go-ethereum/tests/solidity/contracts/OpCodes.sol

pragma solidity >=0.4.21 <0.6.0;

contract Test1 {
  function isSameAddress(address a, address b) public returns(bool){  //Simply add the two arguments and return
      if (a == b) return true;
      return false;
  }
}

contract OpCodes {

    Test1 test1;

    constructor() public {  //Constructor function
      test1 = new Test1();  //Create new "Test1" function
    }

   modifier onlyOwner(address _owner) {
      require(msg.sender == _owner);
      _;
   }
   // Add a todo to the list
   function test() public {

     //simple_instructions
     /*assembly { pop(sub(dup1, mul(dup1, dup1))) }*/

     //keywords
     assembly { pop(address) return(2, byte(2,1)) }

     //label_complex
     /*assembly { 7 abc: 8 eq jump(abc) jumpi(eq(7, 8), abc) pop }
     assembly { pop(jumpi(eq(7, 8), abc)) jump(abc) }*/

     //functional
     /*assembly { let x := 2 add(7, mul(6, x)) mul(7, 8) add =: x }*/

     //for_statement
     assembly { for { let i := 1 } lt(i, 5) { i := add(i, 1) } {} }
     assembly { for { let i := 6 } gt(i, 5) { i := add(i, 1) } {} }
     assembly { for { let i := 1 } slt(i, 5) { i := add(i, 1) } {} }
     assembly { for { let i := 6 } sgt(i, 5) { i := add(i, 1) } {} }

     //no_opcodes_in_strict
     assembly { pop(callvalue()) }

     //no_dup_swap_in_strict
     /*assembly { swap1() }*/

     //print_functional
     assembly { let x := mul(sload(0x12), 7) }

     //print_if
     assembly { if 2 { pop(mload(0)) }}

     //function_definitions_multiple_args
     assembly { function f(a, d){ mstore(a, d) } function g(a, d) -> x, y {}}

     //sstore
     assembly { function f(a, d){ sstore(a, d) } function g(a, d) -> x, y {}}

     //mstore8
     assembly { function f(a, d){ mstore8(a, d) } function g(a, d) -> x, y {}}

     //calldatacopy
     assembly {
       let a := mload(0x40)
       let b := add(a, 32)
       calldatacopy(a, 4, 32)
       /*calldatacopy(b, add(4, 32), 32)*/
       /*result := add(mload(a), mload(b))*/
     }

     //codecopy
     assembly {
       let a := mload(0x40)
       let b := add(a, 32)
       codecopy(a, 4, 32)
     }

     //codecopy
     assembly {
       let a := mload(0x40)
       let b := add(a, 32)
       extcodecopy(0, a, 4, 32)
     }

     //for_statement
     assembly { let x := calldatasize() for { let i := 0} lt(i, x) { i := add(i, 1) } { mstore(i, 2) } }

     //keccak256
     assembly { pop(keccak256(0,0)) }

     //returndatasize
     assembly { let r := returndatasize }

     //returndatacopy
     assembly { returndatacopy(64, 32, 0) }
     //byzantium vs const Constantinople
     //staticcall
     assembly { pop(staticcall(10000, 0x123, 64, 0x10, 128, 0x10)) }

     /*//create2 Constantinople
     assembly { pop(create2(10, 0x123, 32, 64)) }*/

     //create Constantinople
     assembly { pop(create(10, 0x123, 32)) }

     //shift Constantinople
     /*assembly { pop(shl(10, 32)) }
     assembly { pop(shr(10, 32)) }
     assembly { pop(sar(10, 32)) }*/


