#include #include #include #include #include "util.h" #include "lllparser.h" #include "bignum.h" std::string valid[][3] = { { "if", "2", "3" }, { "unless", "2", "2" }, { "while", "2", "2" }, { "until", "2", "2" }, { "code", "1", "2" }, { "init", "2", "2" }, { "shared", "2", "3" }, { "alloc", "1", "1" }, { "array", "1", "1" }, { "call", "2", "4" }, { "create", "1", "4" }, { "msg", "4", "6" }, { "getch", "2", "2" }, { "setch", "3", "3" }, { "sha3", "1", "2" }, { "return", "1", "2" }, { "inset", "1", "1" }, { "array_lit", "0", tt256 }, { "seq", "0", tt256 }, { "---END---", "", "" } //Keep this line at the end of the list }; std::string macros[][2] = { { "(+= $a $b)", "(set $a (+ $a $b))" }, { "(*= $a $b)", "(set $a (* $a $b))" }, { "(-= $a $b)", "(set $a (- $a $b))" }, { "(/= $a $b)", "(set $a (/ $a $b))" }, { "(%= $a $b)", "(set $a (% $a $b))" }, { "(^= $a $b)", "(set $a (^ $a $b))" }, { "(@/= $a $b)", "(set $a (@/ $a $b))" }, { "(@%= $a $b)", "(set $a (@% $a $b))" }, { "(!= $a $b)", "(not (eq $a $b))" }, { "(if $cond $do (else $else))", "(if $cond $do $else)" }, { "(code $code)", "$code" }, { "(access msg.data $ind)", "(calldataload (mul 32 $ind))" }, { "(array $len)", "(alloc (mul 32 $len))" }, { "(while $cond $do)", "(until (not $cond) $do)", }, { "(while (not $cond) $do)", "(until $cond $do)", }, { "(if $cond $do)", "(unless (not $cond) $do)", }, { "(if (not $cond) $do)", "(unless $cond $do)", }, { "(access contract.storage $ind)", "(sload $ind)" }, { "(access $var $ind)", "(mload (add $var (mul 32 $ind)))" }, { "(set (access contract.storage $ind) $val)", "(sstore $ind $val)" }, { "(set (access $var $ind) $val)", "(mstore (add $var (mul 32 $ind)) $val)" }, { "(getch $var $ind)", "(mod (mload (add $var $ind)) 256)" }, { "(setch $var $ind $val)", "(mstore8 (add $var $ind) $val)", }, { "(send $to $value)", "(call (sub (gas) 25) $to $value 0 0 0 0)" }, { "(send $gas $to $value)", "(call $gas $to $value 0 0 0 0)" }, { "(sha3 $x)", "(seq (set $1 $x) (~sha3 (ref $1) 32))" }, { "(sha3 $mstart $msize)", "(~sha3 $mstart (mul 32 $msize))" }, { "(id $0)", "$0" }, { "(return $x)", "(seq (set $1 $x) (~return (ref $1) 32))" }, { "(return $start $len)", "(~return $start (mul 32 $len))" }, { "(&& $x $y)", "(if $x $y 0)" }, { "(|| $x $y)", "(seq (set $1 $x) (if (get $1) (get $1) $y))" }, { "(>= $x $y)", "(not (slt $x $y))" }, { "(<= $x $y)", "(not (sgt $x $y))" }, { "(@>= $x $y)", "(not (lt $x $y))" }, { "(@<= $x $y)", "(not (gt $x $y))" }, { "(create $code)", "(create 0 $code)" }, { "(create $endowment $code)", "(seq (set $1 (msize)) (create $endowment (get $1) (lll (outer $code) (msize))))" }, { "(call $f $dataval)", "(msg (sub (gas) 45) $f 0 $dataval)" }, { "(call $f $inp $inpsz)", "(msg (sub (gas) 25) $f 0 $inp $inpsz)" }, { "(call $f $inp $inpsz $outsz)", "(seq (set $1 $outsz) (set $2 (alloc (mul 32 (get $1)))) (pop (call (sub (gas) (add 25 (get $1))) $f 0 $inp (mul 32 $inpsz) (get $2) (mul 32 (get $1)))) (get $2))" }, { "(msg $gas $to $val $inp $inpsz)", "(seq (call $gas $to $val $inp (mul 32 $inpsz) (ref $1) 32) (get $1))" }, { "(msg $gas $to $val $dataval)", "(seq (set $1 $dataval) (call $gas $to $val (ref $1) 32 (ref $2) 32) (get $2))" }, { "(msg $gas $to $val $inp $inpsz $outsz)", "(seq (set $1 (mul 32 $outsz)) (set $2 (alloc (get $1))) (pop (call $gas $to $val $inp (mul 32 $inpsz) (get $2) (get $1))) (get $2))" }, { "(outer (init $init $code))", "(seq $init (~return 0 (lll $code 0)))" }, { "(outer (shared $shared (init $init (code $code))))", "(seq $shared $init (~return 0 (lll (seq $shared $code) 0)))" }, { "(outer $code)", "(~return 0 (lll $code 0))" }, { "(seq (seq) $x)", "$x" }, { "(inset $x)", "$x" }, { "(create $x)", "(seq (set $1 (msize)) (create $val (get $1) (lll $code (get $1))))" }, { "msg.datasize", "(div (calldatasize) 32)" }, { "msg.sender", "(caller)" }, { "msg.value", "(callvalue)" }, { "tx.gasprice", "(gasprice)" }, { "tx.origin", "(origin)" }, { "tx.gas", "(gas)" }, { "contract.balance", "(balance)" }, { "contract.address", "(address)" }, { "block.prevhash", "(prevhash)" }, { "block.coinbase", "(coinbase)" }, { "block.timestamp", "(timestamp)" }, { "block.number", "(number)" }, { "block.difficulty", "(difficulty)" }, { "block.gaslimit", "(gaslimit)" }, { "stop", "(stop)" }, { "---END---", "" } //Keep this line at the end of the list }; std::vector > nodeMacros; std::string synonyms[][2] = { { "or", "||" }, { "and", "&&" }, { "elif", "if" }, { "!", "not" }, { "string", "alloc" }, { "+", "add" }, { "-", "sub" }, { "*", "mul" }, { "/", "sdiv" }, { "^", "exp" }, { "**", "exp" }, { "%", "smod" }, { "@/", "div" }, { "@%", "mod" }, { "@<", "lt" }, { "@>", "gt" }, { "<", "slt" }, { ">", "sgt" }, { "=", "set" }, { "==", "eq" }, { "---END---", "" } //Keep this line at the end of the list }; struct matchResult { bool success; std::map map; }; // Returns two values. First, a boolean to determine whether the node matches // the pattern, second, if the node does match then a map mapping variables // in the pattern to nodes matchResult match(Node p, Node n) { matchResult o; o.success = false; if (p.type == TOKEN) { if (p.val == n.val && n.type == TOKEN) o.success = true; else if (p.val[0] == '$') { o.success = true; o.map[p.val.substr(1)] = n; } } else if (n.type==TOKEN || p.val!=n.val || p.args.size()!=n.args.size()) { } else { for (unsigned i = 0; i < p.args.size(); i++) { matchResult oPrime = match(p.args[i], n.args[i]); if (!oPrime.success) { o.success = false; return o; } for (std::map::iterator it = oPrime.map.begin(); it != oPrime.map.end(); it++) { o.map[(*it).first] = (*it).second; } } o.success = true; } return o; } // Fills in the pattern with a dictionary mapping variable names to // nodes (these dicts are generated by match). Match and subst together // create a full pattern-matching engine. Node subst(Node pattern, std::map dict, std::string varflag, Metadata metadata) { if (pattern.type == TOKEN && pattern.val[0] == '$') { if (dict.count(pattern.val.substr(1))) { return dict[pattern.val.substr(1)]; } else { return token(varflag + pattern.val.substr(1), metadata); } } else if (pattern.type == TOKEN) { return pattern; } else { std::vector args; for (unsigned i = 0; i < pattern.args.size(); i++) { args.push_back(subst(pattern.args[i], dict, varflag, metadata)); } return astnode(pattern.val, args, metadata); } } // array_lit transform Node array_lit_transform(Node node) { std::vector o1; o1.push_back(token(intToDecimal(node.args.size() * 32), node.metadata)); std::vector o2; std::string symb = "_temp"+mkUniqueToken()+"_0"; o2.push_back(token(symb, node.metadata)); o2.push_back(astnode("alloc", o1, node.metadata)); std::vector o3; o3.push_back(astnode("set", o2, node.metadata)); for (unsigned i = 0; i < node.args.size(); i++) { // (mstore (add (get symb) i*32) v) std::vector o5; o5.push_back(token(symb, node.metadata)); std::vector o6; o6.push_back(astnode("get", o5, node.metadata)); o6.push_back(token(intToDecimal(i * 32), node.metadata)); std::vector o7; o7.push_back(astnode("add", o6)); o7.push_back(node.args[i]); o3.push_back(astnode("mstore", o7, node.metadata)); } std::vector