mirror of
https://github.com/ethereum/solidity
synced 2023-10-03 13:03:40 +00:00
967 lines
46 KiB
ReStructuredText
967 lines
46 KiB
ReStructuredText
#################
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Solidity Assembly
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#################
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.. index:: ! assembly, ! asm, ! evmasm
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Solidity defines an assembly language that can also be used without Solidity.
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This assembly language can also be used as "inline assembly" inside Solidity
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source code. We start with describing how to use inline assembly and how it
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differs from standalone assembly and then specify assembly itself.
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TODO: Write about how scoping rules of inline assembly are a bit different
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and the complications that arise when for example using internal functions
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of libraries. Furhermore, write about the symbols defined by the compiler.
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Inline Assembly
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===============
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For more fine-grained control especially in order to enhance the language by writing libraries,
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it is possible to interleave Solidity statements with inline assembly in a language close
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to the one of the virtual machine. Due to the fact that the EVM is a stack machine, it is
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often hard to address the correct stack slot and provide arguments to opcodes at the correct
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point on the stack. Solidity's inline assembly tries to facilitate that and other issues
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arising when writing manual assembly by the following features:
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* functional-style opcodes: ``mul(1, add(2, 3))`` instead of ``push1 3 push1 2 add push1 1 mul``
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* assembly-local variables: ``let x := add(2, 3) let y := mload(0x40) x := add(x, y)``
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* access to external variables: ``function f(uint x) { assembly { x := sub(x, 1) } }``
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* labels: ``let x := 10 repeat: x := sub(x, 1) jumpi(repeat, eq(x, 0))``
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* loops: ``for { let i := 0 } lt(i, x) { i := add(i, 1) } { y := mul(2, y) }``
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* switch statements: ``switch x case 0: { y := mul(x, 2) } default: { y := 0 }``
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* function calls: ``function f(x) -> (y) { switch x case 0: { y := 1 } default: { y := mul(x, f(sub(x, 1))) } }``
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.. note::
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Of the above, loops, function calls and switch statements are not yet implemented.
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We now want to describe the inline assembly language in detail.
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.. warning::
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Inline assembly is a way to access the Ethereum Virtual Machine
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at a low level. This discards several important safety
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features of Solidity.
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Example
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-------
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The following example provides library code to access the code of another contract and
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load it into a ``bytes`` variable. This is not possible at all with "plain Solidity" and the
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idea is that assembly libraries will be used to enhance the language in such ways.
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.. code::
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pragma solidity ^0.4.0;
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library GetCode {
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function at(address _addr) returns (bytes o_code) {
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assembly {
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// retrieve the size of the code, this needs assembly
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let size := extcodesize(_addr)
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// allocate output byte array - this could also be done without assembly
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// by using o_code = new bytes(size)
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o_code := mload(0x40)
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// new "memory end" including padding
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mstore(0x40, add(o_code, and(add(add(size, 0x20), 0x1f), not(0x1f))))
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// store length in memory
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mstore(o_code, size)
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// actually retrieve the code, this needs assembly
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extcodecopy(_addr, add(o_code, 0x20), 0, size)
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}
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}
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}
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Inline assembly could also be beneficial in cases where the optimizer fails to produce
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efficient code. Please be aware that assembly is much more difficult to write because
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the compiler does not perform checks, so you should use it for complex things only if
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you really know what you are doing.
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.. code::
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pragma solidity ^0.4.0;
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library VectorSum {
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// This function is less efficient because the optimizer currently fails to
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// remove the bounds checks in array access.
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function sumSolidity(uint[] _data) returns (uint o_sum) {
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for (uint i = 0; i < _data.length; ++i)
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o_sum += _data[i];
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}
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// We know that we only access the array in bounds, so we can avoid the check.
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// 0x20 needs to be added to an array because the first slot contains the
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// array length.
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function sumAsm(uint[] _data) returns (uint o_sum) {
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for (uint i = 0; i < _data.length; ++i) {
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assembly {
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o_sum := mload(add(add(_data, 0x20), mul(i, 0x20)))
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}
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}
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}
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}
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Syntax
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------
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Assembly parses comments, literals and identifiers exactly as Solidity, so you can use the
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usual ``//`` and ``/* */`` comments. Inline assembly is marked by ``assembly { ... }`` and inside
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these curly braces, the following can be used (see the later sections for more details)
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- literals, i.e. ``0x123``, ``42`` or ``"abc"`` (strings up to 32 characters)
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- opcodes (in "instruction style"), e.g. ``mload sload dup1 sstore``, for a list see below
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- opcodes in functional style, e.g. ``add(1, mlod(0))``
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- labels, e.g. ``name:``
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- variable declarations, e.g. ``let x := 7`` or ``let x := add(y, 3)``
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- identifiers (labels or assembly-local variables and externals if used as inline assembly), e.g. ``jump(name)``, ``3 x add``
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- assignments (in "instruction style"), e.g. ``3 =: x``
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- assignments in functional style, e.g. ``x := add(y, 3)``
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- blocks where local variables are scoped inside, e.g. ``{ let x := 3 { let y := add(x, 1) } }``
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Opcodes
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-------
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This document does not want to be a full description of the Ethereum virtual machine, but the
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following list can be used as a reference of its opcodes.
