
ABI_CHECK(callContractFunction("f(uint256,uint256)", u256(0x4266), u256(240)), fromHex("4266000000000000000000000000000000000000000000000000000000000000"));
ABI_CHECK(callContractFunction("f(uint256,uint256)", u256(0x4266), u256(256)), encodeArgs(u256(0)));
}
BOOST_AUTO_TEST_CASE(shift_left_uint32)
{
char const* sourceCode = R"(
contract C {
function f(uint32 a, uint32 b) public returns (uint) {
return a << b;
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("f(uint32,uint32)", u256(0x4266), u256(0)), encodeArgs(u256(0x4266)));
ABI_CHECK(callContractFunction("f(uint32,uint32)", u256(0x4266), u256(8)), encodeArgs(u256(0x426600)));
ABI_CHECK(callContractFunction("f(uint32,uint32)", u256(0x4266), u256(16)), encodeArgs(u256(0x42660000)));
ABI_CHECK(callContractFunction("f(uint32,uint32)", u256(0x4266), u256(17)), encodeArgs(u256(0x84cc0000)));
ABI_CHECK(callContractFunction("f(uint32,uint32)", u256(0x4266), u256(32)), encodeArgs(u256(0)));
}
BOOST_AUTO_TEST_CASE(shift_left_uint8)
{
char const* sourceCode = R"(
contract C {
function f(uint8 a, uint8 b) public returns (uint) {
return a << b;
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("f(uint8,uint8)", u256(0x66), u256(0)), encodeArgs(u256(0x66)));
ABI_CHECK(callContractFunction("f(uint8,uint8)", u256(0x66), u256(8)), encodeArgs(u256(0)));
}
BOOST_AUTO_TEST_CASE(shift_left_larger_type)
{
// This basically tests proper cleanup and conversion. It should not convert x to int8.
char const* sourceCode = R"(
contract C {
function f() public returns (int8) {
uint8 x = 254;
int8 y = 1;
return y << x;
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("f()"), encodeArgs(u256(0)));
}
BOOST_AUTO_TEST_CASE(shift_left_assignment)
{
char const* sourceCode = R"(
contract C {
function f(uint a, uint b) public returns (uint) {
a <<= b;
return a;
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("f(uint256,uint256)", u256(0x4266), u256(0)), encodeArgs(u256(0x4266)));
ABI_CHECK(callContractFunction("f(uint256,uint256)", u256(0x4266), u256(8)), encodeArgs(u256(0x426600)));
ABI_CHECK(callContractFunction("f(uint256,uint256)", u256(0x4266), u256(16)), encodeArgs(u256(0x42660000)));
ABI_CHECK(callContractFunction("f(uint256,uint256)", u256(0x4266), u256(17)), encodeArgs(u256(0x84cc0000)));
ABI_CHECK(callContractFunction("f(uint256,uint256)", u256(0x4266), u256(240)), fromHex("4266000000000000000000000000000000000000000000000000000000000000"));
ABI_CHECK(callContractFunction("f(uint256,uint256)", u256(0x4266), u256(256)), encodeArgs(u256(0)));
}
BOOST_AUTO_TEST_CASE(shift_left_assignment_different_type)
{
char const* sourceCode = R"(
contract C {
function f(uint a, uint8 b) public returns (uint) {
a <<= b;
return a;
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("f(uint256,uint8)", u256(0x4266), u256(0)), encodeArgs(u256(0x4266)));
ABI_CHECK(callContractFunction("f(uint256,uint8)", u256(0x4266), u256(8)), encodeArgs(u256(0x426600)));
ABI_CHECK(callContractFunction("f(uint256,uint8)", u256(0x4266), u256(16)), encodeArgs(u256(0x42660000)));
ABI_CHECK(callContractFunction("f(uint256,uint8)", u256(0x4266), u256(17)), encodeArgs(u256(0x84cc0000)));
ABI_CHECK(callContractFunction("f(uint256,uint8)", u256(0x4266), u256(240)), fromHex("4266000000000000000000000000000000000000000000000000000000000000"));
}
BOOST_AUTO_TEST_CASE(shift_right)
{
char const* sourceCode = R"(
contract C {
function f(uint a, uint b) public returns (uint) {
return a >> b;
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("f(uint256,uint256)", u256(0x4266), u256(0)), encodeArgs(u256(0x4266)));
ABI_CHECK(callContractFunction("f(uint256,uint256)", u256(0x4266), u256(8)), encodeArgs(u256(0x42)));
ABI_CHECK(callContractFunction("f(uint256,uint256)", u256(0x4266), u256(16)), encodeArgs(u256(0)));
ABI_CHECK(callContractFunction("f(uint256,uint256)", u256(0x4266), u256(17)), encodeArgs(u256(0)));
ABI_CHECK(callContractFunction("f(uint256,uint256)", u256(1)<<255, u256(5)), encodeArgs(u256(1)<<250));
}
BOOST_AUTO_TEST_CASE(shift_right_garbled)
{
char const* sourceCode = R"(
contract C {
function f(uint8 a, uint8 b) public returns (uint) {
assembly {
a := 0xffffffff
}
// Higher bits should be cleared before the shift
return a >> b;
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("f(uint8,uint8)", u256(0x0), u256(4)), encodeArgs(u256(0xf)));
ABI_CHECK(callContractFunction("f(uint8,uint8)", u256(0x0), u256(0x1004)), encodeArgs(u256(0xf)));
}
BOOST_AUTO_TEST_CASE(shift_right_garbled_signed)
{
char const* sourceCode = R"(
contract C {
function f(int8 a, uint8 b) public returns (int) {
assembly {
a := 0xfffffff0
}
// Higher bits should be signextended before the shift
return a >> b;
}
function g(int8 a, uint8 b) public returns (int) {
assembly {
a := 0xf0
}
// Higher bits should be signextended before the shift
return a >> b;
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("f(int8,uint8)", u256(0x0), u256(3)), encodeArgs(u256(-2)));
ABI_CHECK(callContractFunction("f(int8,uint8)", u256(0x0), u256(4)), encodeArgs(u256(-1)));
ABI_CHECK(callContractFunction("f(int8,uint8)", u256(0x0), u256(0xFF)), encodeArgs(u256(-1)));
ABI_CHECK(callContractFunction("f(int8,uint8)", u256(0x0), u256(0x1003)), encodeArgs(u256(-2)));
ABI_CHECK(callContractFunction("f(int8,uint8)", u256(0x0), u256(0x1004)), encodeArgs(u256(-1)));
ABI_CHECK(callContractFunction("g(int8,uint8)", u256(0x0), u256(3)), encodeArgs(u256(-2)));
ABI_CHECK(callContractFunction("g(int8,uint8)", u256(0x0), u256(4)), encodeArgs(u256(-1)));
ABI_CHECK(callContractFunction("g(int8,uint8)", u256(0x0), u256(0xFF)), encodeArgs(u256(-1)));
ABI_CHECK(callContractFunction("g(int8,uint8)", u256(0x0), u256(0x1003)), encodeArgs(u256(-2)));
ABI_CHECK(callContractFunction("g(int8,uint8)", u256(0x0), u256(0x1004)), encodeArgs(u256(-1)));
}
BOOST_AUTO_TEST_CASE(shift_right_uint32)
{
char const* sourceCode = R"(
contract C {
function f(uint32 a, uint32 b) public returns (uint) {
return a >> b;
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("f(uint32,uint32)", u256(0x4266), u256(0)), encodeArgs(u256(0x4266)));
ABI_CHECK(callContractFunction("f(uint32,uint32)", u256(0x4266), u256(8)), encodeArgs(u256(0x42)));
ABI_CHECK(callContractFunction("f(uint32,uint32)", u256(0x4266), u256(16)), encodeArgs(u256(0)));
ABI_CHECK(callContractFunction("f(uint32,uint32)", u256(0x4266), u256(17)), encodeArgs(u256(0)));
}
BOOST_AUTO_TEST_CASE(shift_right_uint8)
{
char const* sourceCode = R"(
contract C {
function f(uint8 a, uint8 b) public returns (uint) {
return a >> b;
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("f(uint8,uint8)", u256(0x66), u256(0)), encodeArgs(u256(0x66)));
ABI_CHECK(callContractFunction("f(uint8,uint8)", u256(0x66), u256(8)), encodeArgs(u256(0x0)));
}
BOOST_AUTO_TEST_CASE(shift_right_assignment)
{
char const* sourceCode = R"(
contract C {
function f(uint a, uint b) public returns (uint) {
a >>= b;
return a;
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("f(uint256,uint256)", u256(0x4266), u256(0)), encodeArgs(u256(0x4266)));
ABI_CHECK(callContractFunction("f(uint256,uint256)", u256(0x4266), u256(8)), encodeArgs(u256(0x42)));
ABI_CHECK(callContractFunction("f(uint256,uint256)", u256(0x4266), u256(16)), encodeArgs(u256(0)));
ABI_CHECK(callContractFunction("f(uint256,uint256)", u256(0x4266), u256(17)), encodeArgs(u256(0)));
}
BOOST_AUTO_TEST_CASE(shift_right_assignment_signed)
{
char const* sourceCode = R"(
contract C {
function f(int a, int b) public returns (int) {
a >>= b;
return a;
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("f(int256,int256)", u256(0x4266), u256(0)), encodeArgs(u256(0x4266)));
ABI_CHECK(callContractFunction("f(int256,int256)", u256(0x4266), u256(8)), encodeArgs(u256(0x42)));
ABI_CHECK(callContractFunction("f(int256,int256)", u256(0x4266), u256(16)), encodeArgs(u256(0)));
ABI_CHECK(callContractFunction("f(int256,int256)", u256(0x4266), u256(17)), encodeArgs(u256(0)));
}
BOOST_AUTO_TEST_CASE(shift_right_negative_lvalue)
{
char const* sourceCode = R"(
contract C {
function f(int a, int b) public returns (int) {
return a >> b;
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("f(int256,int256)", u256(-4266), u256(0)), encodeArgs(u256(-4266)));
ABI_CHECK(callContractFunction("f(int256,int256)", u256(-4266), u256(1)), encodeArgs(u256(-2133)));
ABI_CHECK(callContractFunction("f(int256,int256)", u256(-4266), u256(4)), encodeArgs(u256(-267)));
ABI_CHECK(callContractFunction("f(int256,int256)", u256(-4266), u256(8)), encodeArgs(u256(-17)));
ABI_CHECK(callContractFunction("f(int256,int256)", u256(-4266), u256(16)), encodeArgs(u256(-1)));
ABI_CHECK(callContractFunction("f(int256,int256)", u256(-4266), u256(17)), encodeArgs(u256(-1)));
ABI_CHECK(callContractFunction("f(int256,int256)", u256(-4267), u256(0)), encodeArgs(u256(-4267)));
ABI_CHECK(callContractFunction("f(int256,int256)", u256(-4267), u256(1)), encodeArgs(u256(-2134)));
ABI_CHECK(callContractFunction("f(int256,int256)", u256(-4267), u256(4)), encodeArgs(u256(-267)));
ABI_CHECK(callContractFunction("f(int256,int256)", u256(-4267), u256(8)), encodeArgs(u256(-17)));
ABI_CHECK(callContractFunction("f(int256,int256)", u256(-4267), u256(16)), encodeArgs(u256(-1)));
ABI_CHECK(callContractFunction("f(int256,int256)", u256(-4267), u256(17)), encodeArgs(u256(-1)));
}
BOOST_AUTO_TEST_CASE(shift_right_negative_literal)
{
char const* sourceCode = R"(
contract C {
function f1() public pure returns (bool) {
return (-4266 >> 0) == -4266;
}
function f2() public pure returns (bool) {
return (-4266 >> 1) == -2133;
}
function f3() public pure returns (bool) {
return (-4266 >> 4) == -267;
}
function f4() public pure returns (bool) {
return (-4266 >> 8) == -17;
}
function f5() public pure returns (bool) {
return (-4266 >> 16) == -1;
}
function f6() public pure returns (bool) {
return (-4266 >> 17) == -1;
}
function g1() public pure returns (bool) {
return (-4267 >> 0) == -4267;
}
function g2() public pure returns (bool) {
return (-4267 >> 1) == -2134;
}
function g3() public pure returns (bool) {
return (-4267 >> 4) == -267;
}
function g4() public pure returns (bool) {
return (-4267 >> 8) == -17;
}
function g5() public pure returns (bool) {
return (-4267 >> 16) == -1;
}
function g6() public pure returns (bool) {
return (-4267 >> 17) == -1;
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("f1()"), encodeArgs(true));
ABI_CHECK(callContractFunction("f2()"), encodeArgs(true));
ABI_CHECK(callContractFunction("f3()"), encodeArgs(true));
ABI_CHECK(callContractFunction("f4()"), encodeArgs(true));
ABI_CHECK(callContractFunction("f5()"), encodeArgs(true));
ABI_CHECK(callContractFunction("f6()"), encodeArgs(true));
ABI_CHECK(callContractFunction("g1()"), encodeArgs(true));
ABI_CHECK(callContractFunction("g2()"), encodeArgs(true));
ABI_CHECK(callContractFunction("g3()"), encodeArgs(true));
ABI_CHECK(callContractFunction("g4()"), encodeArgs(true));
ABI_CHECK(callContractFunction("g5()"), encodeArgs(true));
ABI_CHECK(callContractFunction("g6()"), encodeArgs(true));
}
BOOST_AUTO_TEST_CASE(shift_right_negative_lvalue_int8)
{
char const* sourceCode = R"(
contract C {
function f(int8 a, int8 b) public returns (int) {
return a >> b;
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("f(int8,int8)", u256(-66), u256(0)), encodeArgs(u256(-66)));
ABI_CHECK(callContractFunction("f(int8,int8)", u256(-66), u256(1)), encodeArgs(u256(-33)));
ABI_CHECK(callContractFunction("f(int8,int8)", u256(-66), u256(4)), encodeArgs(u256(-5)));
ABI_CHECK(callContractFunction("f(int8,int8)", u256(-66), u256(8)), encodeArgs(u256(-1)));
ABI_CHECK(callContractFunction("f(int8,int8)", u256(-66), u256(16)), encodeArgs(u256(-1)));
ABI_CHECK(callContractFunction("f(int8,int8)", u256(-66), u256(17)), encodeArgs(u256(-1)));
ABI_CHECK(callContractFunction("f(int8,int8)", u256(-67), u256(0)), encodeArgs(u256(-67)));
ABI_CHECK(callContractFunction("f(int8,int8)", u256(-67), u256(1)), encodeArgs(u256(-34)));
ABI_CHECK(callContractFunction("f(int8,int8)", u256(-67), u256(4)), encodeArgs(u256(-5)));
ABI_CHECK(callContractFunction("f(int8,int8)", u256(-67), u256(8)), encodeArgs(u256(-1)));
ABI_CHECK(callContractFunction("f(int8,int8)", u256(-67), u256(16)), encodeArgs(u256(-1)));
ABI_CHECK(callContractFunction("f(int8,int8)", u256(-67), u256(17)), encodeArgs(u256(-1)));
}
BOOST_AUTO_TEST_CASE(shift_right_negative_lvalue_signextend_int8)
{
char const* sourceCode = R"(
contract C {
function f(int8 a, int8 b) public returns (int8) {
return a >> b;
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("f(int8,int8)", u256(0x99u), u256(0)), encodeArgs(u256(-103)));
ABI_CHECK(callContractFunction("f(int8,int8)", u256(0x99u), u256(1)), encodeArgs(u256(-52)));
ABI_CHECK(callContractFunction("f(int8,int8)", u256(0x99u), u256(2)), encodeArgs(u256(-26)));
ABI_CHECK(callContractFunction("f(int8,int8)", u256(0x99u), u256(4)), encodeArgs(u256(-7)));
ABI_CHECK(callContractFunction("f(int8,int8)", u256(0x99u), u256(8)), encodeArgs(u256(-1)));
}
BOOST_AUTO_TEST_CASE(shift_right_negative_lvalue_signextend_int16)
{
char const* sourceCode = R"(
contract C {
function f(int16 a, int16 b) public returns (int16) {
return a >> b;
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("f(int16,int16)", u256(0xFF99u), u256(0)), encodeArgs(u256(-103)));
ABI_CHECK(callContractFunction("f(int16,int16)", u256(0xFF99u), u256(1)), encodeArgs(u256(-52)));
ABI_CHECK(callContractFunction("f(int16,int16)", u256(0xFF99u), u256(2)), encodeArgs(u256(-26)));
ABI_CHECK(callContractFunction("f(int16,int16)", u256(0xFF99u), u256(4)), encodeArgs(u256(-7)));
ABI_CHECK(callContractFunction("f(int16,int16)", u256(0xFF99u), u256(8)), encodeArgs(u256(-1)));
}
BOOST_AUTO_TEST_CASE(shift_right_negative_lvalue_signextend_int32)
{
char const* sourceCode = R"(
contract C {
function f(int32 a, int32 b) public returns (int32) {
return a >> b;
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("f(int32,int32)", u256(0xFFFFFF99u), u256(0)), encodeArgs(u256(-103)));
ABI_CHECK(callContractFunction("f(int32,int32)", u256(0xFFFFFF99u), u256(1)), encodeArgs(u256(-52)));
ABI_CHECK(callContractFunction("f(int32,int32)", u256(0xFFFFFF99u), u256(2)), encodeArgs(u256(-26)));
ABI_CHECK(callContractFunction("f(int32,int32)", u256(0xFFFFFF99u), u256(4)), encodeArgs(u256(-7)));
ABI_CHECK(callContractFunction("f(int32,int32)", u256(0xFFFFFF99u), u256(8)), encodeArgs(u256(-1)));
}
BOOST_AUTO_TEST_CASE(shift_right_negative_lvalue_int16)
{
char const* sourceCode = R"(
contract C {
function f(int16 a, int16 b) public returns (int) {
return a >> b;
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("f(int16,int16)", u256(-4266), u256(0)), encodeArgs(u256(-4266)));
ABI_CHECK(callContractFunction("f(int16,int16)", u256(-4266), u256(1)), encodeArgs(u256(-2133)));
