From 51fe1bd9c2fb60106ecf259c7d1749f28a584e0c Mon Sep 17 00:00:00 2001 From: Denton Liu Date: Wed, 11 May 2016 15:55:07 -0400 Subject: Replaced tabs with spaces --- docs/control-structures.rst | 194 ++++++++++++++++++++++---------------------- 1 file changed, 97 insertions(+), 97 deletions(-) (limited to 'docs/control-structures.rst') diff --git a/docs/control-structures.rst b/docs/control-structures.rst index 5a22cbe3..49d12087 100644 --- a/docs/control-structures.rst +++ b/docs/control-structures.rst @@ -246,8 +246,8 @@ arising when writing manual assembly by the following features: We now want to describe the inline assembly language in detail. .. warning:: - Inline assembly is still a relatively new feature and might change if it does not prove useful, - so please try to keep up to date. + Inline assembly is still a relatively new feature and might change if it does not prove useful, + so please try to keep up to date. Example ------- @@ -258,23 +258,23 @@ idea is that assembly libraries will be used to enhance the language in such way .. code:: - library GetCode { - function at(address _addr) returns (bytes o_code) { - assembly { - // retrieve the size of the code, this needs assembly - let size := extcodesize(_addr) - // allocate output byte array - this could also be done without assembly - // by using o_code = new bytes(size) - o_code := mload(0x40) - // new "memory end" including padding - mstore(0x40, add(o_code, and(add(add(size, 0x20), 0x1f), not(0x1f)))) - // store length in memory - mstore(o_code, size) - // actually retrieve the code, this needs assembly - extcodecopy(_addr, add(o_code, 0x20), 0, size) - } - } - } + library GetCode { + function at(address _addr) returns (bytes o_code) { + assembly { + // retrieve the size of the code, this needs assembly + let size := extcodesize(_addr) + // allocate output byte array - this could also be done without assembly + // by using o_code = new bytes(size) + o_code := mload(0x40) + // new "memory end" including padding + mstore(0x40, add(o_code, and(add(add(size, 0x20), 0x1f), bnot(0x1f)))) + // store length in memory + mstore(o_code, size) + // actually retrieve the code, this needs assembly + extcodecopy(_addr, add(o_code, 0x20), 0, size) + } + } + } Inline assemmbly could also be beneficial in cases where the optimizer fails to produce efficient code. Please be aware that assembly is much more difficult to write because @@ -283,24 +283,24 @@ you really know what you are doing. .. code:: - library VectorSum { - // This function is less efficient because the optimizer currently fails to - // remove the bounds checks in array access. - function sumSolidity(uint[] _data) returns (uint o_sum) { - for (uint i = 0; i < _data.length; ++i) - o_sum += _data[i]; - } - // We know that we only access the array in bounds, so we can avoid the check. - // 0x20 needs to be added to an array because the first slot contains the - // array length. - function sumAsm(uint[] _data) returns (uint o_sum) { - for (uint i = 0; i < _data.length; ++i) { - assembly { + library VectorSum { + // This function is less efficient because the optimizer currently fails to + // remove the bounds checks in array access. + function sumSolidity(uint[] _data) returns (uint o_sum) { + for (uint i = 0; i < _data.length; ++i) + o_sum += _data[i]; + } + // We know that we only access the array in bounds, so we can avoid the check. + // 0x20 needs to be added to an array because the first slot contains the + // array length. + function sumAsm(uint[] _data) returns (uint o_sum) { + for (uint i = 0; i < _data.length; ++i) { + assembly { o_sum := mload(add(add(_data, 0x20), i)) } } - } - } + } + } Syntax ------ @@ -487,7 +487,7 @@ Strings are stored left-aligned and cannot be longer than 32 bytes. .. code:: - assembly { 2 3 add "abc" and } + assembly { 2 3 add "abc" and } Functional Style ----------------- @@ -497,7 +497,7 @@ adding `3` to the contents in memory at position `0x80` would be .. code:: - 3 0x80 mload add 0x80 mstore + 3 0x80 mload add 0x80 mstore