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If an opcode takes arguments (always from the top of the stack), they are given in parentheses.
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Note that the order of arguments can be seen to be reversed in non-functional style (explained below).
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Opcodes marked with ``-`` do not push an item onto the stack, those marked with ``*`` are
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special and all others push exactly one item onte the stack.
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In the following, ``mem[a...b)`` signifies the bytes of memory starting at position ``a`` up to
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(excluding) position ``b`` and ``storage[p]`` signifies the storage contents at position ``p``.
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The opcodes ``pushi`` and ``jumpdest`` cannot be used directly.
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In the grammar, opcodes are represented as pre-defined identifiers.
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+-------------------------+------+-----------------------------------------------------------------+
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| stop + `-` | stop execution, identical to return(0,0) |
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+-------------------------+------+-----------------------------------------------------------------+
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| add(x, y) | | x + y |
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+-------------------------+------+-----------------------------------------------------------------+
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| sub(x, y) | | x - y |
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+-------------------------+------+-----------------------------------------------------------------+
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| mul(x, y) | | x * y |
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+-------------------------+------+-----------------------------------------------------------------+
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| div(x, y) | | x / y |
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+-------------------------+------+-----------------------------------------------------------------+
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| sdiv(x, y) | | x / y, for signed numbers in two's complement |
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+-------------------------+------+-----------------------------------------------------------------+
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| mod(x, y) | | x % y |
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+-------------------------+------+-----------------------------------------------------------------+
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| smod(x, y) | | x % y, for signed numbers in two's complement |
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+-------------------------+------+-----------------------------------------------------------------+
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| exp(x, y) | | x to the power of y |
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+-------------------------+------+-----------------------------------------------------------------+
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| not(x) | | ~x, every bit of x is negated |
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+-------------------------+------+-----------------------------------------------------------------+
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| lt(x, y) | | 1 if x < y, 0 otherwise |
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+-------------------------+------+-----------------------------------------------------------------+
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| gt(x, y) | | 1 if x > y, 0 otherwise |
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+-------------------------+------+-----------------------------------------------------------------+
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| slt(x, y) | | 1 if x < y, 0 otherwise, for signed numbers in two's complement |
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+-------------------------+------+-----------------------------------------------------------------+
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| sgt(x, y) | | 1 if x > y, 0 otherwise, for signed numbers in two's complement |
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+-------------------------+------+-----------------------------------------------------------------+
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| eq(x, y) | | 1 if x == y, 0 otherwise |
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+-------------------------+------+-----------------------------------------------------------------+
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| iszero(x) | | 1 if x == 0, 0 otherwise |
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+-------------------------+------+-----------------------------------------------------------------+
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| and(x, y) | | bitwise and of x and y |
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+-------------------------+------+-----------------------------------------------------------------+
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| or(x, y) | | bitwise or of x and y |
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+-------------------------+------+-----------------------------------------------------------------+
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| xor(x, y) | | bitwise xor of x and y |
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+-------------------------+------+-----------------------------------------------------------------+
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| byte(n, x) | | nth byte of x, where the most significant byte is the 0th byte |
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+-------------------------+------+-----------------------------------------------------------------+
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| addmod(x, y, m) | | (x + y) % m with arbitrary precision arithmetics |
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+-------------------------+------+-----------------------------------------------------------------+
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| mulmod(x, y, m) | | (x * y) % m with arbitrary precision arithmetics |
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+-------------------------+------+-----------------------------------------------------------------+
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| signextend(i, x) | | sign extend from (i*8+7)th bit counting from least significant |
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+-------------------------+------+-----------------------------------------------------------------+
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| sha3(p, n) | | keccak(mem[p...(p+n))) |
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+-------------------------+------+-----------------------------------------------------------------+
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| jump(label) | `-` | jump to label / code position |
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+-------------------------+------+-----------------------------------------------------------------+
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| jumpi(label, cond) | `-` | jump to label if cond is nonzero |
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+-------------------------+------+-----------------------------------------------------------------+
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| pc | | current position in code |
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+-------------------------+------+-----------------------------------------------------------------+
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| pop(x) | `-` | remove the element pushed by x |
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+-------------------------+------+-----------------------------------------------------------------+
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| dup1 ... dup16 | | copy ith stack slot to the top (counting from top) |
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+-------------------------+------+-----------------------------------------------------------------+
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| swap1 ... swap16 | `*` | swap topmost and ith stack slot below it |
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+-------------------------+------+-----------------------------------------------------------------+
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| mload(p) | | mem[p..(p+32)) |
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+-------------------------+------+-----------------------------------------------------------------+
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| mstore(p, v) | `-` | mem[p..(p+32)) := v |
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+-------------------------+------+-----------------------------------------------------------------+
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| mstore8(p, v) | `-` | mem[p] := v & 0xff - only modifies a single byte |
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+-------------------------+------+-----------------------------------------------------------------+
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| sload(p) | | storage[p] |
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+-------------------------+------+-----------------------------------------------------------------+
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| sstore(p, v) | `-` | storage[p] := v |
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+-------------------------+------+-----------------------------------------------------------------+
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| msize | | size of memory, i.e. largest accessed memory index |
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+-------------------------+------+-----------------------------------------------------------------+
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| gas | | gas still available to execution |
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+-------------------------+------+-----------------------------------------------------------------+
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| address | | address of the current contract / execution context |
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+-------------------------+------+-----------------------------------------------------------------+