ABI_CHECK(callContractFunction("f(int16,int16)", u256(-4266), u256(4)), encodeArgs(u256(-267)));
ABI_CHECK(callContractFunction("f(int16,int16)", u256(-4266), u256(8)), encodeArgs(u256(-17)));
ABI_CHECK(callContractFunction("f(int16,int16)", u256(-4266), u256(16)), encodeArgs(u256(-1)));
ABI_CHECK(callContractFunction("f(int16,int16)", u256(-4266), u256(17)), encodeArgs(u256(-1)));
ABI_CHECK(callContractFunction("f(int16,int16)", u256(-4267), u256(0)), encodeArgs(u256(-4267)));
ABI_CHECK(callContractFunction("f(int16,int16)", u256(-4267), u256(1)), encodeArgs(u256(-2134)));
ABI_CHECK(callContractFunction("f(int16,int16)", u256(-4267), u256(4)), encodeArgs(u256(-267)));
ABI_CHECK(callContractFunction("f(int16,int16)", u256(-4267), u256(8)), encodeArgs(u256(-17)));
ABI_CHECK(callContractFunction("f(int16,int16)", u256(-4267), u256(16)), encodeArgs(u256(-1)));
ABI_CHECK(callContractFunction("f(int16,int16)", u256(-4267), u256(17)), encodeArgs(u256(-1)));
}
BOOST_AUTO_TEST_CASE(shift_right_negative_lvalue_int32)
{
char const* sourceCode = R"(
contract C {
function f(int32 a, int32 b) public returns (int) {
return a >> b;
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("f(int32,int32)", u256(-4266), u256(0)), encodeArgs(u256(-4266)));
ABI_CHECK(callContractFunction("f(int32,int32)", u256(-4266), u256(1)), encodeArgs(u256(-2133)));
ABI_CHECK(callContractFunction("f(int32,int32)", u256(-4266), u256(4)), encodeArgs(u256(-267)));
ABI_CHECK(callContractFunction("f(int32,int32)", u256(-4266), u256(8)), encodeArgs(u256(-17)));
ABI_CHECK(callContractFunction("f(int32,int32)", u256(-4266), u256(16)), encodeArgs(u256(-1)));
ABI_CHECK(callContractFunction("f(int32,int32)", u256(-4266), u256(17)), encodeArgs(u256(-1)));
ABI_CHECK(callContractFunction("f(int32,int32)", u256(-4267), u256(0)), encodeArgs(u256(-4267)));
ABI_CHECK(callContractFunction("f(int32,int32)", u256(-4267), u256(1)), encodeArgs(u256(-2134)));
ABI_CHECK(callContractFunction("f(int32,int32)", u256(-4267), u256(4)), encodeArgs(u256(-267)));
ABI_CHECK(callContractFunction("f(int32,int32)", u256(-4267), u256(8)), encodeArgs(u256(-17)));
ABI_CHECK(callContractFunction("f(int32,int32)", u256(-4267), u256(16)), encodeArgs(u256(-1)));
ABI_CHECK(callContractFunction("f(int32,int32)", u256(-4267), u256(17)), encodeArgs(u256(-1)));
}
BOOST_AUTO_TEST_CASE(shift_right_negative_lvalue_assignment)
{
char const* sourceCode = R"(
contract C {
function f(int a, int b) public returns (int) {
a >>= b;
return a;
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("f(int256,int256)", u256(-4266), u256(0)), encodeArgs(u256(-4266)));
ABI_CHECK(callContractFunction("f(int256,int256)", u256(-4266), u256(1)), encodeArgs(u256(-2133)));
ABI_CHECK(callContractFunction("f(int256,int256)", u256(-4266), u256(4)), encodeArgs(u256(-267)));
ABI_CHECK(callContractFunction("f(int256,int256)", u256(-4266), u256(8)), encodeArgs(u256(-17)));
ABI_CHECK(callContractFunction("f(int256,int256)", u256(-4266), u256(16)), encodeArgs(u256(-1)));
ABI_CHECK(callContractFunction("f(int256,int256)", u256(-4266), u256(17)), encodeArgs(u256(-1)));
ABI_CHECK(callContractFunction("f(int256,int256)", u256(-4267), u256(0)), encodeArgs(u256(-4267)));
ABI_CHECK(callContractFunction("f(int256,int256)", u256(-4267), u256(1)), encodeArgs(u256(-2134)));
ABI_CHECK(callContractFunction("f(int256,int256)", u256(-4267), u256(4)), encodeArgs(u256(-267)));
ABI_CHECK(callContractFunction("f(int256,int256)", u256(-4267), u256(8)), encodeArgs(u256(-17)));
ABI_CHECK(callContractFunction("f(int256,int256)", u256(-4267), u256(16)), encodeArgs(u256(-1)));
ABI_CHECK(callContractFunction("f(int256,int256)", u256(-4267), u256(17)), encodeArgs(u256(-1)));
}
BOOST_AUTO_TEST_CASE(shift_negative_rvalue)
{
char const* sourceCode = R"(
contract C {
function f(int a, int b) public returns (int) {
return a << b;
}
function g(int a, int b) public returns (int) {
return a >> b;
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("f(int256,int256)", u256(1), u256(-1)), encodeArgs());
ABI_CHECK(callContractFunction("g(int256,int256)", u256(1), u256(-1)), encodeArgs());
}
BOOST_AUTO_TEST_CASE(shift_negative_rvalue_assignment)
{
char const* sourceCode = R"(
contract C {
function f(int a, int b) public returns (int) {
a <<= b;
return a;
}
function g(int a, int b) public returns (int) {
a >>= b;
return a;
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("f(int256,int256)", u256(1), u256(-1)), encodeArgs());
ABI_CHECK(callContractFunction("g(int256,int256)", u256(1), u256(-1)), encodeArgs());
}
BOOST_AUTO_TEST_CASE(shift_constant_left_assignment)
{
char const* sourceCode = R"(
contract C {
function f() public returns (uint a) {
a = 0x42;
a <<= 8;
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("f()"), encodeArgs(u256(0x4200)));
}
BOOST_AUTO_TEST_CASE(shift_constant_right_assignment)
{
char const* sourceCode = R"(
contract C {
function f() public returns (uint a) {
a = 0x4200;
a >>= 8;
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("f()"), encodeArgs(u256(0x42)));
}
BOOST_AUTO_TEST_CASE(shift_cleanup)
{
char const* sourceCode = R"(
contract C {
function f() public returns (uint16 x) {
x = 0xffff;
x += 32;
x <<= 8;
x >>= 16;
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("f()"), encodeArgs(u256(0x0)));
}
BOOST_AUTO_TEST_CASE(shift_cleanup_garbled)
{
char const* sourceCode = R"(
contract C {
function f() public returns (uint8 x) {
assembly {
x := 0xffff
}
x >>= 8;
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("f()"), encodeArgs(u256(0x0)));
}
BOOST_AUTO_TEST_CASE(shift_overflow)
{
char const* sourceCode = R"(
contract C {
function leftU(uint8 x, uint8 y) public returns (uint8) {
return x << y;
}
function leftS(int8 x, int8 y) public returns (int8) {
return x << y;
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("leftU(uint8,uint8)", 255, 8), encodeArgs(u256(0)));
ABI_CHECK(callContractFunction("leftU(uint8,uint8)", 255, 1), encodeArgs(u256(254)));
ABI_CHECK(callContractFunction("leftU(uint8,uint8)", 255, 0), encodeArgs(u256(255)));
// Result is -128 and output is sign-extended, not zero-padded.
ABI_CHECK(callContractFunction("leftS(int8,int8)", 1, 7), encodeArgs(u256(0) - 128));
ABI_CHECK(callContractFunction("leftS(int8,int8)", 1, 6), encodeArgs(u256(64)));
}
BOOST_AUTO_TEST_CASE(shift_bytes)
{
char const* sourceCode = R"(
contract C {
function left(bytes20 x, uint8 y) public returns (bytes20) {
return x << y;
}
function right(bytes20 x, uint8 y) public returns (bytes20) {
return x >> y;
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("left(bytes20,uint8)", "12345678901234567890", 8 * 8), encodeArgs("901234567890" + string(8, 0)));
ABI_CHECK(callContractFunction("right(bytes20,uint8)", "12345678901234567890", 8 * 8), encodeArgs(string(8, 0) + "123456789012"));
}
BOOST_AUTO_TEST_CASE(shift_bytes_cleanup)
{
char const* sourceCode = R"(
contract C {
function left(uint8 y) public returns (bytes20) {
bytes20 x;
assembly { x := "12345678901234567890abcde" }
return x << y;
}
function right(uint8 y) public returns (bytes20) {
bytes20 x;
assembly { x := "12345678901234567890abcde" }
return x >> y;
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("left(uint8)", 8 * 8), encodeArgs("901234567890" + string(8, 0)));
ABI_CHECK(callContractFunction("right(uint8)", 8 * 8), encodeArgs(string(8, 0) + "123456789012"));
}
BOOST_AUTO_TEST_CASE(exp_cleanup)
{
char const* sourceCode = R"(
contract C {
function f() public pure returns (uint8 x) {
uint8 y = uint8(2) ** uint8(8);
return 0 ** y;
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("f()"), encodeArgs(u256(0x1)));
}
BOOST_AUTO_TEST_CASE(exp_cleanup_direct)
{
char const* sourceCode = R"(
contract C {
function f() public pure returns (uint8 x) {
return uint8(0) ** uint8(uint8(2) ** uint8(8));
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("f()"), encodeArgs(u256(0x1)));
}
BOOST_AUTO_TEST_CASE(exp_cleanup_nonzero_base)
{
char const* sourceCode = R"(
contract C {
function f() public pure returns (uint8 x) {
return uint8(0x166) ** uint8(uint8(2) ** uint8(8));
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("f()"), encodeArgs(u256(0x1)));
}
BOOST_AUTO_TEST_CASE(cleanup_in_compound_assign)
{
char const* sourceCode = R"(
contract C {
function test() public returns (uint, uint) {
uint32 a = 0xffffffff;
uint16 x = uint16(a);
uint16 y = x;
x /= 0x100;
y = y / 0x100;
return (x, y);
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("test()"), encodeArgs(u256(0xff), u256(0xff)));
}
BOOST_AUTO_TEST_CASE(inline_assembly_in_modifiers)
{
char const* sourceCode = R"(
contract C {
modifier m {
uint a = 1;
assembly {
a := 2
}
if (a != 2)
revert();
_;
}
function f() m public returns (bool) {
return true;
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("f()"), encodeArgs(true));
}
BOOST_AUTO_TEST_CASE(packed_storage_overflow)
{
char const* sourceCode = R"(
contract C {
uint16 x = 0x1234;
uint16 a = 0xffff;
uint16 b;
function f() public returns (uint, uint, uint, uint) {
a++;
uint c = b;
delete b;
a -= 2;
return (x, c, b, a);
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("f()"), encodeArgs(u256(0x1234), u256(0), u256(0), u256(0xfffe)));
}
BOOST_AUTO_TEST_CASE(contracts_separated_with_comment)
{
char const* sourceCode = R"(
contract C1 {}
/**
**/
contract C2 {}
)";
compileAndRun(sourceCode, 0, "C1");
compileAndRun(sourceCode, 0, "C2");
}
BOOST_AUTO_TEST_CASE(include_creation_bytecode_only_once)
{
char const* sourceCode = R"(
contract D {
bytes a = hex"1237651237125387136581271652831736512837126583171583712358126123765123712538713658127165283173651283712658317158371235812612376512371253871365812716528317365128371265831715837123581261237651237125387136581271652831736512837126583171583712358126";
bytes b = hex"1237651237125327136581271252831736512837126583171383712358126123765125712538713658127165253173651283712658357158371235812612376512371a5387136581271652a317365128371265a317158371235812612a765123712538a13658127165a83173651283712a58317158371235a126";
constructor(uint) public {}
}
contract Double {
function f() public {
new D(2);
}
function g() public {
new D(3);
}
}
contract Single {
function f() public {
new D(2);
}
}
)";
compileAndRun(sourceCode);
BOOST_CHECK_LE(
double(m_compiler.object("Double").bytecode.size()),
1.2 * double(m_compiler.object("Single").bytecode.size())
);
}
BOOST_AUTO_TEST_CASE(recursive_structs)
{
char const* sourceCode = R"(
contract C {
struct S {
S[] x;
}
S sstorage;
function f() public returns (uint) {
S memory s;
s.x = new S[](10);
delete s;
sstorage.x.length++;
delete sstorage;
return 1;
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("f()"), encodeArgs(u256(1)));
}
BOOST_AUTO_TEST_CASE(invalid_instruction)
{
char const* sourceCode = R"(
contract C {
function f() public {
assembly {
invalid()
}
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("f()"), encodeArgs());
}
BOOST_AUTO_TEST_CASE(assert_require)
{
char const* sourceCode = R"(
contract C {
function f() public {
assert(false);
}
function g(bool val) public returns (bool) {
assert(val == true);
return true;
}
function h(bool val) public returns (bool) {
require(val);
return true;
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("f()"), encodeArgs());
ABI_CHECK(callContractFunction("g(bool)", false), encodeArgs());
ABI_CHECK(callContractFunction("g(bool)", true), encodeArgs(true));
ABI_CHECK(callContractFunction("h(bool)", false), encodeArgs());
ABI_CHECK(callContractFunction("h(bool)", true), encodeArgs(true));
}
BOOST_AUTO_TEST_CASE(revert)
{
char const* sourceCode = R"(
contract C {
uint public a = 42;
function f() public {
a = 1;
revert();
}
function g() public {
a = 1;
assembly {
revert(0, 0)
}
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("f()"), encodeArgs());
ABI_CHECK(callContractFunction("a()"), encodeArgs(u256(42)));
ABI_CHECK(callContractFunction("g()"), encodeArgs());
ABI_CHECK(callContractFunction("a()"), encodeArgs(u256(42)));
}
BOOST_AUTO_TEST_CASE(revert_with_cause)
{
char const* sourceCode = R"(
contract D {
string constant msg1 = "test1234567890123456789012345678901234567890";
string msg2 = "test1234567890123456789012345678901234567890";
function f() public {
revert("test123");
}
function g() public {
revert("test1234567890123456789012345678901234567890");
}
function h() public {
revert(msg1);
}
function i() public {
revert(msg2);
}
function j() public {
string memory msg3 = "test1234567890123456789012345678901234567890";
revert(msg3);
}
}
contract C {
D d = new D();
function forward(address target, bytes memory data) internal returns (bool success, bytes memory retval) {
uint retsize;
assembly {
success := call(not(0), target, 0, add(data, 0x20), mload(data), 0, 0)
retsize := returndatasize()
}
retval = new bytes(retsize);
assembly {
returndatacopy(add(retval, 0x20), 0, returndatasize())
}
}
function f() public returns (bool, bytes memory) {
return forward(address(d), msg.data);
}
function g() public returns (bool, bytes memory) {
return forward(address(d), msg.data);
}
function h() public returns (bool, bytes memory) {
return forward(address(d), msg.data);
}
function i() public returns (bool, bytes memory) {
return forward(address(d), msg.data);
}
function j() public returns (bool, bytes memory) {
return forward(address(d), msg.data);
}
}
)";
if (dev::test::Options::get().evmVersion().supportsReturndata())
{
compileAndRun(sourceCode, 0, "C");
bytes const errorSignature = bytes{0x08, 0xc3, 0x79, 0xa0};
ABI_CHECK(callContractFunction("f()"), encodeArgs(0, 0x40, 0x64) + errorSignature + encodeArgs(0x20, 7, "test123") + bytes(28, 0));
ABI_CHECK(callContractFunction("g()"), encodeArgs(0, 0x40, 0x84) + errorSignature + encodeArgs(0x20, 44, "test1234567890123456789012345678901234567890") + bytes(28, 0));
ABI_CHECK(callContractFunction("h()"), encodeArgs(0, 0x40, 0x84) + errorSignature + encodeArgs(0x20, 44, "test1234567890123456789012345678901234567890") + bytes(28, 0));
ABI_CHECK(callContractFunction("i()"), encodeArgs(0, 0x40, 0x84) + errorSignature + encodeArgs(0x20, 44, "test1234567890123456789012345678901234567890") + bytes(28, 0));
ABI_CHECK(callContractFunction("j()"), encodeArgs(0, 0x40, 0x84) + errorSignature + encodeArgs(0x20, 44, "test1234567890123456789012345678901234567890") + bytes(28, 0));
}
}
BOOST_AUTO_TEST_CASE(require_with_message)
{
char const* sourceCode = R"(
contract D {
bool flag = false;
string storageError = "abc";
string constant constantError = "abc";
function f(uint x) public {
require(x > 7, "failed");
}
function g() public {
// As a side-effect of internalFun, the flag will be set to true
// (even if the condition is true),
// but it will only throw in the next evaluation.