     //not
     assembly { pop( not(0x1f)) }

     //exp
     assembly { pop( exp(2, 226)) }

     //mod
     assembly { pop( mod(3, 9)) }

     //smod
     assembly { pop( smod(3, 9)) }

     //div
     assembly { pop( div(4, 2)) }

     //sdiv
     assembly { pop( sdiv(4, 2)) }

     //iszero
     assembly { pop(iszero(1)) }

     //and
     assembly { pop(and(2,3)) }

     //or
     assembly { pop(or(3,3)) }

     //xor
     assembly { pop(xor(3,3)) }

     //addmod
     assembly { pop(addmod(3,3,6)) }

     //mulmod
     assembly { pop(mulmod(3,3,3)) }

     //signextend
     assembly { pop(signextend(1, 10)) }

     //sha3
     assembly { pop(calldataload(0)) }

     //blockhash
     assembly { pop(blockhash(sub(number(), 1))) }

     //balance
     assembly { pop(balance(0x0)) }

     //caller
     assembly { pop(caller()) }

     //codesize
     assembly { pop(codesize()) }

     //extcodesize
     assembly { pop(extcodesize(0x1)) }

     //origin
     assembly { pop(origin()) }

     //gas
     assembly {  pop(gas())}

     //msize
     assembly {  pop(msize())}

     //pc
     assembly {  pop(pc())}

     //gasprice
     assembly {  pop(gasprice())}

     //coinbase
     assembly {  pop(coinbase())}

     //timestamp
     assembly {  pop(timestamp())}

     //number
     assembly {  pop(number())}

     //difficulty
     assembly {  pop(difficulty())}

     //gaslimit
     assembly {  pop(gaslimit())}

     //call
     address contractAddr = address(test1);
     bytes4 sig = bytes4(keccak256("isSameAddress(address,address)")); //Function signature
     address a = msg.sender;

     assembly {
         let x := mload(0x40)   //Find empty storage location using "free memory pointer"
         mstore(x,sig) //Place signature at begining of empty storage
         mstore(add(x,0x04),a) // first address parameter. just after signature
         mstore(add(x,0x24),a) // 2nd address parameter - first padded. add 32 bytes (not 20 bytes)
         mstore(0x40,add(x,0x64)) // this is missing in other examples. Set free pointer before function call. so it is used by called function.
          // new free pointer position after the output values of the called function.

         let success := call(
                         5000, //5k gas
                         contractAddr, //To addr
                         0,    //No wei passed
                         x,    // Inputs are at location x
                         0x44, //Inputs size two padded, so 68 bytes
                         x,    //Store output over input
                         0x20) //Output is 32 bytes long
     }

     //callcode
     assembly {
         let x := mload(0x40)   //Find empty storage location using "free memory pointer"
         mstore(x,sig) //Place signature at begining of empty storage
         mstore(add(x,0x04),a) // first address parameter. just after signature
         mstore(add(x,0x24),a) // 2nd address parameter - first padded. add 32 bytes (not 20 bytes)
         mstore(0x40,add(x,0x64)) // this is missing in other examples. Set free pointer before function call. so it is used by called function.
          // new free pointer position after the output values of the called function.

         let success := callcode(
                         5000, //5k gas
                         contractAddr, //To addr
                         0,    //No wei passed
                         x,    // Inputs are at location x
                         0x44, //Inputs size two padded, so 68 bytes
                         x,    //Store output over input
                         0x20) //Output is 32 bytes long
     }

     //delegatecall
     assembly {
         let x := mload(0x40)   //Find empty storage location using "free memory pointer"
         mstore(x,sig) //Place signature at begining of empty storage
         mstore(add(x,0x04),a) // first address parameter. just after signature
         mstore(add(x,0x24),a) // 2nd address parameter - first padded. add 32 bytes (not 20 bytes)
         mstore(0x40,add(x,0x64)) // this is missing in other examples. Set free pointer before function call. so it is used by called function.
          // new free pointer position after the output values of the called function.

         let success := delegatecall(
                         5000, //5k gas
                         contractAddr, //To addr
                         x,    // Inputs are at location x
                         0x44, //Inputs size two padded, so 68 bytes
                         x,    //Store output over input
                         0x20) //Output is 32 bytes long
     }

     uint256 _id = 0x420042;

     //log0
     log0(
         bytes32(0x50cb9fe53daa9737b786ab3646f04d0150dc50ef4e75f59509d83667ad5adb20)
     );

     //log1
     log1(
         bytes32(0x50cb9fe53daa9737b786ab3646f04d0150dc50ef4e75f59509d83667ad5adb20),
         bytes32(0x50cb9fe53daa9737b786ab3646f04d0150dc50ef4e75f59509d83667ad5adb20)
     );