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| balance(a) | | wei balance at address a |
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+-------------------------+------+-----------------------------------------------------------------+
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| caller | | call sender (excluding delegatecall) |
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+-------------------------+------+-----------------------------------------------------------------+
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| callvalue | | wei sent together with the current call |
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+-------------------------+------+-----------------------------------------------------------------+
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| calldataload(p) | | call data starting from position p (32 bytes) |
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+-------------------------+------+-----------------------------------------------------------------+
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| calldatasize | | size of call data in bytes |
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+-------------------------+------+-----------------------------------------------------------------+
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| calldatacopy(t, f, s) | `-` | copy s bytes from calldata at position f to mem at position t |
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+-------------------------+------+-----------------------------------------------------------------+
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| codesize | | size of the code of the current contract / execution context |
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+-------------------------+------+-----------------------------------------------------------------+
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| codecopy(t, f, s) | `-` | copy s bytes from code at position f to mem at position t |
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+-------------------------+------+-----------------------------------------------------------------+
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| extcodesize(a) | | size of the code at address a |
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+-------------------------+------+-----------------------------------------------------------------+
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| extcodecopy(a, t, f, s) | `-` | like codecopy(t, f, s) but take code at address a |
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+-------------------------+------+-----------------------------------------------------------------+
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| create(v, p, s) | | create new contract with code mem[p..(p+s)) and send v wei |
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| | | and return the new address |
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+-------------------------+------+-----------------------------------------------------------------+
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| call(g, a, v, in, | | call contract at address a with input mem[in..(in+insize)) |
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| insize, out, outsize) | | providing g gas and v wei and output area |
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| | | mem[out..(out+outsize)) returning 0 on error (eg. out of gas) |
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| | | and 1 on success |
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+-------------------------+------+-----------------------------------------------------------------+
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| callcode(g, a, v, in, | | identical to `call` but only use the code from a and stay |
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| insize, out, outsize) | | in the context of the current contract otherwise |
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+-------------------------+------+-----------------------------------------------------------------+
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| delegatecall(g, a, in, | | identical to `callcode` but also keep ``caller`` |
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| insize, out, outsize) | | and ``callvalue`` |
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+-------------------------+------+-----------------------------------------------------------------+
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| return(p, s) | `-` | end execution, return data mem[p..(p+s)) |
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+-------------------------+------+-----------------------------------------------------------------+
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| selfdestruct(a) | `-` | end execution, destroy current contract and send funds to a |
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+-------------------------+------+-----------------------------------------------------------------+
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| invalid | `-` | end execution with invalid instruction |
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+-------------------------+------+-----------------------------------------------------------------+
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| log0(p, s) | `-` | log without topics and data mem[p..(p+s)) |
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+-------------------------+------+-----------------------------------------------------------------+
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| log1(p, s, t1) | `-` | log with topic t1 and data mem[p..(p+s)) |
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+-------------------------+------+-----------------------------------------------------------------+
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| log2(p, s, t1, t2) | `-` | log with topics t1, t2 and data mem[p..(p+s)) |
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+-------------------------+------+-----------------------------------------------------------------+
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| log3(p, s, t1, t2, t3) | `-` | log with topics t1, t2, t3 and data mem[p..(p+s)) |
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+-------------------------+------+-----------------------------------------------------------------+
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| log4(p, s, t1, t2, t3, | `-` | log with topics t1, t2, t3, t4 and data mem[p..(p+s)) |
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| t4) | | |
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+-------------------------+------+-----------------------------------------------------------------+
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| origin | | transaction sender |
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+-------------------------+------+-----------------------------------------------------------------+
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| gasprice | | gas price of the transaction |
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+-------------------------+------+-----------------------------------------------------------------+
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| blockhash(b) | | hash of block nr b - only for last 256 blocks excluding current |
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+-------------------------+------+-----------------------------------------------------------------+
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| coinbase | | current mining beneficiary |
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+-------------------------+------+-----------------------------------------------------------------+
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| timestamp | | timestamp of the current block in seconds since the epoch |
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+-------------------------+------+-----------------------------------------------------------------+
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| number | | current block number |
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+-------------------------+------+-----------------------------------------------------------------+
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| difficulty | | difficulty of the current block |
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+-------------------------+------+-----------------------------------------------------------------+
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| gaslimit | | block gas limit of the current block |
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+-------------------------+------+-----------------------------------------------------------------+
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Literals
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--------
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You can use integer constants by typing them in decimal or hexadecimal notation and an
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appropriate ``PUSHi`` instruction will automatically be generated. The following creates code
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to add 2 and 3 resulting in 5 and then computes the bitwise and with the string "abc".
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Strings are stored left-aligned and cannot be longer than 32 bytes.
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.. code::
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assembly { 2 3 add "abc" and }
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Functional Style
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-----------------
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You can type opcode after opcode in the same way they will end up in bytecode. For example
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adding ``3`` to the contents in memory at position ``0x80`` would be
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.. code::
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3 0x80 mload add 0x80 mstore
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As it is often hard to see what the actual arguments for certain opcodes are,
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Solidity inline assembly also provides a "functional style" notation where the same code
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would be written as follows
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.. code::
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mstore(0x80, add(mload(0x80), 3))
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Functional style and instructional style can be mixed, but any opcode inside a
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functional style expression has to return exactly one stack slot (most of the opcodes do).