bool flagCopy = flag;
require(flagCopy == false, internalFun());
}
function internalFun() public returns (string memory) {
flag = true;
return "only on second run";
}
function h() public {
require(false, storageError);
}
function i() public {
require(false, constantError);
}
function j() public {
string memory errMsg = "msg";
require(false, errMsg);
}
}
contract C {
D d = new D();
function forward(address target, bytes memory data) internal returns (bool success, bytes memory retval) {
uint retsize;
assembly {
success := call(not(0), target, 0, add(data, 0x20), mload(data), 0, 0)
retsize := returndatasize()
}
retval = new bytes(retsize);
assembly {
returndatacopy(add(retval, 0x20), 0, returndatasize())
}
}
function f(uint x) public returns (bool, bytes memory) {
return forward(address(d), msg.data);
}
function g() public returns (bool, bytes memory) {
return forward(address(d), msg.data);
}
function h() public returns (bool, bytes memory) {
return forward(address(d), msg.data);
}
function i() public returns (bool, bytes memory) {
return forward(address(d), msg.data);
}
function j() public returns (bool, bytes memory) {
return forward(address(d), msg.data);
}
}
)";
if (dev::test::Options::get().evmVersion().supportsReturndata())
{
compileAndRun(sourceCode, 0, "C");
bytes const errorSignature = bytes{0x08, 0xc3, 0x79, 0xa0};
ABI_CHECK(callContractFunction("f(uint256)", 8), encodeArgs(1, 0x40, 0));
ABI_CHECK(callContractFunction("f(uint256)", 5), encodeArgs(0, 0x40, 0x64) + errorSignature + encodeArgs(0x20, 6, "failed") + bytes(28, 0));
ABI_CHECK(callContractFunction("g()"), encodeArgs(1, 0x40, 0));
ABI_CHECK(callContractFunction("g()"), encodeArgs(0, 0x40, 0x64) + errorSignature + encodeArgs(0x20, 18, "only on second run") + bytes(28, 0));
ABI_CHECK(callContractFunction("h()"), encodeArgs(0, 0x40, 0x64) + errorSignature + encodeArgs(0x20, 3, "abc") + bytes(28, 0));
ABI_CHECK(callContractFunction("i()"), encodeArgs(0, 0x40, 0x64) + errorSignature + encodeArgs(0x20, 3, "abc") + bytes(28, 0));
ABI_CHECK(callContractFunction("j()"), encodeArgs(0, 0x40, 0x64) + errorSignature + encodeArgs(0x20, 3, "msg") + bytes(28, 0));
}
}
BOOST_AUTO_TEST_CASE(bubble_up_error_messages)
{
char const* sourceCode = R"(
contract D {
function f() public {
revert("message");
}
function g() public {
this.f();
}
}
contract C {
D d = new D();
function forward(address target, bytes memory data) internal returns (bool success, bytes memory retval) {
uint retsize;
assembly {
success := call(not(0), target, 0, add(data, 0x20), mload(data), 0, 0)
retsize := returndatasize()
}
retval = new bytes(retsize);
assembly {
returndatacopy(add(retval, 0x20), 0, returndatasize())
}
}
function f() public returns (bool, bytes memory) {
return forward(address(d), msg.data);
}
function g() public returns (bool, bytes memory) {
return forward(address(d), msg.data);
}
}
)";
if (dev::test::Options::get().evmVersion().supportsReturndata())
{
compileAndRun(sourceCode, 0, "C");
bytes const errorSignature = bytes{0x08, 0xc3, 0x79, 0xa0};
ABI_CHECK(callContractFunction("f()"), encodeArgs(0, 0x40, 0x64) + errorSignature + encodeArgs(0x20, 7, "message") + bytes(28, 0));
ABI_CHECK(callContractFunction("g()"), encodeArgs(0, 0x40, 0x64) + errorSignature + encodeArgs(0x20, 7, "message") + bytes(28, 0));
}
}
BOOST_AUTO_TEST_CASE(bubble_up_error_messages_through_transfer)
{
char const* sourceCode = R"(
contract D {
function() external payable {
revert("message");
}
function f() public {
address(this).transfer(0);
}
}
contract C {
D d = new D();
function forward(address target, bytes memory data) internal returns (bool success, bytes memory retval) {
uint retsize;
assembly {
success := call(not(0), target, 0, add(data, 0x20), mload(data), 0, 0)
retsize := returndatasize()
}
retval = new bytes(retsize);
assembly {
returndatacopy(add(retval, 0x20), 0, returndatasize())
}
}
function f() public returns (bool, bytes memory) {
return forward(address(d), msg.data);
}
}
)";
if (dev::test::Options::get().evmVersion().supportsReturndata())
{
compileAndRun(sourceCode, 0, "C");
bytes const errorSignature = bytes{0x08, 0xc3, 0x79, 0xa0};
ABI_CHECK(callContractFunction("f()"), encodeArgs(0, 0x40, 0x64) + errorSignature + encodeArgs(0x20, 7, "message") + bytes(28, 0));
}
}
BOOST_AUTO_TEST_CASE(bubble_up_error_messages_through_create)
{
char const* sourceCode = R"(
contract E {
constructor() public {
revert("message");
}
}
contract D {
function f() public {
E x = new E();
}
}
contract C {
D d = new D();
function forward(address target, bytes memory data) internal returns (bool success, bytes memory retval) {
uint retsize;
assembly {
success := call(not(0), target, 0, add(data, 0x20), mload(data), 0, 0)
retsize := returndatasize()
}
retval = new bytes(retsize);
assembly {
returndatacopy(add(retval, 0x20), 0, returndatasize())
}
}
function f() public returns (bool, bytes memory) {
return forward(address(d), msg.data);
}
}
)";
if (dev::test::Options::get().evmVersion().supportsReturndata())
{
compileAndRun(sourceCode, 0, "C");
bytes const errorSignature = bytes{0x08, 0xc3, 0x79, 0xa0};
ABI_CHECK(callContractFunction("f()"), encodeArgs(0, 0x40, 0x64) + errorSignature + encodeArgs(0x20, 7, "message") + bytes(28, 0));
}
}
BOOST_AUTO_TEST_CASE(negative_stack_height)
{
// This code was causing negative stack height during code generation
// because the stack height was not adjusted at the beginning of functions.
char const* sourceCode = R"(
contract C {
mapping(uint => Invoice) public invoices;
struct Invoice {
uint AID;
bool Aboola;
bool Aboolc;
bool exists;
}
function nredit(uint startindex) public pure returns(uint[500] memory CIDs, uint[500] memory dates, uint[500] memory RIDs, bool[500] memory Cboolas, uint[500] memory amounts){}
function return500InvoicesByDates(uint begindate, uint enddate, uint startindex) public view returns(uint[500] memory AIDs, bool[500] memory Aboolas, uint[500] memory dates, bytes32[3][500] memory Abytesas, bytes32[3][500] memory bytesbs, bytes32[2][500] memory bytescs, uint[500] memory amounts, bool[500] memory Aboolbs, bool[500] memory Aboolcs){}
function return500PaymentsByDates(uint begindate, uint enddate, uint startindex) public view returns(uint[500] memory BIDs, uint[500] memory dates, uint[500] memory RIDs, bool[500] memory Bboolas, bytes32[3][500] memory bytesbs,bytes32[2][500] memory bytescs, uint[500] memory amounts, bool[500] memory Bboolbs){}
}
)";
compileAndRun(sourceCode, 0, "C");
}
BOOST_AUTO_TEST_CASE(literal_empty_string)
{
char const* sourceCode = R"(
contract C {
bytes32 public x;
uint public a;
function f(bytes32 _x, uint _a) public {
x = _x;
a = _a;
}
function g() public {
this.f("", 2);
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("x()"), encodeArgs(u256(0)));
ABI_CHECK(callContractFunction("a()"), encodeArgs(u256(0)));
ABI_CHECK(callContractFunction("g()"), encodeArgs());
ABI_CHECK(callContractFunction("x()"), encodeArgs(u256(0)));
ABI_CHECK(callContractFunction("a()"), encodeArgs(u256(2)));
}
BOOST_AUTO_TEST_CASE(scientific_notation)
{
char const* sourceCode = R"(
contract C {
function f() public returns (uint) {
return 2e10 wei;
}
function g() public returns (uint) {
return 200e-2 wei;
}
function h() public returns (uint) {
return 2.5e1;
}
function i() public returns (int) {
return -2e10;
}
function j() public returns (int) {
return -200e-2;
}
function k() public returns (int) {
return -2.5e1;
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("f()"), encodeArgs(u256(20000000000)));
ABI_CHECK(callContractFunction("g()"), encodeArgs(u256(2)));
ABI_CHECK(callContractFunction("h()"), encodeArgs(u256(25)));
ABI_CHECK(callContractFunction("i()"), encodeArgs(u256(-20000000000)));
ABI_CHECK(callContractFunction("j()"), encodeArgs(u256(-2)));
ABI_CHECK(callContractFunction("k()"), encodeArgs(u256(-25)));
}
BOOST_AUTO_TEST_CASE(interface_contract)
{
char const* sourceCode = R"(
interface I {
event A();
function f() external returns (bool);
function() external payable;
}
contract A is I {
function f() public returns (bool) {
return g();
}
function g() public returns (bool) {
return true;
}
function() external payable {
}
}
contract C {
function f(address payable _interfaceAddress) public returns (bool) {
I i = I(_interfaceAddress);
return i.f();
}
}
)";
compileAndRun(sourceCode, 0, "A");
u160 const recipient = m_contractAddress;
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("f(address)", recipient), encodeArgs(true));
}
BOOST_AUTO_TEST_CASE(keccak256_assembly)
{
char const* sourceCode = R"(
contract C {
function f() public pure returns (bytes32 ret) {
assembly {
ret := keccak256(0, 0)
}
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("f()"), fromHex("0xc5d2460186f7233c927e7db2dcc703c0e500b653ca82273b7bfad8045d85a470"));
}
BOOST_AUTO_TEST_CASE(multi_modifiers)
{
// This triggered a bug in some version because the variable in the modifier was not
// unregistered correctly.