     //log2
     log2(
         bytes32(0x50cb9fe53daa9737b786ab3646f04d0150dc50ef4e75f59509d83667ad5adb20),
         bytes32(0x50cb9fe53daa9737b786ab3646f04d0150dc50ef4e75f59509d83667ad5adb20),
         bytes32(uint256(msg.sender))
     );

     //log3
     log3(
         bytes32(0x50cb9fe53daa9737b786ab3646f04d0150dc50ef4e75f59509d83667ad5adb20),
         bytes32(0x50cb9fe53daa9737b786ab3646f04d0150dc50ef4e75f59509d83667ad5adb20),
         bytes32(uint256(msg.sender)),
         bytes32(_id)
     );

     //log4
     log4(
         bytes32(0x50cb9fe53daa9737b786ab3646f04d0150dc50ef4e75f59509d83667ad5adb20),
         bytes32(0x50cb9fe53daa9737b786ab3646f04d0150dc50ef4e75f59509d83667ad5adb20),
         bytes32(uint256(msg.sender)),
         bytes32(_id),
         bytes32(_id)

     );

     //selfdestruct
     assembly { selfdestruct(0x02) }
   }

  function test_revert() public {

    //revert
    assembly{ revert(0, 0) }
  }

  function test_invalid() public {

    //revert
    assembly{ invalid() }
  }

  function test_stop() public {

    //revert
    assembly{ stop() }
  }

}
tests/solidity: add contract to test every opcode (#19283) Fixes #18210 2019-09-26 04:30:33 -04:00			`pragma solidity >=0.4.21 <0.6.0;`

			`contract Test1 {`
			`function isSameAddress(address a, address b) public returns(bool){ //Simply add the two arguments and return`
			`if (a == b) return true;`
			`return false;`
			`}`
			`}`

			`contract OpCodes {`

			`Test1 test1;`

			`constructor() public { //Constructor function`
			`test1 = new Test1(); //Create new "Test1" function`
			`}`

			`modifier onlyOwner(address _owner) {`
			`require(msg.sender == _owner);`
			`_;`
			`}`
			`// Add a todo to the list`
			`function test() public {`

			`//simple_instructions`
			`/assembly { pop(sub(dup1, mul(dup1, dup1))) }/`

			`//keywords`
			`assembly { pop(address) return(2, byte(2,1)) }`

			`//label_complex`
			`/*assembly { 7 abc: 8 eq jump(abc) jumpi(eq(7, 8), abc) pop }`
			`assembly { pop(jumpi(eq(7, 8), abc)) jump(abc) }*/`

			`//functional`
			`/assembly { let x := 2 add(7, mul(6, x)) mul(7, 8) add =: x }/`

			`//for_statement`
			`assembly { for { let i := 1 } lt(i, 5) { i := add(i, 1) } {} }`
			`assembly { for { let i := 6 } gt(i, 5) { i := add(i, 1) } {} }`
			`assembly { for { let i := 1 } slt(i, 5) { i := add(i, 1) } {} }`
			`assembly { for { let i := 6 } sgt(i, 5) { i := add(i, 1) } {} }`

			`//no_opcodes_in_strict`
			`assembly { pop(callvalue()) }`

			`//no_dup_swap_in_strict`
			`/assembly { swap1() }/`

			`//print_functional`
			`assembly { let x := mul(sload(0x12), 7) }`

			`//print_if`
			`assembly { if 2 { pop(mload(0)) }}`

			`//function_definitions_multiple_args`
			`assembly { function f(a, d){ mstore(a, d) } function g(a, d) -> x, y {}}`

			`//sstore`
			`assembly { function f(a, d){ sstore(a, d) } function g(a, d) -> x, y {}}`

			`//mstore8`
			`assembly { function f(a, d){ mstore8(a, d) } function g(a, d) -> x, y {}}`

			`//calldatacopy`
			`assembly {`
			`let a := mload(0x40)`
			`let b := add(a, 32)`
			`calldatacopy(a, 4, 32)`
			`/calldatacopy(b, add(4, 32), 32)/`
			`/result := add(mload(a), mload(b))/`
			`}`