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Note that the order of arguments is reversed in functional-style as opposed to the instruction-style
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way. If you use functional-style, the first argument will end up on the stack top.
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Access to External Variables and Functions
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------------------------------------------
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Solidity variables and other identifiers can be accessed by simply using their name.
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For storage and memory variables, this will push the address and not the value onto the
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stack. Also note that non-struct and non-array storage variable addresses occupy two slots
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on the stack: One for the address and one for the byte offset inside the storage slot.
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In assignments (see below), we can even use local Solidity variables to assign to.
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Functions external to inline assembly can also be accessed: The assembly will
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push their entry label (with virtual function resolution applied). The calling semantics
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in solidity are:
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- the caller pushes return label, arg1, arg2, ..., argn
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- the call returns with ret1, ret2, ..., retn
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This feature is still a bit cumbersome to use, because the stack offset essentially
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changes during the call, and thus references to local variables will be wrong.
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It is planned that the stack height changes can be specified in inline assembly.
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.. code::
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pragma solidity ^0.4.0;
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contract C {
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uint b;
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function f(uint x) returns (uint r) {
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assembly {
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b pop // remove the offset, we know it is zero
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sload
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x
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mul
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=: r // assign to return variable r
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}
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}
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}
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Labels
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------
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Another problem in EVM assembly is that ``jump`` and ``jumpi`` use absolute addresses
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which can change easily. Solidity inline assembly provides labels to make the use of
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jumps easier. The following code computes an element in the Fibonacci series.
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.. code::
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{
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let n := calldataload(4)
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let a := 1
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let b := a
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loop:
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jumpi(loopend, eq(n, 0))
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a add swap1
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n := sub(n, 1)
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jump(loop)
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loopend:
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mstore(0, a)
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return(0, 0x20)
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}
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Please note that automatically accessing stack variables can only work if the
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assembler knows the current stack height. This fails to work if the jump source
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and target have different stack heights. It is still fine to use such jumps, but
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you should just not access any stack variables (even assembly variables) in that case.
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Furthermore, the stack height analyser goes through the code opcode by opcode
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(and not according to control flow), so in the following case, the assembler
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will have a wrong impression about the stack height at label ``two``:
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.. code::
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{
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jump(two)
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one:
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// Here the stack height is 1 (because we pushed 7),
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// but the assembler thinks it is 0 because it reads
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// from top to bottom.
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// Accessing stack variables here will lead to errors.
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jump(three)
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two:
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7 // push something onto the stack
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jump(one)
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three:
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}
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.. note::
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``invalidJumpLabel`` is a pre-defined label. Jumping to this location will always
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result in an invalid jump, effectively aborting execution of the code.
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Declaring Assembly-Local Variables
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----------------------------------
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You can use the ``let`` keyword to declare variables that are only visible in
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inline assembly and actually only in the current ``{...}``-block. What happens
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is that the ``let`` instruction will create a new stack slot that is reserved
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for the variable and automatically removed again when the end of the block
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is reached. You need to provide an initial value for the variable which can
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be just ``0``, but it can also be a complex functional-style expression.
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.. code::
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pragma solidity ^0.4.0;
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contract C {
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function f(uint x) returns (uint b) {
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assembly {
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let v := add(x, 1)
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mstore(0x80, v)
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{
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let y := add(sload(v), 1)
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b := y
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} // y is "deallocated" here
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b := add(b, v)
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} // v is "deallocated" here
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}
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}
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Assignments
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-----------
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Assignments are possible to assembly-local variables and to function-local
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variables. Take care that when you assign to variables that point to
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memory or storage, you will only change the pointer and not the data.
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There are two kinds of assignments: functional-style and instruction-style.
|
|
For functional-style assignments (``variable := value``), you need to provide a value in a
|
|
functional-style expression that results in exactly one stack value
|
|
and for instruction-style (``=: variable``), the value is just taken from the stack top.
|
|
For both ways, the colon points to the name of the variable. The assignment
|
|
is performed by replacing the variable's value on the stack by the new value.
|
|
|
|
.. 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
|
|
}
|
|
|
|
Switch
|
|
------
|
|
|
|
You can use a switch statement as a very basic version of "if/else".
|
|
It takes the value of an expression and compares it to several constants.
|
|
The branch corresponding to the matching constant is taken. Contrary to the
|
|
error-prone behaviour of some programming languages, control flow does
|
|
not continue from one case to the next. There can be a fallback or default
|
|
case called ``default``.
|
|
|
|
.. code::
|
|
|
|
assembly {
|
|
let x := 0
|
|
switch calldataload(4)
|
|
case 0: {
|
|
x := calldataload(0x24)
|
|
}
|
|
default: {
|
|
x := calldataload(0x44)
|
|
}
|
|
sstore(0, div(x, 2))
|
|
}
|
|
|
|
The list of cases does not require curly braces, but the body of a
|
|
case does require them.