char const* sourceCode = R"(
contract C {
uint public x;
modifier m1 {
address a1 = msg.sender;
x++;
_;
}
function f1() m1() public {
x += 7;
}
function f2() m1() public {
x += 3;
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("f1()"), bytes());
ABI_CHECK(callContractFunction("x()"), encodeArgs(u256(8)));
ABI_CHECK(callContractFunction("f2()"), bytes());
ABI_CHECK(callContractFunction("x()"), encodeArgs(u256(12)));
}
BOOST_AUTO_TEST_CASE(inlineasm_empty_let)
{
char const* sourceCode = R"(
contract C {
function f() public pure returns (uint a, uint b) {
assembly {
let x
let y, z
a := x
b := z
}
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("f()"), encodeArgs(u256(0), u256(0)));
}
BOOST_AUTO_TEST_CASE(bare_call_invalid_address)
{
char const* sourceCode = R"YY(
contract C {
/// Calling into non-existant account is successful (creates the account)
function f() external returns (bool) {
(bool success,) = address(0x4242).call("");
return success;
}
function h() external returns (bool) {
(bool success,) = address(0x4242).delegatecall("");
return success;
}
}
)YY";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("f()"), encodeArgs(u256(1)));
ABI_CHECK(callContractFunction("h()"), encodeArgs(u256(1)));
if (dev::test::Options::get().evmVersion().hasStaticCall())
{
char const* sourceCode = R"YY(
contract C {
function f() external returns (bool, bytes memory) {
return address(0x4242).staticcall("");
}
}
)YY";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("f()"), encodeArgs(u256(1), 0x40, 0x00));
}
}
BOOST_AUTO_TEST_CASE(bare_call_return_data)
{
if (dev::test::Options::get().evmVersion().supportsReturndata())
{
vector<string> calltypes = {"call", "delegatecall"};
if (dev::test::Options::get().evmVersion().hasStaticCall())
calltypes.emplace_back("staticcall");
for (string const& calltype: calltypes)
{
string sourceCode = R"DELIMITER(
contract A {
constructor() public {
}
function return_bool() public pure returns(bool) {
return true;
}
function return_int32() public pure returns(int32) {
return -32;
}
function return_uint32() public pure returns(uint32) {
return 0x3232;
}
function return_int256() public pure returns(int256) {
return -256;
}
function return_uint256() public pure returns(uint256) {
return 0x256256;
}
function return_bytes4() public pure returns(bytes4) {
return 0xabcd0012;
}
function return_multi() public pure returns(bool, uint32, bytes4) {
return (false, 0x3232, 0xabcd0012);
}
function return_bytes() public pure returns(bytes memory b) {
b = new bytes(2);
b[0] = 0x42;
b[1] = 0x21;
}
}
contract C {
A addr;
constructor() public {
addr = new A();
}
function f(string memory signature) public returns (bool, bytes memory) {
return address(addr).)DELIMITER" + calltype + R"DELIMITER((abi.encodeWithSignature(signature));
}
function check_bool() external returns (bool) {
(bool success, bytes memory data) = f("return_bool()");
assert(success);
bool a = abi.decode(data, (bool));
assert(a);
return true;
}
function check_int32() external returns (bool) {
(bool success, bytes memory data) = f("return_int32()");
assert(success);
int32 a = abi.decode(data, (int32));
assert(a == -32);
return true;
}
function check_uint32() external returns (bool) {
(bool success, bytes memory data) = f("return_uint32()");
assert(success);
uint32 a = abi.decode(data, (uint32));
assert(a == 0x3232);
return true;
}
function check_int256() external returns (bool) {
(bool success, bytes memory data) = f("return_int256()");
assert(success);
int256 a = abi.decode(data, (int256));
assert(a == -256);
return true;
}
function check_uint256() external returns (bool) {
(bool success, bytes memory data) = f("return_uint256()");
assert(success);
uint256 a = abi.decode(data, (uint256));
assert(a == 0x256256);
return true;
}
function check_bytes4() external returns (bool) {
(bool success, bytes memory data) = f("return_bytes4()");
assert(success);
bytes4 a = abi.decode(data, (bytes4));
assert(a == 0xabcd0012);
return true;
}
function check_multi() external returns (bool) {
(bool success, bytes memory data) = f("return_multi()");
assert(success);
(bool a, uint32 b, bytes4 c) = abi.decode(data, (bool, uint32, bytes4));
assert(a == false && b == 0x3232 && c == 0xabcd0012);
return true;
}
function check_bytes() external returns (bool) {
(bool success, bytes memory data) = f("return_bytes()");
assert(success);
(bytes memory d) = abi.decode(data, (bytes));
assert(d.length == 2 && d[0] == 0x42 && d[1] == 0x21);
return true;
}
}
)DELIMITER";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("f(string)", encodeDyn(string("return_bool()"))), encodeArgs(true, 0x40, 0x20, true));
ABI_CHECK(callContractFunction("f(string)", encodeDyn(string("return_int32()"))), encodeArgs(true, 0x40, 0x20, u256(-32)));
ABI_CHECK(callContractFunction("f(string)", encodeDyn(string("return_uint32()"))), encodeArgs(true, 0x40, 0x20, u256(0x3232)));
ABI_CHECK(callContractFunction("f(string)", encodeDyn(string("return_int256()"))), encodeArgs(true, 0x40, 0x20, u256(-256)));
ABI_CHECK(callContractFunction("f(string)", encodeDyn(string("return_uint256()"))), encodeArgs(true, 0x40, 0x20, u256(0x256256)));
ABI_CHECK(callContractFunction("f(string)", encodeDyn(string("return_bytes4()"))), encodeArgs(true, 0x40, 0x20, u256(0xabcd0012) << (28*8)));
ABI_CHECK(callContractFunction("f(string)", encodeDyn(string("return_multi()"))), encodeArgs(true, 0x40, 0x60, false, u256(0x3232), u256(0xabcd0012) << (28*8)));
ABI_CHECK(callContractFunction("f(string)", encodeDyn(string("return_bytes()"))), encodeArgs(true, 0x40, 0x60, 0x20, 0x02, encode(bytes{0x42,0x21}, false)));
ABI_CHECK(callContractFunction("check_bool()"), encodeArgs(true));
ABI_CHECK(callContractFunction("check_int32()"), encodeArgs(true));
ABI_CHECK(callContractFunction("check_uint32()"), encodeArgs(true));
ABI_CHECK(callContractFunction("check_int256()"), encodeArgs(true));
ABI_CHECK(callContractFunction("check_uint256()"), encodeArgs(true));
ABI_CHECK(callContractFunction("check_bytes4()"), encodeArgs(true));
ABI_CHECK(callContractFunction("check_multi()"), encodeArgs(true));
ABI_CHECK(callContractFunction("check_bytes()"), encodeArgs(true));
}
}
}
BOOST_AUTO_TEST_CASE(delegatecall_return_value)
{
if (dev::test::Options::get().evmVersion().supportsReturndata())
{
char const* sourceCode = R"DELIMITER(
contract C {
uint value;
function set(uint _value) external {
value = _value;
}
function get() external view returns (uint) {
return value;
}
function get_delegated() external returns (bool, bytes memory) {
return address(this).delegatecall(abi.encodeWithSignature("get()"));
}
function assert0() external view {
assert(value == 0);
}
function assert0_delegated() external returns (bool, bytes memory) {
return address(this).delegatecall(abi.encodeWithSignature("assert0()"));
}
}
)DELIMITER";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("get()"), encodeArgs(u256(0)));
ABI_CHECK(callContractFunction("assert0_delegated()"), encodeArgs(u256(1), 0x40, 0x00));
ABI_CHECK(callContractFunction("get_delegated()"), encodeArgs(u256(1), 0x40, 0x20, 0x00));
ABI_CHECK(callContractFunction("set(uint256)", u256(1)), encodeArgs());
ABI_CHECK(callContractFunction("get()"), encodeArgs(u256(1)));
ABI_CHECK(callContractFunction("assert0_delegated()"), encodeArgs(u256(0), 0x40, 0x00));
ABI_CHECK(callContractFunction("get_delegated()"), encodeArgs(u256(1), 0x40, 0x20, 1));
ABI_CHECK(callContractFunction("set(uint256)", u256(42)), encodeArgs());
ABI_CHECK(callContractFunction("get()"), encodeArgs(u256(42)));
ABI_CHECK(callContractFunction("assert0_delegated()"), encodeArgs(u256(0), 0x40, 0x00));
ABI_CHECK(callContractFunction("get_delegated()"), encodeArgs(u256(1), 0x40, 0x20, 42));
}
else
{
char const* sourceCode = R"DELIMITER(
contract C {
uint value;
function set(uint _value) external {
value = _value;
}
function get() external view returns (uint) {
return value;
}
function get_delegated() external returns (bool) {
(bool success,) = address(this).delegatecall(abi.encodeWithSignature("get()"));
return success;
}
function assert0() external view {
assert(value == 0);
}
function assert0_delegated() external returns (bool) {
(bool success,) = address(this).delegatecall(abi.encodeWithSignature("assert0()"));
return success;
}
}
)DELIMITER";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("get()"), encodeArgs(u256(0)));
ABI_CHECK(callContractFunction("assert0_delegated()"), encodeArgs(u256(1)));
ABI_CHECK(callContractFunction("get_delegated()"), encodeArgs(u256(1)));
ABI_CHECK(callContractFunction("set(uint256)", u256(1)), encodeArgs());
ABI_CHECK(callContractFunction("get()"), encodeArgs(u256(1)));
ABI_CHECK(callContractFunction("assert0_delegated()"), encodeArgs(u256(0)));
ABI_CHECK(callContractFunction("get_delegated()"), encodeArgs(u256(1)));
ABI_CHECK(callContractFunction("set(uint256)", u256(42)), encodeArgs());
ABI_CHECK(callContractFunction("get()"), encodeArgs(u256(42)));
ABI_CHECK(callContractFunction("assert0_delegated()"), encodeArgs(u256(0)));
ABI_CHECK(callContractFunction("get_delegated()"), encodeArgs(u256(1)));
}
}
BOOST_AUTO_TEST_CASE(function_types_sig)
{
char const* sourceCode = R"(
contract C {
uint public x;
function f() public pure returns (bytes4) {
return this.f.selector;
}
function g() public returns (bytes4) {
function () pure external returns (bytes4) fun = this.f;
return fun.selector;
}
function h() public returns (bytes4) {
function () pure external returns (bytes4) fun = this.f;
return fun.selector;
}
function i() public pure returns (bytes4) {
return this.x.selector;
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("f()"), encodeArgs(asString(FixedHash<4>(dev::keccak256("f()")).asBytes())));
ABI_CHECK(callContractFunction("g()"), encodeArgs(asString(FixedHash<4>(dev::keccak256("f()")).asBytes())));
ABI_CHECK(callContractFunction("h()"), encodeArgs(asString(FixedHash<4>(dev::keccak256("f()")).asBytes())));
ABI_CHECK(callContractFunction("i()"), encodeArgs(asString(FixedHash<4>(dev::keccak256("x()")).asBytes())));
}
BOOST_AUTO_TEST_CASE(constant_string)
{
char const* sourceCode = R"(
contract C {
bytes constant a = "\x03\x01\x02";
bytes constant b = hex"030102";
string constant c = "hello";
function f() public returns (bytes memory) {
return a;
}
function g() public returns (bytes memory) {
return b;
}
function h() public returns (bytes memory) {
return bytes(c);
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("f()"), encodeDyn(string("\x03\x01\x02")));
ABI_CHECK(callContractFunction("g()"), encodeDyn(string("\x03\x01\x02")));
ABI_CHECK(callContractFunction("h()"), encodeDyn(string("hello")));
}
BOOST_AUTO_TEST_CASE(address_overload_resolution)
{
char const* sourceCode = R"(
contract C {
function balance() public returns (uint) {
return 1;
}
function transfer(uint amount) public returns (uint) {
return amount;
}
}
contract D {
function f() public returns (uint) {
return (new C()).balance();
}
function g() public returns (uint) {
return (new C()).transfer(5);
}
}
)";
compileAndRun(sourceCode, 0, "D");
BOOST_CHECK(callContractFunction("f()") == encodeArgs(u256(1)));
BOOST_CHECK(callContractFunction("g()") == encodeArgs(u256(5)));
}
BOOST_AUTO_TEST_CASE(snark)
{
char const* sourceCode = R"(
library Pairing {
struct G1Point {
uint X;
uint Y;
}
// Encoding of field elements is: X[0] * z + X[1]
struct G2Point {
uint[2] X;
uint[2] Y;
}
/// @return the generator of G1
function P1() internal returns (G1Point memory) {
return G1Point(1, 2);
}
/// @return the generator of G2
function P2() internal returns (G2Point memory) {
return G2Point(
[11559732032986387107991004021392285783925812861821192530917403151452391805634,
10857046999023057135944570762232829481370756359578518086990519993285655852781],
[4082367875863433681332203403145435568316851327593401208105741076214120093531,
8495653923123431417604973247489272438418190587263600148770280649306958101930]
);
}
/// @return the negation of p, i.e. p.add(p.negate()) should be zero.
function negate(G1Point memory p) internal returns (G1Point memory) {
// The prime q in the base field F_q for G1
uint q = 21888242871839275222246405745257275088696311157297823662689037894645226208583;
if (p.X == 0 && p.Y == 0)
return G1Point(0, 0);
return G1Point(p.X, q - (p.Y % q));
}
/// @return the sum of two points of G1
function add(G1Point memory p1, G1Point memory p2) internal returns (G1Point memory r) {
uint[4] memory input;
input[0] = p1.X;
input[1] = p1.Y;
input[2] = p2.X;
input[3] = p2.Y;
bool success;
assembly {
success := call(sub(gas, 2000), 6, 0, input, 0xc0, r, 0x60)
// Use "invalid" to make gas estimation work
switch success case 0 { invalid() }
}
require(success);
}
/// @return the product of a point on G1 and a scalar, i.e.
/// p == p.mul(1) and p.add(p) == p.mul(2) for all points p.
function mul(G1Point memory p, uint s) internal returns (G1Point memory r) {
uint[3] memory input;
input[0] = p.X;
input[1] = p.Y;
input[2] = s;
bool success;
assembly {
success := call(sub(gas, 2000), 7, 0, input, 0x80, r, 0x60)
// Use "invalid" to make gas estimation work
switch success case 0 { invalid() }
}
require(success);
}
/// @return the result of computing the pairing check
/// e(p1[0], p2[0]) * .... * e(p1[n], p2[n]) == 1
/// For example pairing([P1(), P1().negate()], [P2(), P2()]) should
/// return true.
function pairing(G1Point[] memory p1, G2Point[] memory p2) internal returns (bool) {
require(p1.length == p2.length);
uint elements = p1.length;
uint inputSize = p1.length * 6;
uint[] memory input = new uint[](inputSize);
for (uint i = 0; i < elements; i++)
{
input[i * 6 + 0] = p1[i].X;
input[i * 6 + 1] = p1[i].Y;
input[i * 6 + 2] = p2[i].X[0];
input[i * 6 + 3] = p2[i].X[1];
input[i * 6 + 4] = p2[i].Y[0];
input[i * 6 + 5] = p2[i].Y[1];
}
uint[1] memory out;
bool success;
assembly {
success := call(sub(gas, 2000), 8, 0, add(input, 0x20), mul(inputSize, 0x20), out, 0x20)
// Use "invalid" to make gas estimation work
switch success case 0 { invalid() }
}
require(success);
return out[0] != 0;
}
function pairingProd2(G1Point memory a1, G2Point memory a2, G1Point memory b1, G2Point memory b2) internal returns (bool) {
G1Point[] memory p1 = new G1Point[](2);
G2Point[] memory p2 = new G2Point[](2);
p1[0] = a1;
p1[1] = b1;
p2[0] = a2;
p2[1] = b2;
return pairing(p1, p2);
}
function pairingProd3(
G1Point memory a1, G2Point memory a2,
G1Point memory b1, G2Point memory b2,
G1Point memory c1, G2Point memory c2
) internal returns (bool) {
G1Point[] memory p1 = new G1Point[](3);
G2Point[] memory p2 = new G2Point[](3);
p1[0] = a1;
p1[1] = b1;
p1[2] = c1;
p2[0] = a2;
p2[1] = b2;