			`//codecopy`
			`assembly {`
			`let a := mload(0x40)`
			`let b := add(a, 32)`
			`codecopy(a, 4, 32)`
			`}`

			`//codecopy`
			`assembly {`
			`let a := mload(0x40)`
			`let b := add(a, 32)`
			`extcodecopy(0, a, 4, 32)`
			`}`

			`//for_statement`
			`assembly { let x := calldatasize() for { let i := 0} lt(i, x) { i := add(i, 1) } { mstore(i, 2) } }`

			`//keccak256`
			`assembly { pop(keccak256(0,0)) }`

			`//returndatasize`
			`assembly { let r := returndatasize }`

			`//returndatacopy`
			`assembly { returndatacopy(64, 32, 0) }`
			`//byzantium vs const Constantinople`
			`//staticcall`
			`assembly { pop(staticcall(10000, 0x123, 64, 0x10, 128, 0x10)) }`

			`/*//create2 Constantinople`
			`assembly { pop(create2(10, 0x123, 32, 64)) }*/`

			`//create Constantinople`
			`assembly { pop(create(10, 0x123, 32)) }`

			`//shift Constantinople`
			`/*assembly { pop(shl(10, 32)) }`
			`assembly { pop(shr(10, 32)) }`
			`assembly { pop(sar(10, 32)) }*/`


			`//not`
			`assembly { pop( not(0x1f)) }`

			`//exp`
			`assembly { pop( exp(2, 226)) }`

			`//mod`
			`assembly { pop( mod(3, 9)) }`

			`//smod`
			`assembly { pop( smod(3, 9)) }`

			`//div`
			`assembly { pop( div(4, 2)) }`

			`//sdiv`
			`assembly { pop( sdiv(4, 2)) }`

			`//iszero`
			`assembly { pop(iszero(1)) }`

			`//and`
			`assembly { pop(and(2,3)) }`

			`//or`
			`assembly { pop(or(3,3)) }`

			`//xor`
			`assembly { pop(xor(3,3)) }`

			`//addmod`
			`assembly { pop(addmod(3,3,6)) }`

			`//mulmod`
			`assembly { pop(mulmod(3,3,3)) }`

			`//signextend`
			`assembly { pop(signextend(1, 10)) }`

			`//sha3`
			`assembly { pop(calldataload(0)) }`

			`//blockhash`
			`assembly { pop(blockhash(sub(number(), 1))) }`

			`//balance`
			`assembly { pop(balance(0x0)) }`

			`//caller`
			`assembly { pop(caller()) }`

			`//codesize`
			`assembly { pop(codesize()) }`

			`//extcodesize`
			`assembly { pop(extcodesize(0x1)) }`

			`//origin`
			`assembly { pop(origin()) }`

			`//gas`
			`assembly { pop(gas())}`

			`//msize`
			`assembly { pop(msize())}`

			`//pc`
			`assembly { pop(pc())}`

			`//gasprice`
			`assembly { pop(gasprice())}`

			`//coinbase`
			`assembly { pop(coinbase())}`

			`//timestamp`
			`assembly { pop(timestamp())}`

			`//number`
			`assembly { pop(number())}`

			`//difficulty`
			`assembly { pop(difficulty())}`

			`//gaslimit`
			`assembly { pop(gaslimit())}`

			`//call`
			`address contractAddr = address(test1);`
			`bytes4 sig = bytes4(keccak256("isSameAddress(address,address)")); //Function signature`
			`address a = msg.sender;`

			`assembly {`
			`let x := mload(0x40) //Find empty storage location using "free memory pointer"`
			`mstore(x,sig) //Place signature at begining of empty storage`
			`mstore(add(x,0x04),a) // first address parameter. just after signature`
			`mstore(add(x,0x24),a) // 2nd address parameter - first padded. add 32 bytes (not 20 bytes)`
			`mstore(0x40,add(x,0x64)) // this is missing in other examples. Set free pointer before function call. so it is used by called function.`
			`// new free pointer position after the output values of the called function.`