|
|
|
|
Loops
|
|
-----
|
|
|
|
Assembly supports a simple for-style loop. For-style loops have
|
|
a header containing an initializing part, a condition and a post-iteration
|
|
part. The condition has to be a functional-style expression, while
|
|
the other two can also be blocks. If the initializing part is a block that
|
|
declares any variables, the scope of these variables is extended into the
|
|
body (including the condition and the post-iteration part).
|
|
|
|
The following example computes the sum of an area in memory.
|
|
|
|
.. code::
|
|
|
|
assembly {
|
|
let x := 0
|
|
for { let i := 0 } lt(i, 0x100) { i := add(i, 0x20) } {
|
|
x := add(x, mload(i))
|
|
}
|
|
}
|
|
|
|
Functions
|
|
---------
|
|
|
|
Assembly allows the definition of low-level functions. These take their
|
|
arguments (and a return PC) from the stack and also put the results onto the
|
|
stack. Calling a function looks the same way as executing a functional-style
|
|
opcode.
|
|
|
|
Functions can be defined anywhere and are visible in the block they are
|
|
declared in. Inside a function, you cannot access local variables
|
|
defined outside of that function. There is no explicit ``return``
|
|
statement.
|
|
|
|
If you call a function that returns multiple values, you have to assign
|
|
them to a tuple using ``(a, b) := f(x)`` or ``let (a, b) := f(x)``.
|
|
|
|
The following example implements the power function by square-and-multiply.
|
|
|
|
.. code::
|
|
|
|
assembly {
|
|
function power(base, exponent) -> (result) {
|
|
switch exponent
|
|
0: { result := 1 }
|
|
1: { result := base }
|
|
default: {
|
|
result := power(mul(base, base), div(exponent, 2))
|
|
switch mod(exponent, 2)
|
|
1: { result := mul(base, result) }
|
|
}
|
|
}
|
|
}
|
|
|
|
Things to Avoid
|
|
---------------
|
|
|
|
Inline assembly might have a quite high-level look, but it actually is extremely
|
|
low-level. Function calls, loops and switches are converted by simple
|
|
rewriting rules and after that, the only thing the assembler does for you is re-arranging
|
|
functional-style opcodes, managing jump labels, counting stack height for
|
|
variable access and removing stack slots for assembly-local variables when the end
|
|
of their block is reached. Especially for those two last cases, it is important
|
|
to know that the assembler only counts stack height from top to bottom, not
|
|
necessarily following control flow. Furthermore, operations like swap will only
|
|
swap the contents of the stack but not the location of variables.
|
|
|
|
Conventions in Solidity
|
|
-----------------------
|
|
|
|
In contrast to EVM assembly, Solidity knows types which are narrower than 256 bits,
|
|
e.g. ``uint24``. In order to make them more efficient, most arithmetic operations just
|
|
treat them as 256-bit numbers and the higher-order bits are only cleaned at the
|
|
point where it is necessary, i.e. just shortly before they are written to memory
|
|
or before comparisons are performed. This means that if you access such a variable
|
|
from within inline assembly, you might have to manually clean the higher order bits
|
|
first.
|
|
|
|
Solidity manages memory in a very simple way: There is a "free memory pointer"
|
|
at position ``0x40`` in memory. If you want to allocate memory, just use the memory
|
|
from that point on and update the pointer accordingly.
|
|
|
|
Elements in memory arrays in Solidity always occupy multiples of 32 bytes (yes, this is
|
|
even true for ``byte[]``, but not for ``bytes`` and ``string``). Multi-dimensional memory
|
|
arrays are pointers to memory arrays. The length of a dynamic array is stored at the
|
|
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.
|
|
|
|
|
|
Standalone Assembly
|
|
===================
|
|
|
|
The assembly language described as inline assembly above can also be used
|
|
standalone and in fact, the plan is to use it as an intermediate language
|
|
for the Solidity compiler. In this form, it tries to achieve several goals:
|
|
|
|
1. Programs written in it should be readable, even if the code is generated by a compiler from Solidity.
|
|
2. The translation from assembly to bytecode should contain as few "surprises" as possible.
|
|
3. Control flow should be easy to detect to help in formal verification and optimization.
|
|
|
|
In order to achieve the first and last goal, assembly provides high-level constructs
|
|
like ``for`` loops, ``switch`` statements and function calls. It should be possible
|
|
to write assembly programs that do not make use of explicit ``SWAP``, ``DUP``,
|
|
``JUMP`` and ``JUMPI`` statements, because the first two obfuscate the data flow
|
|
and the last two obfuscate control flow. Furthermore, functional statements of
|
|
the form ``mul(add(x, y), 7)`` are preferred over pure opcode statements like
|
|
``7 y x add mul`` because in the first form, it is much easier to see which
|
|
operand is used for which opcode.
|
|
|
|
The second goal is achieved by introducing a desugaring phase that only removes
|
|
the higher level constructs in a very regular way and still allows inspecting
|
|
the generated low-level assembly code. The only non-local operation performed
|
|
by the assembler is name lookup of user-defined identifiers (functions, variables, ...),
|
|
which follow very simple and regular scoping rules and cleanup of local variables from the stack.
|
|
|
|
Scoping: An identifier that is declared (label, variable, function, assembly)
|
|
is only visible in the block where it was declared (including nested blocks
|
|
inside the current block). It is not legal to access local variables across
|
|
function borders, even if they would be in scope. Shadowing is allowed, but
|
|
two identifiers with the same name cannot be declared in the same block.