p2[2] = c2;
return pairing(p1, p2);
}
function pairingProd4(
G1Point memory a1, G2Point memory a2,
G1Point memory b1, G2Point memory b2,
G1Point memory c1, G2Point memory c2,
G1Point memory d1, G2Point memory d2
) internal returns (bool) {
G1Point[] memory p1 = new G1Point[](4);
G2Point[] memory p2 = new G2Point[](4);
p1[0] = a1;
p1[1] = b1;
p1[2] = c1;
p1[3] = d1;
p2[0] = a2;
p2[1] = b2;
p2[2] = c2;
p2[3] = d2;
return pairing(p1, p2);
}
}
contract Test {
using Pairing for *;
struct VerifyingKey {
Pairing.G2Point A;
Pairing.G1Point B;
Pairing.G2Point C;
Pairing.G2Point gamma;
Pairing.G1Point gammaBeta1;
Pairing.G2Point gammaBeta2;
Pairing.G2Point Z;
Pairing.G1Point[] IC;
}
struct Proof {
Pairing.G1Point A;
Pairing.G1Point A_p;
Pairing.G2Point B;
Pairing.G1Point B_p;
Pairing.G1Point C;
Pairing.G1Point C_p;
Pairing.G1Point K;
Pairing.G1Point H;
}
function f() public returns (bool) {
Pairing.G1Point memory p1;
Pairing.G1Point memory p2;
p1.X = 1; p1.Y = 2;
p2.X = 1; p2.Y = 2;
Pairing.G1Point memory explict_sum = Pairing.add(p1, p2);
Pairing.G1Point memory scalar_prod = Pairing.mul(p1, 2);
return (explict_sum.X == scalar_prod.X &&
explict_sum.Y == scalar_prod.Y);
}
function g() public returns (bool) {
Pairing.G1Point memory x = Pairing.add(Pairing.P1(), Pairing.negate(Pairing.P1()));
// should be zero
return (x.X == 0 && x.Y == 0);
}
function testMul() public returns (bool) {
Pairing.G1Point memory p;
// @TODO The points here are reported to be not well-formed
p.X = 14125296762497065001182820090155008161146766663259912659363835465243039841726;
p.Y = 16229134936871442251132173501211935676986397196799085184804749187146857848057;
p = Pairing.mul(p, 13986731495506593864492662381614386532349950841221768152838255933892789078521);
return
p.X == 18256332256630856740336504687838346961237861778318632856900758565550522381207 &&
p.Y == 6976682127058094634733239494758371323697222088503263230319702770853579280803;
}
function pair() public returns (bool) {
Pairing.G2Point memory fiveTimesP2 = Pairing.G2Point(
[4540444681147253467785307942530223364530218361853237193970751657229138047649, 20954117799226682825035885491234530437475518021362091509513177301640194298072],
[11631839690097995216017572651900167465857396346217730511548857041925508482915, 21508930868448350162258892668132814424284302804699005394342512102884055673846]
);
// The prime p in the base field F_p for G1
uint p = 21888242871839275222246405745257275088696311157297823662689037894645226208583;
Pairing.G1Point[] memory g1points = new Pairing.G1Point[](2);
Pairing.G2Point[] memory g2points = new Pairing.G2Point[](2);
// check e(5 P1, P2)e(-P1, 5 P2) == 1
g1points[0] = Pairing.P1().mul(5);
g1points[1] = Pairing.P1().negate();
g2points[0] = Pairing.P2();
g2points[1] = fiveTimesP2;
if (!Pairing.pairing(g1points, g2points))
return false;
// check e(P1, P2)e(-P1, P2) == 1
g1points[0] = Pairing.P1();
g1points[1] = Pairing.P1();
g1points[1].Y = p - g1points[1].Y;
g2points[0] = Pairing.P2();
g2points[1] = Pairing.P2();
if (!Pairing.pairing(g1points, g2points))
return false;
return true;
}
function verifyingKey() internal returns (VerifyingKey memory vk) {
vk.A = Pairing.G2Point([0x209dd15ebff5d46c4bd888e51a93cf99a7329636c63514396b4a452003a35bf7, 0x04bf11ca01483bfa8b34b43561848d28905960114c8ac04049af4b6315a41678], [0x2bb8324af6cfc93537a2ad1a445cfd0ca2a71acd7ac41fadbf933c2a51be344d, 0x120a2a4cf30c1bf9845f20c6fe39e07ea2cce61f0c9bb048165fe5e4de877550]);
vk.B = Pairing.G1Point(0x2eca0c7238bf16e83e7a1e6c5d49540685ff51380f309842a98561558019fc02, 0x03d3260361bb8451de5ff5ecd17f010ff22f5c31cdf184e9020b06fa5997db84);
vk.C = Pairing.G2Point([0x2e89718ad33c8bed92e210e81d1853435399a271913a6520736a4729cf0d51eb, 0x01a9e2ffa2e92599b68e44de5bcf354fa2642bd4f26b259daa6f7ce3ed57aeb3], [0x14a9a87b789a58af499b314e13c3d65bede56c07ea2d418d6874857b70763713, 0x178fb49a2d6cd347dc58973ff49613a20757d0fcc22079f9abd10c3baee24590]);
vk.gamma = Pairing.G2Point([0x25f83c8b6ab9de74e7da488ef02645c5a16a6652c3c71a15dc37fe3a5dcb7cb1, 0x22acdedd6308e3bb230d226d16a105295f523a8a02bfc5e8bd2da135ac4c245d], [0x065bbad92e7c4e31bf3757f1fe7362a63fbfee50e7dc68da116e67d600d9bf68, 0x06d302580dc0661002994e7cd3a7f224e7ddc27802777486bf80f40e4ca3cfdb]);
vk.gammaBeta1 = Pairing.G1Point(0x15794ab061441e51d01e94640b7e3084a07e02c78cf3103c542bc5b298669f21, 0x14db745c6780e9df549864cec19c2daf4531f6ec0c89cc1c7436cc4d8d300c6d);
vk.gammaBeta2 = Pairing.G2Point([0x1f39e4e4afc4bc74790a4a028aff2c3d2538731fb755edefd8cb48d6ea589b5e, 0x283f150794b6736f670d6a1033f9b46c6f5204f50813eb85c8dc4b59db1c5d39], [0x140d97ee4d2b36d99bc49974d18ecca3e7ad51011956051b464d9e27d46cc25e, 0x0764bb98575bd466d32db7b15f582b2d5c452b36aa394b789366e5e3ca5aabd4]);
vk.Z = Pairing.G2Point([0x217cee0a9ad79a4493b5253e2e4e3a39fc2df38419f230d341f60cb064a0ac29, 0x0a3d76f140db8418ba512272381446eb73958670f00cf46f1d9e64cba057b53c], [0x26f64a8ec70387a13e41430ed3ee4a7db2059cc5fc13c067194bcc0cb49a9855, 0x2fd72bd9edb657346127da132e5b82ab908f5816c826acb499e22f2412d1a2d7]);
vk.IC = new Pairing.G1Point[](10);
vk.IC[0] = Pairing.G1Point(0x0aee46a7ea6e80a3675026dfa84019deee2a2dedb1bbe11d7fe124cb3efb4b5a, 0x044747b6e9176e13ede3a4dfd0d33ccca6321b9acd23bf3683a60adc0366ebaf);
vk.IC[1] = Pairing.G1Point(0x1e39e9f0f91fa7ff8047ffd90de08785777fe61c0e3434e728fce4cf35047ddc, 0x2e0b64d75ebfa86d7f8f8e08abbe2e7ae6e0a1c0b34d028f19fa56e9450527cb);
vk.IC[2] = Pairing.G1Point(0x1c36e713d4d54e3a9644dffca1fc524be4868f66572516025a61ca542539d43f, 0x042dcc4525b82dfb242b09cb21909d5c22643dcdbe98c4d082cc2877e96b24db);
vk.IC[3] = Pairing.G1Point(0x17d5d09b4146424bff7e6fb01487c477bbfcd0cdbbc92d5d6457aae0b6717cc5, 0x02b5636903efbf46db9235bbe74045d21c138897fda32e079040db1a16c1a7a1);
vk.IC[4] = Pairing.G1Point(0x0f103f14a584d4203c27c26155b2c955f8dfa816980b24ba824e1972d6486a5d, 0x0c4165133b9f5be17c804203af781bcf168da7386620479f9b885ecbcd27b17b);
vk.IC[5] = Pairing.G1Point(0x232063b584fb76c8d07995bee3a38fa7565405f3549c6a918ddaa90ab971e7f8, 0x2ac9b135a81d96425c92d02296322ad56ffb16299633233e4880f95aafa7fda7);
vk.IC[6] = Pairing.G1Point(0x09b54f111d3b2d1b2fe1ae9669b3db3d7bf93b70f00647e65c849275de6dc7fe, 0x18b2e77c63a3e400d6d1f1fbc6e1a1167bbca603d34d03edea231eb0ab7b14b4);
vk.IC[7] = Pairing.G1Point(0x0c54b42137b67cc268cbb53ac62b00ecead23984092b494a88befe58445a244a, 0x18e3723d37fae9262d58b548a0575f59d9c3266db7afb4d5739555837f6b8b3e);
vk.IC[8] = Pairing.G1Point(0x0a6de0e2240aa253f46ce0da883b61976e3588146e01c9d8976548c145fe6e4a, 0x04fbaa3a4aed4bb77f30ebb07a3ec1c7d77a7f2edd75636babfeff97b1ea686e);
vk.IC[9] = Pairing.G1Point(0x111e2e2a5f8828f80ddad08f9f74db56dac1cc16c1cb278036f79a84cf7a116f, 0x1d7d62e192b219b9808faa906c5ced871788f6339e8d91b83ac1343e20a16b30);
}
function verify(uint[] memory input, Proof memory proof) internal returns (uint) {
VerifyingKey memory vk = verifyingKey();
require(input.length + 1 == vk.IC.length);
// Compute the linear combination vk_x
Pairing.G1Point memory vk_x = Pairing.G1Point(0, 0);
for (uint i = 0; i < input.length; i++)
vk_x = Pairing.add(vk_x, Pairing.mul(vk.IC[i + 1], input[i]));
vk_x = Pairing.add(vk_x, vk.IC[0]);
if (!Pairing.pairingProd2(proof.A, vk.A, Pairing.negate(proof.A_p), Pairing.P2())) return 1;
if (!Pairing.pairingProd2(vk.B, proof.B, Pairing.negate(proof.B_p), Pairing.P2())) return 2;
if (!Pairing.pairingProd2(proof.C, vk.C, Pairing.negate(proof.C_p), Pairing.P2())) return 3;
if (!Pairing.pairingProd3(
proof.K, vk.gamma,
Pairing.negate(Pairing.add(vk_x, Pairing.add(proof.A, proof.C))), vk.gammaBeta2,
Pairing.negate(vk.gammaBeta1), proof.B
)) return 4;
if (!Pairing.pairingProd3(
Pairing.add(vk_x, proof.A), proof.B,
Pairing.negate(proof.H), vk.Z,
Pairing.negate(proof.C), Pairing.P2()
)) return 5;
return 0;
}
event Verified(string);
function verifyTx() public returns (bool) {
uint[] memory input = new uint[](9);
Proof memory proof;
proof.A = Pairing.G1Point(12873740738727497448187997291915224677121726020054032516825496230827252793177, 21804419174137094775122804775419507726154084057848719988004616848382402162497);
proof.A_p = Pairing.G1Point(7742452358972543465462254569134860944739929848367563713587808717088650354556, 7324522103398787664095385319014038380128814213034709026832529060148225837366);
proof.B = Pairing.G2Point(
[8176651290984905087450403379100573157708110416512446269839297438960217797614, 15588556568726919713003060429893850972163943674590384915350025440408631945055],
[15347511022514187557142999444367533883366476794364262773195059233657571533367, 4265071979090628150845437155927259896060451682253086069461962693761322642015]);
proof.B_p = Pairing.G1Point(2979746655438963305714517285593753729335852012083057917022078236006592638393, 6470627481646078059765266161088786576504622012540639992486470834383274712950);
proof.C = Pairing.G1Point(6851077925310461602867742977619883934042581405263014789956638244065803308498, 10336382210592135525880811046708757754106524561907815205241508542912494488506);
proof.C_p = Pairing.G1Point(12491625890066296859584468664467427202390981822868257437245835716136010795448, 13818492518017455361318553880921248537817650587494176379915981090396574171686);
proof.H = Pairing.G1Point(12091046215835229523641173286701717671667447745509192321596954139357866668225, 14446807589950902476683545679847436767890904443411534435294953056557941441758);
proof.K = Pairing.G1Point(21341087976609916409401737322664290631992568431163400450267978471171152600502, 2942165230690572858696920423896381470344658299915828986338281196715687693170);
input[0] = 13986731495506593864492662381614386532349950841221768152838255933892789078521;
input[1] = 622860516154313070522697309645122400675542217310916019527100517240519630053;
input[2] = 11094488463398718754251685950409355128550342438297986977413505294941943071569;
input[3] = 6627643779954497813586310325594578844876646808666478625705401786271515864467;
input[4] = 2957286918163151606545409668133310005545945782087581890025685458369200827463;
input[5] = 1384290496819542862903939282897996566903332587607290986044945365745128311081;
input[6] = 5613571677741714971687805233468747950848449704454346829971683826953541367271;
input[7] = 9643208548031422463313148630985736896287522941726746581856185889848792022807;
input[8] = 18066496933330839731877828156604;
if (verify(input, proof) == 0) {
emit Verified("Transaction successfully verified.");
return true;
} else {
return false;
}
}
}
)";
compileAndRun(sourceCode, 0, "Pairing");
compileAndRun(sourceCode, 0, "Test", bytes(), map<string, Address>{{"Pairing", m_contractAddress}});
// Disabled because the point seems to be not well-formed, we need to find another example.
//BOOST_CHECK(callContractFunction("testMul()") == encodeArgs(true));
BOOST_CHECK(callContractFunction("f()") == encodeArgs(true));
BOOST_CHECK(callContractFunction("g()") == encodeArgs(true));
BOOST_CHECK(callContractFunction("pair()") == encodeArgs(true));
BOOST_CHECK(callContractFunction("verifyTx()") == encodeArgs(true));
}
BOOST_AUTO_TEST_CASE(abi_encode)
{
char const* sourceCode = R"(
contract C {
function f0() public returns (bytes memory) {
return abi.encode();
}
function f1() public returns (bytes memory) {
return abi.encode(1, 2);
}
function f2() public returns (bytes memory) {
string memory x = "abc";
return abi.encode(1, x, 2);
}
function f3() public returns (bytes memory r) {
// test that memory is properly allocated
string memory x = "abc";
r = abi.encode(1, x, 2);
bytes memory y = "def";
require(y[0] == "d");
y[0] = "e";
require(y[0] == "e");
}
function f4() public returns (bytes memory) {
bytes4 x = "abcd";
return abi.encode(bytes2(x));
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("f0()"), encodeArgs(0x20, 0));
ABI_CHECK(callContractFunction("f1()"), encodeArgs(0x20, 0x40, 1, 2));
ABI_CHECK(callContractFunction("f2()"), encodeArgs(0x20, 0xa0, 1, 0x60, 2, 3, "abc"));
ABI_CHECK(callContractFunction("f3()"), encodeArgs(0x20, 0xa0, 1, 0x60, 2, 3, "abc"));
ABI_CHECK(callContractFunction("f4()"), encodeArgs(0x20, 0x20, "ab"));
}
BOOST_AUTO_TEST_CASE(abi_encode_v2)
{
char const* sourceCode = R"(
pragma experimental ABIEncoderV2;
contract C {
struct S { uint a; uint[] b; }
function f0() public pure returns (bytes memory) {
return abi.encode();
}
function f1() public pure returns (bytes memory) {
return abi.encode(1, 2);
}
function f2() public pure returns (bytes memory) {
string memory x = "abc";
return abi.encode(1, x, 2);
}
function f3() public pure returns (bytes memory r) {
// test that memory is properly allocated
string memory x = "abc";
r = abi.encode(1, x, 2);
bytes memory y = "def";
require(y[0] == "d");
y[0] = "e";
require(y[0] == "e");
}
S s;
function f4() public returns (bytes memory r) {
string memory x = "abc";
s.a = 7;
s.b.push(2);
s.b.push(3);
r = abi.encode(1, x, s, 2);
bytes memory y = "def";
require(y[0] == "d");
y[0] = "e";
require(y[0] == "e");
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("f0()"), encodeArgs(0x20, 0));
ABI_CHECK(callContractFunction("f1()"), encodeArgs(0x20, 0x40, 1, 2));
ABI_CHECK(callContractFunction("f2()"), encodeArgs(0x20, 0xa0, 1, 0x60, 2, 3, "abc"));
ABI_CHECK(callContractFunction("f3()"), encodeArgs(0x20, 0xa0, 1, 0x60, 2, 3, "abc"));
ABI_CHECK(callContractFunction("f4()"), encodeArgs(0x20, 0x160, 1, 0x80, 0xc0, 2, 3, "abc", 7, 0x40, 2, 2, 3));
}
BOOST_AUTO_TEST_CASE(abi_encodePacked)
{
char const* sourceCode = R"(
contract C {
function f0() public pure returns (bytes memory) {
return abi.encodePacked();
}
function f1() public pure returns (bytes memory) {
return abi.encodePacked(uint8(1), uint8(2));
}
function f2() public pure returns (bytes memory) {
string memory x = "abc";
return abi.encodePacked(uint8(1), x, uint8(2));
}
function f3() public pure returns (bytes memory r) {
// test that memory is properly allocated
string memory x = "abc";
r = abi.encodePacked(uint8(1), x, uint8(2));
bytes memory y = "def";
require(y[0] == "d");
y[0] = "e";
require(y[0] == "e");
}
function f4() public pure returns (bytes memory) {
string memory x = "abcdefghijklmnopqrstuvwxyzabcdefghijklmnopqrstuvwxyz";
return abi.encodePacked(uint16(0x0701), x, uint16(0x1201));
}
function f_literal() public pure returns (bytes memory) {
return abi.encodePacked(uint8(0x01), "abc", uint8(0x02));
}
function f_calldata() public pure returns (bytes memory) {
return abi.encodePacked(uint8(0x01), msg.data, uint8(0x02));
}
}
)";
for (auto v2: {false, true})
{
compileAndRun(string(v2 ? "pragma experimental ABIEncoderV2;\n" : "") + sourceCode, 0, "C");
ABI_CHECK(callContractFunction("f0()"), encodeArgs(0x20, 0));
ABI_CHECK(callContractFunction("f1()"), encodeArgs(0x20, 2, "\x01\x02"));