o8; o8.push_back(token(symb, node.metadata)); o3.push_back(astnode("get", o8)); return astnode("seq", o3, node.metadata); } // Recursively applies rewrite rules Node apply_rules(Node node) { // If the rewrite rules have not yet been parsed, parse them if (!nodeMacros.size()) { for (int i = 0; i < 9999; i++) { std::vector o; if (macros[i][0] == "---END---") break; o.push_back(parseLLL(macros[i][0])); o.push_back(parseLLL(macros[i][1])); nodeMacros.push_back(o); } } // Main code unsigned pos = 0; std::string prefix = "_temp"+mkUniqueToken()+"_"; while(1) { if (synonyms[pos][0] == "---END---") { break; } else if (node.type == ASTNODE && node.val == synonyms[pos][0]) { node.val = synonyms[pos][1]; } pos++; } for (pos = 0; pos < nodeMacros.size(); pos++) { Node pattern = nodeMacros[pos][0]; matchResult mr = match(pattern, node); if (mr.success) { Node pattern2 = nodeMacros[pos][1]; node = subst(pattern2, mr.map, prefix, node.metadata); } } // Array_lit special instruction if (node.val == "array_lit") node = array_lit_transform(node); if (node.type == ASTNODE && node.val != "ref" && node.val != "get") { unsigned i = 0; if (node.val == "set") i = 1; for (i = i; i < node.args.size(); i++) { node.args[i] = apply_rules(node.args[i]); } } else if (node.type == TOKEN && !isNumberLike(node)) { std::vector args; args.push_back(node); node = astnode("get", args, node.metadata); } // This allows people to use ~x as a way of having functions with the same // name and arity as macros; the idea is that ~x is a "final" form, and // should not be remacroed, but it is converted back at the end if (node.type == ASTNODE && node.val[0] == '~') node.val = node.val.substr(1); return node; } Node optimize(Node inp) { if (inp.type == TOKEN) return tryNumberize(inp); for (unsigned i = 0; i < inp.args.size(); i++) { inp.args[i] = optimize(inp.args[i]); } if (inp.args.size() == 2 && inp.args[0].type == TOKEN && inp.args[1].type == TOKEN) { std::string o; if (inp.val == "add") { o = decimalMod(decimalAdd(inp.args[0].val, inp.args[1].val), tt256); } else if (inp.val == "sub") { if (decimalGt(inp.args[0].val, inp.args[1].val, true)) o = decimalSub(inp.args[0].val, inp.args[1].val); } else if (inp.val == "mul") { o = decimalMod(decimalMul(inp.args[0].val, inp.args[1].val), tt256); } else if (inp.val == "div" && inp.args[1].val != "0") { o = decimalDiv(inp.args[0].val, inp.args[1].val); } else if (inp.val == "sdiv" && inp.args[1].val != "0" && decimalGt(tt255, inp.args[0].val) && decimalGt(tt255, inp.args[1].val)) { o = decimalDiv(inp.args[0].val, inp.args[1].val); } else if (inp.val == "mod" && inp.args[1].val != "0") { o = decimalMod(inp.args[0].val, inp.args[1].val); } else if (inp.val == "smod" && inp.args[1].val != "0" && decimalGt(tt255, inp.args[0].val) && decimalGt(tt255, inp.args[1].val)) { o = decimalMod(inp.args[0].val, inp.args[1].val); } if (o.length()) return token(o, inp.metadata); } return inp; } Node validate(Node inp) { if (inp.type == ASTNODE) { int i = 0; while(valid[i][0] != "---END---") { if (inp.val == valid[i][0]) { if (decimalGt(valid[i][1], intToDecimal(inp.args.size()))) { err("Too few arguments for "+inp.val, inp.metadata); } if (decimalGt(intToDecimal(inp.args.size()), valid[i][2])) { err("Too many arguments for "+inp.val, inp.metadata); } } i++; } } for (unsigned i = 0; i < inp.args.size(); i++) validate(inp.args[i]); return inp; } Node preprocess(Node inp) { std::vector args; args.push_back(inp); return astnode("outer", args, inp.metadata); } Node rewrite(Node inp) { return optimize(apply_rules(validate(preprocess(inp)))); } using namespace std;