|
|
Local variables cannot be accessed before they were declared, but labels,
|
|
functions and assemblies can. Assemblies are special blocks that are used
|
|
for e.g. returning runtime code or creating contracts. No identifier from an
|
|
outer assembly is visible in a sub-assembly.
|
|
|
|
If control flow passes over the end of a block, pop instructions are inserted
|
|
that match the number of local variables declared in that block, unless the
|
|
``}`` is directly preceded by an opcode that does not have a continuing control
|
|
flow path. Whenever a local variable is referenced, the code generator needs
|
|
to know its current relative position in the stack and thus it needs to
|
|
keep track of the current so-called stack height.
|
|
At the end of a block, this implicit stack height is always reduced by the number
|
|
of local variables whether ther is a continuing control flow or not.
|
|
|
|
This means that the stack height before and after the block should be the same.
|
|
If this is not the case, a warning is issued,
|
|
unless the last instruction in the block did not have a continuing control flow path.
|
|
|
|
Why do we use higher-level constructs like ``switch``, ``for`` and functions:
|
|
|
|
Using ``switch``, ``for`` and functions, it should be possible to write
|
|
complex code without using ``jump`` or ``jumpi`` manually. This makes it much
|
|
easier to analyze the control flow, which allows for improved formal
|
|
verification and optimization.
|
|
|
|
Furthermore, if manual jumps are allowed, computing the stack height is rather complicated.
|
|
The position of all local variables on the stack needs to be known, otherwise
|
|
neither references to local variables nor removing local variables automatically
|
|
from the stack at the end of a block will work properly. Because of that,
|
|
every label that is preceded by an instruction that ends or diverts control flow
|
|
should be annotated with the current stack layout. This annotation is performed
|
|
automatically during the desugaring phase.
|
|
|
|
Example:
|
|
|
|
We will follow an example compilation from Solidity to desugared assembly.
|
|
We consider the runtime bytecode of the following Solidity program::
|
|
|
|
contract C {
|
|
function f(uint x) returns (uint y) {
|
|
y = 1;
|
|
for (uint i = 0; i < x; i++)
|
|
y = 2 * y;
|
|
}
|
|
}
|
|
|
|
The following assembly will be generated::
|
|
|
|
{
|
|
mstore(0x40, 0x60) // store the "free memory pointer"
|
|
// function dispatcher
|
|
switch div(calldataload(0), exp(2, 226))
|
|
case 0xb3de648b: {
|
|
let (r) = f(calldataload(4))
|
|
let ret := $allocate(0x20)
|
|
mstore(ret, r)
|
|
return(ret, 0x20)
|
|
}
|
|
default: { jump(invalidJumpLabel) }
|
|
// memory allocator
|
|
function $allocate(size) -> (pos) {
|
|
pos := mload(0x40)
|
|
mstore(0x40, add(pos, size))
|
|
}
|
|
// the contract function
|
|
function f(x) -> (y) {
|
|
y := 1
|
|
for { let i := 0 } lt(i, x) { i := add(i, 1) } {
|
|
y := mul(2, y)
|
|
}
|
|
}
|
|
}
|
|
|
|
After the desugaring phase it looks as follows::
|
|
|
|
{
|
|
mstore(0x40, 0x60)
|
|
{
|
|
let $0 := div(calldataload(0), exp(2, 226))
|
|
jumpi($case1, eq($0, 0xb3de648b))
|
|
jump($caseDefault)
|
|
$case1:
|
|
{
|
|
// the function call - we put return label and arguments on the stack
|
|
$ret1 calldataload(4) jump($fun_f)
|
|
$ret1 [r]: // a label with a [...]-annotation resets the stack height
|
|
// to "current block + number of local variables". It also
|
|
// introduces a variable, r:
|
|
// r is at top of stack, $0 is below (from enclosing block)
|
|
$ret2 0x20 jump($fun_allocate)
|
|
$ret2 [ret]: // stack here: $0, r, ret (top)
|
|
mstore(ret, r)
|
|
return(ret, 0x20)
|
|
// although it is useless, the jump is automatically inserted,
|
|
// since the desugaring process does not analyze control-flow
|
|
jump($endswitch)
|
|
}
|
|
$caseDefault:
|
|
{
|
|
jump(invalidJumpLabel)
|
|
jump($endswitch)
|
|
}
|
|
$endswitch:
|
|
}
|
|
jump($afterFunction)
|
|
$fun_allocate:
|
|
{
|
|
$start[$retpos, size]:
|
|
// output variables live in the same scope as the arguments.
|
|
let pos := 0
|
|
{
|
|
pos := mload(0x40)
|
|
mstore(0x40, add(pos, size))
|
|
}
|
|
swap1 pop swap1 jump
|
|
}
|
|
$fun_f:
|
|
{
|
|
start [$retpos, x]:
|
|
let y := 0
|
|
{
|
|
let i := 0
|
|
$for_begin:
|
|
jumpi($for_end, iszero(lt(i, x)))
|
|
{
|
|
y := mul(2, y)
|
|
}
|
|
$for_continue:
|
|
{ i := add(i, 1) }
|
|
jump($for_begin)
|
|
$for_end:
|
|
} // Here, a pop instruction is inserted for i
|
|
swap1 pop swap1 jump
|
|
}
|
|
$afterFunction:
|
|
stop
|
|
}
|
|
|
|
|
|
Assembly happens in four stages:
|
|
|
|
1. Parsing
|
|
2. Desugaring (removes switch, for and functions)
|
|
3. Opcode stream generation
|
|
4. Bytecode generation
|
|
|
|
We will specify steps one to three in a pseudo-formal way. More formal
|
|
specifications will follow.