ABI_CHECK(callContractFunction("f2()"), encodeArgs(0x20, 5, "\x01" "abc" "\x02"));
ABI_CHECK(callContractFunction("f3()"), encodeArgs(0x20, 5, "\x01" "abc" "\x02"));
ABI_CHECK(callContractFunction("f4()"), encodeArgs(
0x20,
2 + 26 + 26 + 2,
"\x07\x01" "abcdefghijklmnopqrstuvwxyzabcdefghijklmnopqrstuvwxyz" "\x12\x01"
));
ABI_CHECK(callContractFunction("f_literal()"), encodeArgs(0x20, 5, "\x01" "abc" "\x02"));
ABI_CHECK(callContractFunction("f_calldata()"), encodeArgs(0x20, 6, "\x01" "\xa5\xbf\xa1\xee" "\x02"));
}
}
BOOST_AUTO_TEST_CASE(abi_encodePacked_from_storage)
{
char const* sourceCode = R"(
contract C {
uint24[9] small_fixed;
int24[9] small_fixed_signed;
uint24[] small_dyn;
uint248[5] large_fixed;
uint248[] large_dyn;
bytes bytes_storage;
function sf() public returns (bytes memory) {
small_fixed[0] = 0xfffff1;
small_fixed[2] = 0xfffff2;
small_fixed[5] = 0xfffff3;
small_fixed[8] = 0xfffff4;
return abi.encodePacked(uint8(0x01), small_fixed, uint8(0x02));
}
function sd() public returns (bytes memory) {
small_dyn.length = 9;
small_dyn[0] = 0xfffff1;
small_dyn[2] = 0xfffff2;
small_dyn[5] = 0xfffff3;
small_dyn[8] = 0xfffff4;
return abi.encodePacked(uint8(0x01), small_dyn, uint8(0x02));
}
function sfs() public returns (bytes memory) {
small_fixed_signed[0] = -2;
small_fixed_signed[2] = 0xffff2;
small_fixed_signed[5] = -200;
small_fixed_signed[8] = 0xffff4;
return abi.encodePacked(uint8(0x01), small_fixed_signed, uint8(0x02));
}
function lf() public returns (bytes memory) {
large_fixed[0] = 2**248-1;
large_fixed[1] = 0xfffff2;
large_fixed[2] = 2**248-2;
large_fixed[4] = 0xfffff4;
return abi.encodePacked(uint8(0x01), large_fixed, uint8(0x02));
}
function ld() public returns (bytes memory) {
large_dyn.length = 5;
large_dyn[0] = 2**248-1;
large_dyn[1] = 0xfffff2;
large_dyn[2] = 2**248-2;
large_dyn[4] = 0xfffff4;
return abi.encodePacked(uint8(0x01), large_dyn, uint8(0x02));
}
function bytes_short() public returns (bytes memory) {
bytes_storage = "abcd";
return abi.encodePacked(uint8(0x01), bytes_storage, uint8(0x02));
}
function bytes_long() public returns (bytes memory) {
bytes_storage = "0123456789012345678901234567890123456789";
return abi.encodePacked(uint8(0x01), bytes_storage, uint8(0x02));
}
}
)";
for (auto v2: {false, true})
{
compileAndRun(string(v2 ? "pragma experimental ABIEncoderV2;\n" : "") + sourceCode, 0, "C");
bytes payload = encodeArgs(0xfffff1, 0, 0xfffff2, 0, 0, 0xfffff3, 0, 0, 0xfffff4);
bytes encoded = encodeArgs(0x20, 0x122, "\x01" + asString(payload) + "\x02");
ABI_CHECK(callContractFunction("sf()"), encoded);
ABI_CHECK(callContractFunction("sd()"), encoded);
ABI_CHECK(callContractFunction("sfs()"), encodeArgs(0x20, 0x122, "\x01" + asString(encodeArgs(
u256(-2), 0, 0xffff2, 0, 0, u256(-200), 0, 0, 0xffff4
)) + "\x02"));
payload = encodeArgs(
u256("0xffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffff"),
0xfffff2,
u256("0xfffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffe"),
0,
0xfffff4
);
ABI_CHECK(callContractFunction("lf()"), encodeArgs(0x20, 5 * 32 + 2, "\x01" + asString(encodeArgs(payload)) + "\x02"));
ABI_CHECK(callContractFunction("ld()"), encodeArgs(0x20, 5 * 32 + 2, "\x01" + asString(encodeArgs(payload)) + "\x02"));
ABI_CHECK(callContractFunction("bytes_short()"), encodeArgs(0x20, 6, "\x01" "abcd\x02"));
ABI_CHECK(
callContractFunction("bytes_long()"),
encodeArgs(0x20, 42, "\x01" "0123456789012345678901234567890123456789\x02")
);
}
}
BOOST_AUTO_TEST_CASE(abi_encodePacked_from_memory)
{
char const* sourceCode = R"(
contract C {
function sf() public pure returns (bytes memory) {
uint24[9] memory small_fixed;
small_fixed[0] = 0xfffff1;
small_fixed[2] = 0xfffff2;
small_fixed[5] = 0xfffff3;
small_fixed[8] = 0xfffff4;
return abi.encodePacked(uint8(0x01), small_fixed, uint8(0x02));
}
function sd() public pure returns (bytes memory) {
uint24[] memory small_dyn = new uint24[](9);
small_dyn[0] = 0xfffff1;
small_dyn[2] = 0xfffff2;
small_dyn[5] = 0xfffff3;
small_dyn[8] = 0xfffff4;
return abi.encodePacked(uint8(0x01), small_dyn, uint8(0x02));
}
function sfs() public pure returns (bytes memory) {
int24[9] memory small_fixed_signed;
small_fixed_signed[0] = -2;
small_fixed_signed[2] = 0xffff2;
small_fixed_signed[5] = -200;
small_fixed_signed[8] = 0xffff4;
return abi.encodePacked(uint8(0x01), small_fixed_signed, uint8(0x02));
}
function lf() public pure returns (bytes memory) {
uint248[5] memory large_fixed;
large_fixed[0] = 2**248-1;
large_fixed[1] = 0xfffff2;
large_fixed[2] = 2**248-2;
large_fixed[4] = 0xfffff4;
return abi.encodePacked(uint8(0x01), large_fixed, uint8(0x02));
}
function ld() public pure returns (bytes memory) {
uint248[] memory large_dyn = new uint248[](5);
large_dyn[0] = 2**248-1;
large_dyn[1] = 0xfffff2;
large_dyn[2] = 2**248-2;
large_dyn[4] = 0xfffff4;
return abi.encodePacked(uint8(0x01), large_dyn, uint8(0x02));
}
}
)";
for (auto v2: {false, true})
{
compileAndRun(string(v2 ? "pragma experimental ABIEncoderV2;\n" : "") + sourceCode, 0, "C");
bytes payload = encodeArgs(0xfffff1, 0, 0xfffff2, 0, 0, 0xfffff3, 0, 0, 0xfffff4);
bytes encoded = encodeArgs(0x20, 0x122, "\x01" + asString(payload) + "\x02");
ABI_CHECK(callContractFunction("sf()"), encoded);
ABI_CHECK(callContractFunction("sd()"), encoded);
ABI_CHECK(callContractFunction("sfs()"), encodeArgs(0x20, 0x122, "\x01" + asString(encodeArgs(
u256(-2), 0, 0xffff2, 0, 0, u256(-200), 0, 0, 0xffff4
)) + "\x02"));
payload = encodeArgs(
u256("0xffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffff"),
0xfffff2,
u256("0xfffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffe"),
0,
0xfffff4
);
ABI_CHECK(callContractFunction("lf()"), encodeArgs(0x20, 5 * 32 + 2, "\x01" + asString(encodeArgs(payload)) + "\x02"));
ABI_CHECK(callContractFunction("ld()"), encodeArgs(0x20, 5 * 32 + 2, "\x01" + asString(encodeArgs(payload)) + "\x02"));
}
}
BOOST_AUTO_TEST_CASE(abi_encodePacked_functionPtr)
{
char const* sourceCode = R"(
contract C {
C other = C(0x1112131400000000000011121314000000000087);
function testDirect() public view returns (bytes memory) {
return abi.encodePacked(uint8(8), other.f, uint8(2));
}
function testFixedArray() public view returns (bytes memory) {
function () external pure returns (bytes memory)[1] memory x;
x[0] = other.f;
return abi.encodePacked(uint8(8), x, uint8(2));
}
function testDynamicArray() public view returns (bytes memory) {
function () external pure returns (bytes memory)[] memory x = new function() external pure returns (bytes memory)[](1);
x[0] = other.f;
return abi.encodePacked(uint8(8), x, uint8(2));
}
function f() public pure returns (bytes memory) {}
}
)";
for (auto v2: {false, true})
{
compileAndRun(string(v2 ? "pragma experimental ABIEncoderV2;\n" : "") + sourceCode, 0, "C");
string directEncoding = asString(fromHex("08" "1112131400000000000011121314000000000087" "26121ff0" "02"));
ABI_CHECK(callContractFunction("testDirect()"), encodeArgs(0x20, directEncoding.size(), directEncoding));
string arrayEncoding = asString(fromHex("08" "1112131400000000000011121314000000000087" "26121ff0" "0000000000000000" "02"));
ABI_CHECK(callContractFunction("testFixedArray()"), encodeArgs(0x20, arrayEncoding.size(), arrayEncoding));
ABI_CHECK(callContractFunction("testDynamicArray()"), encodeArgs(0x20, arrayEncoding.size(), arrayEncoding));
}
}
BOOST_AUTO_TEST_CASE(abi_encodePackedV2_structs)
{
char const* sourceCode = R"(
pragma experimental ABIEncoderV2;
contract C {
struct S {
uint8 a;
int16 b;
uint8[2] c;
int16[] d;
}
S s;
event E(S indexed);
constructor() public {
s.a = 0x12;
s.b = -7;
s.c[0] = 2;
s.c[1] = 3;
s.d.length = 2;
s.d[0] = -7;
s.d[1] = -8;
}
function testStorage() public {
emit E(s);
}
function testMemory() public {
S memory m = s;
emit E(m);
}
}
)";
compileAndRun(sourceCode, 0, "C");
bytes structEnc = encodeArgs(int(0x12), u256(-7), int(2), int(3), u256(-7), u256(-8));
ABI_CHECK(callContractFunction("testStorage()"), encodeArgs());
BOOST_REQUIRE_EQUAL(m_logs[0].topics.size(), 2);
BOOST_CHECK_EQUAL(m_logs[0].topics[0], dev::keccak256(string("E((uint8,int16,uint8[2],int16[]))")));
BOOST_CHECK_EQUAL(m_logs[0].topics[1], dev::keccak256(asString(structEnc)));
ABI_CHECK(callContractFunction("testMemory()"), encodeArgs());
BOOST_REQUIRE_EQUAL(m_logs[0].topics.size(), 2);
BOOST_CHECK_EQUAL(m_logs[0].topics[0], dev::keccak256(string("E((uint8,int16,uint8[2],int16[]))")));
BOOST_CHECK_EQUAL(m_logs[0].topics[1], dev::keccak256(asString(structEnc)));
}
BOOST_AUTO_TEST_CASE(abi_encodePackedV2_nestedArray)
{
char const* sourceCode = R"(
pragma experimental ABIEncoderV2;
contract C {
struct S {
uint8 a;
int16 b;
}
event E(S[2][][3] indexed);
function testNestedArrays() public {
S[2][][3] memory x;
x[1] = new S[2][](2);
x[1][0][0].a = 1;
x[1][0][0].b = 2;
x[1][0][1].a = 3;
x[1][1][1].b = 4;
emit E(x);
}
}
)";
compileAndRun(sourceCode, 0, "C");
bytes structEnc = encodeArgs(1, 2, 3, 0, 0, 0, 0, 4);
ABI_CHECK(callContractFunction("testNestedArrays()"), encodeArgs());
BOOST_REQUIRE_EQUAL(m_logs[0].topics.size(), 2);
BOOST_CHECK_EQUAL(m_logs[0].topics[0], dev::keccak256(string("E((uint8,int16)[2][][3])")));
BOOST_CHECK_EQUAL(m_logs[0].topics[1], dev::keccak256(asString(structEnc)));
}
BOOST_AUTO_TEST_CASE(abi_encodePackedV2_arrayOfStrings)
{
char const* sourceCode = R"(
pragma experimental ABIEncoderV2;
contract C {
string[] x;
event E(string[] indexed);
constructor() public {
x.length = 2;
x[0] = "abc";
x[1] = "0123456789012345678901234567890123456789";
}
function testStorage() public {
emit E(x);
}
function testMemory() public {
string[] memory y = x;
emit E(y);
}
}
)";
compileAndRun(sourceCode, 0, "C");
bytes arrayEncoding = encodeArgs("abc", "0123456789012345678901234567890123456789");
ABI_CHECK(callContractFunction("testStorage()"), encodeArgs());
BOOST_REQUIRE_EQUAL(m_logs[0].topics.size(), 2);
BOOST_CHECK_EQUAL(m_logs[0].topics[0], dev::keccak256(string("E(string[])")));
BOOST_CHECK_EQUAL(m_logs[0].topics[1], dev::keccak256(asString(arrayEncoding)));
ABI_CHECK(callContractFunction("testMemory()"), encodeArgs());
BOOST_REQUIRE_EQUAL(m_logs[0].topics.size(), 2);
BOOST_CHECK_EQUAL(m_logs[0].topics[0], dev::keccak256(string("E(string[])")));
BOOST_CHECK_EQUAL(m_logs[0].topics[1], dev::keccak256(asString(arrayEncoding)));
}
BOOST_AUTO_TEST_CASE(event_signature_in_library)
{
// This tests a bug that was present where the "internal signature"
// for structs was also used for events.
char const* sourceCode = R"(
pragma experimental ABIEncoderV2;
library L {
struct S {
uint8 a;
int16 b;
}
event E(S indexed, S);
function f() internal {
S memory s;
emit E(s, s);
}
}
contract C {
constructor() public {
L.f();
}
}
)";
compileAndRun(sourceCode, 0, "C");
BOOST_REQUIRE_EQUAL(m_logs[0].topics.size(), 2);
BOOST_CHECK_EQUAL(m_logs[0].topics[0], dev::keccak256(string("E((uint8,int16),(uint8,int16))")));
}
BOOST_AUTO_TEST_CASE(abi_encode_with_selector)
{
char const* sourceCode = R"(
contract C {
function f0() public pure returns (bytes memory) {
return abi.encodeWithSelector(0x12345678);
}
function f1() public pure returns (bytes memory) {
return abi.encodeWithSelector(0x12345678, "abc");
}
function f2() public pure returns (bytes memory) {
bytes4 x = 0x12345678;
return abi.encodeWithSelector(x, "abc");
}
function f3() public pure returns (bytes memory) {
bytes4 x = 0x12345678;
return abi.encodeWithSelector(x, uint(-1));
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("f0()"), encodeArgs(0x20, 4, "\x12\x34\x56\x78"));
bytes expectation;
expectation = encodeArgs(0x20, 4 + 0x60) + bytes{0x12, 0x34, 0x56, 0x78} + encodeArgs(0x20, 3, "abc") + bytes(0x20 - 4);
ABI_CHECK(callContractFunction("f1()"), expectation);
expectation = encodeArgs(0x20, 4 + 0x60) + bytes{0x12, 0x34, 0x56, 0x78} + encodeArgs(0x20, 3, "abc") + bytes(0x20 - 4);
ABI_CHECK(callContractFunction("f2()"), expectation);
expectation = encodeArgs(0x20, 4 + 0x20) + bytes{0x12, 0x34, 0x56, 0x78} + encodeArgs(u256(-1)) + bytes(0x20 - 4);
ABI_CHECK(callContractFunction("f3()"), expectation);
}
BOOST_AUTO_TEST_CASE(abi_encode_with_selectorv2)
{
char const* sourceCode = R"(
pragma experimental ABIEncoderV2;
contract C {
function f0() public pure returns (bytes memory) {
return abi.encodeWithSelector(0x12345678);
}
function f1() public pure returns (bytes memory) {
return abi.encodeWithSelector(0x12345678, "abc");
}
function f2() public pure returns (bytes memory) {
bytes4 x = 0x12345678;
return abi.encodeWithSelector(x, "abc");
}
function f3() public pure returns (bytes memory) {
bytes4 x = 0x12345678;
return abi.encodeWithSelector(x, uint(-1));
}
struct S { uint a; string b; uint16 c; }
function f4() public pure returns (bytes memory) {
bytes4 x = 0x12345678;
S memory s;
s.a = 0x1234567;
s.b = "Lorem ipsum dolor sit ethereum........";
s.c = 0x1234;
return abi.encodeWithSelector(x, uint(-1), s, uint(3));
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("f0()"), encodeArgs(0x20, 4, "\x12\x34\x56\x78"));
bytes expectation;
expectation = encodeArgs(0x20, 4 + 0x60) + bytes{0x12, 0x34, 0x56, 0x78} + encodeArgs(0x20, 3, "abc") + bytes(0x20 - 4);
ABI_CHECK(callContractFunction("f1()"), expectation);
expectation = encodeArgs(0x20, 4 + 0x60) + bytes{0x12, 0x34, 0x56, 0x78} + encodeArgs(0x20, 3, "abc") + bytes(0x20 - 4);
ABI_CHECK(callContractFunction("f2()"), expectation);
expectation = encodeArgs(0x20, 4 + 0x20) + bytes{0x12, 0x34, 0x56, 0x78} + encodeArgs(u256(-1)) + bytes(0x20 - 4);
ABI_CHECK(callContractFunction("f3()"), expectation);
expectation =
encodeArgs(0x20, 4 + 0x120) +
bytes{0x12, 0x34, 0x56, 0x78} +
encodeArgs(u256(-1), 0x60, u256(3), 0x1234567, 0x60, 0x1234, 38, "Lorem ipsum dolor sit ethereum........") +
bytes(0x20 - 4);
ABI_CHECK(callContractFunction("f4()"), expectation);
}
BOOST_AUTO_TEST_CASE(abi_encode_with_signature)
{
char const* sourceCode = R"T(
contract C {
function f0() public pure returns (bytes memory) {
return abi.encodeWithSignature("f(uint256)");
}
function f1() public pure returns (bytes memory) {
string memory x = "f(uint256)";
return abi.encodeWithSignature(x, "abc");
}
string xstor;
function f1s() public returns (bytes memory) {
xstor = "f(uint256)";
return abi.encodeWithSignature(xstor, "abc");
}
function f2() public pure returns (bytes memory r, uint[] memory ar) {
string memory x = "Lorem ipsum dolor sit amet, consectetur adipiscing elit, sed do eiusmod tempor incididunt ut labore et dolore magna aliqua.";
uint[] memory y = new uint[](4);
y[0] = uint(-1);
y[1] = uint(-2);
y[2] = uint(-3);
y[3] = uint(-4);
r = abi.encodeWithSignature(x, y);
// The hash uses temporary memory. This allocation re-uses the memory
// and should initialize it properly.