As it is often hard to see what the actual arguments for certain opcodes are, Solidity inline assembly also provides a "functional style" notation where the same code @@ -505,7 +505,7 @@ would be written as follows .. code:: - mstore(0x80, add(mload(0x80), 3)) + mstore(0x80, add(mload(0x80), 3)) Functional style and instructional style can be mixed, but any opcode inside a functional style expression has to return exactly one stack slot (most of the opcodes do). @@ -536,18 +536,18 @@ It is planned that the stack height changes can be specified in inline assembly. .. code:: - contract c { - uint b; - function f(uint x) returns (uint r) { - assembly { - b pop // remove the offset, we know it is zero - sload - x - mul - =: r // assign to return variable r - } - } - } + contract c { + uint b; + function f(uint x) returns (uint r) { + assembly { + b pop // remove the offset, we know it is zero + sload + x + mul + =: r // assign to return variable r + } + } + } Labels ------ @@ -558,19 +558,19 @@ jumps easier. The following code computes an element in the Fibonacci series. .. code:: - { - let n := calldataload(4) - let a := 1 - let b := a - loop: - jumpi(loopend, eq(n, 0)) - a add swap1 - n := sub(n, 1) - jump(loop) - loopend: - mstore(0, a) - return(0, 0x20) - } + { + let n := calldataload(4) + let a := 1 + let b := a + loop: + jumpi(loopend, eq(n, 0)) + a add swap1 + n := sub(n, 1) + jump(loop) + loopend: + mstore(0, a) + return(0, 0x20) + } Please note that automatically accessing stack variables can only work if the assembler knows the current stack height. This fails to work if the jump source @@ -583,19 +583,19 @@ will have a wrong impression about the stack height at label `two`: .. code:: - { - jump(two) - one: - // Here the stack height is 1 (because we pushed 7), - // but the assembler thinks it is 0 because it reads - // from top to bottom. - // Accessing stack variables here will lead to errors. - jump(three) - two: - 7 // push something onto the stack - jump(one) - three: - } + { + jump(two) + one: + // Here the stack height is 1 (because we pushed 7), + // but the assembler thinks it is 0 because it reads + // from top to bottom. + // Accessing stack variables here will lead to errors. + jump(three) + two: + 7 // push something onto the stack + jump(one) + three: + } Declaring Assembly-Local Variables @@ -610,19 +610,19 @@ be just `0`, but it can also be a complex functional-style expression. .. code:: - contract c { - function f(uint x) returns (uint b) { - assembly { - let v := add(x, 1) - mstore(0x80, v) - { - let y := add(sload(v), 1) - b := y - } // y is "deallocated" here - b := add(b, v) - } // v is "deallocated" here - } - } + contract c { + function f(uint x) returns (uint b) { + assembly { + let v := add(x, 1) + mstore(0x80, v) + { + let y := add(sload(v), 1) + b := y + } // y is "deallocated" here + b := add(b, v) + } // v is "deallocated" here + } + } Assignments @@ -640,12 +640,12 @@ For both ways, the colon points to the name of the variable. .. code:: - assembly { - let v := 0 // functional-style assignment as part of variable declaration - let g := add(v, 2) - sload(10) - =: v // instruction style assignment, puts the result of sload(10) into v - } + assembly { + let v := 0 // functional-style assignment as part of variable declaration + let g := add(v, 2) + sload(10) + =: v // instruction style assignment, puts the result of sload(10) into v + } Things to Avoid @@ -681,6 +681,6 @@ arrays are pointers to memory arrays. The length of a dynamic array is stored at first slot of the array and then only the array elements follow. .. warning:: - Statically-sized memory arrays do not have a length field, but it will be added soon - to allow better convertibility between statically- and dynamically-sized arrays, so - please do not rely on that. + Statically-sized memory arrays do not have a length field, but it will be added soon + to allow better convertibility between statically- and dynamically-sized arrays, so + please do not rely on that. -- cgit