|
|
|
|
|
|
Parsing / Grammar
|
|
-----------------
|
|
|
|
The tasks of the parser are the following:
|
|
|
|
- Turn the byte stream into a token stream, discarding C++-style comments
|
|
(a special comment exists for source references, but we will not explain it here).
|
|
- Turn the token stream into an AST according to the grammar below
|
|
- Register identifiers with the block they are defined in (annotation to the
|
|
AST node) and note from which point on, variables can be accessed.
|
|
|
|
The assembly lexer follows the one defined by Solidity itself.
|
|
|
|
Whitespace is used to delimit tokens and it consists of the characters
|
|
Space, Tab and Linefeed. Comments are regular JavaScript/C++ comments and
|
|
are interpreted in the same way as Whitespace.
|
|
|
|
Grammar::
|
|
|
|
AssemblyBlock = '{' AssemblyItem* '}'
|
|
AssemblyItem =
|
|
Identifier |
|
|
AssemblyBlock |
|
|
FunctionalAssemblyExpression |
|
|
AssemblyLocalDefinition |
|
|
FunctionalAssemblyAssignment |
|
|
AssemblyAssignment |
|
|
LabelDefinition |
|
|
AssemblySwitch |
|
|
AssemblyFunctionDefinition |
|
|
AssemblyFor |
|
|
'break' | 'continue' |
|
|
SubAssembly | 'dataSize' '(' Identifier ')' |
|
|
LinkerSymbol |
|
|
'errorLabel' | 'bytecodeSize' |
|
|
NumberLiteral | StringLiteral | HexLiteral
|
|
Identifier = [a-zA-Z_$] [a-zA-Z_0-9]*
|
|
FunctionalAssemblyExpression = Identifier '(' ( AssemblyItem ( ',' AssemblyItem )* )? ')'
|
|
AssemblyLocalDefinition = 'let' IdentifierOrList ':=' FunctionalAssemblyExpression
|
|
FunctionalAssemblyAssignment = IdentifierOrList ':=' FunctionalAssemblyExpression
|
|
IdentifierOrList = Identifier | '(' IdentifierList ')'
|
|
IdentifierList = Identifier ( ',' Identifier)*
|
|
AssemblyAssignment = '=:' Identifier
|
|
LabelDefinition = Identifier ( '[' ( IdentifierList | NumberLiteral ) ']' )? ':'
|
|
AssemblySwitch = 'switch' FunctionalAssemblyExpression AssemblyCase*
|
|
( 'default' ':' AssemblyBlock )?
|
|
AssemblyCase = 'case' FunctionalAssemblyExpression ':' AssemblyBlock
|
|
AssemblyFunctionDefinition = 'function' Identifier '(' IdentifierList? ')'
|
|
( '->' '(' IdentifierList ')' )? AssemblyBlock
|
|
AssemblyFor = 'for' ( AssemblyBlock | FunctionalAssemblyExpression)
|
|
FunctionalAssemblyExpression ( AssemblyBlock | FunctionalAssemblyExpression) AssemblyBlock
|
|
SubAssembly = 'assembly' Identifier AssemblyBlock
|
|
LinkerSymbol = 'linkerSymbol' '(' StringLiteral ')'
|
|
NumberLiteral = HexNumber | DecimalNumber
|
|
HexLiteral = 'hex' ('"' ([0-9a-fA-F]{2})* '"' | '\'' ([0-9a-fA-F]{2})* '\'')
|
|
StringLiteral = '"' ([^"\r\n\\] | '\\' .)* '"'
|
|
HexNumber = '0x' [0-9a-fA-F]+
|
|
DecimalNumber = [0-9]+
|
|
|
|
|
|
Desugaring
|
|
----------
|
|
|
|
An AST transformation removes for, switch and function constructs. The result
|
|
is still parseable by the same parser, but it will not use certain constructs.
|
|
If jumpdests are added that are only jumped to and not continued at, information
|
|
about the stack content is added, unless no local variables of outer scopes are
|
|
accessed or the stack height is the same as for the previous instruction.