ar = new uint[](2);
}
}
)T";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("f0()"), encodeArgs(0x20, 4, "\xb3\xde\x64\x8b"));
bytes expectation;
expectation = encodeArgs(0x20, 4 + 0x60) + bytes{0xb3, 0xde, 0x64, 0x8b} + encodeArgs(0x20, 3, "abc") + bytes(0x20 - 4);
ABI_CHECK(callContractFunction("f1()"), expectation);
ABI_CHECK(callContractFunction("f1s()"), expectation);
expectation =
encodeArgs(0x40, 0x140, 4 + 0xc0) +
(bytes{0xe9, 0xc9, 0x21, 0xcd} + encodeArgs(0x20, 4, u256(-1), u256(-2), u256(-3), u256(-4)) + bytes(0x20 - 4)) +
encodeArgs(2, 0, 0);
ABI_CHECK(callContractFunction("f2()"), expectation);
}
BOOST_AUTO_TEST_CASE(abi_encode_with_signaturev2)
{
char const* sourceCode = R"T(
pragma experimental ABIEncoderV2;
contract C {
function f0() public pure returns (bytes memory) {
return abi.encodeWithSignature("f(uint256)");
}
function f1() public pure returns (bytes memory) {
string memory x = "f(uint256)";
return abi.encodeWithSignature(x, "abc");
}
string xstor;
function f1s() public returns (bytes memory) {
xstor = "f(uint256)";
return abi.encodeWithSignature(xstor, "abc");
}
function f2() public pure returns (bytes memory r, uint[] memory ar) {
string memory x = "Lorem ipsum dolor sit amet, consectetur adipiscing elit, sed do eiusmod tempor incididunt ut labore et dolore magna aliqua.";
uint[] memory y = new uint[](4);
y[0] = uint(-1);
y[1] = uint(-2);
y[2] = uint(-3);
y[3] = uint(-4);
r = abi.encodeWithSignature(x, y);
// The hash uses temporary memory. This allocation re-uses the memory
// and should initialize it properly.
ar = new uint[](2);
}
struct S { uint a; string b; uint16 c; }
function f4() public pure returns (bytes memory) {
bytes4 x = 0x12345678;
S memory s;
s.a = 0x1234567;
s.b = "Lorem ipsum dolor sit ethereum........";
s.c = 0x1234;
return abi.encodeWithSignature(s.b, uint(-1), s, uint(3));
}
}
)T";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("f0()"), encodeArgs(0x20, 4, "\xb3\xde\x64\x8b"));
bytes expectation;
expectation = encodeArgs(0x20, 4 + 0x60) + bytes{0xb3, 0xde, 0x64, 0x8b} + encodeArgs(0x20, 3, "abc") + bytes(0x20 - 4);
ABI_CHECK(callContractFunction("f1()"), expectation);
ABI_CHECK(callContractFunction("f1s()"), expectation);
expectation =
encodeArgs(0x40, 0x140, 4 + 0xc0) +
(bytes{0xe9, 0xc9, 0x21, 0xcd} + encodeArgs(0x20, 4, u256(-1), u256(-2), u256(-3), u256(-4)) + bytes(0x20 - 4)) +
encodeArgs(2, 0, 0);
ABI_CHECK(callContractFunction("f2()"), expectation);
expectation =
encodeArgs(0x20, 4 + 0x120) +
bytes{0x7c, 0x79, 0x30, 0x02} +
encodeArgs(u256(-1), 0x60, u256(3), 0x1234567, 0x60, 0x1234, 38, "Lorem ipsum dolor sit ethereum........") +
bytes(0x20 - 4);
ABI_CHECK(callContractFunction("f4()"), expectation);
}
BOOST_AUTO_TEST_CASE(abi_encode_empty_string)
{
char const* sourceCode = R"(
// Tests that this will not end up using a "bytes0" type
// (which would assert)
contract C {
function f() public pure returns (bytes memory, bytes memory) {
return (abi.encode(""), abi.encodePacked(""));
}
}
)";
compileAndRun(sourceCode, 0, "C");
if (!dev::test::Options::get().useABIEncoderV2)
{
// ABI Encoder V2 has slightly different padding, tested below.
ABI_CHECK(callContractFunction("f()"), encodeArgs(
0x40, 0xc0,
0x60, 0x20, 0x00, 0x00,
0x00
));
}
}
BOOST_AUTO_TEST_CASE(abi_encode_empty_string_v2)
{
char const* sourceCode = R"(
// Tests that this will not end up using a "bytes0" type
// (which would assert)
pragma experimental ABIEncoderV2;
contract C {
function f() public pure returns (bytes memory, bytes memory) {
return (abi.encode(""), abi.encodePacked(""));
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("f()"), encodeArgs(
0x40, 0xa0,
0x40, 0x20, 0x00,
0x00
));
}
BOOST_AUTO_TEST_CASE(abi_encode_rational)
{
char const* sourceCode = R"(
// Tests that rational numbers (even negative ones) are encoded properly.
contract C {
function f() public pure returns (bytes memory) {
return abi.encode(1, -2);
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("f()"), encodeArgs(
0x20,
0x40, u256(1), u256(-2)
));
}
BOOST_AUTO_TEST_CASE(abi_encode_rational_v2)
{
char const* sourceCode = R"(
// Tests that rational numbers (even negative ones) are encoded properly.
pragma experimental ABIEncoderV2;
contract C {
function f() public pure returns (bytes memory) {
return abi.encode(1, -2);
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("f()"), encodeArgs(
0x20,
0x40, u256(1), u256(-2)
));
}
BOOST_AUTO_TEST_CASE(abi_encode_call)
{
char const* sourceCode = R"T(
contract C {
bool x;
function c(uint a, uint[] memory b) public {
require(a == 5);
require(b.length == 2);
require(b[0] == 6);
require(b[1] == 7);
x = true;
}
function f() public returns (bool) {
uint a = 5;
uint[] memory b = new uint[](2);
b[0] = 6;
b[1] = 7;
(bool success,) = address(this).call(abi.encodeWithSignature("c(uint256,uint256[])", a, b));
require(success);
return x;
}
}
)T";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("f()"), encodeArgs(true));
}
BOOST_AUTO_TEST_CASE(staticcall_for_view_and_pure)
{
char const* sourceCode = R"(
contract C {
uint x;
function f() public returns (uint) {
x = 3;
return 1;
}
}
interface CView {
function f() view external returns (uint);
}
interface CPure {
function f() pure external returns (uint);
}
contract D {
function f() public returns (uint) {
return (new C()).f();
}
function fview() public returns (uint) {
return (CView(address(new C()))).f();
}
function fpure() public returns (uint) {
return (CPure(address(new C()))).f();
}
}
)";
compileAndRun(sourceCode, 0, "D");
// This should work (called via CALL)
ABI_CHECK(callContractFunction("f()"), encodeArgs(1));
if (dev::test::Options::get().evmVersion().hasStaticCall())
{
// These should throw (called via STATICCALL)
ABI_CHECK(callContractFunction("fview()"), encodeArgs());
ABI_CHECK(callContractFunction("fpure()"), encodeArgs());
}
else
{
ABI_CHECK(callContractFunction("fview()"), encodeArgs(1));
ABI_CHECK(callContractFunction("fpure()"), encodeArgs(1));
}
}
BOOST_AUTO_TEST_CASE(bitwise_shifting_constantinople)
{
if (!dev::test::Options::get().evmVersion().hasBitwiseShifting())
return;
char const* sourceCode = R"(
contract C {
function shl(uint a, uint b) public returns (uint c) {
assembly {
c := shl(b, a)
}
}
function shr(uint a, uint b) public returns (uint c) {
assembly {
c := shr(b, a)
}
}
function sar(uint a, uint b) public returns (uint c) {
assembly {
c := sar(b, a)
}
}
}
)";
compileAndRun(sourceCode);
BOOST_CHECK(callContractFunction("shl(uint256,uint256)", u256(1), u256(2)) == encodeArgs(u256(4)));
BOOST_CHECK(callContractFunction("shl(uint256,uint256)", u256("0xffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffff"), u256(1)) == encodeArgs(u256("0xfffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffe")));
BOOST_CHECK(callContractFunction("shl(uint256,uint256)", u256("0xffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffff"), u256(256)) == encodeArgs(u256(0)));
BOOST_CHECK(callContractFunction("shr(uint256,uint256)", u256(3), u256(1)) == encodeArgs(u256(1)));
BOOST_CHECK(callContractFunction("shr(uint256,uint256)", u256("0xffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffff"), u256(1)) == encodeArgs(u256("0x7fffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffff")));
BOOST_CHECK(callContractFunction("shr(uint256,uint256)", u256("0xffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffff"), u256(255)) == encodeArgs(u256(1)));
BOOST_CHECK(callContractFunction("shr(uint256,uint256)", u256("0xffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffff"), u256(256)) == encodeArgs(u256(0)));
BOOST_CHECK(callContractFunction("sar(uint256,uint256)", u256(3), u256(1)) == encodeArgs(u256(1)));
BOOST_CHECK(callContractFunction("sar(uint256,uint256)", u256("0xffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffff"), u256(1)) == encodeArgs(u256("0xffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffff")));
BOOST_CHECK(callContractFunction("sar(uint256,uint256)", u256("0xffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffff"), u256(255)) == encodeArgs(u256("0xffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffff")));
BOOST_CHECK(callContractFunction("sar(uint256,uint256)", u256("0xffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffff"), u256(256)) == encodeArgs(u256("0xffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffff")));
}
BOOST_AUTO_TEST_CASE(bitwise_shifting_constants_constantinople)
{
if (!dev::test::Options::get().evmVersion().hasBitwiseShifting())
return;
char const* sourceCode = R"(
contract C {
function shl_1() public returns (bool) {
uint c;
assembly {
c := shl(2, 1)
}
assert(c == 4);
return true;
}
function shl_2() public returns (bool) {
uint c;
assembly {
c := shl(1, 0xffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffff)
}
assert(c == 0xfffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffe);
return true;
}
function shl_3() public returns (bool) {
uint c;
assembly {
c := shl(256, 0xffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffff)
}
assert(c == 0);
return true;
}
function shr_1() public returns (bool) {
uint c;
assembly {
c := shr(1, 3)
}
assert(c == 1);
return true;
}
function shr_2() public returns (bool) {
uint c;
assembly {
c := shr(1, 0xffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffff)
}
assert(c == 0x7fffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffff);
return true;
}
function shr_3() public returns (bool) {
uint c;
assembly {
c := shr(256, 0xffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffff)
}
assert(c == 0);
return true;
}
}
)";
compileAndRun(sourceCode);
BOOST_CHECK(callContractFunction("shl_1()") == encodeArgs(u256(1)));
BOOST_CHECK(callContractFunction("shl_2()") == encodeArgs(u256(1)));
BOOST_CHECK(callContractFunction("shl_3()") == encodeArgs(u256(1)));
BOOST_CHECK(callContractFunction("shr_1()") == encodeArgs(u256(1)));
BOOST_CHECK(callContractFunction("shr_2()") == encodeArgs(u256(1)));
BOOST_CHECK(callContractFunction("shr_3()") == encodeArgs(u256(1)));
}
BOOST_AUTO_TEST_CASE(bitwise_shifting_constantinople_combined)
{
if (!dev::test::Options::get().evmVersion().hasBitwiseShifting())
return;
char const* sourceCode = R"(
contract C {
function shl_zero(uint a) public returns (uint c) {
assembly {
c := shl(0, a)
}
}
function shr_zero(uint a) public returns (uint c) {
assembly {
c := shr(0, a)
}
}
function sar_zero(uint a) public returns (uint c) {
assembly {
c := sar(0, a)
}
}
function shl_large(uint a) public returns (uint c) {
assembly {
c := shl(0x110, a)
}
}
function shr_large(uint a) public returns (uint c) {
assembly {
c := shr(0x110, a)
}
}
function sar_large(uint a) public returns (uint c) {
assembly {
c := sar(0x110, a)
}
}
function shl_combined(uint a) public returns (uint c) {
assembly {
c := shl(4, shl(12, a))
}
}
function shr_combined(uint a) public returns (uint c) {
assembly {
c := shr(4, shr(12, a))
}
}
function sar_combined(uint a) public returns (uint c) {
assembly {
c := sar(4, sar(12, a))
}
}
function shl_combined_large(uint a) public returns (uint c) {
assembly {
c := shl(0xd0, shl(0x40, a))
}
}
function shl_combined_overflow(uint a) public returns (uint c) {
assembly {
c := shl(0x01, shl(not(0x00), a))
}
}
function shr_combined_large(uint a) public returns (uint c) {
assembly {
c := shr(0xd0, shr(0x40, a))
}
}
function shr_combined_overflow(uint a) public returns (uint c) {
assembly {
c := shr(0x01, shr(not(0x00), a))
}
}
function sar_combined_large(uint a) public returns (uint c) {
assembly {
c := sar(0xd0, sar(0x40, a))
}
}
}
)";
compileAndRun(sourceCode);
BOOST_CHECK(callContractFunction("shl_zero(uint256)", u256(0)) == encodeArgs(u256(0)));
BOOST_CHECK(callContractFunction("shl_zero(uint256)", u256("0xffff")) == encodeArgs(u256("0xffff")));
BOOST_CHECK(callContractFunction("shl_zero(uint256)", u256("0xffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffff")) == encodeArgs(u256("0xffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffff")));
BOOST_CHECK(callContractFunction("shr_zero(uint256)", u256(0)) == encodeArgs(u256(0)));
BOOST_CHECK(callContractFunction("shr_zero(uint256)", u256("0xffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffff")) == encodeArgs(u256("0xffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffff")));
BOOST_CHECK(callContractFunction("sar_zero(uint256)", u256(0)) == encodeArgs(u256(0)));
BOOST_CHECK(callContractFunction("sar_zero(uint256)", u256("0xffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffff")) == encodeArgs(u256("0xffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffff")));
BOOST_CHECK(callContractFunction("shl_large(uint256)", u256(0)) == encodeArgs(u256(0)));
BOOST_CHECK(callContractFunction("shl_large(uint256)", u256("0xffff")) == encodeArgs(u256(0)));
BOOST_CHECK(callContractFunction("shl_large(uint256)", u256("0xffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffff")) == encodeArgs(u256(0)));
BOOST_CHECK(callContractFunction("shr_large(uint256)", u256(0)) == encodeArgs(u256(0)));
BOOST_CHECK(callContractFunction("shr_large(uint256)", u256("0xffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffff")) == encodeArgs(u256(0)));
BOOST_CHECK(callContractFunction("sar_large(uint256)", u256(0)) == encodeArgs(u256(0)));
BOOST_CHECK(callContractFunction("sar_large(uint256)", u256("0x7fffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffff")) == encodeArgs(u256(0)));
BOOST_CHECK(callContractFunction("sar_large(uint256)", u256("0xffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffff")) == encodeArgs(u256("0xffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffff")));
BOOST_CHECK(callContractFunction("shl_combined(uint256)", u256(0)) == encodeArgs(u256(0)));
BOOST_CHECK(callContractFunction("shl_combined(uint256)", u256("0xffff")) == encodeArgs(u256("0xffff0000")));