			`let success := call(`
			`5000, //5k gas`
			`contractAddr, //To addr`
			`0, //No wei passed`
			`x, // Inputs are at location x`
			`0x44, //Inputs size two padded, so 68 bytes`
			`x, //Store output over input`
			`0x20) //Output is 32 bytes long`
			`}`

			`//callcode`
			`assembly {`
			`let x := mload(0x40) //Find empty storage location using "free memory pointer"`
			`mstore(x,sig) //Place signature at begining of empty storage`
			`mstore(add(x,0x04),a) // first address parameter. just after signature`
			`mstore(add(x,0x24),a) // 2nd address parameter - first padded. add 32 bytes (not 20 bytes)`
			`mstore(0x40,add(x,0x64)) // this is missing in other examples. Set free pointer before function call. so it is used by called function.`
			`// new free pointer position after the output values of the called function.`

			`let success := callcode(`
			`5000, //5k gas`
			`contractAddr, //To addr`
			`0, //No wei passed`
			`x, // Inputs are at location x`
			`0x44, //Inputs size two padded, so 68 bytes`
			`x, //Store output over input`
			`0x20) //Output is 32 bytes long`
			`}`

			`//delegatecall`
			`assembly {`
			`let x := mload(0x40) //Find empty storage location using "free memory pointer"`
			`mstore(x,sig) //Place signature at begining of empty storage`
			`mstore(add(x,0x04),a) // first address parameter. just after signature`
			`mstore(add(x,0x24),a) // 2nd address parameter - first padded. add 32 bytes (not 20 bytes)`
			`mstore(0x40,add(x,0x64)) // this is missing in other examples. Set free pointer before function call. so it is used by called function.`
			`// new free pointer position after the output values of the called function.`

			`let success := delegatecall(`
			`5000, //5k gas`
			`contractAddr, //To addr`
			`x, // Inputs are at location x`
			`0x44, //Inputs size two padded, so 68 bytes`
			`x, //Store output over input`
			`0x20) //Output is 32 bytes long`
			`}`

			`uint256 _id = 0x420042;`

			`//log0`
			`log0(`
			`bytes32(0x50cb9fe53daa9737b786ab3646f04d0150dc50ef4e75f59509d83667ad5adb20)`
			`);`

			`//log1`
			`log1(`
			`bytes32(0x50cb9fe53daa9737b786ab3646f04d0150dc50ef4e75f59509d83667ad5adb20),`
			`bytes32(0x50cb9fe53daa9737b786ab3646f04d0150dc50ef4e75f59509d83667ad5adb20)`
			`);`

			`//log2`
			`log2(`
			`bytes32(0x50cb9fe53daa9737b786ab3646f04d0150dc50ef4e75f59509d83667ad5adb20),`
			`bytes32(0x50cb9fe53daa9737b786ab3646f04d0150dc50ef4e75f59509d83667ad5adb20),`
			`bytes32(uint256(msg.sender))`
			`);`

			`//log3`
			`log3(`
			`bytes32(0x50cb9fe53daa9737b786ab3646f04d0150dc50ef4e75f59509d83667ad5adb20),`
			`bytes32(0x50cb9fe53daa9737b786ab3646f04d0150dc50ef4e75f59509d83667ad5adb20),`
			`bytes32(uint256(msg.sender)),`
			`bytes32(_id)`
			`);`

			`//log4`
			`log4(`
			`bytes32(0x50cb9fe53daa9737b786ab3646f04d0150dc50ef4e75f59509d83667ad5adb20),`
			`bytes32(0x50cb9fe53daa9737b786ab3646f04d0150dc50ef4e75f59509d83667ad5adb20),`
			`bytes32(uint256(msg.sender)),`
			`bytes32(_id),`
			`bytes32(_id)`

			`);`

			`//selfdestruct`
			`assembly { selfdestruct(0x02) }`
			`}`

			`function test_revert() public {`

			`//revert`
			`assembly{ revert(0, 0) }`
			`}`

			`function test_invalid() public {`

			`//revert`
			`assembly{ invalid() }`
			`}`

			`function test_stop() public {`

			`//revert`
			`assembly{ stop() }`
			`}`

			`}`