|
|
|
|
Pseudocode::
|
|
|
|
desugar item: AST -> AST =
|
|
match item {
|
|
AssemblyFunctionDefinition('function' name '(' arg1, ..., argn ')' '->' ( '(' ret1, ..., retm ')' body) ->
|
|
<name>:
|
|
{
|
|
$<name>_start [$retPC, $argn, ..., arg1]:
|
|
let ret1 := 0 ... let retm := 0
|
|
{ desugar(body) }
|
|
swap and pop items so that only ret1, ... retn, $retPC are left on the stack
|
|
jump
|
|
}
|
|
AssemblyFor('for' { init } condition post body) ->
|
|
{
|
|
init // cannot be its own block because we want variable scope to extend into the body
|
|
// find I such that there are no labels $forI_*
|
|
$forI_begin:
|
|
jumpi($forI_end, iszero(condition))
|
|
{ body }
|
|
$forI_continue:
|
|
{ post }
|
|
jump($forI_begin)
|
|
$forI_end:
|
|
}
|
|
'break' ->
|
|
{
|
|
// find nearest enclosing scope with label $forI_end
|
|
pop all local variables that are defined at the current point
|
|
but not at $forI_end
|
|
jump($forI_end)
|
|
}
|
|
'continue' ->
|
|
{
|
|
// find nearest enclosing scope with label $forI_continue
|
|
pop all local variables that are defined at the current point
|
|
but not at $forI_continue
|
|
jump($forI_continue)
|
|
}
|
|
AssemblySwitch(switch condition cases ( default: defaultBlock )? ) ->
|
|
{
|
|
// find I such that there is no $switchI* label or variable
|
|
let $switchI_value := condition
|
|
for each of cases match {
|
|
case val: -> jumpi($switchI_caseJ, eq($switchI_value, val))
|
|
}
|
|
if default block present: ->
|
|
{ defaultBlock jump($switchI_end) }
|
|
for each of cases match {
|
|
case val: { body } -> $switchI_caseJ: { body jump($switchI_end) }
|
|
}
|
|
$switchI_end:
|
|
}
|
|
FunctionalAssemblyExpression( identifier(arg1, arg2, ..., argn) ) ->
|
|
{
|
|
if identifier is function <name> with n args and m ret values ->
|
|
{
|
|
// find I such that $funcallI_* does not exist
|
|
$funcallI_return argn ... arg2 arg1 jump(<name>)
|
|
if the current context is `let (id1, ..., idm) := f(...)` ->
|
|
$funcallI_return [id1, ..., idm]:
|
|
else ->
|
|
$funcallI_return[m - n - 1]:
|
|
turn the functional expression that leads to the function call
|
|
into a statement stream
|
|
}
|
|
else -> desugar(children of node)
|
|
}
|
|
default node ->
|
|
desugar(children of node)
|
|
}
|
|
|
|
Opcode Stream Generation
|
|
------------------------
|
|
|
|
During opcode stream generation, we keep track of the current stack height,
|
|
so that accessing stack variables by name is possible.
|
|
|
|
Pseudocode::
|
|
|
|
codegen item: AST -> opcode_stream =
|
|
match item {
|
|
AssemblyBlock({ items }) ->
|
|
join(codegen(item) for item in items)
|
|
if last generated opcode has continuing control flow:
|
|
POP for all local variables registered at the block (including variables
|
|
introduced by labels)
|
|
warn if the stack height at this point is not the same as at the start of the block
|
|
Identifier(id) ->
|
|
lookup id in the syntactic stack of blocks
|
|
match type of id
|
|
Local Variable ->
|
|
DUPi where i = 1 + stack_height - stack_height_of_identifier(id)
|
|
Label ->
|
|
// reference to be resolved during bytecode generation
|
|
PUSH<bytecode position of label>
|
|
SubAssembly ->
|
|
PUSH<bytecode position of subassembly data>
|
|
FunctionalAssemblyExpression(id ( arguments ) ) ->
|
|
join(codegen(arg) for arg in arguments.reversed())
|
|
id (which has to be an opcode, might be a function name later)
|
|
AssemblyLocalDefinition(let (id1, ..., idn) := expr) ->
|
|
register identifiers id1, ..., idn as locals in current block at current stack height
|
|
codegen(expr) - assert that expr returns n items to the stack
|
|
FunctionalAssemblyAssignment((id1, ..., idn) := expr) ->
|
|
lookup id1, ..., idn in the syntactic stack of blocks, assert that they are variables
|
|
codegen(expr)
|
|
for j = n, ..., i:
|
|
SWAPi where i = 1 + stack_height - stack_height_of_identifier(idj)
|
|
POP
|
|
AssemblyAssignment(=: id) ->
|
|
look up id in the syntactic stack of blocks, assert that it is a variable
|
|
SWAPi where i = 1 + stack_height - stack_height_of_identifier(id)
|
|
POP
|
|
LabelDefinition(name [id1, ..., idn] :) ->
|
|
JUMPDEST
|
|
// register new variables id1, ..., idn and set the stack height to
|
|
// stack_height_at_block_start + number_of_local_variables
|
|
LabelDefinition(name [number] :) ->
|
|
JUMPDEST
|
|
// adjust stack height by +number (can be negative)
|
|
NumberLiteral(num) ->
|
|
PUSH<num interpreted as decimal and right-aligned>
|
|
HexLiteral(lit) ->
|
|
PUSH32<lit interpreted as hex and left-aligned>
|
|
StringLiteral(lit) ->
|
|
PUSH32<lit utf-8 encoded and left-aligned>
|
|
SubAssembly(assembly <name> block) ->
|
|
append codegen(block) at the end of the code
|
|
dataSize(<name>) ->
|
|
assert that <name> is a subassembly ->
|
|
PUSH32<size of code generated from subassembly <name>>
|
|
linkerSymbol(<lit>) ->
|
|
PUSH32<zeros> and append position to linker table
|
|
}
|