BOOST_CHECK(callContractFunction("shl_combined(uint256)", u256("0xffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffff")) == encodeArgs(u256("0xffffffffffffffffffffffffffffffffffffffffffffffffffffffffffff0000")));
BOOST_CHECK(callContractFunction("shr_combined(uint256)", u256(0)) == encodeArgs(u256(0)));
BOOST_CHECK(callContractFunction("shr_combined(uint256)", u256("0xffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffff")) == encodeArgs(u256("0x0000ffffffffffffffffffffffffffffffffffffffffffffffffffffffffffff")));
BOOST_CHECK(callContractFunction("sar_combined(uint256)", u256(0)) == encodeArgs(u256(0)));
BOOST_CHECK(callContractFunction("sar_combined(uint256)", u256("0x7fffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffff")) == encodeArgs(u256("0x00007fffffffffffffffffffffffffffffffffffffffffffffffffffffffffff")));
BOOST_CHECK(callContractFunction("sar_combined(uint256)", u256("0xffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffff")) == encodeArgs(u256("0xffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffff")));
BOOST_CHECK(callContractFunction("shl_combined_large(uint256)", u256(0)) == encodeArgs(u256(0)));
BOOST_CHECK(callContractFunction("shl_combined_large(uint256)", u256("0xffff")) == encodeArgs(u256(0)));
BOOST_CHECK(callContractFunction("shl_combined_large(uint256)", u256("0xffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffff")) == encodeArgs(u256(0)));
BOOST_CHECK(callContractFunction("shl_combined_overflow(uint256)", u256(2)) == encodeArgs(u256(0)));
BOOST_CHECK(callContractFunction("shr_combined_large(uint256)", u256(0)) == encodeArgs(u256(0)));
BOOST_CHECK(callContractFunction("shr_combined_large(uint256)", u256("0xffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffff")) == encodeArgs(u256(0)));
BOOST_CHECK(callContractFunction("shr_combined_overflow(uint256)", u256(2)) == encodeArgs(u256(0)));
BOOST_CHECK(callContractFunction("sar_combined_large(uint256)", u256(0)) == encodeArgs(u256(0)));
BOOST_CHECK(callContractFunction("sar_combined_large(uint256)", u256("0x7fffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffff")) == encodeArgs(u256(0)));
BOOST_CHECK(callContractFunction("sar_combined_large(uint256)", u256("0xffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffff")) == encodeArgs(u256("0xffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffff")));
}
BOOST_AUTO_TEST_CASE(senders_balance)
{
char const* sourceCode = R"(
contract C {
function f() public view returns (uint) {
return msg.sender.balance;
}
}
contract D {
C c = new C();
constructor() public payable { }
function f() public view returns (uint) {
return c.f();
}
}
)";
compileAndRun(sourceCode, 27, "D");
BOOST_CHECK(callContractFunction("f()") == encodeArgs(u256(27)));
}
BOOST_AUTO_TEST_CASE(abi_decode_trivial)
{
char const* sourceCode = R"(
contract C {
function f(bytes memory data) public pure returns (uint) {
return abi.decode(data, (uint));
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("f(bytes)", 0x20, 0x20, 33), encodeArgs(u256(33)));
}
BOOST_AUTO_TEST_CASE(abi_encode_decode_simple)
{
char const* sourceCode = R"XX(
contract C {
function f() public pure returns (uint, bytes memory) {
bytes memory arg = "abcdefg";
return abi.decode(abi.encode(uint(33), arg), (uint, bytes));
}
}
)XX";
compileAndRun(sourceCode);
ABI_CHECK(
callContractFunction("f()"),
encodeArgs(33, 0x40, 7, "abcdefg")
);
}
BOOST_AUTO_TEST_CASE(abi_decode_simple)
{
char const* sourceCode = R"(
contract C {
function f(bytes memory data) public pure returns (uint, bytes memory) {
return abi.decode(data, (uint, bytes));
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(
callContractFunction("f(bytes)", 0x20, 0x20 * 4, 33, 0x40, 7, "abcdefg"),
encodeArgs(33, 0x40, 7, "abcdefg")
);
}
BOOST_AUTO_TEST_CASE(abi_decode_v2)
{
char const* sourceCode = R"(
pragma experimental ABIEncoderV2;
contract C {
struct S { uint a; uint[] b; }
function f() public pure returns (S memory) {
S memory s;
s.a = 8;
s.b = new uint[](3);
s.b[0] = 9;
s.b[1] = 10;
s.b[2] = 11;
return abi.decode(abi.encode(s), (S));
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(
callContractFunction("f()"),
encodeArgs(0x20, 8, 0x40, 3, 9, 10, 11)
);
}
BOOST_AUTO_TEST_CASE(abi_decode_simple_storage)
{
char const* sourceCode = R"(
contract C {
bytes data;
function f(bytes memory _data) public returns (uint, bytes memory) {
data = _data;
return abi.decode(data, (uint, bytes));
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(
callContractFunction("f(bytes)", 0x20, 0x20 * 4, 33, 0x40, 7, "abcdefg"),
encodeArgs(33, 0x40, 7, "abcdefg")
);
}
BOOST_AUTO_TEST_CASE(abi_decode_v2_storage)
{
char const* sourceCode = R"(
pragma experimental ABIEncoderV2;
contract C {
bytes data;
struct S { uint a; uint[] b; }
function f() public returns (S memory) {
S memory s;
s.a = 8;
s.b = new uint[](3);
s.b[0] = 9;
s.b[1] = 10;
s.b[2] = 11;
data = abi.encode(s);
return abi.decode(data, (S));
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(
callContractFunction("f()"),
encodeArgs(0x20, 8, 0x40, 3, 9, 10, 11)
);
}
BOOST_AUTO_TEST_CASE(abi_decode_calldata)
{
char const* sourceCode = R"(
contract C {
function f(bytes calldata data) external pure returns (uint, bytes memory r) {
return abi.decode(data, (uint, bytes));
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(
callContractFunction("f(bytes)", 0x20, 0x20 * 4, 33, 0x40, 7, "abcdefg"),
encodeArgs(33, 0x40, 7, "abcdefg")
);
}
BOOST_AUTO_TEST_CASE(abi_decode_v2_calldata)
{
char const* sourceCode = R"(
pragma experimental ABIEncoderV2;
contract C {
struct S { uint a; uint[] b; }
function f(bytes calldata data) external pure returns (S memory) {
return abi.decode(data, (S));
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(
callContractFunction("f(bytes)", 0x20, 0x20 * 7, 0x20, 33, 0x40, 3, 10, 11, 12),
encodeArgs(0x20, 33, 0x40, 3, 10, 11, 12)
);
}
BOOST_AUTO_TEST_CASE(abi_decode_static_array)
{
char const* sourceCode = R"(
contract C {
function f(bytes calldata data) external pure returns (uint[2][3] memory) {
return abi.decode(data, (uint[2][3]));
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(
callContractFunction("f(bytes)", 0x20, 6 * 0x20, 1, 2, 3, 4, 5, 6),
encodeArgs(1, 2, 3, 4, 5, 6)
);
}
BOOST_AUTO_TEST_CASE(abi_decode_static_array_v2)
{
char const* sourceCode = R"(
pragma experimental ABIEncoderV2;
contract C {
function f(bytes calldata data) external pure returns (uint[2][3] memory) {
return abi.decode(data, (uint[2][3]));
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(
callContractFunction("f(bytes)", 0x20, 6 * 0x20, 1, 2, 3, 4, 5, 6),
encodeArgs(1, 2, 3, 4, 5, 6)
);
}
BOOST_AUTO_TEST_CASE(abi_decode_dynamic_array)
{
char const* sourceCode = R"(
contract C {
function f(bytes calldata data) external pure returns (uint[] memory) {
return abi.decode(data, (uint[]));
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(
callContractFunction("f(bytes)", 0x20, 6 * 0x20, 0x20, 4, 3, 4, 5, 6),
encodeArgs(0x20, 4, 3, 4, 5, 6)
);
}
BOOST_AUTO_TEST_CASE(write_storage_external)
{
char const* sourceCode = R"(
contract C {
uint public x;
function f(uint y) public payable {
x = y;
}
function g(uint y) external {
x = y;
}
function h() public {
this.g(12);
}
}
contract D {
C c = new C();
function f() public payable returns (uint) {
c.g(3);
return c.x();
}
function g() public returns (uint) {
c.g(8);
return c.x();
}
function h() public returns (uint) {
c.h();
return c.x();
}
}
)";
compileAndRun(sourceCode, 0, "D");
ABI_CHECK(callContractFunction("f()"), encodeArgs(3));
ABI_CHECK(callContractFunction("g()"), encodeArgs(8));
ABI_CHECK(callContractFunction("h()"), encodeArgs(12));
}
BOOST_AUTO_TEST_CASE(test_underscore_in_hex)
{
char const* sourceCode = R"(
contract test {
function f(bool cond) public pure returns (uint) {
uint32 x = 0x1234_ab;
uint y = 0x1234_abcd_1234;
return cond ? x : y;
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("f(bool)", true), encodeArgs(u256(0x1234ab)));
ABI_CHECK(callContractFunction("f(bool)", false), encodeArgs(u256(0x1234abcd1234)));
}
BOOST_AUTO_TEST_CASE(flipping_sign_tests)
{
char const* sourceCode = R"(
contract test {
function f() public returns (bool){
int x = -2**255;
assert(-x == x);
return true;
}
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("f()"), encodeArgs(true));
}
BOOST_AUTO_TEST_CASE(external_public_override)
{
char const* sourceCode = R"(
contract A {
function f() external returns (uint) { return 1; }
}
contract B is A {
function f() public returns (uint) { return 2; }
function g() public returns (uint) { return f(); }
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("f()"), encodeArgs(2));
ABI_CHECK(callContractFunction("g()"), encodeArgs(2));
}
BOOST_AUTO_TEST_CASE(base_access_to_function_type_variables)
{
char const* sourceCode = R"(
contract C {
function () internal returns (uint) x;
function set() public {
C.x = g;
}
function g() public pure returns (uint) { return 2; }
function h() public returns (uint) { return C.x(); }
}
)";
compileAndRun(sourceCode);
ABI_CHECK(callContractFunction("g()"), encodeArgs(2));
ABI_CHECK(callContractFunction("h()"), encodeArgs());
ABI_CHECK(callContractFunction("set()"), encodeArgs());
ABI_CHECK(callContractFunction("h()"), encodeArgs(2));
}
BOOST_AUTO_TEST_CASE(code_access)
{
char const* sourceCode = R"(
contract C {
function lengths() public pure returns (bool) {
uint crLen = type(D).creationCode.length;
uint runLen = type(D).runtimeCode.length;
require(runLen < crLen);
require(crLen >= 0x20);
require(runLen >= 0x20);
return true;
}
function creation() public pure returns (bytes memory) {
return type(D).creationCode;
}
function runtime() public pure returns (bytes memory) {
return type(D).runtimeCode;
}
function runtimeAllocCheck() public pure returns (bytes memory) {
uint[] memory a = new uint[](2);
bytes memory c = type(D).runtimeCode;
uint[] memory b = new uint[](2);
a[0] = 0x1111;
a[1] = 0x2222;
b[0] = 0x3333;
b[1] = 0x4444;
return c;
}
}
contract D {
function f() public pure returns (uint) { return 7; }
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("lengths()"), encodeArgs(true));
bytes codeCreation = callContractFunction("creation()");
bytes codeRuntime1 = callContractFunction("runtime()");
bytes codeRuntime2 = callContractFunction("runtimeAllocCheck()");
ABI_CHECK(codeRuntime1, codeRuntime2);
}
BOOST_AUTO_TEST_CASE(code_access_padding)
{
char const* sourceCode = R"(
contract C {
function diff() public pure returns (uint remainder) {
bytes memory a = type(D).creationCode;
bytes memory b = type(D).runtimeCode;
assembly { remainder := mod(sub(b, a), 0x20) }
}
}
contract D {
function f() public pure returns (uint) { return 7; }
}
)";
compileAndRun(sourceCode, 0, "C");
// This checks that the allocation function pads to multiples of 32 bytes
ABI_CHECK(callContractFunction("diff()"), encodeArgs(0));
}
BOOST_AUTO_TEST_CASE(code_access_create)
{
char const* sourceCode = R"(
contract C {
function test() public returns (uint) {
bytes memory c = type(D).creationCode;
D d;
assembly {
d := create(0, add(c, 0x20), mload(c))
}
return d.f();
}
}
contract D {
uint x;
constructor() public { x = 7; }
function f() public view returns (uint) { return x; }
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("test()"), encodeArgs(7));
}
BOOST_AUTO_TEST_CASE(code_access_content)
{
char const* sourceCode = R"(
contract C {
function testRuntime() public returns (bool) {
D d = new D();
bytes32 runtimeHash = keccak256(type(D).runtimeCode);
bytes32 otherHash;
uint size;
assembly {
size := extcodesize(d)
extcodecopy(d, mload(0x40), 0, size)
otherHash := keccak256(mload(0x40), size)
}
require(size == type(D).runtimeCode.length);
require(runtimeHash == otherHash);
return true;
}
function testCreation() public returns (bool) {
D d = new D();
bytes32 creationHash = keccak256(type(D).creationCode);
require(creationHash == d.x());
return true;
}
}
contract D {
bytes32 public x;
constructor() public {
bytes32 codeHash;
assembly {
let size := codesize()
codecopy(mload(0x40), 0, size)
codeHash := keccak256(mload(0x40), size)
}
x = codeHash;
}
}
)";
compileAndRun(sourceCode, 0, "C");
ABI_CHECK(callContractFunction("testRuntime()"), encodeArgs(true));
ABI_CHECK(callContractFunction("testCreation()"), encodeArgs(true));
}
BOOST_AUTO_TEST_CASE(contract_name)
{
char const* sourceCode = R"(
contract C {
string public nameAccessor = type(C).name;
string public constant constantNameAccessor = type(C).name;
function name() public pure returns (string memory) {
return type(C).name;
}
}
contract D is C {
function name() public pure returns (string memory) {
return type(D).name;
}
function name2() public pure returns (string memory) {
return type(C).name;
}
}
contract ThisIsAVeryLongContractNameExceeding256bits {
string public nameAccessor = type(ThisIsAVeryLongContractNameExceeding256bits).name;
string public constant constantNameAccessor = type(ThisIsAVeryLongContractNameExceeding256bits).name;
function name() public pure returns (string memory) {
return type(ThisIsAVeryLongContractNameExceeding256bits).name;
}
}
)";
compileAndRun(sourceCode, 0, "C");
bytes argsC = encodeArgs(u256(0x20), u256(1), "C");
ABI_CHECK(callContractFunction("name()"), argsC);
ABI_CHECK(callContractFunction("nameAccessor()"), argsC);
ABI_CHECK(callContractFunction("constantNameAccessor()"), argsC);
compileAndRun(sourceCode, 0, "D");
bytes argsD = encodeArgs(u256(0x20), u256(1), "D");
ABI_CHECK(callContractFunction("name()"), argsD);
ABI_CHECK(callContractFunction("name2()"), argsC);
string longName = "ThisIsAVeryLongContractNameExceeding256bits";
compileAndRun(sourceCode, 0, longName);
bytes argsLong = encodeArgs(u256(0x20), u256(longName.length()), longName);
ABI_CHECK(callContractFunction("name()"), argsLong);
ABI_CHECK(callContractFunction("nameAccessor()"), argsLong);
ABI_CHECK(callContractFunction("constantNameAccessor()"), argsLong);
}
BOOST_AUTO_TEST_SUITE_END()
}
}
} // end namespaces
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